WO2017080247A1 - Synchronization method and device - Google Patents
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- WO2017080247A1 WO2017080247A1 PCT/CN2016/090458 CN2016090458W WO2017080247A1 WO 2017080247 A1 WO2017080247 A1 WO 2017080247A1 CN 2016090458 W CN2016090458 W CN 2016090458W WO 2017080247 A1 WO2017080247 A1 WO 2017080247A1
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- 230000003993 interaction Effects 0.000 claims abstract description 19
- 230000005540 biological transmission Effects 0.000 abstract description 3
- 238000010586 diagram Methods 0.000 description 18
- 230000008569 process Effects 0.000 description 14
- 230000001360 synchronised effect Effects 0.000 description 10
- 230000000694 effects Effects 0.000 description 4
- 238000004364 calculation method Methods 0.000 description 3
- 238000012423 maintenance Methods 0.000 description 3
- 238000012986 modification Methods 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
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- 230000006870 function Effects 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W36/00—Hand-off or reselection arrangements
- H04W36/0005—Control or signalling for completing the hand-off
- H04W36/0055—Transmission or use of information for re-establishing the radio link
- H04W36/0077—Transmission or use of information for re-establishing the radio link of access information of target access point
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W36/00—Hand-off or reselection arrangements
- H04W36/16—Performing reselection for specific purposes
- H04W36/18—Performing reselection for specific purposes for allowing seamless reselection, e.g. soft reselection
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W56/00—Synchronisation arrangements
- H04W56/001—Synchronization between nodes
Definitions
- the present application relates to, but is not limited to, the field of communications, and more particularly to a synchronization method and apparatus.
- FIG. 1 is a flowchart of a terminal handover cell in a related art. After a source base station sends a handover command or simultaneously initiates a data forwarding process to a target base station, the process after the handover command is sent is as follows:
- Step S102 After receiving the handover command, the UE performs downlink synchronization with the target cell, including frequency synchronization and time synchronization.
- Step S104 The UE waits for an opportunity for available random access.
- Step S106 The UE initiates a random access request at an available random access opportunity.
- Step S108 After receiving the random access request of the UE, the target eNB sends a random access response and an uplink timing advance (Timing Advance) to the UE.
- Timing Advance an uplink timing advance
- Step S110 The UE adjusts the uplink timing to perform uplink synchronization.
- Step S112 The target cell sends data to the UE.
- FIG. 2 is a schematic diagram of signal synchronization between different cells in the related art. As can be seen from FIG. 2, signal synchronization between different cells can be classified into three levels according to strictness: subframe boundary alignment, subframe number alignment, and system frame number ( System Frame Number (SFN) is number aligned.
- SFN System Frame Number
- the SFN difference information includes the difference between the different cells: the SFN number; the difference of the subframe number; the difference of the subframe boundary.
- the UE measures the signal of the source cell and the target cell, and reads the respective SFN numbers in the system information of the source cell and the target cell, so that the difference between the SFN of the downlink signal of the source cell and the target cell can be measured.
- the UE can report the measurement result to the network side according to the network configuration.
- the SFN difference between the source cell and the target cell on the network side can be obtained by the network side, such as the operation, management, and maintenance (OAM) management.
- OAM operation, management, and maintenance
- the UE After receiving the downlink signal, the UE may determine the location of the downlink signal subframe. In order to avoid uplink interference, the network needs to ensure that the signals sent by different UEs arrive at a fixed time. Therefore, the network side needs to configure an uplink timing advance (Timing Advance, abbreviated as TA) for the uplink transmission of the UE. After receiving the TA value, if the UE wants to send an uplink signal, the UE performs the uplink signal transmission by using the subframe position of the next line as the reference and the advance TA time value.
- Timing Advance abbreviated as TA
- the UE only needs to obtain the TA value in the uplink out-of-synchronization state. Therefore, the UE may trigger the UE to initiate the random access procedure, and the network side sends the TA value to the UE in the random access response.
- the TA value Since the location of the UE is constantly changing, it is necessary to maintain the validity of the TA value. On the network side, the value of the TA is maintained. You can set a timer for the TA value of the UE. When the TA is sent to the UE, the network sends a new TA value to the UE before the timer expires. The maintenance of the TA value of the UE is started or restarted when the TA value is received according to the timer set by the network side. After the timer expires, the TA value is considered to be invalid, and the behavior of the UE is out of synchronization, and the uplink cannot be lost. The cell sends an uplink signal.
- the method of synchronizing the terminal with the target cell in the related art causes a long data interruption time and affects the normal operation of the service. Therefore, an effective solution has not been proposed for this problem.
- This document provides a synchronization method and device to solve the problem that at least the terminal and the target cell existing in the related art are synchronized, which causes a long data interruption time and affects the normal operation of the service.
- a synchronization method includes: receiving, by a source base station, first system frame number SFN difference information between a source cell and a target cell, and starting, transmitting, and receiving, by the terminal UE in the target cell.
- Sub-frame position information of the data where the first SFN difference information is determined by the source base station and the target base station by negotiation interaction, and the subframe position information is according to the Determining, by the first SFN difference information, determining, according to the first SFN difference information and the subframe position information, an actual subframe position in which data is started to be transceived in the target cell; according to the determined actual subframe The location is downlink synchronized with the target cell.
- the method further includes: determining second SFN difference information between the source cell and the target cell; Determining, by the SFN difference information, the second SFN difference information, and a predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell, determining a second uplink for uplink synchronization with the target cell a TA value; performing uplink synchronization with the target cell according to the determined second TA value.
- determining the second SFN difference information between the source cell and the target cell includes: determining a subframe boundary of the target cell; and determining, according to the subframe boundary of the target cell, the predetermined source The difference between the subframe boundaries of the cell determines the second SFN difference information.
- the second TA value TA T :TA T TA S -(D UE +D NW ); wherein, the TA S is the first TA value, and the D UE is the second SFN corresponding to the second SFN difference information
- the difference, D NW is the first SFN difference corresponding to the first SFN difference information.
- a synchronization method including: determining, by means of a negotiation interaction with a target base station, a first system frame number SFN difference information between a source cell and a target cell of a terminal UE, and the Transmitting, by the UE, the subframe position information of the data in the target cell, and sending the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the location
- the subframe position information is used to indicate that the UE determines an actual subframe position in which the data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
- a synchronization method including: with a source base station Determining the first system frame number SFN difference information between the source cell and the target cell of the terminal UE and the subframe position information of the UE starting to transmit and receive data in the target cell by using a negotiation interaction manner; and using the first SFN
- the difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines to start sending and receiving data in the target cell.
- the actual subframe position is downlink synchronized with the target cell according to the determined actual subframe position.
- a synchronization apparatus including: a receiving module, configured to: receive, by a source base station, a first system frame number SFN difference information between a source cell and a target cell, and a terminal UE And the first SFN difference information is determined by the source base station and the target base station by using a negotiation interaction, where the subframe position information is according to the first Determining, by the SFN difference information, the first determining module is configured to: determine, according to the first SFN difference information and the subframe position information, an actual subframe position that starts to send and receive data in the target cell; The module is configured to: perform downlink synchronization with the target cell according to the determined actual subframe position.
- the apparatus further includes: a second determining module, configured to: after performing downlink synchronization with the target cell according to the determined actual subframe position, determining between the source cell and the target cell
- the second SFN difference information is configured to: set, according to the first SFN difference information, the second SFN difference information, and a predetermined first uplink when performing uplink synchronization with the source cell
- the timing advance TA value determines a second TA value for performing uplink synchronization with the target cell
- the second synchronization module is configured to perform uplink synchronization with the target cell according to the determined second TA value.
- the second determining module includes: a first determining unit, configured to: determine a subframe boundary of the target cell; and a second determining unit, configured to: determine, according to a subframe boundary of the target cell, and a predetermined The difference of the subframe boundaries of the source cell determines the second SFN difference information.
- a synchronization apparatus including: a fourth determining module, configured to: determine, by means of negotiation interaction with a target base station, a first system frame between a source cell and a target cell of a terminal UE No. SFN difference information and subframe position information of the UE starting to transmit and receive data in the target cell; the first sending module is configured to: send the first SFN difference information and the subframe position information to The UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines an actual subframe position in which data is started to be transceived in the target cell and according to the determined actual sub-subject The frame position is downlink synchronized with the target cell.
- a synchronization apparatus including: a fifth determining module, configured to: determine, by means of negotiation interaction with a source base station, a first system frame between a source cell and a target cell of a terminal UE No. SFN difference information and subframe position information of the UE starting to transmit and receive data in the target cell; the second sending module is configured to: send the first SFN difference information and the subframe position information to The UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines an actual subframe position in which data is started to be transceived in the target cell and according to the determined actual sub-subject The frame position is downlink synchronized with the target cell.
- a computer readable storage medium storing computer executable instructions that are implemented by a processor to implement the above method.
- the first system frame number SFN difference information between the source cell and the target cell and the subframe position information in which the terminal UE starts to send and receive data in the target cell are used, where the The first SFN difference information is determined by the source base station and the target base station by negotiation, and the subframe position information is determined according to the first SFN difference information; according to the first SFN difference information and the Determining the subframe position information determines an actual subframe position in which the data is started to be transceived in the target cell; and performing downlink synchronization with the target cell according to the determined actual subframe position.
- the data interruption time is long, which affects the normal operation of the service, thereby reducing the data interruption time when the terminal synchronizes with the target cell, and ensuring the normal service.
- the effect of running is long, which affects the normal operation of the service, thereby reducing the data interruption time when the terminal synchronizes with the target cell, and ensuring the normal service.
- FIG. 2 is a schematic diagram of signal synchronization between different cells in the related art
- FIG. 3 is a flow chart of a first synchronization method in accordance with an embodiment of the present invention.
- FIG. 4 is a flow chart of a second synchronization method according to an embodiment of the present invention.
- FIG. 5 is a flowchart of a third synchronization method according to an embodiment of the present invention.
- FIG. 6 is a schematic diagram 1 of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention
- FIG. 7 is a flowchart of a terminal handover cell according to an embodiment of the present invention.
- FIG. 8 is a second schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
- FIG. 9 is a third schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
- Figure 10 is a block diagram showing the structure of a first synchronizing apparatus according to an embodiment of the present invention.
- FIG. 11 is a block diagram showing an optional structure of a first synchronizing apparatus according to an embodiment of the present invention.
- FIG. 12 is a structural block diagram of a second determining module 112 in a first synchronization apparatus according to an embodiment of the present invention.
- Figure 13 is a block diagram showing the structure of a second synchronizing apparatus according to an embodiment of the present invention.
- Figure 14 is a block diagram showing the structure of a third synchronizing apparatus according to an embodiment of the present invention.
- FIG. 3 is a flowchart of a first synchronization method according to an embodiment of the present invention. As shown in FIG. 3, the process includes the following steps:
- Step S302 Receive a first system frame number SFN between the source cell and the target cell sent by the source base station. And the difference information and the subframe location information that the terminal UE starts to send and receive data in the target cell, where the first SFN difference information is determined by the source base station and the target base station through negotiation, and the subframe position information is according to the first SFN. Determining the difference information;
- Step S304 determining, according to the first SFN difference information and the subframe position information, an actual subframe position in which data is started to be transmitted and received in the target cell;
- Step S306 performing downlink synchronization with the target cell according to the determined actual subframe position.
- the foregoing operation may be performed by the terminal, and determining, according to the first SFN difference information and the subframe position information, the actual subframe position of starting and receiving data in the target cell, according to the SFN number and the subframe number of the source cell. Determining at least one of the subframe boundaries, the SFN number, the subframe number, and the subframe of the target cell may be determined according to at least one of the SFN number of the source cell, the subframe number, the subframe boundary, and the first SFN difference value. At least one of the boundaries is based on subframe position information transmitted by the source base station (the subframe position information is determined by the network side, but the terminal does not know where the subframe position is, so further determining the actual subframe is needed.
- the above related information of the location and the target cell determines the actual subframe position at which the terminal starts transmitting and receiving data in the target cell.
- the foregoing related information of the source cell may be acquired when the terminal performs data interaction with the source base station, so that when the source cell needs to be handed over to the target cell, the information that has been acquired in advance may be directly used for switching.
- the first SFN difference between the source cell and the target cell on the network side and the subframe position information in which the UE starts to transmit and receive data in the target cell are determined by the source base station and the target base station, and then sent to the UE, thereby
- the terminal does not need to perform multiple data interactions with the source base station and the target base station to obtain the first SFN difference and the actual subframe position in which the data is started to be sent and received in the target cell, which saves time, shortens data interruption time, and ensures normal service. run.
- the method further includes: determining second SFN difference information between the source cell and the target cell; according to the first SFN difference The value information, the second SFN difference information, and the predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell are determined for uplink synchronization with the target cell. a second TA value; performing uplink synchronization with the target cell according to the determined second TA value.
- the foregoing uplink synchronization process and the downlink synchronization process may also be performed simultaneously, that is, the foregoing second SFN difference information may also be acquired in the process of downlink synchronization.
- the implementation of the embodiment may be a terminal.
- the terminal may determine (for example, may determine by a predetermined algorithm or determine according to other manners) a second TA value for uplink synchronization with the target cell, Therefore, there is no need to send the network side, which saves data interruption time. Shorten the time for the terminal to synchronize with the target base station for uplink synchronization.
- determining the second SFN difference information between the source cell and the target cell includes: determining a subframe boundary of the target cell; and determining, according to the subframe boundary of the target cell, a predetermined source cell The difference of the frame boundaries determines the second SFN difference information.
- the subframe boundary of the target cell may be determined when performing downlink synchronization with the target cell.
- FIG. 4 is a flowchart of a second synchronization method according to an embodiment of the present invention. As shown in FIG. 4, the process includes the following steps:
- Step S402 determining, by means of a negotiation interaction with the target base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE and the subframe position information of the UE starting to transmit and receive data in the target cell;
- Step S404 the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the actual subframe position in which the data is started to be sent and received in the target cell. Performing downlink synchronization with the target cell according to the determined actual subframe position.
- the foregoing operation may be performed by the source base station of the UE.
- the first SFN difference between the source cell and the target cell on the network side and the subframe position information in which the UE starts to transmit and receive data in the target cell are determined by the source base station and the target base station, and then sent to the UE, thereby
- the terminal does not need to perform multiple data interactions with the source base station and the target base station to obtain the first SFN difference and the actual subframe position in which the data is started to be sent and received in the target cell, which saves time, shortens data interruption time, and ensures normal service. run.
- the data interruption time is long, and the normal operation of the service is affected, thereby reducing the data interruption time when the terminal and the target cell perform downlink synchronization.
- FIG. 5 is a flowchart of a third synchronization method according to an embodiment of the present invention. As shown in FIG. 5, the process includes the following steps:
- Step S502 determining, by means of a negotiation interaction with the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position information of the UE starting to transmit and receive data in the target cell;
- Step S504 the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the actual subframe position in which the data is started to be sent and received in the target cell. Perform downlink synchronization with the target cell according to the determined actual subframe position.
- the foregoing operation may be performed by the target base station of the UE.
- the first SFN difference between the source cell and the target cell on the network side and the subframe position information in which the UE starts to transmit and receive data in the target cell are determined by the source base station and the target base station, and then sent to the UE, thereby
- the terminal does not need to perform multiple data interactions with the source base station and the target base station to obtain the first SFN difference and the actual subframe position in which the data is started to be sent and received in the target cell, which saves time, shortens data interruption time, and ensures normal service. run.
- Embodiment 1 is a diagrammatic representation of Embodiment 1:
- FIG. 6 is a schematic diagram 1 of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
- FIG. 7 is a flowchart of a terminal handover cell according to an embodiment of the present invention. As shown in FIG. 7, the process includes the following steps:
- Step S702 The source base station and the target base station negotiate a subframe position at which the UE starts transmitting and receiving data after the UE switches to the target cell.
- the source base station and the target base station need to exchange the SFN difference information of the source cell and the target cell (corresponding to the first SFN difference information), and determine, by using the difference information, that the UE starts to send and receive data after switching to the target cell. Subframe position.
- the negotiation process may adopt a handover preparation process or other inter-base station signaling procedures.
- the SFN difference information of the source cell and the target cell may be sent by the source base station to the target base station, or may be sent by the target base station to the source base station.
- Step S704 The source base station sends a handover command (RRC Connection Reconfiguraton) to the UE. If the UE is in the uplink synchronization state in the source cell, the UE sends the SFN difference information between the source cell and the target cell on the network side and the subframe position information in which the UE starts transmitting and receiving data in the target cell.
- RRC Connection Reconfiguraton a handover command
- Step S706 The UE according to the SFN number/subframe number/subframe boundary of the source cell, and the SFN difference information between the source cell and the target cell on the network side sent in step S704, and the UE configured on the network side starts in the target cell.
- the subframe position information of the data is transmitted and received, and the actual subframe position at which the data is started to be transmitted and received after the target cell handover is determined.
- the downlink SFN difference between the source cell and the target cell of the signal (corresponding to the second SFN difference information described above).
- the UE may calculate a TA value (corresponding to the second TA value described above) obtained in the target cell, and acquire uplink synchronization in the target cell.
- the calculation method is as follows:
- TA T D UE + TA S - D NW ;
- TA T TA value of the target cell (corresponding to the second TA value described above).
- TA S TA value of the source cell (corresponding to the first TA value described above).
- D NW SFN difference between the source cell and the target cell on the network side (corresponding to the first SFN difference value described above).
- D UE SFN difference between the source cell and the target cell measured by the UE (corresponding to the second SFN difference value described above).
- Step S708 According to the network configuration, the UE may send an uplink signal in the target cell.
- Step S710 The network side may send data to the UE according to the location of the UE that starts transmitting and receiving the subframe at the target cell, or may send the data to the UE after receiving the uplink signal of the UE in step S708.
- the UE may start to send and receive data according to the location of the subframe that is sent to the UE at the target cell. It is also possible to start transmitting and receiving data in the target cell after step S708.
- Step S712 The network side sends uplink grant information to the UE. This step can be performed simultaneously with step S710.
- Step S714 The UE sends an uplink data or an RRC Connection Reconfiguration Complete message to the network side according to the uplink grant information.
- Embodiment 2 is a diagrammatic representation of Embodiment 1:
- the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, and the subframe boundary of the source cell measured by the UE is before the subframe boundary of the target cell, as shown in FIG. 8.
- 8 is a second schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
- step S706 for the subframe boundary of the source cell and the target cell measured by the UE on the network side, if the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, the source cell measured by the UE The subframe boundary is before the subframe boundary of the target cell, as shown in FIG. Then, the UE can calculate the TA value obtained in the target cell, and acquire the uplink synchronization in the target cell.
- the calculation method is as follows:
- TA T D UE + TA S - D NW ;
- TA T TA value of the target cell.
- TA S TA value of the source cell.
- D NW SFN difference between the source cell and the target cell on the network side.
- D UE The SFN difference between the source cell and the target cell measured by the UE.
- Embodiment 3 is a diagrammatic representation of Embodiment 3
- FIG. 9 is a third schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
- step S706 for the subframe boundary of the source cell and the target cell measured by the UE on the network side, if the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, the source cell measured by the UE The subframe boundary is after the subframe boundary of the target cell, as shown in FIG. Then, the UE can calculate the TA value obtained in the target cell, and acquire the uplink synchronization in the target cell.
- the calculation method is as follows:
- TA T TA S -(D NW +D UE );
- TA T TA value of the target cell.
- TA S TA value of the source cell.
- D NW SFN difference between the source cell and the target cell on the network side.
- D UE The SFN difference between the source cell and the target cell measured by the UE.
- the method according to the above embodiment can be implemented by means of software plus a necessary general hardware platform, and of course, by hardware, but in many cases, the former is A better implementation.
- the technical solution of the embodiment of the present invention may be embodied in the form of a software product stored in a storage medium (such as a ROM/RAM, a magnetic disk, an optical disk), and includes a plurality of instructions for making A terminal device (which may be a mobile phone, a computer, a server, or a network device, etc.) performs the method described in the embodiments of the present invention.
- a synchronization device is also provided, which is used to implement the foregoing embodiments and optional implementations, and details are not described herein.
- the term "module” may implement a combination of software and/or hardware of a predetermined function.
- the apparatus described in the following embodiments can be implemented in software, hardware, or a combination of software and hardware, is also possible and conceived. of.
- FIG. 10 is a structural block diagram of a first synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 10, the apparatus includes a receiving module 102, a first determining module 104, and a first synchronization module 106. .
- the receiving module 102 is configured to: receive, by the source base station, the first system frame number SFN difference information between the source cell and the target cell, and the subframe location information that the terminal UE starts to send and receive data in the target cell, where the first SFN The difference information is determined by the source base station and the target base station through negotiation, and the subframe position information is determined according to the first SFN difference information.
- the first determining module 104 is connected to the receiving module 102, and is configured to: according to the first The SFN difference information and the subframe position information determine an actual subframe position at which the data is started to be transmitted and received in the target cell.
- the first synchronization module 106 is connected to the first determining module 104, and is configured to: according to the determined actual subframe position and the target cell. Perform downlink synchronization.
- FIG. 11 is a block diagram showing an optional structure of a first synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 11, the apparatus includes a second determination module 112 and a third determination in addition to all the modules shown in FIG. The module 114 and the second synchronization module 116 are described below.
- the second determining module 112 is connected to the first synchronization module 106, and configured to: after performing downlink synchronization with the target cell according to the determined actual subframe position, determining second SFN difference information between the source cell and the target cell;
- the third determining module 114 is connected to the second determining module 112, and is configured to: according to the first SFN difference information, the second SFN difference information, and the predetermined first uplink timing advance when performing uplink synchronization with the source cell.
- the TA value determines a second TA value for uplink synchronization with the target cell.
- the second synchronization module 116 is connected to the third determining module 114, and is configured to perform uplink synchronization with the target cell according to the determined second TA value.
- FIG. 12 is a structural block diagram of a second determining module 112 in a first synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 12, the second determining module 112 includes a first determining unit 122 and a second determining unit 124. The second determination module 112 is described.
- the first determining unit 122 is configured to: determine a subframe boundary of the target cell; the second determining unit 124 is connected to the first determining unit 122, and is configured to: according to the subframe boundary of the target cell and the predetermined source cell The difference of the subframe boundaries determines the second SFN difference information.
- FIG. 13 is a structural block diagram of a second synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 13, the apparatus includes a fourth determination module 132 and a first transmission module 134, which will be described below.
- the fourth determining module 132 is configured to: determine, by means of negotiation and interaction with the target base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position where the UE starts to send and receive data in the target cell.
- the first sending module 134 is connected to the fourth determining module 132, and configured to: send the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used.
- the UE is instructed to determine an actual subframe position in which data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
- FIG. 14 is a block diagram showing the structure of a third synchronizing apparatus according to an embodiment of the present invention. As shown in FIG. 14, the apparatus includes a fifth determining module 142 and a second transmitting module 144, which will be described below.
- the fifth determining module 142 is configured to: determine, by means of negotiation and interaction with the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position where the UE starts to send and receive data in the target cell.
- the second sending module 144 is connected to the fifth determining module 142, and configured to: send the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used.
- the UE is instructed to determine an actual subframe position in which data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
- modules may be implemented by software or hardware.
- the foregoing may be implemented by, but not limited to, the foregoing modules are all located in the same processor; or, the modules are respectively located in multiple processes. In the device.
- Embodiments of the present invention also provide a storage medium.
- the above The storage medium can be configured to store program code for performing the following steps:
- the storage medium is further arranged to store program code for performing the following steps:
- S21 Determine a first system frame number SFN difference information between a source cell and a target cell of the terminal UE, and a subframe position information that the UE starts to send and receive data in the target cell, by performing a negotiation interaction with the target base station;
- the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the actual subframe position in which the data is started to be sent and received in the target cell, and according to The determined actual subframe position is downlink synchronized with the target cell.
- the storage medium is further arranged to store program code for performing the following steps:
- S31 Determine, by means of a negotiation, the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position information that the UE starts to send and receive data in the target cell.
- the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines an actual subframe position that starts to send and receive data in the target cell, and according to The determined actual subframe position is downlink synchronized with the target cell.
- the foregoing storage medium may include, but is not limited to, a USB flash drive, a Read-Only Memory (ROM), and a Random Access Memory (RAM).
- ROM Read-Only Memory
- RAM Random Access Memory
- the processor executes according to the stored program code in the storage medium. The above steps.
- the method described in the embodiment of the present invention can assist the UE to acquire the downlink and uplink synchronization of the target cell more quickly during the handover process, thereby reducing the data interruption time of the handover process.
- modules or steps of the embodiments of the present invention can be implemented by a general-purpose computing device, which can be centralized on a single computing device or distributed over a network of multiple computing devices. Alternatively, they may be implemented by program code executable by the computing device such that they may be stored in the storage device by the computing device and, in some cases, may be different from the order herein.
- the steps shown or described are performed either separately as an integrated circuit module, or a plurality of modules or steps thereof are fabricated as a single integrated circuit module.
- embodiments of the invention are not limited to any specific combination of hardware and software.
- the embodiment of the present invention solves the problem that when the terminal and the target cell are synchronized in the related art, the data interruption time is long, and the normal operation of the service is affected, thereby reducing the data interruption when the terminal synchronizes with the target cell. Time to ensure the normal operation of the business.
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Abstract
Disclosed are a synchronization method and device. The method comprises: receiving first system frame number (SFN) difference information between a source cell and a target cell and information of a subframe position where a terminal (UE) starts transmitting and receiving data in the target cell sent by a source base station, wherein the first SFN difference information is determined by negotiation and interaction between the source base station and a target base station, and the information of subframe position is determined according to the first SFN difference information; determining an actual subframe position where the transmission and reception of data starts in the target cell according to the first SFN difference information and the information of subframe position; and performing downlink synchronization with the target cell according to the determined actual subframe position.
Description
本申请涉及但不限于通信领域,尤指一种同步方法及装置。The present application relates to, but is not limited to, the field of communications, and more particularly to a synchronization method and apparatus.
图1是相关技术中的终端切换小区的流程图,源基站在发送切换命令后或同时可以向目标基站发起数据前转过程,在发送切换命令后的流程如下:1 is a flowchart of a terminal handover cell in a related art. After a source base station sends a handover command or simultaneously initiates a data forwarding process to a target base station, the process after the handover command is sent is as follows:
步骤S102:UE在接收到切换命令后和目标小区进行无线信号的下行同步,包括频率同步和时间同步。Step S102: After receiving the handover command, the UE performs downlink synchronization with the target cell, including frequency synchronization and time synchronization.
步骤S104:UE等待可用的随机接入的机会。Step S104: The UE waits for an opportunity for available random access.
步骤S106:UE在可用的随机接入机会发起随机接入请求。Step S106: The UE initiates a random access request at an available random access opportunity.
步骤S108:目标eNB接收到UE的随机接入请求后,发送随机接入响应和上行定时提前量(Timing Advance)给UE。Step S108: After receiving the random access request of the UE, the target eNB sends a random access response and an uplink timing advance (Timing Advance) to the UE.
步骤S110:UE调整上行定时进行上行同步。Step S110: The UE adjusts the uplink timing to perform uplink synchronization.
步骤S112:目标小区发送数据给UE。Step S112: The target cell sends data to the UE.
图2是相关技术中的不同小区间的信号同步示意图,由图2可知,不同小区间的信号同步按照严格程度可以分为三个级别:子帧边界对齐、子帧编号对齐、系统帧号(System Frame Number,简称为SFN)编号对齐。2 is a schematic diagram of signal synchronization between different cells in the related art. As can be seen from FIG. 2, signal synchronization between different cells can be classified into three levels according to strictness: subframe boundary alignment, subframe number alignment, and system frame number ( System Frame Number (SFN) is number aligned.
SFN差值信息包括不同小区间的:SFN编号的差值;子帧编号的差值;子帧边界的差值。The SFN difference information includes the difference between the different cells: the SFN number; the difference of the subframe number; the difference of the subframe boundary.
UE通过测量源小区和目标小区的信号,并读取源小区和目标小区的系统信息中各自的SFN号,从而可以测量得到源小区和目标小区的下行信号的SFN的差值。UE可以根据网络配置,将测量结果上报网络侧。The UE measures the signal of the source cell and the target cell, and reads the respective SFN numbers in the system information of the source cell and the target cell, so that the difference between the SFN of the downlink signal of the source cell and the target cell can be measured. The UE can report the measurement result to the network side according to the network configuration.
网络侧通过实现,如运行、管理和维护(Operation Administration and Maintenance,简称为OAM)管理,可以获得网络侧的源小区和目标小区的SFN差值。
The SFN difference between the source cell and the target cell on the network side can be obtained by the network side, such as the operation, management, and maintenance (OAM) management.
UE在接收到下行信号后,可以确定下行信号子帧的位置。为了避免上行干扰,网络要保证不同UE发送的信号在固定的时刻到达,因此网络侧需要给UE的上行发送配置一个上行定时提前量(Timing Advance,简称为TA)。UE在收到该TA值后,如果UE要发送上行信号,则UE以下行子帧位置为参考再提前TA时间值进行上行信号的发送。After receiving the downlink signal, the UE may determine the location of the downlink signal subframe. In order to avoid uplink interference, the network needs to ensure that the signals sent by different UEs arrive at a fixed time. Therefore, the network side needs to configure an uplink timing advance (Timing Advance, abbreviated as TA) for the uplink transmission of the UE. After receiving the TA value, if the UE wants to send an uplink signal, the UE performs the uplink signal transmission by using the subframe position of the next line as the reference and the advance TA time value.
关于TA值的获取。UE只有在上行失步状态才需要获取TA值,因此可以UE自己触发或网络侧触发UE发起随机接入过程,网路侧在随机接入响应中给UE下发TA值。About the acquisition of the TA value. The UE only needs to obtain the TA value in the uplink out-of-synchronization state. Therefore, the UE may trigger the UE to initiate the random access procedure, and the network side sends the TA value to the UE in the random access response.
关于TA值的维护。由于UE的位置在不停的变化,因此需要对于TA值的有效性进行维护。网络侧的TA值维护,可以对UE的TA值设置一个定时器,在下发TA给UE的时候启动,在定时器超时前网络侧下发新的TA值给UE。UE的TA值维护,根据网络侧设置的定时器,在收到TA值的时候启动或重启,在定时器超后认为该TA值失效,UE上行为失步状态,不能再在上行失步的小区发送上行信号。About the maintenance of the TA value. Since the location of the UE is constantly changing, it is necessary to maintain the validity of the TA value. On the network side, the value of the TA is maintained. You can set a timer for the TA value of the UE. When the TA is sent to the UE, the network sends a new TA value to the UE before the timer expires. The maintenance of the TA value of the UE is started or restarted when the TA value is received according to the timer set by the network side. After the timer expires, the TA value is considered to be invalid, and the behavior of the UE is out of synchronization, and the uplink cannot be lost. The cell sends an uplink signal.
采用相关技术中的终端与目标小区进行同步的方式,会造成数据中断时间长,影响业务的正常运行的问题,针对该问题,目前并未提出有效的解决方案。The method of synchronizing the terminal with the target cell in the related art causes a long data interruption time and affects the normal operation of the service. Therefore, an effective solution has not been proposed for this problem.
发明内容Summary of the invention
以下是对本文详细描述的主题的概述。本概述并非是为了限制权利要求的保护范围。The following is an overview of the topics detailed in this document. This Summary is not intended to limit the scope of the claims.
本文提供了一种同步方法及装置,以至少解决相关技术中存在的终端与目标小区进行同步时,会造成数据中断时间长,影响业务的正常运行的问题。This document provides a synchronization method and device to solve the problem that at least the terminal and the target cell existing in the related art are synchronized, which causes a long data interruption time and affects the normal operation of the service.
根据本发明实施例的一个方面,提供了一种同步方法,包括:接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在所述目标小区中开始收发数据的子帧位置信息,其中,所述第一SFN差值信息为所述源基站与目标基站通过协商交互确定的,所述子帧位置信息是根据所
述第一SFN差值信息确定的;根据所述第一SFN差值信息和所述子帧位置信息确定在所述目标小区中开始收发数据的实际子帧位置;根据确定的所述实际子帧位置与所述目标小区进行下行同步。According to an aspect of the embodiments of the present invention, a synchronization method includes: receiving, by a source base station, first system frame number SFN difference information between a source cell and a target cell, and starting, transmitting, and receiving, by the terminal UE in the target cell. Sub-frame position information of the data, where the first SFN difference information is determined by the source base station and the target base station by negotiation interaction, and the subframe position information is according to the
Determining, by the first SFN difference information, determining, according to the first SFN difference information and the subframe position information, an actual subframe position in which data is started to be transceived in the target cell; according to the determined actual subframe The location is downlink synchronized with the target cell.
可选地,在根据确定的所述实际子帧位置与所述目标小区进行下行同步之后,还包括:确定所述源小区和所述目标小区间的第二SFN差值信息;根据所述第一SFN差值信息、所述第二SFN差值信息和预先确定的与所述源小区进行上行同步时的第一上行定时提前量TA值确定用于与所述目标小区进行上行同步的第二TA值;根据确定的所述第二TA值与所述目标小区进行上行同步。Optionally, after performing downlink synchronization with the target cell according to the determined actual subframe position, the method further includes: determining second SFN difference information between the source cell and the target cell; Determining, by the SFN difference information, the second SFN difference information, and a predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell, determining a second uplink for uplink synchronization with the target cell a TA value; performing uplink synchronization with the target cell according to the determined second TA value.
可选地,确定所述源小区和所述目标小区间的第二SFN差值信息包括:确定所述目标小区的子帧边界;根据所述目标小区的子帧边界和预先确定的所述源小区的子帧边界的差值,确定所述第二SFN差值信息。Optionally, determining the second SFN difference information between the source cell and the target cell includes: determining a subframe boundary of the target cell; and determining, according to the subframe boundary of the target cell, the predetermined source The difference between the subframe boundaries of the cell determines the second SFN difference information.
可选地,根据所述第一SFN差值信息、所述第二SFN差值信息和预先确定的与所述源小区进行上行同步时的第一上行定时提前量TA值确定用于与所述目标小区进行上行同步时的第二TA值包括以下之一:当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之前时,通过如下公式确定所述第二TA值TAT:TAT=DUE+TAS-DNW;当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之后时,通过如下公式确定所述第二TA值TAT:TAT=TAS-(DUE+DNW);其中,TAS为所述第一TA值,DUE为所述第二SFN差值信息对应的第二SFN差值,DNW为所述第一SFN差值信息对应的第一SFN差值。Optionally, determining, according to the first SFN difference information, the second SFN difference information, and a predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell, The second TA value when the target cell performs uplink synchronization includes one of the following: when the predetermined subframe boundary of the source cell is before the determined subframe boundary of the target cell, the foregoing formula is determined by the following formula a second TA value TA T :TA T =D UE +TA S -D NW ; when the predetermined subframe boundary of the source cell is after the determined subframe boundary of the target cell, the method is determined by the following formula The second TA value TA T :TA T =TA S -(D UE +D NW ); wherein, the TA S is the first TA value, and the D UE is the second SFN corresponding to the second SFN difference information The difference, D NW is the first SFN difference corresponding to the first SFN difference information.
根据本发明实施例的另一方面,提供了一种同步方法,包括:与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。According to another aspect of the present invention, a synchronization method is provided, including: determining, by means of a negotiation interaction with a target base station, a first system frame number SFN difference information between a source cell and a target cell of a terminal UE, and the Transmitting, by the UE, the subframe position information of the data in the target cell, and sending the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the location The subframe position information is used to indicate that the UE determines an actual subframe position in which the data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
根据本发明实施例的另一方面,提供了一种同步方法,包括:与源基站
通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。According to another aspect of an embodiment of the present invention, a synchronization method is provided, including: with a source base station
Determining the first system frame number SFN difference information between the source cell and the target cell of the terminal UE and the subframe position information of the UE starting to transmit and receive data in the target cell by using a negotiation interaction manner; and using the first SFN The difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines to start sending and receiving data in the target cell. The actual subframe position is downlink synchronized with the target cell according to the determined actual subframe position.
根据本发明实施例的另一方面,提供了一种同步装置,包括:接收模块,设置为:接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在所述目标小区中开始收发数据的子帧位置信息,其中,所述第一SFN差值信息为所述源基站与目标基站通过协商交互确定的,所述子帧位置信息是根据所述第一SFN差值信息确定的;第一确定模块,设置为:根据所述第一SFN差值信息和所述子帧位置信息确定在所述目标小区中开始收发数据的实际子帧位置;第一同步模块,设置为:根据确定的所述实际子帧位置与所述目标小区进行下行同步。According to another aspect of the present invention, a synchronization apparatus is provided, including: a receiving module, configured to: receive, by a source base station, a first system frame number SFN difference information between a source cell and a target cell, and a terminal UE And the first SFN difference information is determined by the source base station and the target base station by using a negotiation interaction, where the subframe position information is according to the first Determining, by the SFN difference information, the first determining module is configured to: determine, according to the first SFN difference information and the subframe position information, an actual subframe position that starts to send and receive data in the target cell; The module is configured to: perform downlink synchronization with the target cell according to the determined actual subframe position.
可选地,所述装置还包括:第二确定模块,设置为:在根据确定的所述实际子帧位置与所述目标小区进行下行同步之后,确定所述源小区和所述目标小区间的第二SFN差值信息;第三确定模块,设置为:根据所述第一SFN差值信息、所述第二SFN差值信息和预先确定的与所述源小区进行上行同步时的第一上行定时提前量TA值确定用于与所述目标小区进行上行同步的第二TA值;第二同步模块,设置为:根据确定的所述第二TA值与所述目标小区进行上行同步。Optionally, the apparatus further includes: a second determining module, configured to: after performing downlink synchronization with the target cell according to the determined actual subframe position, determining between the source cell and the target cell The second SFN difference information is configured to: set, according to the first SFN difference information, the second SFN difference information, and a predetermined first uplink when performing uplink synchronization with the source cell The timing advance TA value determines a second TA value for performing uplink synchronization with the target cell; and the second synchronization module is configured to perform uplink synchronization with the target cell according to the determined second TA value.
可选地,所述第二确定模块包括:第一确定单元,设置为:确定所述目标小区的子帧边界;第二确定单元,设置为:根据所述目标小区的子帧边界和预先确定的所述源小区的子帧边界的差值,确定所述第二SFN差值信息。Optionally, the second determining module includes: a first determining unit, configured to: determine a subframe boundary of the target cell; and a second determining unit, configured to: determine, according to a subframe boundary of the target cell, and a predetermined The difference of the subframe boundaries of the source cell determines the second SFN difference information.
可选地,所述第三确定模块通过以下方式之一确定所述第二SFN差值信息:当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之前时,通过如下公式确定所述第二TA值TAT:TAT=DUE+TAS-DNW;当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之后时,通过如下公式确定所述第二TA值TAT:TAT=TAS-(DUE+DNW);其中,
TAS为所述第一TA值,DUE为所述第二SFN差值信息对应的第二SFN差值,DNW为所述第一SFN差值信息对应的第一SFN差值。Optionally, the third determining module determines the second SFN difference information by using one of the following manners: when a predetermined subframe boundary of the source cell is before determining the subframe boundary of the target cell when determining the second TA TA value T by the following formula: TA T = D UE + TA S -D NW; when the target sub-sub-cell of predetermined frame boundary of the source cell is determined frame when the boundary after determining the second TA TA value T by the following formula: TA T = TA S - ( D UE + D NW); wherein, said first S TA TA value, D UE to the second The second SFN difference value corresponding to the SFN difference information, and D NW is the first SFN difference value corresponding to the first SFN difference information.
根据本发明实施例的另一方面,提供了一种同步装置,包括:第四确定模块,设置为:与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;第一发送模块,设置为:将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。According to another aspect of the present invention, a synchronization apparatus is provided, including: a fourth determining module, configured to: determine, by means of negotiation interaction with a target base station, a first system frame between a source cell and a target cell of a terminal UE No. SFN difference information and subframe position information of the UE starting to transmit and receive data in the target cell; the first sending module is configured to: send the first SFN difference information and the subframe position information to The UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines an actual subframe position in which data is started to be transceived in the target cell and according to the determined actual sub-subject The frame position is downlink synchronized with the target cell.
根据本发明实施例的另一方面,提供了一种同步装置,包括:第五确定模块,设置为:与源基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;第二发送模块,设置为:将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。According to another aspect of the present invention, a synchronization apparatus is provided, including: a fifth determining module, configured to: determine, by means of negotiation interaction with a source base station, a first system frame between a source cell and a target cell of a terminal UE No. SFN difference information and subframe position information of the UE starting to transmit and receive data in the target cell; the second sending module is configured to: send the first SFN difference information and the subframe position information to The UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines an actual subframe position in which data is started to be transceived in the target cell and according to the determined actual sub-subject The frame position is downlink synchronized with the target cell.
根据本发明实施例的另一方面,提供了一种计算机可读存储介质,存储有计算机可执行指令,所述计算机可执行指令被处理器执行时实现上述方法。According to another aspect of an embodiment of the present invention, there is provided a computer readable storage medium storing computer executable instructions that are implemented by a processor to implement the above method.
通过本发明实施例,采用接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在所述目标小区中开始收发数据的子帧位置信息,其中,所述第一SFN差值信息为所述源基站与目标基站通过协商交互确定的,所述子帧位置信息是根据所述第一SFN差值信息确定的;根据所述第一SFN差值信息和所述子帧位置信息确定在所述目标小区中开始收发数据的实际子帧位置;根据确定的所述实际子帧位置与所述目标小区进行下行同步。解决了相关技术中存在的终端与目标小区进行同步时,会造成数据中断时间长,影响业务的正常运行的问题,进而达到了减少终端与目标小区进行同步时的数据中断时间,保证业务的正常运行的效果。According to the embodiment of the present invention, the first system frame number SFN difference information between the source cell and the target cell and the subframe position information in which the terminal UE starts to send and receive data in the target cell are used, where the The first SFN difference information is determined by the source base station and the target base station by negotiation, and the subframe position information is determined according to the first SFN difference information; according to the first SFN difference information and the Determining the subframe position information determines an actual subframe position in which the data is started to be transceived in the target cell; and performing downlink synchronization with the target cell according to the determined actual subframe position. When the synchronization between the terminal and the target cell in the related art is solved, the data interruption time is long, which affects the normal operation of the service, thereby reducing the data interruption time when the terminal synchronizes with the target cell, and ensuring the normal service. The effect of running.
在阅读并理解了附图和详细描述后,可以明白其他方面。
Other aspects will be apparent upon reading and understanding the drawings and detailed description.
附图概述BRIEF abstract
图1是相关技术中的终端切换小区的流程图;1 is a flowchart of a terminal handover cell in the related art;
图2是相关技术中的不同小区间的信号同步示意图;2 is a schematic diagram of signal synchronization between different cells in the related art;
图3是根据本发明实施例的第一种同步方法的流程图;3 is a flow chart of a first synchronization method in accordance with an embodiment of the present invention;
图4是根据本发明实施例的第二种同步方法的流程图;4 is a flow chart of a second synchronization method according to an embodiment of the present invention;
图5是根据本发明实施例的第三种同步方法的流程图;FIG. 5 is a flowchart of a third synchronization method according to an embodiment of the present invention; FIG.
图6是根据本发明实施例的源小区和目标小区的子帧边界示意图一;6 is a schematic diagram 1 of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention;
图7是根据本发明实施例的终端切换小区的流程图;7 is a flowchart of a terminal handover cell according to an embodiment of the present invention;
图8是根据本发明实施例的源小区和目标小区的子帧边界示意图二;8 is a second schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention;
图9是根据本发明实施例的源小区和目标小区的子帧边界示意图三;9 is a third schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention;
图10是根据本发明实施例的第一种同步装置的结构框图;Figure 10 is a block diagram showing the structure of a first synchronizing apparatus according to an embodiment of the present invention;
图11是根据本发明实施例的第一种同步装置的可选结构框图;11 is a block diagram showing an optional structure of a first synchronizing apparatus according to an embodiment of the present invention;
图12是根据本发明实施例的第一种同步装置中第二确定模块112的结构框图;FIG. 12 is a structural block diagram of a second determining module 112 in a first synchronization apparatus according to an embodiment of the present invention;
图13是根据本发明实施例的第二种同步装置的结构框图;Figure 13 is a block diagram showing the structure of a second synchronizing apparatus according to an embodiment of the present invention;
图14是根据本发明实施例的第三种同步装置的结构框图。Figure 14 is a block diagram showing the structure of a third synchronizing apparatus according to an embodiment of the present invention.
下文中将参考附图并结合实施例来详细说明本发明的实施方式。需要说明的是,在不冲突的情况下,本申请中的实施例及实施例中的特征可以相互组合。Embodiments of the present invention will be described in detail below with reference to the drawings in conjunction with the embodiments. It should be noted that the embodiments in the present application and the features in the embodiments may be combined with each other without conflict.
需要说明的是,本文的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别类似的对象,而不必用于描述特定的顺序或先后次序。It should be noted that the terms "first", "second" and the like in the specification and claims of the present specification and the above drawings are used to distinguish similar objects, and are not necessarily used to describe a specific order or order.
在本实施例中提供了一种同步方法,图3是根据本发明实施例的第一种同步方法的流程图,如图3所示,该流程包括如下步骤:A synchronization method is provided in this embodiment. FIG. 3 is a flowchart of a first synchronization method according to an embodiment of the present invention. As shown in FIG. 3, the process includes the following steps:
步骤S302,接收源基站发送的源小区和目标小区间的第一系统帧号SFN
差值信息和终端UE在目标小区中开始收发数据的子帧位置信息,其中,该第一SFN差值信息为源基站与目标基站通过协商交互确定的,该子帧位置信息是根据第一SFN差值信息确定的;Step S302: Receive a first system frame number SFN between the source cell and the target cell sent by the source base station.
And the difference information and the subframe location information that the terminal UE starts to send and receive data in the target cell, where the first SFN difference information is determined by the source base station and the target base station through negotiation, and the subframe position information is according to the first SFN. Determining the difference information;
步骤S304,根据上述第一SFN差值信息和子帧位置信息确定在目标小区中开始收发数据的实际子帧位置;Step S304, determining, according to the first SFN difference information and the subframe position information, an actual subframe position in which data is started to be transmitted and received in the target cell;
步骤S306,根据确定的上述实际子帧位置与目标小区进行下行同步。Step S306, performing downlink synchronization with the target cell according to the determined actual subframe position.
其中,执行上述操作的可以是终端,在根据第一SFN差值信息和子帧位置信息确定在目标小区中开始收发数据的实际子帧位置时,还需要依据源小区的SFN编号、子帧编号、子帧边界中的至少之一进行确定,根据源小区的SFN编号、子帧编号、子帧边界中的至少之一和第一SFN差值可以确定目标小区的SFN编号、子帧编号、子帧边界中的至少之一,在根据源基站发送的子帧位置信息(该子帧位置信息是网络侧确定的,但是终端并不知道该子帧位置在哪儿,所以需要进一步进行确定实际的子帧位置)和目标小区的上述相关信息确定终端在目标小区中开始收发数据的实际子帧位置。源小区的上述相关信息可以是终端与源基站进行数据交互时便获取的,从而在需要由源小区切换至目标小区时,就可以直接利用上述预先已经获取的信息进行切换了。The foregoing operation may be performed by the terminal, and determining, according to the first SFN difference information and the subframe position information, the actual subframe position of starting and receiving data in the target cell, according to the SFN number and the subframe number of the source cell. Determining at least one of the subframe boundaries, the SFN number, the subframe number, and the subframe of the target cell may be determined according to at least one of the SFN number of the source cell, the subframe number, the subframe boundary, and the first SFN difference value. At least one of the boundaries is based on subframe position information transmitted by the source base station (the subframe position information is determined by the network side, but the terminal does not know where the subframe position is, so further determining the actual subframe is needed. The above related information of the location and the target cell determines the actual subframe position at which the terminal starts transmitting and receiving data in the target cell. The foregoing related information of the source cell may be acquired when the terminal performs data interaction with the source base station, so that when the source cell needs to be handed over to the target cell, the information that has been acquired in advance may be directly used for switching.
通过上述步骤,网络侧的源小区和目标小区间的第一SFN差值和UE在目标小区中开始收发数据的子帧位置信息都是由源基站和目标基站协商确定后发送给UE的,从而无需终端与源基站和目标基站进行多次数据交互以获取上述第一SFN差值和在目标小区中开始收发数据的实际子帧位置,节省了时间,缩短了数据中断时间,保证了业务的正常运行。从而,解决了相关技术中存在的终端与目标小区进行同步时,会造成数据中断时间长,影响业务的正常运行的问题,进而达到了减少终端与目标小区进行同步时的数据中断时间,保证业务的正常运行的效果。Through the above steps, the first SFN difference between the source cell and the target cell on the network side and the subframe position information in which the UE starts to transmit and receive data in the target cell are determined by the source base station and the target base station, and then sent to the UE, thereby The terminal does not need to perform multiple data interactions with the source base station and the target base station to obtain the first SFN difference and the actual subframe position in which the data is started to be sent and received in the target cell, which saves time, shortens data interruption time, and ensures normal service. run. Therefore, when the terminal and the target cell existing in the related art are synchronized, the data interruption time is long, and the normal operation of the service is affected, thereby reducing the data interruption time when the terminal synchronizes with the target cell, and ensuring the service. The effect of normal operation.
在一个可选的实施例中,在根据确定的实际子帧位置与目标小区进行下行同步之后,还包括:确定上述源小区和目标小区间的第二SFN差值信息;根据上述第一SFN差值信息、第二SFN差值信息和预先确定的与源小区进行上行同步时的第一上行定时提前量TA值确定用于与目标小区进行上行同步
的第二TA值;根据确定的上述第二TA值与目标小区进行上行同步。其中,上述的上行同步过程和下行同步过程也可以是同时进行的,即,也可以在下行同步的过程中获取上述的第二SFN差值信息。执行该实施例的可以是终端,因此,通过该实施例,终端可以自己确定(例如,可以通过预定的算法进行确定,或者根据其他的方式确定)与目标小区进行上行同步的第二TA值,从而无需网络侧下发,节省数据中断时间。缩短终端与目标基站进行上行同步的时间。In an optional embodiment, after performing downlink synchronization with the target cell according to the determined actual subframe position, the method further includes: determining second SFN difference information between the source cell and the target cell; according to the first SFN difference The value information, the second SFN difference information, and the predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell are determined for uplink synchronization with the target cell.
a second TA value; performing uplink synchronization with the target cell according to the determined second TA value. The foregoing uplink synchronization process and the downlink synchronization process may also be performed simultaneously, that is, the foregoing second SFN difference information may also be acquired in the process of downlink synchronization. The implementation of the embodiment may be a terminal. Therefore, by using the embodiment, the terminal may determine (for example, may determine by a predetermined algorithm or determine according to other manners) a second TA value for uplink synchronization with the target cell, Therefore, there is no need to send the network side, which saves data interruption time. Shorten the time for the terminal to synchronize with the target base station for uplink synchronization.
在一个可选的实施例中,确定上述源小区和目标小区间的第二SFN差值信息包括:确定目标小区的子帧边界;根据该目标小区的子帧边界和预先确定的源小区的子帧边界的差值,确定第二SFN差值信息。其中,上述的目标小区的子帧边界可以是在与目标小区进行下行同步的时候确定的。In an optional embodiment, determining the second SFN difference information between the source cell and the target cell includes: determining a subframe boundary of the target cell; and determining, according to the subframe boundary of the target cell, a predetermined source cell The difference of the frame boundaries determines the second SFN difference information. The subframe boundary of the target cell may be determined when performing downlink synchronization with the target cell.
在一个可选的实施例中,根据上述第一SFN差值信息、第二SFN差值信息和预先确定的与源小区进行上行同步时的第一上行定时提前量TA值确定用于与目标小区进行上行同步时的第二TA值包括以下之一:当预先确定的上述源小区的子帧边界是在确定的目标小区的子帧边界之前时,可以通过如下公式确定第二TA值TAT:TAT=DUE+TAS-DNW;当预先确定的源小区的子帧边界是在确定的目标小区的子帧边界之后时,可以通过如下公式确定第二TA值TAT:TAT=TAS-(DUE+DNW);其中,TAS为第一TA值,DUE为第二SFN差值信息对应的第二SFN差值,DNW为第一SFN差值信息对应的第一SFN差值。In an optional embodiment, determining, according to the first SFN difference information, the second SFN difference information, and a predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell, a second value TA is one of uplink synchronization comprising: said source cell when the sub-frame boundary is a predetermined time before the determination of the target cell sub-frame boundaries may be determined second TA TA value T by the following formula: TA T = D UE + TA S - D NW ; When the predetermined subframe boundary of the source cell is after the subframe boundary of the determined target cell, the second TA value TA T can be determined by the following formula: TA T = TA S - (D UE + D NW ); wherein, TA S is a first TA value, D UE is a second SFN difference corresponding to the second SFN difference information, and D NW is a first corresponding to the first SFN difference information. A SFN difference.
图4是根据本发明实施例的第二种同步方法的流程图,如图4所示,该流程包括如下步骤:FIG. 4 is a flowchart of a second synchronization method according to an embodiment of the present invention. As shown in FIG. 4, the process includes the following steps:
步骤S402,与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和UE在目标小区中开始收发数据的子帧位置信息;Step S402, determining, by means of a negotiation interaction with the target base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE and the subframe position information of the UE starting to transmit and receive data in the target cell;
步骤S404,将上述第一SFN差值信息和子帧位置信息发送给UE,其中,该第一SFN差值信息和子帧位置信息用于指示UE确定在目标小区中开始收发数据的实际子帧位置并根据确定的上述实际子帧位置与目标小区进行下行同步。
Step S404, the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the actual subframe position in which the data is started to be sent and received in the target cell. Performing downlink synchronization with the target cell according to the determined actual subframe position.
其中,执行上述操作的可以是UE的源基站。通过上述步骤,网络侧的源小区和目标小区间的第一SFN差值和UE在目标小区中开始收发数据的子帧位置信息都是由源基站和目标基站协商确定后发送给UE的,从而无需终端与源基站和目标基站进行多次数据交互以获取上述第一SFN差值和在目标小区中开始收发数据的实际子帧位置,节省了时间,缩短了数据中断时间,保证了业务的正常运行。从而,解决了相关技术中存在的终端与目标小区进行下行同步时,会造成数据中断时间长,影响业务的正常运行的问题,进而达到了减少终端与目标小区进行下行同步时的数据中断时间,保证业务的正常运行的效果。The foregoing operation may be performed by the source base station of the UE. Through the above steps, the first SFN difference between the source cell and the target cell on the network side and the subframe position information in which the UE starts to transmit and receive data in the target cell are determined by the source base station and the target base station, and then sent to the UE, thereby The terminal does not need to perform multiple data interactions with the source base station and the target base station to obtain the first SFN difference and the actual subframe position in which the data is started to be sent and received in the target cell, which saves time, shortens data interruption time, and ensures normal service. run. Therefore, when the downlink synchronization between the terminal and the target cell in the related art is solved, the data interruption time is long, and the normal operation of the service is affected, thereby reducing the data interruption time when the terminal and the target cell perform downlink synchronization. The effect of ensuring the normal operation of the business.
图5是根据本发明实施例的第三种同步方法的流程图,如图5所示,该流程包括如下步骤:FIG. 5 is a flowchart of a third synchronization method according to an embodiment of the present invention. As shown in FIG. 5, the process includes the following steps:
步骤S502,与源基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和UE在目标小区中开始收发数据的子帧位置信息;Step S502, determining, by means of a negotiation interaction with the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position information of the UE starting to transmit and receive data in the target cell;
步骤S504,将上述第一SFN差值信息和子帧位置信息发送给UE,其中,该第一SFN差值信息和子帧位置信息用于指示UE确定在目标小区中开始收发数据的实际子帧位置并根据确定的实际子帧位置与目标小区进行下行同步。Step S504, the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the actual subframe position in which the data is started to be sent and received in the target cell. Perform downlink synchronization with the target cell according to the determined actual subframe position.
其中,执行上述操作的可以是UE的目标基站。通过上述步骤,网络侧的源小区和目标小区间的第一SFN差值和UE在目标小区中开始收发数据的子帧位置信息都是由源基站和目标基站协商确定后发送给UE的,从而无需终端与源基站和目标基站进行多次数据交互以获取上述第一SFN差值和在目标小区中开始收发数据的实际子帧位置,节省了时间,缩短了数据中断时间,保证了业务的正常运行。从而,解决了相关技术中存在的终端与目标小区进行同步时,会造成数据中断时间长,影响业务的正常运行的问题,进而达到了减少终端与目标小区进行同步时的数据中断时间,保证业务的正常运行的效果。The foregoing operation may be performed by the target base station of the UE. Through the above steps, the first SFN difference between the source cell and the target cell on the network side and the subframe position information in which the UE starts to transmit and receive data in the target cell are determined by the source base station and the target base station, and then sent to the UE, thereby The terminal does not need to perform multiple data interactions with the source base station and the target base station to obtain the first SFN difference and the actual subframe position in which the data is started to be sent and received in the target cell, which saves time, shortens data interruption time, and ensures normal service. run. Therefore, when the terminal and the target cell existing in the related art are synchronized, the data interruption time is long, and the normal operation of the service is affected, thereby reducing the data interruption time when the terminal synchronizes with the target cell, and ensuring the service. The effect of normal operation.
下面结合实施例对本申请进行说明:The present application is described below in conjunction with the embodiments:
实施例一:
Embodiment 1:
在该实施例中,UE测量的源小区的子帧边界是在网路(即,网络侧)给定的目标小区边界之前,UE测量的源小区的子帧边界是在目标小区的子帧边界之前,如图6所示,图6是根据本发明实施例的源小区和目标小区的子帧边界示意图一。In this embodiment, the subframe boundary of the source cell measured by the UE is before the target cell boundary given by the network (ie, the network side), and the subframe boundary of the source cell measured by the UE is the subframe boundary of the target cell. Previously, as shown in FIG. 6, FIG. 6 is a schematic diagram 1 of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
图7是根据本发明实施例的终端切换小区的流程图,如图7所示,该流程包括如下步骤:FIG. 7 is a flowchart of a terminal handover cell according to an embodiment of the present invention. As shown in FIG. 7, the process includes the following steps:
步骤S702:源基站和目标基站协商UE切换到目标小区后开始收发数据的子帧位置。在协商过程中源基站和目标基站需要交互源小区和目标小区的SFN差值信息(对应于上述的第一SFN差值信息),通过该差值信息确定UE切换到目标小区后开始收发数据的子帧位置。该协商过程可以采用切换准备过程,也可以采用其他基站间信令过程。源小区和目标小区的SFN差值信息,可以是源基站发送给目标基站,也可以是目标基站发送给源基站。Step S702: The source base station and the target base station negotiate a subframe position at which the UE starts transmitting and receiving data after the UE switches to the target cell. The source base station and the target base station need to exchange the SFN difference information of the source cell and the target cell (corresponding to the first SFN difference information), and determine, by using the difference information, that the UE starts to send and receive data after switching to the target cell. Subframe position. The negotiation process may adopt a handover preparation process or other inter-base station signaling procedures. The SFN difference information of the source cell and the target cell may be sent by the source base station to the target base station, or may be sent by the target base station to the source base station.
步骤S704:源基站给UE发送切换命令(RRC Connection Reconfiguraton)。如果UE在源小区是上行同步状态,则给UE发送网络侧的源小区和目标小区间的SFN差值信息和UE在目标小区开始收发数据的子帧位置信息。Step S704: The source base station sends a handover command (RRC Connection Reconfiguraton) to the UE. If the UE is in the uplink synchronization state in the source cell, the UE sends the SFN difference information between the source cell and the target cell on the network side and the subframe position information in which the UE starts transmitting and receiving data in the target cell.
步骤S706:UE根据源小区的SFN编号/子帧编号/子帧边界,和步骤S704中发送的网络侧的源小区和目标小区间的SFN差值信息,以及网络侧配置的UE在目标小区开始收发数据的子帧位置信息,确定在目标小区切换后开始收发数据的实际子帧位置。并根据实际子帧位置发起和目标小区的同步过程,从而确定目标小区的子帧边界,进而根据确定的目标小区的子帧边界和预先确定的源小区的子帧边界的差值确定UE侧接收到信号的源小区和目标小区间的下行SFN差值(对应于上述的第二SFN差值信息)。对于网络侧的和UE测量到的源小区和目标小区的子帧边界,如果UE测量的源小区的子帧边界是在网路给定的目标小区边界之前,UE测量的源小区的子帧边界是在目标小区的子帧边界之前,如图6所示。则UE可以计算获得在目标小区的TA值(对应于上述的第二TA值),获取在目标小区的上行同步。计算方法如下:Step S706: The UE according to the SFN number/subframe number/subframe boundary of the source cell, and the SFN difference information between the source cell and the target cell on the network side sent in step S704, and the UE configured on the network side starts in the target cell. The subframe position information of the data is transmitted and received, and the actual subframe position at which the data is started to be transmitted and received after the target cell handover is determined. And determining, according to the actual subframe position, a synchronization process with the target cell, to determine a subframe boundary of the target cell, and determining, according to the determined difference between the subframe boundary of the target cell and the subframe boundary of the predetermined source cell, the UE side receiving. The downlink SFN difference between the source cell and the target cell of the signal (corresponding to the second SFN difference information described above). For the subframe boundary of the source cell and the target cell measured by the UE on the network side, if the subframe boundary of the source cell measured by the UE is before the target cell boundary given by the network, the subframe boundary of the source cell measured by the UE It is before the subframe boundary of the target cell, as shown in FIG. 6. Then, the UE may calculate a TA value (corresponding to the second TA value described above) obtained in the target cell, and acquire uplink synchronization in the target cell. The calculation method is as follows:
TAT=DUE+TAS-DNW;TA T = D UE + TA S - D NW ;
TAT:目标小区的TA值(对应于上述的第二TA值)。
TA T : TA value of the target cell (corresponding to the second TA value described above).
TAS:源小区的TA值(对应于上述的第一TA值)。TA S : TA value of the source cell (corresponding to the first TA value described above).
DNW:网络侧的源小区和目标小区的SFN差值(对应于上述的第一SFN差值)。D NW : SFN difference between the source cell and the target cell on the network side (corresponding to the first SFN difference value described above).
DUE:UE测量到的源小区和目标小区的SFN差值(对应于上述的第二SFN差值)。D UE : SFN difference between the source cell and the target cell measured by the UE (corresponding to the second SFN difference value described above).
步骤S708:根据网络配置,UE可以在目标小区发送上行信号。Step S708: According to the network configuration, the UE may send an uplink signal in the target cell.
步骤S710:网络侧可以根据发送给UE的在目标小区开始收发子帧的位置给UE发送数据,也可以在收到步骤S708的UE上行信号后给UE发送数据。UE可以根据发送给UE的在目标小区开始收发子帧的位置,开始收发数据。也可以在步骤S708后开始在目标小区收发数据。Step S710: The network side may send data to the UE according to the location of the UE that starts transmitting and receiving the subframe at the target cell, or may send the data to the UE after receiving the uplink signal of the UE in step S708. The UE may start to send and receive data according to the location of the subframe that is sent to the UE at the target cell. It is also possible to start transmitting and receiving data in the target cell after step S708.
步骤S712:网络侧发送上行授权信息给UE。该步骤可以和步骤S710同时进行。Step S712: The network side sends uplink grant information to the UE. This step can be performed simultaneously with step S710.
步骤S714:UE根据上行授权信息发送上行数据或切换完成消息(RRC Connection Reconfiguration Complete)给网络侧。Step S714: The UE sends an uplink data or an RRC Connection Reconfiguration Complete message to the network side according to the uplink grant information.
实施例二:Embodiment 2:
在该实施例中,UE测量的源小区的子帧边界是在网路给定的目标小区边界之后,UE测量的源小区的子帧边界是在目标小区的子帧边界之前,如图8所示,图8是根据本发明实施例的源小区和目标小区的子帧边界示意图二。In this embodiment, the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, and the subframe boundary of the source cell measured by the UE is before the subframe boundary of the target cell, as shown in FIG. 8. 8 is a second schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
该实施例步骤同实施例一。步骤S706中,对于网络侧的和UE测量到的源小区和目标小区的子帧边界,如果UE测量的源小区的子帧边界是在网路给定的目标小区边界之后,UE测量的源小区的子帧边界是在目标小区的子帧边界之前,如图8所示。则UE可以计算获得在目标小区的TA值,获取在目标小区的上行同步。计算方法如下:The steps of this embodiment are the same as those in the first embodiment. In step S706, for the subframe boundary of the source cell and the target cell measured by the UE on the network side, if the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, the source cell measured by the UE The subframe boundary is before the subframe boundary of the target cell, as shown in FIG. Then, the UE can calculate the TA value obtained in the target cell, and acquire the uplink synchronization in the target cell. The calculation method is as follows:
TAT=DUE+TAS-DNW;TA T = D UE + TA S - D NW ;
TAT:目标小区的TA值。TA T : TA value of the target cell.
TAS:源小区的TA值。
TA S : TA value of the source cell.
DNW:网络侧的源小区和目标小区的SFN差值。D NW : SFN difference between the source cell and the target cell on the network side.
DUE:UE测量到的源小区和目标小区的SFN差值。D UE : The SFN difference between the source cell and the target cell measured by the UE.
实施例三:Embodiment 3:
在该实施例中,UE测量的源小区的子帧边界是在网路给定的目标小区边界之后,UE测量的源小区的子帧边界是在目标小区的子帧边界之后,如图9所示,图9是根据本发明实施例的源小区和目标小区的子帧边界示意图三。In this embodiment, the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, and the subframe boundary of the source cell measured by the UE is after the subframe boundary of the target cell, as shown in FIG. FIG. 9 is a third schematic diagram of a subframe boundary of a source cell and a target cell according to an embodiment of the present invention.
该实施例步骤同实施例一。步骤S706中,对于网络侧的和UE测量到的源小区和目标小区的子帧边界,如果UE测量的源小区的子帧边界是在网路给定的目标小区边界之后,UE测量的源小区的子帧边界是在目标小区的子帧边界之后,如图9所示。则UE可以计算获得在目标小区的TA值,获取在目标小区的上行同步。计算方法如下:The steps of this embodiment are the same as those in the first embodiment. In step S706, for the subframe boundary of the source cell and the target cell measured by the UE on the network side, if the subframe boundary of the source cell measured by the UE is after the target cell boundary given by the network, the source cell measured by the UE The subframe boundary is after the subframe boundary of the target cell, as shown in FIG. Then, the UE can calculate the TA value obtained in the target cell, and acquire the uplink synchronization in the target cell. The calculation method is as follows:
TAT=TAS–(DNW+DUE);TA T =TA S -(D NW +D UE );
TAT:目标小区的TA值。TA T : TA value of the target cell.
TAS:源小区的TA值。TA S : TA value of the source cell.
DNW:网络侧的源小区和目标小区的SFN差值。D NW : SFN difference between the source cell and the target cell on the network side.
DUE:UE测量到的源小区和目标小区的SFN差值。D UE : The SFN difference between the source cell and the target cell measured by the UE.
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到根据上述实施例的方法可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件,但很多情况下前者是更佳的实施方式。基于这样的理解,本发明实施例的技术方案可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质(如ROM/RAM、磁碟、光盘)中,包括多个指令用以使得一台终端设备(可以是手机,计算机,服务器,或者网络设备等)执行本发明实施例所述的方法。Through the description of the above embodiments, those skilled in the art can clearly understand that the method according to the above embodiment can be implemented by means of software plus a necessary general hardware platform, and of course, by hardware, but in many cases, the former is A better implementation. Based on the understanding, the technical solution of the embodiment of the present invention may be embodied in the form of a software product stored in a storage medium (such as a ROM/RAM, a magnetic disk, an optical disk), and includes a plurality of instructions for making A terminal device (which may be a mobile phone, a computer, a server, or a network device, etc.) performs the method described in the embodiments of the present invention.
在本实施例中还提供了一种同步装置,该装置用于实现上述实施例及可选实施方式,已经进行过说明的不再赘述。如以下所使用的,术语“模块”可以实现预定功能的软件和/或硬件的组合。尽管以下实施例所描述的装置可以以软件来实现,但是硬件,或者软件和硬件的组合的实现也是可能并被构想
的。In this embodiment, a synchronization device is also provided, which is used to implement the foregoing embodiments and optional implementations, and details are not described herein. As used below, the term "module" may implement a combination of software and/or hardware of a predetermined function. Although the apparatus described in the following embodiments can be implemented in software, hardware, or a combination of software and hardware, is also possible and conceived.
of.
图10是根据本发明实施例的第一种同步装置的结构框图,如图10所示,该装置包括接收模块102、第一确定模块104和第一同步模块106,下面对该装置进行说明。FIG. 10 is a structural block diagram of a first synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 10, the apparatus includes a receiving module 102, a first determining module 104, and a first synchronization module 106. .
接收模块102,设置为:接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在目标小区中开始收发数据的子帧位置信息,其中,该第一SFN差值信息为源基站与目标基站通过协商交互确定的,该子帧位置信息是根据第一SFN差值信息确定的;第一确定模块104,连接至上述接收模块102,设置为:根据第一SFN差值信息和子帧位置信息确定在目标小区中开始收发数据的实际子帧位置;第一同步模块106,连接至上述第一确定模块104,设置为:根据确定的实际子帧位置与目标小区进行下行同步。The receiving module 102 is configured to: receive, by the source base station, the first system frame number SFN difference information between the source cell and the target cell, and the subframe location information that the terminal UE starts to send and receive data in the target cell, where the first SFN The difference information is determined by the source base station and the target base station through negotiation, and the subframe position information is determined according to the first SFN difference information. The first determining module 104 is connected to the receiving module 102, and is configured to: according to the first The SFN difference information and the subframe position information determine an actual subframe position at which the data is started to be transmitted and received in the target cell. The first synchronization module 106 is connected to the first determining module 104, and is configured to: according to the determined actual subframe position and the target cell. Perform downlink synchronization.
图11是根据本发明实施例的第一种同步装置的可选结构框图,如图11所示,该装置除包括图10所示的所有模块外,还包括第二确定模块112、第三确定模块114和第二同步模块116,下面对该装置进行说明。11 is a block diagram showing an optional structure of a first synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 11, the apparatus includes a second determination module 112 and a third determination in addition to all the modules shown in FIG. The module 114 and the second synchronization module 116 are described below.
第二确定模块112,连接至上述第一同步模块106,设置为:在根据确定的实际子帧位置与目标小区进行下行同步之后,确定上述源小区和目标小区间的第二SFN差值信息;第三确定模块114,连接至上述第二确定模块112,设置为:根据第一SFN差值信息、第二SFN差值信息和预先确定的与源小区进行上行同步时的第一上行定时提前量TA值确定用于与目标小区进行上行同步的第二TA值;第二同步模块116,连接至上述第三确定模块114,设置为:根据确定的第二TA值与目标小区进行上行同步。The second determining module 112 is connected to the first synchronization module 106, and configured to: after performing downlink synchronization with the target cell according to the determined actual subframe position, determining second SFN difference information between the source cell and the target cell; The third determining module 114 is connected to the second determining module 112, and is configured to: according to the first SFN difference information, the second SFN difference information, and the predetermined first uplink timing advance when performing uplink synchronization with the source cell. The TA value determines a second TA value for uplink synchronization with the target cell. The second synchronization module 116 is connected to the third determining module 114, and is configured to perform uplink synchronization with the target cell according to the determined second TA value.
图12是根据本发明实施例的第一种同步装置中第二确定模块112的结构框图,如图12所示,该第二确定模块112包括第一确定单元122和第二确定单元124,下面对该第二确定模块112进行说明。FIG. 12 is a structural block diagram of a second determining module 112 in a first synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 12, the second determining module 112 includes a first determining unit 122 and a second determining unit 124. The second determination module 112 is described.
第一确定单元122,设置为:确定目标小区的子帧边界;第二确定单元124,连接至上述第一确定单元122,设置为:根据上述目标小区的子帧边界和预先确定的源小区的子帧边界的差值,确定第二SFN差值信息。
The first determining unit 122 is configured to: determine a subframe boundary of the target cell; the second determining unit 124 is connected to the first determining unit 122, and is configured to: according to the subframe boundary of the target cell and the predetermined source cell The difference of the subframe boundaries determines the second SFN difference information.
在一个可选的实施例中,上述第三确定模块可以通过以下方式之一确定第二SFN差值信息:当预先确定的上述源小区的子帧边界是在确定的目标小区的子帧边界之前时,可以通过如下公式确定第二TA值TAT:TAT=DUE+TAS-DNW;当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之后时,可以通过如下公式确定第二TA值TAT:TAT=TAS-(DUE+DNW);其中,TAS为第一TA值,DUE为第二SFN差值信息对应的第二SFN差值,DNW为第一SFN差值信息对应的第一SFN差值。In an optional embodiment, the foregoing third determining module may determine the second SFN difference information by using one of the following manners: when the predetermined subframe boundary of the source cell is before the determined subframe boundary of the target cell , it is possible to determine the second value TA TA T by the following formula: TA T = D UE + TA S -D NW; the target cell when the sub-sub-frame boundary determined in advance in the source cell is determined frame boundaries Thereafter, when the second value TA TA T can be determined by the following equation: TA T = TA S - ( D UE + D NW); wherein, S is the first TA value TA, D UE is the difference information corresponding to a second SFN The second SFN difference, D NW is the first SFN difference corresponding to the first SFN difference information.
图13是根据本发明实施例的第二种同步装置的结构框图,如图13所示,该装置包括第四确定模块132和第一发送模块134,下面对该装置进行说明。FIG. 13 is a structural block diagram of a second synchronization apparatus according to an embodiment of the present invention. As shown in FIG. 13, the apparatus includes a fourth determination module 132 and a first transmission module 134, which will be described below.
第四确定模块132,设置为:与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和UE在目标小区中开始收发数据的子帧位置信息;第一发送模块134,连接至上述第四确定模块132,设置为:将上述第一SFN差值信息和子帧位置信息发送给UE,其中,该第一SFN差值信息和子帧位置信息用于指示UE确定在目标小区中开始收发数据的实际子帧位置并根据确定的实际子帧位置与目标小区进行下行同步。The fourth determining module 132 is configured to: determine, by means of negotiation and interaction with the target base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position where the UE starts to send and receive data in the target cell. The first sending module 134 is connected to the fourth determining module 132, and configured to: send the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used. The UE is instructed to determine an actual subframe position in which data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
图14是根据本发明实施例的第三种同步装置的结构框图,如图14所示,该装置包括第五确定模块142和第二发送模块144,下面对该装置进行说明。14 is a block diagram showing the structure of a third synchronizing apparatus according to an embodiment of the present invention. As shown in FIG. 14, the apparatus includes a fifth determining module 142 and a second transmitting module 144, which will be described below.
第五确定模块142,设置为:与源基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和UE在目标小区中开始收发数据的子帧位置信息;第二发送模块144,连接至上述第五确定模块142,设置为:将上述第一SFN差值信息和子帧位置信息发送给UE,其中,该第一SFN差值信息和子帧位置信息用于指示UE确定在目标小区中开始收发数据的实际子帧位置并根据确定的实际子帧位置与目标小区进行下行同步。The fifth determining module 142 is configured to: determine, by means of negotiation and interaction with the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position where the UE starts to send and receive data in the target cell. The second sending module 144 is connected to the fifth determining module 142, and configured to: send the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used. The UE is instructed to determine an actual subframe position in which data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
需要说明的是,上述模块是可以通过软件或硬件来实现的,对于后者,可以通过以下方式实现,但不限于此:上述模块均位于同一处理器中;或者,上述模块分别位于多个处理器中。It should be noted that the above modules may be implemented by software or hardware. For the latter, the foregoing may be implemented by, but not limited to, the foregoing modules are all located in the same processor; or, the modules are respectively located in multiple processes. In the device.
本发明的实施例还提供了一种存储介质。可选地,在本实施例中,上述
存储介质可以被设置为存储用于执行以下步骤的程序代码:Embodiments of the present invention also provide a storage medium. Optionally, in this embodiment, the above
The storage medium can be configured to store program code for performing the following steps:
S11,接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在目标小区中开始收发数据的子帧位置信息,其中,该第一SFN差值信息为源基站与目标基站通过协商交互确定的,该子帧位置信息是根据第一SFN差值信息确定的;S11. The first system frame number SFN difference information between the source cell and the target cell that is sent by the source base station, and the subframe position information that the terminal UE starts to send and receive data in the target cell, where the first SFN difference information is a source. Determining, by the base station and the target base station, by negotiation, the subframe position information is determined according to the first SFN difference information;
S12,根据上述第一SFN差值信息和子帧位置信息确定在目标小区中开始收发数据的实际子帧位置;S12. Determine, according to the first SFN difference information and the subframe position information, an actual subframe position that starts to send and receive data in the target cell.
S13,根据确定的上述实际子帧位置与目标小区进行下行同步。S13. Perform downlink synchronization with the target cell according to the determined actual subframe position.
可选地,存储介质还被设置为存储用于执行以下步骤的程序代码:Optionally, the storage medium is further arranged to store program code for performing the following steps:
S21,与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和UE在目标小区中开始收发数据的子帧位置信息;S21: Determine a first system frame number SFN difference information between a source cell and a target cell of the terminal UE, and a subframe position information that the UE starts to send and receive data in the target cell, by performing a negotiation interaction with the target base station;
S22,将上述第一SFN差值信息和子帧位置信息发送给UE,其中,该第一SFN差值信息和子帧位置信息用于指示UE确定在目标小区中开始收发数据的实际子帧位置并根据确定的上述实际子帧位置与目标小区进行下行同步。S22, the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the actual subframe position in which the data is started to be sent and received in the target cell, and according to The determined actual subframe position is downlink synchronized with the target cell.
可选地,存储介质还被设置为存储用于执行以下步骤的程序代码:Optionally, the storage medium is further arranged to store program code for performing the following steps:
S31,与源基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和UE在目标小区中开始收发数据的子帧位置信息;S31. Determine, by means of a negotiation, the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position information that the UE starts to send and receive data in the target cell.
S32,将上述第一SFN差值信息和子帧位置信息发送给UE,其中,该第一SFN差值信息和子帧位置信息用于指示UE确定在目标小区中开始收发数据的实际子帧位置并根据确定的实际子帧位置与目标小区进行下行同步。S32, the first SFN difference information and the subframe position information are sent to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines an actual subframe position that starts to send and receive data in the target cell, and according to The determined actual subframe position is downlink synchronized with the target cell.
可选地,在本实施例中,上述存储介质可以包括但不限于:U盘、只读存储器(Read-Only Memory,简称为ROM)、随机存取存储器(Random Access Memory,简称为RAM)、移动硬盘、磁碟或者光盘等多种可以存储程序代码的介质。Optionally, in the embodiment, the foregoing storage medium may include, but is not limited to, a USB flash drive, a Read-Only Memory (ROM), and a Random Access Memory (RAM). A variety of media that can store program code, such as a hard disk, a disk, or an optical disk.
可选地,在本实施例中,处理器根据存储介质中已存储的程序代码执行
上述的步骤。Optionally, in this embodiment, the processor executes according to the stored program code in the storage medium.
The above steps.
可选地,本实施例中的示例可以参考上述实施例及可选实施方式中所描述的示例,本实施例在此不再赘述。For example, the examples in this embodiment may refer to the examples described in the foregoing embodiments and the optional embodiments, and details are not described herein again.
采用本发明实施例中所述的方法,可以辅助UE在切换过程中更快的获取目标小区的下行和上行同步,从而减少切换过程的数据中断时间。The method described in the embodiment of the present invention can assist the UE to acquire the downlink and uplink synchronization of the target cell more quickly during the handover process, thereby reducing the data interruption time of the handover process.
显然,本领域的技术人员应该明白,上述的本发明实施例的模块或步骤可以用通用的计算装置来实现,它们可以集中在单个的计算装置上,或者分布在多个计算装置所组成的网络上,可选地,它们可以用计算装置可执行的程序代码来实现,从而,可以将它们存储在存储装置中由计算装置来执行,并且在某些情况下,可以以不同于此处的顺序执行所示出或描述的步骤,或者将它们分别制作成集成电路模块,或者将它们中的多个模块或步骤制作成单个集成电路模块来实现。这样,本发明实施例不限制于任何特定的硬件和软件结合。It will be apparent to those skilled in the art that the above-described modules or steps of the embodiments of the present invention can be implemented by a general-purpose computing device, which can be centralized on a single computing device or distributed over a network of multiple computing devices. Alternatively, they may be implemented by program code executable by the computing device such that they may be stored in the storage device by the computing device and, in some cases, may be different from the order herein. The steps shown or described are performed either separately as an integrated circuit module, or a plurality of modules or steps thereof are fabricated as a single integrated circuit module. Thus, embodiments of the invention are not limited to any specific combination of hardware and software.
以上所述仅为本发明的可选实施例而已,并不用于限制本申请,对于本领域的技术人员来说,本申请可以有多种更改和变化。凡在本申请的精神和原则之内,所作的任何修改、等同替换、改进等,均应包含在本申请的保护范围之内。The above description is only an alternative embodiment of the present invention, and is not intended to limit the present application, and various changes and modifications may be made by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of this application are intended to be included within the scope of the present application.
通过本发明实施例,解决了相关技术中存在的终端与目标小区进行同步时,会造成数据中断时间长,影响业务的正常运行的问题,进而达到了减少终端与目标小区进行同步时的数据中断时间,保证业务的正常运行的效果。
The embodiment of the present invention solves the problem that when the terminal and the target cell are synchronized in the related art, the data interruption time is long, and the normal operation of the service is affected, thereby reducing the data interruption when the terminal synchronizes with the target cell. Time to ensure the normal operation of the business.
Claims (12)
- 一种同步方法,包括:A synchronization method that includes:接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在所述目标小区中开始收发数据的子帧位置信息,其中,所述第一SFN差值信息为所述源基站与目标基站通过协商交互确定的,所述子帧位置信息是根据所述第一SFN差值信息确定的;And receiving, by the source base station, the first system frame number SFN difference information between the source cell and the target cell, and the subframe location information that the terminal UE starts to send and receive data in the target cell, where the first SFN difference information is Determining, by the source base station and the target base station, the subframe position information is determined according to the first SFN difference information;根据所述第一SFN差值信息和所述子帧位置信息确定在所述目标小区中开始收发数据的实际子帧位置;Determining, according to the first SFN difference information and the subframe position information, an actual subframe position in which data is started to be transceived in the target cell;根据确定的所述实际子帧位置与所述目标小区进行下行同步。Performing downlink synchronization with the target cell according to the determined actual subframe position.
- 根据权利要求1所述的方法,其中,在根据确定的所述实际子帧位置与所述目标小区进行下行同步之后,还包括:The method according to claim 1, wherein after performing downlink synchronization with the target cell according to the determined actual subframe position, the method further includes:确定所述源小区和所述目标小区间的第二SFN差值信息;Determining second SFN difference information between the source cell and the target cell;根据所述第一SFN差值信息、所述第二SFN差值信息和预先确定的与所述源小区进行上行同步时的第一上行定时提前量TA值确定用于与所述目标小区进行上行同步的第二TA值;Determining, according to the first SFN difference information, the second SFN difference information, and a predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell, for performing uplink with the target cell The second TA value of the synchronization;根据确定的所述第二TA值与所述目标小区进行上行同步。Performing uplink synchronization with the target cell according to the determined second TA value.
- 根据权利要求2所述的方法,其中,确定所述源小区和所述目标小区间的第二SFN差值信息包括:The method of claim 2, wherein determining the second SFN difference information between the source cell and the target cell comprises:确定所述目标小区的子帧边界;Determining a subframe boundary of the target cell;根据所述目标小区的子帧边界和预先确定的所述源小区的子帧边界的差值,确定所述第二SFN差值信息。And determining, according to a difference between a subframe boundary of the target cell and a predetermined subframe boundary of the source cell, the second SFN difference information.
- 根据权利要求3所述的方法,其中,根据所述第一SFN差值信息、所述第二SFN差值信息和预先确定的与所述源小区进行上行同步时的第一上行定时提前量TA值确定用于与所述目标小区进行上行同步时的第二TA值包括以下之一:The method according to claim 3, wherein the first uplink timing advance amount TA when uplink synchronization is performed with the source cell according to the first SFN difference information, the second SFN difference information, and a predetermined The second TA value when the value is determined to be used for uplink synchronization with the target cell includes one of the following:当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之前时,通过如下公式确定所述第二TA值TAT: When a predetermined sub-frame boundaries of the source cell is the target cell before the sub-frame boundary is determined, it is determined by the following formula said second value TA TA T:TAT=DUE+TAS-DNW;TA T = D UE + TA S - D NW ;当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之后时,通过如下公式确定所述第二TA值TAT:When a predetermined sub-frame boundaries of the source cell is the target cell after the sub-frame boundary is determined, determining a second value TA TA T by the following formula:TAT=TAS-(DUE+DNW);TA T =TA S -(D UE +D NW );其中,TAS为所述第一TA值,DUE为所述第二SFN差值信息对应的第二SFN差值,DNW为所述第一SFN差值信息对应的第一SFN差值。The TA S is the first TTL value, and the D UE is the second SFN difference corresponding to the second SFN difference information, and the D NW is the first SFN difference corresponding to the first SFN difference information.
- 一种同步方法,包括:A synchronization method that includes:与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;Determining, by means of a negotiation, the target base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the subframe position information of the UE starting to send and receive data in the target cell;将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。Transmitting the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the target The actual subframe position of the data is started to be transmitted and received in the cell, and downlink synchronization is performed with the target cell according to the determined actual subframe position.
- 一种同步方法,包括:A synchronization method that includes:与源基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;Determining the first system frame number SFN difference information between the source cell and the target cell of the terminal UE and the subframe position information of the UE starting to transmit and receive data in the target cell, by performing a negotiation interaction with the source base station;将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。Transmitting the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used to indicate that the UE determines the target The actual subframe position of the data is started to be transmitted and received in the cell, and downlink synchronization is performed with the target cell according to the determined actual subframe position.
- 一种同步装置,包括:A synchronization device comprising:接收模块,设置为:接收源基站发送的源小区和目标小区间的第一系统帧号SFN差值信息和终端UE在所述目标小区中开始收发数据的子帧位置信息,其中,所述第一SFN差值信息为所述源基站与目标基站通过协商交互确定的,所述子帧位置信息是根据所述第一SFN差值信息确定的;The receiving module is configured to: receive, by the source base station, the first system frame number SFN difference information between the source cell and the target cell, and the subframe location information that the terminal UE starts to send and receive data in the target cell, where the The SFN difference information is determined by the source base station and the target base station by negotiation, and the subframe position information is determined according to the first SFN difference information;第一确定模块,设置为:根据所述第一SFN差值信息和所述子帧位置信 息确定在所述目标小区中开始收发数据的实际子帧位置;a first determining module, configured to: according to the first SFN difference information and the subframe position information Determining an actual subframe position at which the data is started to be transmitted and received in the target cell;第一同步模块,设置为:根据确定的所述实际子帧位置与所述目标小区进行下行同步。The first synchronization module is configured to: perform downlink synchronization with the target cell according to the determined actual subframe position.
- 根据权利要求7所述的装置,所述装置还包括:The apparatus of claim 7 further comprising:第二确定模块,设置为:在根据确定的所述实际子帧位置与所述目标小区进行下行同步之后,确定所述源小区和所述目标小区间的第二SFN差值信息;a second determining module, configured to: after performing downlink synchronization with the target cell according to the determined actual subframe position, determining second SFN difference information between the source cell and the target cell;第三确定模块,设置为:根据所述第一SFN差值信息、所述第二SFN差值信息和预先确定的与所述源小区进行上行同步时的第一上行定时提前量TA值确定用于与所述目标小区进行上行同步的第二TA值;a third determining module, configured to: determine, according to the first SFN difference information, the second SFN difference information, and a predetermined first uplink timing advance amount TA value when performing uplink synchronization with the source cell a second TA value for uplink synchronization with the target cell;第二同步模块,设置为:根据确定的所述第二TA值与所述目标小区进行上行同步。The second synchronization module is configured to: perform uplink synchronization with the target cell according to the determined second TA value.
- 根据权利要求8所述的装置,其中,所述第二确定模块包括:The apparatus of claim 8, wherein the second determining module comprises:第一确定单元,设置为:确定所述目标小区的子帧边界;a first determining unit, configured to: determine a subframe boundary of the target cell;第二确定单元,设置为:根据所述目标小区的子帧边界和预先确定的所述源小区的子帧边界的差值,确定所述第二SFN差值信息。The second determining unit is configured to: determine the second SFN difference information according to a difference between a subframe boundary of the target cell and a predetermined subframe boundary of the source cell.
- 根据权利要求9所述的装置,其中,所述第三确定模块通过以下方式之一确定所述第二SFN差值信息:The apparatus according to claim 9, wherein said third determining module determines said second SFN difference information by one of:当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之前时,通过如下公式确定所述第二TA值TAT:When a predetermined sub-frame boundaries of the source cell is the target cell before the sub-frame boundary is determined, it is determined by the following formula said second value TA TA T:TAT=DUE+TAS-DNW;TA T = D UE + TA S - D NW ;当预先确定的所述源小区的子帧边界是在确定的所述目标小区的子帧边界之后时,通过如下公式确定所述第二TA值TAT:When a predetermined sub-frame boundaries of the source cell is the target cell after the sub-frame boundary is determined, determining a second value TA TA T by the following formula:TAT=TAS-(DUE+DNW);TA T =TA S -(D UE +D NW );其中,TAS为所述第一TA值,DUE为所述第二SFN差值信息对应的第二SFN差值,DNW为所述第一SFN差值信息对应的第一SFN差值。The TA S is the first TTL value, and the D UE is the second SFN difference corresponding to the second SFN difference information, and the D NW is the first SFN difference corresponding to the first SFN difference information.
- 一种同步装置,包括: A synchronization device comprising:第四确定模块,设置为:与目标基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;The fourth determining module is configured to: determine, by means of a negotiation interaction with the target base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the UE starts to send and receive data in the target cell. Subframe position information;第一发送模块,设置为:将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。The first sending module is configured to: send the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used to indicate The UE determines an actual subframe position in which the data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
- 一种同步装置,包括:A synchronization device comprising:第五确定模块,设置为:与源基站通过协商交互的方式确定终端UE的源小区和目标小区间的第一系统帧号SFN差值信息和所述UE在所述目标小区中开始收发数据的子帧位置信息;The fifth determining module is configured to: determine, by means of a negotiation interaction with the source base station, the first system frame number SFN difference information between the source cell and the target cell of the terminal UE, and the UE starts to send and receive data in the target cell. Subframe position information;第二发送模块,设置为:将所述第一SFN差值信息和所述子帧位置信息发送给所述UE,其中,所述第一SFN差值信息和所述子帧位置信息用于指示所述UE确定在所述目标小区中开始收发数据的实际子帧位置并根据确定的所述实际子帧位置与所述目标小区进行下行同步。 The second sending module is configured to: send the first SFN difference information and the subframe position information to the UE, where the first SFN difference information and the subframe position information are used to indicate The UE determines an actual subframe position in which the data is started to be transceived in the target cell, and performs downlink synchronization with the target cell according to the determined actual subframe position.
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CN104205932A (en) * | 2012-04-13 | 2014-12-10 | 高通股份有限公司 | Method and apparatus for expedited wireless device handover |
CN104053202A (en) * | 2013-03-12 | 2014-09-17 | 中兴通讯股份有限公司 | Cell primary scrambling code conflict identification, soft handover and adjacent cell list generating method and device |
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CN106686669A (en) | 2017-05-17 |
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