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WO2019227361A1 - System information block (sib) transmission method and device - Google Patents

System information block (sib) transmission method and device Download PDF

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Publication number
WO2019227361A1
WO2019227361A1 PCT/CN2018/089101 CN2018089101W WO2019227361A1 WO 2019227361 A1 WO2019227361 A1 WO 2019227361A1 CN 2018089101 W CN2018089101 W CN 2018089101W WO 2019227361 A1 WO2019227361 A1 WO 2019227361A1
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WO
WIPO (PCT)
Prior art keywords
sib
period
time
transmitted
duration
Prior art date
Application number
PCT/CN2018/089101
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French (fr)
Chinese (zh)
Inventor
韩金侠
李振宇
南杨
李铮
张武荣
Original Assignee
华为技术有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Publication date
Application filed by 华为技术有限公司 filed Critical 华为技术有限公司
Priority to CN201880094029.7A priority Critical patent/CN112586030B/en
Priority to PCT/CN2018/089101 priority patent/WO2019227361A1/en
Publication of WO2019227361A1 publication Critical patent/WO2019227361A1/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/04Error control
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02DCLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
    • Y02D30/00Reducing energy consumption in communication networks
    • Y02D30/70Reducing energy consumption in communication networks in wireless communication networks

Definitions

  • the present application relates to the field of communications, and in particular, to a method and device for transmitting a system information block SIB.
  • Narrowband Internet of Things technology is an emerging technology in the field of Internet of Things. It supports the cellular data connection of low-power devices in the WAN. It has wide coverage, multiple connections, fast speed, low cost, and high performance. Low power consumption and excellent architecture.
  • the narrowband Internet of Things can also be called low-power wide-area network (LPWAN).
  • LPWAN low-power wide-area network
  • MFA MulteFire Alliance
  • MFA has proposed a narrowband Internet of Things (NB-IoT-U) technology based on unlicensed spectrum.
  • NB-IoT-U has the technical characteristics of NB-IoT, but in order to adapt to unlicensed spectrum regulations (for example, spectrum regulations of the Federal Communications Commission (FCC) and European Telecommunications Standards Institute (ETSI)) Spectrum regulations), based on the NB-IoT frame structure, made some modifications to adapt to unlicensed spectrum regulations.
  • unlicensed spectrum regulations for example, spectrum regulations of the Federal Communications Commission (FCC) and European Telecommunications Standards Institute (ETSI)
  • FCC Federal Communications Commission
  • ETSI European Telecommunications Standards Institute
  • one frame structure of NB-IoT-U is that both uplink and downlink comply with frequency hopping regulations
  • another possible frame structure is that uplink meets frequency hopping regulations and downlink meet Digital modulation regulations.
  • the third possible frame structure is that the uplink conforms to the frequency hopping regulations, and the downward behavior is a mixed mode, that is, the primary fixed channel part (or primary fixed segment) complies with the digital modulation regulations.
  • the data channel Partially (or data segments) comply with frequency hopping regulations.
  • the frame structure of NB-IoT-U is a frame structure that meets the requirements of the duty cycle.
  • FIG. 1 is a schematic structural diagram of sending a system information block (system information block) in an NB-IoT-U system provided in the prior art.
  • system information block system information block
  • the SIB is sent at a predetermined number of consecutive valid downlink subframes in a fixed channel period. If the SIB period includes two fixed channel periods, the SIB is concentrated to be transmitted in one fixed channel period, and no SIB is transmitted in the other fixed channel period.
  • the terminal device finishes receiving the master information block (master information block, MIB) within a fixed channel period without SIB transmission, it needs to wait for another fixed channel period to receive the SIB. Therefore, the delay of the initial access of the cell by the terminal device is increased.
  • master information block master information block
  • the embodiments of the present application provide a SIB transmission method and device, which can effectively reduce the delay of a terminal device accessing a network.
  • an SIB transmission method including: repeatedly sending N SIBs in a first period in the time domain, and the first period includes m second periods. It is understandable that the first The second cycle duration is m times the cycle duration, N is a positive integer greater than 0, and m is a positive integer greater than 0. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is The number of repetitions of the SIB in the m second period of the m second periods is Rounds up.
  • the sending entity that sends the SIB may be a base station or a chip of the base station.
  • the receiving entity receiving the SIB may be a terminal device or a chip of the terminal device.
  • N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
  • the SIBs that need to be sent in each second period from the first second period to the m-1th second period in the m second periods can be sent through the following specific implementation methods:
  • the first implementation manner is that each of the m second period to the m-1 second period to the second Secondary SIBs can be sent at regular intervals. Secondary SIB occupation Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
  • the second achievable manner is that each of the m second period to the m-1 second period to each second period sent in the second period Secondary SIB occupation Time units, Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit can also be 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • the SIBs that need to be sent in the m second period of the m second periods can be sent in the following specific implementation manners:
  • the first implementable manner is that in the m second period, the Secondary SIBs can be sent at regular intervals. Secondary SIB occupation Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
  • the second achievable manner the m sent in the m second period of the second period Secondary SIB occupation Time units, Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit can also be 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • N is a positive integer and N is an integer power of 2; m is a positive integer and m is an integer power of 2; The number of repetitions of the SIB in each of the second cycles is N / m.
  • SIBs that need to be sent in each of the m second cycles can be sent in the following specific implementations:
  • N / m SIBs sent in each second period occupy N / m time units.
  • the SIB takes one time unit.
  • the duration of the time unit is T2 * m / N, and T2 represents the duration of the second cycle.
  • the duration of the time unit is 160 milliseconds.
  • N / m times of SIBs transmitted in each second cycle occupy N / m time units, N / m time units are transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit is 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • N / m SIBs are transmitted continuously in each second cycle, the N / m transmitted SIBs occupy consecutive N * p / m downlink subframes, and p is a single SIB transmission and occupies downlinks.
  • the number of subframes, for example, p 8.
  • N SIBs repeatedly sent in the first period in the time domain are evenly distributed in the second period, so that the terminal device does not need to wait for a second period to receive the SIB, thereby reducing the terminal device's initial cell access. Delay.
  • the start time of sending the SIB for the first time in each second period is the time of the second period to which the first sent SIB belongs. The time at which the start time starts to shift from the preset offset value.
  • the duration of the time unit is T2 * m / N or 160ms.
  • the start of sending the SIB in each time unit The start time is the time offset from the start time of the time unit by a preset offset value.
  • the time unit duration is 160ms.
  • the start time of sending the SIB in each time unit is the slave time unit. The time at which the start time of the offset starts to shift from the preset offset value.
  • the preset offset value may be pre-configured; or, the preset offset value is carried through the MIB.
  • the preset offset value can be 40 milliseconds.
  • the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel.
  • the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value.
  • the start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value.
  • the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
  • the data channel may also be referred to as a data segment.
  • the number of SIB transmissions in each second cycle of the first N second cycles is 1, and in each second cycle of the next mN second cycles The number of SIB transmissions is zero.
  • an SIB transmission method including: receiving N SIBs in a first period in the time domain, and the first period includes m second periods. It is understandable that the first period The duration of the second period is m times, N is a positive integer greater than 0, and m is a positive integer greater than 0. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is The number of repetitions of the SIB in the m second period of the m second periods is Rounds up.
  • the sending entity that sends the SIB may be a base station or a chip of the base station.
  • the receiving entity receiving the SIB may be a terminal device or a chip of the terminal device.
  • N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
  • the SIBs that need to be sent in each second period from the first second period to the m-1th second period in the m second periods can be sent through the following specific implementation methods:
  • the first implementation manner is that each of the m second period to the m-1 second period to the second Secondary SIBs can be sent at regular intervals. Secondary SIB occupation Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
  • the second achievable manner is that each of the m second period to the m-1 second period to each second period sent in the second period Secondary SIB occupation Time units, Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit can also be 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • the SIBs that need to be sent in the m second period of the m second periods can be sent in the following specific implementation manners:
  • the first implementable manner is that in the m second period, the Secondary SIBs can be sent at regular intervals. Secondary SIB occupation Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
  • the second achievable manner the m sent in the m second period of the second period Secondary SIB occupation Time units, Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit can also be 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • N is a positive integer and N is an integer power of 2
  • m is a positive integer and m is an integer power of 2
  • N is greater than or equal to m
  • m The number of repetitions of the SIB in each of the second cycles is N / m.
  • SIBs that need to be sent in each of the m second cycles can be sent in the following specific implementations:
  • N / m SIBs sent in each second period occupy N / m time units.
  • the SIB takes one time unit.
  • the duration of the time unit is T2 * m / N, and T2 represents the duration of the second cycle.
  • the duration of the time unit is 160 milliseconds.
  • N / m times of SIBs transmitted in each second cycle occupy N / m time units, N / m time units are transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit is 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • N / m SIBs are transmitted continuously in each second cycle, the N / m transmitted SIBs occupy consecutive N * p / m downlink subframes, and p is a single SIB transmission and occupies downlinks.
  • the number of subframes, for example, p 8.
  • N SIBs repeatedly sent in the first period in the time domain are evenly distributed in the second period, so that the terminal device does not need to wait for a second period to receive the SIB, thereby reducing the terminal device's initial cell access. Delay.
  • the start time of sending the SIB for the first time in each second period is the time of the second period to which the first sent SIB belongs. The time at which the start time starts to shift from the preset offset value.
  • the duration of the time unit is T2 * m / N or 160ms.
  • the start of sending the SIB in each time unit The start time is the time offset from the start time of the time unit by a preset offset value.
  • the time unit duration is 160ms.
  • the start time of sending the SIB in each time unit is the slave time unit. The time at which the start time of the offset starts to shift from the preset offset value.
  • the preset offset value may be pre-configured; or, the preset offset value is carried through the MIB.
  • the preset offset value can be 40 milliseconds.
  • the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel.
  • the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value.
  • the start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value.
  • the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
  • the number of SIB transmissions in each second cycle of the first N second cycles is 1, and in each second cycle of the next mN second cycles The number of SIB transmissions is zero.
  • a wireless communication device is provided.
  • the wireless communication device is a base station or a chip of a base station.
  • the wireless communication device includes a sending unit, where the sending unit is configured to be a first unit in the time domain.
  • the SIB is repeatedly sent N times.
  • the first cycle includes m second cycles. It can be understood that the duration of the first cycle is m times the duration of the second cycle, N is a positive integer greater than 0, and m is a positive integer greater than 0. Integer.
  • the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is The number of repetitions of the SIB in the m second period of the m second periods is Rounds up.
  • a wireless communication device is provided.
  • the wireless communication device is a terminal device or a chip of a terminal device.
  • the wireless communication device includes a receiving unit, where the receiving unit is configured to In the first cycle, N SIBs are received.
  • the first cycle includes m second cycles. It can be understood that the length of the first cycle is m times the length of the second cycle. N is a positive integer greater than 0 and m is greater than 0. Positive integer.
  • N is greater than or equal to m
  • the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is The number of repetitions of the SIB in the m second period of the m second periods is Rounds up.
  • the sending entity that sends the SIB may be a base station or a chip of the base station.
  • the receiving entity receiving the SIB may be a terminal device or a chip of the terminal device.
  • N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
  • the SIBs that need to be sent in each second period from the first second period to the m-1th second period in the m second periods can be implemented by the following specific implementation send:
  • the first implementation manner is that each of the m second period to the m-1 second period to the second Secondary SIBs can be sent at regular intervals. Secondary SIB occupation Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
  • the second achievable manner is that each of the m second period to the m-1 second period to each second period sent in the second period Secondary SIB occupation Time units, Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit can also be 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • the SIBs that need to be sent in the m second period of the m second periods can be sent in the following specific implementation manners:
  • the first implementable manner is that in the m second period, the Secondary SIBs can be sent at regular intervals. Secondary SIB occupation Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
  • the second achievable manner the m sent in the m second period of the second period Secondary SIB occupation Time units, Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit can also be 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • N is a positive integer and N is an integer power of 2
  • m is a positive integer and m is an integer power of 2
  • N is greater than or equal to m
  • m The number of repetitions of the SIB in each of the second cycles is N / m.
  • SIBs that need to be sent in each of the m second cycles can be sent in the following specific implementations:
  • N / m SIBs sent in each second period occupy N / m time units.
  • the SIB takes one time unit.
  • the duration of the time unit is T2 * m / N, and T2 represents the duration of the second cycle.
  • the duration of the time unit is 160 milliseconds.
  • N / m times of SIBs transmitted in each second cycle occupy N / m time units, N / m time units are transmitted continuously, and each transmitted SIB occupies one time unit.
  • the duration of the time unit is 160 milliseconds.
  • each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  • each transmitted SIB occupies 8 consecutive downlink subframes.
  • each successively transmitted SIB occupies 4 consecutive downlink subframes.
  • N / m SIBs are transmitted continuously in each second cycle, the N / m transmitted SIBs occupy consecutive N * p / m downlink subframes, and p is a single SIB transmission and occupies downlinks.
  • the number of subframes, for example, p 8.
  • N SIBs repeatedly sent in the first period in the time domain are evenly distributed in the second period, so that the terminal device does not need to wait for a second period to receive the SIB, thereby reducing the terminal device's initial cell access. Delay.
  • the start time of sending the SIB for the first time in each second period is the time of the second period to which the first sent SIB belongs. The time at which the start time starts to shift from the preset offset value.
  • the duration of the time unit is T2 * m / N or 160ms.
  • the start of sending the SIB in each time unit The start time is the time offset from the start time of the time unit by a preset offset value.
  • the time unit duration is 160ms.
  • the start time of sending the SIB in each time unit is the slave time unit. The time at which the start time of the offset starts to shift from the preset offset value.
  • the preset offset value may be pre-configured; or, the preset offset value is carried through the MIB.
  • the preset offset value can be 40 milliseconds.
  • the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel.
  • the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value.
  • the start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value.
  • the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
  • the number of SIB transmissions in each second cycle of the first N second cycles is 1, and in each second cycle of the next mN second cycles The number of SIB transmissions is zero.
  • the functional modules of the third aspect and the fourth aspect may be implemented by hardware, and may also be implemented by hardware executing corresponding software.
  • the hardware or software includes one or more modules corresponding to the above functions.
  • the transceiver is used to complete the functions of the receiving unit and the sending unit
  • the processor is used to complete the functions of the processing unit
  • the memory is used to store the program instructions of the processor for processing the SIB transmission method in the embodiment of the present application.
  • the processor, the transceiver, and the memory are connected and communicate with each other through a bus.
  • an embodiment of the present application provides a device, including: a processor, a memory, a bus, and a transceiver; the memory is used to store a computer to execute instructions, the processor is connected to the memory through the bus, and when the processor runs When the processor executes the computer execution instructions stored in the memory, so that the device executes the method according to any aspect described above.
  • the transceiver when the device is a base station, the transceiver is used to complete a function of a transmitting unit.
  • the transceiver is used to complete the function of the receiving unit.
  • an embodiment of the present application provides a computer-readable storage medium for storing computer software instructions used by the foregoing device, and when the computer software instruction is run on the computer, the computer can execute the method in any of the foregoing aspects.
  • an embodiment of the present application provides a computer program product containing instructions, which when executed on a computer, enables the computer to execute the method in any of the foregoing aspects.
  • the names of the base station, the terminal device, and the wireless communication device do not limit the device itself. In actual implementation, these devices may appear under other names. As long as the functions of each device are similar to the embodiments of the present application, they fall into the scope of the claims of the present application and their equivalent technologies.
  • FIG. 1 is a schematic structural diagram of sending an SIB in an NB-IoT-U system provided in the prior art
  • FIG. 2 is a simplified schematic diagram of a passing system according to an embodiment of the present application.
  • FIG. 3 is a flowchart of a SIB transmission method according to an embodiment of the present application.
  • FIG. 4 is a schematic structural diagram of sending an SIB according to an embodiment of the present application.
  • FIG. 5 is a schematic structural diagram of another SIB sending method according to an embodiment of the present application.
  • FIG. 6 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 7 is a schematic structural diagram of sending a SIB including a secondary fixed channel provided in the prior art
  • FIG. 8 is a schematic structural diagram of sending an SIB including a secondary fixed channel according to an embodiment of the present application.
  • FIG. 9 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 10 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 11 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 12 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 13 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 14 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • 15 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • 16 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • 17 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • FIG. 19 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • 20 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • 21 is a flowchart of another SIB transmission method according to an embodiment of the present application.
  • 22 is a schematic diagram of a frame structure of an NB-IoT-U provided by an embodiment of the present application.
  • FIG. 23 is a schematic diagram of a frame structure of another NB-IoT-U according to an embodiment of the present application.
  • FIG. 24 is a schematic diagram of a frame structure of still another NB-IoT-U according to an embodiment of the present application.
  • FIG. 25 is a schematic structural diagram of a base station according to an embodiment of the present application.
  • FIG. 26 is a schematic structural diagram of a device according to an embodiment of the present application.
  • FIG. 27 is a schematic structural diagram of another base station according to an embodiment of the present application.
  • FIG. 28 is a schematic structural diagram of a base station according to an embodiment of the present application.
  • FIG. 29 is a schematic structural diagram of another base station according to an embodiment of the present application.
  • FIG. 2 shows a simplified schematic diagram of a communication system to which embodiments of the present application can be applied.
  • the communication system may include: a base station 201 and a terminal device 202.
  • the base station 201 may be a base station (BS) or a base station controller for wireless communication. Specifically, the base station may include a user plane base station and a control plane base station.
  • a base station is a device that is deployed in a wireless access network to provide wireless communication functions for the terminal device 202. Its main functions are: management of wireless resources, compression of Internet protocol (IP) headers, and user data flow. Encryption, selection of mobile management entity (MME) when user equipment is attached, routing user plane data to service gateway (SGW), organization and transmission of paging messages, organization and transmission of broadcast messages, Configuration of measurements and measurement reports for mobility or scheduling purposes, etc.
  • the base station 201 may include various forms of macro base stations, micro base stations, relay stations, access points, and the like.
  • the names of equipment with base station functions may be different.
  • LTE networks they are called evolved base stations (evolved NodeB, eNB, or eNodeB).
  • eNB evolved base stations
  • eNodeB evolved base stations
  • a base station Node B
  • gNB next generation base station
  • the base station 201 may be another device that provides a wireless communication function for the terminal device 202.
  • a base station a device that provides a wireless communication function for the terminal device 202 is referred to as a base station.
  • the terminal device 202 may also be called a terminal, a user equipment (UE), a mobile station (MS), a mobile terminal (MT), or the like.
  • the terminal device can be a mobile phone, a tablet, a computer with a wireless transceiver function, a virtual reality (VR) terminal device, an augmented reality (AR) terminal device, an industrial control (industrial control) ), Wireless terminals in self-driving, wireless terminals in remote surgery, wireless terminals in smart grid, wireless terminals in transportation safety Terminals, wireless terminals in smart cities, wireless terminals in smart homes, and so on.
  • the embodiment of the present application does not limit the specific technology and specific device form adopted by the terminal device.
  • the terminal device 202 may also be a relay (Relay) and a base station that can perform data communication can be used as a terminal device.
  • the terminal device 202 is used as a user equipment in a general sense as an example.
  • the communication system provided in the embodiments of the present application may refer to an unauthorized wireless communication system restricted by spectrum regulations.
  • the NB-IoT-U system may refer to an unauthorized wireless communication system restricted by spectrum regulations.
  • the SIB transmission method described in the embodiments of the present application is applicable to spectrum regulations below 1 GHz.
  • the FCC's spectrum regulations impose the following restrictions on devices using the 902MHZ-928MHz band.
  • the 6dB channel bandwidth (bandwidth / each channel) must not be less than 500kHz, the PSD must not be greater than 8dBm / 3kHz, and the transmit power (or conductive power) not greater than 30dBm, which is equivalent Isotropic radiated power (EIRP) is limited to not more than 36 dBm.
  • EIRP Isotropic radiated power
  • FHSS frequency hopping spread spectrum
  • the 20dB channel bandwidth is less than 250kHz, at least 50 frequency hopping channels are supported, and the average occupation time of each channel (average time of occupation) is not greater than 0.4s / 20s, that is, the average occupation time of each channel within 20 seconds No more than 0.4 seconds, and EIRP is no more than 36dBm; if the channel bandwidth is between 250kHz and 500kHz, at least 25 frequency hopping channels are supported, and the average occupation time (average time of each channel) of each channel is not greater than 0.4s / 10s and other restrictions.
  • ETSI imposes the following restrictions on devices using unlicensed frequency bands below 1GHz.
  • the equivalent radiated power (or effective radiated power) (ERP) is 27dBm at the maximum, and the duty cycle is 10% at the maximum within one hour.
  • ERP effective radiated power
  • the equivalent radiated power is 27dBm at the maximum and 1 hour Within the network access point, the maximum duty cycle is 10%, otherwise the duty cycle is 2.5%.
  • words such as “exemplary” or “such as” are used as an example, illustration, or description. Any embodiment or design described as “example” or “such as” in the embodiments of the present application should not be construed as more preferred or more advantageous than other embodiments or designs. Rather, the words “exemplary” or “such as” are used to present concepts in a concrete manner.
  • the network architecture and service scenarios described in the embodiments of the present application are intended to more clearly illustrate the technical solutions of the embodiments of the present application, and do not constitute a limitation on the technical solutions provided by the embodiments of the present application. Those skilled in the art can know that with the network The evolution of the architecture and the emergence of new business scenarios. The technical solutions provided in the embodiments of the present application are also applicable to similar technical issues.
  • connection in the present application means that they can communicate with each other, and specifically, they can be connected in a wired manner or wirelessly, which is not specifically limited in the embodiments of the present application.
  • the devices connected to each other may be directly connected or may be connected through other devices, which is not specifically limited in the embodiment of the present application.
  • the SIB transmission format in the NB-IoT-U system is: starting from a fixed channel period as the boundary. After the synchronization signal and MIB, or synchronization signal, MIB, and other broadcast information are sent, the SIB The number of SIB repetitions in the SIB cycle is concentrated to send all SIBs in a fixed channel period, and all SIBs occupy consecutive effective downlink subframes.
  • the so-called effective downlink subframe is a downlink subframe that can be used for transmitting SIB. If the SIB period includes two fixed channel periods, the SIB is concentrated to be transmitted in one fixed channel period, and no SIB is transmitted in the other fixed channel period. In this case, if the terminal device completes MIB reception within a fixed channel period without SIB transmission, it needs to wait for another fixed channel period to receive SIB. Therefore, the delay of the initial access of the cell by the terminal device is increased.
  • the embodiment of the present application provides a SIB transmission method.
  • the basic principle is: In the first period in the time domain, the SIB is repeatedly transmitted N times.
  • the first period includes m second periods. It is understandable that the duration of the first period is The duration of the second period is m times, N is a positive integer greater than 0, and m is a positive integer greater than 0.
  • N is greater than or equal to m
  • the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is The number of repetitions of the SIB in the m second period of the m second periods is Rounds up.
  • the sending entity that sends the SIB may be a base station or a chip of the base station.
  • the receiving entity receiving the SIB may be a terminal device or a chip of the terminal device.
  • N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
  • the embodiment of the present application assumes that the sending entity is a base station and the receiving entity is a terminal device.
  • the communication between the base station and the terminal device is taken as an example for description.
  • FIG. 3 is a flowchart of a SIB transmission method according to an embodiment of the present application. As shown in FIG. 3, the method may include:
  • the base station repeatedly sends the SIB N times in the first cycle in the time domain.
  • the first period includes m second periods.
  • the first cycle can be understood as the cycle of sending the SIB.
  • the second period can be understood as the (main) fixed channel period.
  • the (main) fixed channel period may also be referred to as a MIB period, a PBCH period, or a (main) discovery reference signal (DRS) period.
  • the so-called main fixed channel can be understood as a fixed frequency of sending synchronization signals and MIBs, or messages such as synchronization signals, MIBs, and other broadcast information.
  • the main fixed channel can also be called a common channel.
  • base stations In order to reduce the delay in the initial access of terminal equipment, base stations usually first send synchronization signals and MIBs, or synchronization signals, MIBs, and other broadcast information, at a fixed frequency point that is predetermined. After waiting for the message, after sending the synchronization signal and MIB, or the synchronization signal, MIB, and other broadcast information, the SIB is sent to the terminal device in a time division multiplexed manner on the data channel.
  • the synchronization signal and MIB, or the synchronization signal, MIB, and other broadcast information are sent on the fixed channel, so that the terminal device searches for the synchronization signal during blind detection, and then receives the MIB information and other broadcast information, and then receives the SIB and executes Random access and other processes.
  • the SIBs described in the embodiments of the present application include SIB1 to SIB7.
  • the synchronization signals include a primary synchronization signal (PSS) and a secondary synchronization signal (SSS).
  • PSS primary synchronization signal
  • SSS secondary synchronization signal
  • the MIB is transmitted through a physical downlink broadcast channel (PBCH).
  • PBCH physical downlink broadcast channel
  • Other broadcast information includes, but is not limited to, other SIBs that do not use the SIB transmission scheme described in the embodiments of the present application.
  • the frequency domain resources and time domain resources occupied by the fixed channel and the data channel described in the embodiments of the present application are unlicensed spectrum resources.
  • the fixed channel duration may include an uplink portion, which is not limited in the embodiment of the present application.
  • the first period includes m second periods, which can be understood as the second period having a length of m times the first period.
  • T1 the duration of the first cycle
  • T2 the duration of the second cycle
  • T1 m * T2.
  • the time unit of T1 and the time unit of T2 can be 1 millisecond (millisecond, ms), or 10ms, respectively. In the embodiments of the present application, 1 millisecond is taken as an example for description.
  • the number of SIB repetitions in each second period from the first second period to the m-1th second period in m second periods is The number of SIB repetitions in the m second period in the m second periods is among them, Rounds up.
  • the round-up symbol is omitted by default, that is, the calculation result of the default N / m is an integer.
  • N is an integer power of 2
  • m can be equal to 1, 2, 4, or 8.
  • N is an integer power of 2.
  • N can be equal to 1, 2, 4, 8, or 16.
  • the number of repetitions of the SIB in each of the m second periods may be N / m.
  • the method of sending the SIB in the second cycle is described by taking the calculation result of N / m as an integer as an example.
  • the N SIBs are uniformly distributed in m second periods, that is, the number of repetitions of the SIB in each second period of the m second periods is N / m.
  • the first period includes two second periods, and the SIB is sent once in each second period in the first period.
  • the first cycle includes two second cycles, and the SIB is transmitted eight times in each second cycle in the first cycle.
  • the number of SIB repetitions in each second cycle in the first N second cycles is 1, and The number of repetitions is 0.
  • the first cycle includes 2 second cycles
  • the SIB is sent once in the first second cycle in the first cycle
  • the second No SIB is sent for two cycles.
  • the first cycle includes 4 second cycles
  • the SIB is sent once in the first second cycle and the second second cycle in the first cycle, and in the first cycle
  • the SIB is not transmitted during the third second period and the fourth second period.
  • repeatedly sending the SIBs N times in the embodiment of the present application includes sending the SIBs for the first time. It can be understood that the SIB is repeatedly sent N times in the first cycle in the time domain, that is, the SIB is sent N times in the first cycle in the time domain, and the content of the SIB sent each time is the same.
  • the following describes in detail a sending manner in which the SIB is repeatedly sent N / m times in each second cycle.
  • N / m times of SIBs are sent at equal intervals in each second cycle. In combination with the above N times of SIBs, they are evenly distributed in m second cycles. Understandably, N times of SIBs are sent at the first Send at regular intervals throughout the week.
  • the SIB transmitted each time in each second cycle may be considered to occupy one time unit, and the N / m SIBs transmitted in each second cycle may occupy N / m time units. Furthermore, the N / m time units may be uniformly distributed in each second period, that is, the N / m time units are sent at equal intervals.
  • each transmitted SIB occupies consecutive downlink subframes. For example, each transmitted SIB can occupy 8 consecutive downlink subframes. Or, in each time unit, each transmitted SIB may occupy 4 consecutive downlink subframes.
  • time unit can be understood as a time unit for sending the SIB once.
  • the embodiment of the present application does not limit the name of the time unit for sending the SIB once.
  • a time unit may also be referred to as a time unit block, a time unit window, a transmission block, or a transmission window.
  • the duration of each time unit in the N / m time units can be determined according to the duration of the first cycle, the duration of the second cycle, and the number of repetitions of the SIB. Depending on the duration of the first cycle, the duration of the second cycle, and the number of repetitions of the SIB, the duration of the time unit may also be different.
  • the duration of the time unit of the SIB transmitted each time is T3.
  • the time unit of T3 can be 1ms or 10ms.
  • the first period includes two second periods.
  • the repetitive times of the SIB are 16, 8, 4, 2, and 1, respectively.
  • each second cycle contains 8 time units, and 8 time units Uniformly distributed in every second cycle.
  • each second cycle contains 4 time units, and 4 time units are in Uniformly distributed in every second cycle.
  • each second cycle contains 2 time units, and 2 time units Uniformly distributed in every second cycle.
  • each second cycle includes one time unit.
  • duration of the foregoing time unit is only a schematic description, and the specific duration of the time unit may not be limited in the embodiment of the present application.
  • duration of the time unit described in the embodiments of the present application may also be multiplexed with the definition in the NB-IoT system.
  • the duration of the time unit may be considered to be 160 ms regardless of the number of repetitions of the SIB.
  • the duration of the time unit may be determined according to the number of data channels occupied by the SIB when sending the SIB and the channel duration of each data channel.
  • the duration of the time unit is 80 ms. If the current SIB transmission occupies 2 data channels, the duration of the time unit is 40ms. It can be understood that the duration of the time unit described in the embodiment of the present application includes the sending duration of sending the SIB.
  • the start transmission time of the SIB in the time unit transmitted for the first time in the second cycle needs to be offset from the primary fixed channel duration.
  • the terminal equipment in the NB-IoT-U system is a low-cost terminal and the processing capability of the terminal equipment is limited, the terminal equipment needs time to process the MIB after receiving the MIB (or the synchronization signal, or the synchronization signal and other broadcast information). (Or synchronization signals, or synchronization signals and other broadcast information), SIBs cannot be received immediately. Therefore, in order to ensure the complete reception of each SIB in the second period, the delay of the terminal device receiving the SIB is reduced.
  • the start time of the first SIB transmission in the first time unit in the second cycle needs to be offset by a period of time relative to the end time of the primary fixed channel, that is, in the first time unit in the second cycle, the first time
  • the position of an SIB subframe relative to the end subframe of the MIB needs to have a time offset, so as to ensure that the terminal device can receive the SIB in time.
  • the start time of sending the SIB for the first time in the first time unit in the second cycle is a time shifted by T4 and T5 from the start time of the second cycle to which the first transmitted SIB belongs.
  • T4 represents the duration of the primary fixed channel
  • T5 represents the time offset from the end subframe position of the MIB transmission (or primary fixed channel).
  • the time unit of T4 and T5 is the same as the unit of time unit, which is 1ms or 10ms, T4 is an integer greater than or equal to 1, and T5 is an integer greater than or equal to 0.
  • FIG. 5 is another schematic structural diagram of sending an SIB according to an embodiment of the present application.
  • the duration of the second cycle is 1280 ms and the duration of the time unit is 160 ms.
  • One time unit includes 8 channels. The length of the eight channels is 20ms. Each channel includes 20 subframes, and the duration of one subframe is 1ms.
  • the first channel is used as the main fixed channel for transmitting synchronization signals and MIBs, that is, the duration of the main fixed channel is 20ms.
  • the remaining 7 channels are used as data channels for transmitting uplink data and downlink data, and the duration of each data channel is 20ms.
  • the first 2 subframes in a data channel are used to transmit downlink data, and the last 18 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 2 downlink (DL) subframes and 18 uplink (up link, UL) subframe.
  • the position of the first subframe in the current time unit to send the SIB is offset from the start time of the current time unit by the duration of the main fixed channel and the duration of one data channel, that is, 40 ms.
  • a data channel includes 2 downlink subframes, then sending a SIB in the current time unit occupies a total of 4 downlink channels in the data channel.
  • the duration of sending the SIB in the current time unit is 80ms.
  • Other data channels include downlink subframes for transmitting downlink data, that is, the second data channel, the seventh data channel, and the eighth data channel.
  • the service delay caused by the SIB transmission is at least 80ms.
  • the number of data channels shared by the sending SIB in the current time unit is also different.
  • the first 8 subframes in a data channel are used to transmit downlink data
  • the last 12 subframes are used to transmit uplink data
  • the uplink and downlink ratio of the data channel is 8 downlink subframes and 12 uplinks.
  • Subframe In the case that the SIB needs to occupy 8 consecutive downlink subframes in the current time unit, and a data channel includes eight downlink subframes, the SIB sent in the current time unit occupies a total of one downlink downlink data frame.
  • the duration of sending the SIB in the unit is 20ms.
  • Other data channels include downlink subframes for transmitting downlink data, that is, the second data channel, and the fourth to eighth data channels.
  • the service delay caused by the SIB transmission is at least 20ms.
  • the number of uplink subframes in the uplink-downlink ratio of the data channel is greater than the number of downlink subframes.
  • the number of downlink subframes in a data channel may be an integer such as 1, 2, 3, 4, 5, 6, 7, 8, or 9.
  • the number of consecutive downlink subframes required to send the SIB in the current time unit is a multiple of the number of downlink subframes in a data channel
  • the number of data channels required to send the SIB in the current time unit is the current
  • the quotient of the number of consecutive downlink subframes required to send an SIB in a time unit divided by the number of downlink subframes in a data channel, that is, C A / B, where A indicates that the SIB needs to occupy consecutive
  • the number of downlink subframes B represents the number of downlink subframes in a data channel
  • the downlink subframes in the first data channel are all used to transmit the SIB
  • the first three downlink subframes in the second data channel are used to transmit the SIB
  • the last two downlink Sub-frames can be used to transmit downlink data.
  • the downlink subframes in the first data channel are all used to transmit the SIB
  • the first two downlink subframes in the second data channel are used to transmit the SIB
  • the last four downlink Sub-frames can be used to transmit downlink data.
  • the downlink subframes in the first data channel are all used to transmit the SIB
  • the first downlink subframe in the second data channel is used to transmit the SIB
  • the last six downlink subframes Frames can be used to transmit downlink data.
  • the start time of sending the SIB in each time unit can be uniformly specified as the time offset from the start time of the time unit by T4 and T5, that is, the SIB is in each time unit
  • the first downlink subframe transmitted by is offset by T4 and T5 from the first downlink subframe of the current SIB time unit.
  • the above sum of T4 and T5 can be considered as a preset offset value.
  • the preset offset value may be pre-configured to be related to the frame structure.
  • the preset offset value may also be pre-configured by the base station device, for example, the preset offset value is 40 milliseconds.
  • the preset offset value may also be indicated by broadcast information, such as the MIB instruction, and the preset offset value is 40 milliseconds.
  • the preset offset value can also be indicated by a synchronization sequence.
  • the synchronization sequence includes PSS and SSS. Understandably, it is assumed that 10 milliseconds is a radio frame, and the value of the radio frame number n f ranges from 0 to 1023.
  • a radio frame contains 10 sub-frames, each sub-frame contains 2 time slots, and the time slot number n s ranges from 0 to 19 in a radio frame.
  • the start position of each SIB transmission is relative to the start of the time unit to which the SIB transmission belongs.
  • the preset offset value for the position The duration of the first cycle is equal to 2560ms, then the starting position of the SIB transmission in each time unit for sending the SIB satisfies: among them
  • the so-called rounding down refers to rounding up to the nearest integer when the result of the calculation is not an integer.
  • the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel.
  • the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value.
  • the start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value.
  • the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
  • the duration of the first cycle is 2560ms and the number of SIB repetitions N is equal to 16.
  • the synchronization signal and MIB transmitted by the main fixed channel occupy 20ms, and 8 transmissions are required in the second cycle.
  • SIB each sending SIB takes 8ms, and the downlink signal occupied by the synchronization signal and MIB transmitted by the main fixed channel and the data channel transmitted by the SIB is approximately
  • the downlink duty cycle requirement is 10%, the resources used to transmit downlink data only account for 3.4%, so the SIB overhead can be reduced by increasing the first cycle.
  • the duration of the first cycle is 5120ms
  • the downlink overhead occupied by the synchronization signal and MIB transmitted by the main fixed channel and the SIB transmitted by the data channel is approximately
  • the duration of the first cycle is 10240ms
  • the downlink overhead occupied by the synchronization signal and MIB transmitted by the main fixed channel and the SIB transmitted by the data channel is approximately
  • the duration of the first cycle can be pre-configured according to the actual situation. For example, in areas where there is no duty cycle requirement, the duration of the first cycle is preconfigured to 2560ms. In areas with duty cycle requirements, the duration of the first cycle is pre-configured to 5120ms or 10240ms.
  • the duration of the first cycle can also be configured through MIB to support greater flexibility.
  • each SIB transmission is relative to the start position of the time unit to which the SIB transmission belongs.
  • the start position of the SIB transmission in each time unit in which the SIB is transmitted satisfies: Or alternatively, if the duration of the first cycle is equal to 10240ms, and N> 1, the start position of the SIB transmission within each time unit for sending the SIB satisfies among them
  • the so-called rounding down refers to rounding up to the nearest integer when the result of the calculation is not an integer.
  • the overhead of the SIB can also be reduced by reducing the maximum number of SIB retransmissions.
  • the duration of the first cycle is 2560ms, and the maximum number of repetitions N of the SIB in the first cycle is equal to 8.
  • the downlink signal occupied by the synchronization signal and MIB transmitted by the main fixed channel and the SIB transmitted by the data channel is approximately 4.1%.
  • the number of repetitions of the SIB in the first cycle can be indicated by the MIB. In areas where there is no duty cycle requirement, the number of SIB repetitions is 4, 8, and 16. In areas with duty cycle requirements, the number of SIB repetitions is 2, 4, and 8.
  • the SIBs repeatedly sent in the first cycle are evenly distributed between the second cycles.
  • the terminal device if the downlink data reception (or the downlink data transmission of the base station) of the terminal device coincides with the SIB transmission period, the terminal device (or the base station) needs to delay the SIB transmission duration before continuing the downlink reception (or downlink) Sending), because the SIBs are concentrated to be sent in a fixed channel period, it is possible that most of the downlink resources in the fixed channel period are occupied by the SIB, and the downlink resources occupied by the SIB cannot perform data transmission, thereby increasing service delay. Taking SIB repeated transmission 16 times, each transmission takes 8 downlink subframes as an example, at least 128 consecutive downlink subframes need to be occupied by the SIB.
  • NB-IoT-U is a TDD system
  • the SIB is transmitted in units of time units in the second cycle. The SIB only occupies part of the downlink subframes in one time unit, so the service delay of the terminal device can also be reduced.
  • a secondary fixed channel can be periodically configured on the data channel.
  • the SIBs are all sent in a second cycle.
  • the SIB needs to occupy 128 (16 * 8) ms consecutively, that is, 128 downlink subframes.
  • the duration of a data channel is 20ms and it takes 16 data channels to send the SIB, and the SIB needs to last 320 (16 * 20) ms.
  • FIG. 7 is a schematic structural diagram of a SIB including a secondary fixed channel provided in the prior art.
  • the downlink subframe that can be used to send the SIB does not include at least the downlink subframe occupied by the primary fixed channel and the downlink subframe occupied by the secondary fixed channel.
  • the downlink subframes occupied by the SIB in the embodiments of the present application refer to valid downlink subframes, that is, downlink subframes that can be used to transmit SIBs. In all the downlink subframes, except for the main fixed channel and the downlink subframe used for transmitting the SIB, the remaining downlink subframes may be used for transmitting downlink data.
  • the terminal device since the number of secondary fixed channels in the secondary fixed channel period or the primary fixed channel period may be configured in the SIB, the terminal device does not know the secondary fixed channel period when receiving the SIB.
  • An embodiment of the present application provides an implementable method. When a base station sends an SIB, resource reservation is performed according to a minimum period that a fixed channel can support. The SIB is sent only on resources that are not reserved for the fixed channel. The terminal device is also The SIB reception is performed according to the minimum period reservation mode of the fixed channel.
  • the terminal device assumes that The number of auxiliary fixed channels in a second period is 7, that is, the fixed channel period is 160 ms. As long as it is a reserved fixed channel resource, the downlink subframe corresponding to the fixed channel resource is invalid for the SIB.
  • the duration of the time unit is 160 ms.
  • the adjacent fixed channel period is 160 ms, including the period of the main fixed channel and the secondary fixed channel, and the period of the secondary fixed channel and the secondary fixed channel. It can be seen that, like the primary fixed channel, the secondary fixed channel occupies the first channel of each SIB time unit, that is, the first 20ms of each SIB time unit. Since the SIB can be sent after being offset 40ms from the start of the time unit where the SIB is located, the SIB and the secondary fixed channel will not conflict.
  • the SIB can be sent from the start of the time unit where the SIB is located and offset by 40ms, and then the SIB is sent. Therefore, the SIB and the auxiliary fixed channel are not Will conflict.
  • the adjacent fixed channel period is 320 ms.
  • the secondary fixed channel and the SIB time unit have an intersection time unit.
  • the secondary fixed channel is the same as the primary fixed channel.
  • Each fixed channel occupies the first channel of each SIB time unit, that is, the first 20ms of each SIB time unit.
  • the SIB may be sent and then sent again after an offset of 40ms from the start of the time unit where the SIB is located, so that the SIB and the secondary fixed channel do not conflict.
  • the start time of sending the SIB in each time unit is a time shifted from the start time of the time unit by a preset offset value, thereby effectively avoiding the position of the auxiliary fixed channel and further reducing
  • the service delay caused by the SIB transmission is avoided, and the collision between the SIB and the secondary fixed channel transmission time is avoided.
  • the N / m SIBs transmitted in each second cycle may occupy N / m times unit.
  • the N / m time units may be continuously distributed (centrally distributed) in each second cycle, that is, the N / m time units are continuously transmitted.
  • each transmitted SIB occupies consecutive downlink subframes.
  • each transmitted SIB can occupy 8 consecutive downlink subframes.
  • each transmitted SIB may occupy 4 consecutive downlink subframes.
  • the duration of the time unit described in the embodiments of the present application may also be multiplexed with the definition in the NB-IoT system.
  • the duration of the time unit may be considered to be 160 ms regardless of the number of repetitions of the SIB.
  • the duration of the time unit may be determined according to the number of data channels occupied by the SIB when sending the SIB and the channel duration of each data channel. For example, if the channel duration of one channel is 20 milliseconds, and the current SIB transmission occupies 4 data channels, the duration of the time unit is 80 milliseconds. If the current SIB transmission occupies 2 data channels, the duration of the time unit is 40 milliseconds. It can be understood that the duration of the time unit described in the embodiment of the present application includes the sending duration of sending the SIB.
  • T1 2560ms
  • T2 1280ms
  • the number of repetitions of the SIB is 16, 8, 4, 2, and 1, respectively.
  • N 16 SIBs are sent in each second cycle.
  • the 8 SIBs sent in each second cycle occupy 8 time units.
  • the SIBs sent each time occupy a time unit. Continuously transmitted (continuously distributed) every second period.
  • N 4
  • two SIBs are sent in each second cycle.
  • the two SIBs sent in each second cycle occupy two time units. Each time SIB is sent, one time unit is used. Continuously transmitted (continuously distributed) every second period.
  • the start time of sending the SIB for the first time in each second cycle is a time offset from the start time of the second cycle to which the first transmitted SIB belongs by a preset offset value.
  • the time unit duration is 160ms
  • the start time of sending the SIB in each time unit is offset from the start time of the time unit.
  • the moment of the preset offset value For other detailed descriptions of the preset offset value, reference may be made to the description in the first implementable manner, which is not repeated in the embodiment of the present application. For other detailed descriptions of downlink overhead and auxiliary fixed channels, etc., reference may also be made to the description in the first implementable manner, which is not repeatedly described in this embodiment of the present application.
  • the SIBs repeatedly sent in the first cycle are evenly distributed between the second cycles.
  • the terminal device receiving the SIB again can ensure that the terminal device completely receives the first transmission of the SIB in the second period.
  • downlink data transmission may be interrupted by SIB transmission multiple times, so service delay It is larger than the service delay in the first implementable manner, but smaller than the prior art.
  • N / m SIBs are continuously transmitted in each second period. At this time, there is no time unit described in the first implementation manner and the second implementation manner described above.
  • Each transmitted SIB can occupy consecutive downlink subframes. If each transmitted SIB can occupy 8 consecutive downlink subframes, the N / m transmitted SIBs occupy consecutive N * 8 / m downlink subframes. If the SIB transmitted each time can occupy 4 consecutive downlink subframes, the SIB transmitted N / m times can occupy consecutive N * 4 / m downlink subframes.
  • T1 2560ms
  • T2 1280ms
  • N 16
  • 8 SIBs are sent in each second period
  • 8 SIBs are sent continuously (continuous distribution) in each second period
  • the duration of the SIB is 160ms, that is, the increased service delay is 160ms.
  • the SIB is transmitted twice in each second cycle, and the SIB is transmitted continuously (continuously) twice in each second cycle.
  • * 8/2 16 downlink subframes. Taking a data channel with a duration of 20ms and an uplink and downlink ratio of the data channel with 8 downlink subframes and 12 uplink subframes as an example, the duration of the SIB is 40ms, that is, the increased service delay is 40ms.
  • the SIB is sent once in each second cycle, and the SIB is sent continuously (continuously distributed) once in each second cycle.
  • 8/2 8 downlink subframes.
  • the duration of the SIB is 20ms, that is, the increased service delay is 20ms.
  • N 1
  • the SIB is sent once in the first second period in the first period, and the SIB is not sent in the second second period in the first period.
  • the start time of transmitting the SIB for the first time in each second cycle is a time offset from the start time of the second cycle to which the first transmitted SIB belongs by a preset offset value.
  • a preset offset value reference may be made to the description in the first implementable manner, which is not repeated in the embodiment of the present application.
  • downlink overhead and auxiliary fixed channels, etc. reference may also be made to the description in the first implementable manner, which is not repeatedly described in this embodiment of the present application.
  • FIG. 14 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • the duration of the second cycle is 1280 ms
  • the second cycle includes 64 channels
  • the duration of the 64 channels is 20 ms.
  • Each channel includes 20 subframes, and the duration of one subframe is 1ms.
  • the first channel is used as the main fixed channel for transmitting synchronization signals and MIBs, that is, the duration of the main fixed channel is 20ms.
  • the remaining channels are used as data channels for transmitting uplink data and downlink data.
  • the first 2 subframes in a data channel are used to transmit downlink data, and the last 18 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 2 downlink subframes and 18 uplink subframes.
  • the position of the first subframe in the current second period to send the SIB is offset from the start time of the current second period by the length of the main fixed channel and the length of one data channel, that is, 40 ms.
  • the SIB is repeatedly transmitted 8 times, and each transmitted SIB occupies 8 consecutive downlink subframes.
  • the SIB needs to occupy 64 consecutive downlink subframes.
  • a data channel includes two downlink subframes, so sending a SIB in the current second cycle occupies a total of 32 downlink channels in the data channel, and the duration of sending the SIB in the current second cycle is 640ms. Downlink subframes included in other data channels are used to transmit downlink data. At this time, the service delay caused by the SIB transmission is at least 640ms.
  • the number of data channels shared by the sending SIB in the current second cycle is also different.
  • the first 8 subframes in a data channel are used to transmit downlink data
  • the last 12 subframes are used to transmit uplink data
  • the uplink and downlink ratio of the data channel is 8 downlink subframes and 12 uplinks. Subframe.
  • the SIB needs to occupy 64 consecutive downlink subframes in the current second cycle, and one data channel includes 8 downlink subframes, then sending the SIB in the current second cycle consumes a total of 8 downlink downlink subframes, The duration of sending the SIB in the current second cycle is 160ms. Downlink subframes included in other data channels are used to transmit downlink data. At this time, the service delay caused by the SIB transmission is at least 160ms.
  • the SIBs repeatedly sent in the first cycle are evenly distributed between the second cycles and concentratedly distributed in the second cycle.
  • the terminal device receiving the SIB again can ensure that the terminal device completely receives the first transmission of the SIB in the second period.
  • downlink data transmission may be interrupted by SIB transmission multiple times, so service delay It is larger than the service delay in the first implementable manner, but smaller than the prior art.
  • the N / m SIBs sent in each second cycle may occupy N / m times unit.
  • the duration of the time unit is T2 * m / N.
  • the duration of the time unit may be T1 / m.
  • the SIB can be evenly distributed, that is, the p downlink subframes occupied by each SIB transmission are evenly distributed in each of the time units to which it belongs.
  • P is A positive integer greater than 0.
  • each transmitted SIB may occupy 8 downlink subframes, and the 8 downlink subframes occupied by SIB transmission within the time unit occupied by the transmission of the SIB are evenly distributed within each time unit to which they belong.
  • the SIB transmitted each time can occupy 4 downlink subframes, and the 4 downlink subframes occupied by the SIB transmission in the time unit occupied by the transmission of the SIB are even in each time unit to which they belong. distributed.
  • the start time of the first SIB transmission in each time unit in the second cycle is relative to the current time.
  • the start time of the time unit needs to be shifted from the start time of the current time unit for a period of time according to a preset offset value before sending the SIB. Therefore, the subframes used to send the SIB in the time unit can be distributed evenly within the remaining time after the start time of the current time unit is offset from the preset offset value.
  • the first period includes two second periods.
  • each second cycle contains 8 time units
  • 8 time units are evenly distributed in each second cycle.
  • the duration of the primary fixed channel and the duration of the data channel are both 20 ms
  • each ((( T2 * m / N) -T6) / p duration includes at least one downlink subframe for sending SIB.
  • T6 represents a preset offset value.
  • the number of channels that can be used to transmit the SIB in one time unit is equal to the number of downlink subframes required to transmit the SIB once.
  • each second cycle contains 4 time units
  • 4 time units are evenly distributed in each second cycle.
  • the number of channels that can be used to transmit the SIB in one time unit is equal to the number of downlink subframes required to transmit the SIB once. .
  • each second cycle includes 2 time units.
  • 2 time units are evenly distributed in each second cycle.
  • the 8 downlink subframes occupied by the SIB transmission can be evenly distributed within the first 400ms of the remaining 600ms within the time unit after the offset.
  • two downlink subframes are sent every 100 ms within the first 400 ms of the remaining 600 ms in the time unit after the offset, and the two downlink subframes may be downlink subframes in the same channel.
  • 100ms includes 5 channels.
  • each second cycle includes one time unit.
  • the 4 downlink subframes occupied by SIB transmission can be evenly distributed within the first 1120ms (28 channels) of the remaining 1200ms in the time unit after the offset.
  • one downlink subframe is sent every 280ms within the first 1120ms of the remaining 1200ms in the time unit after the offset.
  • 280ms includes 7 channels. The first downlink subframe in the first channel of each of the 7 channels is used to send the SIB.
  • N 1
  • FIG. 20 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application.
  • the duration of the second cycle is 1280 ms and the duration of the time unit is 160 ms.
  • One time unit includes 8 channels. The length of the eight channels is 20ms. Each channel includes 20 subframes, and the duration of one subframe is 1ms.
  • the first channel is used as the main fixed channel for transmitting synchronization signals and MIBs, that is, the duration of the main fixed channel is 20ms.
  • the remaining 7 channels are used as data channels for transmitting uplink data and downlink data, and the duration of each data channel is 20ms.
  • the first 2 subframes in a data channel are used to transmit downlink data, and the last 18 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 2 downlink subframes and 18 uplink subframes.
  • the position of the first subframe in the current time unit to send the SIB is offset from the start time of the current time unit by the duration of the main fixed channel and the duration of one data channel, that is, 40 ms.
  • one data channel includes 2 downlink subframes
  • the first of each of the last 6 data channels in the current time unit The downlink sub-frame is used to send the SIB, and then the second downlink sub-frame in any two data channels of the last 6 data channels is selected to send the remaining 2 SIBs, and the offset is preset in each time unit
  • Each 20ms after the offset value includes at least one downlink subframe for sending the SIB.
  • the service delay caused by the SIB transmission is at least 40ms.
  • the SIB transmission methods described in the above embodiments may be used in combination.
  • the N / m SIBs transmitted in each second cycle may occupy N / m time units.
  • N / m time units can be evenly distributed or continuous (centralized), that is, N / m time units are sent continuously.
  • the SIB can be continuous. Distributed or evenly distributed.
  • the terminal device receives N SIBs in the first cycle in the time domain.
  • the base station needs to send a synchronization signal and a MIB to the terminal device before sending the SIB repeatedly N times in the first period in the time domain.
  • the embodiment of the present application may further include the following steps.
  • the base station sends the synchronization signal and the main information block to the terminal device by using a fixed channel.
  • the terminal device receives a synchronization signal and a main information block on a fixed channel.
  • the terminal device After the terminal device receives the synchronization signal and the main information block, and synchronizes with the base station after performing the SIB and performs random access, it can communicate with the base station.
  • FIG. 22, FIG. 23 and FIG. 24 are schematic diagrams of three frame structures of the NB-IoT-U provided by the embodiments of the present application.
  • the primary fixed channel shown in FIG. 22, FIG. 23, and FIG. 24 may also be referred to as a primary fixed channel segment (primary anchor channel segment) or a primary fixed segment (or anchor segment) or fixed segment (anchor segment).
  • the secondary fixed channel can also be referred to as a secondary fixed channel segment or a secondary fixed segment.
  • a data channel can also be referred to as a data channel segment (data channel segment) or a data segment (data segment).
  • any of the so-called channels of the channels, data channels, primary fixed channels, secondary fixed channels, and fixed channels described in the embodiments of the present application can be understood as different occupations for each frequency hopping. channel.
  • a fixed segment can be called a channel
  • each data frame in a data segment can be called a channel.
  • the number of channels can also be understood as the number of data frames.
  • the one data frame means that each time unit in the data segment with independent uplink and downlink forms a data frame.
  • the data segment can also refer to all data frames in the fixed channel period except the main fixed segment and the secondary fixed segment. It can also refer to a data frame.
  • the data segment and Data frames are interchangeable.
  • the channel duration of each channel can also be pre-configured or configured through MIB, which can be 20ms or 40ms.
  • each network element such as a base station and a terminal device, includes a hardware structure and / or a software module corresponding to each function.
  • this application can be implemented in hardware or a combination of hardware and computer software. Whether a certain function is performed by hardware or computer software-driven hardware depends on the specific application and design constraints of the technical solution. A professional technician can use different methods to implement the described functions for each specific application, but such implementation should not be considered to be beyond the scope of this application.
  • each functional module may be divided corresponding to each function, or two or more functions may be integrated into one processing module.
  • the above integrated modules can be implemented in the form of hardware or software functional modules. It should be noted that the division of the modules in the embodiments of the present application is schematic, and is only a logical function division. In actual implementation, there may be another division manner.
  • FIG. 25 shows a schematic diagram of a possible composition of the base station involved in the foregoing and embodiments.
  • the base station can execute any method embodiment of each method embodiment of the present application. Steps performed by the base station.
  • the base station may include: a sending unit 2501.
  • the sending unit 2501 is configured to support the base station to perform S301 in the SIB transmission method shown in FIG. 3 and S301 and S303 in the SIB transmission method shown in FIG. 21.
  • the base station may further include a processing unit 2502 and a receiving unit 2503.
  • the base station provided in the embodiment of the present application is configured to execute the above-mentioned SIB transmission method, and thus can achieve the same effect as the above-mentioned SIB transmission method.
  • FIG. 26 is a schematic structural diagram of a device according to an embodiment of the present application. As shown in FIG. 26, the device may include at least one processor 2601, a memory 2602, a transceiver 2603, and a bus 2604.
  • the processor 2601 is a control center of the device, and may be a processor or a collective name of multiple processing elements.
  • the processor 2601 is a central processing unit (CPU), may also be a specific integrated circuit (Application Specific Integrated Circuit, ASIC), or one or more integrated circuits configured to implement the embodiments of the present application.
  • CPU central processing unit
  • ASIC Application Specific Integrated Circuit
  • microprocessors Digital Signal Processor, DSP
  • FPGA Field Programmable Gate Array
  • the processor 2601 may execute various functions of the device by running or executing software programs stored in the memory 2602 and calling data stored in the memory 2602.
  • the processor 2601 may include one or more CPUs, such as CPU0 and CPU1 shown in FIG. 26.
  • the device may include multiple processors, such as the processor 2601 and the processor 2605 shown in FIG. 26.
  • processors can be a single-core processor (single-CPU) or a multi-core processor (multi-CPU).
  • a processor herein may refer to one or more devices, circuits, and / or processing cores for processing data (such as computer program instructions).
  • the memory 2602 may be a read-only memory (ROM) or other types of static storage devices that can store static information and instructions, a random access memory (Random Access Memory, RAM), or other types that can store information and instructions
  • the dynamic storage device can also be Electrically Erasable Programmable Read-Only Memory (EEPROM), Compact Disc (Read-Only Memory, CD-ROM) or other optical disk storage, optical disk storage (Including compact discs, laser discs, optical discs, digital versatile discs, Blu-ray discs, etc.), disk storage media or other magnetic storage devices, or can be used to carry or store desired program code in the form of instructions or data structures and can be used by a computer Any other media accessed, but not limited to this.
  • the memory 2602 may exist independently, and is connected to the processor 2601 through a bus 2604.
  • the memory 2602 may also be integrated with the processor 2601.
  • the memory 2602 is configured to store a software program that executes the solution of the present application, and is controlled and executed by the processor 2601.
  • the transceiver 2603 is configured to communicate with other devices or a communication network. For example, it is used to communicate with communication networks such as Ethernet, radio access network (RAN), wireless local area networks (WLAN) and the like. If the device is a base station, the transceiver 2603 may include all or part of a baseband processor, and may optionally include an RF processor. The RF processor is used to transmit and receive RF signals, and the baseband processor is used to implement processing of the baseband signal converted from the RF signal or the baseband signal to be converted into the RF signal.
  • RAN radio access network
  • WLAN wireless local area networks
  • the transceiver 2603 is configured to send N times of SIBs and receive N times of SIBs.
  • the bus 2604 may be an Industry Standard Architecture (ISA) bus, an External Component Interconnect (PCI) bus, or an Extended Industry Standard Architecture (EISA) bus.
  • ISA Industry Standard Architecture
  • PCI External Component Interconnect
  • EISA Extended Industry Standard Architecture
  • the bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is used in FIG. 26, but it does not mean that there is only one bus or one type of bus.
  • the device structure shown in FIG. 26 does not constitute a limitation on the device, and may include more or fewer components than shown, or some components may be combined, or different components may be arranged.
  • FIG. 27 shows another possible composition diagram of the base station involved in the foregoing embodiment.
  • the base station includes a processing module 2701 and a communication module 2702.
  • the processing module 2701 is used to control and manage the actions of the base station and / or other processes used in the technology described herein.
  • the communication module 2702 is configured to support communication between the base station and other network entities, for example, communication with the functional modules or network entities shown in FIG. 28 and FIG. 29. Specifically, for example, the communication module 2702 is configured to support the base station to execute S301 in FIG. 3 and S301 and S303 in FIG. 21.
  • the base station may further include a storage module 2703 for storing program code and data of the base station.
  • the processing module 2701 may be a processor or a controller. It may implement or execute various exemplary logical blocks, modules, and circuits described in connection with the disclosure of this application.
  • a processor may also be a combination that implements computing functions, such as a combination of one or more microprocessors, a combination of a DSP and a microprocessor, and so on.
  • the communication module 2702 may be a transceiver, a transceiver circuit, or a communication interface.
  • the storage module 2703 may be a memory.
  • the base station involved in this embodiment of the present application may be the device shown in FIG. 26.
  • FIG. 28 shows a possible composition diagram of the terminal device involved in the foregoing and embodiments, and the terminal device can execute any one of the method embodiments of the present application Steps performed by the terminal device in the embodiment.
  • the terminal device may include: a receiving unit 2801.
  • the receiving unit 2801 is configured to support a terminal device to execute S302 in the SIB transmission method shown in FIG. 3 and S302 and S304 in the SIB transmission method shown in FIG. 21.
  • the terminal device may further include a processing unit 2802 and a sending unit 2803.
  • the terminal device configured to execute the above-mentioned SIB transmission method, and thus can achieve the same effect as the above-mentioned SIB transmission method.
  • FIG. 29 shows another possible composition diagram of the terminal device involved in the foregoing embodiment.
  • the terminal device includes a processing module 2901 and a communication module 2902.
  • the processing module 2901 is used to control and manage the actions of the terminal device and / or other processes used in the technology described herein.
  • the communication module 2902 is configured to support communication between the terminal device and other network entities, for example, communication with the functional modules or network entities shown in FIG. 25 and FIG. 27.
  • the communication module 2902 is configured to support a terminal device to execute S302 in FIG. 3, and S302 and S304 in FIG. 21.
  • the terminal device may further include a storage module 2903 for storing program code and data of the terminal device.
  • the processing module 2901 may be a processor or a controller. It may implement or execute various exemplary logical blocks, modules, and circuits described in connection with the disclosure of this application.
  • a processor may also be a combination that implements computing functions, such as a combination of one or more microprocessors, a combination of a DSP and a microprocessor, and so on.
  • the communication module 2902 may be a transceiver, a transceiver circuit, or a communication interface.
  • the storage module 2903 may be a memory.
  • the terminal device involved in this embodiment of the present application may be the device shown in FIG. 26.
  • the disclosed apparatus and method may be implemented in other ways.
  • the device embodiments described above are only schematic.
  • the division of the modules or units is only a logical function division.
  • multiple units or components may be divided.
  • the combination can either be integrated into another device, or some features can be ignored or not implemented.
  • the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, which may be electrical, mechanical or other forms.
  • the unit described as a separate component may or may not be physically separated, and the component displayed as a unit may be a physical unit or multiple physical units, that is, may be located in one place, or may be distributed to multiple different places. . Some or all of the units may be selected according to actual needs to achieve the objective of the solution of this embodiment.
  • each functional unit in each embodiment of the present application may be integrated into one processing unit, or each of the units may exist separately physically, or two or more units may be integrated into one unit.
  • the above integrated unit may be implemented in the form of hardware or in the form of software functional unit.
  • the integrated unit When the integrated unit is implemented in the form of a software functional unit and sold or used as an independent product, it may be stored in a readable storage medium.
  • the technical solutions of the embodiments of the present application essentially or partly contribute to the existing technology or all or part of the technical solutions may be embodied in the form of a software product, which is stored in a storage medium
  • the instructions include a number of instructions for causing a device (which can be a single-chip microcomputer, a chip, or the like) or a processor to execute all or part of the steps of the method described in each embodiment of the present application.
  • the foregoing storage medium includes various media that can store program codes, such as a U disk, a mobile hard disk, a ROM, a RAM, a magnetic disk, or an optical disk.

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Abstract

The embodiments of the present application relate to the field of communications, and disclosed thereby are an SIB transmission method and device, which may effectively reduce the delay of a terminal device accessing a network. The specific solution comprises: an SIB is repeatedly transmitted N times in a first period on a time domain, wherein the first period comprises m second periods; when N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the (m-1)th second period among the m second periods is formula (I), and the number of repetitions of the SIB in the mth second period among the m second periods is formula (II); N is a positive integer greater than 0, m is a positive integer greater than 0, and formula (III) represents rounding up to an integer. The embodiments of the present application are used in a process of transmitting an SIB. The method provided in the present embodiment may be applied to communication systems, such as V2X, LTE-V, V2V, vehicle networking, MTC, IoT, LTE-M, M2M, Internet of Things, and the like.

Description

一种系统信息块SIB传输方法及设备Method and equipment for transmitting system information block SIB 技术领域Technical field
本申请涉及通信领域,尤其涉及一种系统信息块SIB传输方法及设备。The present application relates to the field of communications, and in particular, to a method and device for transmitting a system information block SIB.
背景技术Background technique
窄带物联网(narrow band internet of things,NB-IoT)技术是物联网领域一个新兴的技术,支持低功耗设备在广域网的蜂窝数据连接,具有覆盖广、连接多、速率快、成本低、功耗低和架构优等特点。窄带物联网也可以称为低功耗广域网(low-power wide-area network,LPWAN)。为了充分利用频谱资源,MulteFire联盟(multeFire alliance,MFA)提出了基于非授权频谱的窄带物联网(unlicensed spectrum narrow band internet of things,NB-IoT-U)技术。NB-IoT-U具有NB-IoT的技术特征,但是为了适配非授权频谱法规(例如,联邦通讯委员会(federal communications commission,FCC)的频谱法规和欧洲电信标准协会(european telecommunications standards institute,ETSI)的频谱法规),在NB-IoT帧结构的基础上,做了一些适配非授权频谱法规的修改。例如,根据目前的MFA的规定,在FCC法规下,NB-IoT-U的一种帧结构是上行和下行均符合跳频法规,另一种可能的帧结构是上行符合跳频法规,下行符合数字调制法规,第三种可能的帧结构是上行符合跳频法规,下行为混合模式,即主固定(primary anchor)信道部分(或主固定段(primary anchor segment))符合数字调制法规,数据信道部分(或数据段(data segment))符合跳频法规。在ETSI法规下,NB-IoT-U的帧结构为符合占空比要求的帧结构。Narrowband Internet of Things (NB-IoT) technology is an emerging technology in the field of Internet of Things. It supports the cellular data connection of low-power devices in the WAN. It has wide coverage, multiple connections, fast speed, low cost, and high performance. Low power consumption and excellent architecture. The narrowband Internet of Things can also be called low-power wide-area network (LPWAN). In order to make full use of the spectrum resources, the MulteFire Alliance (MulteFire alliance) (MFA) has proposed a narrowband Internet of Things (NB-IoT-U) technology based on unlicensed spectrum. NB-IoT-U has the technical characteristics of NB-IoT, but in order to adapt to unlicensed spectrum regulations (for example, spectrum regulations of the Federal Communications Commission (FCC) and European Telecommunications Standards Institute (ETSI)) Spectrum regulations), based on the NB-IoT frame structure, made some modifications to adapt to unlicensed spectrum regulations. For example, according to the current MFA regulations, under the FCC regulations, one frame structure of NB-IoT-U is that both uplink and downlink comply with frequency hopping regulations, and another possible frame structure is that uplink meets frequency hopping regulations and downlink meet Digital modulation regulations. The third possible frame structure is that the uplink conforms to the frequency hopping regulations, and the downward behavior is a mixed mode, that is, the primary fixed channel part (or primary fixed segment) complies with the digital modulation regulations. The data channel Partially (or data segments) comply with frequency hopping regulations. Under ETSI regulations, the frame structure of NB-IoT-U is a frame structure that meets the requirements of the duty cycle.
对于上述任何一种帧结构而言,系统信息可以根据统一的格式进行发送。图1为现有技术提供的一种NB-IoT-U系统中发送系统信息块(system information block,SIB)的结构示意图。如图1所示,无论SIB重复次数是多少,都在固定信道周期内的前面多个连续有效下行子帧上发送规定重复次数的SIB。如果SIB周期内包括两个固定信道周期,SIB集中在一个固定信道周期内发送,另外一个固定信道周期内没有SIB发送。在这种情况下,如果终端设备在没有SIB发送的固定信道周期内完成主信息块(master information block,MIB)接收,则需要再等待一个固定信道周期接收SIB。因此,增加了终端设备进行小区初始接入的时延。For any of the above frame structures, system information can be sent according to a unified format. FIG. 1 is a schematic structural diagram of sending a system information block (system information block) in an NB-IoT-U system provided in the prior art. As shown in FIG. 1, no matter how many times the SIB is repeated, the SIB is sent at a predetermined number of consecutive valid downlink subframes in a fixed channel period. If the SIB period includes two fixed channel periods, the SIB is concentrated to be transmitted in one fixed channel period, and no SIB is transmitted in the other fixed channel period. In this case, if the terminal device finishes receiving the master information block (master information block, MIB) within a fixed channel period without SIB transmission, it needs to wait for another fixed channel period to receive the SIB. Therefore, the delay of the initial access of the cell by the terminal device is increased.
发明内容Summary of the Invention
本申请实施例提供一种SIB传输方法及设备,能够有效地减小终端设备接入网络的时延。The embodiments of the present application provide a SIB transmission method and device, which can effectively reduce the delay of a terminal device accessing a network.
为达到上述目的,本申请实施例采用如下技术方案:To achieve the above purpose, the embodiments of the present application adopt the following technical solutions:
本申请实施例的第一方面,提供一种SIB传输方法,包括:在时域上的第一周期中,重复发送N次SIB,第一周期包括m个第二周期,可以理解的,第一周期时长为m倍的第二周期时长,N为大于0的正整数,m为大于0的正整数。当N大于或等于m时,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的 重复次数为
Figure PCTCN2018089101-appb-000001
m个第二周期中第m个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000002
Figure PCTCN2018089101-appb-000003
表示向上取整。发送SIB的发送实体可以是基站,也可以是基站的芯片。接收SIB的接收实体可以是终端设备,也可以是终端设备的芯片。本申请实施例提供的SIB传输方法,在时域上的第一周期中重复发送的N次SIB分散分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。
According to a first aspect of the embodiments of the present application, an SIB transmission method is provided, including: repeatedly sending N SIBs in a first period in the time domain, and the first period includes m second periods. It is understandable that the first The second cycle duration is m times the cycle duration, N is a positive integer greater than 0, and m is a positive integer greater than 0. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is
Figure PCTCN2018089101-appb-000001
The number of repetitions of the SIB in the m second period of the m second periods is
Figure PCTCN2018089101-appb-000002
Figure PCTCN2018089101-appb-000003
Rounds up. The sending entity that sends the SIB may be a base station or a chip of the base station. The receiving entity receiving the SIB may be a terminal device or a chip of the terminal device. In the SIB transmission method provided in the embodiment of the present application, N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
对于m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in each second period from the first second period to the m-1th second period in the m second periods can be sent through the following specific implementation methods:
第一种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000004
次SIB可以等间隔发送,在每个第二周期内发送的
Figure PCTCN2018089101-appb-000005
次SIB占用
Figure PCTCN2018089101-appb-000006
个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为
Figure PCTCN2018089101-appb-000007
T2表示第二周期时长。或者,时间单元的时长还可以是160毫秒。
The first implementation manner is that each of the m second period to the m-1 second period to the second
Figure PCTCN2018089101-appb-000004
Secondary SIBs can be sent at regular intervals.
Figure PCTCN2018089101-appb-000005
Secondary SIB occupation
Figure PCTCN2018089101-appb-000006
Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is
Figure PCTCN2018089101-appb-000007
T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
第二种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000008
次SIB占用
Figure PCTCN2018089101-appb-000009
个时间单元,
Figure PCTCN2018089101-appb-000010
个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长还可以是160毫秒。
The second achievable manner is that each of the m second period to the m-1 second period to each second period sent in the second period
Figure PCTCN2018089101-appb-000008
Secondary SIB occupation
Figure PCTCN2018089101-appb-000009
Time units,
Figure PCTCN2018089101-appb-000010
Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit can also be 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000011
次SIB可以连续发送,
Figure PCTCN2018089101-appb-000012
次发送的SIB占用连续的
Figure PCTCN2018089101-appb-000013
个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。
The third implementable manner is that each of the m second period to the m-1 second period to each second period sent in the second period
Figure PCTCN2018089101-appb-000011
Secondary SIBs can be sent continuously,
Figure PCTCN2018089101-appb-000012
SIBs sent multiple times
Figure PCTCN2018089101-appb-000013
Downlink subframes, p is the number of downlink subframes occupied by one SIB transmission, for example, p = 8.
对于m个第二周期中第m个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in the m second period of the m second periods can be sent in the following specific implementation manners:
第一种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000014
次SIB可以等间隔发送,在第m个第二周期内发送的
Figure PCTCN2018089101-appb-000015
次SIB占用
Figure PCTCN2018089101-appb-000016
个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为
Figure PCTCN2018089101-appb-000017
T2表示第二周期时长。或者,时间单元的时长还可以是160毫秒。
The first implementable manner is that in the m second period, the
Figure PCTCN2018089101-appb-000014
Secondary SIBs can be sent at regular intervals.
Figure PCTCN2018089101-appb-000015
Secondary SIB occupation
Figure PCTCN2018089101-appb-000016
Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is
Figure PCTCN2018089101-appb-000017
T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
第二种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000018
次SIB占用
Figure PCTCN2018089101-appb-000019
个时间单元,
Figure PCTCN2018089101-appb-000020
个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长还可以是160毫秒。
The second achievable manner, the m sent in the m second period of the second period
Figure PCTCN2018089101-appb-000018
Secondary SIB occupation
Figure PCTCN2018089101-appb-000019
Time units,
Figure PCTCN2018089101-appb-000020
Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit can also be 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000021
次SIB可以连续发送,
Figure PCTCN2018089101-appb-000022
次发送的SIB占用连续的
Figure PCTCN2018089101-appb-000023
Figure PCTCN2018089101-appb-000024
个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。
A third implementable manner, in the m second period, the
Figure PCTCN2018089101-appb-000021
Secondary SIBs can be sent continuously,
Figure PCTCN2018089101-appb-000022
SIBs sent multiple times
Figure PCTCN2018089101-appb-000023
Figure PCTCN2018089101-appb-000024
Downlink subframes, p is the number of downlink subframes occupied by one SIB transmission, for example, p = 8.
结合上述可能的实现方式,在一种具体的可实现方式中,N为正整数且N为2的整数次幂,m为正整数且m为2的整数次幂,N大于或等于m,m个第二周期中每个 第二周期内SIB的重复次数为N/m。In combination with the foregoing possible implementation manners, in a specific implementable manner, N is a positive integer and N is an integer power of 2; m is a positive integer and m is an integer power of 2; The number of repetitions of the SIB in each of the second cycles is N / m.
对于m个第二周期中每个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in each of the m second cycles can be sent in the following specific implementations:
第一种可实现方式,若在每个第二周期内N/m次SIB等间隔发送,在每个第二周期内发送的N/m次SIB占用N/m个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为T2*m/N,T2表示第二周期时长。或者,时间单元的时长为160毫秒。In the first implementation manner, if N / m SIBs are sent at equal intervals in each second period, N / m SIBs sent in each second period occupy N / m time units. The SIB takes one time unit. The duration of the time unit is T2 * m / N, and T2 represents the duration of the second cycle. Alternatively, the duration of the time unit is 160 milliseconds.
第二种可实现方式,在每个第二周期内发送的N/m次SIB占用N/m个时间单元,N/m个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长为160毫秒。In a second implementation manner, N / m times of SIBs transmitted in each second cycle occupy N / m time units, N / m time units are transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit is 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,若在每个第二周期内N/m次SIB连续发送,N/m次发送的SIB占用连续的N*p/m个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。A third implementable manner. If N / m SIBs are transmitted continuously in each second cycle, the N / m transmitted SIBs occupy consecutive N * p / m downlink subframes, and p is a single SIB transmission and occupies downlinks. The number of subframes, for example, p = 8.
从而,在时域上的第一周期中重复发送的N次SIB均匀分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。Therefore, N SIBs repeatedly sent in the first period in the time domain are evenly distributed in the second period, so that the terminal device does not need to wait for a second period to receive the SIB, thereby reducing the terminal device's initial cell access. Delay.
结合上述任意一种可能的实现方式,在另一种可能的实现方式中,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移预设偏移值的时刻。With reference to any one of the foregoing possible implementation manners, in another possible implementation manner, the start time of sending the SIB for the first time in each second period is the time of the second period to which the first sent SIB belongs. The time at which the start time starts to shift from the preset offset value.
若在每个第二周期内N/m次SIB等间隔发送,时间单元的时长为T2*m/N或160ms,在另一种可能的实现方式中,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。If N / m SIBs are sent at equal intervals in each second cycle, the duration of the time unit is T2 * m / N or 160ms. In another possible implementation, the start of sending the SIB in each time unit The start time is the time offset from the start time of the time unit by a preset offset value.
若在每个第二周期内N/m个时间单元连续发送,时间单元的时长为160ms,在另一种可能的实现方式中,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。If N / m time units are sent continuously in each second cycle, the time unit duration is 160ms. In another possible implementation, the start time of sending the SIB in each time unit is the slave time unit. The time at which the start time of the offset starts to shift from the preset offset value.
其中,预设偏移值可以是预先配置的;或者,通过MIB携带预设偏移值。预设偏移值可以为40毫秒。The preset offset value may be pre-configured; or, the preset offset value is carried through the MIB. The preset offset value can be 40 milliseconds.
可选的,由于主固定信道时长是确定的,因此,预设偏移值也可以认为是不包括主固定信道时长的时长。例如,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在这种情况下,预设偏移值可以是基站设备预配置的时长,或者是一个数据信道时长,例如,预设偏移值为20毫秒。需要说明的是,下文中,数据信道也可以称为数据段。Optionally, since the duration of the primary fixed channel is determined, the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel. For example, the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value. . The start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value. In this case, the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds. It should be noted that, hereinafter, the data channel may also be referred to as a data segment.
另外,当N小于m时,从第一个第二周期开始,前N个第二周期中每个第二周期内SIB的发送次数为1,后m-N个第二周期中每个第二周期内SIB的发送次数为0。对于前N个第二周期中每个第二周期内需要发送的SIB的具体发送方式以及其他可能 的实现方式可以参考上述当N大于或等于m时的详细阐述,本申请实施例在此不再赘述。In addition, when N is less than m, starting from the first second cycle, the number of SIB transmissions in each second cycle of the first N second cycles is 1, and in each second cycle of the next mN second cycles The number of SIB transmissions is zero. For the specific sending manner of the SIB that needs to be sent in each of the first N second periods and other possible implementation manners, refer to the foregoing detailed description when N is greater than or equal to m, and the embodiments of this application are not described here. To repeat.
本申请实施例的第二方面,提供一种SIB传输方法,包括:在时域上的第一周期中,接收N次SIB,第一周期包括m个第二周期,可以理解的,第一周期时长为m倍的第二周期时长,N为大于0的正整数,m为大于0的正整数。当N大于或等于m时,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000025
m个第二周期中第m个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000026
Figure PCTCN2018089101-appb-000027
表示向上取整。发送SIB的发送实体可以是基站,也可以是基站的芯片。接收SIB的接收实体可以是终端设备,也可以是终端设备的芯片。本申请实施例提供的SIB传输方法,在时域上的第一周期中重复发送的N次SIB分散分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。
According to a second aspect of the embodiments of the present application, an SIB transmission method is provided, including: receiving N SIBs in a first period in the time domain, and the first period includes m second periods. It is understandable that the first period The duration of the second period is m times, N is a positive integer greater than 0, and m is a positive integer greater than 0. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is
Figure PCTCN2018089101-appb-000025
The number of repetitions of the SIB in the m second period of the m second periods is
Figure PCTCN2018089101-appb-000026
Figure PCTCN2018089101-appb-000027
Rounds up. The sending entity that sends the SIB may be a base station or a chip of the base station. The receiving entity receiving the SIB may be a terminal device or a chip of the terminal device. In the SIB transmission method provided in the embodiment of the present application, N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
对于m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in each second period from the first second period to the m-1th second period in the m second periods can be sent through the following specific implementation methods:
第一种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000028
次SIB可以等间隔发送,在每个第二周期内发送的
Figure PCTCN2018089101-appb-000029
次SIB占用
Figure PCTCN2018089101-appb-000030
个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为
Figure PCTCN2018089101-appb-000031
T2表示第二周期时长。或者,时间单元的时长还可以是160毫秒。
The first implementation manner is that each of the m second period to the m-1 second period to the second
Figure PCTCN2018089101-appb-000028
Secondary SIBs can be sent at regular intervals.
Figure PCTCN2018089101-appb-000029
Secondary SIB occupation
Figure PCTCN2018089101-appb-000030
Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is
Figure PCTCN2018089101-appb-000031
T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
第二种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000032
次SIB占用
Figure PCTCN2018089101-appb-000033
个时间单元,
Figure PCTCN2018089101-appb-000034
个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长还可以是160毫秒。
The second achievable manner is that each of the m second period to the m-1 second period to each second period sent in the second period
Figure PCTCN2018089101-appb-000032
Secondary SIB occupation
Figure PCTCN2018089101-appb-000033
Time units,
Figure PCTCN2018089101-appb-000034
Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit can also be 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000035
次SIB可以连续发送,
Figure PCTCN2018089101-appb-000036
次发送的SIB占用连续的
Figure PCTCN2018089101-appb-000037
个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。
The third implementable manner is that each of the m second period to the m-1 second period to each second period sent in the second period
Figure PCTCN2018089101-appb-000035
Secondary SIBs can be sent continuously,
Figure PCTCN2018089101-appb-000036
SIBs sent multiple times
Figure PCTCN2018089101-appb-000037
Downlink subframes, p is the number of downlink subframes occupied by one SIB transmission, for example, p = 8.
对于m个第二周期中第m个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in the m second period of the m second periods can be sent in the following specific implementation manners:
第一种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000038
次SIB可以等间隔发送,在第m个第二周期内发送的
Figure PCTCN2018089101-appb-000039
次SIB占用
Figure PCTCN2018089101-appb-000040
个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为
Figure PCTCN2018089101-appb-000041
T2表示第二周期时长。或者,时间单元的时长还可以是160毫秒。
The first implementable manner is that in the m second period, the
Figure PCTCN2018089101-appb-000038
Secondary SIBs can be sent at regular intervals.
Figure PCTCN2018089101-appb-000039
Secondary SIB occupation
Figure PCTCN2018089101-appb-000040
Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is
Figure PCTCN2018089101-appb-000041
T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
第二种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000042
次SIB占用
Figure PCTCN2018089101-appb-000043
个时间单元,
Figure PCTCN2018089101-appb-000044
个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长还可以是160毫秒。
The second achievable manner, the m sent in the m second period of the second period
Figure PCTCN2018089101-appb-000042
Secondary SIB occupation
Figure PCTCN2018089101-appb-000043
Time units,
Figure PCTCN2018089101-appb-000044
Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit can also be 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个 下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000045
次SIB可以连续发送,
Figure PCTCN2018089101-appb-000046
次发送的SIB占用连续的
Figure PCTCN2018089101-appb-000047
Figure PCTCN2018089101-appb-000048
个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。
A third implementable manner, in the m second period, the
Figure PCTCN2018089101-appb-000045
Secondary SIBs can be sent continuously,
Figure PCTCN2018089101-appb-000046
SIBs sent multiple times
Figure PCTCN2018089101-appb-000047
Figure PCTCN2018089101-appb-000048
Downlink subframes, p is the number of downlink subframes occupied by one SIB transmission, for example, p = 8.
结合上述可能的实现方式,在一种具体的可实现方式中,N为正整数且N为2的整数次幂,m为正整数且m为2的整数次幂,N大于或等于m,m个第二周期中每个第二周期内SIB的重复次数为N/m。In combination with the foregoing possible implementation manners, in a specific implementable manner, N is a positive integer and N is an integer power of 2, m is a positive integer and m is an integer power of 2, and N is greater than or equal to m, m The number of repetitions of the SIB in each of the second cycles is N / m.
对于m个第二周期中每个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in each of the m second cycles can be sent in the following specific implementations:
第一种可实现方式,若在每个第二周期内N/m次SIB等间隔发送,在每个第二周期内发送的N/m次SIB占用N/m个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为T2*m/N,T2表示第二周期时长。或者,时间单元的时长为160毫秒。In the first implementation manner, if N / m SIBs are sent at equal intervals in each second period, N / m SIBs sent in each second period occupy N / m time units. The SIB takes one time unit. The duration of the time unit is T2 * m / N, and T2 represents the duration of the second cycle. Alternatively, the duration of the time unit is 160 milliseconds.
第二种可实现方式,在每个第二周期内发送的N/m次SIB占用N/m个时间单元,N/m个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长为160毫秒。In a second implementation manner, N / m times of SIBs transmitted in each second cycle occupy N / m time units, N / m time units are transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit is 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,若在每个第二周期内N/m次SIB连续发送,N/m次发送的SIB占用连续的N*p/m个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。A third implementable manner. If N / m SIBs are transmitted continuously in each second cycle, the N / m transmitted SIBs occupy consecutive N * p / m downlink subframes, and p is a single SIB transmission and occupies downlinks. The number of subframes, for example, p = 8.
从而,在时域上的第一周期中重复发送的N次SIB均匀分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。Therefore, N SIBs repeatedly sent in the first period in the time domain are evenly distributed in the second period, so that the terminal device does not need to wait for a second period to receive the SIB, thereby reducing the terminal device's initial cell access. Delay.
结合上述任意一种可能的实现方式,在另一种可能的实现方式中,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移预设偏移值的时刻。With reference to any one of the foregoing possible implementation manners, in another possible implementation manner, the start time of sending the SIB for the first time in each second period is the time of the second period to which the first sent SIB belongs. The time at which the start time starts to shift from the preset offset value.
若在每个第二周期内N/m次SIB等间隔发送,时间单元的时长为T2*m/N或160ms,在另一种可能的实现方式中,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。If N / m SIBs are sent at equal intervals in each second cycle, the duration of the time unit is T2 * m / N or 160ms. In another possible implementation, the start of sending the SIB in each time unit The start time is the time offset from the start time of the time unit by a preset offset value.
若在每个第二周期内N/m个时间单元连续发送,时间单元的时长为160ms,在另一种可能的实现方式中,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。If N / m time units are sent continuously in each second cycle, the time unit duration is 160ms. In another possible implementation, the start time of sending the SIB in each time unit is the slave time unit. The time at which the start time of the offset starts to shift from the preset offset value.
其中,预设偏移值可以是预先配置的;或者,通过MIB携带预设偏移值。预设偏移值可以为40毫秒。The preset offset value may be pre-configured; or, the preset offset value is carried through the MIB. The preset offset value can be 40 milliseconds.
可选的,由于主固定信道时长是确定的,因此,预设偏移值也可以认为是不包括主固定信道时长的时长。例如,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移主固 定信道时长和预设偏移值的时刻。在这种情况下,预设偏移值可以是基站设备预配置的时长,或者是一个数据信道时长,例如,预设偏移值为20毫秒。Optionally, since the duration of the primary fixed channel is determined, the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel. For example, the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value. . The start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value. In this case, the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
另外,当N小于m时,从第一个第二周期开始,前N个第二周期中每个第二周期内SIB的发送次数为1,后m-N个第二周期中每个第二周期内SIB的发送次数为0。对于前N个第二周期中每个第二周期内需要发送的SIB的具体发送方式以及其他可能的实现方式可以参考上述当N大于或等于m时的详细阐述,本申请实施例在此不再赘述。In addition, when N is less than m, starting from the first second cycle, the number of SIB transmissions in each second cycle of the first N second cycles is 1, and in each second cycle of the next mN second cycles The number of SIB transmissions is zero. For the specific sending manner of the SIB that needs to be sent in each of the first N second periods and other possible implementation manners, refer to the foregoing detailed description when N is greater than or equal to m, and this embodiment of the present application is no longer here. To repeat.
本申请实施例的第三方面,提供一种无线通信装置,无线通信装置为基站或基站的芯片,无线通信装置包括:发送单元,其中,所述发送单元,用于在时域上的第一周期中,重复发送N次SIB,第一周期包括m个第二周期,可以理解的,第一周期时长为m倍的第二周期时长,N为大于0的正整数,m为大于0的正整数。当N大于或等于m时,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000049
m个第二周期中第m个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000050
Figure PCTCN2018089101-appb-000051
表示向上取整。
According to a third aspect of the embodiments of the present application, a wireless communication device is provided. The wireless communication device is a base station or a chip of a base station. The wireless communication device includes a sending unit, where the sending unit is configured to be a first unit in the time domain. In the cycle, the SIB is repeatedly sent N times. The first cycle includes m second cycles. It can be understood that the duration of the first cycle is m times the duration of the second cycle, N is a positive integer greater than 0, and m is a positive integer greater than 0. Integer. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is
Figure PCTCN2018089101-appb-000049
The number of repetitions of the SIB in the m second period of the m second periods is
Figure PCTCN2018089101-appb-000050
Figure PCTCN2018089101-appb-000051
Rounds up.
本申请实施例的第四方面,提供一种无线通信装置,无线通信装置为终端设备或终端设备的芯片,无线通信装置包括:接收单元,其中,所述接收单元,用于在时域上的第一周期中,接收N次SIB,第一周期包括m个第二周期,可以理解的,第一周期时长为m倍的第二周期时长,N为大于0的正整数,m为大于0的正整数。当N大于或等于m时,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000052
m个第二周期中第m个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000053
Figure PCTCN2018089101-appb-000054
表示向上取整。发送SIB的发送实体可以是基站,也可以是基站的芯片。接收SIB的接收实体可以是终端设备,也可以是终端设备的芯片。本申请实施例提供的SIB传输方法,在时域上的第一周期中重复发送的N次SIB分散分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。
According to a fourth aspect of the embodiments of the present application, a wireless communication device is provided. The wireless communication device is a terminal device or a chip of a terminal device. The wireless communication device includes a receiving unit, where the receiving unit is configured to In the first cycle, N SIBs are received. The first cycle includes m second cycles. It can be understood that the length of the first cycle is m times the length of the second cycle. N is a positive integer greater than 0 and m is greater than 0. Positive integer. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is
Figure PCTCN2018089101-appb-000052
The number of repetitions of the SIB in the m second period of the m second periods is
Figure PCTCN2018089101-appb-000053
Figure PCTCN2018089101-appb-000054
Rounds up. The sending entity that sends the SIB may be a base station or a chip of the base station. The receiving entity receiving the SIB may be a terminal device or a chip of the terminal device. In the SIB transmission method provided in the embodiment of the present application, N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
结合上述第三方面和第四方面,对于m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:With reference to the third aspect and the fourth aspect above, the SIBs that need to be sent in each second period from the first second period to the m-1th second period in the m second periods can be implemented by the following specific implementation send:
第一种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000055
次SIB可以等间隔发送,在每个第二周期内发送的
Figure PCTCN2018089101-appb-000056
次SIB占用
Figure PCTCN2018089101-appb-000057
个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为
Figure PCTCN2018089101-appb-000058
T2表示第二周期时长。或者,时间单元的时长还可以是160毫秒。
The first implementation manner is that each of the m second period to the m-1 second period to the second
Figure PCTCN2018089101-appb-000055
Secondary SIBs can be sent at regular intervals.
Figure PCTCN2018089101-appb-000056
Secondary SIB occupation
Figure PCTCN2018089101-appb-000057
Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is
Figure PCTCN2018089101-appb-000058
T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
第二种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000059
次SIB占用
Figure PCTCN2018089101-appb-000060
个时间单元,
Figure PCTCN2018089101-appb-000061
个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长还可以是160毫秒。
The second achievable manner is that each of the m second period to the m-1 second period to each second period sent in the second period
Figure PCTCN2018089101-appb-000059
Secondary SIB occupation
Figure PCTCN2018089101-appb-000060
Time units,
Figure PCTCN2018089101-appb-000061
Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit can also be 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内发送的
Figure PCTCN2018089101-appb-000062
次SIB可以连续发送,
Figure PCTCN2018089101-appb-000063
次发送的SIB占用连续的
Figure PCTCN2018089101-appb-000064
个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。
The third implementable manner is that each of the m second period to the m-1 second period to each second period sent in the second period
Figure PCTCN2018089101-appb-000062
Secondary SIBs can be sent continuously,
Figure PCTCN2018089101-appb-000063
SIBs sent multiple times
Figure PCTCN2018089101-appb-000064
Downlink subframes, p is the number of downlink subframes occupied by one SIB transmission, for example, p = 8.
对于m个第二周期中第m个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in the m second period of the m second periods can be sent in the following specific implementation manners:
第一种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000065
次SIB可以等间隔发送,在第m个第二周期内发送的
Figure PCTCN2018089101-appb-000066
次SIB占用
Figure PCTCN2018089101-appb-000067
个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为
Figure PCTCN2018089101-appb-000068
T2表示第二周期时长。或者,时间单元的时长还可以是160毫秒。
The first implementable manner is that in the m second period, the
Figure PCTCN2018089101-appb-000065
Secondary SIBs can be sent at regular intervals.
Figure PCTCN2018089101-appb-000066
Secondary SIB occupation
Figure PCTCN2018089101-appb-000067
Time units, and each time the SIB is sent, one time unit is used. Duration of time unit is
Figure PCTCN2018089101-appb-000068
T2 represents the duration of the second cycle. Alternatively, the duration of the time unit may be 160 milliseconds.
第二种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000069
次SIB占用
Figure PCTCN2018089101-appb-000070
个时间单元,
Figure PCTCN2018089101-appb-000071
个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长还可以是160毫秒。
The second achievable manner, the m sent in the m second period of the second period
Figure PCTCN2018089101-appb-000069
Secondary SIB occupation
Figure PCTCN2018089101-appb-000070
Time units,
Figure PCTCN2018089101-appb-000071
Each time unit is transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit can also be 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,m个第二周期中第m个第二周期内发送的
Figure PCTCN2018089101-appb-000072
次SIB可以连续发送,
Figure PCTCN2018089101-appb-000073
次发送的SIB占用连续的
Figure PCTCN2018089101-appb-000074
Figure PCTCN2018089101-appb-000075
个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。
A third implementable manner, in the m second period, the
Figure PCTCN2018089101-appb-000072
Secondary SIBs can be sent continuously,
Figure PCTCN2018089101-appb-000073
SIBs sent multiple times
Figure PCTCN2018089101-appb-000074
Figure PCTCN2018089101-appb-000075
Downlink subframes, p is the number of downlink subframes occupied by one SIB transmission, for example, p = 8.
结合上述可能的实现方式,在一种具体的可实现方式中,N为正整数且N为2的整数次幂,m为正整数且m为2的整数次幂,N大于或等于m,m个第二周期中每个第二周期内SIB的重复次数为N/m。In combination with the foregoing possible implementation manners, in a specific implementable manner, N is a positive integer and N is an integer power of 2, m is a positive integer and m is an integer power of 2, and N is greater than or equal to m, m The number of repetitions of the SIB in each of the second cycles is N / m.
对于m个第二周期中每个第二周期内需要发送的SIB可以通过以下具体的实现方式发送:The SIBs that need to be sent in each of the m second cycles can be sent in the following specific implementations:
第一种可实现方式,若在每个第二周期内N/m次SIB等间隔发送,在每个第二周期内发送的N/m次SIB占用N/m个时间单元,每次发送的SIB占用一个时间单元。时间单元的时长为T2*m/N,T2表示第二周期时长。或者,时间单元的时长为160毫秒。In the first implementation manner, if N / m SIBs are sent at equal intervals in each second period, N / m SIBs sent in each second period occupy N / m time units. The SIB takes one time unit. The duration of the time unit is T2 * m / N, and T2 represents the duration of the second cycle. Alternatively, the duration of the time unit is 160 milliseconds.
第二种可实现方式,在每个第二周期内发送的N/m次SIB占用N/m个时间单元,N/m个时间单元连续发送,每次发送的SIB占用一个时间单元。时间单元的时长为160毫秒。In a second implementation manner, N / m times of SIBs transmitted in each second cycle occupy N / m time units, N / m time units are transmitted continuously, and each transmitted SIB occupies one time unit. The duration of the time unit is 160 milliseconds.
结合上述第一种实现方式和第二种可实现方式,进一步的,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。例如,每次发送的SIB占用连续的8个下行子帧。或,每次发送的SIB占用连续的4个下行子帧。Combining the first implementation manner and the second implementation manner described above, further, each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0. For example, each transmitted SIB occupies 8 consecutive downlink subframes. Or, each successively transmitted SIB occupies 4 consecutive downlink subframes.
第三种可实现方式,若在每个第二周期内N/m次SIB连续发送,N/m次发送的SIB占用连续的N*p/m个下行子帧,p为一次SIB发送占用下行子帧的个数,比如p=8。A third implementable manner. If N / m SIBs are transmitted continuously in each second cycle, the N / m transmitted SIBs occupy consecutive N * p / m downlink subframes, and p is a single SIB transmission and occupies downlinks. The number of subframes, for example, p = 8.
从而,在时域上的第一周期中重复发送的N次SIB均匀分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。Therefore, N SIBs repeatedly sent in the first period in the time domain are evenly distributed in the second period, so that the terminal device does not need to wait for a second period to receive the SIB, thereby reducing the terminal device's initial cell access. Delay.
结合上述任意一种可能的实现方式,在另一种可能的实现方式中,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开 始偏移预设偏移值的时刻。With reference to any one of the foregoing possible implementation manners, in another possible implementation manner, the start time of sending the SIB for the first time in each second period is the time of the second period to which the first sent SIB belongs. The time at which the start time starts to shift from the preset offset value.
若在每个第二周期内N/m次SIB等间隔发送,时间单元的时长为T2*m/N或160ms,在另一种可能的实现方式中,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。If N / m SIBs are sent at equal intervals in each second cycle, the duration of the time unit is T2 * m / N or 160ms. In another possible implementation, the start of sending the SIB in each time unit The start time is the time offset from the start time of the time unit by a preset offset value.
若在每个第二周期内N/m个时间单元连续发送,时间单元的时长为160ms,在另一种可能的实现方式中,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。If N / m time units are sent continuously in each second cycle, the time unit duration is 160ms. In another possible implementation, the start time of sending the SIB in each time unit is the slave time unit. The time at which the start time of the offset starts to shift from the preset offset value.
其中,预设偏移值可以是预先配置的;或者,通过MIB携带预设偏移值。预设偏移值可以为40毫秒。The preset offset value may be pre-configured; or, the preset offset value is carried through the MIB. The preset offset value can be 40 milliseconds.
可选的,由于主固定信道时长是确定的,因此,预设偏移值也可以认为是不包括主固定信道时长的时长。例如,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在这种情况下,预设偏移值可以是基站设备预配置的时长,或者是一个数据信道时长,例如,预设偏移值为20毫秒。Optionally, since the duration of the primary fixed channel is determined, the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel. For example, the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value. . The start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value. In this case, the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
另外,当N小于m时,从第一个第二周期开始,前N个第二周期中每个第二周期内SIB的发送次数为1,后m-N个第二周期中每个第二周期内SIB的发送次数为0。对于前N个第二周期中每个第二周期内需要发送的SIB的具体发送方式以及其他可能的实现方式可以参考上述当N大于或等于m时的详细阐述,本申请实施例在此不再赘述。In addition, when N is less than m, starting from the first second cycle, the number of SIB transmissions in each second cycle of the first N second cycles is 1, and in each second cycle of the next mN second cycles The number of SIB transmissions is zero. For the specific sending manner of the SIB that needs to be sent in each of the first N second periods and other possible implementation manners, refer to the foregoing detailed description when N is greater than or equal to m, and the embodiments of this application are not described here. To repeat.
需要说明的是,上述第三方面和第四方面功能模块可以通过硬件实现,也可以通过硬件执行相应的软件实现。硬件或软件包括一个或多个与上述功能相对应的模块。例如,收发器,用于完成接收单元和发送单元的功能,处理器,用于完成处理单元的功能,存储器,用于存储处理器处理本申请实施例的SIB传输方法的程序指令。处理器、收发器和存储器通过总线连接并完成相互间的通信。具体的,可以参考第一方面提供的SIB传输中发送实体的行为的功能,以及第二方面提供的SIB传输中接收实体的行为的功能。It should be noted that the functional modules of the third aspect and the fourth aspect may be implemented by hardware, and may also be implemented by hardware executing corresponding software. The hardware or software includes one or more modules corresponding to the above functions. For example, the transceiver is used to complete the functions of the receiving unit and the sending unit, the processor is used to complete the functions of the processing unit, and the memory is used to store the program instructions of the processor for processing the SIB transmission method in the embodiment of the present application. The processor, the transceiver, and the memory are connected and communicate with each other through a bus. Specifically, reference may be made to the function of the behavior of the sending entity in the SIB transmission provided in the first aspect, and the function of the behavior of the receiving entity in the SIB transmission provided in the second aspect.
第五方面,本申请实施例提供一种设备,包括:处理器、存储器、总线和收发器;该存储器用于存储计算机执行指令,该处理器与该存储器通过该总线连接,当该处理器运行时,该处理器执行该存储器存储的该计算机执行指令,以使该设备执行如上述任意方面的方法。In a fifth aspect, an embodiment of the present application provides a device, including: a processor, a memory, a bus, and a transceiver; the memory is used to store a computer to execute instructions, the processor is connected to the memory through the bus, and when the processor runs When the processor executes the computer execution instructions stored in the memory, so that the device executes the method according to any aspect described above.
具体的,当该装置为基站时,收发器用于完成发送单元的功能。当该装置为终端设备时,收发器用于完成接收单元的功能。Specifically, when the device is a base station, the transceiver is used to complete a function of a transmitting unit. When the device is a terminal device, the transceiver is used to complete the function of the receiving unit.
第六方面,本申请实施例提供了一种计算机可读存储介质,用于储存为上述装置所用的计算机软件指令,当其在计算机上运行时,使得计算机可以执行上述中任意方面的方法。According to a sixth aspect, an embodiment of the present application provides a computer-readable storage medium for storing computer software instructions used by the foregoing device, and when the computer software instruction is run on the computer, the computer can execute the method in any of the foregoing aspects.
第七方面,本申请实施例提供了一种包含指令的计算机程序产品,当其在计算机上运行时,使得计算机可以执行上述任意方面的方法。In a seventh aspect, an embodiment of the present application provides a computer program product containing instructions, which when executed on a computer, enables the computer to execute the method in any of the foregoing aspects.
另外,第三方面至第七方面中任一种设计方式所带来的技术效果可参见第一方面 至第二方面中不同设计方式所带来的技术效果,此处不再赘述。In addition, for the technical effects brought by any one of the design methods in the third aspect to the seventh aspect, refer to the technical effects brought by the different design methods in the first aspect to the second aspect, which will not be repeated here.
本申请实施例中,基站、终端设备和无线通信装置的名字对设备本身不构成限定,在实际实现中,这些设备可以以其他名称出现。只要各个设备的功能和本申请实施例类似,属于本申请权利要求及其等同技术的范围之内。In the embodiment of the present application, the names of the base station, the terminal device, and the wireless communication device do not limit the device itself. In actual implementation, these devices may appear under other names. As long as the functions of each device are similar to the embodiments of the present application, they fall into the scope of the claims of the present application and their equivalent technologies.
本申请实施例的这些方面或其他方面在以下实施例的描述中会更加简明易懂。These or other aspects of the embodiments of the present application will be more concise and easy to understand in the description of the following embodiments.
附图说明BRIEF DESCRIPTION OF THE DRAWINGS
图1为现有技术提供的一种NB-IoT-U系统中发送SIB的结构示意图;FIG. 1 is a schematic structural diagram of sending an SIB in an NB-IoT-U system provided in the prior art;
图2为本申请实施例提供的一种通过系统的简化示意图;2 is a simplified schematic diagram of a passing system according to an embodiment of the present application;
图3为本申请实施例提供的一种SIB传输方法的流程图;3 is a flowchart of a SIB transmission method according to an embodiment of the present application;
图4为本申请实施例提供的一种发送SIB的结构示意图;4 is a schematic structural diagram of sending an SIB according to an embodiment of the present application;
图5为本申请实施例提供的另一种发送SIB的结构示意图;5 is a schematic structural diagram of another SIB sending method according to an embodiment of the present application;
图6为本申请实施例提供的又一种发送SIB的结构示意图;6 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图7为现有技术提供的一种包含辅固定信道发送SIB的结构示意图;FIG. 7 is a schematic structural diagram of sending a SIB including a secondary fixed channel provided in the prior art; FIG.
图8为本申请实施例提供的一种包含辅固定信道发送SIB的结构示意图;FIG. 8 is a schematic structural diagram of sending an SIB including a secondary fixed channel according to an embodiment of the present application; FIG.
图9为本申请实施例提供的再一种发送SIB的结构示意图;9 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图10为本申请实施例提供的再一种发送SIB的结构示意图;10 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图11为本申请实施例提供的再一种发送SIB的结构示意图;11 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图12为本申请实施例提供的再一种发送SIB的结构示意图;12 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图13为本申请实施例提供的再一种发送SIB的结构示意图;13 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图14为本申请实施例提供的再一种发送SIB的结构示意图;14 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图15为本申请实施例提供的再一种发送SIB的结构示意图;15 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图16为本申请实施例提供的再一种发送SIB的结构示意图;16 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图17为本申请实施例提供的再一种发送SIB的结构示意图;17 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图18为本申请实施例提供的再一种发送SIB的结构示意图;18 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图19为本申请实施例提供的再一种发送SIB的结构示意图;19 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图20为本申请实施例提供的再一种发送SIB的结构示意图;20 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application;
图21为本申请实施例提供的另一种SIB传输方法的流程图;21 is a flowchart of another SIB transmission method according to an embodiment of the present application;
图22为本申请实施例提供的一种NB-IoT-U的帧结构示意图;22 is a schematic diagram of a frame structure of an NB-IoT-U provided by an embodiment of the present application;
图23为本申请实施例提供的另一种NB-IoT-U的帧结构示意图;23 is a schematic diagram of a frame structure of another NB-IoT-U according to an embodiment of the present application;
图24为本申请实施例提供的又一种NB-IoT-U的帧结构示意图;FIG. 24 is a schematic diagram of a frame structure of still another NB-IoT-U according to an embodiment of the present application; FIG.
图25为本申请实施例提供的一种基站的组成结构示意图;FIG. 25 is a schematic structural diagram of a base station according to an embodiment of the present application; FIG.
图26为本申请实施例提供的一种设备的组成结构示意图;FIG. 26 is a schematic structural diagram of a device according to an embodiment of the present application; FIG.
图27为本申请实施例提供的另一种基站的组成结构示意图;FIG. 27 is a schematic structural diagram of another base station according to an embodiment of the present application; FIG.
图28为本申请实施例提供的一种基站的组成结构示意图;FIG. 28 is a schematic structural diagram of a base station according to an embodiment of the present application; FIG.
图29为本申请实施例提供的另一种基站的组成结构示意图。FIG. 29 is a schematic structural diagram of another base station according to an embodiment of the present application.
具体实施方式Detailed ways
下面将结合附图对本申请实施例的实施方式进行详细描述。The embodiments of the embodiments of the present application will be described in detail below with reference to the drawings.
图2示出的是可以应用本申请实施例的通信系统的简化示意图。如图2所示,该通信系统可以包括:基站201和终端设备202。FIG. 2 shows a simplified schematic diagram of a communication system to which embodiments of the present application can be applied. As shown in FIG. 2, the communication system may include: a base station 201 and a terminal device 202.
其中,基站201,可以是无线通信的基站(base station,BS)或基站控制器等。具体的,基站可以包括用户面基站和控制面基站。基站是一种部署在无线接入网中用以为终端设备202提供无线通信功能的装置,其主要功能有:进行无线资源的管理、互联网协议(internet protocol,IP)头的压缩及用户数据流的加密、用户设备附着时进行移动管理实体(mobile management entity,MME)的选择、路由用户面数据至服务网关(service gateway,SGW)、寻呼消息的组织和发送、广播消息的组织和发送、以移动性或调度为目的的测量及测量报告的配置等等。基站201可以包括各种形式的宏基站、微基站、中继站、接入点等等。在采用不同的无线接入技术的系统中,具备基站功能的设备的名称可能会有所不同,例如,在LTE网络中,称为演进的基站(evolved NodeB,eNB或eNodeB),在第3代移动通信技术(the third generation telecommunication,3G)系统中,称为基站(Node B),在下一代无线通信系统中,称为下一代基站(next generation NodeB,gNB)等等。随着通信技术的演进,“基站”这一名称可能会变化。此外,在其它可能的情况下,基站201可以是其它为终端设备202提供无线通信功能的装置。为方便描述,本申请实施例中,为终端设备202提供无线通信功能的装置称为基站。The base station 201 may be a base station (BS) or a base station controller for wireless communication. Specifically, the base station may include a user plane base station and a control plane base station. A base station is a device that is deployed in a wireless access network to provide wireless communication functions for the terminal device 202. Its main functions are: management of wireless resources, compression of Internet protocol (IP) headers, and user data flow. Encryption, selection of mobile management entity (MME) when user equipment is attached, routing user plane data to service gateway (SGW), organization and transmission of paging messages, organization and transmission of broadcast messages, Configuration of measurements and measurement reports for mobility or scheduling purposes, etc. The base station 201 may include various forms of macro base stations, micro base stations, relay stations, access points, and the like. In systems using different wireless access technologies, the names of equipment with base station functions may be different. For example, in LTE networks, they are called evolved base stations (evolved NodeB, eNB, or eNodeB). In a mobile communication technology (the third generation telecommunication (3G) system), it is called a base station (Node B), and in a next generation wireless communication system, it is called a next generation base station (gNB), and so on. As communication technology evolves, the name "base station" may change. In addition, in other possible cases, the base station 201 may be another device that provides a wireless communication function for the terminal device 202. For convenience of description, in the embodiment of the present application, a device that provides a wireless communication function for the terminal device 202 is referred to as a base station.
终端设备202也可以称为终端(terminal)、用户设备(user equipment,UE)、移动台(mobile station,MS)、移动终端(mobile terminal,MT)等。终端设备可以是手机(mobile phone)、平板电脑(Pad)、带无线收发功能的电脑、虚拟现实(virtual reality,VR)终端设备、增强现实(augmented reality,AR)终端设备、工业控制(industrial control)中的无线终端、无人驾驶(self driving)中的无线终端、远程手术(remote medical surgery)中的无线终端、智能电网(smart grid)中的无线终端、运输安全(transportation safety)中的无线终端、智慧城市(smart city)中的无线终端、智慧家庭(smart home)中的无线终端等等。本申请的实施例对终端设备所采用的具体技术和具体设备形态不做限定。终端设备202还可以是中继(Relay)和基站可以进行数据通信的都可以作为终端设备。在本申请实施例中,如图2所示,以终端设备202为一般意义的用户设备为例示出。The terminal device 202 may also be called a terminal, a user equipment (UE), a mobile station (MS), a mobile terminal (MT), or the like. The terminal device can be a mobile phone, a tablet, a computer with a wireless transceiver function, a virtual reality (VR) terminal device, an augmented reality (AR) terminal device, an industrial control (industrial control) ), Wireless terminals in self-driving, wireless terminals in remote surgery, wireless terminals in smart grid, wireless terminals in transportation safety Terminals, wireless terminals in smart cities, wireless terminals in smart homes, and so on. The embodiment of the present application does not limit the specific technology and specific device form adopted by the terminal device. The terminal device 202 may also be a relay (Relay) and a base station that can perform data communication can be used as a terminal device. In the embodiment of the present application, as shown in FIG. 2, the terminal device 202 is used as a user equipment in a general sense as an example.
需要说明的是,本申请实施例提供的通信系统可以指的是受频谱法规限制的非授权的无线通信系统。例如,NB-IoT-U系统。本申请实施例所述的SIB传输方法适用于1GHZ以下的频谱法规。It should be noted that the communication system provided in the embodiments of the present application may refer to an unauthorized wireless communication system restricted by spectrum regulations. For example, the NB-IoT-U system. The SIB transmission method described in the embodiments of the present application is applicable to spectrum regulations below 1 GHz.
例如,FCC的频谱法规对使用902MHZ-928MHz频段的设备进行了以下约束。For example, the FCC's spectrum regulations impose the following restrictions on devices using the 902MHZ-928MHz band.
对于数字调制(digital modulation)设备,需满足6dB信道带宽(bandwidth/each channel)不小于500kHz,PSD不大于8dBm/3kHz,发送功率(或称为传导功率(conducted power))不大于30dBm,等效全向辐射功率(effective isotropic radiated power,EIRP)不大于36dBm等限制。对于跳频扩频(frequency hopping spread spectrum,FHSS)设备,信道带宽不小于25kHz,并且需满足20dB信道带宽(bandwidth/each channel)不大于500kHz。如果20dB信道带宽小于250kHz,则至少支持50个跳频信道,每个信道的平均占用时间(average time of occupancy)不大于为0.4s/20s,即在20秒内,每个信道的平均占用时间不大于为0.4秒,并且EIRP不大于36dBm;如果信道带宽在250kHz到500kHz之间,则至少支持25个跳频信道,每个信道的平均占用时间(average  time of occupancy)不大于为0.4s/10s等限制。具体的可以参考https://www.ecfr.gov/cgi-bin/text-idx?SID=9848c2d82501da1215bf12f957023a34&mc=true&node=pt47.1.15&rgn=div5#se47.1.15_1247的阐述。For digital modulation (digital modulation) equipment, the 6dB channel bandwidth (bandwidth / each channel) must not be less than 500kHz, the PSD must not be greater than 8dBm / 3kHz, and the transmit power (or conductive power) not greater than 30dBm, which is equivalent Isotropic radiated power (EIRP) is limited to not more than 36 dBm. For frequency hopping spread spectrum (FHSS) equipment, the channel bandwidth is not less than 25 kHz, and the 20 dB channel bandwidth (bandwidth / each channel) is not greater than 500 kHz. If the 20dB channel bandwidth is less than 250kHz, at least 50 frequency hopping channels are supported, and the average occupation time of each channel (average time of occupation) is not greater than 0.4s / 20s, that is, the average occupation time of each channel within 20 seconds No more than 0.4 seconds, and EIRP is no more than 36dBm; if the channel bandwidth is between 250kHz and 500kHz, at least 25 frequency hopping channels are supported, and the average occupation time (average time of each channel) of each channel is not greater than 0.4s / 10s and other restrictions. For details, please refer to https://www.ecfr.gov/cgi-bin/text-idx? SID = 9848c2d82501da1215bf12f957023a34 & mc = true & node = pt47.1.15 & rgn = div5 # se47.1.15_1247.
同样,ETSI对使用1GHz以下的非授权频段的设备进行了以下约束。Similarly, ETSI imposes the following restrictions on devices using unlicensed frequency bands below 1GHz.
对于869.4-869.65MHz(band54)频段,等效辐射功率(或者有效辐射功率)(Effective Radiated Power,ERP)最大为27dBm,1小时时间内,占空比(duty cycle)最大为10%。对于865-868MHz频段,只有865.6-865.8MHz,866.2-866.4MHz,866.8-867.0MHz和867.4-867.6MHz四个频带可以使用,需要具备适应功率控制技术,等效辐射功率最大为27dBm,1小时时间内,网络接入点占空比最大为10%,否则占空比为2.5%。具体的可以参考COMMISSION IMPLEMENTING DECISION(EU)2017/1483of 8August 2017的阐述。For the frequency band 869.4-869.65MHz (band54), the equivalent radiated power (or effective radiated power) (ERP) is 27dBm at the maximum, and the duty cycle is 10% at the maximum within one hour. For the 865-868MHz frequency band, only 866.66-865.8MHz, 866.22-866.4MHz, 866.8-867.0MHz, and 867.4-867.6MHz frequency bands can be used. It needs to have adaptive power control technology. The equivalent radiated power is 27dBm at the maximum and 1 hour Within the network access point, the maximum duty cycle is 10%, otherwise the duty cycle is 2.5%. For details, please refer to the explanation of COMMISSION IMPLEMENTING DECISION (EU) 2017 / 1483of 8August 2017.
另外,在本申请实施例中,“示例的”、或者“比如”等词用于表示作例子、例证或说明。本申请实施例中被描述为“示例”或“比如”的任何实施例或设计方案不应被解释为比其它实施例或设计方案更优选或更具优势。确切而言,使用“示例的”、或者“比如”等词旨在以具体方式呈现概念。In addition, in the embodiments of the present application, words such as "exemplary" or "such as" are used as an example, illustration, or description. Any embodiment or design described as “example” or “such as” in the embodiments of the present application should not be construed as more preferred or more advantageous than other embodiments or designs. Rather, the words "exemplary" or "such as" are used to present concepts in a concrete manner.
本申请实施例描述的网络架构以及业务场景是为了更加清楚的说明本申请实施例的技术方案,并不构成对于本申请实施例提供的技术方案的限定,本领域普通技术人员可知,随着网络架构的演变和新业务场景的出现,本申请实施例提供的技术方案对于类似的技术问题,同样适用。The network architecture and service scenarios described in the embodiments of the present application are intended to more clearly illustrate the technical solutions of the embodiments of the present application, and do not constitute a limitation on the technical solutions provided by the embodiments of the present application. Those skilled in the art can know that with the network The evolution of the architecture and the emergence of new business scenarios. The technical solutions provided in the embodiments of the present application are also applicable to similar technical issues.
需要说明的是,本申请中的“连接”是指可以相互通信,具体可以通过有线方式连接,也可以通过无线方式连接,本申请实施例对此不作具体限定。其中,相互连接的设备之间可能是直连,也可能是通过其它设备连接,本申请实施例对此不作具体限定。It should be noted that “connection” in the present application means that they can communicate with each other, and specifically, they can be connected in a wired manner or wirelessly, which is not specifically limited in the embodiments of the present application. The devices connected to each other may be directly connected or may be connected through other devices, which is not specifically limited in the embodiment of the present application.
根据目前的MFA的进展,NB-IoT-U系统中SIB的发送格式为:以固定信道周期的起始点为边界,SIB在同步信号和MIB,或者同步信号、MIB和其它广播信息发送之后,根据SIB周期内的SIB重复次数集中在一个固定信道周期内发送所有SIB,所有SIB占用连续的有效下行子帧。所谓有效下行子帧为可以用于传输SIB的下行子帧。如果SIB周期内包括两个固定信道周期,SIB集中在一个固定信道周期内发送,另外一个固定信道周期内没有SIB发送。在这种情况下,如果终端设备在没有SIB发送的固定信道周期内完成MIB接收,则需要再等待一个固定信道周期接收SIB。因此,增加了终端设备进行小区初始接入的时延。According to the current progress of MFA, the SIB transmission format in the NB-IoT-U system is: starting from a fixed channel period as the boundary. After the synchronization signal and MIB, or synchronization signal, MIB, and other broadcast information are sent, the SIB The number of SIB repetitions in the SIB cycle is concentrated to send all SIBs in a fixed channel period, and all SIBs occupy consecutive effective downlink subframes. The so-called effective downlink subframe is a downlink subframe that can be used for transmitting SIB. If the SIB period includes two fixed channel periods, the SIB is concentrated to be transmitted in one fixed channel period, and no SIB is transmitted in the other fixed channel period. In this case, if the terminal device completes MIB reception within a fixed channel period without SIB transmission, it needs to wait for another fixed channel period to receive SIB. Therefore, the delay of the initial access of the cell by the terminal device is increased.
为了减小终端设备进行小区初始接入的时延。本申请实施例提供一种SIB传输方法,其基本原理是:在时域上的第一周期中,重复发送N次SIB,第一周期包括m个第二周期,可以理解的,第一周期时长为m倍的第二周期时长,N为大于0的正整数,m为大于0的正整数。当N大于或等于m时,m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000076
m个第二周期中第m个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000077
表示向上取整。发送SIB的发送实体可以是基站,也可以是基站的芯片。接收SIB的接收实体可以是终端设备,也可以是终端设备的芯片。本申请实施例提供的SIB传输方法,在时域上的第一周期中 重复发送的N次SIB分散分布在第二周期内,使得终端设备无需等待一个第二周期再接收SIB,从而,减小了终端设备进行小区初始接入的时延。
In order to reduce the delay of the terminal's initial cell access. The embodiment of the present application provides a SIB transmission method. The basic principle is: In the first period in the time domain, the SIB is repeatedly transmitted N times. The first period includes m second periods. It is understandable that the duration of the first period is The duration of the second period is m times, N is a positive integer greater than 0, and m is a positive integer greater than 0. When N is greater than or equal to m, the number of repetitions of the SIB in each second period from the first second period to the m-1th second period in m second periods is
Figure PCTCN2018089101-appb-000076
The number of repetitions of the SIB in the m second period of the m second periods is
Figure PCTCN2018089101-appb-000077
Rounds up. The sending entity that sends the SIB may be a base station or a chip of the base station. The receiving entity receiving the SIB may be a terminal device or a chip of the terminal device. In the SIB transmission method provided in the embodiment of the present application, N SIBs repeatedly sent in the first cycle in the time domain are dispersedly distributed in the second cycle, so that the terminal device does not need to wait for a second cycle before receiving the SIB, thereby reducing The delay of the terminal device's initial access to the cell is achieved.
下面为了方便理解,本申请实施例假设发送实体是基站,接收实体是终端设备。以基站和终端设备之间的通信为例进行描述。In the following, for ease of understanding, the embodiment of the present application assumes that the sending entity is a base station and the receiving entity is a terminal device. The communication between the base station and the terminal device is taken as an example for description.
图3为本申请实施例提供的一种SIB传输方法的流程图,如图3所示,该方法可以包括:FIG. 3 is a flowchart of a SIB transmission method according to an embodiment of the present application. As shown in FIG. 3, the method may include:
S301、基站在时域上的第一周期中重复发送N次SIB。S301. The base station repeatedly sends the SIB N times in the first cycle in the time domain.
第一周期包括m个第二周期。第一周期可以理解为发送SIB的周期。第二周期可以理解为(主)固定信道周期。(主)固定信道周期也可以称为MIB周期、PBCH周期或(主)发现参考信号(discovery reference signal,DRS)周期。所谓主固定信道可以理解为发送同步信号和MIB,或者同步信号、MIB和其它广播信息等消息的固定频点。主固定信道也可以称为公共信道。对于工作在非授权频谱上的系统,为了减小终端设备初始接入时的时延,基站通常先在一个预先约定的固定频点上发送同步信号和MIB,或者同步信号、MIB和其它广播信息等消息,在发送同步信号和MIB,或者同步信号、MIB和其它广播信息之后,在数据信道上采用时分复用的方式向终端设备发送SIB。从而,在固定信道上发送同步信号和MIB,或者同步信号、MIB和其它广播信息,以便于终端设备在盲检测时搜索到同步信号,之后接收MIB信息,以及其它广播信息,再接收SIB并执行随机接入等流程。本申请实施例所述的SIB包括SIB1至SIB7等。同步信号包括主同步信号(primary synchronization signal,PSS)和辅同步信号(secondary synchronization signal,SSS)。MIB通过物理下行广播信道(physical broadcast channel,PBCH)传输,其它广播信息包括但不限于不使用本申请实施例所述的SIB传输方案的其它SIB。为简单起见,下文中,固定信道上省略其它广播信息发送的描述,只描述固定信道上发送同步信号和MIB。本申请实施例所述的固定信道和数据信道占用的频域资源和时域资源均是非授权频谱资源。The first period includes m second periods. The first cycle can be understood as the cycle of sending the SIB. The second period can be understood as the (main) fixed channel period. The (main) fixed channel period may also be referred to as a MIB period, a PBCH period, or a (main) discovery reference signal (DRS) period. The so-called main fixed channel can be understood as a fixed frequency of sending synchronization signals and MIBs, or messages such as synchronization signals, MIBs, and other broadcast information. The main fixed channel can also be called a common channel. For systems operating on unlicensed spectrum, in order to reduce the delay in the initial access of terminal equipment, base stations usually first send synchronization signals and MIBs, or synchronization signals, MIBs, and other broadcast information, at a fixed frequency point that is predetermined. After waiting for the message, after sending the synchronization signal and MIB, or the synchronization signal, MIB, and other broadcast information, the SIB is sent to the terminal device in a time division multiplexed manner on the data channel. Therefore, the synchronization signal and MIB, or the synchronization signal, MIB, and other broadcast information are sent on the fixed channel, so that the terminal device searches for the synchronization signal during blind detection, and then receives the MIB information and other broadcast information, and then receives the SIB and executes Random access and other processes. The SIBs described in the embodiments of the present application include SIB1 to SIB7. The synchronization signals include a primary synchronization signal (PSS) and a secondary synchronization signal (SSS). The MIB is transmitted through a physical downlink broadcast channel (PBCH). Other broadcast information includes, but is not limited to, other SIBs that do not use the SIB transmission scheme described in the embodiments of the present application. For the sake of simplicity, in the following description, the description of sending other broadcast information on the fixed channel is omitted, and only the synchronization signal and the MIB transmitted on the fixed channel are described. The frequency domain resources and time domain resources occupied by the fixed channel and the data channel described in the embodiments of the present application are unlicensed spectrum resources.
需要说明的是,固定信道除了发送同步信号和MIB,或者同步信号、MIB和其它广播信息外,固定信道时长还可以包括上行部分,本申请实施例不做限定。It should be noted that in addition to sending the synchronization signal and MIB, or the synchronization signal, MIB, and other broadcast information, the fixed channel duration may include an uplink portion, which is not limited in the embodiment of the present application.
其中,m为大于0的正整数,N为大于0的正整数。第一周期包括m个第二周期可以理解为第一周期时长为m倍的第二周期时长。在本申请实施例中,假设第一周期时长为T1,第二周期时长为T2,T1=m*T2。T1的时间单位和T2的时间单位分别可以为1毫秒(millisecond,ms),或者10ms。本申请实施例中均以1毫秒为例进行说明。可实现的,当N大于或等于m时,在m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000078
在m个第二周期中第m个第二周期内SIB的重复次数为
Figure PCTCN2018089101-appb-000079
其中,
Figure PCTCN2018089101-appb-000080
表示向上取整。所谓向上取整是指当计算的结果不为整数时取大于且最接近计算结果的整数。例如,N=7,m=2,N/m=3.5,
Figure PCTCN2018089101-appb-000081
2个第二周期中第1个第二周期内SIB的重复次数为4;在2个第二周期中第2个第二周期内SIB的重复次数为3。本申请实施例中默认省略向上取整的符号,即默认N/m的计算结果是整数。例如,m为2的整数次幂,m可以等于1、2、4或8。N为2的整数次幂,N可以等于1、2、4、8或16。m个第二周期中每个第二周期内SIB的重复次数可以为N/m。下文中以N/m的计 算结果是整数为例对第二周期内SIB的发送方式进行介绍。
Among them, m is a positive integer greater than 0, and N is a positive integer greater than 0. The first period includes m second periods, which can be understood as the second period having a length of m times the first period. In the embodiment of the present application, it is assumed that the duration of the first cycle is T1, the duration of the second cycle is T2, and T1 = m * T2. The time unit of T1 and the time unit of T2 can be 1 millisecond (millisecond, ms), or 10ms, respectively. In the embodiments of the present application, 1 millisecond is taken as an example for description. It is achievable that when N is greater than or equal to m, the number of SIB repetitions in each second period from the first second period to the m-1th second period in m second periods is
Figure PCTCN2018089101-appb-000078
The number of SIB repetitions in the m second period in the m second periods is
Figure PCTCN2018089101-appb-000079
among them,
Figure PCTCN2018089101-appb-000080
Rounds up. The so-called round-up means that when the result of the calculation is not an integer, an integer greater than and closest to the result of the calculation is taken. For example, N = 7, m = 2, N / m = 3.5,
Figure PCTCN2018089101-appb-000081
The number of repetitions of the SIB in the first second period of the two second periods is four; the number of repetitions of the SIB in the second second period of the two second periods is three. In the embodiments of the present application, the round-up symbol is omitted by default, that is, the calculation result of the default N / m is an integer. For example, m is an integer power of 2, and m can be equal to 1, 2, 4, or 8. N is an integer power of 2. N can be equal to 1, 2, 4, 8, or 16. The number of repetitions of the SIB in each of the m second periods may be N / m. In the following, the method of sending the SIB in the second cycle is described by taking the calculation result of N / m as an integer as an example.
当N大于或等于m时,N次SIB均匀分布在m个第二周期中,即m个第二周期中每个第二周期内SIB的重复次数为N/m。例如,当N=2且m=2时,第一周期内包含2个第二周期,在第一周期内的每个第二周期内分别发送1次SIB。当N=16且m=2时,第一周期内包含2个第二周期,在第一周期内的每个第二周期内分别发送8次SIB。当N=16且m=4时,第一周期内包含4个第二周期,在第一周期内的每个第二周期内分别发送4次SIB。When N is greater than or equal to m, the N SIBs are uniformly distributed in m second periods, that is, the number of repetitions of the SIB in each second period of the m second periods is N / m. For example, when N = 2 and m = 2, the first period includes two second periods, and the SIB is sent once in each second period in the first period. When N = 16 and m = 2, the first cycle includes two second cycles, and the SIB is transmitted eight times in each second cycle in the first cycle. When N = 16 and m = 4, the first cycle includes four second cycles, and the SIB is sent four times in each second cycle in the first cycle.
当N小于m时,从第一个第二周期开始,前N个第二周期中每个第二周期内SIB的重复次数为1,后m-N个第二周期中每个第二周期内SIB的重复次数为0。例如,当N=1且m=2时,第一周期内包含2个第二周期,在第一周期内的第一个第二周期内发送一次SIB,在第一周期内的第二个第二周期内不发送SIB。当N=2且m=4时,第一周期内包含4个第二周期,在第一周期内的第一个第二周期和第二个第二周期内分别发送一次SIB,在第一周期内的第三个第二周期和第四个第二周期内不发送SIB。When N is less than m, starting from the first second cycle, the number of SIB repetitions in each second cycle in the first N second cycles is 1, and The number of repetitions is 0. For example, when N = 1 and m = 2, the first cycle includes 2 second cycles, the SIB is sent once in the first second cycle in the first cycle, and the second No SIB is sent for two cycles. When N = 2 and m = 4, the first cycle includes 4 second cycles, and the SIB is sent once in the first second cycle and the second second cycle in the first cycle, and in the first cycle The SIB is not transmitted during the third second period and the fourth second period.
需要说明的是,本申请实施例所述的重复发送N次SIB包括第1次发送SIB。可理解的,在时域上的第一周期中重复发送N次SIB即在时域上的第一周期中一共发送N次SIB,每次发送的SIB的内容相同。It should be noted that repeatedly sending the SIBs N times in the embodiment of the present application includes sending the SIBs for the first time. It can be understood that the SIB is repeatedly sent N times in the first cycle in the time domain, that is, the SIB is sent N times in the first cycle in the time domain, and the content of the SIB sent each time is the same.
下面对于在每个第二周期内重复发送N/m次SIB的发送方式进行详细阐述说明。The following describes in detail a sending manner in which the SIB is repeatedly sent N / m times in each second cycle.
在第一种可实现方式中,在每个第二周期内N/m次SIB等间隔发送,结合上述N次SIB均匀分布在m个第二周期中,可理解的,N次SIB发送在第一周期内等间隔发送。在每个第二周期内每次发送的SIB可以认为占用一个时间单元,则在每个第二周期内发送的N/m次SIB可以占用N/m个时间单元。更进一步的,在每个第二周期内N/m个时间单元可以是均匀分布的,即N/m个时间单元等间隔发送。在每个时间单元内,每次发送的SIB占用连续的下行子帧。例如,每次发送的SIB可以占用连续的8个下行子帧。或者,在每个时间单元内,每次发送的SIB可以占用连续的4个下行子帧。In the first implementable manner, N / m times of SIBs are sent at equal intervals in each second cycle. In combination with the above N times of SIBs, they are evenly distributed in m second cycles. Understandably, N times of SIBs are sent at the first Send at regular intervals throughout the week. The SIB transmitted each time in each second cycle may be considered to occupy one time unit, and the N / m SIBs transmitted in each second cycle may occupy N / m time units. Furthermore, the N / m time units may be uniformly distributed in each second period, that is, the N / m time units are sent at equal intervals. Within each time unit, each transmitted SIB occupies consecutive downlink subframes. For example, each transmitted SIB can occupy 8 consecutive downlink subframes. Or, in each time unit, each transmitted SIB may occupy 4 consecutive downlink subframes.
需要说明的是,上述时间单元可以理解为发送一次SIB的时间单位。本申请实施例对发送一次SIB的时间单位的名称不作限定。例如,时间单元也可以称作时间单元块、时间单元窗、发送块或者发送窗。另外,上述N/m个时间单元中每个时间单元的时长可以根据第一周期时长,第二周期时长和SIB的重复次数来确定。根据第一周期时长,第二周期时长和SIB的重复次数的不同,时间单元的时长也可以是不同的。在本申请实施例中,假设每次发送的SIB的时间单元的时长为T3。当N大于或等于m时,用于公式表示,时间单元的时长可以为:T3=T2*m/N。T3的时间单位分别可以为1ms或者10ms。当N小于m时,由于第一周期内的前N个第二周期内只传输一次SIB,则时间单元的时长可以为:T3=T1/m。本申请实施例中以1毫秒为例进行说明。It should be noted that the foregoing time unit can be understood as a time unit for sending the SIB once. The embodiment of the present application does not limit the name of the time unit for sending the SIB once. For example, a time unit may also be referred to as a time unit block, a time unit window, a transmission block, or a transmission window. In addition, the duration of each time unit in the N / m time units can be determined according to the duration of the first cycle, the duration of the second cycle, and the number of repetitions of the SIB. Depending on the duration of the first cycle, the duration of the second cycle, and the number of repetitions of the SIB, the duration of the time unit may also be different. In the embodiment of the present application, it is assumed that the duration of the time unit of the SIB transmitted each time is T3. When N is greater than or equal to m, it is used for formula expression, and the duration of the time unit may be: T3 = T2 * m / N. The time unit of T3 can be 1ms or 10ms. When N is less than m, since the SIB is transmitted only once in the first N second periods in the first period, the duration of the time unit may be: T3 = T1 / m. In the embodiment of the present application, one millisecond is taken as an example for description.
示例的,假设T1=2560ms,T2=1280ms,m=T1/T2=2,即第一周期内包含2个第二周期。如图4所示,分别以SIB的重复次数为16、8、4、2和1进行示意性说明。For example, suppose T1 = 2560ms, T2 = 1280ms, and m = T1 / T2 = 2, that is, the first period includes two second periods. As shown in FIG. 4, the repetitive times of the SIB are 16, 8, 4, 2, and 1, respectively.
当N=16时,每个第二周期内分别发送8次SIB,并且8次发送的SIB在第二周期内均匀分布,即每个第二周期内包含8个时间单元,8个时间单元在每个第二周期内均匀分布。时间单元的时长为:T3=1280*2/16=160ms。When N = 16, 8 SIBs are sent in each second cycle, and the SIBs sent 8 times are evenly distributed in the second cycle, that is, each second cycle contains 8 time units, and 8 time units Uniformly distributed in every second cycle. The duration of the time unit is: T3 = 1280 * 2/16 = 160ms.
当N=8时,每个第二周期内分别发送4次SIB,并且4次发送的SIB在第二周期内均匀分布,即每个第二周期内包含4个时间单元,4个时间单元在每个第二周期内均匀分布。时间单元的时长为:T3=1280*2/8=320ms。When N = 8, 4 SIBs are sent in each second cycle, and the SIBs sent 4 times are evenly distributed in the second cycle, that is, each second cycle contains 4 time units, and 4 time units are in Uniformly distributed in every second cycle. The duration of the time unit is: T3 = 1280 * 2/8 = 320ms.
当N=4时,每个第二周期内分别发送2次SIB,并且2次发送的SIB在第二周期内均匀分布,即每个第二周期内包含2个时间单元,2个时间单元在每个第二周期内均匀分布。时间单元的时长为:T3=1280*2/4=640ms。When N = 4, two SIBs are sent in each second cycle, and the SIBs sent twice are evenly distributed in the second cycle, that is, each second cycle contains 2 time units, and 2 time units Uniformly distributed in every second cycle. The duration of the time unit is: T3 = 1280 * 2/4 = 640ms.
当N=2时,每个第二周期内分别发送1次SIB,即每个第二周期内包含1个时间单元。时间单元的时长为:T3=1280*2/2=1280ms。When N = 2, the SIB is sent once in each second cycle, that is, each second cycle includes one time unit. The duration of the time unit is: T3 = 1280 * 2/2 = 1280ms.
当N=1时,N小于m,在第一周期内的第一个第二周期内发送1次SIB,在第一周期内的第二个第二周期内不发送SIB。时间单元的时长为:T3=2560/2=1280ms。When N = 1, N is less than m, and the SIB is sent once in the first second period in the first period, and the SIB is not sent in the second second period in the first period. The duration of the time unit is: T3 = 2560/2 = 1280ms.
需要说明的是,上述时间单元的时长只是示意性说明,本申请实施例对具体的时间单元时长可以不作限定。当然,本申请实施例所述的时间单元的时长也可以复用NB-IoT系统中的定义。例如,若NB-IoT系统中定义时间单元的时长为160ms,在本申请实施例中无论SIB的重复次数是多少,时间单元的时长均可以认为是160ms。或者,时间单元的时长可以是根据发送SIB时SIB占用的数据信道个数和每个数据信道的信道时长确定的。例如,假设一个数据信道的信道时长为20ms,本次SIB发送占用4个数据信道,则时间单元的时长为80ms。若本次SIB发送占用2个数据信道,则时间单元的时长为40ms。可理解的,本申请实施例所述的时间单元的时长包括了发送SIB的发送时长。It should be noted that the duration of the foregoing time unit is only a schematic description, and the specific duration of the time unit may not be limited in the embodiment of the present application. Of course, the duration of the time unit described in the embodiments of the present application may also be multiplexed with the definition in the NB-IoT system. For example, if the duration of the time unit is defined in the NB-IoT system as 160 ms, in the embodiment of the present application, the duration of the time unit may be considered to be 160 ms regardless of the number of repetitions of the SIB. Alternatively, the duration of the time unit may be determined according to the number of data channels occupied by the SIB when sending the SIB and the channel duration of each data channel. For example, assuming that the channel duration of one data channel is 20 ms, and the current SIB transmission occupies 4 data channels, the duration of the time unit is 80 ms. If the current SIB transmission occupies 2 data channels, the duration of the time unit is 40ms. It can be understood that the duration of the time unit described in the embodiment of the present application includes the sending duration of sending the SIB.
进一步的,由于在每个第二周期内需要先在主固定信道上发送同步信号和MIB,因此,在第二周期内首次发送的时间单元内SIB的起始发送时刻需要偏移主固定信道时长。更进一步的,由于NB-IoT-U系统中的终端设备为低成本终端,终端设备处理能力有限,终端设备在接收完MIB(或同步信号,或者同步信号和其它广播信息)之后需要时间处理MIB(或同步信号,或者同步信号和其它广播信息),无法立即接收SIB,因此,为了保证第二周期内每个SIB的完整接收,降低终端设备接收SIB的时延,如果主固定信道不包含上行部分,则在第二周期内的第一个时间单元中首次发送SIB的起始时刻相对于主固定信道的结束时刻需要偏移一段时长,即在第二周期内的第一个时间单元中第一个SIB子帧相对于MIB的结束子帧位置需要有一个时间偏置,从而保证终端设备能够及时接收到SIB。例如,在第二周期内的第一个时间单元中首次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移了T4和T5的时刻。T4表示主固定信道时长,T5表示相对于MIB发送(或主固定信道)的结束子帧位置的时间偏置。其中,T4和T5的时间单位与时间单元的单位相同,为1ms或者10ms,T4为大于等于1的整数,T5为大于等于0的整数。Further, since the synchronization signal and the MIB need to be transmitted on the primary fixed channel first in each second cycle, the start transmission time of the SIB in the time unit transmitted for the first time in the second cycle needs to be offset from the primary fixed channel duration. . Furthermore, since the terminal equipment in the NB-IoT-U system is a low-cost terminal and the processing capability of the terminal equipment is limited, the terminal equipment needs time to process the MIB after receiving the MIB (or the synchronization signal, or the synchronization signal and other broadcast information). (Or synchronization signals, or synchronization signals and other broadcast information), SIBs cannot be received immediately. Therefore, in order to ensure the complete reception of each SIB in the second period, the delay of the terminal device receiving the SIB is reduced. In some cases, the start time of the first SIB transmission in the first time unit in the second cycle needs to be offset by a period of time relative to the end time of the primary fixed channel, that is, in the first time unit in the second cycle, the first time The position of an SIB subframe relative to the end subframe of the MIB needs to have a time offset, so as to ensure that the terminal device can receive the SIB in time. For example, the start time of sending the SIB for the first time in the first time unit in the second cycle is a time shifted by T4 and T5 from the start time of the second cycle to which the first transmitted SIB belongs. T4 represents the duration of the primary fixed channel, and T5 represents the time offset from the end subframe position of the MIB transmission (or primary fixed channel). The time unit of T4 and T5 is the same as the unit of time unit, which is 1ms or 10ms, T4 is an integer greater than or equal to 1, and T5 is an integer greater than or equal to 0.
下面对上述描述进行举例说明。图5为本申请实施例提供的另一种发送SIB的结构示意图。如图5所示,假设第二周期时长为1280ms,时间单元的时长为160ms。一个时间单元包括8个信道。8个信道的时长均为20ms。每个信道包括20个子帧,一个子帧的时长为1ms。第一个信道作为用于传输同步信号和MIB的主固定信道,即主固定信道时长为20ms。剩余的7个信道作为用于传输上行数据和下行数据的数据信道,每个数据信道的时长为20ms。一个数据信道中前2个子帧用于传输下行数据,后18 个子帧用于传输上行数据,即数据信道的上下行配比为2个下行(down link,DL)子帧和18个上行(up link,UL)子帧。在当前时间单元中的第一个发送SIB的子帧位置相对当前时间单元的起始时刻偏移了主固定信道时长和一个数据信道时长,即40ms。在当前时间单元内发送SIB需要占用连续的8个下行子帧的情况下,一个数据信道包括2个下行子帧,则在当前时间单元内发送SIB共占用4个数据信道的下行子帧,在当前时间单元内发送SIB的时长为80ms。其他数据信道包括的下行子帧用于传输下行数据,即第二个数据信道、第七个数据信道和第八个数据信道。此时,由于SIB发送引起的业务时延至少为80ms。The above description is exemplified below. FIG. 5 is another schematic structural diagram of sending an SIB according to an embodiment of the present application. As shown in FIG. 5, it is assumed that the duration of the second cycle is 1280 ms and the duration of the time unit is 160 ms. One time unit includes 8 channels. The length of the eight channels is 20ms. Each channel includes 20 subframes, and the duration of one subframe is 1ms. The first channel is used as the main fixed channel for transmitting synchronization signals and MIBs, that is, the duration of the main fixed channel is 20ms. The remaining 7 channels are used as data channels for transmitting uplink data and downlink data, and the duration of each data channel is 20ms. The first 2 subframes in a data channel are used to transmit downlink data, and the last 18 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 2 downlink (DL) subframes and 18 uplink (up link, UL) subframe. The position of the first subframe in the current time unit to send the SIB is offset from the start time of the current time unit by the duration of the main fixed channel and the duration of one data channel, that is, 40 ms. In the case that sending a SIB in the current time unit requires 8 consecutive downlink subframes, a data channel includes 2 downlink subframes, then sending a SIB in the current time unit occupies a total of 4 downlink channels in the data channel. The duration of sending the SIB in the current time unit is 80ms. Other data channels include downlink subframes for transmitting downlink data, that is, the second data channel, the seventh data channel, and the eighth data channel. At this time, the service delay caused by the SIB transmission is at least 80ms.
需要说明的是,根据数据信道中上下行子帧配比的不同,在当前时间单元内发送SIB共占用的数据信道个数也不同。例如,如图6所示,假设一个数据信道中前8个子帧用于传输下行数据,后12个子帧用于传输上行数据,即数据信道的上下行配比为8个下行子帧和12上行子帧。在当前时间单元内SIB需要占用连续的8个下行子帧的情况下,一个数据信道包括八个下行子帧,则在当前时间单元内发送SIB共占用一个数据信道的下行子帧,在当前时间单元内发送SIB的时长为20ms。其他数据信道包括的下行子帧用于传输下行数据,即第二个数据信道,以及第四个数据信道至第八个数据信道。此时,由于SIB发送引起的业务时延至少为20ms。It should be noted that, according to different uplink-downlink subframe ratios in the data channel, the number of data channels shared by the sending SIB in the current time unit is also different. For example, as shown in FIG. 6, it is assumed that the first 8 subframes in a data channel are used to transmit downlink data, and the last 12 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 8 downlink subframes and 12 uplinks. Subframe. In the case that the SIB needs to occupy 8 consecutive downlink subframes in the current time unit, and a data channel includes eight downlink subframes, the SIB sent in the current time unit occupies a total of one downlink downlink data frame. At the current time, The duration of sending the SIB in the unit is 20ms. Other data channels include downlink subframes for transmitting downlink data, that is, the second data channel, and the fourth to eighth data channels. At this time, the service delay caused by the SIB transmission is at least 20ms.
另外,在数据传输过程中,通常上行数据比下行数据多,则数据信道的上下行配比中上行子帧的个数大于下行子帧的个数。在本申请实施例所述的一个数据信道中下行子帧的个数可以是1、2、3、4、5、6、7、8或9等整数。对于在当前时间单元内发送SIB需要占用连续的下行子帧的个数是一个数据信道中下行子帧的个数的倍数时,在当前时间单元内发送SIB需要占用的数据信道个数为在当前时间单元内发送SIB需要占用连续的下行子帧的个数除以一个数据信道中下行子帧的个数的商,即C=A/B,A表示在当前时间单元内发送SIB需要占用连续的下行子帧的个数,B表示一个数据信道中下行子帧的个数,C表示当前时间单元内发送SIB需要占用的数据信道个数。例如,当A=8,B=4时,C=2。对于在当前时间单元内发送SIB需要占用连续的下行子帧的个数不是一个数据信道中下行子帧的个数的倍数时,
Figure PCTCN2018089101-appb-000082
表示向上取整。所谓向上取整是指当计算的结果不为整数时取大于且最接近计算结果的整数。例如,当A=8,B=3时,
Figure PCTCN2018089101-appb-000083
其中,发送SIB占用的三个数据信道中,第一个数据信道和第二数据信道中的下行子帧全部用于传输SIB,第三个数据信道中的前两个下行子帧用于传输SIB,后一个下行子帧可以用于传输下行数据。当A=8,B=5时,
Figure PCTCN2018089101-appb-000084
其中,发送SIB占用的二个数据信道中,第一个数据信道中的下行子帧全部用于传输SIB,第二个数据信道中的前三个下行子帧用于传输SIB,后二个下行子帧可以用于传输下行数据。当A=8,B=6时,
Figure PCTCN2018089101-appb-000085
其中,发送SIB占用的二个数据信道中,第一个数据信道中的下行子帧全部用于传输SIB,第二个数据信道中的前二个下行子帧用于传输SIB,后四个下行子帧可以用于传输下行数据。当A=8,B=7时,
Figure PCTCN2018089101-appb-000086
其中,发送SIB占用的二个数据信道中,第一个数据信道中的下行子帧全部用于传输SIB,第二个数据信道中的前一个下行子帧用于传输SIB,后六个下行子帧可以用于传输下行数据。当A=8,B=9时,
Figure PCTCN2018089101-appb-000087
其中,发送SIB占用的一个数据信道中前八个的下行子帧传输SIB,后一个下行子帧可以用于传输下行数据。在第一周期内重 复发送N次SIB占用
Figure PCTCN2018089101-appb-000088
个数据信道。
In addition, in the data transmission process, usually there is more uplink data than downlink data, so the number of uplink subframes in the uplink-downlink ratio of the data channel is greater than the number of downlink subframes. In the embodiment of the present application, the number of downlink subframes in a data channel may be an integer such as 1, 2, 3, 4, 5, 6, 7, 8, or 9. For the number of consecutive downlink subframes required to send the SIB in the current time unit is a multiple of the number of downlink subframes in a data channel, the number of data channels required to send the SIB in the current time unit is the current The quotient of the number of consecutive downlink subframes required to send an SIB in a time unit divided by the number of downlink subframes in a data channel, that is, C = A / B, where A indicates that the SIB needs to occupy consecutive The number of downlink subframes, B represents the number of downlink subframes in a data channel, and C represents the number of data channels required to send an SIB in the current time unit. For example, when A = 8 and B = 4, C = 2. When the number of consecutive downlink subframes required to send an SIB in the current time unit is not a multiple of the number of downlink subframes in a data channel,
Figure PCTCN2018089101-appb-000082
Rounds up. The so-called round-up means that when the result of the calculation is not an integer, an integer greater than and closest to the result of the calculation is taken. For example, when A = 8 and B = 3,
Figure PCTCN2018089101-appb-000083
Among the three data channels occupied by the sending SIB, the downlink subframes in the first data channel and the second data channel are all used to transmit the SIB, and the first two downlink subframes in the third data channel are used to transmit the SIB. The latter downlink subframe can be used to transmit downlink data. When A = 8 and B = 5,
Figure PCTCN2018089101-appb-000084
Among the two data channels occupied by the sending SIB, the downlink subframes in the first data channel are all used to transmit the SIB, the first three downlink subframes in the second data channel are used to transmit the SIB, and the last two downlink Sub-frames can be used to transmit downlink data. When A = 8 and B = 6,
Figure PCTCN2018089101-appb-000085
Among the two data channels occupied by the sending SIB, the downlink subframes in the first data channel are all used to transmit the SIB, the first two downlink subframes in the second data channel are used to transmit the SIB, and the last four downlink Sub-frames can be used to transmit downlink data. When A = 8 and B = 7,
Figure PCTCN2018089101-appb-000086
Among the two data channels occupied by the sending SIB, the downlink subframes in the first data channel are all used to transmit the SIB, the first downlink subframe in the second data channel is used to transmit the SIB, and the last six downlink subframes Frames can be used to transmit downlink data. When A = 8 and B = 9,
Figure PCTCN2018089101-appb-000087
Among them, the first eight downlink subframes of one data channel occupied by the sending SIB transmit the SIB, and the latter downlink subframe can be used to transmit downlink data. Repeatedly send N SIB occupations in the first cycle
Figure PCTCN2018089101-appb-000088
Data channels.
进一步的,出于统一设计的考虑,可以统一规定在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移T4和T5的时刻,即SIB在每个时间单元内的首次发送下行子帧相对于当前SIB时间单元的首个下行子帧时间偏移T4和T5。上述T4和T5之和可以认为是一个预设偏移值。该预设偏移值可以预配置为与帧结构相关。例如,预设偏移值包括主固定信道时长和一个数据信道时长,例如,T4=20毫秒,T5=20毫秒,预设偏移值为40毫秒。该预设偏移值还可以由基站设备预配置,例如,预设偏移值为40毫秒。该预设偏移值也可以通过广播信息指示,如通过MIB指示,预设偏移值为40毫秒。该预设偏移值也可以通过同步序列指示,同步序列包括PSS和SSS,可理解的,假设10毫秒为一个无线帧,无线帧号n f取值范围为0~1023,一个无线帧内包含10个子帧,每个子帧包含2个时隙,时隙号n s在一个无线帧内的取值范围为0~19,每次SIB发送的起始位置相对于SIB发送所属的时间单元起始位置的预设偏移值为
Figure PCTCN2018089101-appb-000089
第一周期时长等于2560ms,则每个发送SIB的时间单元内SIB发送的起始位置满足:
Figure PCTCN2018089101-appb-000090
其中
Figure PCTCN2018089101-appb-000091
为向下取整,所谓向下取整是指当计算的结果不为整数时取小于且最接近计算结果的整数。
Further, for the sake of uniform design, the start time of sending the SIB in each time unit can be uniformly specified as the time offset from the start time of the time unit by T4 and T5, that is, the SIB is in each time unit The first downlink subframe transmitted by is offset by T4 and T5 from the first downlink subframe of the current SIB time unit. The above sum of T4 and T5 can be considered as a preset offset value. The preset offset value may be pre-configured to be related to the frame structure. For example, the preset offset value includes the duration of the main fixed channel and the duration of one data channel, for example, T4 = 20 ms, T5 = 20 ms, and the preset offset value is 40 ms. The preset offset value may also be pre-configured by the base station device, for example, the preset offset value is 40 milliseconds. The preset offset value may also be indicated by broadcast information, such as the MIB instruction, and the preset offset value is 40 milliseconds. The preset offset value can also be indicated by a synchronization sequence. The synchronization sequence includes PSS and SSS. Understandably, it is assumed that 10 milliseconds is a radio frame, and the value of the radio frame number n f ranges from 0 to 1023. A radio frame contains 10 sub-frames, each sub-frame contains 2 time slots, and the time slot number n s ranges from 0 to 19 in a radio frame. The start position of each SIB transmission is relative to the start of the time unit to which the SIB transmission belongs. The preset offset value for the position
Figure PCTCN2018089101-appb-000089
The duration of the first cycle is equal to 2560ms, then the starting position of the SIB transmission in each time unit for sending the SIB satisfies:
Figure PCTCN2018089101-appb-000090
among them
Figure PCTCN2018089101-appb-000091
For rounding down, the so-called rounding down refers to rounding up to the nearest integer when the result of the calculation is not an integer.
可选的,由于主固定信道时长是确定的,因此,预设偏移值也可以认为是不包括主固定信道时长的时长。例如,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移主固定信道时长和预设偏移值的时刻。在这种情况下,预设偏移值可以是基站设备预配置的时长,或者是一个数据信道时长,例如,预设偏移值为20毫秒。Optionally, since the duration of the primary fixed channel is determined, the preset offset value may also be considered as a duration that does not include the duration of the primary fixed channel. For example, the start time of sending the SIB for the first time in each second cycle is the time offset from the start time of the second cycle to which the first transmitted SIB belongs, and the time length of the primary fixed channel and the preset offset value. . The start time of sending the SIB in each time unit is the time from the start time of the time unit to the main fixed channel duration and the preset offset value. In this case, the preset offset value may be a duration pre-configured by the base station device or a data channel duration, for example, the preset offset value is 20 milliseconds.
需要说明的是,假设第一周期时长为2560ms,SIB重复次数N等于16,对于图5所示的帧结构,主固定信道传输的同步信号和MIB占用了20ms,第二周期内需要传输8次SIB,每次发送SIB占用8ms,主固定信道传输的同步信号和MIB以及数据信道传输的SIB占用的下行开销为约为
Figure PCTCN2018089101-appb-000092
在非授权频谱上,如果下行占空比要求为10%,则用于传输下行数据的资源只占3.4%,因此可以通过提高第一周期来降低SIB的开销。例如,当第一周期时长为5120ms时,主固定信道传输的同步信号和MIB以及数据信道传输的SIB占用的下行开销为约为
Figure PCTCN2018089101-appb-000093
当第一周期时长为10240ms时,主固定信道传输的同步信号和MIB以及数据信道传输的SIB占用的下行开销为约为
Figure PCTCN2018089101-appb-000094
第一周期时长可以根据实际情况进行预配置。例如,在没有占空比要求的地区,第一周期时长预配置为2560ms。在有占空比要求的地区,第一周期时长预配置为5120ms或者10240ms。第一周期时长也可以通过MIB配置,以支持更大的灵活性,可理解的,假设10毫秒为一个无线帧,无线帧号n f取值范围为0~1023,一个无线帧内包含10个子帧,每个子帧包含2个时隙,时隙号n s在一个无线帧内的取值范围为0~19,每次SIB发送的起始位置相对于SIB发送所属的时间单元起始位置的预设偏移值为
Figure PCTCN2018089101-appb-000095
如果第一周期时长等于5120ms,则每个发送SIB的时间单元内SIB发送的起始位置满足:
Figure PCTCN2018089101-appb-000096
再或者,如果第一周期时长等于10240ms, N>1,则每个发送SIB的时间单元内SIB发送的起始位置满足
Figure PCTCN2018089101-appb-000097
Figure PCTCN2018089101-appb-000098
其中
Figure PCTCN2018089101-appb-000099
为向下取整,所谓向下取整是指当计算的结果不为整数时取小于且最接近计算结果的整数。
It should be noted that it is assumed that the duration of the first cycle is 2560ms and the number of SIB repetitions N is equal to 16. For the frame structure shown in FIG. 5, the synchronization signal and MIB transmitted by the main fixed channel occupy 20ms, and 8 transmissions are required in the second cycle. SIB, each sending SIB takes 8ms, and the downlink signal occupied by the synchronization signal and MIB transmitted by the main fixed channel and the data channel transmitted by the SIB is approximately
Figure PCTCN2018089101-appb-000092
On the unlicensed spectrum, if the downlink duty cycle requirement is 10%, the resources used to transmit downlink data only account for 3.4%, so the SIB overhead can be reduced by increasing the first cycle. For example, when the duration of the first cycle is 5120ms, the downlink overhead occupied by the synchronization signal and MIB transmitted by the main fixed channel and the SIB transmitted by the data channel is approximately
Figure PCTCN2018089101-appb-000093
When the duration of the first cycle is 10240ms, the downlink overhead occupied by the synchronization signal and MIB transmitted by the main fixed channel and the SIB transmitted by the data channel is approximately
Figure PCTCN2018089101-appb-000094
The duration of the first cycle can be pre-configured according to the actual situation. For example, in areas where there is no duty cycle requirement, the duration of the first cycle is preconfigured to 2560ms. In areas with duty cycle requirements, the duration of the first cycle is pre-configured to 5120ms or 10240ms. The duration of the first cycle can also be configured through MIB to support greater flexibility. Understandably, it is assumed that 10 milliseconds is a radio frame, and the value of the radio frame number n f ranges from 0 to 1023. A radio frame contains 10 sub-frames. Frame, each sub-frame contains 2 time slots, and the value of time slot number n s in a radio frame ranges from 0 to 19. The start position of each SIB transmission is relative to the start position of the time unit to which the SIB transmission belongs. Preset offset value
Figure PCTCN2018089101-appb-000095
If the duration of the first cycle is equal to 5120ms, the start position of the SIB transmission in each time unit in which the SIB is transmitted satisfies:
Figure PCTCN2018089101-appb-000096
Or alternatively, if the duration of the first cycle is equal to 10240ms, and N> 1, the start position of the SIB transmission within each time unit for sending the SIB satisfies
Figure PCTCN2018089101-appb-000097
Figure PCTCN2018089101-appb-000098
among them
Figure PCTCN2018089101-appb-000099
For rounding down, the so-called rounding down refers to rounding up to the nearest integer when the result of the calculation is not an integer.
同样的,除了提高第一周期的时长,也可以通过降低SIB最大重传次数来降低SIB的开销。比如第一周期时长为2560ms,SIB在第一周期内最大重复次数N等于8,此时,主固定信道传输的同步信号和MIB以及数据信道传输的SIB占用的下行开销为约为4.1%。SIB在第一周期内的重复次数可以通过MIB指示。在没有占空比要求的地区,SIB重复次数为4、8和16。在有占空比要求的地区,SIB重复次数为2、4和8。Similarly, in addition to increasing the duration of the first cycle, the overhead of the SIB can also be reduced by reducing the maximum number of SIB retransmissions. For example, the duration of the first cycle is 2560ms, and the maximum number of repetitions N of the SIB in the first cycle is equal to 8. At this time, the downlink signal occupied by the synchronization signal and MIB transmitted by the main fixed channel and the SIB transmitted by the data channel is approximately 4.1%. The number of repetitions of the SIB in the first cycle can be indicated by the MIB. In areas where there is no duty cycle requirement, the number of SIB repetitions is 4, 8, and 16. In areas with duty cycle requirements, the number of SIB repetitions is 2, 4, and 8.
与现有技术相比,在第一周期内重复发送的SIB在第二周期之间均匀分布,对于近距离覆盖终端,不需要等待一个甚至多个第二周期后再接收SIB,减小了初始接入时延;并且从第二周期的起始时刻开始偏移预设偏移值之后,终端设备再接收SIB可以保证终端设备完整接收到第二周期内SIB的首次发送。Compared with the prior art, the SIBs repeatedly sent in the first cycle are evenly distributed between the second cycles. For short-range coverage terminals, there is no need to wait for one or more second cycles to receive SIBs, which reduces the initial The access delay; and after the preset offset value is offset from the beginning of the second period, the terminal device receiving the SIB again can ensure that the terminal device completely receives the first transmission of the SIB in the second period.
此外,在现有技术中,若终端设备的下行数据接收(或基站的下行数据发送)与SIB发送时段重合,则终端设备(或基站)需要延迟SIB发送时长后再继续进行下行接收(或下行发送),由于SIB都集中在一个固定信道周期内发送,有可能该固定信道周期内的大部分下行资源全部被SIB占用,SIB占用的下行资源不能进行数据传输,因此增加了业务时延。以SIB重复发送16次,每次发送占用8个下行子帧为例,则至少需要128个连续下行子帧被SIB占用。由于NB-IoT-U为TDD系统,当数据信道的上下行配比为8个下行子帧和12个上行子帧时,业务将中断(128/8)*20=320ms。本申请实施例所述的SIB传输方法,SIB在第二周期内以时间单元为单位进行发送,SIB只占用一个时间单元内的部分下行子帧,因此也可以减小终端设备的业务时延。In addition, in the prior art, if the downlink data reception (or the downlink data transmission of the base station) of the terminal device coincides with the SIB transmission period, the terminal device (or the base station) needs to delay the SIB transmission duration before continuing the downlink reception (or downlink) Sending), because the SIBs are concentrated to be sent in a fixed channel period, it is possible that most of the downlink resources in the fixed channel period are occupied by the SIB, and the downlink resources occupied by the SIB cannot perform data transmission, thereby increasing service delay. Taking SIB repeated transmission 16 times, each transmission takes 8 downlink subframes as an example, at least 128 consecutive downlink subframes need to be occupied by the SIB. Because NB-IoT-U is a TDD system, when the uplink and downlink ratio of the data channel is 8 downlink subframes and 12 uplink subframes, the service will be interrupted (128/8) * 20 = 320ms. In the SIB transmission method described in the embodiment of the present application, the SIB is transmitted in units of time units in the second cycle. The SIB only occupies part of the downlink subframes in one time unit, so the service delay of the terminal device can also be reduced.
需要说明的是,一种可能的情况是,在第二周期内除了可以配置主固定信道之外,在数据信道上还可以周期性地配置辅固定(secondary anchor)信道。例如,在现有技术中,SIB都集中在一个第二周期内发送,当SIB重复次数为16时,SIB需要占用连续128(16*8)ms,即128个下行子帧。以数据信道的上下行配比为8个下行子帧和12个上行子帧为例,一个数据信道的时长为20ms,需要占用16个数据信道才能发送完SIB,则SIB需要持续320(16*20)ms。如果第二周期内包含7个辅固定信道,加上一个主固定信道,第二周期内包括共8个固定信道,则固定信道周期为160ms,SIB持续320ms时需要跳过2个辅固定信道,因此实际造成的业务时延为360ms。图7为现有技术提供的一种包含辅固定信道发送SIB的结构示意图。在这种情况下,可以用于发送SIB的下行子帧至少不包括主固定信道占用的下行子帧和辅固定信道占用的下行子帧。本申请实施例中所述的SIB占用的下行子帧均指有效下行子帧,即可以用于传输SIB的下行子帧。在所有的下行子帧中除了主固定信道和用于传输SIB的下行子帧之外的剩余下行子帧可以用于传输下行数据。It should be noted that, in a possible case, in addition to the primary fixed channel can be configured in the second period, a secondary fixed channel can be periodically configured on the data channel. For example, in the prior art, the SIBs are all sent in a second cycle. When the number of SIB repetitions is 16, the SIB needs to occupy 128 (16 * 8) ms consecutively, that is, 128 downlink subframes. Taking the uplink and downlink ratio of the data channel as 8 downlink subframes and 12 uplink subframes as an example, the duration of a data channel is 20ms and it takes 16 data channels to send the SIB, and the SIB needs to last 320 (16 * 20) ms. If the second cycle includes 7 secondary fixed channels, plus a primary fixed channel, and a total of 8 fixed channels are included in the second cycle, the fixed channel period is 160ms. When the SIB lasts for 320ms, 2 secondary fixed channels need to be skipped. Therefore, the actual service delay is 360ms. FIG. 7 is a schematic structural diagram of a SIB including a secondary fixed channel provided in the prior art. In this case, the downlink subframe that can be used to send the SIB does not include at least the downlink subframe occupied by the primary fixed channel and the downlink subframe occupied by the secondary fixed channel. The downlink subframes occupied by the SIB in the embodiments of the present application refer to valid downlink subframes, that is, downlink subframes that can be used to transmit SIBs. In all the downlink subframes, except for the main fixed channel and the downlink subframe used for transmitting the SIB, the remaining downlink subframes may be used for transmitting downlink data.
另外,由于辅固定信道周期或者主固定信道周期内的辅固定信道个数可能在SIB中配置,因此终端设备接收SIB时并不知道辅固定信道周期。本申请实施例提供一种可实现的方法是基站发送SIB时,按照固定信道可以支持的最小周期的方式进行资源预留,SIB只在非预留为固定信道占用的资源上发送,终端设备也是根据固定信道的最小周期预留方式进行SIB接收。例如,基站在一个第二周期内支持发送的辅固定信道个数为1、3或7(对应一个第二周期内固定信道个数为2、4或8),则终端设备在 接收SIB时假定一个第二周期内辅固定信道个数为7,即固定信道周期为160ms,只要为预留的固定信道资源,固定信道资源对应的下行子帧对于SIB来说为无效下行子帧。In addition, since the number of secondary fixed channels in the secondary fixed channel period or the primary fixed channel period may be configured in the SIB, the terminal device does not know the secondary fixed channel period when receiving the SIB. An embodiment of the present application provides an implementable method. When a base station sends an SIB, resource reservation is performed according to a minimum period that a fixed channel can support. The SIB is sent only on resources that are not reserved for the fixed channel. The terminal device is also The SIB reception is performed according to the minimum period reservation mode of the fixed channel. For example, if the number of auxiliary fixed channels supported by the base station in a second period is 1, 3, or 7 (corresponding to the number of fixed channels in a second period is 2, 4, or 8), the terminal device assumes that The number of auxiliary fixed channels in a second period is 7, that is, the fixed channel period is 160 ms. As long as it is a reserved fixed channel resource, the downlink subframe corresponding to the fixed channel resource is invalid for the SIB.
图8为本申请实施例提供的一种包含辅固定信道发送SIB的结构示意图。假设T1=2560ms,T2=1280ms,m=T1/T2=2,即第一周期内包含2个第二周期。一个第二周期内包含1个主固定信道和7个辅固定信道,即一个第二周期内包含8个固定信道。FIG. 8 is a schematic structural diagram of sending an SIB including a secondary fixed channel according to an embodiment of the present application. It is assumed that T1 = 2560ms, T2 = 1280ms, and m = T1 / T2 = 2, that is, the first period includes two second periods. A second period includes 1 primary fixed channel and 7 secondary fixed channels, that is, a second period includes 8 fixed channels.
当N=16时,时间单元的时长为160ms。相邻的固定信道周期为160ms,包括主固定信道和辅固定信道的周期,辅固定信道和辅固定信道的周期。可见,辅固定信道和主固定信道一样,占用了每个SIB时间单元的第一个信道,即每个SIB时间单元的前20ms。由于SIB可以从SIB所在的时间单元的起始时刻开始偏移40ms后发送,因此SIB和辅固定信道不会冲突。When N = 16, the duration of the time unit is 160 ms. The adjacent fixed channel period is 160 ms, including the period of the main fixed channel and the secondary fixed channel, and the period of the secondary fixed channel and the secondary fixed channel. It can be seen that, like the primary fixed channel, the secondary fixed channel occupies the first channel of each SIB time unit, that is, the first 20ms of each SIB time unit. Since the SIB can be sent after being offset 40ms from the start of the time unit where the SIB is located, the SIB and the secondary fixed channel will not conflict.
同理,当N=8、N=4、N=2或N=1时都可以从SIB所在的时间单元的起始时刻开始偏移40ms后发送再发送SIB,从而,SIB和辅固定信道不会冲突。In the same way, when N = 8, N = 4, N = 2, or N = 1, the SIB can be sent from the start of the time unit where the SIB is located and offset by 40ms, and then the SIB is sent. Therefore, the SIB and the auxiliary fixed channel are not Will conflict.
相似的,如果一个第二周期内包含3个辅固定信道,则相邻的固定信道周期为320ms。此时,只有部分辅固定信道与SIB的时间单元有交集。在辅固定信道与SIB的时间单元有交集的时间单元,辅固定信道和主固定信道一样,每个固定信道占用了每个SIB时间单元第一个信道,即每个SIB时间单元的前20ms。同理,也可以从SIB所在的时间单元的起始时刻开始偏移40ms后发送再发送SIB,从而,SIB和辅固定信道不会冲突。Similarly, if three secondary fixed channels are included in a second period, the adjacent fixed channel period is 320 ms. At this time, only some of the auxiliary fixed channels have an intersection with the time unit of the SIB. The secondary fixed channel and the SIB time unit have an intersection time unit. The secondary fixed channel is the same as the primary fixed channel. Each fixed channel occupies the first channel of each SIB time unit, that is, the first 20ms of each SIB time unit. In the same way, the SIB may be sent and then sent again after an offset of 40ms from the start of the time unit where the SIB is located, so that the SIB and the secondary fixed channel do not conflict.
由于在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移了预设偏移值的时刻,从而,有效地避开了辅固定信道所在的位置,进一步减小了SIB发送引起的业务时延,避免SIB与辅固定信道发送时间上的冲突。Since the start time of sending the SIB in each time unit is a time shifted from the start time of the time unit by a preset offset value, thereby effectively avoiding the position of the auxiliary fixed channel and further reducing The service delay caused by the SIB transmission is avoided, and the collision between the SIB and the secondary fixed channel transmission time is avoided.
在第二种可实现方式中,若在每个第二周期内每次发送的SIB认为占用一个时间单元,则在每个第二周期内发送的N/m次SIB可以占用N/m个时间单元。此外,在每个第二周期内N/m个时间单元可以是连续分布(集中分布)的,即N/m个时间单元连续发送。在每个时间单元内,每次发送的SIB占用连续的下行子帧。例如,每次发送的SIB可以占用连续的8个下行子帧。或者,在每个时间单元内,每次发送的SIB可以占用连续的4个下行子帧。在这种情况下,本申请实施例所述的时间单元的时长也可以复用NB-IoT系统中的定义。例如,若NB-IoT系统中定义时间单元的时长为160ms,在本申请实施例中无论SIB的重复次数是多少,时间单元的时长均可以认为是160ms。或者,时间单元的时长可以是根据发送SIB时SIB占用的数据信道个数和每个数据信道的信道时长确定的。例如,假设一个信道的信道时长为20毫秒,本次SIB发送占用4个数据信道,则时间单元的时长为80毫秒。若本次SIB发送占用2个数据信道,则时间单元的时长为40毫秒。可理解的,本申请实施例所述的时间单元的时长包括了发送SIB的发送时长。In the second implementable manner, if the SIB transmitted each time in each second cycle is considered to occupy one time unit, the N / m SIBs transmitted in each second cycle may occupy N / m times unit. In addition, the N / m time units may be continuously distributed (centrally distributed) in each second cycle, that is, the N / m time units are continuously transmitted. Within each time unit, each transmitted SIB occupies consecutive downlink subframes. For example, each transmitted SIB can occupy 8 consecutive downlink subframes. Or, in each time unit, each transmitted SIB may occupy 4 consecutive downlink subframes. In this case, the duration of the time unit described in the embodiments of the present application may also be multiplexed with the definition in the NB-IoT system. For example, if the duration of the time unit is defined in the NB-IoT system as 160 ms, in the embodiment of the present application, the duration of the time unit may be considered to be 160 ms regardless of the number of repetitions of the SIB. Alternatively, the duration of the time unit may be determined according to the number of data channels occupied by the SIB when sending the SIB and the channel duration of each data channel. For example, if the channel duration of one channel is 20 milliseconds, and the current SIB transmission occupies 4 data channels, the duration of the time unit is 80 milliseconds. If the current SIB transmission occupies 2 data channels, the duration of the time unit is 40 milliseconds. It can be understood that the duration of the time unit described in the embodiment of the present application includes the sending duration of sending the SIB.
示例的,假设T1=2560ms,T2=1280ms,m=T1/T2=2。如图9所示,分别以SIB的重复次数为16、8、4、2和1进行示意性说明。For example, suppose T1 = 2560ms, T2 = 1280ms, and m = T1 / T2 = 2. As shown in FIG. 9, the number of repetitions of the SIB is 16, 8, 4, 2, and 1, respectively.
当N=16时,每个第二周期内分别发送8次SIB,每个第二周期内发送的8次SIB占用8个时间单元,每次发送的SIB占用一个时间单元,8个时间单元在每个第二周 期内连续发送(连续分布)。When N = 16, 8 SIBs are sent in each second cycle. The 8 SIBs sent in each second cycle occupy 8 time units. The SIBs sent each time occupy a time unit. Continuously transmitted (continuously distributed) every second period.
当N=8时,每个第二周期内分别发送4次SIB,每个第二周期内发送的4次SIB占用4个时间单元,每次发送的SIB占用一个时间单元,4个时间单元在每个第二周期内连续发送(连续分布)。When N = 8, 4 SIBs are sent in each second period, 4 SIBs sent in each second period occupy 4 time units, and each SIB sent takes 1 time unit. The 4 time units are in Continuously transmitted (continuously distributed) every second period.
当N=4时,每个第二周期内分别发送2次SIB,每个第二周期内发送的2次SIB占用2个时间单元,每次发送的SIB占用一个时间单元,2个时间单元在每个第二周期内连续发送(连续分布)。When N = 4, two SIBs are sent in each second cycle. The two SIBs sent in each second cycle occupy two time units. Each time SIB is sent, one time unit is used. Continuously transmitted (continuously distributed) every second period.
当N=2时,每个第二周期内分别发送1次SIB,每个第二周期内发送的1次SIB占用1个时间单元。When N = 2, the SIB is sent once in each second cycle, and the SIB sent once in each second cycle occupies one time unit.
当N=1时,在第一周期内的第一个第一周期内发送1次SIB,在第一周期内的第二个第二周期内不发送SIB。When N = 1, the SIB is sent once in the first first period in the first period, and the SIB is not sent in the second second period in the first period.
另外,在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移预设偏移值的时刻。特别的,若在每个第二周期内N/m个时间单元连续发送,时间单元的时长为160ms,在每个时间单元内发送SIB的起始时刻为从时间单元的起始时刻开始偏移预设偏移值的时刻。对于预设偏移值的其他详细阐述可以参考第一种可实现方式中的描述,本申请实施例在此不再赘述。还有关于下行开销和辅固定信道等的其他详细阐述同样可以参考第一种可实现方式中的描述,本申请实施例在此不再赘述。In addition, the start time of sending the SIB for the first time in each second cycle is a time offset from the start time of the second cycle to which the first transmitted SIB belongs by a preset offset value. Specifically, if N / m time units are sent continuously in each second cycle, the time unit duration is 160ms, and the start time of sending the SIB in each time unit is offset from the start time of the time unit. The moment of the preset offset value. For other detailed descriptions of the preset offset value, reference may be made to the description in the first implementable manner, which is not repeated in the embodiment of the present application. For other detailed descriptions of downlink overhead and auxiliary fixed channels, etc., reference may also be made to the description in the first implementable manner, which is not repeatedly described in this embodiment of the present application.
与现有技术相比,在第一周期内重复发送的SIB在第二周期之间均匀分布,对于近距离覆盖终端,不需要等待一个第二周期后再接收SIB,减小了初始接入时延;并且从第二周期的起始时刻开始偏移预设偏移值之后,终端设备再接收SIB可以保证终端设备完整接收到第二周期内SIB的首次发送。但相对于第一种可实现方式,由于SIB的重复发送在第二周期内集中分布,对于在进行下行数据传输的远距离终端设备,下行数据传输可能多次被SIB发送中断,因此业务时延大于第一种可实现方式中的业务时延,但小于现有技术。Compared with the prior art, the SIBs repeatedly sent in the first cycle are evenly distributed between the second cycles. For short-range coverage terminals, there is no need to wait for a second cycle to receive SIBs, which reduces the initial access time. And after offsetting the preset offset value from the beginning of the second period, the terminal device receiving the SIB again can ensure that the terminal device completely receives the first transmission of the SIB in the second period. However, compared to the first achievable method, since the repeated transmission of SIBs is concentrated in the second period, for long-distance terminal equipment that is performing downlink data transmission, downlink data transmission may be interrupted by SIB transmission multiple times, so service delay It is larger than the service delay in the first implementable manner, but smaller than the prior art.
在第三种可实现方式中,在每个第二周期内N/m次SIB连续发送,此时,不存在上述第一种可实现方式和第二种可实现方式中所述的时间单元的概念了。每次发送的SIB可以占用连续的下行子帧。若每次发送的SIB可以占用连续的8个下行子帧,N/m次发送的SIB占用连续的N*8/m个下行子帧。若每次发送的SIB可以占用连续的4个下行子帧,N/m次发送的SIB占用连续的N*4/m个下行子帧。In the third implementation manner, N / m SIBs are continuously transmitted in each second period. At this time, there is no time unit described in the first implementation manner and the second implementation manner described above. Concept. Each transmitted SIB can occupy consecutive downlink subframes. If each transmitted SIB can occupy 8 consecutive downlink subframes, the N / m transmitted SIBs occupy consecutive N * 8 / m downlink subframes. If the SIB transmitted each time can occupy 4 consecutive downlink subframes, the SIB transmitted N / m times can occupy consecutive N * 4 / m downlink subframes.
示例的,假设T1=2560ms,T2=1280ms,m=T1/T2=2。如图10所示。当N=16时,每个第二周期内分别发送8次SIB,在每个第二周期内8次SIB连续发送(连续分布),8次发送的SIB占用连续的16*8/2=64个下行子帧。以一个数据信道时长为20ms,数据信道上下行配比为8个下行子帧和12个上行子帧为例,SIB持续时长为160ms,即增加的业务时延为160ms。For example, suppose T1 = 2560ms, T2 = 1280ms, and m = T1 / T2 = 2. As shown in Figure 10. When N = 16, 8 SIBs are sent in each second period, 8 SIBs are sent continuously (continuous distribution) in each second period, and the SIBs sent 8 times occupy a continuous 16 * 8/2 = 64 Downlink subframes. Taking the length of a data channel as 20ms and the uplink and downlink ratio of the data channel as 8 downlink subframes and 12 uplink subframes as an example, the duration of the SIB is 160ms, that is, the increased service delay is 160ms.
如图11所示,当N=8时,每个第二周期内分别发送4次SIB,在每个第二周期内4次SIB连续发送(连续分布),4次发送的SIB占用连续的8*8/2=32个下行子帧。以一个数据信道时长为20ms,数据信道上下行配比为8个下行子帧和12个上行子帧为例,SIB持续时长为80ms,即增加的业务时延为80ms。As shown in Figure 11, when N = 8, 4 SIBs are sent in each second cycle, 4 SIBs are sent continuously (continuous distribution) in each second cycle, and the SIBs sent 4 times occupy 8 consecutive times. * 8/2 = 32 downlink subframes. Taking a data channel with a duration of 20ms and an uplink and downlink ratio of the data channel with 8 downlink subframes and 12 uplink subframes as an example, the duration of the SIB is 80ms, that is, the increased service delay is 80ms.
如图12所示,当N=4时,每个第二周期内分别发送2次SIB,在每个第二周期内2次SIB连续发送(连续分布),2次发送的SIB占用连续的4*8/2=16个下行子帧。以一个数据信道时长为20ms,数据信道上下行配比为8个下行子帧和12个上行子帧为例,SIB持续时长为40ms,即增加的业务时延为40ms。As shown in FIG. 12, when N = 4, the SIB is transmitted twice in each second cycle, and the SIB is transmitted continuously (continuously) twice in each second cycle. The SIB transmitted twice occupies 4 consecutive times. * 8/2 = 16 downlink subframes. Taking a data channel with a duration of 20ms and an uplink and downlink ratio of the data channel with 8 downlink subframes and 12 uplink subframes as an example, the duration of the SIB is 40ms, that is, the increased service delay is 40ms.
如图13所示,当N=2时,每个第二周期内分别发送1次SIB,在每个第二周期内1次SIB连续发送(连续分布),1次发送的SIB占用连续的2*8/2=8个下行子帧。以一个数据信道时长为20ms,数据信道上下行配比为8个下行子帧和12个上行子帧为例,SIB持续时长为20ms,即增加的业务时延为20ms。As shown in FIG. 13, when N = 2, the SIB is sent once in each second cycle, and the SIB is sent continuously (continuously distributed) once in each second cycle. * 8/2 = 8 downlink subframes. Taking a data channel with a duration of 20ms and an uplink and downlink ratio of the data channel with 8 downlink subframes and 12 uplink subframes as an example, the duration of the SIB is 20ms, that is, the increased service delay is 20ms.
对于N=1时,N小于m,在第一周期内的第一个第二周期内发送1次SIB,在第一周期内的第二个第二周期内不发送SIB。在第一周期内的第一个第二周期内1次SIB连续发送(连续分布),1次发送的SIB占用连续的1*8=8个下行子帧。For N = 1, N is less than m, and the SIB is sent once in the first second period in the first period, and the SIB is not sent in the second second period in the first period. In the first and second cycle of the first cycle, the SIB is continuously transmitted once (continuously distributed), and the SIB transmitted once occupies consecutive 1 * 8 = 8 downlink subframes.
在每个第二周期内第一次发送SIB的起始时刻为从第一次发送的SIB所属的第二周期的起始时刻开始偏移预设偏移值的时刻。对于预设偏移值的其他详细阐述可以参考第一种可实现方式中的描述,本申请实施例在此不再赘述。还有关于下行开销和辅固定信道等的其他详细阐述同样可以参考第一种可实现方式中的描述,本申请实施例在此不再赘述。The start time of transmitting the SIB for the first time in each second cycle is a time offset from the start time of the second cycle to which the first transmitted SIB belongs by a preset offset value. For other detailed descriptions of the preset offset value, reference may be made to the description in the first implementable manner, which is not repeated in the embodiment of the present application. For other detailed descriptions of downlink overhead and auxiliary fixed channels, etc., reference may also be made to the description in the first implementable manner, which is not repeatedly described in this embodiment of the present application.
下面对上述描述进行举例说明。图14为本申请实施例提供的再一种发送SIB的结构示意图。如图14所示,假设第二周期时长为1280ms,第二周期包括64个信道,64个信道的时长均为20ms。每个信道包括20个子帧,一个子帧的时长为1ms。第一个信道作为用于传输同步信号和MIB的主固定信道,即主固定信道时长为20ms。剩余的信道作为用于传输上行数据和下行数据的数据信道。一个数据信道中前2个子帧用于传输下行数据,后18个子帧用于传输上行数据,即数据信道的上下行配比为2个下行子帧和18个上行子帧。在当前第二周期中的第一个发送SIB的子帧位置相对当前第二周期的起始时刻偏移了主固定信道时长和一个数据信道时长,即40ms。在当前第二周期内重复发送8次SIB,每次发送的SIB占用连续的8个下行子帧,则在当前第二周期内SIB需要占用连续的64个下行子帧。一个数据信道包括2个下行子帧,则在当前第二周期内发送SIB共占用32个数据信道的下行子帧,在当前第二周期内发送SIB的时长为640ms。其他数据信道包括的下行子帧用于传输下行数据。此时,由于SIB发送引起的业务时延至少为640ms。The above description is exemplified below. FIG. 14 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application. As shown in FIG. 14, it is assumed that the duration of the second cycle is 1280 ms, the second cycle includes 64 channels, and the duration of the 64 channels is 20 ms. Each channel includes 20 subframes, and the duration of one subframe is 1ms. The first channel is used as the main fixed channel for transmitting synchronization signals and MIBs, that is, the duration of the main fixed channel is 20ms. The remaining channels are used as data channels for transmitting uplink data and downlink data. The first 2 subframes in a data channel are used to transmit downlink data, and the last 18 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 2 downlink subframes and 18 uplink subframes. The position of the first subframe in the current second period to send the SIB is offset from the start time of the current second period by the length of the main fixed channel and the length of one data channel, that is, 40 ms. In the current second cycle, the SIB is repeatedly transmitted 8 times, and each transmitted SIB occupies 8 consecutive downlink subframes. In the current second cycle, the SIB needs to occupy 64 consecutive downlink subframes. A data channel includes two downlink subframes, so sending a SIB in the current second cycle occupies a total of 32 downlink channels in the data channel, and the duration of sending the SIB in the current second cycle is 640ms. Downlink subframes included in other data channels are used to transmit downlink data. At this time, the service delay caused by the SIB transmission is at least 640ms.
需要说明的是,根据数据信道中上下行子帧配比的不同,在当前第二周期内发送SIB共占用的数据信道个数也不同。例如,如图15所示,假设一个数据信道中前8个子帧用于传输下行数据,后12个子帧用于传输上行数据,即数据信道的上下行配比为8个下行子帧和12上行子帧。在当前第二周期内SIB需要占用连续的64个下行子帧的情况下,一个数据信道包括8个下行子帧,则在当前第二周期内发送SIB共占用8个数据信道的下行子帧,在当前第二周期内发送SIB的时长为160ms。其他数据信道包括的下行子帧用于传输下行数据。此时,由于SIB发送引起的业务时延至少为160ms。It should be noted that, according to different uplink-downlink sub-frame ratios in the data channel, the number of data channels shared by the sending SIB in the current second cycle is also different. For example, as shown in FIG. 15, it is assumed that the first 8 subframes in a data channel are used to transmit downlink data, and the last 12 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 8 downlink subframes and 12 uplinks. Subframe. In the case that the SIB needs to occupy 64 consecutive downlink subframes in the current second cycle, and one data channel includes 8 downlink subframes, then sending the SIB in the current second cycle consumes a total of 8 downlink downlink subframes, The duration of sending the SIB in the current second cycle is 160ms. Downlink subframes included in other data channels are used to transmit downlink data. At this time, the service delay caused by the SIB transmission is at least 160ms.
与现有技术相比,在第一周期内重复发送的SIB在第二周期之间均匀分布,在第二周期内集中分布,对于近距离覆盖终端,不需要等待一个第二周期后再接收SIB,减小了初始接入时延;并且从第二周期的起始时刻开始偏移预设偏移值之后,终端设 备再接收SIB可以保证终端设备完整接收到第二周期内SIB的首次发送。但相对于第一种可实现方式,由于SIB的重复发送在第二周期内集中分布,对于在进行下行数据传输的远距离终端设备,下行数据传输可能多次被SIB发送中断,因此业务时延大于第一种可实现方式中的业务时延,但小于现有技术。Compared with the prior art, the SIBs repeatedly sent in the first cycle are evenly distributed between the second cycles and concentratedly distributed in the second cycle. For short-range coverage terminals, there is no need to wait for a second cycle to receive SIBs. , Reducing the initial access delay; and after offsetting the preset offset value from the beginning of the second period, the terminal device receiving the SIB again can ensure that the terminal device completely receives the first transmission of the SIB in the second period. However, compared to the first achievable method, since the repeated transmission of SIBs is concentrated in the second period, for long-distance terminal equipment that is performing downlink data transmission, downlink data transmission may be interrupted by SIB transmission multiple times, so service delay It is larger than the service delay in the first implementable manner, but smaller than the prior art.
在第四种可实现方式中,若在每个第二周期内每次发送的SIB认为占用一个时间单元,则在每个第二周期内发送的N/m次SIB可以占用N/m个时间单元。当N大于或等于m时,时间单元的时长为T2*m/N。当N小于m时,时间单元的时长可以为T1/m。与第一种可实现方式的区别在于,在每个时间单元内,SIB可以是均匀分布的,即每次SIB发送所占用的p个下行子帧在每个所属时间单元内均匀分布,p为大于0的正整数。例如,每次发送的SIB可以占用8个下行子帧,在该次发送SIB占用的时间单元内SIB发送所占用的8个下行子帧在每个所属时间单元内均匀分布。或者,在每个时间单元内,每次发送的SIB可以占用4个下行子帧,在该次发送SIB占用的时间单元内SIB发送所占用的4个下行子帧在每个所属时间单元内均匀分布。另外,根据上述各个实施例的阐述可知,在实际应用中,为了保证第二周期内每个SIB能够完整接收,在第二周期内的每个时间单元中首次发送SIB的起始时刻相对于当前时间单元的起始时刻需要根据预设偏移值从当前时间单元的起始时刻偏移一段时长后再发送SIB。因此,在时间单元内用于发送SIB的子帧可以在当前时间单元的起始时刻偏移预设偏移值后的剩余时长内均分分布。In a fourth implementable manner, if the SIB sent each time in each second cycle is considered to occupy one time unit, the N / m SIBs sent in each second cycle may occupy N / m times unit. When N is greater than or equal to m, the duration of the time unit is T2 * m / N. When N is less than m, the duration of the time unit may be T1 / m. The difference from the first implementation is that in each time unit, the SIB can be evenly distributed, that is, the p downlink subframes occupied by each SIB transmission are evenly distributed in each of the time units to which it belongs. P is A positive integer greater than 0. For example, each transmitted SIB may occupy 8 downlink subframes, and the 8 downlink subframes occupied by SIB transmission within the time unit occupied by the transmission of the SIB are evenly distributed within each time unit to which they belong. Or, in each time unit, the SIB transmitted each time can occupy 4 downlink subframes, and the 4 downlink subframes occupied by the SIB transmission in the time unit occupied by the transmission of the SIB are even in each time unit to which they belong. distributed. In addition, according to the descriptions of the foregoing embodiments, in actual applications, in order to ensure that each SIB can be completely received in the second cycle, the start time of the first SIB transmission in each time unit in the second cycle is relative to the current time. The start time of the time unit needs to be shifted from the start time of the current time unit for a period of time according to a preset offset value before sending the SIB. Therefore, the subframes used to send the SIB in the time unit can be distributed evenly within the remaining time after the start time of the current time unit is offset from the preset offset value.
示例的,假设T1=2560ms,T2=1280ms,m=T1/T2=2,即第一周期内包含2个第二周期。For example, suppose T1 = 2560ms, T2 = 1280ms, and m = T1 / T2 = 2, that is, the first period includes two second periods.
如图16所示,当N=16时,每个第二周期内分别发送8次SIB,并且8次发送的SIB在第二周期内均匀分布,即每个第二周期内包含8个时间单元,8个时间单元在每个第二周期内均匀分布。时间单元的时长为:T3=T2*m/N=1280*2/16=160ms。另外,假设主固定信道时长和数据信道时长均为20ms,预设偏移值为40ms,即偏移了一个主固定信道时长和一个数据信道时长,p=6。对于每次发送SIB占用的起始子帧为从SIB所属时间单元的起始时刻开始偏移预设偏移值之后的第一个有效下行子帧,则在每个时间单元内每个((T2*m/N)-T6)/p时长内至少包含1个下行子帧用于发送SIB。其中,T6表示预设偏移值。在每个时间单元内的((T2*m/N)-T6)/p=((1280*2/16)-40)/6=20ms内包括1个下行子帧用于发送SIB。此时,SIB发送所占用的6个下行子帧在每个所属时间单元内均匀分布时,在一个时间单元中能够用于传输SIB的信道个数等于传输一次SIB需要占用的下行子帧个数。As shown in FIG. 16, when N = 16, 8 SIBs are sent in each second cycle, and the SIBs sent 8 times are evenly distributed in the second cycle, that is, each second cycle contains 8 time units , 8 time units are evenly distributed in each second cycle. The duration of the time unit is: T3 = T2 * m / N = 1280 * 2/16 = 160ms. In addition, it is assumed that the duration of the primary fixed channel and the duration of the data channel are both 20 ms, and the preset offset value is 40 ms, that is, one primary fixed channel duration and one data channel duration are offset, p = 6. For the starting sub-frame occupied by each transmission of the SIB is the first valid downlink sub-frame after the preset offset value is offset from the start time of the time unit to which the SIB belongs, each ((( T2 * m / N) -T6) / p duration includes at least one downlink subframe for sending SIB. Among them, T6 represents a preset offset value. ((T2 * m / N) -T6) / p = ((1280 * 2/16) -40) / 6 = 20ms in each time unit includes 1 downlink subframe for sending SIB. At this time, when the 6 downlink subframes occupied by the SIB transmission are evenly distributed in each time unit to which they belong, the number of channels that can be used to transmit the SIB in one time unit is equal to the number of downlink subframes required to transmit the SIB once. .
如图17所示,当N=8时,每个第二周期内分别发送4次SIB,并且4次发送的SIB在第二周期内均匀分布,即每个第二周期内包含4个时间单元,4个时间单元在每个第二周期内均匀分布。时间单元的时长为:T3=1280*2/8=320ms。另外,假设主固定信道时长和数据信道时长均为40ms,预设偏移值为80ms,即偏移了一个主固定信道时长和一个数据信道时长,p=6,在每个时间单元内的((T2*m/N)-T6)/p=((1280*2/8)-80)/6=40ms内包括1个下行子帧用于发送SIB。此时,SIB发送所占用的6个下行子帧在每个所属时间单元内均匀分布时,在一个时间单元中能够用于传输SIB的信道个数等于传输一次SIB需要占用的下行子帧个数。As shown in Figure 17, when N = 8, 4 SIBs are sent in each second cycle, and the SIBs sent 4 times are evenly distributed in the second cycle, that is, each second cycle contains 4 time units , 4 time units are evenly distributed in each second cycle. The duration of the time unit is: T3 = 1280 * 2/8 = 320ms. In addition, it is assumed that the length of the main fixed channel and the length of the data channel are both 40ms, and the preset offset value is 80ms, that is, one main fixed channel duration and one data channel duration are offset, p = 6, in each time unit ( (T2 * m / N) -T6) / p = ((1280 * 2/8) -80) / 6 = 40ms includes 1 downlink subframe for sending SIB. At this time, when the 6 downlink subframes occupied by the SIB transmission are evenly distributed in each time unit to which they belong, the number of channels that can be used to transmit the SIB in one time unit is equal to the number of downlink subframes required to transmit the SIB once. .
如图18所示,当N=4时,每个第二周期内分别发送2次SIB,并且2次发送的SIB在第二周期内均匀分布,即每个第二周期内包含2个时间单元,2个时间单元在每个第二周期内均匀分布。时间单元的时长为:T3=1280*2/4=640ms。另外,假设主固定信道时长和数据信道时长均为20ms,预设偏移值为40ms,即偏移了一个主固定信道时长和一个数据信道时长,p=8。由于偏移后时间单元内的剩余时长为600ms,SIB发送所占用的8个下行子帧在600ms内无法均匀分配,此时,为了使SIB发送所占用的8个下行子帧在所属时间单元内剩余的600ms内均匀分布,可以在偏移后时间单元内的剩余600ms的前400ms内均匀分布SIB发送所占用的8个下行子帧。例如,在偏移后时间单元内的剩余600ms的前400ms内的每100ms发送2个下行子帧,2个下行子帧可以是同一个信道中的下行子帧。100ms包括5个信道。As shown in FIG. 18, when N = 4, SIBs are sent twice in each second cycle, and the SIBs sent twice are evenly distributed in the second cycle, that is, each second cycle includes 2 time units. , 2 time units are evenly distributed in each second cycle. The duration of the time unit is: T3 = 1280 * 2/4 = 640ms. In addition, it is assumed that the duration of the primary fixed channel and the duration of the data channel are both 20 ms, and the preset offset value is 40 ms, that is, one primary fixed channel duration and one data channel duration are offset, p = 8. Because the remaining time in the time unit after the offset is 600ms, the 8 downlink subframes occupied by the SIB transmission cannot be evenly distributed within 600ms. At this time, in order to make the 8 downlink subframes occupied by the SIB transmission within the time unit to which it belongs The remaining 600ms are evenly distributed, and the 8 downlink subframes occupied by the SIB transmission can be evenly distributed within the first 400ms of the remaining 600ms within the time unit after the offset. For example, two downlink subframes are sent every 100 ms within the first 400 ms of the remaining 600 ms in the time unit after the offset, and the two downlink subframes may be downlink subframes in the same channel. 100ms includes 5 channels.
如图19所示,当N=2时,每个第二周期内分别发送1次SIB,即每个第二周期内包含1个时间单元。时间单元的时长为:T3=1280*2/2=1280ms。另外,假设主固定信道时长和数据信道时长均为40ms,预设偏移值为80ms,即偏移了一个主固定信道时长和一个数据信道时长,p=4。由于偏移后时间单元内的剩余时长为1200ms,SIB发送所占用的4个下行子帧在1200ms内无法均匀分配,此时,为了使SIB发送所占用的4个下行子帧在所属时间单元内剩余的1200ms内均匀分布,可以在偏移后时间单元内的剩余1200ms的前1120ms(28信道)内均匀分布SIB发送所占用的4个下行子帧。例如,在偏移后时间单元内的剩余1200ms的前1120ms内的每280ms发送1个下行子帧。280ms包括7个信道。在每个7个信道中的第一个信道内的第一个下行子帧用于发送SIB。As shown in FIG. 19, when N = 2, the SIB is sent once in each second cycle, that is, each second cycle includes one time unit. The duration of the time unit is: T3 = 1280 * 2/2 = 1280ms. In addition, it is assumed that the duration of the primary fixed channel and the duration of the data channel are both 40 ms, and the preset offset value is 80 ms, that is, one primary fixed channel duration and one data channel duration are offset, p = 4. Because the remaining time in the time unit after the offset is 1200ms, the 4 downlink subframes occupied by SIB transmission cannot be evenly distributed within 1200ms. At this time, in order to make the 4 downlink subframes occupied by SIB transmission within the time unit to which it belongs The remaining 1200ms are evenly distributed, and the 4 downlink subframes occupied by SIB transmission can be evenly distributed within the first 1120ms (28 channels) of the remaining 1200ms in the time unit after the offset. For example, one downlink subframe is sent every 280ms within the first 1120ms of the remaining 1200ms in the time unit after the offset. 280ms includes 7 channels. The first downlink subframe in the first channel of each of the 7 channels is used to send the SIB.
当N=1时,N小于m,在第一周期内的第一个第二周期内发送1次SIB,在第一周期内的第二个第二周期内不发送SIB。时间单元的时长为:T3=2560/2=1280ms。在时间单元内的描述可以参考N=2的描述。When N = 1, N is less than m, and the SIB is sent once in the first second period in the first period, and the SIB is not sent in the second second period in the first period. The duration of the time unit is: T3 = 2560/2 = 1280ms. For descriptions in time units, refer to the description of N = 2.
下面对上述描述进行举例说明。图20为本申请实施例提供的再一种发送SIB的结构示意图。如图20所示,假设第二周期时长为1280ms,时间单元的时长为160ms。一个时间单元包括8个信道。8个信道的时长均为20ms。每个信道包括20个子帧,一个子帧的时长为1ms。第一个信道作为用于传输同步信号和MIB的主固定信道,即主固定信道时长为20ms。剩余的7个信道作为用于传输上行数据和下行数据的数据信道,每个数据信道的时长为20ms。一个数据信道中前2个子帧用于传输下行数据,后18个子帧用于传输上行数据,即数据信道的上下行配比为2个下行子帧和18个上行子帧。在当前时间单元中的第一个发送SIB的子帧位置相对当前时间单元的起始时刻偏移了主固定信道时长和一个数据信道时长,即40ms。在当前时间单元内发送SIB需要占用8个下行子帧的情况下,一个数据信道包括2个下行子帧,则在当前时间单元内的后6个数据信道中的每个数据信道的第一个下行子帧用于发送SIB,再选取后6个数据信道中的任意2个数据信道中的第二个下行子帧用于发送剩余的2个SIB,则在每个时间单元内偏移预设偏移值后的每个20ms内至少包括1个下行子帧用于发送SIB。此时,由于SIB发送引起的业务时延至少为40ms。The above description is exemplified below. FIG. 20 is a schematic structural diagram of still another SIB transmission according to an embodiment of the present application. As shown in FIG. 20, it is assumed that the duration of the second cycle is 1280 ms and the duration of the time unit is 160 ms. One time unit includes 8 channels. The length of the eight channels is 20ms. Each channel includes 20 subframes, and the duration of one subframe is 1ms. The first channel is used as the main fixed channel for transmitting synchronization signals and MIBs, that is, the duration of the main fixed channel is 20ms. The remaining 7 channels are used as data channels for transmitting uplink data and downlink data, and the duration of each data channel is 20ms. The first 2 subframes in a data channel are used to transmit downlink data, and the last 18 subframes are used to transmit uplink data, that is, the uplink and downlink ratio of the data channel is 2 downlink subframes and 18 uplink subframes. The position of the first subframe in the current time unit to send the SIB is offset from the start time of the current time unit by the duration of the main fixed channel and the duration of one data channel, that is, 40 ms. In the case that sending the SIB in the current time unit requires 8 downlink subframes, one data channel includes 2 downlink subframes, then the first of each of the last 6 data channels in the current time unit The downlink sub-frame is used to send the SIB, and then the second downlink sub-frame in any two data channels of the last 6 data channels is selected to send the remaining 2 SIBs, and the offset is preset in each time unit Each 20ms after the offset value includes at least one downlink subframe for sending the SIB. At this time, the service delay caused by the SIB transmission is at least 40ms.
需要说明的是,上述实施例中所述的SIB传输方法可以组合使用。比如,若在每个第二周期内每次发送的SIB认为占用一个时间单元,则在每个第二周期内发送的 N/m次SIB可以占用N/m个时间单元。在每个第二周期内N/m个时间单元可以均匀分布的,也可以是连续分布(集中分布)的,即N/m个时间单元连续发送,在每个时间单元内,SIB可以是连续分布的,也可以是均匀分布的。It should be noted that the SIB transmission methods described in the above embodiments may be used in combination. For example, if the SIB transmitted each time in each second cycle is considered to occupy one time unit, the N / m SIBs transmitted in each second cycle may occupy N / m time units. In each second period, N / m time units can be evenly distributed or continuous (centralized), that is, N / m time units are sent continuously. In each time unit, the SIB can be continuous. Distributed or evenly distributed.
S302、终端设备在时域上的第一周期中接收N次SIB。S302. The terminal device receives N SIBs in the first cycle in the time domain.
终端设备在时域上的第一周期中接收N次SIB方式可以参考S301中关于N次SIB重复发送方式的阐述,本申请实施例在此不再赘述。For the manner in which the terminal device receives N times of SIBs in the first period in the time domain, reference may be made to the description of the N times of repeated SIB sending manners in S301, which is not repeated in the embodiment of this application.
另外,基站在时域上的第一周期中重复发送N次SIB之前,需要向终端设备发送同步信号和MIB。如图21所示,本申请实施例还可以包括以下步骤。In addition, the base station needs to send a synchronization signal and a MIB to the terminal device before sending the SIB repeatedly N times in the first period in the time domain. As shown in FIG. 21, the embodiment of the present application may further include the following steps.
S303、基站采用固定信道向终端设备发送同步信号和主信息块。S303. The base station sends the synchronization signal and the main information block to the terminal device by using a fixed channel.
S304、终端设备在固定信道上接收同步信号和主信息块。S304. The terminal device receives a synchronization signal and a main information block on a fixed channel.
在终端设备接收到同步信号和主信息块,以及SIB后与基站同步,并执行随机接入后,便可以与基站进行通信。After the terminal device receives the synchronization signal and the main information block, and synchronizes with the base station after performing the SIB and performs random access, it can communicate with the base station.
需要说明的是,本申请实施例中对固定信道、主固定信道、辅固定信道和数据信道的名称不作限定。图22、图23和图24为本申请实施例提供的NB-IoT-U的三种帧结构示意图。在图22、图23和图24中所示的主固定信道也可以称为主固定信道段(primary anchor channel segment)或主固定段(primary anchor segment)或固定段(anchor segment)。辅固定信道也可以称为辅固定信道段(secondary anchor channel segment)或辅固定段(secondary anchor segment)。数据信道也可以称为数据信道段(data channel segment)或数据段(data segment)。It should be noted that the names of the fixed channel, the primary fixed channel, the secondary fixed channel, and the data channel are not limited in the embodiments of the present application. FIG. 22, FIG. 23 and FIG. 24 are schematic diagrams of three frame structures of the NB-IoT-U provided by the embodiments of the present application. The primary fixed channel shown in FIG. 22, FIG. 23, and FIG. 24 may also be referred to as a primary fixed channel segment (primary anchor channel segment) or a primary fixed segment (or anchor segment) or fixed segment (anchor segment). The secondary fixed channel can also be referred to as a secondary fixed channel segment or a secondary fixed segment. A data channel can also be referred to as a data channel segment (data channel segment) or a data segment (data segment).
另外,在跳频系统中,对于本申请实施例所述的信道、数据信道、主固定信道、辅固定信道和固定信道中任意一种所谓的信道均可以理解为每次跳频占用的不同的信道。而对于非跳频系统,比如ETSI法规中,并不要求上下行跳频,一个固定段可以称作一个信道,且数据段中的每个数据帧可以称作一个信道。信道个数也可以理解为数据帧个数。所述一个数据帧(data frame)是指数据段中每个具有独立上下行的时间单元构成一个数据帧。需要说明的是,数据段也可以指固定信道周期内除了主固定段和辅固定段之外的所有数据帧的统称,也可以指一个数据帧,当数据段指一个数据帧时,数据段和数据帧可以互换。各个信道的信道时长也可以预先配置,也可以通过MIB配置,可以是20ms或40ms。In addition, in the frequency hopping system, any of the so-called channels of the channels, data channels, primary fixed channels, secondary fixed channels, and fixed channels described in the embodiments of the present application can be understood as different occupations for each frequency hopping. channel. For non-frequency hopping systems, such as ETSI regulations, uplink and downlink frequency hopping are not required. A fixed segment can be called a channel, and each data frame in a data segment can be called a channel. The number of channels can also be understood as the number of data frames. The one data frame means that each time unit in the data segment with independent uplink and downlink forms a data frame. It should be noted that the data segment can also refer to all data frames in the fixed channel period except the main fixed segment and the secondary fixed segment. It can also refer to a data frame. When the data segment refers to a data frame, the data segment and Data frames are interchangeable. The channel duration of each channel can also be pre-configured or configured through MIB, which can be 20ms or 40ms.
上述主要从各个网元之间交互的角度对本申请实施例提供的方案进行了介绍。可以理解的是,各个网元,例如基站、终端设备为了实现上述功能,其包含了执行各个功能相应的硬件结构和/或软件模块。本领域技术人员应该很容易意识到,结合本文中所公开的实施例描述的各示例的算法步骤,本申请能够以硬件或硬件和计算机软件的结合形式来实现。某个功能究竟以硬件还是计算机软件驱动硬件的方式来执行,取决于技术方案的特定应用和设计约束条件。专业技术人员可以对每个特定的应用来使用不同方法来实现所描述的功能,但是这种实现不应认为超出本申请的范围。The above mainly introduces the solution provided by the embodiment of the present application from the perspective of interaction between various network elements. It can be understood that, in order to implement the above functions, each network element, such as a base station and a terminal device, includes a hardware structure and / or a software module corresponding to each function. Those skilled in the art should easily realize that, in combination with the algorithm steps of the examples described in the embodiments disclosed herein, this application can be implemented in hardware or a combination of hardware and computer software. Whether a certain function is performed by hardware or computer software-driven hardware depends on the specific application and design constraints of the technical solution. A professional technician can use different methods to implement the described functions for each specific application, but such implementation should not be considered to be beyond the scope of this application.
本申请实施例可以根据上述方法示例对基站、终端设备进行功能模块的划分,例如,可以对应各个功能划分各个功能模块,也可以将两个或两个以上的功能集成在一个处理模块中。上述集成的模块既可以采用硬件的形式实现,也可以采用软件功能模块的形式实现。需要说明的是,本申请实施例中对模块的划分是示意性的,仅仅为一 种逻辑功能划分,实际实现时可以有另外的划分方式。In the embodiment of the present application, functional modules may be divided into base stations and terminal devices according to the foregoing method examples. For example, each functional module may be divided corresponding to each function, or two or more functions may be integrated into one processing module. The above integrated modules can be implemented in the form of hardware or software functional modules. It should be noted that the division of the modules in the embodiments of the present application is schematic, and is only a logical function division. In actual implementation, there may be another division manner.
在采用对应各个功能划分各个功能模块的情况下,图25示出了上述和实施例中涉及的基站的一种可能的组成示意图,该基站能执行本申请各方法实施例中任一方法实施例中基站所执行的步骤。如图25所示,该基站可以包括:发送单元2501。In the case where each functional module is divided according to each function, FIG. 25 shows a schematic diagram of a possible composition of the base station involved in the foregoing and embodiments. The base station can execute any method embodiment of each method embodiment of the present application. Steps performed by the base station. As shown in FIG. 25, the base station may include: a sending unit 2501.
其中,发送单元2501,用于支持基站执行图3所示的SIB传输方法中的S301,图21所示的SIB传输方法中的S301和S303。The sending unit 2501 is configured to support the base station to perform S301 in the SIB transmission method shown in FIG. 3 and S301 and S303 in the SIB transmission method shown in FIG. 21.
在本申请实施例中,进一步的,如图25所示,该基站还可以包括:处理单元2502和接收单元2503。In the embodiment of the present application, further, as shown in FIG. 25, the base station may further include a processing unit 2502 and a receiving unit 2503.
需要说明的是,上述方法实施例涉及的各步骤的所有相关内容均可以援引到对应功能模块的功能描述,在此不再赘述。It should be noted that all relevant content of each step involved in the foregoing method embodiments can be referred to the functional description of the corresponding functional module, and will not be repeated here.
本申请实施例提供的基站,用于执行上述SIB传输方法,因此可以达到与上述SIB传输方法相同的效果。The base station provided in the embodiment of the present application is configured to execute the above-mentioned SIB transmission method, and thus can achieve the same effect as the above-mentioned SIB transmission method.
图26为本申请实施例提供的一种设备的组成示意图,如图26所示,设备可以包括至少一个处理器2601,存储器2602、收发器2603、总线2604。FIG. 26 is a schematic structural diagram of a device according to an embodiment of the present application. As shown in FIG. 26, the device may include at least one processor 2601, a memory 2602, a transceiver 2603, and a bus 2604.
下面结合图26对设备的各个构成部件进行具体的介绍:The following describes each component of the device in detail with reference to FIG. 26:
处理器2601是设备的控制中心,可以是一个处理器,也可以是多个处理元件的统称。例如,处理器2601是一个中央处理器(Central Processing Unit,CPU),也可以是特定集成电路(Application Specific Integrated Circuit,ASIC),或者是被配置成实施本申请实施例的一个或多个集成电路,例如:一个或多个微处理器(Digital Signal Processor,DSP),或,一个或者多个现场可编程门阵列(Field Programmable Gate Array,FPGA)。The processor 2601 is a control center of the device, and may be a processor or a collective name of multiple processing elements. For example, the processor 2601 is a central processing unit (CPU), may also be a specific integrated circuit (Application Specific Integrated Circuit, ASIC), or one or more integrated circuits configured to implement the embodiments of the present application. For example, one or more microprocessors (Digital Signal Processor, DSP), or one or more Field Programmable Gate Array (FPGA).
其中,处理器2601可以通过运行或执行存储在存储器2602内的软件程序,以及调用存储在存储器2602内的数据,执行设备的各种功能。The processor 2601 may execute various functions of the device by running or executing software programs stored in the memory 2602 and calling data stored in the memory 2602.
在具体的实现中,作为一种实施例,处理器2601可以包括一个或多个CPU,例如图26中所示的CPU0和CPU1。In a specific implementation, as an embodiment, the processor 2601 may include one or more CPUs, such as CPU0 and CPU1 shown in FIG. 26.
在具体实现中,作为一种实施例,设备可以包括多个处理器,例如图26中所示的处理器2601和处理器2605。这些处理器中的每一个可以是一个单核处理器(single-CPU),也可以是一个多核处理器(multi-CPU)。这里的处理器可以指一个或多个设备、电路、和/或用于处理数据(例如计算机程序指令)的处理核。In a specific implementation, as an embodiment, the device may include multiple processors, such as the processor 2601 and the processor 2605 shown in FIG. 26. Each of these processors can be a single-core processor (single-CPU) or a multi-core processor (multi-CPU). A processor herein may refer to one or more devices, circuits, and / or processing cores for processing data (such as computer program instructions).
存储器2602可以是只读存储器(Read-Only Memory,ROM)或可存储静态信息和指令的其他类型的静态存储设备,随机存取存储器(Random Access Memory,RAM)或者可存储信息和指令的其他类型的动态存储设备,也可以是电可擦可编程只读存储器(Electrically Erasable Programmable Read-Only Memory,EEPROM)、只读光盘(Compact Disc Read-Only Memory,CD-ROM)或其他光盘存储、光碟存储(包括压缩光碟、激光碟、光碟、数字通用光碟、蓝光光碟等)、磁盘存储介质或者其他磁存储设备、或者能够用于携带或存储具有指令或数据结构形式的期望的程序代码并能够由计算机存取的任何其他介质,但不限于此。存储器2602可以是独立存在,通过总线2604与处理器2601相连接。存储器2602也可以和处理器2601集成在一起。The memory 2602 may be a read-only memory (ROM) or other types of static storage devices that can store static information and instructions, a random access memory (Random Access Memory, RAM), or other types that can store information and instructions The dynamic storage device can also be Electrically Erasable Programmable Read-Only Memory (EEPROM), Compact Disc (Read-Only Memory, CD-ROM) or other optical disk storage, optical disk storage (Including compact discs, laser discs, optical discs, digital versatile discs, Blu-ray discs, etc.), disk storage media or other magnetic storage devices, or can be used to carry or store desired program code in the form of instructions or data structures and can be used by a computer Any other media accessed, but not limited to this. The memory 2602 may exist independently, and is connected to the processor 2601 through a bus 2604. The memory 2602 may also be integrated with the processor 2601.
其中,存储器2602用于存储执行本申请方案的软件程序,并由处理器2601来控 制执行。The memory 2602 is configured to store a software program that executes the solution of the present application, and is controlled and executed by the processor 2601.
收发器2603,用于与其他设备或通信网络通信。如用于与以太网,无线接入网(radio access network,RAN),无线局域网(Wireless Local Area Networks,WLAN)等通信网络通信。若设备是基站,收发器2603可以包括基带处理器的全部或部分,以及还可选择性地包括RF处理器。RF处理器用于收发RF信号,基带处理器则用于实现由RF信号转换的基带信号或即将转换为RF信号的基带信号的处理。The transceiver 2603 is configured to communicate with other devices or a communication network. For example, it is used to communicate with communication networks such as Ethernet, radio access network (RAN), wireless local area networks (WLAN) and the like. If the device is a base station, the transceiver 2603 may include all or part of a baseband processor, and may optionally include an RF processor. The RF processor is used to transmit and receive RF signals, and the baseband processor is used to implement processing of the baseband signal converted from the RF signal or the baseband signal to be converted into the RF signal.
在本申请实施例中,收发器2603用于发送N次SIB和接收N次SIB。In the embodiment of the present application, the transceiver 2603 is configured to send N times of SIBs and receive N times of SIBs.
总线2604,可以是工业标准体系结构(Industry Standard Architecture,ISA)总线、外部设备互连(Peripheral Component Interconnect,PCI)总线或扩展工业标准体系结构(Extended Industry Standard Architecture,EISA)总线等。该总线可以分为地址总线、数据总线、控制总线等。为便于表示,图26中仅用一条粗线表示,但并不表示仅有一根总线或一种类型的总线。The bus 2604 may be an Industry Standard Architecture (ISA) bus, an External Component Interconnect (PCI) bus, or an Extended Industry Standard Architecture (EISA) bus. The bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is used in FIG. 26, but it does not mean that there is only one bus or one type of bus.
图26中示出的设备结构并不构成对设备的限定,可以包括比图示更多或更少的部件,或者组合某些部件,或者不同的部件布置。The device structure shown in FIG. 26 does not constitute a limitation on the device, and may include more or fewer components than shown, or some components may be combined, or different components may be arranged.
在采用集成的单元的情况下,图27示出了上述实施例中所涉及的基站的另一种可能的组成示意图。如图27所示,该基站包括:处理模块2701和通信模块2702。In the case of using an integrated unit, FIG. 27 shows another possible composition diagram of the base station involved in the foregoing embodiment. As shown in FIG. 27, the base station includes a processing module 2701 and a communication module 2702.
处理模块2701用于对基站的动作进行控制管理和/或用于本文所描述的技术的其它过程。通信模块2702用于支持基站与其他网络实体的通信,例如与图28和图29中示出的功能模块或网络实体之间的通信。具体的,如通信模块2702用于支持基站执行图3中的S301,图21中的S301和S303。基站还可以包括存储模块2703,用于存储基站的程序代码和数据。The processing module 2701 is used to control and manage the actions of the base station and / or other processes used in the technology described herein. The communication module 2702 is configured to support communication between the base station and other network entities, for example, communication with the functional modules or network entities shown in FIG. 28 and FIG. 29. Specifically, for example, the communication module 2702 is configured to support the base station to execute S301 in FIG. 3 and S301 and S303 in FIG. 21. The base station may further include a storage module 2703 for storing program code and data of the base station.
其中,处理模块2701可以是处理器或控制器。其可以实现或执行结合本申请公开内容所描述的各种示例性的逻辑方框,模块和电路。处理器也可以是实现计算功能的组合,例如包含一个或多个微处理器组合,DSP和微处理器的组合等等。通信模块2702可以是收发器、收发电路或通信接口等。存储模块2703可以是存储器。The processing module 2701 may be a processor or a controller. It may implement or execute various exemplary logical blocks, modules, and circuits described in connection with the disclosure of this application. A processor may also be a combination that implements computing functions, such as a combination of one or more microprocessors, a combination of a DSP and a microprocessor, and so on. The communication module 2702 may be a transceiver, a transceiver circuit, or a communication interface. The storage module 2703 may be a memory.
当处理模块2701为处理器,通信模块2702为收发器,存储模块2703为存储器时,本申请实施例所涉及的基站可以为图26所示的设备。When the processing module 2701 is a processor, the communication module 2702 is a transceiver, and the storage module 2703 is a memory, the base station involved in this embodiment of the present application may be the device shown in FIG. 26.
在采用对应各个功能划分各个功能模块的情况下,图28示出了上述和实施例中涉及的终端设备的一种可能的组成示意图,该终端设备能执行本申请各方法实施例中任一方法实施例中终端设备所执行的步骤。如图28所示,该终端设备可以包括:接收单元2801。In the case where each functional module is divided corresponding to each function, FIG. 28 shows a possible composition diagram of the terminal device involved in the foregoing and embodiments, and the terminal device can execute any one of the method embodiments of the present application Steps performed by the terminal device in the embodiment. As shown in FIG. 28, the terminal device may include: a receiving unit 2801.
其中,接收单元2801,用于支持终端设备执行图3所示的SIB传输方法中的S302,图21所示的SIB传输方法中的S302和S304。The receiving unit 2801 is configured to support a terminal device to execute S302 in the SIB transmission method shown in FIG. 3 and S302 and S304 in the SIB transmission method shown in FIG. 21.
在本申请实施例中,进一步的,如图28所示,该终端设备还可以包括:处理单元2802和发送单元2803。In the embodiment of the present application, further, as shown in FIG. 28, the terminal device may further include a processing unit 2802 and a sending unit 2803.
需要说明的是,上述方法实施例涉及的各步骤的所有相关内容均可以援引到对应功能模块的功能描述,在此不再赘述。本申请实施例提供的终端设备,用于执行上述SIB传输方法,因此可以达到与上述SIB传输方法相同的效果。It should be noted that all relevant content of each step involved in the foregoing method embodiments can be referred to the functional description of the corresponding functional module, and will not be repeated here. The terminal device provided in the embodiment of the present application is configured to execute the above-mentioned SIB transmission method, and thus can achieve the same effect as the above-mentioned SIB transmission method.
在采用集成的单元的情况下,图29示出了上述实施例中所涉及的终端设备的另一 种可能的组成示意图。如图29所示,该终端设备包括:处理模块2901和通信模块2902。In the case where an integrated unit is used, FIG. 29 shows another possible composition diagram of the terminal device involved in the foregoing embodiment. As shown in FIG. 29, the terminal device includes a processing module 2901 and a communication module 2902.
处理模块2901用于对终端设备的动作进行控制管理和/或用于本文所描述的技术的其它过程。通信模块2902用于支持终端设备与其他网络实体的通信,例如与图25和图27中示出的功能模块或网络实体之间的通信。具体的,如通信模块2902用于支持终端设备执行图3中的S302,图21中的S302和S304。终端设备还可以包括存储模块2903,用于存储终端设备的程序代码和数据。The processing module 2901 is used to control and manage the actions of the terminal device and / or other processes used in the technology described herein. The communication module 2902 is configured to support communication between the terminal device and other network entities, for example, communication with the functional modules or network entities shown in FIG. 25 and FIG. 27. Specifically, for example, the communication module 2902 is configured to support a terminal device to execute S302 in FIG. 3, and S302 and S304 in FIG. 21. The terminal device may further include a storage module 2903 for storing program code and data of the terminal device.
其中,处理模块2901可以是处理器或控制器。其可以实现或执行结合本申请公开内容所描述的各种示例性的逻辑方框,模块和电路。处理器也可以是实现计算功能的组合,例如包含一个或多个微处理器组合,DSP和微处理器的组合等等。通信模块2902可以是收发器、收发电路或通信接口等。存储模块2903可以是存储器。The processing module 2901 may be a processor or a controller. It may implement or execute various exemplary logical blocks, modules, and circuits described in connection with the disclosure of this application. A processor may also be a combination that implements computing functions, such as a combination of one or more microprocessors, a combination of a DSP and a microprocessor, and so on. The communication module 2902 may be a transceiver, a transceiver circuit, or a communication interface. The storage module 2903 may be a memory.
当处理模块2901为处理器,通信模块2902为收发器,存储模块2903为存储器时,本申请实施例所涉及的终端设备可以为图26所示的设备。When the processing module 2901 is a processor, the communication module 2902 is a transceiver, and the storage module 2903 is a memory, the terminal device involved in this embodiment of the present application may be the device shown in FIG. 26.
通过以上的实施方式的描述,所属领域的技术人员可以清楚地了解到,为描述的方便和简洁,仅以上述各功能模块的划分进行举例说明,实际应用中,可以根据需要而将上述功能分配由不同的功能模块完成,即将装置的内部结构划分成不同的功能模块,以完成以上描述的全部或者部分功能。Through the description of the above embodiments, those skilled in the art can clearly understand that, for the convenience and brevity of the description, only the division of the above functional modules is used as an example. In practical applications, the above functions can be allocated according to needs. It is completed by different functional modules, that is, the internal structure of the device is divided into different functional modules to complete all or part of the functions described above.
在本申请所提供的几个实施例中,应该理解到,所揭露的装置和方法,可以通过其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如,所述模块或单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个装置,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性,机械或其它的形式。In the several embodiments provided in this application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the device embodiments described above are only schematic. For example, the division of the modules or units is only a logical function division. In actual implementation, there may be another division manner. For example, multiple units or components may be divided. The combination can either be integrated into another device, or some features can be ignored or not implemented. In addition, the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, which may be electrical, mechanical or other forms.
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是一个物理单元或多个物理单元,即可以位于一个地方,或者也可以分布到多个不同地方。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。The unit described as a separate component may or may not be physically separated, and the component displayed as a unit may be a physical unit or multiple physical units, that is, may be located in one place, or may be distributed to multiple different places. . Some or all of the units may be selected according to actual needs to achieve the objective of the solution of this embodiment.
另外,在本申请各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。上述集成的单元既可以采用硬件的形式实现,也可以采用软件功能单元的形式实现。In addition, each functional unit in each embodiment of the present application may be integrated into one processing unit, or each of the units may exist separately physically, or two or more units may be integrated into one unit. The above integrated unit may be implemented in the form of hardware or in the form of software functional unit.
所述集成的单元如果以软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个可读取存储介质中。基于这样的理解,本申请实施例的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的全部或部分可以以软件产品的形式体现出来,该软件产品存储在一个存储介质中,包括若干指令用以使得一个设备(可以是单片机,芯片等)或处理器(processor)执行本申请各个实施例所述方法的全部或部分步骤。而前述的存储介质包括:U盘、移动硬盘、ROM、RAM、磁碟或者光盘等各种可以存储程序代码的介质。When the integrated unit is implemented in the form of a software functional unit and sold or used as an independent product, it may be stored in a readable storage medium. Based on such an understanding, the technical solutions of the embodiments of the present application essentially or partly contribute to the existing technology or all or part of the technical solutions may be embodied in the form of a software product, which is stored in a storage medium The instructions include a number of instructions for causing a device (which can be a single-chip microcomputer, a chip, or the like) or a processor to execute all or part of the steps of the method described in each embodiment of the present application. The foregoing storage medium includes various media that can store program codes, such as a U disk, a mobile hard disk, a ROM, a RAM, a magnetic disk, or an optical disk.
以上所述,仅为本申请的具体实施方式,但本申请的保护范围并不局限于此,任何在本申请揭露的技术范围内的变化或替换,都应涵盖在本申请的保护范围之内。因此,本申请的保护范围应以所述权利要求的保护范围为准。The above is only a specific implementation of this application, but the scope of protection of this application is not limited to this. Any changes or replacements within the technical scope disclosed in this application shall be covered by the scope of protection of this application. . Therefore, the protection scope of this application shall be subject to the protection scope of the claims.

Claims (30)

  1. 一种系统信息块SIB传输方法,其特征在于,所述方法应用于基站或基站的芯片,所述方法包括:A system information block SIB transmission method, characterized in that the method is applied to a base station or a chip of a base station, and the method includes:
    在时域上的第一周期中,重复发送N次SIB,所述第一周期包括m个第二周期,当N大于或等于m时,所述m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100001
    所述m个第二周期中第m个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100002
    N为大于0的正整数,m为大于0的正整数,
    Figure PCTCN2018089101-appb-100003
    表示向上取整。
    In the first cycle in the time domain, the SIB is repeatedly sent N times, the first cycle includes m second cycles, and when N is greater than or equal to m, the first second cycle of the m second cycles The number of SIB repetitions in each second cycle from the m-1th second cycle is
    Figure PCTCN2018089101-appb-100001
    The number of repetitions of the SIB in the m second period of the m second periods is
    Figure PCTCN2018089101-appb-100002
    N is a positive integer greater than 0, m is a positive integer greater than 0,
    Figure PCTCN2018089101-appb-100003
    Rounds up.
  2. 根据权利要求1所述的SIB传输方法,其特征在于,若N为正整数且N为2的整数次幂,m为正整数且m为2的整数次幂,N大于或等于m,所述m个第二周期中每个所述第二周期内SIB的重复次数为N/m。The SIB transmission method according to claim 1, wherein if N is a positive integer and N is an integer power of 2, m is a positive integer and m is an integer power of 2, and N is greater than or equal to m, the The number of repetitions of the SIB in each of the m second periods is N / m.
  3. 根据权利要求2所述的SIB传输方法,其特征在于,若在每个所述第二周期内N/m次SIB等间隔发送,在每个所述第二周期内发送的N/m次SIB占用N/m个时间单元,每次发送的SIB占用一个时间单元。The SIB transmission method according to claim 2, wherein if N / m times of SIBs are transmitted at equal intervals in each of the second cycles, N / m times of SIBs are transmitted in each of the second cycles Occupies N / m time units, and each transmitted SIB occupies one time unit.
  4. 根据权利要求2所述的SIB传输方法,其特征在于,在每个所述第二周期内发送的N/m次SIB占用N/m个时间单元,所述N/m个时间单元连续发送,每次发送的SIB占用一个时间单元。The SIB transmission method according to claim 2, characterized in that the N / m SIBs transmitted in each of the second cycles occupy N / m time units, and the N / m time units are transmitted continuously, Each transmitted SIB takes one time unit.
  5. 根据权利要求3所述的SIB传输方法,其特征在于,所述时间单元的时长为T2*m/N,T2表示第二周期时长。The SIB transmission method according to claim 3, wherein a duration of the time unit is T2 * m / N, and T2 represents a duration of the second period.
  6. 根据权利要求3或4所述的SIB传输方法,其特征在于,所述时间单元的时长为160毫秒。The SIB transmission method according to claim 3 or 4, wherein the duration of the time unit is 160 milliseconds.
  7. 根据权利要求1-6中任一项所述的SIB传输方法,其特征在于,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。The SIB transmission method according to any one of claims 1-6, wherein each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  8. 根据权利要求7所述的SIB传输方法,其特征在于,每次发送的SIB占用连续的8个下行子帧。The SIB transmission method according to claim 7, wherein each transmitted SIB occupies 8 consecutive downlink subframes.
  9. 根据权利要求2所述的SIB传输方法,其特征在于,若在每个所述第二周期内N/m次SIB连续发送,所述N/m次发送的SIB占用连续的N*p/m个下行子帧,p为大于0的正整数。The SIB transmission method according to claim 2, characterized in that if N / m times of SIBs are continuously transmitted in each of the second cycles, the N / m times of SIBs occupy consecutive N * p / m Downlink subframes, p is a positive integer greater than 0.
  10. 根据权利要求1-9中任一项所述的SIB传输方法,其特征在于,在每个所述第二周期内第一次发送SIB的起始时刻为从所述第一次发送的SIB所属的所述第二周期的起始时刻开始偏移预设偏移值的时刻。The SIB transmission method according to any one of claims 1 to 9, characterized in that, the start time of sending the SIB for the first time in each of the second cycles belongs to the SIB sent from the first sending The time at which the start time of the second period begins to shift from a preset offset value.
  11. 根据权利要求3所述的SIB传输方法,其特征在于,若在每个所述第二周期内N/m次SIB等间隔发送,所述时间单元的时长为T2*m/N或160ms,在每个所述时间单元内发送SIB的起始时刻为从所述时间单元的起始时刻开始偏移预设偏移值的时刻。The SIB transmission method according to claim 3, characterized in that if N / m SIBs are sent at equal intervals in each of the second periods, the duration of the time unit is T2 * m / N or 160ms, in The start time of sending the SIB in each time unit is a time offset from the start time of the time unit by a preset offset value.
  12. 根据权利要求4所述的SIB传输方法,其特征在于,若在每个所述第二周期内N/m个时间单元连续发送,所述时间单元的时长为160ms,在每个所述时间单元内发送SIB的起始时刻为从所述时间单元的起始时刻开始偏移预设偏移值的时刻。The SIB transmission method according to claim 4, characterized in that if N / m time units are continuously transmitted in each of the second cycles, the time unit duration is 160 ms, and in each of the time units The start time of the internal transmission SIB is the time offset from the start time of the time unit by a preset offset value.
  13. 根据权利要求10-12中任一项所述的SIB传输方法,其特征在于,在所述发 送N次SIB之前,所述方法还包括:The SIB transmission method according to any one of claims 10-12, wherein before the sending of the SIB N times, the method further comprises:
    预先配置所述预设偏移值;或者,Pre-configure the preset offset value; or
    发送主信息块MIB,所述MIB包括所述预设偏移值。Send a main information block MIB, where the MIB includes the preset offset value.
  14. 根据权利要求13所述的SIB传输方法,其特征在于,所述预设偏移值为40毫秒。The SIB transmission method according to claim 13, wherein the preset offset value is 40 milliseconds.
  15. 一种系统信息块SIB传输方法,其特征在于,所述方法应用于终端设备或终端设备的芯片,所述方法包括:A system information block SIB transmission method, characterized in that the method is applied to a terminal device or a chip of a terminal device, and the method includes:
    在时域上的第一周期中,接收N次SIB,所述第一周期包括m个第二周期,当N大于或等于m时,所述m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100004
    所述m个第二周期中第m个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100005
    N为大于0的正整数,m为大于0的正整数,
    Figure PCTCN2018089101-appb-100006
    表示向上取整。
    In the first period in the time domain, N SIBs are received, the first period includes m second periods, and when N is greater than or equal to m, the first second period of the m second periods is up to The number of SIB repetitions in each second period in the m-1th second period is
    Figure PCTCN2018089101-appb-100004
    The number of repetitions of the SIB in the m second period of the m second periods is
    Figure PCTCN2018089101-appb-100005
    N is a positive integer greater than 0, m is a positive integer greater than 0,
    Figure PCTCN2018089101-appb-100006
    Rounds up.
  16. 根据权利要求15所述的SIB传输方法,其特征在于,若N为正整数且N为2的整数次幂,m为正整数且m为2的整数次幂,N大于或等于m,所述m个第二周期中每个所述第二周期内SIB的重复次数为N/m。The SIB transmission method according to claim 15, wherein if N is a positive integer and N is an integer power of 2, m is a positive integer and m is an integer power of 2, and N is greater than or equal to m, the The number of repetitions of the SIB in each of the m second periods is N / m.
  17. 根据权利要求16所述的SIB传输方法,其特征在于,若在每个所述第二周期内N/m次SIB等间隔发送,在每个所述第二周期内发送的N/m次SIB占用N/m个时间单元,每次发送的SIB占用一个时间单元。The SIB transmission method according to claim 16, characterized in that if N / m times of SIBs are transmitted at equal intervals in each of the second periods, N / m times of SIBs are transmitted in each of the second periods Occupies N / m time units, and each transmitted SIB occupies one time unit.
  18. 根据权利要求16所述的SIB传输方法,其特征在于,在每个所述第二周期内发送的N/m次SIB占用N/m个时间单元,所述N/m个时间单元连续发送,每次发送的SIB占用一个时间单元。The SIB transmission method according to claim 16, characterized in that the N / m SIBs transmitted in each of the second cycles occupy N / m time units, and the N / m time units are transmitted continuously, Each transmitted SIB takes one time unit.
  19. 根据权利要求17所述的SIB传输方法,其特征在于,所述时间单元的时长为T2*m/N,T2表示第二周期时长。The SIB transmission method according to claim 17, wherein a duration of the time unit is T2 * m / N, and T2 represents a duration of the second period.
  20. 根据权利要求17或18所述的SIB传输方法,其特征在于,所述时间单元的时长为160毫秒。The SIB transmission method according to claim 17 or 18, wherein a duration of the time unit is 160 milliseconds.
  21. 根据权利要求15-20中任一项所述的SIB传输方法,其特征在于,每次发送的SIB占用连续的p个下行子帧,p为大于0的正整数。The SIB transmission method according to any one of claims 15-20, wherein each transmitted SIB occupies consecutive p downlink subframes, and p is a positive integer greater than 0.
  22. 根据权利要求21所述的SIB传输方法,其特征在于,每次发送的SIB占用连续的8个下行子帧。The SIB transmission method according to claim 21, wherein each transmitted SIB occupies 8 consecutive downlink subframes.
  23. 根据权利要求16所述的SIB传输方法,其特征在于,若在每个所述第二周期内N/m次SIB连续发送,所述N/m次发送的SIB占用连续的N*p/m个下行子帧,p为大于0的正整数。The SIB transmission method according to claim 16, characterized in that if N / m times of SIBs are continuously transmitted in each of the second periods, the N / m times of SIBs occupy consecutive N * p / m Downlink subframes, p is a positive integer greater than 0.
  24. 根据权利要求15-23中任一项所述的SIB传输方法,其特征在于,在每个所述第二周期内第一次发送SIB的起始时刻为从所述第一次发送的SIB所属的所述第二周期的起始时刻开始偏移预设偏移值的时刻。The SIB transmission method according to any one of claims 15 to 23, wherein a start time of transmitting the SIB for the first time in each of the second periods is a time from which the first SIB is transmitted The time at which the start time of the second period begins to shift from a preset offset value.
  25. 一种无线通信装置,其特征在于,无线通信装置为基站或基站的芯片,所述无线通信装置包括:A wireless communication device, characterized in that the wireless communication device is a base station or a chip of a base station, and the wireless communication device includes:
    发送单元,用于在时域上的第一周期中,重复发送N次SIB,所述第一周期包括m个第二周期,当N大于或等于m时,所述m个第二周期中第1个第二周期至第m-1 个第二周期中每个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100007
    所述m个第二周期中第m个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100008
    N为大于0的正整数,m为大于0的正整数,
    Figure PCTCN2018089101-appb-100009
    表示向上取整。
    A sending unit, configured to repeatedly send the SIB N times in the first period in the time domain, the first period includes m second periods, and when N is greater than or equal to m, the first period in the m second periods The number of SIB repetitions in each second period from 1 second period to the m-1th second period is
    Figure PCTCN2018089101-appb-100007
    The number of repetitions of the SIB in the m second period of the m second periods is
    Figure PCTCN2018089101-appb-100008
    N is a positive integer greater than 0, m is a positive integer greater than 0,
    Figure PCTCN2018089101-appb-100009
    Rounds up.
  26. 一种无线通信装置,其特征在于,所述无线通信装置为终端设备或终端设备的芯片,所述无线通信装置包括:A wireless communication device, characterized in that the wireless communication device is a terminal device or a chip of a terminal device, and the wireless communication device includes:
    接收单元,用于在时域上的第一周期中,接收N次SIB,所述第一周期包括m个第二周期,当N大于或等于m时,所述m个第二周期中第1个第二周期至第m-1个第二周期中每个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100010
    所述m个第二周期中第m个第二周期内SIB的重复次数为
    Figure PCTCN2018089101-appb-100011
    N为大于0的正整数,m为大于0的正整数,
    Figure PCTCN2018089101-appb-100012
    表示向上取整。
    A receiving unit, configured to receive N SIBs in a first period in the time domain, the first period includes m second periods, and when N is greater than or equal to m, the first of the m second periods The number of repetitions of the SIB in each second period from the second period to the m-1th second period is
    Figure PCTCN2018089101-appb-100010
    The number of repetitions of the SIB in the m second period of the m second periods is
    Figure PCTCN2018089101-appb-100011
    N is a positive integer greater than 0, m is a positive integer greater than 0,
    Figure PCTCN2018089101-appb-100012
    Rounds up.
  27. 一种基站,其特征在于,包括:至少一个处理器,以及存储器;其特征在于,A base station includes: at least one processor, and a memory; and
    所述存储器用于存储计算机程序,使得所述计算机程序被所述至少一个处理器执行时实现如权利要求1-14中任一项所述的SIB传输方法。The memory is used to store a computer program, so that when the computer program is executed by the at least one processor, the SIB transmission method according to any one of claims 1-14 is implemented.
  28. 一种终端设备,其特征在于,包括:至少一个处理器,以及存储器;其特征在于,A terminal device, comprising: at least one processor, and a memory; and
    所述存储器用于存储计算机程序,使得所述计算机程序被所述至少一个处理器执行时实现如权利要求15-24中任一项所述的SIB传输方法。The memory is configured to store a computer program, so that when the computer program is executed by the at least one processor, the SIB transmission method according to any one of claims 15 to 24 is implemented.
  29. 一种计算机存储介质,其上存储有计算机程序,其特征在于,所述程序被处理器执行时实现如权利要求1-14中任一项所述的SIB传输方法或权利要求15-24中任一项所述的SIB传输方法。A computer storage medium having stored thereon a computer program, characterized in that, when the program is executed by a processor, the SIB transmission method according to any one of claims 1 to 14 or any one of claims 15 to 24 is implemented. An SIB transmission method according to one item.
  30. 一种包含指令的计算机程序产品,其特征在于,当所述计算机程序产品在基站或内置在基站的芯片中运行时,使得所述基站执行如权利要求1-14中任一项所述的SIB传输方法或权利要求15-24中任一项所述的SIB传输方法。A computer program product containing instructions, wherein when the computer program product runs in a base station or a chip built in the base station, the base station causes the base station to execute the SIB according to any one of claims 1-14. A transmission method or the SIB transmission method according to any one of claims 15-24.
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