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WO2015123845A1 - Resource scheduling method, and data transmission method and equipment - Google Patents

Resource scheduling method, and data transmission method and equipment Download PDF

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Publication number
WO2015123845A1
WO2015123845A1 PCT/CN2014/072324 CN2014072324W WO2015123845A1 WO 2015123845 A1 WO2015123845 A1 WO 2015123845A1 CN 2014072324 W CN2014072324 W CN 2014072324W WO 2015123845 A1 WO2015123845 A1 WO 2015123845A1
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WO
WIPO (PCT)
Prior art keywords
time
control channel
scheduling information
information
frequency resource
Prior art date
Application number
PCT/CN2014/072324
Other languages
French (fr)
Chinese (zh)
Inventor
李振宇
朱松
郭小龙
张维良
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.)
Filing date
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 PCT/CN2014/072324 priority Critical patent/WO2015123845A1/en
Priority to CN201480000426.5A priority patent/CN105009666B/en
Publication of WO2015123845A1 publication Critical patent/WO2015123845A1/en

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/12Wireless traffic scheduling

Definitions

  • the embodiments of the present invention relate to communication technologies, and in particular, to a resource scheduling method, a data transmission method, and a device.
  • the narrowband system proposes a multi-channel technical solution in order to increase the system capacity. For example, in order to reduce the probability of a user equipment (User Equipment, UE for short) transmitting a collision when using the same channel for data transmission, a small number of channels in the channel are set as data channels, and other channels are set as control channels, thereby improving user equipment. The success rate of random access.
  • UE User Equipment
  • the information rate of a single frame in a single channel is relatively low, so that the length of control signaling carried in the control channel is limited, so that a single control frame can only transmit control information of several tens of bits.
  • the number of repetitions of the A area covered by the base station on the network side can be IX, and the B area covered by the base station.
  • the number of repetitions of the C region can be 8X or other repetitions.
  • the number of repetitions of different channels can be different, so that the user equipment can select a matching channel for data transmission.
  • part of the channel can be reserved for competitive use, as shown in Figure 2.
  • the user equipment can communicate with the base station by means of Frequency Division Duplexing (FDD), and the base station adopts a large bandwidth and full duplex mode to form a half-duplex FDD system.
  • FDD Frequency Division Duplexing
  • the base station can also transmit data to other user equipments while receiving data sent by the user equipment, that is, in a half-duplex FDD system, if multiple uplink data channels and downlinks exist simultaneously In the data channel, there is a problem that the control channel is limited. Therefore, in a half-duplex FDD system, when there are multiple uplink data channels and/or multiple downlink data channels, how to perform resource scheduling is a problem to be solved. . Summary of the invention
  • the embodiments of the present invention provide a resource scheduling method, a data transmission method, and a device, which are used to implement reasonable scheduling of resources in a half-duplex FDD system, and improve resource allocation efficiency of a half-duplex FDD system.
  • an embodiment of the present invention provides a resource scheduling method, including:
  • the network side device allocates a first control channel to the at least one data channel, establishes a mapping relationship between the first control channel and the data channel, and notifies the user equipment UE of the mapping relationship;
  • the mapping relationship and the identifier of the target UE allocate time-frequency resource location information to the target UE, and obtain first scheduling information of the at least one data channel according to the time-frequency resource location information, where the first scheduling information is The target UE performs data transmission according to the time-frequency resource location information;
  • the network side device sends the first scheduling information and the feedback information of the uplink data to all UEs by using the first control channel.
  • the first scheduling information includes: an identifier of a target UE;
  • the identity of the target UE is the identity of the target UE
  • the method also includes:
  • the network side device notifies the all UEs of time-frequency resource location information of a data channel that can be scheduled by the first control channel.
  • the network side device when the identifier of the target UE is one in the first scheduling information, the network side device passes the Transmitting, by the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs;
  • the network side device uses all fields or partial resources of the identifier of the target UE with the first
  • the cyclic redundancy check code CRC in a control channel performs an exclusive OR operation
  • the method further includes: when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the method further includes:
  • the network side device determines second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
  • the network side device sends the second scheduling information and/or the feedback information to all UEs through the second control channel.
  • the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location is a physical location of the time-frequency resource; or
  • the time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the network side device sends the first scheduling information to all the UEs by using the first control channel. And before the feedback information of the uplink data, the method further includes:
  • the network side device determines a ratio of the uplink scheduling information UI and the downlink scheduling information DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
  • the UI and the DI are sent to the UE by using the same control channel, the UI and the DI are differentiated by using different time slots; or
  • the UI and the DI are sent to the UE by using different control channels; or, when the UI and the DI are sent to the UE by using the same control channel, the UI is carried in a control slot of the control channel.
  • the uplink indication is different from the downlink indication carried by the DI in the control slot of the control channel.
  • the method further includes:
  • the network side device sends the maximum downlink time-frequency resource quantity that the DI can schedule to all the UEs.
  • an embodiment of the present invention provides a data transmission method, including:
  • mapping relationship sent by the network device is monitored by the user equipment UE, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
  • the target UE in all the UEs sends uplink data to the network side device by using the at least one data channel;
  • All the UEs receive the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and Obtained by the identifier of the target UE;
  • the target UE performs data transmission according to the first scheduling information, and processes feedback information of the uplink data.
  • the first scheduling information includes: an identifier of a target UE;
  • the identity of the target UE is the identity of the target UE
  • the method before the target UE performs data transmission according to the first scheduling information, the method further includes:
  • the UEs receive the time-frequency resource location information sent by the network side device, where the time-frequency resource location information is a time-frequency resource location information of the data channel that can be scheduled by the first control channel.
  • the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second
  • the threshold further includes:
  • All the UEs receive the second scheduling information and/or the feedback information sent by the network side device by using the second control channel;
  • the target UE performs data transmission according to the second scheduling information, and/or processes the feedback information.
  • the second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
  • the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or ,
  • the time-frequency resource location is a physical location of the time-frequency resource
  • the time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the method further includes:
  • all the UEs receive the maximum downlink time-frequency resource that can be scheduled by the DI sent by the network side device.
  • an embodiment of the present invention provides a communications device, including:
  • the memory is for storing instructions
  • the processor executes instructions stored in the memory for:
  • the first scheduling information includes: an identifier of a target UE
  • the identity of the target UE is the identity of the target UE
  • the processor sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel;
  • the processor performs an exclusive OR operation on all or a part of the identifier of the target UE with a cyclic redundancy check code CRC in the first control channel;
  • the feedback information and the information after the exclusive OR operation are transmitted to the all UEs.
  • the processor is further configured to:
  • the time-frequency resource location is a virtual resource corresponding to the time-frequency resource. Location; or,
  • the time-frequency resource location is a physical location of the time-frequency resource
  • the time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the processor sends the first scheduling information and the information to all the UEs by using the first control channel. Before the feedback information of the uplink data is used,
  • a seventh possible implementation manner when the UI and the DI are sent to the UE by using the same control channel, the UI and the The DI is differentiated by different time slot ratios; or
  • the UI and the DI are sent to the UE by using different control channels; or
  • the uplink indication carried by the UI in the control slot of the control channel is different from the downlink carried by the DI in the control slot of the control channel.
  • the processor sends the foregoing to the all UEs by using the first control channel Before/after the scheduling information and the feedback information of the uplink data, it is also used to:
  • an embodiment of the present invention provides a user equipment, including:
  • the memory is for storing instructions
  • the processor executes instructions stored in the memory for:
  • mapping relationship sent by the network side device is monitored, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
  • the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and the target UE Obtained by the logo;
  • the first scheduling information includes: an identifier of a target UE;
  • the identity of the target UE is the identity of the target UE
  • time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
  • the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second
  • the threshold is also used by the processor
  • Data transmission is performed according to the second scheduling information, and/or the feedback information is processed.
  • the second scheduling information is included in the second control channel acquired by the network side device.
  • the second scheduling information of the target UE identifier is included in the second control channel acquired by the network side device.
  • the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or ,
  • the time-frequency resource location is a physical location of the time-frequency resource
  • the time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the first and second possible implementation manners of the fourth aspect in a fifth possible implementation manner, before the performing data transmission by the processor according to the first scheduling information,
  • a fifth aspect of the present invention provides a communications device, including:
  • An allocating unit configured to allocate a first control channel to the at least one data channel
  • an establishing unit configured to establish, according to the first control channel allocated by the allocating unit, a mapping relationship between the first control channel and the data channel;
  • a sending unit configured to notify all the user equipments UE of the mapping relationship established by the establishing unit, where the scheduling information generating unit is configured to allocate time-frequency resources to the target UE according to the mapping relationship established by the establishing unit and the identifier of the target UE Position information, and obtaining first scheduling information of the at least one data channel according to the time-frequency resource location information, where the first scheduling information causes the target UE to perform data transmission according to the time-frequency resource location information;
  • a receiving unit configured to receive, by using the at least one data channel, uplink data sent by at least one target UE;
  • the sending unit is further configured to send, by using the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs.
  • the first scheduling information includes: an identifier of a target UE;
  • the identity of the target UE is the identity of the target UE
  • the sending unit is further configured to send, by using the first control channel, the first scheduling information and the uplink data to the UE After the information, the time-frequency resource location information of the data channel that can be scheduled by the first control channel is notified to all the UEs.
  • the sending unit when the identifier of the target UE is one in the first scheduling information, the sending unit sends the target UE All or part of the identifier of the identifier is XORed with the cyclic redundancy check code CRC in the first control channel;
  • the quantity of the data channel is less than a preset first threshold, and the number of control channels is greater than When the second threshold is preset, the scheduling information generating unit is further used to
  • the sending unit is further configured to send the second scheduling information and/or the feedback information to all UEs by using the second control channel.
  • the time-frequency resource location is a virtual resource corresponding to the time-frequency resource Location;
  • the time-frequency resource location is a physical location of the time-frequency resource
  • the time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the communications device further includes: a determining unit;
  • the determining unit is configured to determine an uplink scheduling information UI and a downlink adjustment in the first scheduling information. a ratio of the degree information DI, and location information of the UI and the DI in the first control channel.
  • the UI and the DI are sent to the UE by using different control channels; or
  • the uplink indication carried by the UI in the control slot of the control channel is different from the downlink carried by the DI in the control slot of the control channel.
  • the sending unit is further used to
  • an embodiment of the present invention provides a user equipment, including:
  • a receiving unit configured to monitor a mapping relationship sent by the network side device, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
  • a sending unit configured to send uplink data to the network side device by using the at least one data channel when the user equipment UE is a target UE;
  • the receiving unit configured to: after the transmitting unit sends the uplink data, receive first scheduling information that is sent by the network side device by using the first control channel, and feedback information of the uplink data, where a scheduling information is obtained by the network side device according to the mapping relationship and the identifier of the target UE;
  • a processing unit configured to: after the receiving unit receives the first scheduling information, perform data transmission according to the first scheduling information, and process feedback information of the uplink data.
  • the first scheduling information includes: an identifier of a target UE
  • the receiving unit is further configured to receive time-frequency resource location information sent by the network side device, where the processing unit performs data transmission, where The frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
  • the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second
  • the receiving unit is further used for
  • the processing unit is further configured to: after the receiving unit receives the second scheduling information, perform data transmission according to the second scheduling information, and/or process the feedback information.
  • the second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
  • the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or ,
  • the time-frequency resource location is a physical location of the time-frequency resource
  • the time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the receiving unit is further used to
  • the resource scheduling method, the data transmission method, and the device in the embodiment allocate a first control channel to the at least one data channel by using the network side device, and establish a mapping relationship between the first control channel and the data channel. And obtaining the first scheduling information according to the mapping relationship, and the network side device sends the first scheduling information and the feedback information of the uplink data to the UE after receiving the uplink data sent by the target UE, so that the network side device adopts a unified control policy to implement the half-double Reasonable scheduling of resources in the FDD system to improve the resource allocation efficiency of the half-duplex FDD system.
  • 1 is a schematic diagram of a coverage area of a current base station
  • FIG. 2 is a schematic diagram of the use of each channel in the current narrowband system
  • FIG. 3 is a schematic flowchart of a resource scheduling method according to an embodiment of the present invention.
  • FIG. 4A to FIG. 4F are schematic diagrams showing resource allocation of a control channel according to Embodiment 1 of the present invention
  • FIG. 5 is a schematic flowchart of a resource scheduling method according to another embodiment of the present invention.
  • FIG. 6 is a schematic flowchart of a data transmission method according to an embodiment of the present invention.
  • FIG. 7 is a schematic structural diagram of a communication device according to an embodiment of the present invention.
  • FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • FIG. 9 is a schematic structural diagram of a communication device according to another embodiment of the present invention.
  • FIG. 10 is a schematic structural diagram of a user equipment according to another embodiment of the present invention.
  • a control channel can be responsible for several The resource allocation and scheduling of the data channel reduces the number of collisions of user equipment data transmission and improves the resource allocation efficiency of the half-duplex FDD system.
  • FIG. 3 is a schematic flowchart of a resource scheduling method according to an embodiment of the present invention. As shown in FIG. 3, the resource scheduling method in this embodiment includes the following content.
  • the network side device allocates a first control channel to the at least one data channel, and establishes a mapping relationship between the first control channel and the data channel.
  • the at least one data channel can include an uplink data channel and a downlink data channel.
  • the network side device notifies all UEs of the mapping relationship.
  • a network side device such as a base station can notify all UEs of the mapping relationship through system broadcast or paging messages.
  • all UEs in the location refer to all UEs in the coverage area of the network side device.
  • the changed mapping relationship may be notified to the UE by broadcasting. That is to say, when the format of the control channel changes, the format of the changed control channel can be notified to the UE by broadcast.
  • the time-frequency resource location information of the partial data channel may be included in the control channel, and the UE needs to know in advance the time-frequency resource range corresponding to the data channel that can be scheduled by each control channel. .
  • the network side device allocates time-frequency resource location information to the target UE according to the mapping relationship and the identifier of the target UE, and obtains first scheduling information of the at least one data channel according to the time-frequency resource location information.
  • the first scheduling information causes the target UE to perform data transmission according to the time-frequency resource location information.
  • the first scheduling information may include Uplink Scheduling Information (Downlink Scheduling Information) and Downlink Scheduling Information (DI), and the UI is used to schedule the UE in the UI.
  • the specified uplink resource transmits data in a prescribed manner, and the DI is used to schedule the UE to receive data in a prescribed manner on the resource specified by the DI.
  • the time-frequency resource location may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or the time-frequency resource location may be in the first control channel. Controlling relative position information within a time-frequency resource range of the scheduleable data channel corresponding to the time slot.
  • the network side device receives, by using the at least one data channel, at least one target UE to send. Upstream data.
  • the network side device sends the first scheduling information and the feedback information of the uplink data to all UEs by using the first control channel.
  • the feedback information of the uplink data of some UEs in a small number of UEs may be carried in the control channel.
  • the first scheduling information and the feedback information in the first control channel are differentiated by bits.
  • the feedback information of the first scheduling information and the uplink data may also be distinguished by other distinguishing manners, and this embodiment is merely an example.
  • the resource scheduling method in this embodiment enables the network side device to adopt a unified control strategy, implements reasonable scheduling of resources in the half-duplex FDD system, and improves resource allocation efficiency of the half-duplex FDD system.
  • the first scheduling information of the first control channel in FIG. 4B may include a UI and a DI; wherein UI-1 in FIG. 4B may schedule resources corresponding to U0 and U1 of the uplink data channel, for UE-1. Used with UE-2, as shown by the shading in Figure 4B.
  • the UI-2 in Fig. 4B can schedule resources corresponding to U2 and U3 of the uplink data channel for use by UE-3 and UE-4. Unallocated resources are available for competition.
  • the first control channel in Figure 4B can also carry feedback information of the uplink data, thereby effectively utilizing the resources of the half-duplex FDD system.
  • the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel can be a display indication.
  • the first scheduling information includes: an identifier of the target UE, and The time-frequency resource location information of the data channel that the first control channel can schedule.
  • FIG. 4C shows a schematic diagram of the display indication.
  • the UI and the DI respectively carry the identifier of the target UE and the time-frequency resource location information of the data channel that can be scheduled by the first control channel.
  • the resources indicated by the UI are indicated by the fields in the UI, and the resources indicated by the DI are also indicated by the fields in the DI.
  • the channel indication field, the resource location field, and the resource length indication field in the UI specify the scheduled channel number and resource location information.
  • the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel may also be an implicit indication.
  • the first scheduling information may include only: the identifier of the target UE.
  • the network side device and the target UE perform data transmission in a pre-agreed manner.
  • the network side device and the UE may perform a data transmission by using a table that specifies a time-frequency resource location information of a scheduling index and a data channel by using a protocol.
  • the network side device can transmit data to all UEs in advance.
  • the time-frequency resource location information of the data channel that can be used is notified by a broadcast or paging message, and after receiving the first scheduling information, the target UE may use the time-frequency location information notified by the network-side device to carry relevant data to implement data transmission. .
  • Figure 4D shows a schematic diagram of an implicit indication.
  • the UI and DI carry only the identity of the target UE.
  • the resources indicated by the UI are delivered to all UEs through broadcast messages, or the resources indicated by the UI are agreed with the UE protocol.
  • the resource scheduling method in this embodiment adopts the foregoing implicit indication manner, which can save the overhead of the control channel, and thus can schedule more target UEs.
  • the above display indication manner is adopted, and the idle resources can be better scheduled.
  • the resource scheduling method in the half-duplex FDD system can be made more flexible.
  • the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel may be a display indication for scheduling (hereinafter referred to as display scheduling), or may be an implicit indication for scheduling. (hereinafter referred to as implicit scheduling), as shown in Figure 4E.
  • display scheduling a display indication for scheduling
  • implicit scheduling an implicit indication for scheduling.
  • Frame 0, frame 1, frame 4, and frame 6 frame number, abbreviated as frame are used for uplink scheduling, where frame 0, frame 1, and frame 6 are in the form of implicit scheduling (assuming two UEs are scheduled), and frame 4 is displayed.
  • the UI of the frame 0 implicitly schedules the uplink data channels U0 and U1, and allocates the uplink data channel resources of the frame number 1 to the frame number 6 to the UE-1 and the UE-2, respectively, but the uplink data of the UE-2 is compared. Less, it is sent at frame 3.
  • the UI of the frame 4 can dynamically allocate the resources of the frames 5 and 6 of the uplink data channel U1 to the new UE-3 by the display scheduling method.
  • the DI of the frame 2 implicitly schedules the downlink data channels DO and D1
  • the resources of the frame 3 to the frame 5 are respectively allocated to the UE-4 and the UE-5
  • the DI of the frame 3 is implicitly scheduled to be downlink.
  • the data channels DO and D1 are allocated to the UE_5 and the UE_6 respectively. Due to the implicit scheduling, only the frame 6 carries the downlink data of the UE-5, but the UE-5 is in the conference.
  • the downlink data is also received on the channel DO, and when the identifier of the UE carried in the data is not the identity of the UE, the reception is stopped.
  • the network side device such as the base station, it can perform the scheduling through the DI display of the frame 5, and the channel is The data of frame 7 and frame 8 of the DO is assigned a new UE.
  • the downlink resource information of the uplink data may also be carried on the resource that is displayed in the scheduling.
  • the feedback information of the uplink data of UE-1 may be carried in frame 7 by displaying the content of the scheduled DI-3 information.
  • the format of the control channel may be bound to the frame number in the control channel (the different frame numbers may correspond to different formats), and the format of the control channel of the UE is notified by broadcast, so that the UE can learn the implicit indication.
  • the UI includes one or more of the following information: a differentiated identifier of the control information and the data information, a UI identifier, an identifier of the target UE, channel indication information, resource location information, and a resource length indication.
  • Information Modulation and Coding Scheme (MCS), frame number, number of repetitions, channel idle state indication information, backoff time after collision, backoff probability after collision, etc.
  • MCS Modulation and Coding Scheme
  • the DI includes one or more of the following information: a differentiated identifier of the control information and the data information, a DI identifier, an identifier of the target UE, channel indication information, resource location information, resource length indication information, MCS, frame number, number of repetitions, Channel idle state indication information, backoff time after collision, backoff probability after collision, and the like.
  • the identifier of the target UE is used to distinguish the target UE; the channel indication information is used to indicate which channel is scheduled; the resource location information is used to indicate the starting location of the resource; the resource length indication information is used to indicate the length of the scheduled resource; The number of repetitions is used to indicate the number of times the data needs to be repeatedly transmitted; the channel idle state indication information is used to indicate the idle condition of the channel; the backoff time after the collision is used to indicate how long the UE needs to retreat and then re-engage if a collision occurs. Competition; The backoff probability after collision is used to indicate how much the UE should back off if there is a collision.
  • the network side device may notify the UE of the order, the proportion, the distinguishing manner, and the like of the UI and the DI through the broadcast/paging message.
  • the information capacity carried by the control channel of the current narrowband system is very limited.
  • the foregoing step 305 may be specifically the step 305' not shown in the following figure:
  • the network side device performs an exclusive-OR operation on all the fields or partial resources of the identifier of the target UE and a Cyclical Redundancy Check (CRC) in the first control channel;
  • CRC Cyclical Redundancy Check
  • the network side device transmits the feedback information and the information after the XOR operation to the all UEs. That is to say, when each UI or DI only schedules one UE, the UE identifier or a part of the bit (bit) of the UE identifier and the CRC check code may be XORed to display an indication, thereby further saving control signaling overhead.
  • the foregoing method can well compress the control information in the first control channel, that is, the first scheduling information, so that the complete time-frequency resource location information is not used in the first scheduling information, and the communication delay can be better reduced.
  • the redundant Control channel multiplexing is used for data channels.
  • the resource scheduling method may include steps A01 to A02 which are not shown in the following figures.
  • the network side device determines second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE.
  • control channel when used as the data channel, the control channel can be no longer allocated for the second control channel, and the second control channel can directly implement the function of the data channel and realize the function of the control channel.
  • the time-frequency resource location information in this step may indicate time-frequency resource location information in the second control channel.
  • the network side device sends the second scheduling information to all UEs by using the second control channel.
  • the network side device simultaneously receives uplink data sent by at least one target UE through at least one data channel.
  • the network side device may also send second scheduling information and feedback information to all UEs through the second control channel.
  • control channel can also be used for sending service data, thereby effectively improving resource utilization.
  • the control channel can also be multiplexed into a downlink data channel, and the control information and data are distinguished by specific bits (bits).
  • the UI and DI can also be combined into XI, as shown in Figure 4F.
  • the C/D field is used to distinguish between control information and data.
  • the UI/DI field is used to distinguish whether it is uplink scheduling information or downlink scheduling information.
  • the Res and ACK fields are used to distinguish whether it is scheduling information or feedback information of uplink data. It should be understood that the feedback information of the uplink data may be carried in the XI at this time.
  • the UE After receiving the second scheduling information of the second control channel, the UE first parses the C/D field to obtain whether the current frame is control information or data. If it is control information, and then parses the UI/DI field to obtain whether the current frame is uplink scheduling information. Downstream scheduling information.
  • the resource scheduling method in this embodiment can flexibly adjust the structure of the control information to match different channel number proportions and channel bandwidths, and under different load conditions, whether the control channel is limited or the data channel is limited, the flexible adjustment control is adopted.
  • the use of channels ensures maximum system capacity and improves channel utilization.
  • the second control channel is multiplexed into a data channel, which may be specifically as follows, steps A1 to A12:
  • the network side device receives the uplink data sent by the at least one target UE through the at least one data channel.
  • the network side device sends the feedback information of the uplink data to the target UE by using a second control channel.
  • the resource scheduling method of the present embodiment solves the problem that the number of bits of the control channel is limited by the combination of the UI/DI implicit indication and the display indication, and at the same time maintains the flexibility of scheduling.
  • FIG. 5 is a schematic flowchart of a resource scheduling method according to an embodiment of the present invention. As shown in FIG. 5, the resource scheduling method in this embodiment includes the following content.
  • the network side device allocates a first control channel to the at least one data channel, establishes a mapping relationship between the first control channel and the data channel, and notifies all the UEs of the mapping relationship;
  • the network side device allocates time-frequency resource location information to the target UE according to the mapping relationship and the identifier of the target UE, and obtains first scheduling information of the at least one data channel according to the time-frequency resource location information.
  • the first scheduling information is used to enable the target UE to perform data transmission according to the time-frequency resource location information;
  • the network side device determines a ratio of UI and DI in the first scheduling information, and UI and
  • the network side device may distinguish between the UI and the DI by using different time slot ratios.
  • the uplink indication carried by the UI in the control slot of the first control channel is different, and the DI is in the first control channel.
  • the downstream indication carried in the control slot is not limited to the UI and the DI.
  • the network side device receives the uplink data sent by the at least one target UE by using the at least one data channel.
  • the network side device sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel.
  • the first scheduling information may all be a UI, or the first scheduling information may all be a DI.
  • the UI and DI of the first scheduling information are sent to the UE using different first control channels.
  • the above method enables the network side device to adopt a unified control strategy to implement reasonable scheduling of resources in the half-duplex FDD system, and improve the resource allocation efficiency of the half-duplex FDD system.
  • the foregoing resource scheduling method shown in FIG. 5 may further include a step 505a not shown in the following figure:
  • the network side device sends the ratio of the UI and the DI in the first scheduling information to the UE; and/or,
  • the network side device sends the UI and the DI in the first scheduling information to the UE; and/or,
  • the network side device sends the maximum uplink time-frequency resource quantity that the UI can schedule to the UE; and/or,
  • the network side device sends the maximum downlink time-frequency resource quantity that the DI can schedule to the UE.
  • the step 505a may be located before the foregoing step 505, or may be located after the foregoing step 505, which is not limited in this embodiment.
  • step 505a may be implemented by the network side device by means of system broadcast.
  • control channels corresponding to the data channels of different coverage levels may be different. That is to say, the coverage level of at least one data channel in which the first control channel establishes a mapping relationship is the same.
  • the UE can select different control channel camps according to its own channel conditions. In order to take into account the flexible requirements of the number of UEs in each coverage level, a few uplink data channels may be reserved, and a specific number of repetitions may not be set. When a network side device, such as a base station, schedules a channel that does not distinguish the number of repetitions, it must use a display. Scheduled UI/DI.
  • the physical uplink indication channel (PUICH) and the physical downlink indication channel (Physical downlink indication channel PDICH) can consider scheduling only a single UE, increase Flexibility.
  • FIG. 6 is a schematic flowchart diagram of a data transmission method according to an embodiment of the present invention. As shown in FIG. 6, the data transmission method in this embodiment includes the following content.
  • the mapping relationship between the first control channel and the at least one data channel is the mapping relationship between the first control channel and the at least one data channel.
  • the target UE in all UEs sends uplink data to the network side device by using the at least one data channel.
  • the UE receives the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and Obtained by the identifier of the target UE;
  • the target UE performs data transmission according to the first scheduling information, and processes feedback information of the uplink data.
  • the first scheduling information may include: an identifier of the target UE.
  • the first scheduling information and the time-frequency resource location information of the data channel that the first control channel can schedule may be an implicit indication.
  • the first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
  • the first scheduling information and the time-frequency resource location information of the data channel that the first control channel can schedule may be a display indication.
  • the first scheduling information may include a UI and/or a DI.
  • the at least one data channel can include an uplink data channel and a downlink data channel.
  • the method shown in FIG. 6 may further include a step 603a not shown in the figure:
  • all UEs receive a ratio of the UI and the DI in the first scheduling information sent by the network side device, and/or,
  • All UEs receive a method for distinguishing the UI and the DI in the first scheduling information sent by the network side device, and/or,
  • All UEs receive the maximum number of uplink time-frequency resources that can be scheduled by the UI sent by the network side device, and/or,
  • All UEs receive the maximum number of downlink time-frequency resources that can be scheduled by the DI sent by the network side device.
  • the network side device sends the message to all UEs through system broadcast or paging message.
  • the ratio of UI and DI the way of distinguishing between UI and DI, the maximum number of uplink time-frequency resources that the UI can schedule, the maximum number of downlink time-frequency resources that DI can schedule, and so on.
  • the method further includes: Step 604a:
  • All UEs receive time-frequency resource location information sent by the network side device, where the time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
  • the time-frequency resource location in the embodiment may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or the time-frequency resource location is the first The relative position information in the time-frequency resource range of the scheduleable data channel corresponding to the control slot in a control channel.
  • the embodiment may multiplex the control channels into data channels.
  • the above method also includes steps B01 and B02 which are not shown in the figure:
  • All UEs receive second scheduling information and/or the feedback information sent by the network side device by using the second control channel.
  • the target UE performs data transmission according to the second scheduling information, and/or is in the feedback information.
  • the second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
  • the data transmission method of the embodiment implements reasonable scheduling of resources in the half-duplex FDD system and improves the resource allocation efficiency of the half-duplex FDD system.
  • FIG. 7 is a schematic structural diagram of a communication device according to an embodiment of the present invention.
  • the communication device of this embodiment includes: a processor 71, a memory 72, a bus 73, and a communication interface 74.
  • the processor 71 And the memory 72 can be connected by a bus 73, wherein the memory 72 is used for storing instructions, and the processor 71 executes the instructions stored in the memory 72, and performs the following processing: assigning a first control channel to at least one data channel, establishing a Determining a mapping relationship between the first control channel and the data channel, and notifying the user equipment UE of the mapping relationship;
  • Allocating a time-frequency resource location letter to the target UE according to the mapping relationship and the identifier of the target UE Obtaining, according to the time-frequency resource location information, first scheduling information of the at least one data channel, where the first scheduling information enables the target UE to perform data transmission according to the time-frequency resource location information;
  • the foregoing first scheduling information may include: an identifier of the target UE.
  • the scheduling information and the time-frequency resource location information of the data channel that the first control channel can schedule are implicit scheduling modes.
  • the foregoing first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
  • the scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel are display scheduling modes.
  • the processor 81 sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel
  • the processor The sending, by the first control channel, the first scheduling information and the feedback information of the uplink data to the all UEs by using the first control channel;
  • the processor 81 performs an exclusive-OR operation on all the fields or partial resources of the identifier of the target UE and the CRC in the first control channel;
  • the feedback information and the information after the exclusive OR operation are transmitted to the all UEs.
  • the processor when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the processor is further configured to:
  • the time-frequency resource location may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or, the time-frequency resource location may be Corresponding position information in a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the processor 81 is further configured to determine, before sending, by using the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs. a ratio of UI and DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
  • the UI and the DI are sent to the UE by using the same control channel, the UI and the DI are differentiated by using different time slots; or
  • the UI and DI are sent to the UE using different control channels; or,
  • the processor 81 Before the processor 81 sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel, the processor 81 is further configured to:
  • the processor in the communication device allocates a first control channel for the at least one data channel, and establishes a mapping relationship between the first control channel and the data channel, and then obtains first scheduling information according to the mapping relationship, where the network side device sends the target UE.
  • the first scheduling information and the feedback information of the uplink data are sent to the UE, so that the network side device adopts a unified control strategy to implement reasonable scheduling of resources in the half-duplex FDD system, and improve resource allocation of the half-duplex FDD system. effectiveness.
  • FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • the user equipment in this embodiment includes: a processor 81, a memory 82, a bus 83, and a communication interface 84.
  • the processor 81 The memory 82 can be connected to the memory 82, wherein the memory 82 is used to store instructions, and the processor 81 executes the instructions stored in the memory 82 to perform the following processing:
  • the mapping relationship sent by the network side device is monitored, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
  • the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and the target UE Obtained by the logo;
  • the first scheduling information may include: an identifier of the target UE.
  • the first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
  • time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
  • the processor 81 is further configured to:
  • Data transmission is performed according to the second scheduling information, and/or the feedback information is processed.
  • the second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
  • the time-frequency resource location may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or the time-frequency resource location may be the The relative position information in the time-frequency resource range of the scheduleable data channel corresponding to the control slot in a control channel.
  • the user equipment interacts with the network side device to implement reasonable scheduling of resources in the half-duplex FDD system and improve the resource allocation efficiency of the half-duplex FDD system.
  • FIG. 9 is a schematic structural diagram of a communication device according to an embodiment of the present invention.
  • the communication device of this embodiment includes: an allocating unit 91, an establishing unit 92, a sending unit 93, a scheduling information generating unit 94, and Receiving unit 95;
  • the allocating unit 91 is configured to allocate a first control channel to the at least one data channel;
  • the establishing unit 92 is configured to establish a mapping relationship between the first control channel and the data channel according to the first control channel allocated by the allocating unit;
  • the sending unit 93 is configured to notify all the user equipments UE of the mapping relationship established by the establishing unit.
  • the scheduling information generating unit 94 is configured to allocate time-frequency resources to the target UE according to the mapping relationship established by the establishing unit and the identifier of the target UE. Position information, and obtaining first scheduling information of the at least one data channel according to the time-frequency resource location information, where the first scheduling information causes the target UE to perform data transmission according to the time-frequency resource location information;
  • the receiving unit 95 is configured to receive uplink data sent by the at least one target UE by using the at least one data channel;
  • the sending unit 93 is further configured to send, by using the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs.
  • the first scheduling information may include: an identifier of the target UE.
  • the first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
  • the sending unit 93 is also used to
  • the identifier of the target UE is one in the first scheduling information.
  • the sending unit 93 performs an exclusive OR operation on all the fields or partial resources of the identifier of the target UE and the cyclic redundancy check code CRC in the first control channel;
  • the scheduling information generating unit 94 is further configured to determine Second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
  • the sending unit 93 is further configured to send the second scheduling information and/or the feedback information to all UEs by using the second control channel.
  • the foregoing time-frequency resource location may be a location of the virtual resource corresponding to the time-frequency resource; or the foregoing time-frequency resource location may be a physical location of the time-frequency resource; or the foregoing time-frequency resource
  • the location may be relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
  • the communication device further includes a determining unit 96 not shown in the figure; the determining unit 96 is configured to determine a ratio of the UI and the DI in the first scheduling information, and
  • the UI and the DI are sent to the UE by using the same control channel, the UI and the DI are differentiated by using different time slots; or
  • the UI and the DI are sent to the UE by using different control channels; or
  • the uplink indication carried by the UI in the control slot of the control channel is different from the downlink carried by the DI in the control slot of the control channel.
  • the sending unit 93 is also used to
  • the above communication device flexibly configures the UI and DI of the scheduled data channel to implement half-duplex FDD Reasonable scheduling of resources in the system improves the resource allocation efficiency of the half-duplex FDD system.
  • FIG. 10 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • the user equipment in this embodiment includes: a receiving unit 1001, a sending unit 1002, and a processing unit 1003.
  • the receiving unit 1001 is configured to monitor a mapping relationship that is sent by the network side device, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel.
  • the sending unit 1002 is configured to send uplink data to the network side device by using the at least one data channel when the UE is a target UE;
  • the receiving unit 1001 is configured to: after the transmitting unit 1002 sends the uplink data, receive first scheduling information that is sent by the network side device by using the first control channel, and feedback information of the uplink data, where The first scheduling information is obtained by the network side device according to the mapping relationship and the identifier of the target UE;
  • the processing unit 1003 is configured to: after the receiving unit 1001 receives the first scheduling information, perform data transmission according to the first scheduling information, and process feedback information of the uplink data.
  • the first scheduling information may include: an identifier of the target UE.
  • the foregoing first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
  • the receiving unit 1001 is further configured to: before the processing unit 1003 performs data transmission, receive time-frequency resource location information sent by the network-side device, where the time-frequency resource location information is The time-frequency resource location information of the data channel that the first control channel can schedule.
  • the receiving unit 1001 when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the receiving unit 1001 is further used.
  • the processing unit 1003 is further configured to: after the receiving unit receives the second scheduling information, perform data transmission according to the second scheduling information, and/or process the feedback information.
  • the second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
  • the foregoing time-frequency resource location may be a location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be a physical location of the time-frequency resource; or, the time-frequency resource bit
  • the relative position information in the time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel may be set.
  • the receiving unit 1001 is further configured to: before the processing unit 1003 performs data transmission, receive the UI and the first scheduling information sent by the network side device.
  • the user equipment interacts with the network side device to implement reasonable scheduling of resources in the half-duplex FDD system and improve the resource allocation efficiency of the half-duplex FDD system.
  • the foregoing storage medium includes: a medium that can store program codes, such as a ROM, a RAM, a magnetic disk, or an optical disk.

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Abstract

Provided are a resource scheduling method, and a data transmission method and equipment. The resource scheduling method comprises: network side equipment allocating a first control channel to at least one data channel, establishing a mapping relation between the first control channel and the data channel, and notifying all UE (User Equipment) of the mapping relation; the network side equipment allocating time frequency resource location information to target UE according to the mapping relation and the identification of the target UE and obtaining first scheduling information of the at least one data channel according to the time frequency resource location information, and the first scheduling information allowing for the target UE to perform data transmission according to the time frequency resource location information; the network side equipment receiving, through the at least one data channel, uplink data sent by at least one target UE; and the network side equipment sending the first scheduling information and the feedback information of the uplink data to all the UE through the first control channel. The method described above enables an increase in the rate of utilization of resources in a narrowband system.

Description

资源调度方法、 数据传输方法及设备  Resource scheduling method, data transmission method and device
技术领域 Technical field
本发明实施例涉及通信技术, 尤其涉及一种资源调度方法、 数据传输方 法及设备。  The embodiments of the present invention relate to communication technologies, and in particular, to a resource scheduling method, a data transmission method, and a device.
背景技术 Background technique
目前, 集中控制为主导的蜂窝网络中, 窄带系统为了提高系统容量, 提 出了多信道的技术方案。 例如, 为了减少多用户设备(User Equipment, 简称 UE)使用同一信道进行数据发送时发送碰撞的概率, 将信道中的少部分信道 设置为数据信道, 其他信道设置为控制信道, 进而实现提高用户设备随机接 入的成功率。  At present, in the centralized control of the dominant cellular network, the narrowband system proposes a multi-channel technical solution in order to increase the system capacity. For example, in order to reduce the probability of a user equipment (User Equipment, UE for short) transmitting a collision when using the same channel for data transmission, a small number of channels in the channel are set as data channels, and other channels are set as control channels, thereby improving user equipment. The success rate of random access.
然而, 在窄带系统中, 单信道中单帧的信息速率比较低, 使得控制信道 中携带控制信令的长度受限, 从而造成单个控制帧只能发送几十个比特的控 制 息。  However, in a narrowband system, the information rate of a single frame in a single channel is relatively low, so that the length of control signaling carried in the control channel is limited, so that a single control frame can only transmit control information of several tens of bits.
为此, 窄带系统中, 为了提升信号的覆盖范围, 只能采用增加数据发送 的重复次数, 如图 1所示, 网络侧的基站覆盖的 A区域的重复次数可为 IX、 基站覆盖的 B区域、 C区域的重复次数可为 8X或其它重复次数。 针对不同信 号的覆盖要求, 可使不同信道的重复次数不同, 从而使得用户设备可以选择 匹配的信道进行数据传输。 此外, 为使信道增加灵活性, 还可保留部分信道 进行竞争使用, 如图 2所示。  Therefore, in the narrowband system, in order to improve the coverage of the signal, only the number of repetitions of data transmission can be increased. As shown in FIG. 1, the number of repetitions of the A area covered by the base station on the network side can be IX, and the B area covered by the base station. The number of repetitions of the C region can be 8X or other repetitions. For different coverage requirements of different signals, the number of repetitions of different channels can be different, so that the user equipment can select a matching channel for data transmission. In addition, in order to increase the flexibility of the channel, part of the channel can be reserved for competitive use, as shown in Figure 2.
当前, 为降低用户设备的成本, 用户设备可采用频分双工 (Frequency Division Duplexing, 简称 FDD) 方式与基站进行通信, 基站则采用大带宽、 全双工的方式, 从而形成半双工 FDD系统。  Currently, in order to reduce the cost of the user equipment, the user equipment can communicate with the base station by means of Frequency Division Duplexing (FDD), and the base station adopts a large bandwidth and full duplex mode to form a half-duplex FDD system. .
在半双工 FDD系统中, 基站在接收用户设备发送的数据的同时, 也可以 发送数据给其它用户设备, 也就是说, 在半双工 FDD系统中, 如果同时存在 多个上行数据信道和下行数据信道, 会出现控制信道受限的问题, 因此, 在 半双工 FDD系统中,同时存在多个上行数据信道和 /或多个下行数据信道的情 况下, 如何进行资源调度是需要解决的问题。 发明内容 In a half-duplex FDD system, the base station can also transmit data to other user equipments while receiving data sent by the user equipment, that is, in a half-duplex FDD system, if multiple uplink data channels and downlinks exist simultaneously In the data channel, there is a problem that the control channel is limited. Therefore, in a half-duplex FDD system, when there are multiple uplink data channels and/or multiple downlink data channels, how to perform resource scheduling is a problem to be solved. . Summary of the invention
本发明实施例提供一种资源调度方法、 数据传输方法及设备, 用以实现 半双工 FDD系统中资源的合理调度, 提高半双工 FDD系统的资源分配效率。  The embodiments of the present invention provide a resource scheduling method, a data transmission method, and a device, which are used to implement reasonable scheduling of resources in a half-duplex FDD system, and improve resource allocation efficiency of a half-duplex FDD system.
第一方面, 本发明实施例提供一种资源调度方法, 包括:  In a first aspect, an embodiment of the present invention provides a resource scheduling method, including:
网络侧设备为至少一个数据信道分配第一控制信道, 建立所述第一控制 信道和所述数据信道的映射关系, 并将所述映射关系通知全部用户设备 UE; 所述网络侧设备根据所述映射关系和目标 UE的标识为所述目标 UE分配 时频资源位置信息, 并根据所述时频资源位置信息获得所述至少一个数据信 道的第一调度信息,所述第一调度信息使所述目标 UE根据所述时频资源位置 信息进行数据传输;  The network side device allocates a first control channel to the at least one data channel, establishes a mapping relationship between the first control channel and the data channel, and notifies the user equipment UE of the mapping relationship; The mapping relationship and the identifier of the target UE allocate time-frequency resource location information to the target UE, and obtain first scheduling information of the at least one data channel according to the time-frequency resource location information, where the first scheduling information is The target UE performs data transmission according to the time-frequency resource location information;
所述网络侧设备通过所述至少一个数据信道接收至少一个目标 UE 发送 的上行数据;  Receiving, by the network side device, the uplink data sent by the at least one target UE by using the at least one data channel;
所述网络侧设备通过所述第一控制信道向所述全部 UE 发送所述第一调 度信息和所述上行数据的反馈信息。  The network side device sends the first scheduling information and the feedback information of the uplink data to all UEs by using the first control channel.
结合第一方面, 在第一种可能的实现方式中, 所述第一调度信息包括: 目标 UE的标识;  With reference to the first aspect, in a first possible implementation manner, the first scheduling information includes: an identifier of a target UE;
或者,  Or,
目标 UE的标识;  The identity of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。  The time-frequency resource location information of the data channel that the first control channel can schedule.
结合第一方面, 在第二种可能的实现方式中, 所述网络侧设备通过所述 第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数据的反馈 信息之后, 所述方法还包括:  With reference to the first aspect, in a second possible implementation, after the network side device sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel, The method also includes:
所述网络侧设备将第一控制信道能够调度的数据信道的时频资源位置信 息通知所述全部 UE。  The network side device notifies the all UEs of time-frequency resource location information of a data channel that can be scheduled by the first control channel.
结合第一方面及上述第一方面的其他可能的实现方式, 在第三种可能的 实现方式中, 在所述第一调度信息中目标 UE的标识为一个时, 所述网络侧设 备通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行 数据的反馈信息; 包括:  With reference to the first aspect and other possible implementation manners of the foregoing first aspect, in a third possible implementation, when the identifier of the target UE is one in the first scheduling information, the network side device passes the Transmitting, by the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs;
所述网络侧设备将所述目标 UE 的标识的全部字段或部分资源与所述第 一控制信道中的循环冗余校验码 CRC进行异或运算; The network side device uses all fields or partial resources of the identifier of the target UE with the first The cyclic redundancy check code CRC in a control channel performs an exclusive OR operation;
所述网络侧设备将所述反馈信息和异或运算之后的信息发送至所述全部 结合第一方面及上述第一方面的第一、 第二种可能的实现方式, 在第四 种可能的实现方式中, 在所述数据信道的数量小于预设第一阈值, 且控制信 道的数量大于预设的第二阈值时, 所述方法还包括:  Transmitting, by the network side device, the feedback information and the information after the exclusive OR operation to the first and second possible implementation manners of the first aspect and the first aspect, in a fourth possible implementation The method further includes: when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the method further includes:
所述网络侧设备确定第二控制信道的第二调度信息, 所述第二调度信息 用于为目标 UE分配所述第二控制信道中的时频资源位置信息;  The network side device determines second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
所述网络侧设备通过所述第二控制信道向所述全部 UE 发送所述第二调 度信息和 /或所述反馈信息。  The network side device sends the second scheduling information and/or the feedback information to all UEs through the second control channel.
结合第一方面及上述第一方面的第一、 第二、 第三种可能的实现方式, 在第五种可能的实现方式中,  With reference to the first aspect and the first, second, and third possible implementation manners of the foregoing first aspect, in a fifth possible implementation manner,
所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 所述时频资源位置为所述时频资源的物理位置; 或者,  The time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location is a physical location of the time-frequency resource; or
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。  The time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
结合第一方面及上述第一方面的其他可能的实现方式, 在第六种可能的 实现方式中,所述网络侧设备通过所述第一控制信道向所述全部 UE发送所述 第一调度信息和所述上行数据的反馈信息之前, 所述方法还包括:  With reference to the first aspect and other possible implementation manners of the foregoing first aspect, in a sixth possible implementation, the network side device sends the first scheduling information to all the UEs by using the first control channel. And before the feedback information of the uplink data, the method further includes:
所述网络侧设备确定所述第一调度信息中上行调度信息 UI 和下行调度 信息 DI的配比, 以及所述 UI和所述 DI在所述第一控制信道中的位置信息。  The network side device determines a ratio of the uplink scheduling information UI and the downlink scheduling information DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
结合第一方面及上述第一方面的第六种可能的实现方式, 在第七种可能 的实现方式中,  With reference to the first aspect and the sixth possible implementation manner of the foregoing first aspect, in a seventh possible implementation manner,
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI和所述 DI采用不同的时隙配比区分; 或者,  When the UI and the DI are sent to the UE by using the same control channel, the UI and the DI are differentiated by using different time slots; or
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者, 所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。  The UI and the DI are sent to the UE by using different control channels; or, when the UI and the DI are sent to the UE by using the same control channel, the UI is carried in a control slot of the control channel. The uplink indication is different from the downlink indication carried by the DI in the control slot of the control channel.
结合第一方面及上述第一方面的第六、 第七种可能的实现方式, 在第八 种可能的实现方式中, Combining the first aspect with the sixth and seventh possible implementations of the first aspect above, in the eighth Possible implementations,
所述网络侧设备通过所述第一控制信道向所述全部 UE 发送所述第一调 度信息和所述上行数据的反馈信息之前 /之后, 所述方法还包括:  Before the network side device sends the first scheduling information and the feedback information of the uplink data to the all UEs by using the first control channel, the method further includes:
所述网络侧设备将所述第一调度信息中所述 UI和所述 DI的配比发送至 所述全部 UE; 和 /或,  Transmitting, by the network side device, the ratio of the UI and the DI in the first scheduling information to all UEs; and/or,
所述网络侧设备将所述第一调度信息中所述 UI和所述 DI的区分方式发 送至所述全部 UE; 和 /或,  Transmitting, by the network side device, the manner in which the UI and the DI in the first scheduling information are differentiated to all UEs; and/or,
所述网络侧设备将所述 UI 所能调度的最大上行时频资源数量发送至所 述全部 UE; 和 /或,  Transmitting, by the network side device, the maximum uplink time-frequency resource that can be scheduled by the UI to all UEs; and/or,
所述网络侧设备将所述 DI 所能调度的最大下行时频资源数量发送至所 述全部 UE。  The network side device sends the maximum downlink time-frequency resource quantity that the DI can schedule to all the UEs.
第二方面, 本发明实施例提供一种数据传输方法, 包括:  In a second aspect, an embodiment of the present invention provides a data transmission method, including:
所有用户设备 UE监听网络侧设备发送的映射关系,所述映射关系为第一 控制信道和至少一个数据信道的映射关系;  The mapping relationship sent by the network device is monitored by the user equipment UE, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
所述所有 UE中的目标 UE通过所述至少一个数据信道向所述网络侧设备 发送上行数据;  The target UE in all the UEs sends uplink data to the network side device by using the at least one data channel;
所述所有 UE 接收所述网络侧设备通过所述第一控制信道发送的第一调 度信息和所述上行数据的反馈信息, 所述第一调度信息为所述网络侧设备根 据所述映射关系和所述目标 UE的标识获得的;  All the UEs receive the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and Obtained by the identifier of the target UE;
所述目标 UE根据所述第一调度信息进行数据传输,并处理所述上行数据 的反馈信息。  The target UE performs data transmission according to the first scheduling information, and processes feedback information of the uplink data.
结合第二方面, 在第一种可能的实现方式中, 所述第一调度信息包括: 目标 UE的标识;  With reference to the second aspect, in a first possible implementation manner, the first scheduling information includes: an identifier of a target UE;
或者,  Or,
目标 UE的标识;  The identity of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。  The time-frequency resource location information of the data channel that the first control channel can schedule.
结合第二方面, 在第二种可能的实现方式中, 所述目标 UE根据所述第一 调度信息进行数据传输之前, 所述方法还包括:  With reference to the second aspect, in a second possible implementation manner, before the target UE performs data transmission according to the first scheduling information, the method further includes:
所述所有 UE 接收所述网络侧设备发送的时频资源位置信息, 所述时频 资源位置信息为所述第一控制信道能够调度的数据信道的时频资源位置信 结合第二方面及第二方面的上述可能的实现方式, 在第三种可能的实现 方式中, 在所述数据信道的数量小于预设第一阈值, 且控制信道的数量大于 预设的第二阈值时, 所述方法还包括: All the UEs receive the time-frequency resource location information sent by the network side device, where the time-frequency resource location information is a time-frequency resource location information of the data channel that can be scheduled by the first control channel. With reference to the second aspect and the foregoing possible implementation manner of the second aspect, in a third possible implementation manner, the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second The threshold further includes:
所述所有 UE 接收所述网络侧设备通过所述第二控制信道发送的第二调 度信息和 /或所述反馈信息;  All the UEs receive the second scheduling information and/or the feedback information sent by the network side device by using the second control channel;
所述目标 UE根据所述第二调度信息进行数据传输, 和 /或处理所述反馈 信息。  The target UE performs data transmission according to the second scheduling information, and/or processes the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。  The second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
结合第二方面及第二方面的第一、 第二种可能的实现方式, 在第四种可 能的实现方式中,所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者,  With reference to the second aspect and the first and second possible implementation manners of the second aspect, in a fourth possible implementation, the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or ,
所述时频资源位置为所述时频资源的物理位置; 或者,  The time-frequency resource location is a physical location of the time-frequency resource; or
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。  The time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
结合第二方面及第二方面的第一、 第二种可能的实现方式, 在第五种可 能的实现方式中,  With reference to the second aspect and the first and second possible implementation manners of the second aspect, in a fifth possible implementation manner,
所述目标 UE 根据所述第一调度信息进行数据传输之前, 所述方法还包 括:  Before the target UE performs data transmission according to the first scheduling information, the method further includes:
所述所有 UE接收所述网络侧设备发送的所述第一调度信息中所述 UI和 所述 DI的配比, 和 /或,  Receiving, by the UE, the ratio of the UI and the DI in the first scheduling information sent by the network side device, and/or,
所述所有 UE接收所述网络侧设备发送的所述第一调度信息中所述 UI和 所述 DI的区分方法, 和 /或,  Receiving, by the UE, the UI and the DI distinguishing method in the first scheduling information sent by the network side device, and/or,
所述所有 UE接收所述网络侧设备发送的所述 UI所能调度的最大上行时 频资源数量, 和 /或,  Receiving, by the UE, the maximum number of uplink time-frequency resources that can be scheduled by the UI sent by the network side device, and/or,
所述所有 UE接收所述网络侧设备发送的所述 DI所能调度的最大下行时 频资源数量。  And all the UEs receive the maximum downlink time-frequency resource that can be scheduled by the DI sent by the network side device.
第三方面, 本发明实施例提供一种通信设备, 包括:  In a third aspect, an embodiment of the present invention provides a communications device, including:
存储器和处理器; 所述存储器用于存储指令; Memory and processor; The memory is for storing instructions;
所述处理器执行所述存储器中存储的指令, 用于:  The processor executes instructions stored in the memory for:
为至少一个数据信道分配第一控制信道, 建立所述第一控制信道和所述 数据信道的映射关系, 并将所述映射关系通知全部用户设备 UE;  Allocating a first control channel to the at least one data channel, establishing a mapping relationship between the first control channel and the data channel, and notifying the user equipment UE of the mapping relationship;
根据所述映射关系和目标 UE的标识为所述目标 UE分配时频资源位置信 息, 并根据所述时频资源位置信息获得所述至少一个数据信道的第一调度信 息,所述第一调度信息使所述目标 UE根据所述时频资源位置信息进行数据传 输;  Allocating time-frequency resource location information to the target UE according to the mapping relationship and the identifier of the target UE, and obtaining first scheduling information of the at least one data channel according to the time-frequency resource location information, the first scheduling information And causing the target UE to perform data transmission according to the time-frequency resource location information;
通过所述至少一个数据信道接收至少一个目标 UE发送的上行数据; 通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上 行数据的反馈信息。  Receiving uplink data sent by the at least one target UE by using the at least one data channel; and transmitting, by using the first control channel, the first scheduling information and the feedback information of the uplink data to the all UEs.
结合第三方面, 在第一种可能的实现方式中, 所述第一调度信息包括: 目标 UE的标识;  With reference to the third aspect, in a first possible implementation, the first scheduling information includes: an identifier of a target UE;
或者,  Or,
目标 UE的标识;  The identity of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。  The time-frequency resource location information of the data channel that the first control channel can schedule.
结合第三方面, 在第二种可能的实现方式中, 所述处理器通过所述第一 控制信道向所述全部 UE 发送所述第一调度信息和所述上行数据的反馈信息 之后, 还用于  With reference to the third aspect, in a second possible implementation manner, after the processor sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel, Yu
将第一控制信道能够调度的数据信道的时频资源位置信息通知所述全部 结合第三方面及第三方面的上述可能的实现方式, 在第三种可能的实现 方式中, 在所述第一调度信息中目标 UE的标识为一个时, 所述处理器通过所 述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数据的反 馈信息; 包括:  Notifying the time-frequency resource location information of the data channel that can be scheduled by the first control channel to all of the foregoing possible implementations in combination with the third aspect and the third aspect, in a third possible implementation manner, in the first When the identifier of the target UE in the scheduling information is one, the processor sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel;
所述处理器将所述目标 UE 的标识的全部字段或部分资源与所述第一控 制信道中的循环冗余校验码 CRC进行异或运算;  The processor performs an exclusive OR operation on all or a part of the identifier of the target UE with a cyclic redundancy check code CRC in the first control channel;
将所述反馈信息和异或运算之后的信息发送至所述全部 UE。  The feedback information and the information after the exclusive OR operation are transmitted to the all UEs.
结合第三方面及第三方面的第一、 第二种可能的实现方式, 在第四种可 能的实现方式中, , 在所述数据信道的数量小于预设第一阈值, 且控制信道 的数量大于预设的第二阈值时, 所述处理器还用于: With reference to the third aspect and the first and second possible implementation manners of the third aspect, in a fourth possible implementation manner, the number of the data channels is less than a preset first threshold, and the control channel is When the number is greater than a preset second threshold, the processor is further configured to:
确定第二控制信道的第二调度信息,所述第二调度信息用于为目标 UE分 配所述第二控制信道中的时频资源位置信息;  Determining second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
通过所述第二控制信道向所述全部 UE发送所述第二调度信息和 /或所述 反馈信息。  And transmitting, by the second control channel, the second scheduling information and/or the feedback information to all UEs.
结合第三方面及第三方面的第一、 第二、 第三种可能的实现方式, 在第 五种可能的实现方式中, 所述时频资源位置为所述时频资源对应的虚拟资源 的位置; 或者,  With reference to the third aspect and the first, second, and third possible implementation manners of the third aspect, in a fifth possible implementation, the time-frequency resource location is a virtual resource corresponding to the time-frequency resource. Location; or,
所述时频资源位置为所述时频资源的物理位置; 或者,  The time-frequency resource location is a physical location of the time-frequency resource; or
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。  The time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
结合第三方面及第三方面的上述可能的实现方式, 在第六种可能的实现 方式中,所述处理器通过所述第一控制信道向所述全部 UE发送所述第一调度 信息和所述上行数据的反馈信息之前, 还用于  With reference to the third aspect and the foregoing possible implementation manner of the third aspect, in a sixth possible implementation manner, the processor sends the first scheduling information and the information to all the UEs by using the first control channel. Before the feedback information of the uplink data is used,
确定所述第一调度信息中上行调度信息 UI和下行调度信息 DI的配比, 以及所述 UI和所述 DI在所述第一控制信道中的位置信息。  Determining a ratio of the uplink scheduling information UI and the downlink scheduling information DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
结合第三方面及第三方面的第六种可能的实现方式, 在第七种可能的实 现方式中, 所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI 和所述 DI采用不同的时隙配比区分; 或者,  With reference to the third aspect and the sixth possible implementation manner of the third aspect, in a seventh possible implementation manner, when the UI and the DI are sent to the UE by using the same control channel, the UI and the The DI is differentiated by different time slot ratios; or
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者,  The UI and the DI are sent to the UE by using different control channels; or
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。  When the UI and the DI are sent to the UE by using the same control channel, the uplink indication carried by the UI in the control slot of the control channel is different from the downlink carried by the DI in the control slot of the control channel. Instructions.
结合第三方面及第三方面的第六、 第七种可能的实现方式, 在第八种可 能的实现方式中,所述处理器通过所述第一控制信道向所述全部 UE发送所述 第一调度信息和所述上行数据的反馈信息之前 /之后, 还用于:  With reference to the third aspect and the sixth and seventh possible implementation manners of the third aspect, in an eighth possible implementation, the processor sends the foregoing to the all UEs by using the first control channel Before/after the scheduling information and the feedback information of the uplink data, it is also used to:
将所述第一调度信息中所述 UI和所述 DI的配比发送至所述全部 UE; 和 Transmitting a ratio of the UI and the DI in the first scheduling information to the all UEs; and
/或, / or,
将所述第一调度信息中所述 UI和所述 DI的区分方式发送至所述全部 UE; 和 /或, 将所述 UI所能调度的最大上行时频资源数量发送至所述全部 UE;和 /或, 将所述 DI所能调度的最大下行时频资源数量发送至所述全部 UE。 Transmitting the UI and the DI in the first scheduling information to the all UEs; and/or, And sending, to the all UEs, the maximum number of uplink time-frequency resources that can be scheduled by the UI; and/or sending the maximum downlink time-frequency resource that can be scheduled by the DI to all the UEs.
第四方面, 本发明实施例提供一种用户设备, 包括:  In a fourth aspect, an embodiment of the present invention provides a user equipment, including:
存储器和处理器;  Memory and processor;
所述存储器用于存储指令;  The memory is for storing instructions;
所述处理器执行所述存储器中存储的指令, 用于:  The processor executes instructions stored in the memory for:
监听网络侧设备发送的映射关系, 所述映射关系为第一控制信道和至少 一个数据信道的映射关系;  The mapping relationship sent by the network side device is monitored, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
在所述用户设备 UE为目标 UE时, 通过所述至少一个数据信道向所述网 络侧设备发送上行数据,  When the user equipment UE is the target UE, sending uplink data to the network side device by using the at least one data channel,
接收所述网络侧设备通过所述第一控制信道发送的第一调度信息和所述 上行数据的反馈信息, 所述第一调度信息为所述网络侧设备根据所述映射关 系和所述目标 UE的标识获得的;  And receiving the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and the target UE Obtained by the logo;
根据所述第一调度信息进行数据传输,并处理所述上行数据的反馈信息。 结合第四方面, 在第一种可能的实现方式中, 所述第一调度信息包括: 目标 UE的标识;  Performing data transmission according to the first scheduling information, and processing feedback information of the uplink data. With reference to the fourth aspect, in a first possible implementation manner, the first scheduling information includes: an identifier of a target UE;
或者,  Or,
目标 UE的标识;  The identity of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。  The time-frequency resource location information of the data channel that the first control channel can schedule.
结合第四方面, 在第二种可能的实现方式中, 所述处理器根据所述第一 调度信息进行数据传输之前, 还用于  With reference to the fourth aspect, in a second possible implementation manner, before the performing data transmission by the processor according to the first scheduling information,
接收所述网络侧设备发送的时频资源位置信息, 所述时频资源位置信息 为所述第一控制信道能够调度的数据信道的时频资源位置信息。  Receiving time-frequency resource location information sent by the network side device, where the time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
结合第四方面及第四方面的上述可能的实现方式, 在第三种可能的实现 方式中, 在所述数据信道的数量小于预设第一阈值, 且控制信道的数量大于 预设的第二阈值时, 所述处理器还用于  With the fourth aspect and the foregoing possible implementation manner of the fourth aspect, in a third possible implementation manner, the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second The threshold is also used by the processor
接收所述网络侧设备通过所述第二控制信道发送的第二调度信息和 /或 所述反馈信息;  Receiving second scheduling information and/or the feedback information that is sent by the network side device by using the second control channel;
根据所述第二调度信息进行数据传输, 和 /或处理所述反馈信息。  Data transmission is performed according to the second scheduling information, and/or the feedback information is processed.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。 The second scheduling information is included in the second control channel acquired by the network side device. The second scheduling information of the target UE identifier.
结合第四方面及第四方面的第一、 第二种可能的实现方式, 在第四种可 能的实现方式中,所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者,  With reference to the fourth aspect and the first and second possible implementation manners of the fourth aspect, in a fourth possible implementation, the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or ,
所述时频资源位置为所述时频资源的物理位置; 或者,  The time-frequency resource location is a physical location of the time-frequency resource; or
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。  The time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
结合第四方面及第四方面的第一、 第二种可能的实现方式, 在第五种可 能的实现方式中, 所述处理器根据所述第一调度信息进行数据传输之前, 还 用于  With reference to the fourth aspect, the first and second possible implementation manners of the fourth aspect, in a fifth possible implementation manner, before the performing data transmission by the processor according to the first scheduling information,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的配 比, 和 /或,  Receiving, by the network side device, the ratio of the UI and the DI in the first scheduling information, and/or,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区 分方法, 和 /或,  Receiving, by the network side device, the method for distinguishing the UI and the DI in the first scheduling information, and/or,
接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资源数量, 和 /或,  Receiving, by the network side device, the maximum uplink time-frequency resource that can be scheduled by the UI, and/or,
接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资源数量。 第五方面, 本发明实施例提供一种通信设备, 包括:  And receiving, by the network side device, the maximum downlink time-frequency resource that can be scheduled by the DI. A fifth aspect of the present invention provides a communications device, including:
分配单元, 用于为至少一个数据信道分配第一控制信道;  An allocating unit, configured to allocate a first control channel to the at least one data channel;
建立单元, 用于根据分配单元分配的第一控制信道, 建立所述第一控制 信道和所述数据信道的映射关系;  And an establishing unit, configured to establish, according to the first control channel allocated by the allocating unit, a mapping relationship between the first control channel and the data channel;
发送单元, 用于将所述建立单元建立的映射关系通知全部用户设备 UE; 调度信息生成单元,用于根据所述建立单元建立的映射关系和目标 UE的 标识为所述目标 UE分配时频资源位置信息,并根据所述时频资源位置信息获 得所述至少一个数据信道的第一调度信息, 所述第一调度信息使所述目标 UE 根据所述时频资源位置信息进行数据传输;  a sending unit, configured to notify all the user equipments UE of the mapping relationship established by the establishing unit, where the scheduling information generating unit is configured to allocate time-frequency resources to the target UE according to the mapping relationship established by the establishing unit and the identifier of the target UE Position information, and obtaining first scheduling information of the at least one data channel according to the time-frequency resource location information, where the first scheduling information causes the target UE to perform data transmission according to the time-frequency resource location information;
接收单元,用于通过所述至少一个数据信道接收至少一个目标 UE发送的 上行数据;  a receiving unit, configured to receive, by using the at least one data channel, uplink data sent by at least one target UE;
所述发送单元,还用于通过所述第一控制信道向所述全部 UE发送所述第 一调度信息和所述上行数据的反馈信息。 结合第五方面, 在第一种可能的实现方式中, 所述第一调度信息包括: 目标 UE的标识; The sending unit is further configured to send, by using the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs. With reference to the fifth aspect, in a first possible implementation manner, the first scheduling information includes: an identifier of a target UE;
或者,  Or,
目标 UE的标识;  The identity of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。  The time-frequency resource location information of the data channel that the first control channel can schedule.
结合第五方面, 在第二种可能的实现方式中, 所述发送单元, 还用于 在通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述 上行数据的反馈信息之后, 将第一控制信道能够调度的数据信道的时频资源 位置信息通知所述全部 UE。  With reference to the fifth aspect, in a second possible implementation, the sending unit is further configured to send, by using the first control channel, the first scheduling information and the uplink data to the UE After the information, the time-frequency resource location information of the data channel that can be scheduled by the first control channel is notified to all the UEs.
结合第五方面及第五方面的上述可能的实现方式, 在第三种可能的实现 方式中, 在所述第一调度信息中目标 UE的标识为一个时, 所述发送单元将所 述目标 UE 的标识的全部字段或部分资源与所述第一控制信道中的循环冗余 校验码 CRC进行异或运算;  With reference to the fifth aspect and the foregoing possible implementation manners of the fifth aspect, in a third possible implementation manner, when the identifier of the target UE is one in the first scheduling information, the sending unit sends the target UE All or part of the identifier of the identifier is XORed with the cyclic redundancy check code CRC in the first control channel;
并将所述反馈信息和异或运算之后的信息发送至所述全部 UE。  And transmitting the feedback information and the information after the XOR operation to the all UEs.
结合第五方面及第五方面的第一、 第二种可能的实现方式, 在第四种可 能的实现方式中, 在所述数据信道的数量小于预设第一阈值, 且控制信道的 数量大于预设的第二阈值时, 所述调度信息生成单元, 还用于  With reference to the fifth aspect and the first and second possible implementation manners of the fifth aspect, in a fourth possible implementation manner, the quantity of the data channel is less than a preset first threshold, and the number of control channels is greater than When the second threshold is preset, the scheduling information generating unit is further used to
确定第二控制信道的第二调度信息,所述第二调度信息用于为目标 UE分 配所述第二控制信道中的时频资源位置信息;  Determining second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
所述发送单元,还用于通过所述第二控制信道向所述全部 UE发送所述第 二调度信息和 /或所述反馈信息。  The sending unit is further configured to send the second scheduling information and/or the feedback information to all UEs by using the second control channel.
结合第五方面及第五方面的第一、 第二、 第三种可能的实现方式, 在第 五种可能的实现方式中, 所述时频资源位置为所述时频资源对应的虚拟资源 的位置; 或者,  With reference to the first, second, and third possible implementation manners of the fifth aspect and the fifth aspect, in a fifth possible implementation, the time-frequency resource location is a virtual resource corresponding to the time-frequency resource Location; or,
所述时频资源位置为所述时频资源的物理位置; 或者,  The time-frequency resource location is a physical location of the time-frequency resource; or
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。  The time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
结合第五方面及第五方面的上述可能的实现方式, 在第六种可能的实现 方式中, 所述通信设备还包括: 确定单元;  With the fifth aspect and the foregoing possible implementation manner of the fifth aspect, in a sixth possible implementation, the communications device further includes: a determining unit;
所述确定单元用于确定所述第一调度信息中上行调度信息 UI 和下行调 度信息 DI的配比,以及所述 UI和所述 DI在所述第一控制信道中的位置信息。 结合第五方面及第五方面的第六种可能的实现方式, 在第七种可能的实 现方式中, 所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI 和所述 DI采用不同的时隙配比区分; 或者, The determining unit is configured to determine an uplink scheduling information UI and a downlink adjustment in the first scheduling information. a ratio of the degree information DI, and location information of the UI and the DI in the first control channel. With reference to the fifth aspect, the sixth possible implementation manner of the fifth aspect, in a seventh possible implementation manner, when the UI and the DI are sent to the UE by using the same control channel, the UI and the The DI is differentiated by different time slot ratios; or
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者,  The UI and the DI are sent to the UE by using different control channels; or
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。  When the UI and the DI are sent to the UE by using the same control channel, the uplink indication carried by the UI in the control slot of the control channel is different from the downlink carried by the DI in the control slot of the control channel. Instructions.
结合第五方面及第五方面的第六、 第七种可能的实现方式, 在第八种可 能的实现方式中, 所述发送单元, 还用于  With reference to the fifth aspect and the sixth and seventh possible implementation manners of the fifth aspect, in an eighth possible implementation, the sending unit is further used to
将所述第一调度信息中所述 UI和所述 DI的配比发送至所述全部 UE; 和 Transmitting a ratio of the UI and the DI in the first scheduling information to the all UEs; and
/或, / or,
将所述第一调度信息中所述 UI和所述 DI的区分方式发送至所述全部 UE; 和 /或,  Transmitting, by the first scheduling information, the manner in which the UI and the DI are differentiated to all UEs; and/or,
将所述 UI所能调度的最大上行时频资源数量发送至所述全部 UE;和 /或, 将所述 DI所能调度的最大下行时频资源数量发送至所述全部 UE。  And sending, to the all UEs, the maximum number of uplink time-frequency resources that can be scheduled by the UI; and/or sending the maximum downlink time-frequency resource that can be scheduled by the DI to all the UEs.
第六方面, 本发明实施例提供一种用户设备, 包括:  In a sixth aspect, an embodiment of the present invention provides a user equipment, including:
接收单元, 用于监听网络侧设备发送的映射关系, 所述映射关系为第一 控制信道和至少一个数据信道的映射关系;  a receiving unit, configured to monitor a mapping relationship sent by the network side device, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
发送单元, 用于在所述用户设备 UE为目标 UE时, 通过所述至少一个数 据信道向所述网络侧设备发送上行数据;  a sending unit, configured to send uplink data to the network side device by using the at least one data channel when the user equipment UE is a target UE;
所述接收单元, 用于在所述发送单元发送所述上行数据之后, 接收所述 网络侧设备通过所述第一控制信道发送的第一调度信息和所述上行数据的反 馈信息, 所述第一调度信息为所述网络侧设备根据所述映射关系和所述目标 UE的标识获得的;  The receiving unit, configured to: after the transmitting unit sends the uplink data, receive first scheduling information that is sent by the network side device by using the first control channel, and feedback information of the uplink data, where a scheduling information is obtained by the network side device according to the mapping relationship and the identifier of the target UE;
处理单元, 用于在所述接收单元接收所述第一调度信息之后, 根据所述 第一调度信息进行数据传输, 并处理所述上行数据的反馈信息。  a processing unit, configured to: after the receiving unit receives the first scheduling information, perform data transmission according to the first scheduling information, and process feedback information of the uplink data.
结合第六方面, 在第一种可能的实现方式中, 所述第一调度信息包括: 目标 UE的标识;  With reference to the sixth aspect, in a first possible implementation manner, the first scheduling information includes: an identifier of a target UE;
或者, 目标 UE的标识; or, The identity of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。  The time-frequency resource location information of the data channel that the first control channel can schedule.
结合第六方面, 在第二种可能的实现方式中, 所述接收单元, 还用于 在所述处理单元进行数据传输之前, 接收所述网络侧设备发送的时频资 源位置信息, 所述时频资源位置信息为所述第一控制信道能够调度的数据信 道的时频资源位置信息。  With reference to the sixth aspect, in a second possible implementation manner, the receiving unit is further configured to receive time-frequency resource location information sent by the network side device, where the processing unit performs data transmission, where The frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
结合第六方面及第六方面的上述可能的实现方式, 在第三种可能的实现 方式中, 在所述数据信道的数量小于预设第一阈值, 且控制信道的数量大于 预设的第二阈值时, 所述接收单元, 还用于  With the sixth aspect and the foregoing possible implementation manners of the sixth aspect, in a third possible implementation manner, the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second When the threshold is used, the receiving unit is further used for
接收所述网络侧设备通过所述第二控制信道发送的第二调度信息和 /或 所述反馈信息;  Receiving second scheduling information and/or the feedback information that is sent by the network side device by using the second control channel;
所述处理单元, 还用于在所述接收单元接收所述第二调度信息之后, 根 据所述第二调度信息进行数据传输, 和 /或处理所述反馈信息。  The processing unit is further configured to: after the receiving unit receives the second scheduling information, perform data transmission according to the second scheduling information, and/or process the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。  The second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
结合第六方面及第六方面的第一、 第二种可能的实现方式, 在第四种可 能的实现方式中,所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者,  With reference to the sixth aspect and the first and second possible implementation manners of the sixth aspect, in a fourth possible implementation, the time-frequency resource location is a location of the virtual resource corresponding to the time-frequency resource; or ,
所述时频资源位置为所述时频资源的物理位置; 或者,  The time-frequency resource location is a physical location of the time-frequency resource; or
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。  The time-frequency resource location is relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
结合第六方面及第六方面的第一、 第二种可能的实现方式, 在第五种可 能的实现方式中, 所述接收单元还用于  With reference to the sixth aspect, the first and second possible implementation manners of the sixth aspect, in a fifth possible implementation, the receiving unit is further used to
在所述处理单元进行数据传输之前, 接收所述网络侧设备发送的所述第 一调度信息中所述 UI和所述 DI的配比, 和 /或,  Receiving a ratio of the UI and the DI in the first scheduling information sent by the network side device, and/or, before the processing unit performs data transmission,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区 分方法, 和 /或,  Receiving, by the network side device, the method for distinguishing the UI and the DI in the first scheduling information, and/or,
接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资源数量, 和 /或,  Receiving, by the network side device, the maximum uplink time-frequency resource that can be scheduled by the UI, and/or,
接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资源数量。 由上述技术方案可知, 本实施例中的资源调度方法、 数据传输方法及设 备, 通过网络侧设备为至少一个数据信道分配包括第一控制信道, 并建立第 一控制信道与数据信道的映射关系, 进而根据映射关系获得第一调度信息, 网络侧设备在接收目标 UE 发送的上行数据之后将第一调度信息和上行数据 的反馈信息发送 UE,可使得网络侧设备采用统一的控制策略,实现半双工 FDD 系统中资源的合理调度, 提高半双工 FDD系统的资源分配效率。 附图说明 And receiving, by the network side device, the maximum downlink time-frequency resource that can be scheduled by the DI. According to the foregoing technical solution, the resource scheduling method, the data transmission method, and the device in the embodiment allocate a first control channel to the at least one data channel by using the network side device, and establish a mapping relationship between the first control channel and the data channel. And obtaining the first scheduling information according to the mapping relationship, and the network side device sends the first scheduling information and the feedback information of the uplink data to the UE after receiving the uplink data sent by the target UE, so that the network side device adopts a unified control policy to implement the half-double Reasonable scheduling of resources in the FDD system to improve the resource allocation efficiency of the half-duplex FDD system. DRAWINGS
为了更清楚地说明本发明实施例或现有技术中的技术方案, 下面将对实 施例或现有技术描述中所需要使用的附图作一简单地介绍, 显而易见地, 下 面描述中的附图是本发明的一些实施例, 对于本领域普通技术人员来讲, 在 不付出创造性劳动性的前提下, 还可以根据这些附图获得其他的附图。  In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, a brief description of the drawings used in the embodiments or the prior art description will be briefly described below. Obviously, the drawings in the following description It is a certain embodiment of the present invention, and other drawings can be obtained from those skilled in the art without any inventive labor.
图 1为当前基站的覆盖区域示意图;  1 is a schematic diagram of a coverage area of a current base station;
图 2为当前窄带系统中各信道的使用示意图;  2 is a schematic diagram of the use of each channel in the current narrowband system;
图 3为本发明一实施例提供的资源调度方法的流程示意图;  FIG. 3 is a schematic flowchart of a resource scheduling method according to an embodiment of the present invention;
图 4A至图 4F为本发明实施例一的控制信道的资源分配的示意图; 图 5为本发明另一实施例提供的资源调度方法的流程示意图;  4A to FIG. 4F are schematic diagrams showing resource allocation of a control channel according to Embodiment 1 of the present invention; FIG. 5 is a schematic flowchart of a resource scheduling method according to another embodiment of the present invention;
图 6为本发明一实施例提供的数据传输方法的流程示意图;  FIG. 6 is a schematic flowchart of a data transmission method according to an embodiment of the present invention;
图 7为本发明一实施例提供的通信设备的结构示意图;  FIG. 7 is a schematic structural diagram of a communication device according to an embodiment of the present invention;
图 8为本发明一实施例提供的用户设备的结构示意图;  FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention;
图 9为本发明另一实施例提供的通信设备的结构示意图;  FIG. 9 is a schematic structural diagram of a communication device according to another embodiment of the present invention;
图 10为本发明另一实施例提供的用户设备的结构示意图。  FIG. 10 is a schematic structural diagram of a user equipment according to another embodiment of the present invention.
具体实施方式 detailed description
为使本发明实施例的目的、 技术方案和优点更加清楚, 下面将结合本 发明实施例中的附图, 对本发明实施例中的技术方案进行清楚、 完整地描 述, 显然,所描述的实施例是本发明一部分实施例, 而不是全部的实施例。 基于本发明中的实施例, 本领域普通技术人员在没有作出创造性劳动前提 下所获得的所有其他实施例, 都属于本发明保护的范围。  The technical solutions in the embodiments of the present invention will be clearly and completely described in conjunction with the accompanying drawings in the embodiments of the present invention. It is a partial embodiment of the invention, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without creative efforts are within the scope of the present invention.
本发明实施例通过对控制信道的设计, 实现一个控制信道可负责若干个 数据信道的资源分配和调度, 减少用户设备数据发送的碰撞次数, 同时提升 半双工 FDD系统的资源分配效率。 In the embodiment of the present invention, by implementing the control channel, a control channel can be responsible for several The resource allocation and scheduling of the data channel reduces the number of collisions of user equipment data transmission and improves the resource allocation efficiency of the half-duplex FDD system.
图 3示出了本发明一实施例提供的资源调度方法的流程示意图, 如图 3 所示, 本实施例的资源调度方法包括如下内容。  FIG. 3 is a schematic flowchart of a resource scheduling method according to an embodiment of the present invention. As shown in FIG. 3, the resource scheduling method in this embodiment includes the following content.
301、 网络侧设备为至少一个数据信道分配第一控制信道, 建立所述第一 控制信道和所述数据信道的映射关系。  301. The network side device allocates a first control channel to the at least one data channel, and establishes a mapping relationship between the first control channel and the data channel.
至少一个数据信道可包括上行数据信道和下行数据信道。  The at least one data channel can include an uplink data channel and a downlink data channel.
302、 所述网络侧设备将所述映射关系通知全部 UE。  302. The network side device notifies all UEs of the mapping relationship.
举例来说, 网络侧设备如基站可将映射关系通过系统广播或者寻呼消息 通知全部 UE。  For example, a network side device such as a base station can notify all UEs of the mapping relationship through system broadcast or paging messages.
在本实施例中, 该处的全部 UE指的是网络侧设备覆盖区域内的全部 UE。 可选地, 在第一控制信息和所述数据信道的映射关系发生改变时, 可以 将改变后的映射关系通过广播通知 UE。 也就是说, 控制信道的格式发生改变 时, 可以将改变后的控制信道的格式通过广播通知 UE。  In this embodiment, all UEs in the location refer to all UEs in the coverage area of the network side device. Optionally, when the mapping relationship between the first control information and the data channel is changed, the changed mapping relationship may be notified to the UE by broadcasting. That is to say, when the format of the control channel changes, the format of the changed control channel can be notified to the UE by broadcast.
由于窄带系统中控制信道的格式会被压缩, 该控制信道中可包含部分数 据信道的时频资源位置信息, 由此, UE需要提前获知每一控制信道能够调度 的数据信道对应的时频资源范围。  Since the format of the control channel in the narrowband system is compressed, the time-frequency resource location information of the partial data channel may be included in the control channel, and the UE needs to know in advance the time-frequency resource range corresponding to the data channel that can be scheduled by each control channel. .
303、网络侧设备根据所述映射关系和目标 UE的标识为所述目标 UE分配 时频资源位置信息, 并根据所述时频资源位置信息获得所述至少一个数据信 道的第一调度信息,所述第一调度信息使所述目标 UE根据所述时频资源位置 信息进行数据传输。  303. The network side device allocates time-frequency resource location information to the target UE according to the mapping relationship and the identifier of the target UE, and obtains first scheduling information of the at least one data channel according to the time-frequency resource location information. The first scheduling information causes the target UE to perform data transmission according to the time-frequency resource location information.
举例来说, 如图 4A所示, 第一调度信息可包括上行调度信息 (Uplink scheduling information, 简禾尔 UI ) 禾口下行调度信息 (Downlink scheduling information, 简称 DI ) , UI用于调度 UE在 UI指定的上行资源以规定的方 式发送数据, DI用于调度 UE在 DI指定的资源上以规定的方式接收数据。  For example, as shown in FIG. 4A, the first scheduling information may include Uplink Scheduling Information (Downlink Scheduling Information) and Downlink Scheduling Information (DI), and the UI is used to schedule the UE in the UI. The specified uplink resource transmits data in a prescribed manner, and the DI is used to schedule the UE to receive data in a prescribed manner on the resource specified by the DI.
在本实施例中, 时频资源位置可为时频资源对应的虚拟资源的位置; 或 者, 时频资源位置可为时频资源的物理位置; 或者, 时频资源位置可为第一 控制信道中控制时隙对应的能够调度的数据信道的时频资源范围内的相对位 置信息。  In this embodiment, the time-frequency resource location may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or the time-frequency resource location may be in the first control channel. Controlling relative position information within a time-frequency resource range of the scheduleable data channel corresponding to the time slot.
304、 网络侧设备通过所述至少一个数据信道接收至少一个目标 UE发送 的上行数据。 304. The network side device receives, by using the at least one data channel, at least one target UE to send. Upstream data.
305、 网络侧设备通过所述第一控制信道向全部 UE发送所述第一调度信 息和所述上行数据的反馈信息。  305. The network side device sends the first scheduling information and the feedback information of the uplink data to all UEs by using the first control channel.
当网络侧设备调度少量 UE时, 可以在控制信道中携带少量 UE中的部分 UE的上行数据的反馈信息。  When the network side device schedules a small number of UEs, the feedback information of the uplink data of some UEs in a small number of UEs may be carried in the control channel.
在本实施例中, 第一控制信道中的所述第一调度信息和所述反馈信息通 过比特区分。 当然, 第一调度信息与上行数据的反馈信息还可通过其他区分 方式进行区分, 本实施例仅为举例说明。  In this embodiment, the first scheduling information and the feedback information in the first control channel are differentiated by bits. Certainly, the feedback information of the first scheduling information and the uplink data may also be distinguished by other distinguishing manners, and this embodiment is merely an example.
本实施例的资源调度方法使得网络侧设备采用统一的控制策略, 实现半 双工 FDD系统中资源的合理调度, 提高半双工 FDD系统的资源分配效率。  The resource scheduling method in this embodiment enables the network side device to adopt a unified control strategy, implements reasonable scheduling of resources in the half-duplex FDD system, and improves resource allocation efficiency of the half-duplex FDD system.
如图 4B所示, 图 4B中第一控制信道的第一调度信息可包括 UI和 DI; 其中, 图 4B中的 UI-1可调度上行数据信道的 U0和 U1对应的资源, 供 UE-1 和 UE-2使用, 如图 4B中的阴影所示。 图 4B中的 UI-2可调度上行数据信道 的 U2和 U3对应的资源供 UE-3和 UE-4使用。 未被分配的资源可以供竞争使 用。  As shown in FIG. 4B, the first scheduling information of the first control channel in FIG. 4B may include a UI and a DI; wherein UI-1 in FIG. 4B may schedule resources corresponding to U0 and U1 of the uplink data channel, for UE-1. Used with UE-2, as shown by the shading in Figure 4B. The UI-2 in Fig. 4B can schedule resources corresponding to U2 and U3 of the uplink data channel for use by UE-3 and UE-4. Unallocated resources are available for competition.
图 4B中的第一控制信道还可携带上行数据的反馈信息, 由此, 可有效利 用半双工 FDD系统的资源。  The first control channel in Figure 4B can also carry feedback information of the uplink data, thereby effectively utilizing the resources of the half-duplex FDD system.
可选地, 在本实施例中, 第一调度信息与第一控制信道所能调度的数据 信道的时频资源位置信息可为显示指示, 例如, 第一调度信息包括: 目标 UE 的标识, 和第一控制信道能够调度的数据信道的时频资源位置信息。  Optionally, in this embodiment, the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel can be a display indication. For example, the first scheduling information includes: an identifier of the target UE, and The time-frequency resource location information of the data channel that the first control channel can schedule.
图 4C示出了显示指示的示意图, 图 4C中, UI和 DI分别携带目标 UE的 标识, 以及第一控制信道所能调度的数据信道的时频资源位置信息。 在图 4C 中, UI指示的资源是通过 UI中的字段来指示, DI指示的资源也是通过 DI中 的字段来指示。 UI中通过信道指示字段、 资源位置字段、 资源长度指示字段 指定调度的信道编号和资源位置信息。  FIG. 4C shows a schematic diagram of the display indication. In FIG. 4C, the UI and the DI respectively carry the identifier of the target UE and the time-frequency resource location information of the data channel that can be scheduled by the first control channel. In Figure 4C, the resources indicated by the UI are indicated by the fields in the UI, and the resources indicated by the DI are also indicated by the fields in the DI. The channel indication field, the resource location field, and the resource length indication field in the UI specify the scheduled channel number and resource location information.
当然, 第一调度信息与第一控制信道所能调度的数据信道的时频资源位 置信息也可为隐式指示, 此时, 第一调度信息可只包括: 目标 UE的标识。 此 时, 网络侧设备和目标 UE均按照预先约定的方式进行数据传输。例如, 网络 侧设备和 UE 可通过协议规定一张包含调度索引和数据信道的时频资源位置 信息的表格进行数据传输。或者, 网络侧设备预先将全部 UE可进行数据传输 能够使用的数据信道的时频资源位置信息通过广播或寻呼消息通知, 进而目 标 UE在接收到第一调度信息之后,可采用网络侧设备提前通知的时频位置信 息携带相关的数据实现数据传输。 Certainly, the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel may also be an implicit indication. In this case, the first scheduling information may include only: the identifier of the target UE. At this time, the network side device and the target UE perform data transmission in a pre-agreed manner. For example, the network side device and the UE may perform a data transmission by using a table that specifies a time-frequency resource location information of a scheduling index and a data channel by using a protocol. Alternatively, the network side device can transmit data to all UEs in advance. The time-frequency resource location information of the data channel that can be used is notified by a broadcast or paging message, and after receiving the first scheduling information, the target UE may use the time-frequency location information notified by the network-side device to carry relevant data to implement data transmission. .
图 4D示出了隐式指示的示意图, 图 4D中, UI和 DI仅携带的是目标 UE 的标识。 在图 4D中, UI指示的资源通过广播消息下发至全部 UE, 或者 UI指 示的资源是与 UE协议约定的。  Figure 4D shows a schematic diagram of an implicit indication. In Figure 4D, the UI and DI carry only the identity of the target UE. In FIG. 4D, the resources indicated by the UI are delivered to all UEs through broadcast messages, or the resources indicated by the UI are agreed with the UE protocol.
本实施例的资源调度方法中采用上述隐式指示的方式, 可以节省控制信 道的开销, 进而可以调度更多的目标 UE。 在资源调度方法中采用上述显示指 示的方式, 可以较好的调度空闲资源。 由此, 可使得半双工 FDD系统中资源 调度方式更加灵活。  The resource scheduling method in this embodiment adopts the foregoing implicit indication manner, which can save the overhead of the control channel, and thus can schedule more target UEs. In the resource scheduling method, the above display indication manner is adopted, and the idle resources can be better scheduled. As a result, the resource scheduling method in the half-duplex FDD system can be made more flexible.
在具体的应用过程中, 第一调度信息与第一控制信道所能调度的数据信 道的时频资源位置信息可以是显示指示进行调度 (下述简称显示调度) , 也 可以是隐式指示进行调度(下述简称隐式调度) , 如图 4E所示。 在图 4E中。 帧 0、 帧 1、 帧 4、 帧 6 (帧号, 简称帧) 用于上行调度, 其中帧 0、 帧 1、 帧 6采用隐式调度的形式 (假设调度两个 UE ) , 帧 4采用显示调度的形式 (假 设调度单个 UE) ; 帧 2、 帧 3、 帧 5、 帧 7、 帧 8用于下行调度; 其中, 帧 2、 帧 3、 帧 8采用显示调度的形式 (假设调度两个 UE) , 帧 5、 帧 7采用显示 调度的形式 (假设调度单个 UE) 。  In a specific application process, the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel may be a display indication for scheduling (hereinafter referred to as display scheduling), or may be an implicit indication for scheduling. (hereinafter referred to as implicit scheduling), as shown in Figure 4E. In Figure 4E. Frame 0, frame 1, frame 4, and frame 6 (frame number, abbreviated as frame) are used for uplink scheduling, where frame 0, frame 1, and frame 6 are in the form of implicit scheduling (assuming two UEs are scheduled), and frame 4 is displayed. The form of scheduling (assuming a single UE is scheduled); Frame 2, Frame 3, Frame 5, Frame 7, and Frame 8 are used for downlink scheduling; where Frame 2, Frame 3, and Frame 8 are in the form of display scheduling (assuming two UEs are scheduled) ), frame 5, frame 7 takes the form of display scheduling (assuming a single UE is scheduled).
例如, 帧 0的 UI隐式调度上行数据信道 U0和 U1 , 将帧号 1到帧号 6的 上行数据信道资源分别分配给了 UE-1和 UE-2 , 但是由于 UE-2的上行数据较 少, 在帧 3时便发送完毕。此时帧 4的 UI可以通过显示调度的方法将上行数 据信道 U1的帧 5和 6的资源动态分配给新的 UE-3。  For example, the UI of the frame 0 implicitly schedules the uplink data channels U0 and U1, and allocates the uplink data channel resources of the frame number 1 to the frame number 6 to the UE-1 and the UE-2, respectively, but the uplink data of the UE-2 is compared. Less, it is sent at frame 3. At this time, the UI of the frame 4 can dynamically allocate the resources of the frames 5 and 6 of the uplink data channel U1 to the new UE-3 by the display scheduling method.
同理, 对与下行数据信道, 帧 2的 DI隐式调度下行数据信道 DO和 D1 , 将帧 3到帧 5的资源分别分配给 UE-4和 UE-5, 帧 3的 DI隐式调度下行数据 信道 DO和 D1 , 将帧 6到帧 8的资源分别分配给 UE_5和 UE_6, 由于采用隐式 调度, 此时虽然仅有帧 6中携带了 UE-5的下行数据, 但是 UE-5在会在帧 7 也在信道 DO继续接收下行数据,发现数据中携带的 UE的标识不是自己的标识 时,停止接收,对于网络侧设备如基站来说,它可以通过帧 5的 DI显示调度, 将信道 DO的帧 7和帧 8的数据分配一个新的 UE。  Similarly, for the downlink data channel, the DI of the frame 2 implicitly schedules the downlink data channels DO and D1, the resources of the frame 3 to the frame 5 are respectively allocated to the UE-4 and the UE-5, and the DI of the frame 3 is implicitly scheduled to be downlink. The data channels DO and D1 are allocated to the UE_5 and the UE_6 respectively. Due to the implicit scheduling, only the frame 6 carries the downlink data of the UE-5, but the UE-5 is in the conference. In frame 7, the downlink data is also received on the channel DO, and when the identifier of the UE carried in the data is not the identity of the UE, the reception is stopped. For the network side device, such as the base station, it can perform the scheduling through the DI display of the frame 5, and the channel is The data of frame 7 and frame 8 of the DO is assigned a new UE.
当然, 显示调度的资源上还可以携带上行数据的下行反馈信息。 例如, UE-1的上行数据的反馈信息可以在帧 7,通过显示调度的 DI-3信息的内容携 带。 Certainly, the downlink resource information of the uplink data may also be carried on the resource that is displayed in the scheduling. E.g, The feedback information of the uplink data of UE-1 may be carried in frame 7 by displaying the content of the scheduled DI-3 information.
在本实施例中, 控制信道的格式可与控制信道中的帧号进行绑定 (不同 帧号可对应不同的格式) , 通过广播通知 UE控制信道的格式, 以使 UE能够 获知隐式指示的调度信息与时频资源位置信息的映射关系。  In this embodiment, the format of the control channel may be bound to the frame number in the control channel (the different frame numbers may correspond to different formats), and the format of the control channel of the UE is notified by broadcast, so that the UE can learn the implicit indication. The mapping relationship between scheduling information and time-frequency resource location information.
应说明的是, 本实施例中, UI包括下述信息的一种或多种: 控制信息和 数据信息的区分标识、 UI标识、 目标 UE的标识、 信道指示信息、 资源位置 信息、 资源长度指示信息、 调制与编码策略 (Modulation and Coding Scheme, 简称 MCS)、 帧号、 重复次数、 信道空闲状态指示信息、 碰撞后的退避时间、 碰撞后的退避概率等;  It should be noted that, in this embodiment, the UI includes one or more of the following information: a differentiated identifier of the control information and the data information, a UI identifier, an identifier of the target UE, channel indication information, resource location information, and a resource length indication. Information, Modulation and Coding Scheme (MCS), frame number, number of repetitions, channel idle state indication information, backoff time after collision, backoff probability after collision, etc.
DI包括下述信息的一种或多种: 控制信息和数据信息的区分标识、 DI标 识、 目标 UE的标识、信道指示信息、资源位置信息、资源长度指示信息、 MCS、 帧号、 重复次数、 信道空闲状态指示信息、 碰撞后的退避时间、 碰撞后的退 避概率等。  The DI includes one or more of the following information: a differentiated identifier of the control information and the data information, a DI identifier, an identifier of the target UE, channel indication information, resource location information, resource length indication information, MCS, frame number, number of repetitions, Channel idle state indication information, backoff time after collision, backoff probability after collision, and the like.
其中, 目标 UE的标识用于区分目标 UE; 信道指示信息用于指示调度的 是哪个信道; 资源位置信息用于指示资源的起始位置; 资源长度指示信息用 于指示调度的资源长度; MCS 用于指示码率; 重复次数用于指示数据需要重 复发送次数; 信道空闲状态指示信息用于指示信道的空闲情况; 碰撞后的退 避时间用于指示 UE如果发生碰撞, 需要退避多长时间后重新参与竞争; 碰撞 后的退避概率用于指示 UE如果发生碰撞应该以多大概率进行退避。  The identifier of the target UE is used to distinguish the target UE; the channel indication information is used to indicate which channel is scheduled; the resource location information is used to indicate the starting location of the resource; the resource length indication information is used to indicate the length of the scheduled resource; The number of repetitions is used to indicate the number of times the data needs to be repeatedly transmitted; the channel idle state indication information is used to indicate the idle condition of the channel; the backoff time after the collision is used to indicate how long the UE needs to retreat and then re-engage if a collision occurs. Competition; The backoff probability after collision is used to indicate how much the UE should back off if there is a collision.
上述任一控制信道可以通过 UI和 DI按照不同的时隙配比进行组合。 其 中, 网络侧设备可以将 UI和 DI的顺序、 比例、 区分方式等通过广播 /寻呼消 息通知 UE。  Any of the above control channels can be combined by UI and DI according to different time slot ratios. The network side device may notify the UE of the order, the proportion, the distinguishing manner, and the like of the UI and the DI through the broadcast/paging message.
可选地, 由于当前窄带系统的控制信道承载的信息容量十分受限。 进而 在所述第一调度信息中目标 UE的标识为一个时,前述的步骤 305可具体为下 述的图中未示出的步骤 305' :  Optionally, the information capacity carried by the control channel of the current narrowband system is very limited. Further, when the identifier of the target UE is one in the first scheduling information, the foregoing step 305 may be specifically the step 305' not shown in the following figure:
305' 、 网络侧设备将所述目标 UE的标识的全部字段或部分资源与所述 第一控制信道中的循环冗余校验码 (Cyclical Redundancy Check, 简称 CRC) 进行异或运算;  305 ′, the network side device performs an exclusive-OR operation on all the fields or partial resources of the identifier of the target UE and a Cyclical Redundancy Check (CRC) in the first control channel;
网络侧设备将所述反馈信息和异或运算之后的信息发送至所述全部 UE。 也就是说, 当每个 UI或者 DI仅调度一个 UE时, 可以将 UE标识或者 UE 标识的一部分比特(bit )和 CRC校验码进行异或后可显示指示, 进一步节省 控制信令开销。 The network side device transmits the feedback information and the information after the XOR operation to the all UEs. That is to say, when each UI or DI only schedules one UE, the UE identifier or a part of the bit (bit) of the UE identifier and the CRC check code may be XORed to display an indication, thereby further saving control signaling overhead.
上述方式可很好的压缩第一控制信道中的控制信息即第一调度信息, 使 得第一调度信息中不用再标识完整的时频资源位置信息了, 进而可较好的降 低通信的延迟。  The foregoing method can well compress the control information in the first control channel, that is, the first scheduling information, so that the complete time-frequency resource location information is not used in the first scheduling information, and the communication delay can be better reduced.
在一种可选的应用场景中, 若半双工 FDD系统中, 数据信道的数量小于 预设的第一阈值, 且控制信道的数量大于预设的第二阈值时, 此时可将多余 的控制信道复用为数据信道进行使用。  In an optional application scenario, if the number of data channels in the half-duplex FDD system is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the redundant Control channel multiplexing is used for data channels.
例如, 资源调度方法可包括下述图中未示出的步骤 A01至步骤 A02。  For example, the resource scheduling method may include steps A01 to A02 which are not shown in the following figures.
A01、 网络侧设备确定第二控制信道的第二调度信息, 第二调度信息用于 为目标 UE分配第二控制信道中的时频资源位置信息。  A01. The network side device determines second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE.
可理解的是, 在第二控制信道作为数据信道使用时, 可不再为第二控制 信道分配控制信道, 直接将第二控制信道实现数据信道的功能同时实现控制 信道的功能。  It can be understood that when the second control channel is used as the data channel, the control channel can be no longer allocated for the second control channel, and the second control channel can directly implement the function of the data channel and realize the function of the control channel.
该步骤中的时频资源位置信息可指示的是第二控制信道中的时频资源位 置信息。  The time-frequency resource location information in this step may indicate time-frequency resource location information in the second control channel.
A02、 网络侧设备通过第二控制信道向全部 UE发送第二调度信息。  A02. The network side device sends the second scheduling information to all UEs by using the second control channel.
当然,若网络侧设备同时通过至少一个数据信道接收至少一个目标 UE发 送的上行数据。  Of course, if the network side device simultaneously receives uplink data sent by at least one target UE through at least one data channel.
则 A02中,网络侧设备还可通过第二控制信道向全部 UE发送第二调度信 息和反馈信息。  In A02, the network side device may also send second scheduling information and feedback information to all UEs through the second control channel.
可理解的是, 在总信道数目不足的情况下, 上述控制信道也可用于业务 数据的发送, 进而可有效提升资源利用率。  It can be understood that, in the case that the total number of channels is insufficient, the foregoing control channel can also be used for sending service data, thereby effectively improving resource utilization.
在具体应用中, 当下行数据信道受限, 而控制信道资源充足时, 还可以 将控制信道复用为下行数据信道, 通过特定的 bit (比特) 区分控制信息和 数据。 可选地, UI和 DI也可以合并为 XI, 如图 4F所示。 C/D字段用于区分 是控制信息还是数据。 UI/DI 字段用于区分是上行调度信息还是下行调度信 息。 Res、 ACK字段用于区分是调度信息还是上行数据的反馈信息。 应理解的 是, 此时 XI中可携带上行数据的反馈信息。 UE在接收上述第二控制信道的第二调度信息之后, 先解析 C/D字段得到 本帧是控制信息还是数据, 如果是控制信息, 再通过解析 UI/DI字段得到本 帧是上行调度信息还是下行调度信息。 In a specific application, when the downlink data channel is limited and the control channel resources are sufficient, the control channel can also be multiplexed into a downlink data channel, and the control information and data are distinguished by specific bits (bits). Alternatively, the UI and DI can also be combined into XI, as shown in Figure 4F. The C/D field is used to distinguish between control information and data. The UI/DI field is used to distinguish whether it is uplink scheduling information or downlink scheduling information. The Res and ACK fields are used to distinguish whether it is scheduling information or feedback information of uplink data. It should be understood that the feedback information of the uplink data may be carried in the XI at this time. After receiving the second scheduling information of the second control channel, the UE first parses the C/D field to obtain whether the current frame is control information or data. If it is control information, and then parses the UI/DI field to obtain whether the current frame is uplink scheduling information. Downstream scheduling information.
本实施例的资源调度方法可以通过灵活调整控制信息的结构来匹配不同 信道数目比例和信道带宽, 在不同负荷情况下, 无论控制信道受限, 还是数 据信道受限的情况下, 通过灵活调节控制信道的使用, 保证了系统容量的最 大化, 提升信道利用率。  The resource scheduling method in this embodiment can flexibly adjust the structure of the control information to match different channel number proportions and channel bandwidths, and under different load conditions, whether the control channel is limited or the data channel is limited, the flexible adjustment control is adopted. The use of channels ensures maximum system capacity and improves channel utilization.
在具体的应用过程中, 将第二控制信道复用为数据信道可具体如下的图 中未示出的步骤 Al l至步骤 A12:  In a specific application process, the second control channel is multiplexed into a data channel, which may be specifically as follows, steps A1 to A12:
Al l、 网络侧设备通过至少一个数据信道接收至少一个目标 UE发送的上 行数据。  Al l, the network side device receives the uplink data sent by the at least one target UE through the at least one data channel.
A12、 网络侧设备通过第二控制信道向所述目标 UE发送所述上行数据的 反馈信息。  A12. The network side device sends the feedback information of the uplink data to the target UE by using a second control channel.
针对窄带系统, 本实施例的资源调度方法, 通过 UI/DI隐式指示和显示 指示相互结合, 解决了控制信道比特 (bit )数受限的问题, 同时又保持了调 度的灵活性。  For the narrowband system, the resource scheduling method of the present embodiment solves the problem that the number of bits of the control channel is limited by the combination of the UI/DI implicit indication and the display indication, and at the same time maintains the flexibility of scheduling.
图 5示出了本发明一实施例提供的资源调度方法的流程示意图, 如图 5 所示, 本实施例的资源调度方法包括如下内容。  FIG. 5 is a schematic flowchart of a resource scheduling method according to an embodiment of the present invention. As shown in FIG. 5, the resource scheduling method in this embodiment includes the following content.
501、 网络侧设备为至少一个数据信道分配第一控制信道, 建立所述第一 控制信道和所述数据信道的映射关系, 并将所述映射关系通知全部 UE;  501, the network side device allocates a first control channel to the at least one data channel, establishes a mapping relationship between the first control channel and the data channel, and notifies all the UEs of the mapping relationship;
502、网络侧设备根据所述映射关系和目标 UE的标识为所述目标 UE分配 时频资源位置信息, 并根据所述时频资源位置信息获得所述至少一个数据信 道的第一调度信息,所述第一调度信息使所述目标 UE根据所述时频资源位置 信息进行数据传输;  502. The network side device allocates time-frequency resource location information to the target UE according to the mapping relationship and the identifier of the target UE, and obtains first scheduling information of the at least one data channel according to the time-frequency resource location information. The first scheduling information is used to enable the target UE to perform data transmission according to the time-frequency resource location information;
503、 网络侧设备确定所述第一调度信息中 UI和 DI的配比, 以及 UI和 503. The network side device determines a ratio of UI and DI in the first scheduling information, and UI and
DI在所述第一控制信道中的位置信息。 DI location information in the first control channel.
举例来说, 在本步骤中, UI和 DI采用同一第一控制信道向所述 UE发送 时, 网络侧设备可采用不同的时隙配比区分 UI和 DI。  For example, in this step, when the UI and the DI are sent to the UE by using the same first control channel, the network side device may distinguish between the UI and the DI by using different time slot ratios.
可选地, 在本步骤中, UI和 DI可采用同一第一控制信道向 UE发送时, UI在第一控制信道的控制时隙中携带的上行指示不同于, DI在第一控制信道 的控制时隙中携带的下行指示。 Optionally, in this step, when the UI and the DI are sent to the UE by using the same first control channel, the uplink indication carried by the UI in the control slot of the first control channel is different, and the DI is in the first control channel. The downstream indication carried in the control slot.
504、 网络侧设备通过所述至少一个数据信道接收至少一个目标 UE发送 的上行数据;  504. The network side device receives the uplink data sent by the at least one target UE by using the at least one data channel.
505、 网络侧设备通过所述第一控制信道向所述全部 UE发送所述第一调 度信息和所述上行数据的反馈信息。  505. The network side device sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel.
当然, 第一调度信息可全部为 UI , 或者, 第一调度信息可全部为 DI。 或 者, 第一调度信息的 UI和 DI和采用不同的第一控制信道向 UE发送。  Of course, the first scheduling information may all be a UI, or the first scheduling information may all be a DI. Alternatively, the UI and DI of the first scheduling information are sent to the UE using different first control channels.
上述方法使得网络侧设备采用统一的控制策略, 实现半双工 FDD系统中 资源的合理调度, 提高半双工 FDD系统的资源分配效率。  The above method enables the network side device to adopt a unified control strategy to implement reasonable scheduling of resources in the half-duplex FDD system, and improve the resource allocation efficiency of the half-duplex FDD system.
可选地, 前述图 5所示的资源调度方法还可包括如下的图中未示出的步 骤 505a:  Optionally, the foregoing resource scheduling method shown in FIG. 5 may further include a step 505a not shown in the following figure:
505a, 网络侧设备将所述第一调度信息中所述 UI和所述 DI的配比发送 至所述 UE; 和 /或,  505a, the network side device sends the ratio of the UI and the DI in the first scheduling information to the UE; and/or,
网络侧设备将所述第一调度信息中所述 UI和所述 DI的区分方式发送至 所述 UE; 和 /或,  The network side device sends the UI and the DI in the first scheduling information to the UE; and/or,
网络侧设备将所述 UI所能调度的最大上行时频资源数量发送至所述 UE; 和 /或,  The network side device sends the maximum uplink time-frequency resource quantity that the UI can schedule to the UE; and/or,
网络侧设备将所述 DI所能调度的最大下行时频资源数量发送至所述 UE。 该处的步骤 505a可位于前述的步骤 505之前, 也可位于前述的步骤 505 之后, 本实施例不对其进行限定。  The network side device sends the maximum downlink time-frequency resource quantity that the DI can schedule to the UE. The step 505a may be located before the foregoing step 505, or may be located after the foregoing step 505, which is not limited in this embodiment.
上述步骤 505a可以是网络侧设备通过系统广播的方式实现。  The foregoing step 505a may be implemented by the network side device by means of system broadcast.
在本实施例中, 不同覆盖等级的数据信道对应的控制信道可不同。 也就 是说,第一控制信道建立映射关系的至少一个数据信道的覆盖等级是相同的。  In this embodiment, the control channels corresponding to the data channels of different coverage levels may be different. That is to say, the coverage level of at least one data channel in which the first control channel establishes a mapping relationship is the same.
此外, UE可根据自己的信道情况选择不同的控制信道驻留。 为了考虑到 满足各个覆盖等级 UE数量的比例灵活的需求,可能保留少数几个上行数据信 道, 不设置特定的重复次数, 网络侧设备如基站针对不区分重复次数的信道 进行调度时, 必须使用显示调度的 UI/DI。 在单帧的控制信息比特数受限, 但是总的控制信道容量不受限的情况下, 物理上行指示信道 (Physical upl ink indication channel , 简称 PUICH) 和物理下行指示信道 (Physical downlink indication channel , 简称 PDICH) 可以考虑仅调度单个 UE, 增加 灵活性。 In addition, the UE can select different control channel camps according to its own channel conditions. In order to take into account the flexible requirements of the number of UEs in each coverage level, a few uplink data channels may be reserved, and a specific number of repetitions may not be set. When a network side device, such as a base station, schedules a channel that does not distinguish the number of repetitions, it must use a display. Scheduled UI/DI. The physical uplink indication channel (PUICH) and the physical downlink indication channel (Physical downlink indication channel PDICH) can consider scheduling only a single UE, increase Flexibility.
图 6示出了本发明一实施例提供的数据传输方法的流程示意图, 如图 6 所示, 本实施例的数据传输方法包括如下内容。  FIG. 6 is a schematic flowchart diagram of a data transmission method according to an embodiment of the present invention. As shown in FIG. 6, the data transmission method in this embodiment includes the following content.
601、 所有 UE监听网络侧设备发送的映射关系, 所述映射关系为第一控 制信道和至少一个数据信道的映射关系;  601. The mapping relationship between the first control channel and the at least one data channel is the mapping relationship between the first control channel and the at least one data channel.
602、所有 UE中的目标 UE通过所述至少一个数据信道向所述网络侧设备 发送上行数据;  602. The target UE in all UEs sends uplink data to the network side device by using the at least one data channel.
603、 所有 UE接收所述网络侧设备通过所述第一控制信道发送的第一调 度信息和所述上行数据的反馈信息, 所述第一调度信息为所述网络侧设备根 据所述映射关系和所述目标 UE的标识获得的;  603. The UE receives the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and Obtained by the identifier of the target UE;
604、 目标 UE根据所述第一调度信息进行数据传输, 并处理所述上行数 据的反馈信息。  604. The target UE performs data transmission according to the first scheduling information, and processes feedback information of the uplink data.
举例来说, 第一调度信息可包括: 目标 UE的标识。 此时, 第一调度信息 与第一控制信道能够调度的数据信道的时频资源位置信息可为隐式指示。  For example, the first scheduling information may include: an identifier of the target UE. At this time, the first scheduling information and the time-frequency resource location information of the data channel that the first control channel can schedule may be an implicit indication.
或者, 第一调度信息可包括: 目标 UE的标识, 和所述第一控制信道能够 调度的数据信道的时频资源位置信息。 此时, 第一调度信息与第一控制信道 能够调度的数据信道的时频资源位置信息可为显示指示。  Alternatively, the first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule. At this time, the first scheduling information and the time-frequency resource location information of the data channel that the first control channel can schedule may be a display indication.
可选地, 第一调度信息可包括 UI和 /或 DI。 至少一个数据信道可包括上 行数据信道和下行数据信道。  Optionally, the first scheduling information may include a UI and/or a DI. The at least one data channel can include an uplink data channel and a downlink data channel.
在一种具体的应用场景中, 在前述的步骤 604之前, 图 6所示的方法还 可包括图中未示出的步骤 603a:  In a specific application scenario, before the foregoing step 604, the method shown in FIG. 6 may further include a step 603a not shown in the figure:
603a, 所有 UE接收所述网络侧设备发送的所述第一调度信息中所述 UI 和所述 DI的配比, 和 /或,  603a, all UEs receive a ratio of the UI and the DI in the first scheduling information sent by the network side device, and/or,
所有 UE接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区分方法, 和 /或,  All UEs receive a method for distinguishing the UI and the DI in the first scheduling information sent by the network side device, and/or,
所有 UE接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资 源数量, 和 /或,  All UEs receive the maximum number of uplink time-frequency resources that can be scheduled by the UI sent by the network side device, and/or,
所有 UE接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资 源数量。  All UEs receive the maximum number of downlink time-frequency resources that can be scheduled by the DI sent by the network side device.
举例来说, 网络侧设备进而通过系统广播或者寻呼消息向所有 UE 发送 UI和 DI的配比、 UI和 DI的区分方式、 UI所能调度的最大上行时频资源数 量、 DI所能调度的最大下行时频资源数量等等。 For example, the network side device sends the message to all UEs through system broadcast or paging message. The ratio of UI and DI, the way of distinguishing between UI and DI, the maximum number of uplink time-frequency resources that the UI can schedule, the maximum number of downlink time-frequency resources that DI can schedule, and so on.
可选地, 若第一调度信息与第一控制信道能够调度的数据信道的时频资 源位置信息为隐式指示时, 上述数据传输方法的步骤 604之前, 还包括下述 的图中未示出的步骤 604a:  Optionally, if the first scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel are implicitly indicated, before the step 604 of the data transmission method, the method further includes: Step 604a:
604a: 所有 UE接收所述网络侧设备发送的时频资源位置信息, 所述时频 资源位置信息为所述第一控制信道能够调度的数据信道的时频资源位置信 息。  604a: All UEs receive time-frequency resource location information sent by the network side device, where the time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
本实施例中的时频资源位置可为所述时频资源对应的虚拟资源的位置; 或者, 时频资源位置可为所述时频资源的物理位置; 或者, 时频资源位置为 所述第一控制信道中控制时隙对应的能够调度的数据信道的时频资源范围内 的相对位置信息。  The time-frequency resource location in the embodiment may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or the time-frequency resource location is the first The relative position information in the time-frequency resource range of the scheduleable data channel corresponding to the control slot in a control channel.
可选地, 在所述数据信道的数量小于预设第一阈值, 且控制信道的数量 大于预设的第二阈值时, 本实施例可将控制信道复用为数据信道。 例如, 上 述方法还包括图中未示出的步骤 B01和 B02:  Optionally, when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the embodiment may multiplex the control channels into data channels. For example, the above method also includes steps B01 and B02 which are not shown in the figure:
B01、 所有 UE接收所述网络侧设备通过所述第二控制信道发送的第二调 度信息和 /或所述反馈信息;  B01. All UEs receive second scheduling information and/or the feedback information sent by the network side device by using the second control channel.
B02、 目标 UE根据所述第二调度信息进行数据传输, 和 /或处于所述反馈 信息。  B02. The target UE performs data transmission according to the second scheduling information, and/or is in the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。  The second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
由上述实施例可知, 本实施例的数据传输方法, 实现半双工 FDD系统中 资源的合理调度, 提高半双工 FDD系统的资源分配效率。  It can be seen from the above embodiment that the data transmission method of the embodiment implements reasonable scheduling of resources in the half-duplex FDD system and improves the resource allocation efficiency of the half-duplex FDD system.
图 7示出了本发明一实施例提供的通信设备的结构示意图,如图 7所示, 本实施例的通信设备包括: 处理器 71、 存储器 72、 总线 73和通信接口 74, 该处理器 71和存储器 72之间可通过总线 73连接, 其中, 该存储器 72用 于存储指令, 该处理器 71执行存储器 72中存储的指令, 进行如下处理: 为至少一个数据信道分配第一控制信道, 建立所述第一控制信道和所述 数据信道的映射关系, 并将所述映射关系通知全部用户设备 UE;  FIG. 7 is a schematic structural diagram of a communication device according to an embodiment of the present invention. As shown in FIG. 7, the communication device of this embodiment includes: a processor 71, a memory 72, a bus 73, and a communication interface 74. The processor 71 And the memory 72 can be connected by a bus 73, wherein the memory 72 is used for storing instructions, and the processor 71 executes the instructions stored in the memory 72, and performs the following processing: assigning a first control channel to at least one data channel, establishing a Determining a mapping relationship between the first control channel and the data channel, and notifying the user equipment UE of the mapping relationship;
根据所述映射关系和目标 UE的标识为所述目标 UE分配时频资源位置信 息, 并根据所述时频资源位置信息获得所述至少一个数据信道的第一调度信 息,所述第一调度信息使所述目标 UE根据所述时频资源位置信息进行数据传 输; Allocating a time-frequency resource location letter to the target UE according to the mapping relationship and the identifier of the target UE Obtaining, according to the time-frequency resource location information, first scheduling information of the at least one data channel, where the first scheduling information enables the target UE to perform data transmission according to the time-frequency resource location information;
通过所述至少一个数据信道接收至少一个目标 UE发送的上行数据; 通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上 行数据的反馈信息。  Receiving uplink data sent by the at least one target UE by using the at least one data channel; and transmitting, by using the first control channel, the first scheduling information and the feedback information of the uplink data to the all UEs.
举例来说, 前述的第一调度信息可包括: 目标 UE的标识。 此时, 调度信 息和第一控制信道能够调度的数据信道的时频资源位置信息为隐式调度方 式。  For example, the foregoing first scheduling information may include: an identifier of the target UE. At this time, the scheduling information and the time-frequency resource location information of the data channel that the first control channel can schedule are implicit scheduling modes.
前述的第一调度信息可包括: 目标 UE的标识, 和第一控制信道能够调度 的数据信道的时频资源位置信息。 此时, , 调度信息和第一控制信道能够调 度的数据信道的时频资源位置信息为显示调度方式。  The foregoing first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule. At this time, the scheduling information and the time-frequency resource location information of the data channel that can be scheduled by the first control channel are display scheduling modes.
可选地, 所述处理器 81通过所述第一控制信道向所述全部 UE发送所述 第一调度信息和所述上行数据的反馈信息之后, 还用于  Optionally, after the processor 81 sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel,
将第一控制信道能够调度的数据信道的时频资源位置信息通知所述全部 在一种可选的实现方式中,在所述第一调度信息中目标 UE的标识为一个 时, 所述处理器 81通过所述第一控制信道向所述全部 UE发送所述第一调度 信息和所述上行数据的反馈信息; 包括:  And notifying, in an optional implementation manner, the time-frequency resource location information of the data channel that can be scheduled by the first control channel, where the identifier of the target UE is one in the first scheduling information, the processor The sending, by the first control channel, the first scheduling information and the feedback information of the uplink data to the all UEs by using the first control channel;
所述处理器 81将所述目标 UE的标识的全部字段或部分资源与所述第一 控制信道中的 CRC进行异或运算;  The processor 81 performs an exclusive-OR operation on all the fields or partial resources of the identifier of the target UE and the CRC in the first control channel;
将所述反馈信息和异或运算之后的信息发送至所述全部 UE。  The feedback information and the information after the exclusive OR operation are transmitted to the all UEs.
在另一种可选的实现方式中,在所述数据信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值时, 所述处理器还用于:  In another optional implementation manner, when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the processor is further configured to:
确定第二控制信道的第二调度信息,所述第二调度信息用于为目标 UE分 配所述第二控制信道中的时频资源位置信息;  Determining second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
通过所述第二控制信道向所述全部 UE发送所述第二调度信息和 /或所述 反馈信息。  And transmitting, by the second control channel, the second scheduling information and/or the feedback information to all UEs.
举例来说, 前述的时频资源位置可为时频资源对应的虚拟资源的位置; 或者, 时频资源位置可为所述时频资源的物理位置; 或者, 时频资源位置可 为所述第一控制信道中控制时隙对应的能够调度的数据信道的时频资源范围 内的相对位置信息。 For example, the time-frequency resource location may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or, the time-frequency resource location may be Corresponding position information in a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
在第三种可选的实现方式中,所述处理器 81通过所述第一控制信道向所 述全部 UE发送所述第一调度信息和所述上行数据的反馈信息之前, 还用于 确定所述第一调度信息中 UI和 DI的配比, 以及所述 UI和所述 DI在所 述第一控制信道中的位置信息。  In a third optional implementation manner, the processor 81 is further configured to determine, before sending, by using the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs. a ratio of UI and DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
应说明的是, UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI 和所述 DI采用不同的时隙配比区分; 或者,  It should be noted that, when the UI and the DI are sent to the UE by using the same control channel, the UI and the DI are differentiated by using different time slots; or
UI和 DI采用不同的控制信道向 UE发送; 或者,  The UI and DI are sent to the UE using different control channels; or,
UI和 DI采用同一控制信道向 UE发送时, 所述 UI在控制信道的控制时 隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中携带的下行指 在第四种可选的实现方式中,所述处理器 81通过所述第一控制信道向所 述全部 UE发送所述第一调度信息和所述上行数据的反馈信息之前 /之后, 还 用于:  When the UI and the DI are sent to the UE by using the same control channel, the uplink indication carried by the UI in the control slot of the control channel is different from that of the downlink finger carried by the DI in the control slot of the control channel. In the selected implementation manner, before the processor 81 sends the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel, the processor 81 is further configured to:
将所述第一调度信息中所述 UI和所述 DI的配比发送至所述全部 UE; 和 Transmitting a ratio of the UI and the DI in the first scheduling information to the all UEs; and
/或, / or,
将所述第一调度信息中所述 UI和所述 DI的区分方式发送至所述全部 UE; 和 /或,  Transmitting, by the first scheduling information, the manner in which the UI and the DI are differentiated to all UEs; and/or,
将所述 UI所能调度的最大上行时频资源数量发送至所述全部 UE;和 /或, 将所述 DI所能调度的最大下行时频资源数量发送至所述全部 UE。  And sending, to the all UEs, the maximum number of uplink time-frequency resources that can be scheduled by the UI; and/or sending the maximum downlink time-frequency resource that can be scheduled by the DI to all the UEs.
上述通信设备中的处理器为至少一个数据信道分配包括第一控制信道, 并建立第一控制信道与数据信道的映射关系, 进而根据映射关系获得第一调 度信息,网络侧设备在接收目标 UE发送的上行数据之后将第一调度信息和上 行数据的反馈信息发送 UE, 可使得网络侧设备采用统一的控制策略, 实现半 双工 FDD系统中资源的合理调度, 提高半双工 FDD系统的资源分配效率。  The processor in the communication device allocates a first control channel for the at least one data channel, and establishes a mapping relationship between the first control channel and the data channel, and then obtains first scheduling information according to the mapping relationship, where the network side device sends the target UE. After the uplink data, the first scheduling information and the feedback information of the uplink data are sent to the UE, so that the network side device adopts a unified control strategy to implement reasonable scheduling of resources in the half-duplex FDD system, and improve resource allocation of the half-duplex FDD system. effectiveness.
图 8示出了本发明一实施例提供的用户设备的结构示意图,如图 8所示, 本实施例的用户设备包括: 处理器 81、 存储器 82、 总线 83和通信接口 84, 该处理器 81和存储器 82之间可通过总线 83连接, 其中, 该存储器 82用 于存储指令, 该处理器 81执行存储器 82中存储的指令, 进行如下处理: 监听网络侧设备发送的映射关系, 所述映射关系为第一控制信道和至少 一个数据信道的映射关系; FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention. As shown in FIG. 8, the user equipment in this embodiment includes: a processor 81, a memory 82, a bus 83, and a communication interface 84. The processor 81 The memory 82 can be connected to the memory 82, wherein the memory 82 is used to store instructions, and the processor 81 executes the instructions stored in the memory 82 to perform the following processing: The mapping relationship sent by the network side device is monitored, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel;
在所述用户设备 UE为目标 UE时, 通过所述至少一个数据信道向所述网 络侧设备发送上行数据,  When the user equipment UE is the target UE, sending uplink data to the network side device by using the at least one data channel,
接收所述网络侧设备通过所述第一控制信道发送的第一调度信息和所述 上行数据的反馈信息, 所述第一调度信息为所述网络侧设备根据所述映射关 系和所述目标 UE的标识获得的;  And receiving the first scheduling information that is sent by the network side device by using the first control channel, and the feedback information of the uplink data, where the first scheduling information is that the network side device according to the mapping relationship and the target UE Obtained by the logo;
根据所述第一调度信息进行数据传输,并处理所述上行数据的反馈信息。 可选地, 第一调度信息可包括: 目标 UE的标识。 或者, 第一调度信息可 包括: 目标 UE的标识, 和所述第一控制信道能够调度的数据信道的时频资源 位置信息。  Performing data transmission according to the first scheduling information, and processing feedback information of the uplink data. Optionally, the first scheduling information may include: an identifier of the target UE. Alternatively, the first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
在一种可选的实现方式中,所述处理器 81根据所述第一调度信息进行数 据传输之前, 还用于  In an optional implementation manner, before the processor 81 performs data transmission according to the first scheduling information,
接收所述网络侧设备发送的时频资源位置信息, 所述时频资源位置信息 为所述第一控制信道能够调度的数据信道的时频资源位置信息。  Receiving time-frequency resource location information sent by the network side device, where the time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
在第二种可选的实现方式中,在所述数据信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值时, 所述处理器 81还用于  In a second optional implementation manner, when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the processor 81 is further configured to:
接收所述网络侧设备通过所述第二控制信道发送的第二调度信息和 /或 所述反馈信息;  Receiving second scheduling information and/or the feedback information that is sent by the network side device by using the second control channel;
根据所述第二调度信息进行数据传输, 和 /或处理所述反馈信息。  Data transmission is performed according to the second scheduling information, and/or the feedback information is processed.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。  The second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
举例来说, 时频资源位置可为所述时频资源对应的虚拟资源的位置; 或 者, 时频资源位置可为所述时频资源的物理位置; 或者, 时频资源位置可为 所述第一控制信道中控制时隙对应的能够调度的数据信道的时频资源范围内 的相对位置信息。  For example, the time-frequency resource location may be the location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be the physical location of the time-frequency resource; or the time-frequency resource location may be the The relative position information in the time-frequency resource range of the scheduleable data channel corresponding to the control slot in a control channel.
在第三种可选的实现方式中,所述处理器 81根据所述第一调度信息进行 数据传输之前, 还用于  In a third optional implementation manner, before the processor 81 performs data transmission according to the first scheduling information,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的配 比, 和 /或, 接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区 分方法, 和 /或, Receiving, by the network side device, the ratio of the UI and the DI in the first scheduling information, and/or, Receiving, by the network side device, the UI and the DI distinguishing method in the first scheduling information, and/or,
接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资源数量, 和 /或,  Receiving, by the network side device, the maximum uplink time-frequency resource that can be scheduled by the UI, and/or,
接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资源数量。 上述用户设备与网络侧设备交互, 可实现半双工 FDD系统中资源的合理 调度, 提高半双工 FDD系统的资源分配效率。  And receiving, by the network side device, the maximum downlink time-frequency resource that can be scheduled by the DI. The user equipment interacts with the network side device to implement reasonable scheduling of resources in the half-duplex FDD system and improve the resource allocation efficiency of the half-duplex FDD system.
图 9示出了本发明一实施例提供的通信设备的结构示意图,如图 9所示, 本实施例的通信设备包括: 分配单元 91、 建立单元 92、 发送单元 93、 调度 信息生成单元 94和接收单元 95;  FIG. 9 is a schematic structural diagram of a communication device according to an embodiment of the present invention. As shown in FIG. 9, the communication device of this embodiment includes: an allocating unit 91, an establishing unit 92, a sending unit 93, a scheduling information generating unit 94, and Receiving unit 95;
其中, 分配单元 91用于为至少一个数据信道分配第一控制信道; 建立单元 92用于根据分配单元分配的第一控制信道,建立所述第一控制 信道和所述数据信道的映射关系;  The allocating unit 91 is configured to allocate a first control channel to the at least one data channel; the establishing unit 92 is configured to establish a mapping relationship between the first control channel and the data channel according to the first control channel allocated by the allocating unit;
发送单元 93用于将所述建立单元建立的映射关系通知全部用户设备 UE; 调度信息生成单元 94用于根据所述建立单元建立的映射关系和目标 UE 的标识为所述目标 UE分配时频资源位置信息,并根据所述时频资源位置信息 获得所述至少一个数据信道的第一调度信息, 所述第一调度信息使所述目标 UE根据所述时频资源位置信息进行数据传输;  The sending unit 93 is configured to notify all the user equipments UE of the mapping relationship established by the establishing unit. The scheduling information generating unit 94 is configured to allocate time-frequency resources to the target UE according to the mapping relationship established by the establishing unit and the identifier of the target UE. Position information, and obtaining first scheduling information of the at least one data channel according to the time-frequency resource location information, where the first scheduling information causes the target UE to perform data transmission according to the time-frequency resource location information;
接收单元 95用于通过所述至少一个数据信道接收至少一个目标 UE发送 的上行数据;  The receiving unit 95 is configured to receive uplink data sent by the at least one target UE by using the at least one data channel;
所述发送单元 93还用于通过所述第一控制信道向所述全部 UE发送所述 第一调度信息和所述上行数据的反馈信息。  The sending unit 93 is further configured to send, by using the first control channel, the first scheduling information and the feedback information of the uplink data to all the UEs.
举例来说, 第一调度信息可包括: 目标 UE的标识。 或者, 第一调度信息 可包括: 目标 UE的标识, 和第一控制信道能够调度的数据信道的时频资源位 置信息。  For example, the first scheduling information may include: an identifier of the target UE. Alternatively, the first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
在一种可选的场景中, 所述发送单元 93还用于  In an optional scenario, the sending unit 93 is also used to
在通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述 上行数据的反馈信息之后, 将第一控制信道能够调度的数据信道的时频资源 位置信息通知所述全部 UE。  After transmitting the first scheduling information and the feedback information of the uplink data to all the UEs by using the first control channel, notifying all the time-frequency resource location information of the data channel that can be scheduled by the first control channel UE.
在第二种可选的场景中, 在所述第一调度信息中目标 UE 的标识为一个 时, 所述发送单元 93将所述目标 UE的标识的全部字段或部分资源与所述第 一控制信道中的循环冗余校验码 CRC进行异或运算; In a second optional scenario, the identifier of the target UE is one in the first scheduling information. The sending unit 93 performs an exclusive OR operation on all the fields or partial resources of the identifier of the target UE and the cyclic redundancy check code CRC in the first control channel;
并将所述反馈信息和异或运算之后的信息发送至所述全部 UE。  And transmitting the feedback information and the information after the XOR operation to the all UEs.
在第三种可选的场景中, 在所述数据信道的数量小于预设第一阈值, 且 控制信道的数量大于预设的第二阈值时, 所述调度信息生成单元 94还用于 确定第二控制信道的第二调度信息,所述第二调度信息用于为目标 UE分 配所述第二控制信道中的时频资源位置信息;  In a third optional scenario, when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the scheduling information generating unit 94 is further configured to determine Second scheduling information of the second control channel, where the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
所述发送单元 93还用于通过所述第二控制信道向所述全部 UE发送所述 第二调度信息和 /或所述反馈信息。  The sending unit 93 is further configured to send the second scheduling information and/or the feedback information to all UEs by using the second control channel.
举例来说, 前述的时频资源位置可为所述时频资源对应的虚拟资源的位 置; 或者, 前述的时频资源位置可为所述时频资源的物理位置; 或者, 前述 的时频资源位置可为所述第一控制信道中控制时隙对应的能够调度的数据信 道的时频资源范围内的相对位置信息。  For example, the foregoing time-frequency resource location may be a location of the virtual resource corresponding to the time-frequency resource; or the foregoing time-frequency resource location may be a physical location of the time-frequency resource; or the foregoing time-frequency resource The location may be relative location information within a time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel.
在第四种可选的场景中,所述通信设备还包括图中未示出的确定单元 96; 所述确定单元 96用于确定所述第一调度信息中 UI和 DI 的配比, 以及 In a fourth optional scenario, the communication device further includes a determining unit 96 not shown in the figure; the determining unit 96 is configured to determine a ratio of the UI and the DI in the first scheduling information, and
UI和 DI在所述第一控制信道中的位置信息。 Location information of the UI and DI in the first control channel.
举例来说, UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI 和所述 DI采用不同的时隙配比区分; 或者,  For example, when the UI and the DI are sent to the UE by using the same control channel, the UI and the DI are differentiated by using different time slots; or
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者,  The UI and the DI are sent to the UE by using different control channels; or
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。  When the UI and the DI are sent to the UE by using the same control channel, the uplink indication carried by the UI in the control slot of the control channel is different from the downlink carried by the DI in the control slot of the control channel. Instructions.
在第五种可选的场景中, 所述发送单元 93还用于  In a fifth optional scenario, the sending unit 93 is also used to
将所述第一调度信息中所述 UI和所述 DI的配比发送至所述全部 UE; 和 /或,  Transmitting the ratio of the UI and the DI in the first scheduling information to the all UEs; and/or,
将所述第一调度信息中所述 UI和所述 DI的区分方式发送至所述全部 UE; 和 /或,  Transmitting, by the first scheduling information, the manner in which the UI and the DI are differentiated to all UEs; and/or,
将所述 UI所能调度的最大上行时频资源数量发送至所述全部 UE;和 /或, 将所述 DI所能调度的最大下行时频资源数量发送至所述全部 UE。  And sending, to the all UEs, the maximum number of uplink time-frequency resources that can be scheduled by the UI; and/or sending the maximum downlink time-frequency resource that can be scheduled by the DI to all the UEs.
上述的通信设备灵活配置调度数据信道的 UI和 DI ,进而实现半双工 FDD 系统中资源的合理调度, 提高半双工 FDD系统的资源分配效率。 The above communication device flexibly configures the UI and DI of the scheduled data channel to implement half-duplex FDD Reasonable scheduling of resources in the system improves the resource allocation efficiency of the half-duplex FDD system.
图 10示出了本发明一实施例提供的用户设备的结构示意图, 如图 10所 示, 本实施例的用户设备包括: 接收单元 1001、 发送单元 1002和处理单元 1003;  FIG. 10 is a schematic structural diagram of a user equipment according to an embodiment of the present invention. As shown in FIG. 10, the user equipment in this embodiment includes: a receiving unit 1001, a sending unit 1002, and a processing unit 1003.
其中, 接收单元 1001用于监听网络侧设备发送的映射关系, 所述映射关 系为第一控制信道和至少一个数据信道的映射关系;  The receiving unit 1001 is configured to monitor a mapping relationship that is sent by the network side device, where the mapping relationship is a mapping relationship between the first control channel and the at least one data channel.
发送单元 1002用于在所述 UE为目标 UE时,通过所述至少一个数据信道 向所述网络侧设备发送上行数据;  The sending unit 1002 is configured to send uplink data to the network side device by using the at least one data channel when the UE is a target UE;
所述接收单元 1001用于在所述发送单元 1002发送所述上行数据之后, 接收所述网络侧设备通过所述第一控制信道发送的第一调度信息和所述上行 数据的反馈信息, 所述第一调度信息为所述网络侧设备根据所述映射关系和 所述目标 UE的标识获得的;  The receiving unit 1001 is configured to: after the transmitting unit 1002 sends the uplink data, receive first scheduling information that is sent by the network side device by using the first control channel, and feedback information of the uplink data, where The first scheduling information is obtained by the network side device according to the mapping relationship and the identifier of the target UE;
处理单元 1003用于在所述接收单元 1001接收所述第一调度信息之后, 根据所述第一调度信息进行数据传输, 并处理所述上行数据的反馈信息。  The processing unit 1003 is configured to: after the receiving unit 1001 receives the first scheduling information, perform data transmission according to the first scheduling information, and process feedback information of the uplink data.
举例来说, 第一调度信息可包括: 目标 UE的标识。 或者, 前述的第一调 度信息可包括: 目标 UE的标识, 和第一控制信道能够调度的数据信道的时频 资源位置信息。  For example, the first scheduling information may include: an identifier of the target UE. Alternatively, the foregoing first scheduling information may include: an identifier of the target UE, and time-frequency resource location information of the data channel that the first control channel can schedule.
在一种可选的场景中, 接收单元 1001还用于在所述处理单元 1003进行 数据传输之前, 接收所述网络侧设备发送的时频资源位置信息, 所述时频资 源位置信息为所述第一控制信道能够调度的数据信道的时频资源位置信息。  In an optional scenario, the receiving unit 1001 is further configured to: before the processing unit 1003 performs data transmission, receive time-frequency resource location information sent by the network-side device, where the time-frequency resource location information is The time-frequency resource location information of the data channel that the first control channel can schedule.
在第二种可选的场景中, 在所述数据信道的数量小于预设第一阈值, 且 控制信道的数量大于预设的第二阈值时, 所述接收单元 1001还用于  In the second optional scenario, when the number of the data channels is less than a preset first threshold, and the number of control channels is greater than a preset second threshold, the receiving unit 1001 is further used.
接收所述网络侧设备通过所述第二控制信道发送的第二调度信息和 /或 所述反馈信息;  Receiving second scheduling information and/or the feedback information that is sent by the network side device by using the second control channel;
所述处理单元 1003还用于在所述接收单元接收所述第二调度信息之后, 根据所述第二调度信息进行数据传输, 和 /或处理所述反馈信息。  The processing unit 1003 is further configured to: after the receiving unit receives the second scheduling information, perform data transmission according to the second scheduling information, and/or process the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。  The second scheduling information is second scheduling information of the second control channel that is acquired by the network side device, and includes the target UE identifier.
举例来说, 前述的时频资源位置可为所述时频资源对应的虚拟资源的位 置; 或者, 时频资源位置可为所述时频资源的物理位置; 或者, 时频资源位 置可为所述第一控制信道中控制时隙对应的能够调度的数据信道的时频资源 范围内的相对位置信息。 For example, the foregoing time-frequency resource location may be a location of the virtual resource corresponding to the time-frequency resource; or the time-frequency resource location may be a physical location of the time-frequency resource; or, the time-frequency resource bit The relative position information in the time-frequency resource range of the scheduleable data channel corresponding to the control slot in the first control channel may be set.
在第三种可选的场景中, 所述接收单元 1001 还用于, 在所述处理单元 1003进行数据传输之前, 接收所述网络侧设备发送的所述第一调度信息中所 述 UI和所述 DI的配比, 和 /或,  In a third optional scenario, the receiving unit 1001 is further configured to: before the processing unit 1003 performs data transmission, receive the UI and the first scheduling information sent by the network side device. The ratio of DI, and / or,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区 分方法, 和 /或,  Receiving, by the network side device, the method for distinguishing the UI and the DI in the first scheduling information, and/or,
接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资源数量, 和 /或,  Receiving, by the network side device, the maximum uplink time-frequency resource that can be scheduled by the UI, and/or,
接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资源数量。 上述用户设备与网络侧设备交互, 可实现半双工 FDD系统中资源的合理 调度, 提高半双工 FDD系统的资源分配效率。  And receiving, by the network side device, the maximum downlink time-frequency resource that can be scheduled by the DI. The user equipment interacts with the network side device to implement reasonable scheduling of resources in the half-duplex FDD system and improve the resource allocation efficiency of the half-duplex FDD system.
本领域普通技术人员可以理解: 实现上述方法实施例的全部或部分步骤 可以通过程序指令相关的硬件来完成, 前述的程序可以存储于一计算机可读 取存储介质中, 该程序在执行时, 执行包括上述方法实施例的步骤; 而前述 的存储介质包括: R0M、 RAM, 磁碟或者光盘等各种可以存储程序代码的介质。  A person skilled in the art can understand that all or part of the steps of implementing the above method embodiments may be completed by using hardware related to program instructions, and the foregoing program may be stored in a computer readable storage medium, and the program is executed when executed. The steps of the foregoing method embodiments are included; and the foregoing storage medium includes: a medium that can store program codes, such as a ROM, a RAM, a magnetic disk, or an optical disk.
最后应说明的是: 以上各实施例仅用以说明本发明的技术方案, 而非对 其限制; 尽管参照前述各实施例对本发明进行了详细的说明, 本领域的普通 技术人员应当理解:其依然可以对前述各实施例所记载的技术方案进行修改, 或者对其中部分或者全部技术特征进行等同替换; 而这些修改或者替换, 并 不使相应技术方案的本质脱离本发明各实施例技术方案的范围。  Finally, it should be noted that the above embodiments are only for explaining the technical solutions of the present invention, and are not intended to be limiting thereof; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that The technical solutions described in the foregoing embodiments may be modified, or some or all of the technical features may be equivalently replaced; and the modifications or substitutions do not deviate from the technical solutions of the embodiments of the present invention. range.

Claims

权 利 要 求 书 claims
1、 一种资源调度方法, 其特征在于, 包括: 1. A resource scheduling method, characterized by including:
网络侧设备为至少一个数据信道分配第一控制信道, 建立所述第一控制 信道和所述数据信道的映射关系, 并将所述映射关系通知全部用户设备 UE; 所述网络侧设备根据所述映射关系和目标 UE的标识为所述目标 UE分配 时频资源位置信息, 并根据所述时频资源位置信息获得所述至少一个数据信 道的第一调度信息,所述第一调度信息使所述目标 UE根据所述时频资源位置 信息进行数据传输; The network side device allocates a first control channel to at least one data channel, establishes a mapping relationship between the first control channel and the data channel, and notifies all user equipment UE of the mapping relationship; The mapping relationship and the identification of the target UE allocate time-frequency resource location information to the target UE, and obtain the first scheduling information of the at least one data channel based on the time-frequency resource location information. The first scheduling information enables the The target UE performs data transmission according to the time-frequency resource location information;
所述网络侧设备通过所述至少一个数据信道接收至少一个目标 UE 发送 的上行数据; The network side device receives uplink data sent by at least one target UE through the at least one data channel;
所述网络侧设备通过所述第一控制信道向所述全部 UE 发送所述第一调 度信息和所述上行数据的反馈信息。 The network side device sends the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel.
2、 根据权利要求 1所述的方法, 其特征在于, 所述第一调度信息包括: 目标 UE的标识; 2. The method according to claim 1, characterized in that the first scheduling information includes: an identification of the target UE;
或者, or,
目标 UE的标识; The identification of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。 The time-frequency resource location information of the data channel that can be scheduled by the first control channel.
3、 根据权利要求 1所述的方法, 其特征在于, 所述网络侧设备通过所述 第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数据的反馈 信息之后, 所述方法还包括: 3. The method according to claim 1, characterized in that, after the network side device sends the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel, The above methods also include:
所述网络侧设备将第一控制信道能够调度的数据信道的时频资源位置信 息通知所述全部 UE。 The network side device notifies all UEs of the time-frequency resource location information of the data channels that can be scheduled by the first control channel.
4、 根据权利要求 1至 3任一所述的方法, 其特征在于, 在所述第一调度 信息中目标 UE的标识为一个时,所述网络侧设备通过所述第一控制信道向所 述全部 UE发送所述第一调度信息和所述上行数据的反馈信息; 包括: 4. The method according to any one of claims 1 to 3, characterized in that, when the identification of the target UE in the first scheduling information is one, the network side device sends a message to the first control channel through the first control channel. All UEs send the first scheduling information and the feedback information of the uplink data; including:
所述网络侧设备将所述目标 UE 的标识的全部字段或部分资源与所述第 一控制信道中的循环冗余校验码 CRC进行异或运算; The network side device performs an XOR operation on all fields or part of the resources identified by the target UE and the cyclic redundancy check code CRC in the first control channel;
所述网络侧设备将所述反馈信息和异或运算之后的信息发送至所述全部 The network side device sends the feedback information and the information after the XOR operation to all
5、 根据权利要求 1至 3任一所述的方法, 其特征在于, 在所述数据信道 的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值时, 所述 方法还包括: 5. The method according to any one of claims 1 to 3, characterized in that, in the data channel When the number of is less than the preset first threshold, and the number of control channels is greater than the preset second threshold, the method further includes:
所述网络侧设备确定第二控制信道的第二调度信息, 所述第二调度信息 用于为目标 UE分配所述第二控制信道中的时频资源位置信息; The network side device determines second scheduling information of the second control channel, and the second scheduling information is used to allocate time-frequency resource location information in the second control channel to the target UE;
所述网络侧设备通过所述第二控制信道向所述全部 UE 发送所述第二调 度信息和 /或所述反馈信息。 The network side device sends the second scheduling information and/or the feedback information to all UEs through the second control channel.
6、 根据权利要求 1至 4任一所述的方法, 其特征在于, 6. The method according to any one of claims 1 to 4, characterized in that,
所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 所述时频资源位置为所述时频资源的物理位置; 或者, The time-frequency resource location is the location of the virtual resource corresponding to the time-frequency resource; or, the time-frequency resource location is the physical location of the time-frequency resource; or,
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。 The time-frequency resource position is the relative position information within the time-frequency resource range of the schedulable data channel corresponding to the control time slot in the first control channel.
7、 根据权利要求 1至 6任一所述的方法, 其特征在于, 所述网络侧设备 通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数 据的反馈信息之前, 所述方法还包括: 7. The method according to any one of claims 1 to 6, characterized in that, the network side device sends the first scheduling information and the feedback of the uplink data to all UEs through the first control channel. Before the information, the method also includes:
所述网络侧设备确定所述第一调度信息中上行调度信息 UI 和下行调度 信息 DI的配比, 以及所述 UI和所述 DI在所述第一控制信道中的位置信息。 The network side device determines a ratio of uplink scheduling information UI and downlink scheduling information DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
8、 根据权利要求 7所述的方法, 其特征在于, 8. The method according to claim 7, characterized in that,
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI和所述 DI采用不同的时隙配比区分; 或者, When the UI and the DI are sent to the UE using the same control channel, the UI and the DI are distinguished by different time slot ratios; or,
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者, 所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。 The UI and the DI are sent to the UE using different control channels; or, when the UI and the DI are sent to the UE using the same control channel, the UI is carried in the control time slot of the control channel. The uplink indication is different from the downlink indication carried by the DI in the control time slot of the control channel.
9、 根据权利要求 7或 8所述的方法, 其特征在于, 所述网络侧设备通过 所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数据的 反馈信息之前 /之后, 所述方法还包括: 9. The method according to claim 7 or 8, characterized in that, before the network side device sends the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel /After that, the method also includes:
所述网络侧设备将所述第一调度信息中所述 UI和所述 DI的配比发送至 所述全部 UE; 和 /或, The network side device sends the ratio of the UI and the DI in the first scheduling information to all UEs; and/or,
所述网络侧设备将所述第一调度信息中所述 UI和所述 DI的区分方式发 送至所述全部 UE; 和 /或, 所述网络侧设备将所述 UI 所能调度的最大上行时频资源数量发送至所 述全部 UE; 和 /或, The network side device sends the distinguishing method of the UI and the DI in the first scheduling information to all UEs; and/or, The network side device sends the maximum number of uplink time-frequency resources that can be scheduled by the UI to all UEs; and/or,
所述网络侧设备将所述 DI 所能调度的最大下行时频资源数量发送至所 述全部 UE。 The network side device sends the maximum number of downlink time-frequency resources that can be scheduled by the DI to all UEs.
10、 一种数据传输方法, 其特征在于, 包括: 10. A data transmission method, characterized by including:
所有用户设备 UE监听网络侧设备发送的映射关系,所述映射关系为第一 控制信道和至少一个数据信道的映射关系; All user equipment UEs monitor the mapping relationship sent by the network side device, where the mapping relationship is the mapping relationship between the first control channel and at least one data channel;
所述所有 UE中的目标 UE通过所述至少一个数据信道向所述网络侧设备 发送上行数据; The target UE among all UEs sends uplink data to the network side device through the at least one data channel;
所述所有 UE 接收所述网络侧设备通过所述第一控制信道发送的第一调 度信息和所述上行数据的反馈信息, 所述第一调度信息为所述网络侧设备根 据所述映射关系和所述目标 UE的标识获得的; The all UEs receive the first scheduling information and the feedback information of the uplink data sent by the network side device through the first control channel, and the first scheduling information is the network side device according to the mapping relationship and The identity of the target UE is obtained;
所述目标 UE根据所述第一调度信息进行数据传输,并处理所述上行数据 的反馈信息。 The target UE performs data transmission according to the first scheduling information, and processes the feedback information of the uplink data.
11、根据权利要求 10所述的方法,其特征在于,所述第一调度信息包括: 目标 UE的标识; 11. The method according to claim 10, characterized in that the first scheduling information includes: an identification of the target UE;
或者, or,
目标 UE的标识; The identification of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。 The time-frequency resource location information of the data channel that can be scheduled by the first control channel.
12、 根据权利要求 10所述的方法, 其特征在于, 所述目标 UE根据所述 第一调度信息进行数据传输之前, 所述方法还包括: 12. The method according to claim 10, characterized in that, before the target UE performs data transmission according to the first scheduling information, the method further includes:
所述所有 UE 接收所述网络侧设备发送的时频资源位置信息, 所述时频 资源位置信息为所述第一控制信道能够调度的数据信道的时频资源位置信 息。 The all UEs receive the time-frequency resource location information sent by the network side device, and the time-frequency resource location information is the time-frequency resource location information of the data channel that can be scheduled by the first control channel.
13、 根据权利要求 10至 12任一所述的方法, 其特征在于, 在所述数据 信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值时, 所述方法还包括: 13. The method according to any one of claims 10 to 12, wherein when the number of data channels is less than a preset first threshold and the number of control channels is greater than a preset second threshold, the method Also includes:
所述所有 UE 接收所述网络侧设备通过所述第二控制信道发送的第二调 度信息和 /或所述反馈信息; The all UEs receive the second scheduling information and/or the feedback information sent by the network side device through the second control channel;
所述目标 UE根据所述第二调度信息进行数据传输, 和 /或处理所述反馈 信息。 The target UE performs data transmission according to the second scheduling information, and/or processes the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。 Wherein, the second scheduling information is the second scheduling information of the second control channel obtained by the network side device and includes the target UE identity.
14、 根据权利要求 10至 12任一所述的方法, 其特征在于, 14. The method according to any one of claims 10 to 12, characterized in that,
所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 所述时频资源位置为所述时频资源的物理位置; 或者, The time-frequency resource location is the location of the virtual resource corresponding to the time-frequency resource; or, the time-frequency resource location is the physical location of the time-frequency resource; or,
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。 The time-frequency resource position is the relative position information within the time-frequency resource range of the schedulable data channel corresponding to the control time slot in the first control channel.
15、 根据权利要求 10至 12任一所述的方法, 其特征在于, 所述目标 UE 根据所述第一调度信息进行数据传输之前, 所述方法还包括: 15. The method according to any one of claims 10 to 12, characterized in that, before the target UE performs data transmission according to the first scheduling information, the method further includes:
所述所有 UE接收所述网络 备发送的所述第一调度信息中所述 UI和 所述 DI的配比, 和 /或, All UEs receive the ratio of the UI and the DI in the first scheduling information sent by the network equipment, and/or,
所述所有 UE接收所述网络 备发送的所述第一调度信息中所述 UI和 所述 DI的区分方法, 和 /或, All UEs receive the method of distinguishing the UI and the DI in the first scheduling information sent by the network equipment, and/or,
所述所有 UE接收所述网络 备发送的所述 UI所能调度的最大上行时 频资源数量, 和 /或, The maximum number of uplink time-frequency resources that all UEs can schedule when receiving the UI sent by the network equipment, and/or,
所述所有 UE接收所述网络 备发送的所述 DI所能调度的最大下行时 频资源数量。 All UEs receive the maximum number of downlink time-frequency resources that can be scheduled by the DI sent by the network equipment.
16、 一种通信设备, 其特征在于, 包括: 16. A communication device, characterized by including:
存储器和处理器; memory and processor;
所述存储器用于存储指令; The memory is used to store instructions;
所述处理器执行所述存储器中存储的指令, 用于: The processor executes instructions stored in the memory for:
为至少一个数据信道分配第一控制信道, 建立所述第一控制信道和所述 数据信道的映射关系, 并将所述映射关系通知全部用户设备 UE; Allocate a first control channel to at least one data channel, establish a mapping relationship between the first control channel and the data channel, and notify all user equipment UEs of the mapping relationship;
根据所述映射关系和目标 UE的标识为所述目标 UE分配时频资源位置信 息, 并根据所述时频资源位置信息获得所述至少一个数据信道的第一调度信 息,所述第一调度信息使所述目标 UE根据所述时频资源位置信息进行数据传 输; Allocate time-frequency resource location information to the target UE according to the mapping relationship and the identification of the target UE, and obtain first scheduling information of the at least one data channel based on the time-frequency resource location information, the first scheduling information causing the target UE to perform data transmission according to the time-frequency resource location information;
通过所述至少一个数据信道接收至少一个目标 UE发送的上行数据; 通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上 行数据的反馈信息。 Receive uplink data sent by at least one target UE through the at least one data channel; Send the first scheduling information and the uplink data to all UEs through the first control channel Feedback information for row data.
17、 根据权利要求 16所述的通信设备, 其特征在于, 所述第一调度信息 包括: 17. The communication device according to claim 16, wherein the first scheduling information includes:
目标 UE的标识; The identification of the target UE;
或者, or,
目标 UE的标识; The identification of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。 The time-frequency resource location information of the data channel that can be scheduled by the first control channel.
18、 根据权利要求 16所述的通信设备, 其特征在于, 所述处理器通过所 述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数据的反 馈信息之后, 还用于 18. The communication device according to claim 16, characterized in that, after the processor sends the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel, used for
将第一控制信道能够调度的数据信道的时频资源位置信息通知所述全部 Notify all of the time-frequency resource location information of the data channels that can be scheduled by the first control channel
19、 根据权利要求 16至 18任一所述的通信设备, 其特征在于, 在所述 第一调度信息中目标 UE的标识为一个时,所述处理器通过所述第一控制信道 向所述全部 UE发送所述第一调度信息和所述上行数据的反馈信息; 包括: 所述处理器将所述目标 UE 的标识的全部字段或部分资源与所述第一控 制信道中的循环冗余校验码 CRC进行异或运算; 19. The communication device according to any one of claims 16 to 18, characterized in that, when the identification of the target UE in the first scheduling information is one, the processor sends a message to the first control channel through the first control channel. All UEs send the first scheduling information and the feedback information of the uplink data; including: the processor comparing all fields or part of resources identified by the target UE with cyclic redundancy in the first control channel; Check the code CRC for XOR operation;
将所述反馈信息和异或运算之后的信息发送至所述全部 UE。 The feedback information and the information after the XOR operation are sent to all UEs.
20、 根据权利要求 16至 18任一所述的通信设备, 其特征在于, 在所述 数据信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值 时, 所述处理器还用于: 20. The communication device according to any one of claims 16 to 18, wherein when the number of data channels is less than a preset first threshold and the number of control channels is greater than a preset second threshold, the The processor is also used for:
确定第二控制信道的第二调度信息,所述第二调度信息用于为目标 UE分 配所述第二控制信道中的时频资源位置信息; Determine second scheduling information of the second control channel, the second scheduling information being used to allocate time-frequency resource location information in the second control channel to the target UE;
通过所述第二控制信道向所述全部 UE发送所述第二调度信息和 /或所述 反馈信息。 Send the second scheduling information and/or the feedback information to all UEs through the second control channel.
21、 根据权利要求 16至 19任一所述的通信设备, 其特征在于, 所述时 频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 21. The communication device according to any one of claims 16 to 19, characterized in that the location of the time-frequency resource is the location of the virtual resource corresponding to the time-frequency resource; or,
所述时频资源位置为所述时频资源的物理位置; 或者, The time-frequency resource location is the physical location of the time-frequency resource; or,
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。 The time-frequency resource position is the relative position information within the time-frequency resource range of the schedulable data channel corresponding to the control time slot in the first control channel.
22、 根据权利要求 16至 21任一所述的通信设备, 其特征在于, 所述处 理器通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上 行数据的反馈信息之前, 还用于 22. The communication device according to any one of claims 16 to 21, wherein the processor sends the first scheduling information and the feedback of the uplink data to all UEs through the first control channel. before information, also used for
确定所述第一调度信息中上行调度信息 UI和下行调度信息 DI的配比, 以及所述 UI和所述 DI在所述第一控制信道中的位置信息。 Determine the ratio of the uplink scheduling information UI and the downlink scheduling information DI in the first scheduling information, and the location information of the UI and the DI in the first control channel.
23、 根据权利要求 22所述的通信设备, 其特征在于, 所述 UI和所述 DI 采用同一控制信道向所述 UE发送时,所述 UI和所述 DI采用不同的时隙配比 区分; 或者, 23. The communication device according to claim 22, characterized in that, when the UI and the DI are sent to the UE using the same control channel, the UI and the DI are distinguished by different time slot ratios; or,
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者, The UI and the DI are sent to the UE using different control channels; or,
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。 When the UI and the DI are sent to the UE using the same control channel, the uplink indication carried by the UI in the control time slot of the control channel is different from the downlink indication carried by the DI in the control time slot of the control channel. instruct.
24、 根据权利要求 22或 23所述的通信设备, 其特征在于, 所述处理器 通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述上行数 据的反馈信息之前 /之后, 还用于: 24. The communication device according to claim 22 or 23, characterized in that, before the processor sends the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel, After /, also used for:
将所述第一调度信息中所述 UI和所述 DI的配比发送至所述全部 UE; 和 Send the ratio of the UI and the DI in the first scheduling information to all UEs; and
/或, /or,
将所述第一调度信息中所述 UI和所述 DI的区分方式发送至所述全部 UE; 和 /或, Send the distinction between the UI and the DI in the first scheduling information to all UEs; and/or,
将所述 UI所能调度的最大上行时频资源数量发送至所述全部 UE;和 /或, 将所述 DI所能调度的最大下行时频资源数量发送至所述全部 UE。 Send the maximum number of uplink time-frequency resources that can be scheduled by the UI to all UEs; and/or send the maximum number of downlink time-frequency resources that can be scheduled by the DI to all UEs.
25、 一种用户设备, 其特征在于, 包括: 25. A user equipment, characterized by: including:
存储器和处理器; memory and processor;
所述存储器用于存储指令; The memory is used to store instructions;
所述处理器执行所述存储器中存储的指令, 用于: The processor executes instructions stored in the memory for:
监听网络侧设备发送的映射关系, 所述映射关系为第一控制信道和至少 一个数据信道的映射关系; Monitor the mapping relationship sent by the network side device, where the mapping relationship is the mapping relationship between the first control channel and at least one data channel;
在所述用户设备 UE为目标 UE时, 通过所述至少一个数据信道向所述网 络侧设备发送上行数据, When the user equipment UE is the target UE, sending uplink data to the network side device through the at least one data channel,
接收所述网络侧设备通过所述第一控制信道发送的第一调度信息和所述 上行数据的反馈信息, 所述第一调度信息为所述网络侧设备根据所述映射关 系和所述目标 UE的标识获得的; Receive first scheduling information sent by the network side device through the first control channel and the Feedback information of uplink data, the first scheduling information is obtained by the network side device according to the mapping relationship and the identity of the target UE;
根据所述第一调度信息进行数据传输,并处理所述上行数据的反馈信息。 Perform data transmission according to the first scheduling information, and process the feedback information of the uplink data.
26、 根据权利要求 25所述的用户设备, 其特征在于, 所述第一调度信息 包括: 目标 UE的标识; 26. The user equipment according to claim 25, characterized in that, the first scheduling information includes: an identification of the target UE;
或者, or,
目标 UE的标识; The identification of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。 The time-frequency resource location information of the data channel that can be scheduled by the first control channel.
27、 根据权利要求 25所述的用户设备, 其特征在于, 所述处理器根据所 述第一调度信息进行数据传输之前, 还用于 27. The user equipment according to claim 25, characterized in that, before the processor performs data transmission according to the first scheduling information, it is also configured to:
接收所述网络侧设备发送的时频资源位置信息, 所述时频资源位置信息 为所述第一控制信道能够调度的数据信道的时频资源位置信息。 Receive time-frequency resource location information sent by the network side device, where the time-frequency resource location information is time-frequency resource location information of a data channel that can be scheduled by the first control channel.
28、 根据权利要求 25至 27任一所述的用户设备, 其特征在于, 在所述 数据信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值 时, 所述处理器还用于 28. The user equipment according to any one of claims 25 to 27, wherein when the number of data channels is less than a preset first threshold and the number of control channels is greater than a preset second threshold, the The processor is also used
接收所述网络侧设备通过所述第二控制信道发送的第二调度信息和 /或 所述反馈信息; Receive the second scheduling information and/or the feedback information sent by the network side device through the second control channel;
根据所述第二调度信息进行数据传输, 和 /或处理所述反馈信息。 Perform data transmission according to the second scheduling information, and/or process the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。 Wherein, the second scheduling information is the second scheduling information of the second control channel obtained by the network side device and includes the target UE identity.
29、 根据权利要求 25至 27任一所述的用户设备, 其特征在于, 所述时 频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 29. The user equipment according to any one of claims 25 to 27, wherein the time-frequency resource location is the location of the virtual resource corresponding to the time-frequency resource; or,
所述时频资源位置为所述时频资源的物理位置; 或者, The time-frequency resource location is the physical location of the time-frequency resource; or,
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。 The time-frequency resource position is the relative position information within the time-frequency resource range of the schedulable data channel corresponding to the control time slot in the first control channel.
30、 根据权利要求 25至 27任一所述的用户设备, 其特征在于, 所述处 理器根据所述第一调度信息进行数据传输之前, 还用于 30. The user equipment according to any one of claims 25 to 27, characterized in that, before the processor performs data transmission according to the first scheduling information, it is also configured to:
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的配 比, 和 /或, Receive the ratio of the UI and the DI in the first scheduling information sent by the network side device, and/or,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区 分方法, 和 /或, Receive the area of the UI and the DI in the first scheduling information sent by the network side device. method, and/or,
接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资源数量, 和 /或, Receive the maximum number of uplink time-frequency resources that can be scheduled by the UI sent by the network side device, and/or,
接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资源数量。 Receive the maximum number of downlink time-frequency resources that can be scheduled by the DI sent by the network side device.
31、 一种通信设备, 其特征在于, 包括: 31. A communication device, characterized by: including:
分配单元, 用于为至少一个数据信道分配第一控制信道; An allocation unit, configured to allocate a first control channel to at least one data channel;
建立单元, 用于根据分配单元分配的第一控制信道, 建立所述第一控制 信道和所述数据信道的映射关系; An establishment unit, configured to establish a mapping relationship between the first control channel and the data channel according to the first control channel allocated by the allocation unit;
发送单元, 用于将所述建立单元建立的映射关系通知全部用户设备 UE; 调度信息生成单元,用于根据所述建立单元建立的映射关系和目标 UE的 标识为所述目标 UE分配时频资源位置信息,并根据所述时频资源位置信息获 得所述至少一个数据信道的第一调度信息, 所述第一调度信息使所述目标 UE 根据所述时频资源位置信息进行数据传输; a sending unit, configured to notify all user equipments UE of the mapping relationship established by the establishing unit; a scheduling information generating unit, configured to allocate time-frequency resources to the target UE according to the mapping relationship established by the establishing unit and the identification of the target UE location information, and obtain the first scheduling information of the at least one data channel based on the time-frequency resource location information, and the first scheduling information enables the target UE to perform data transmission based on the time-frequency resource location information;
接收单元,用于通过所述至少一个数据信道接收至少一个目标 UE发送的 上行数据; A receiving unit configured to receive uplink data sent by at least one target UE through the at least one data channel;
所述发送单元,还用于通过所述第一控制信道向所述全部 UE发送所述第 一调度信息和所述上行数据的反馈信息。 The sending unit is further configured to send the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel.
32、 根据权利要求 31所述的通信设备, 其特征在于, 所述第一调度信息 包括: 目标 UE的标识; 32. The communication device according to claim 31, wherein the first scheduling information includes: an identification of the target UE;
或者, or,
目标 UE的标识; The identification of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。 The time-frequency resource location information of the data channel that can be scheduled by the first control channel.
33、 根据权利要求 31所述的通信设备, 其特征在于, 所述发送单元, 还 用于 33. The communication device according to claim 31, characterized in that the sending unit is also used to
在通过所述第一控制信道向所述全部 UE 发送所述第一调度信息和所述 上行数据的反馈信息之后, 将第一控制信道能够调度的数据信道的时频资源 位置信息通知所述全部 UE。 After sending the first scheduling information and the feedback information of the uplink data to all UEs through the first control channel, notify all UEs of the time-frequency resource location information of the data channels that can be scheduled by the first control channel. UE.
34、 根据权利要求 31至 33任一所述的通信设备, 其特征在于, 在所述 第一调度信息中目标 UE的标识为一个时, 所述发送单元将所述目标 UE的标 识的全部字段或部分资源与所述第一控制信道中的循环冗余校验码 CRC进行 异或运算; 34. The communication device according to any one of claims 31 to 33, characterized in that, when there is one identifier of the target UE in the first scheduling information, the sending unit sends all fields of the identifier of the target UE. Or part of the resources are combined with the cyclic redundancy check code CRC in the first control channel XOR operation;
并将所述反馈信息和异或运算之后的信息发送至所述全部 UE。 and send the feedback information and the information after the XOR operation to all UEs.
35、 根据权利要求 31至 33任一所述的通信设备, 其特征在于, 在所述 数据信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值 时, 所述调度信息生成单元, 还用于 35. The communication device according to any one of claims 31 to 33, wherein when the number of data channels is less than a preset first threshold and the number of control channels is greater than a preset second threshold, the Scheduling information generation unit, also used for
确定第二控制信道的第二调度信息,所述第二调度信息用于为目标 UE分 配所述第二控制信道中的时频资源位置信息; Determine second scheduling information of the second control channel, the second scheduling information being used to allocate time-frequency resource location information in the second control channel to the target UE;
所述发送单元,还用于通过所述第二控制信道向所述全部 UE发送所述第 二调度信息和 /或所述反馈信息。 The sending unit is further configured to send the second scheduling information and/or the feedback information to all UEs through the second control channel.
36、 根据权利要求 31至 34任一所述的通信设备, 其特征在于, 所述时 频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 36. The communication device according to any one of claims 31 to 34, wherein the time-frequency resource location is the location of the virtual resource corresponding to the time-frequency resource; or,
所述时频资源位置为所述时频资源的物理位置; 或者, The time-frequency resource location is the physical location of the time-frequency resource; or,
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。 The time-frequency resource position is the relative position information within the time-frequency resource range of the schedulable data channel corresponding to the control time slot in the first control channel.
37、 根据权利要求 31至 36任一所述的通信设备, 其特征在于, 所述通 信设备还包括: 确定单元; 37. The communication device according to any one of claims 31 to 36, characterized in that the communication device further includes: a determining unit;
所述确定单元用于确定所述第一调度信息中上行调度信息 UI 和下行调 度信息 DI的配比,以及所述 UI和所述 DI在所述第一控制信道中的位置信息。 The determining unit is configured to determine a ratio of uplink scheduling information UI and downlink scheduling information DI in the first scheduling information, and location information of the UI and the DI in the first control channel.
38、 根据权利要求 37所述的通信设备, 其特征在于, 所述 UI和所述 DI 采用同一控制信道向所述 UE发送时,所述 UI和所述 DI采用不同的时隙配比 区分; 或者, 38. The communication device according to claim 37, characterized in that, when the UI and the DI are sent to the UE using the same control channel, the UI and the DI are distinguished by different time slot ratios; or,
所述 UI和所述 DI采用不同的控制信道向所述 UE发送; 或者, The UI and the DI are sent to the UE using different control channels; or,
所述 UI和所述 DI采用同一控制信道向所述 UE发送时, 所述 UI在控制 信道的控制时隙中携带的上行指示不同于,所述 DI在控制信道的控制时隙中 携带的下行指示。 When the UI and the DI are sent to the UE using the same control channel, the uplink indication carried by the UI in the control time slot of the control channel is different from the downlink indication carried by the DI in the control time slot of the control channel. instruct.
39、 根据权利要求 37或 38所述的通信设备, 其特征在于, 所述发送单 元, 还用于 39. The communication device according to claim 37 or 38, characterized in that the sending unit is also used to
将所述第一调度信息中所述 UI和所述 DI的配比发送至所述全部 UE; 和 Send the ratio of the UI and the DI in the first scheduling information to all UEs; and
/或, /or,
将所述第一调度信息中所述 UI和所述 DI的区分方式发送至所述全部 UE; 和 /或, Send the distinction between the UI and the DI in the first scheduling information to all UEs; and / or,
将所述 UI所能调度的最大上行时频资源数量发送至所述全部 UE;和 /或, 将所述 DI所能调度的最大下行时频资源数量发送至所述全部 UE。 Send the maximum number of uplink time-frequency resources that can be scheduled by the UI to all UEs; and/or send the maximum number of downlink time-frequency resources that can be scheduled by the DI to all UEs.
40、 一种用户设备, 其特征在于, 包括: 40. A user equipment, characterized by: including:
接收单元, 用于监听网络侧设备发送的映射关系, 所述映射关系为第一 控制信道和至少一个数据信道的映射关系; The receiving unit is configured to monitor the mapping relationship sent by the network side device, where the mapping relationship is the mapping relationship between the first control channel and at least one data channel;
发送单元, 用于在所述用户设备 UE为目标 UE时, 通过所述至少一个数 据信道向所述网络侧设备发送上行数据; A sending unit, configured to send uplink data to the network side device through the at least one data channel when the user equipment UE is the target UE;
所述接收单元, 用于在所述发送单元发送所述上行数据之后, 接收所述 网络侧设备通过所述第一控制信道发送的第一调度信息和所述上行数据的反 馈信息, 所述第一调度信息为所述网络侧设备根据所述映射关系和所述目标 The receiving unit is configured to receive the first scheduling information and the feedback information of the uplink data sent by the network side device through the first control channel after the sending unit sends the uplink data, and the first A scheduling information is the network side device according to the mapping relationship and the target
UE的标识获得的; The identity of the UE is obtained;
处理单元, 用于在所述接收单元接收所述第一调度信息之后, 根据所述 第一调度信息进行数据传输, 并处理所述上行数据的反馈信息。 A processing unit, configured to perform data transmission according to the first scheduling information after the receiving unit receives the first scheduling information, and process the feedback information of the uplink data.
41、 根据权利要求 40所述的用户设备, 其特征在于, 所述第一调度信息 包括: 目标 UE的标识; 41. The user equipment according to claim 40, characterized in that the first scheduling information includes: an identification of the target UE;
或者, or,
目标 UE的标识; The identification of the target UE;
所述第一控制信道能够调度的数据信道的时频资源位置信息。 The time-frequency resource location information of the data channel that can be scheduled by the first control channel.
42、 根据权利要求 40所述的用户设备, 其特征在于, 所述接收单元, 还 用于 42. The user equipment according to claim 40, characterized in that the receiving unit is also used to
在所述处理单元进行数据传输之前, 接收所述网络侧设备发送的时频资 源位置信息, 所述时频资源位置信息为所述第一控制信道能够调度的数据信 道的时频资源位置信息。 Before the processing unit performs data transmission, the time-frequency resource location information sent by the network side device is received, where the time-frequency resource location information is the time-frequency resource location information of the data channel that can be scheduled by the first control channel.
43、 根据权利要求 40至 42任一所述的用户设备, 其特征在于, 在所述 数据信道的数量小于预设第一阈值, 且控制信道的数量大于预设的第二阈值 时, 所述接收单元, 还用于 43. The user equipment according to any one of claims 40 to 42, wherein when the number of data channels is less than a preset first threshold and the number of control channels is greater than a preset second threshold, the receiving unit, also for
接收所述网络侧设备通过所述第二控制信道发送的第二调度信息和 /或 所述反馈信息; Receive the second scheduling information and/or the feedback information sent by the network side device through the second control channel;
所述处理单元, 还用于在所述接收单元接收所述第二调度信息之后, 根 据所述第二调度信息进行数据传输, 和 /或处理所述反馈信息。 The processing unit is further configured to: after the receiving unit receives the second scheduling information, Perform data transmission according to the second scheduling information, and/or process the feedback information.
其中, 所述第二调度信息为所述网络侧设备获取的第二控制信道的包括 所述目标 UE标识的第二调度信息。 Wherein, the second scheduling information is the second scheduling information of the second control channel obtained by the network side device and includes the target UE identity.
44、 根据权利要求 40至 42任一所述的用户设备, 其特征在于, 所述时频资源位置为所述时频资源对应的虚拟资源的位置; 或者, 所述时频资源位置为所述时频资源的物理位置; 或者, 44. The user equipment according to any one of claims 40 to 42, wherein the time-frequency resource location is the location of the virtual resource corresponding to the time-frequency resource; or, the time-frequency resource location is the The physical location of the time-frequency resource; or,
所述时频资源位置为所述第一控制信道中控制时隙对应的能够调度的数 据信道的时频资源范围内的相对位置信息。 The time-frequency resource position is the relative position information within the time-frequency resource range of the schedulable data channel corresponding to the control time slot in the first control channel.
45、 根据权利要求 40至 42任一所述的用户设备, 其特征在于, 所述接 收单元还用于 45. The user equipment according to any one of claims 40 to 42, characterized in that the receiving unit is also used to
在所述处理单元进行数据传输之前, 接收所述网络侧设备发送的所述第 一调度信息中所述 UI和所述 DI的配比, 和 /或, Before the processing unit performs data transmission, receive the ratio of the UI and the DI in the first scheduling information sent by the network side device, and/or,
接收所述网络侧设备发送的所述第一调度信息中所述 UI和所述 DI的区 分方法, 和 /或, Receive a method for distinguishing the UI and the DI in the first scheduling information sent by the network side device, and/or,
接收所述网络侧设备发送的所述 UI所能调度的最大上行时频资源数量, 和 /或, Receive the maximum number of uplink time-frequency resources that can be scheduled by the UI sent by the network side device, and/or,
接收所述网络侧设备发送的所述 DI所能调度的最大下行时频资源数量。 Receive the maximum number of downlink time-frequency resources that can be scheduled by the DI sent by the network side device.
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