阅读说明：本技术 一种通信的方法及装置 (Communication method and device ) 是由 张莉莉 于 2020-04-17 设计创作，主要内容包括：本申请涉及通信技术领域,公开了一种通信的方法及装置,用以提出一种在侧行链路通信中设置定时器的时长值的方式。第一终端接收来自第二终端的侧行链路控制信息SCI,所述SCI指示侧行链路的时域资源。所述第一终端确定第一定时器的第一时长值；其中,所述第一时长值属于为资源池配置的时长值集合或者为侧行链路配置的时长值集合,所述时长值集合中包括至少一个时长值；或者,所述第一时长值根据所述第一终端的非连续接收DRX的配置信息和/或所述SCI指示的时域资源确定。所述第一终端在第一时刻启动所述第一定时器,在所述第一时长值内的至少一个时间单元监听侧行链路的控制信息和/或侧行链路的数据信息。(The application relates to the technical field of communication, and discloses a communication method and device, which are used for providing a mode of setting a time length value of a timer in sidelink communication. The first terminal receives sidelink control information, SCI, from the second terminal, the SCI indicating a time domain resource of the sidelink. The first terminal determines a first time length value of a first timer; the first time length value belongs to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set comprises at least one time length value; or, the first duration value is determined according to the configuration information of the Discontinuous Reception (DRX) of the first terminal and/or the time domain resource indicated by the SCI. The first terminal starts the first timer at a first time, and monitors control information of a sidelink and/or data information of the sidelink in at least one time unit within the first time length value.)

1. A method of communication, the method comprising:

a first terminal receives Sidelink Control Information (SCI) from a second terminal, wherein the SCI indicates a time domain resource of a sidelink;

the first terminal determines a first time length value of a first timer; the first time length value belongs to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set comprises at least one time length value; or, the first time length value is determined according to the configuration information of the Discontinuous Reception (DRX) of the first terminal and/or the time domain resource of the sidelink indicated by the SCI;

the first terminal starts the first timer at a first time, and monitors control information of a sidelink and/or data information of the sidelink in at least one time unit within the first time length value.

2. The method of claim 1, wherein the first terminal determining the first duration value of the inactivity timer comprises:

the first terminal determines a duration value in the duration value set as the first duration value; or

The first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI; or

The first terminal receiving the first time value from the second terminal; or

The first terminal receives the first time length value from a network device.

3. The method of claim 2, wherein the first terminal determines the first time value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, and wherein the determining of the first time value comprises at least one of:

the first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain position of the time domain resource of the sidelink indicated by the SCI; alternatively, the first and second electrodes may be,

the first terminal determines the first time value according to whether the configuration information of discontinuous reception of the first terminal and the time domain resource of the sidelink indicated by the SCI are completely overlapped; alternatively, the first and second electrodes may be,

and the first terminal determines the first time length value according to the configuration information of the discontinuous reception of the first terminal and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

4. The method of claim 2 or 3, wherein the determining, by the first terminal, the first time value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI comprises:

and the first terminal determines the first time value according to the discontinuous reception duration of the first terminal and/or the time domain resource of the sidelink indicated by the SCI.

5. The method of any one of claims 2-4, wherein the degree of overlap comprises any one of:

the time domain resource is located completely within the duration of discontinuous reception of the first terminal, or at least the first m symbols of the time domain resource are located within the duration of discontinuous reception of the first terminal, or the overlapping portion of the time domain resource and the duration of discontinuous reception of the first terminal fails to contain at least the first m symbols of the time domain resource.

6. The method of any one of claims 1-5, wherein the first time is any one of:

the starting symbol of the SCI;

the next symbol to the starting symbol of the SCI;

a termination symbol of the SCI;

a next symbol to a termination symbol of the SCI;

a starting symbol of a first time domain resource indicated by the SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the SCI;

a termination symbol of a first time domain resource indicated by the SCI;

a symbol next to a termination symbol of the first time domain resource indicated by the SCI.

7. The method of any of claims 1-5, wherein the SCI includes a first-level SCI and a second-level SCI, and wherein the first time is any of:

a start symbol of the first-level SCI or a start symbol of the second-level SCI;

a next symbol to the start symbol of the first-level SCI or a next symbol to the start symbol of the second-level SCI;

a termination symbol of the first-level SCI or a termination symbol of the second-level SCI;

a next symbol of a termination symbol of the first-level SCI or a next symbol of a termination symbol of the second-level SCI;

a starting symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI;

a termination symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a termination symbol of the first time domain resource indicated by the first-level SCI.

8. The method of any of claims 1-7, wherein the configuration information comprises at least one of:

start offset, duration, cycle length, pattern index.

9. The method of any of claims 1-8, wherein the time domain resources of the sidelink indicated by the SCI comprise:

a first resource set, the first resource set comprising time domain resources of N sidelink, N being a positive integer; or the like, or, alternatively,

a second set of resources comprising a periodic first set of resources comprising time domain resources of N sidelink, N being a positive integer.

10. The method of claim 9, wherein determining the first duration value according to the configuration information of Discontinuous Reception (DRX) of the first terminal and/or the time domain resource of the sidelink indicated by the SCI comprises:

determining a first time length value according to a difference value between the third time and the second time;

wherein the second time is any one of:

the starting symbol of the SCI;

a symbol next to the starting symbol of the SCI;

a termination symbol of the SCI;

a next symbol to a termination symbol of the SCI;

a starting symbol of a first time domain resource indicated by the SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the SCI;

a termination symbol of a first time domain resource indicated by the SCI;

a symbol next to a termination symbol of the first time domain resource indicated by the SCI;

wherein the third time is any one of:

a starting symbol of an xth time domain resource in a first set of resources indicated by the SCI;

a next symbol of a starting symbol of an xth time domain resource in a first set of resources indicated by the SCI;

a termination symbol of an xth time domain resource in a first set of resources indicated by the SCI;

a next symbol of a termination symbol of an xth time domain resource in the first combination of resources indicated by the SCI;

a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the SCI;

a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the SCI;

a termination symbol for an xth time domain resource in a yth first set of resources in a second set of resources indicated by the SCI;

a next symbol of a termination symbol of an xth time domain resource in a yth first set of resources in a second set of resources indicated by the SCI;

wherein y is an integer greater than or equal to 1, x is an integer greater than or equal to 1, and x is an integer less than or equal to n.

11. The method of claim 9, wherein determining the first duration value according to the configuration information of Discontinuous Reception (DRX) of the first terminal and/or the time domain resource indicated by the SCI comprises:

determining a first time length value according to a difference value between the third time and the second time;

the SCIs include a first level SCI and a second level SCI,

the second time is any one of:

a start symbol of the first-level SCI or a start symbol of the second-level SCI;

a next symbol to the start symbol of the first-level SCI or a next symbol to the start symbol of the second-level SCI;

a termination symbol of the first-level SCI or a termination symbol of the second-level SCI;

a next symbol of a termination symbol of the first-level SCI or a next symbol of a termination symbol of the second-level SCI;

a starting symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI;

a termination symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a termination symbol of a first time domain resource indicated by the first-level SCI;

the third time is any one of:

a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI;

a next symbol of a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI;

a termination symbol of an xth time domain resource in a first set of resources indicated by the first-level SCI;

a next symbol of a termination symbol of an xth time domain resource in a first resource combination indicated by the first-level SCI;

a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI;

a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI;

a termination symbol of an xth time domain resource in a yth first resource set in a second resource set indicated by the first-level SCI;

a next symbol of a termination symbol of an x-th time domain resource in a y-th first resource set in the second resource set indicated by the first-level SCI.

12. A method as claimed in claims 10 and 11, wherein determining the first duration value from the difference between the third time and the second time comprises:

taking the difference value between the third moment and the second moment as the first time length value; alternatively, the first and second electrodes may be,

taking the sum of the difference value of the third time and the second time and the first parameter as the first time length value; alternatively, the first and second electrodes may be,

and taking the minimum slot number which is greater than or equal to the difference value between the third time and the second time as the first time length value.

13. The method of claim 12, wherein the first parameter is a duration of a time domain resource or an offset.

14. The method according to any of claims 1-13, wherein one or more of the set of configured duration values for the resource pool is associated with a duration of discontinuous reception, or a cycle length of discontinuous reception;

or, the duration of discontinuous reception or the cycle length of discontinuous reception is associated with one or more duration values in the set of duration values configured for the sidelink.

15. The method of any of claims 1-14, wherein the first duration value is a non-consecutive duration value, wherein non-consecutive means that the first duration value matches a corresponding time domain resource.

16. The method of any of claims 2-14, wherein the first terminal determining a duration value from the set of duration values as the first duration value comprises:

and the first terminal determines the minimum time length value which is greater than or equal to the difference value between the third moment and the second moment in the time length value set as the first time length value.

17. A communication apparatus, characterized in that the apparatus is adapted to perform the method according to any of claims 1-16.

18. A communications apparatus, the apparatus comprising: a processor and a memory; the processor and the memory are coupled;

the memory to store computer program instructions;

the processor is configured to execute some or all of the computer program instructions in the memory, when executed, to implement the method of any of claims 1-16.

19. A computer-readable storage medium having computer-readable instructions stored thereon which, when read and executed by a computer, cause the computer to perform the method of any one of claims 1-16.

Technical Field

The embodiment of the application relates to the technical field of communication, in particular to a communication method and device.

Background

On the sidelink, in consideration of energy saving of the terminal, a Discontinuous Reception (DRX) mechanism may be introduced. The DRX mechanism is as follows: a terminal in Radio Resource Control (RRC) CONNECTED state CONNECTED is configured with one DRX cycle. The DRX cycle includes an active period and a sleep period. In the active period, the terminal monitors and receives data of a Physical Downlink Control Channel (PDCCH). In the dormant period, the terminal does not monitor the data of the PDCCH any more, so as to save power consumption.

Generally, after a terminal is scheduled in a certain subframe and receives data or transmits data, it is likely to continue to be scheduled in the next several subframes. If the user waits until the activation period in the next DRX cycle comes, the user receives data or sends data again, which causes transmission delay. To reduce such delays, the terminal is configured with a Timer drx-Inactivity Timer. The Timer drx-Inactivity Timer is started or restarted whenever the terminal is scheduled to initially transmit data (initial transmission rather than retransmission), and the terminal will remain active, i.e. receive data or transmit data, until the Timer times out. The drx-Inactivity Timer specifies the number of continuous subframes that are continuously in an active state after the terminal successfully decodes the uplink or downlink data indicating initial transmission.

Sidelink data transmission is scheduled on the sidelink by Sidelink Control Information (SCI). In sidelink communication, how to set the time length value of the Timer drx-Inactivity Timer is a technical problem to be solved.

Disclosure of Invention

The embodiment of the application provides a communication method and a communication device, which are used for providing a mode of setting a time length value of a timer in sidelink communication.

In a first aspect, a method of communication is provided, in which a first terminal may receive sidelink control information SCI from a second terminal, the SCI indicating time domain resources of a sidelink. The first terminal may determine a first time value for a first timer; the first time length value may belong to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set includes at least one time length value; alternatively, the first duration value may be determined according to configuration information of discontinuous reception, DRX, of the first terminal and/or a time domain resource indicated by the SCI. Furthermore, the first terminal starts the first timer at a first time, and monitors control information of a sidelink and/or data information of the sidelink in at least one time unit within the first time length value.

A Physical Downlink Control Channel (PDCCH) on the UU port and a Physical Downlink Shared Channel (PDSCH) have a definite time context, the PDCCH is located in the first symbols, the PDSCH is located in the latter symbols, and the first timer is started after the PDCCH. The method and the device make clear the moment when the first terminal starts the first timer on the sidelink, so that the first terminal starts the timer in time and monitors possible or sidelink data transmission during the activation period. SCI and scheduled data information in the sidelink have no explicit time relationship unlike PDCCH and PDSCH on UU port. In addition, it is clear that the first time length value on the sidelink is set according to the received time length value configured for the sidelink, so that the time length in the activation period specifically configured for the sidelink according to the sidelink service can be considered to match the actual service scheduling requirement; or, the first time length value on the sidelink is set according to the time domain position of the time domain resource contained in the SCI, or according to the overlapping condition of the time domain resource contained in the SCI and the duration of the discontinuous reception DRX, so as to ensure that different data transmission resources are flexibly considered, and ensure that the first time length value is in an active state at the time when data transmission is possible or the time when data transmission is reserved, so as to match the actual service scheduling requirement.

In one possible implementation, when the first terminal determines the first duration value of the inactivity timer, the first terminal may determine a duration value from the set of duration values as the first duration value; or, the first terminal may determine the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI; still alternatively, the first terminal may receive the first time length value from the second terminal; still alternatively, the first terminal may receive the first time value from a network device. The second terminal or the network device may determine a duration value from a duration value set as the first duration value and send the first duration value to the first terminal. The second terminal may also determine the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI, and then send the first time length value to the first terminal.

In one possible implementation, the first terminal may include, but is not limited to, at least one of the following when determining the first time value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI: the first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain position of the time domain resource of the sidelink indicated by the SCI; or, the first terminal determines the first time length value according to whether the configuration information of the discontinuous reception of the first terminal and the time domain resource of the sidelink indicated by the SCI are completely overlapped; or, the first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

In a possible implementation, when the first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, the first terminal may determine the first time length value according to an active period of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI.

In a possible implementation, when the first terminal determines the first time value according to the activation period of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, at least one of the following may be included, but is not limited to: the first terminal determines the first time length value according to an activation period of discontinuous reception of the first terminal and/or a time domain position of a time domain resource of a sidelink indicated by the SCI; or, the first terminal determines the first time length value according to whether an activation period of discontinuous reception of the first terminal overlaps with a time domain resource of a sidelink indicated by the SCI; or, the first terminal determines the first time length value according to the activation period of discontinuous reception of the first terminal and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

In one possible implementation, the degree of overlap may include, but is not limited to, any of: the time domain resource is completely located in an activation period of discontinuous reception of the first terminal, or at least first m symbols of the time domain resource are located in the activation period of discontinuous reception of the first terminal, or an overlapping portion of the time domain resource and the activation period of discontinuous reception of the first terminal fails to include at least the first m symbols of the time domain resource.

In one possible implementation, the first time includes, but is not limited to, any of: the starting symbol of the SCI; the next symbol to the starting symbol of the SCI; a termination symbol of the SCI; a next symbol to a termination symbol of the SCI; a starting symbol of a first time domain resource indicated by the SCI; a symbol next to a starting symbol of a first time domain resource indicated by the SCI; a termination symbol of a first time domain resource indicated by the SCI; a symbol next to a termination symbol of the first time domain resource indicated by the SCI. When the SCI received by the first terminal is the first-level SCI, the SCIs described herein at the first time may be replaced with the first-level SCIs.

In one possible implementation, the SCI received by the first terminal may include a first-level SCI and a second-level SCI, and the first time is any one of the following: a start symbol of the first-level SCI or a start symbol of the second-level SCI; a next symbol to the start symbol of the first-level SCI or a next symbol to the start symbol of the second-level SCI; a termination symbol of the first-level SCI or a termination symbol of the second-level SCI; a next symbol of a termination symbol of the first-level SCI or a next symbol of a termination symbol of the second-level SCI; a starting symbol of a first time domain resource indicated by the first-level SCI; a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI; a termination symbol of a first time domain resource indicated by the first-level SCI; a symbol next to a termination symbol of the first time domain resource indicated by the first-level SCI. The SCIs may be further divided into a first-level SCI and a second-level SCI. Therefore, it is necessary to explicitly activate the time relationship between the first timer and the first stage SCI and/or the second stage SCI, and the time relationship between the first time domain resource indicated by the first stage SCI.

In one possible implementation, the configuration information of the discontinuous reception DRX includes, but is not limited to, at least one of: the starting offset of the discontinuous reception DRX, the activation period of the discontinuous reception DRX, the cycle length of the discontinuous reception DRX, the pattern of the discontinuous reception DRX and the pattern index of the discontinuous reception DRX. The active period of discontinuous reception DRX may also be referred to as duration.

In one possible implementation, the SCI indicating time domain resources of the sidelink may include: a first resource set, the first resource set comprising time domain resources of N sidelink, N being a positive integer; or a second resource set is included, the second resource set includes a periodic first resource set, the first resource set includes time domain resources of N sidelink, and N is a positive integer. It is also understood that the second set of resources includes at least two first sets of resources.

In one possible implementation, the first set of resources includes one or more time domain resources. When N is 1, the first set of resources comprises one time domain resource; when N is an integer greater than 1, the first set of resources includes a plurality of time domain resources.

In a possible implementation, when the first duration value is determined according to the configuration information of the discontinuous reception DRX of the first terminal and/or the time domain resource indicated by the SCI, the first duration value may be determined according to a difference between the second time and the third time.

The second time includes, but is not limited to, any of: the starting symbol of the SCI; a symbol next to the starting symbol of the SCI; a termination symbol of the SCI; a next symbol to a termination symbol of the SCI; a starting symbol of a first time domain resource indicated by the SCI; a symbol next to a starting symbol of a first time domain resource indicated by the SCI; a termination symbol of a first time domain resource indicated by the SCI; a symbol next to a termination symbol of the first time domain resource indicated by the SCI. The first time and the second time may be the same or different.

The third time includes, but is not limited to, any of: a starting symbol of an xth time domain resource in a first set of resources indicated by the SCI; a next symbol of a starting symbol of an xth time domain resource in a first set of resources indicated by the SCI; a termination symbol of an xth time domain resource in a first set of resources indicated by the SCI; a next symbol of a termination symbol of an xth time domain resource in the first combination of resources indicated by the SCI; a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the SCI; a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the SCI; a termination symbol for an xth time domain resource in a yth first set of resources in a second set of resources indicated by the SCI; a next symbol of a termination symbol of an xth time domain resource in a yth first set of resources in a second set of resources indicated by the SCI; wherein y is an integer greater than or equal to 1, x is an integer greater than or equal to 1, and x is an integer less than or equal to n.

In one possible implementation, the SCI is a first-level SCI or the SCIs include a first-level SCI and a second-level SCI.

In one possible implementation, when the SCI includes a first-level SCI and a second-level SCI, determining the first duration value according to a difference between the third time and the second time may still be used;

in this case, the second timing is any one of: a start symbol of the first-level SCI or a start symbol of the second-level SCI; a next symbol to the start symbol of the first-level SCI or a next symbol to the start symbol of the second-level SCI; a termination symbol of the first-level SCI or a termination symbol of the second-level SCI; a next symbol of a termination symbol of the first-level SCI or a next symbol of a termination symbol of the second-level SCI; a starting symbol of a first time domain resource indicated by the first-level SCI; a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI; a termination symbol of a first time domain resource indicated by the first-level SCI; a symbol next to a termination symbol of the first time domain resource indicated by the first-level SCI.

In this case, the third time is any one of: a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI; a next symbol of a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI; a termination symbol of an xth time domain resource in a first set of resources indicated by the first-level SCI; a next symbol of a termination symbol of an xth time domain resource in a first resource combination indicated by the first-level SCI; a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI; a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI; a termination symbol of an xth time domain resource in a yth first resource set in a second resource set indicated by the first-level SCI; a next symbol of a termination symbol of an x-th time domain resource in a y-th first resource set in the second resource set indicated by the first-level SCI.

In a possible implementation, when the first time value is determined according to the difference between the third time and the second time, the difference between the third time and the second time may be used as the first time value; or, taking the sum of the difference between the third time and the second time and the first parameter as the first time length value; or, the minimum number of slot slots greater than or equal to the difference between the third time and the second time is taken as the first time length value.

In a possible implementation, the first parameter is a duration of a time domain resource, or an offset.

In a possible implementation, the duration of discontinuous reception associated with one or more duration values in the set of duration values configured for the resource pool, or the cycle length of discontinuous reception; or, the duration of discontinuous reception associated with one or more duration values in the set of duration values configured for the sidelink, or the cycle length of discontinuous reception. The first terminal or the second terminal or the network device may determine the first duration value in the set of duration values according to a duration of discontinuous reception of the first terminal or a cycle length of the discontinuous reception.

In one possible implementation, the first duration value is a non-consecutive duration value, where non-consecutive means that the first duration value matches the corresponding time domain resource.

In a possible implementation, when the first terminal determines a duration value in the duration value set as the first duration value, the first terminal may determine a minimum duration value greater than or equal to a difference between a third time and a second time in the duration value set as the first duration value.

In a second aspect, a method of communication is provided, in which a second terminal sends sidelink control information SCI to a first terminal, the SCI indicating a time domain resource or a plurality of time domain resources.

In a possible implementation, the second terminal sends a first time length value to the first terminal, where the first time length value may belong to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set includes at least one time length value; alternatively, the first duration value may be determined according to configuration information of discontinuous reception, DRX, of the first terminal and/or a time domain resource indicated by the SCI.

In one possible implementation, the second terminal may determine a duration value from the set of duration values as the first duration value; or, the second terminal may determine the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI.

In addition, the process of determining the first duration value by the second terminal according to the drx configuration information of the first terminal and/or the time domain resource indicated by the SCI is the same as the process of determining the first duration value according to the drx configuration information of the first terminal and/or the time domain resource indicated by the SCI described in the possible implementation of the first aspect, and is not repeated here.

In a third aspect, there is provided an apparatus for communication having functionality to implement the first aspect and any possible implementation of the first aspect. These functions may be implemented by hardware, or by hardware executing corresponding software. The hardware or software includes one or more functional modules corresponding to the above functions.

In a fourth aspect, there is provided an apparatus for communicating having the functionality of any one of the possible implementations of the second aspect and the second aspect. These functions may be implemented by hardware, or by hardware executing corresponding software. The hardware or software includes one or more functional modules corresponding to the above functions.

In a fifth aspect, a communication device is provided, which may be the first terminal in the above method embodiment, or a chip disposed in the first terminal. The device comprises a transceiver, a processor and optionally a memory. Wherein the memory is adapted to store a computer program or instructions, and the processor is coupled to the memory and the transceiver, respectively, and when the processor executes the computer program or instructions, the apparatus is adapted to perform the method performed by the first terminal in any of the above-mentioned first aspect and possible implementations of the first aspect via the transceiver.

In a sixth aspect, there is provided a communication device, which may be the second terminal in the above method embodiment, or a chip disposed in the second terminal. The device comprises a transceiver, a processor and optionally a memory. Wherein the memory is adapted to store a computer program or instructions, and the processor is coupled to the memory and the transceiver, respectively, and when the processor executes the computer program or instructions, the apparatus is adapted to perform the method performed by the second terminal in any of the above-mentioned second aspect and possible implementations of the second aspect via the transceiver.

In a seventh aspect, a computer program product is provided, the computer program product comprising: computer program code for causing a computer to perform the method performed by the first terminal in any of the above described first aspect and possible implementations of the first aspect when said computer program code is run on a computer.

In an eighth aspect, there is provided a computer program product comprising: computer program code for causing a computer to perform the method performed by the second terminal in any of the above described second aspect and possible implementations of the second aspect, when said computer program code is run on a computer.

In a ninth aspect, the present application provides a chip system, which includes a processor and a memory, wherein the processor and the memory are electrically coupled; the memory to store computer program instructions; the processor is configured to execute part or all of the computer program instructions in the memory, and when the part or all of the computer program instructions are executed, the processor is configured to implement the functions of the first terminal in the method according to any one of the foregoing first aspect and the first possible implementation of the first aspect.

In one possible design, the chip system may further include a transceiver configured to transmit a signal processed by the processor or receive a signal input to the processor. The chip system may be formed by a chip, or may include a chip and other discrete devices.

In a tenth aspect, the present application provides a chip system, which includes a processor and a memory, wherein the processor and the memory are electrically coupled; the memory to store computer program instructions; the processor is configured to execute part or all of the computer program instructions in the memory, and when the part or all of the computer program instructions are executed, the processor is configured to implement the functions of the second terminal in the method according to any one of the second aspect and the possible implementation of the second aspect.

In one possible design, the chip system may further include a transceiver configured to transmit a signal processed by the processor or receive a signal input to the processor. The chip system may be formed by a chip, or may include a chip and other discrete devices.

In an eleventh aspect, a computer-readable storage medium is provided, which stores a computer program, and when the computer program is executed, the method performed by the first terminal in any of the above-mentioned first aspect and the first possible implementation is performed.

In a twelfth aspect, a computer-readable storage medium is provided, which stores a computer program that, when executed, performs the method performed by the second terminal in any of the above-mentioned second aspect and possible implementations of the second aspect.

In a thirteenth aspect, a system for communication is provided, the system comprising: a first terminal for performing the method of any of the above first aspect and possible implementations of the first aspect, and a second terminal for performing the method of any of the above second aspect and possible implementations of the second aspect.

Optionally, the communication system further comprises a network device for performing the method in any possible implementation of the above aspects and aspects.

Drawings

Fig. 1a is a schematic diagram of a DRX cycle provided in an embodiment of the present application;

fig. 1b is a schematic diagram illustrating a comparison between a short DRX cycle and a long DRX cycle provided in the embodiment of the present application;

fig. 1c is a schematic diagram of a communication system architecture provided in an embodiment of the present application;

fig. 2 is a schematic diagram of a time domain resource indicated by an SCI according to an embodiment of the present disclosure;

fig. 3 is a schematic process diagram of a communication provided in an embodiment of the present application;

FIG. 4a is a diagram illustrating a comparison between a time domain resource of an SCI and a first time domain resource provided in an embodiment of the present application;

fig. 4b is a schematic diagram illustrating a comparison between a time domain resource of an SCI and a first time domain resource according to an embodiment of the present disclosure;

fig. 5a is a schematic time domain resource diagram of a two-level SCI according to an embodiment of the present disclosure;

fig. 5b is a schematic time domain resource diagram of a two-level SCI according to an embodiment of the present disclosure;

fig. 5c is a schematic time domain resource diagram of a two-stage SCI according to an embodiment of the present disclosure;

fig. 6a is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 6b is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 6c is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 6d is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 6e is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 6f is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 7a is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 7b is a schematic diagram illustrating comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 7c is a diagram illustrating a comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 7d is a diagram illustrating a comparison between time domain resources indicated by SCI and DRX according to an embodiment of the present disclosure;

fig. 8 is a diagram of a communication apparatus according to an embodiment of the present application;

fig. 9 is a diagram illustrating a structure of a communication apparatus according to an embodiment of the present application.

Detailed Description

The embodiments of the present application will be described in detail below with reference to the accompanying drawings.

In order to facilitate understanding of the embodiments of the present application, some terms of the embodiments of the present application are explained below to facilitate understanding by those skilled in the art.

A terminal, also referred to as User Equipment (UE), a Mobile Station (MS), a Mobile Terminal (MT), etc., is a device that provides voice and/or data connectivity to a user. For example, the terminal device includes a handheld device, an in-vehicle device, an internet of things device, and the like having a wireless connection function. Currently, the terminal device may be: a mobile phone (mobile phone), a tablet computer, a notebook computer, a palm top computer, a Mobile Internet Device (MID), a wearable device, a Virtual Reality (VR) device, an Augmented Reality (AR) device, a wireless terminal in industrial control (industrial control), a wireless terminal in self driving (self driving), a wireless terminal in remote surgery (remote medical supply), a wireless terminal in smart grid (smart grid), a wireless terminal in transportation safety (smart security), a wireless terminal in city (smart city), a wireless terminal in smart home (smart home), and the like. Flying devices (e.g., smart robots, hot air balloons, drones, airplanes), and the like. In the embodiment of the present application, the apparatuses for implementing the above functions are introduced by taking a terminal as an example.

It should be understood that the terminal in the embodiment of the present application may also refer to a chip in the terminal, a communication device, a unit or a module having a communication function between terminals, and the like, such as an in-vehicle communication device, an in-vehicle communication module, an in-vehicle communication chip, or the like.

"and/or" in the present application, describing an association relationship of associated objects, means that there may be three relationships, for example, a and/or B, may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.

The plural in the present application means two or more.

In the description of the present application, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance, nor order.

In addition, in the embodiments of the present application, the word "exemplary" is used to mean serving as an example, instance, or illustration. Any embodiment or implementation described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments or implementations. Rather, the term using examples is intended to present concepts in a concrete fashion.

In the present application, the value of greater than or equal to may also be referred to as greater than or equal to. The value of less than or equal to may also be referred to as less than or equal to.

The technical scheme of the embodiment of the application can be applied to various communication systems, for example: long Term Evolution (LTE) systems, Worldwide Interoperability for Microwave Access (WiMAX) communication systems, fifth Generation (5th Generation, 5G) systems, such as new radio access technology (NR), and future communication systems.

For convenience of understanding of the embodiment of the present application, an application scenario of the present application is introduced next, and the service scenario described in the embodiment of the present application is for more clearly explaining the technical solution of the embodiment of the present application, and does not constitute a limitation to the technical solution provided in the embodiment of the present application.

The technical scheme provided by the application can be applied to a device to device (D2D) scene, and optionally can be applied to a vehicle to electronic (V2X) scene. For example, D2D may be D2D in a Long Term Evolution (LTE) communication system, D2D in a New Radio (NR) communication system, or D2D in other communication systems that may appear as technologies develop. Similarly, V2X may be LTE V2X, or NR V2X, or V2X in other communication systems that may appear as technology develops. In the V2X communication architecture, data can be transmitted directly from terminal to terminal through SL.

Illustratively, the V2X scenario may be embodied as any of the following systems: vehicle to vehicle communication (V2V), vehicle to vehicle communication (V2P), vehicle to network (V2N) traffic and vehicle to infrastructure communication (V2I), and so on.

Wherein one participant of V2N is a terminal device and the other participant is a service entity. V2N is the most widely used form of car networking, and its main function is to connect the vehicle to the cloud server through the mobile network, so as to provide navigation, entertainment, anti-theft functions through the cloud server.

Both participants of V2V are terminal devices. V2V may be used as an inter-vehicle information interaction reminder, the most typical application being for inter-vehicle collision avoidance safety systems.

Both participants of V2P are terminal devices. V2P may be used to provide safety warnings to pedestrians or non-motor vehicles on the road.

One participant in V2I is a terminal device and the other participant is an infrastructure (or infrastructure). V2I may be used for vehicle-to-infrastructure communications, e.g., where the infrastructure may be roads, traffic lights, roadblocks, etc., where road management information such as timing of traffic light signals may be obtained.

In the inter-device communication D2D communication, a sidelink resource is a resource used for communication between a terminal device and a terminal device. The sidelink resources may include sidelink resources in the frequency domain and sidelink resources in the time domain.

DRX mechanism

In Uu port communication between a terminal device and a network device, a DRX mechanism is introduced to save power for the terminal device. The DRX mechanism configures one DRX cycle for a terminal device in a Radio Resource Control (RRC) connected state. As shown in fig. 1a, the DRX cycle consists of "On Duration (awake period or awake time or active period or Duration)" and "Opportunity for DRX (sleep period or sleep time)". In the time of the 'On Duration', the terminal equipment monitors and receives a Physical Downlink Control Channel (PDCCH); during the "Opportunity for DRX" time, the terminal device does not receive data of the PDCCH to save power consumption.

For a DRX Cycle, time is divided into successive DRX cycles (cycles) in the time domain. drxStartOffset specifies the starting subframe of the DRX Cycle, long DRX Cycle specifies how many subframes a long DRX Cycle takes, both parameters being specified by the long DRX-Cycle startoffset field. The timer onDurationTimer specifies the number of consecutive subframes (i.e., the number of subframes for which the active period lasts) that need to monitor the PDCCH from the start subframe of the DRX cycle.

In general, when a terminal device is scheduled and receives or transmits data in a certain subframe, it is likely to continue to be scheduled in the next several subframes, and if it is to wait for the next DRX cycle to receive or transmit the data, it will cause extra delay. Therefore, in order to reduce such delay, the terminal device may stay in the active period after being scheduled, that is, may continuously monitor the PDCCH during the configured active period. The realization mechanism is as follows: whenever the terminal device is scheduled to initially transmit data, a DRX inactivity timer (DRX inactivity timer) is started (or restarted or enabled), and the terminal device will remain in an active state until the timer times out. The drxinactivtytimer specifies the number of consecutive subframes that are continuously in an active state after the terminal device successfully decodes a PDCCH indicating Uplink (UL) or Downlink (DL) user data of an initial transmission. I.e. the timer is restarted once each time the terminal device has the initial transmission data scheduled. It should be noted that here, the initial transmission is not the retransmission. Initial transmission, which refers to the first transmission of a Transport Block (TB); retransmission, refers to every retransmission of the same transport block after the first transmission.

In the present application, the on duration in the DRX cycle belongs to the active period, and the working period of the timer after the drxinactivtytimer is started also belongs to the active period.

The choice of DRX cycle involves a balance between battery savings and latency. In one aspect, a long DRX cycle is beneficial for extending battery life of the terminal device; for example, when a user is reading a downloaded web page, resources are wasted if the terminal device continues to receive downlink data at this time. On the other hand, a shorter DRX cycle facilitates faster response when there is a new data transmission; for example, the terminal device requests another web page or voice over internet protocol (VoIP). To meet the above requirements, each terminal device may configure two DRX cycles: short DRX Cycle (short DRX Cycle) and long DRX Cycle (long DRX Cycle), as shown in fig. 1b, which is a diagram comparing the short DRX Cycle and the long DRX Cycle.

In the embodiment of the present application, a DRX mode (DRX mode) includes an active period and a sleep period, and may specify a starting subframe of the DRX mode by drxStartOffset, specify how many subframes the DRX mode occupies by a DRX Cycle, and specify the number of consecutive subframes that need to monitor the PDCCH (i.e., the number of subframes for which the active period lasts) from the starting subframe of the DRX mode by onDurationTimer. The DRX mode in the embodiment of the present application may also be referred to as a DRX pattern (DRX pattern), a DRX cycle (DRX cycle), a DRX cycle set (DRX cycle set), a DRX index (DRX index), a DRX identifier, or DRX.

Sidelink resource (or called sidelink resource)

In the embodiment of the present application, the sidelink resource may also be referred to as a resource for short, or a transmission resource. In this application, the sidelink may also be referred to as a side link, or a sidelink, or a PC5 interface link, or an inter-terminal device link. In this application, a transmission block may also be referred to as a data packet. In the present application, the value of greater than or equal to may also be referred to as greater than or equal to; the value of less than or equal to may also be referred to as less than or equal to.

In D2D communication, a sidelink resource is a resource used for communication between a terminal device and a terminal device. The sidelink resources may include sidelink resources in the frequency domain and sidelink resources in the time domain. The main discussion of the present application is related to the time domain sidelink resource in the sidelink resource, and the sidelink resources appearing subsequently may all refer to the time domain sidelink resource, which is described in a unified way herein. The sidelink resources in the time domain may also be referred to as sidelink time domain resources.

From a transmission type perspective, the sidelink resources may include sidelink transmission resources and sidelink reception resources. The sidelink transmission resource is used for transmitting information, such as sidelink control information and/or sidelink data information. The sidelink reception resources are used for receiving information, such as sidelink control information and/or sidelink data information.

Currently, there are two methods for selecting sidelink resources, the first is to allocate resources for sidelink by a network device, and the second is to select reserved sidelink resources from idle resources by a terminal device at a transmitting end, and send Sidelink Control Information (SCI) to a terminal device at a receiving end, where the SCI carries information for indicating the reserved sidelink resources. Wherein, each time an SCI is sent, time domain resources (N is a positive integer) of at most N sidelink can be reserved, and the time domain resources of the sidelink reserved in the same SCI are used for transmitting the same data packet or the same transmission block; or, the time domain resources of the sidelink reserved in the same SCI may also be a first time domain resource to an xth time domain resource for transmitting a data packet or a transmission block, and an xth +1 time domain resource to an nth time domain resource for transmitting another data packet or another transmission block, where X is a positive integer greater than or equal to 1 and less than or equal to N, and so on, and is not enumerated one by one. Optionally, N is 1 or any integer greater than 1. Optionally, the SCI may further carry a period value, and the N time domain resources reserved in one SCI may be repeatedly reserved by the period value. It should be noted that the time domain resources of the sidelink reserved in different periods are used for transmitting different transport blocks. For example, as shown in fig. 2, N time domain resources in the first period are used for transmitting transport block 1, N time domain resources in the second period are used for transmitting transport block 2, N time domain resources in the third period are used for transmitting transport block 3, and so on.

With regard to the reserved sidelink resources, there are three reserved sidelink resources in each period, the sidelink resource reserved in the first period is used for transmitting transport block 1(TB1), and the sidelink resource reserved in the second period is used for transmitting transport block 2(TB 2). It should be noted that all sidelink resource requirements reserved in each period are limited to a time window, that is, the reserved sidelink resource cannot exceed the time window, as shown in fig. 2.

In this application, a subframe may also be replaced by a slot (slot) or a mini slot, without limitation.

In this application, all "configured" may be that the network device is configured to the first terminal through RRC signaling or Media Access Control (MAC) signaling. Wherein the RRC signaling may be broadcast signaling, signaling common to a group of UEs or dedicated (dedicated) signaling, etc.

Optionally, in this application, one time domain resource may be one slot or multiple slots.

In this application, the resources of the sidelink may also be referred to as reserved resources of the sidelink or allocated resources of the sidelink. The resource may be a time domain resource or a frequency domain resource. The N time domain resources included in the first resource set are reserved transmission resources for the same transmission block or different transmission blocks. The periodic first set of resources comprised in the second set of resources are reserved transmission resources for different transport blocks.

As shown in fig. 1c, on the sidelink, the terminals may transmit the service data in a unicast, multicast or broadcast manner. Traffic has certain characteristics and may be periodic or aperiodic, for example. There may also be differences in the demands of the traffic data on resources. For example, for a periodic service, a time domain resource needs to be periodically reserved for data transmission; for aperiodic traffic, the time domain resources do not need to be reserved periodically. In this application, a time domain resource may also be referred to as a time domain resource location, or a time domain resource of a resource block, a time domain location of a resource block, a time domain resource location of a resource block, or the like.

The time domain resource may be a periodic or aperiodic time domain resource. For example, when the time domain resource is a non-periodic time domain resource, the time domain resource can be represented as a first resource set, the first resource set includes N time domain resources, and N is an integer greater than or equal to 1. Taking N-3 as an example, the first resource set includes 3 time domain resources. For another example, when the time domain resource is a periodic time domain resource, the time domain resource may be represented as a second resource set, the second resource set includes a periodic first resource set, the first resource set includes N time domain resources, and N is an integer greater than or equal to 1. The second set of resources includes the periodic first set of resources, which may also be referred to as a second set of resources including at least two first sets of resources, where the at least two first sets of resources are periodic. Taking N-3 as an example, the second resource set includes multiple periods of time domain resources and each period includes 3 time domain resources, or it is understood that the time domain resources in the second resource set are periodically configured according to every 3 time domain resources.

As an implementation method, the terminal device on the transmitting side may transmit an SCI to the terminal device on the receiving side, where the SCI at least includes N time domain resources and a resource reservation period value T, and N is a positive integer.

Two examples of terminal sending sidelink control information SCI for time domain resource reservation are introduced below:

in the first case, the resource reservation period value T is 0, which indicates that the time domain resources are aperiodic, that is, only N time domain resources are reserved, and the first set of resources may be used to represent the reserved N time domain resources. The N time domain resources here can be understood as the maximum number of resources (maxNumResource), and the N value can be a parameter configured by a higher layer, which is less than or equal to the maximum value Nmax. When N is greater than or equal to 3, the time intervals between any two adjacent time domain resources may be the same or different. As shown in fig. 2, t1 and t2 may be the same or different. The time domain lengths of the plurality of time domain resources may be the same or different.

In the second case, the resource reservation period value T is greater than 0, indicating that the time domain resource is periodically repeated. That is, multiple time domain resources of N are reserved, and the second resource set may represent the multiple time domain resources of N that are reserved. It is to be understood that the second set of resources comprises a periodic first set of resources comprising N time domain resources, N being an integer greater than or equal to 1. It can also be understood that N time domain resources periodically circulate according to the resource reservation period T, where N is a positive integer. The periodic cycle may also be referred to as a periodic repetition, a periodic period, or a periodic occurrence. In this application, "periodic" may be interchanged with "periodic".

In yet another description: the SCI indicates a set of time domain resources reserved according to a resource reservation period T, the set of reserved time domain resources including the N time domain resources. Which may also be referred to as: and the N time domain resources periodically circulate according to the resource reservation period T. The periodic cycle, which may also be referred to as periodic repetition, periodic reservation, occurs in sequence. The period T is a reserved resource period (resource reservation period) value indicated in the SCI. For example, m sets of time domain resources may be reserved according to the resource reservation period T, where m is an integer greater than or equal to 2. m may also be referred to as the number of periods.

The difference between the second case and the first case is: in addition to reserving the N time domain resources, after T is separated, there is a reserved time domain resource set (a first resource set) which includes N time domain resources; after 2T, there is another reserved time domain resource set (the first resource set), which contains N time domain resources, and so on.

"according" in this application may also be replaced by "based on". That is, the terminal device on the receiving side may instead be based on the acquired time domain resource according to the acquired time domain resource.

As shown in fig. 2, the SCI indicates that the first set of resources includes 3 time domain resources, and the first set of resources is periodically reserved multiple times according to a resource reservation period T. The time interval t1 between the first time domain resource and the second time domain resource in the 3 time domain resources may be the same as or different from the time interval t2 between the second time domain resource and the third time domain resource. The interval may be based on the starting point of each time domain resource, i.e., t1 is obtained by subtracting the starting point of the first time domain resource from the starting point of the second time domain resource, and t2 is obtained by subtracting the starting point of the second time domain resource from the starting point of the third time domain resource. The interval may also be obtained based on the termination point of each time domain resource, i.e. t1 is obtained by subtracting the termination point of the first time domain resource from the termination point of the second time domain resource, and t2 is obtained by subtracting the termination point of the second time domain resource from the termination point of the third time domain resource.

Next, a setting manner of a time length value of a Timer (drx-Inactivity Timer) for a reservation manner of time domain resources on a sidelink is described to match an actual service scheduling requirement.

As shown in fig. 3, a schematic diagram of a communication process is provided, which specifically includes the following steps:

step 301: the second terminal sends SCI to the first terminal, and the first terminal receives sidelink control information SCI from the second terminal, wherein the SCI indicates time domain resources of the sidelink.

In this application, the SCI indicates a time domain resource of a sidelink, which may also be referred to as the SCI indicating a reserved time domain resource of a sidelink, or as the SCI indicating one or more time domain resources of a sidelink. Wherein, the time domain resource of the sidelink indicated by the SCI can be used to transmit control information of the sidelink and/or data information of the sidelink. The SCI indicates a time domain resource of the sidelink, and the specific meaning is as follows: the first time domain resource is the time domain resource scheduled by the current SCI, and the time domain resource behind the first time domain resource is the reserved time domain resource.

And the time domain resource of the sidelink indicated by the SCI is the time domain resource reserved by the second terminal for the first terminal. The time domain resource of the sidelink indicated by the SCI may refer to the aforementioned time domain resource reservation method, and is not repeated here.

The SCI indicates the transmission of data for a new sidelink, which may also be referred to as the SCI indicating the initial transmission, rather than the retransmission, of data.

Step 302: the first terminal determines a first time value of a first timer.

The first timer may also be referred to as an inactivity timer, or a timer configured for a sidelink, or an inactivity timer configured for a sidelink, or a DRX inactivity timer configured for a sidelink.

In one example, the first duration value belongs to a duration value set configured for a resource pool or a duration value set configured for a sidelink, and the duration value set includes at least one duration value. The set of duration values configured for a resource pool may also be referred to as a corresponding (or corresponding) set of duration values for the resource pool. Optionally, when the first terminal has a plurality of resource pools, each resource pool has a corresponding set of duration values. For example, the first terminal has two resource pools, the first resource pool has a corresponding first set of duration values, and the second resource pool has a corresponding second set of duration values. The set of duration values configured for the sidelink may also be referred to as a corresponding (or corresponding) set of duration values for the sidelink. The configured time length value set for the resource pool or the configured time length value set for the sidelink may be configured to the first terminal by the network device through RRC signaling or Media Access Control (MAC) signaling. Wherein the RRC signaling may be broadcast signaling, signaling common to a group of UEs or dedicated (dedicated) signaling, etc.

In another example, the first duration value is determined according to configuration information of Discontinuous Reception (DRX) of the first terminal and/or a time domain resource indicated by the SCI.

Next, various ways of determining the first duration value of the inactivity timer by the first terminal are described.

In one possible approach: the first terminal determines ("determines" or may be referred to as selecting) a duration value from the set of duration values as the first duration value.

In yet another possible approach: and the first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI.

In yet another possible approach: the first terminal receives the first time value from the second terminal ("receives" from the second terminal, which may also be referred to as the second terminal configuration). The first time length value may be carried in the SCI in step 301, or may be sent by the second terminal to the first terminal through other signaling. Wherein the first duration value may be a corresponding duration value index/identifier in the duration value set configured by RRC signaling. The second terminal may determine (determine, which may also be referred to as selecting) a duration value from the set of duration values as the first duration value to send to the first terminal. Or, the second terminal determines the first time length value according to the configuration information of the discontinuous reception of the first terminal/the second terminal and/or the time domain resource indicated by the SCI and then sends the first time length value to the first terminal.

In yet another possible approach: the first terminal receives the first time length value from a network device. Sent by RRC signaling. The network device may determine (determine, which may also be referred to as selecting) a duration value from the set of duration values as the first duration value to send to the first terminal.

The configuration information of the discontinuous reception includes at least one of a start offset (start offset), an activation period (on duration), a cycle length (cycle length), a pattern (pattern) or a pattern index (pattern index) of the discontinuous reception. The activation period may also be referred to as an activation duration, or activation time, or activation period, or duration.

The configuration information of the discontinuous reception of the first terminal may be configured by the second terminal or the network device to the first terminal, or determined by the first terminal itself.

The first terminal or the second terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI, and the first time length value comprises at least one of the following items:

the first terminal determines the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain position of the time domain resource indicated by the SCI; alternatively, the first and second electrodes may be,

the first terminal determines the first time length value according to whether the configuration information of discontinuous reception of the first terminal is overlapped with the time domain resource indicated by the SCI; alternatively, the first and second electrodes may be,

and the first terminal determines the first time length value according to the configuration information of the discontinuous reception of the first terminal and the overlapping degree of the time domain resources indicated by the SCI.

Optionally, the determining, by the first terminal, the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI includes:

the first terminal determines the first time value according to an activation period of discontinuous reception (duration of discontinuous reception) of the first terminal and/or a time domain resource of a sidelink indicated by the SCI.

Optionally, the first terminal determines the first time value according to the duration of discontinuous reception of the first terminal and/or the time domain position of the time domain resource indicated by the SCI; alternatively, the first and second electrodes may be,

the first terminal determines the first time value according to whether the discontinuous reception duration of the first terminal and the time domain resource indicated by the SCI are overlapped; alternatively, the first and second electrodes may be,

and the first terminal determines the first time length value according to the discontinuous reception duration of the first terminal and the overlapping degree of the time domain resources indicated by the SCI.

The specific process is described later with reference to fig. 6a to 7 d.

When the first time value of the first timer belongs to the set of time values configured for the resource pool or the set of time values configured for the sidelink, the order of the step 302 and the step 301 is not limited.

Step 303: the first terminal starts the first timer at a first time, and monitors (or detects, or receives) the control information of the sidelink and/or the data information of the sidelink in at least one time unit within the first time length value.

The sequence of step 303 and step 302 is not limited.

The time unit is at least one of a slot (slot), a symbol (symbol), a mini slot, or a mini symbol. The at least one time unit may be one or more symbols, or one or more slots, or a combination of one or more slots and one or more symbols.

The first time domain resource in this application refers to the first of the time domain resources indicated by the currently detected SCI. The currently detected SCI is also located in the first time domain resource.

And the first terminal stops the first timer when determining that the first timer exceeds the first time length value. It should be noted that "listen" is a state and may not receive, unlike "receive" in the present application. The first terminal restarts or starts the timer after it has monitored an SCI. Wherein the SCI indicates that the first terminal needs to perform data reception. The time unit includes, but is not limited to, at least one of a subframe, slot, mini-slot, or symbol. In the present application, a time (timing/moment/epoch) may also be referred to as a time position or a time domain position.

It should be noted that: the time domain resource occupied by the active period is far greater than the time domain resource occupied by the SCI, if the first terminal monitors an SCI in the active period, the active period at least includes the monitored time domain resource (symbol position) occupied by the SCI, and the situation that the first terminal starts to be in the sleep period when monitoring the next symbol of the starting symbol of the SCI, so that the SCI cannot be received is avoided. It can also be understood that if the SCI is located in the first m symbols of a slot, then at least m symbols of a reserved resource are located within the DRX on duration, thereby ensuring that the SCI can be correctly detected.

Next, an example of the first time will be described by taking fig. 4a and 4b as an example. The first time includes, but is not limited to, any of:

the starting symbol of the SCI. In this application, the start symbol of the SCI may be a start point of the start symbol of the SCI or an end point of the start symbol of the SCI. The starting symbol of the SCI may also be referred to as the SCI start, or the moment when the first terminal receives the SCI start, or the first terminal receives the SCI start.

The next symbol to the starting symbol of the SCI. In this application, the next symbol of the start symbol of the SCI may be a start point of the next symbol of the start symbol of the SCI or an end point of the next symbol of the start symbol of the SCI. The end point of the start symbol of the SCI and the start point of the next symbol of the start symbol of the SCI may be at the same time. The next symbol of the starting symbol of the SCI may also be referred to as the time after the first terminal receives the starting symbol of the SCI, or as the time when the first terminal receives the ending symbol of the SCI.

A termination symbol of the SCI. In this application, the end symbol of the SCI may be a start point of the end symbol of the SCI or an end point of the end symbol of the SCI. The termination symbol of the SCI may also be referred to as the SCI end, or the end of the SCI received by the first terminal, or the end time or termination time of the SCI received by the first terminal.

The next symbol of the termination symbol of the SCI. In this application, the next symbol of the end symbol of the SCI may be a start point of the next symbol of the end symbol of the SCI or an end point of the next symbol of the end symbol of the SCI. The end point of the end symbol of the SCI and the start point of the next symbol of the end symbol of the SCI may be at the same time. The next symbol of the termination symbol of the SCI may also be referred to as after the first terminal receives the termination symbol of the SCI, or as a termination time at which the first terminal receives the termination symbol of the SCI.

A starting symbol of a first time domain resource indicated by the SCI. In this application, the starting symbol of the first time domain resource indicated by the SCI may be a starting point of the starting symbol of the first time domain resource indicated by the SCI, or a terminating point of the starting symbol of the first time domain resource indicated by the SCI.

The starting symbol of the first time domain resource indicated by the SCI may be the same as the starting symbol of the SCI, or the starting symbol of the first time domain resource indicated by the SCI may be earlier than the starting symbol of the SCI in consideration of the number of symbols required for Automatic Gain Control (AGC). Optionally, the starting symbol of the SCI may be the starting symbol of the first time domain resource indicated by the SCI plus the number of AGC symbols.

A symbol next to a starting symbol of the first time domain resource indicated by the SCI. In this application, the next symbol of the starting symbol of the first time domain resource indicated by the SCI may be a starting point of the next symbol of the starting symbol of the first time domain resource indicated by the SCI, or a terminating point of the next symbol of the starting symbol of the first time domain resource indicated by the SCI. The end point of the start symbol of the first time domain resource may be at the same time as the start point of the next symbol of the start symbol of the first time domain resource.

A termination symbol of a first time domain resource indicated by the SCI. In this application, the end symbol of the first time domain resource indicated by the SCI may be a start point of the end symbol of the first time domain resource indicated by the SCI, or a stop point of the end symbol of the first time domain resource indicated by the SCI.

A symbol next to a termination symbol of the first time domain resource indicated by the SCI. In this application, the next symbol of the end symbol of the first time domain resource indicated by the SCI may be a starting point of the next symbol of the end symbol of the first time domain resource indicated by the SCI, or a stopping point of the next symbol of the end symbol of the first time domain resource indicated by the SCI. The end point of the end symbol of the first time domain resource may be at the same time as the start point of the next symbol of the end symbol of the first time domain resource.

The SCIs mentioned above are all SCIs in step 301.

In this application, "start symbol of time domain resource" may also be referred to as "start of time domain resource" or "start time of time domain resource", "end symbol of time domain resource" may also be referred to as "end of time domain resource" or "end time of time domain resource", and "start point of symbol" may also be referred to as "start time of symbol", or "start of symbol". The "end point of a symbol" may also be referred to as "end time of the symbol" or as "end of the symbol". The "next symbol after symbol" may also be referred to as the "next symbol after symbol", or as the "first symbol after symbol". The next symbol, e.g., the terminating symbol, may also be referred to as the next symbol after the terminating symbol, or the first symbol after the terminating symbol.

It should be noted that in the example of fig. 4a, the starting symbol of the SCI is the same time as the starting symbol of the first time domain resource indicated by the SCI. In the example of fig. 4b, the starting symbol of the SCI is not the same time as the starting symbol of the first time domain resource indicated by the SCI, and 1 symbol is required for Automatic Gain Control (AGC). Fig. 4a and fig. 4b both illustrate the example that SCI occupies 3 symbols and the first time domain resource occupies 14 symbols, and in practical application, the number of the symbols occupied by SCI and the number of the symbols occupied by the first time domain resource are not limited. In practice, the first time domain resource may occupy 14 or 12 symbols. In both fig. 4a and fig. 4b, the starting point of the symbol is taken as an example for explanation.

In this application, the terminal device starts or restarts the first timer, referring to the currently detected SCI. That is, each time an SCI is detected, it is determined whether to start or restart the first timer. The first time domain resource is therefore the first of the time domain resources indicated by the currently detected SCI. The SCI is located within the first time domain resource. The first time domain resource may also be referred to as a time domain resource scheduled by the currently detected SCI.

If the first time is before the termination point of the stop symbol of the SCI in step 301, the first terminal may listen to the information in the SCI in step 301 and possibly another SCI different from the SCI in step 301 for the first duration value. If the first time is at or after the termination point of the termination symbol of the SCI in step 301, the first terminal may hear another SCI different from the SCI in step 301 within the first duration value. The SCI received by the first terminal in step 301 may be referred to as a first SCI and another SCI different from the SCI in step 301 may be referred to as a second SCI. The "said SCI" described in the following examples can be regarded as the first SCI.

The following is a detailed description: the procedure of determining the first duration value according to the time domain resource of the DRX discontinuous reception active period of the first terminal and/or the time domain resource indicated by the SCI, which is described in step 302. The first terminal and the second terminal may both be determined as follows.

In an example, a first time length value may be determined according to a second time and a third time, specifically, a difference between the third time and the second time may be used as the first time length value, or a sum of the difference and a first parameter may be used as the first time length value, where the first parameter is a length of one time domain resource or one offset. The second time may be the same as or different from the first time. The minimum number of slot slots greater than or equal to the difference between the third time and the second time may also be used as the first time length value. That is, the difference between the third time and the second time is rounded up to obtain the first time length value. That is, the first time length value includes an integer number of slots, and the difference value is rounded up to obtain the first time length value expressed according to the number of slots. For example, when the difference between the third time and the second time is 2.5 slots, the first time value is determined to be 3 slots.

Next, an example of the second time and the third time is described, and it should be noted that, in the following example for the second time and the third time, the "start symbol" may be a start point or an end point of the start symbol; an "end symbol" may be a starting point or an end point of an end symbol; the "next symbol" may be a starting point or an ending point of the next symbol; the starting symbol of the SCI may also be referred to as the SCI start, or the first terminal receives the SCI start; and the end symbol of the SCI may also be referred to as the SCI end, or the first terminal receives the SCI end, etc., all similar to the above example describing the first time instant.

Exemplary, second time instants include, but are not limited to, any of:

the starting symbol of the SCI; such as the start point of the SCI start symbol or the end point of the SCI start symbol.

A symbol next to the starting symbol of the SCI; such as the start point of the next symbol of the start symbol of the SCI or the end point of the next symbol of the start symbol of the SCI.

A termination symbol of the SCI; such as the start point of the end symbol of the SCI or the end point of the end symbol of the SCI.

A next symbol to a termination symbol of the SCI; such as the start point of the next symbol of the end symbol of the SCI or the end point of the next symbol of the end symbol of the SCI.

A starting symbol of a first time domain resource indicated by the SCI; for example, a start point of a start symbol of the first time domain resource indicated by the SCI, or an end point of the start symbol of the first time domain resource indicated by the SCI.

A symbol next to a starting symbol of a first time domain resource indicated by the SCI; for example, a starting point of a next symbol to a starting symbol of the first time domain resource indicated by the SCI, or an ending point of a next symbol to a starting symbol of the first time domain resource indicated by the SCI.

A termination symbol of a first time domain resource indicated by the SCI; for example, a starting point of a termination symbol of the first time domain resource indicated by the SCI, or a termination point of a termination symbol of the first time domain resource indicated by the SCI.

A symbol next to a termination symbol of the first time domain resource indicated by the SCI. For example, a starting point of a next symbol of a termination symbol of the first time domain resource indicated by the SCI, or a terminating point of a next symbol of a start symbol of the first time domain resource indicated by the SCI.

For example, the third time includes, but is not limited to, any of:

a starting symbol of an xth time domain resource in a first set of resources indicated by the SCI; for example, a starting point of a starting symbol of an x-th time domain resource in the first set of resources indicated by the SCI, or a terminating point of a starting symbol of an x-th time domain resource in the first set of resources indicated by the SCI.

A next symbol of a starting symbol of an xth time domain resource in a first set of resources indicated by the SCI; for example, a starting point of a next symbol of a starting symbol of an x-th time domain resource in the first set of resources indicated by the SCI, or a terminating point of a next symbol of a starting symbol of an x-th time domain resource in the first set of resources indicated by the SCI.

A termination symbol of an xth time domain resource in a first set of resources indicated by the SCI; for example, a starting point of a termination symbol of an x-th time domain resource in the first set of resources indicated by the SCI, or a termination point of a termination symbol of an x-th time domain resource in the first set of resources indicated by the SCI.

A next symbol of a termination symbol of an xth time domain resource in a first set of resources indicated by the SCI; for example, a starting point of a next symbol of a termination symbol of an x-th time domain resource in the first set of resources indicated by the SCI, or a terminating point of a next symbol of a termination symbol of an x-th time domain resource in the first set of resources indicated by the SCI.

A starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the SCI; for example, a starting point of a starting symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI, or a terminating point of a starting symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI.

A next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the SCI; for example, a starting point of a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI, or a terminating point of a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI.

A termination symbol for an xth time domain resource in a yth first set of resources in a second set of resources indicated by the SCI; for example, a starting point of a termination symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI, or a termination point of a termination symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI.

A next symbol of a termination symbol of an xth time domain resource in a yth first set of resources in a second set of resources indicated by the SCI; for example, a starting point of a next symbol of a termination symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI, or a termination point of a next symbol of a termination symbol of an x-th time domain resource in a y-th first resource set of the second resource set indicated by the SCI.

The SCIs mentioned above are all SCIs in step 301. Y is an integer of 1 or more. x is an integer greater than or equal to 1, and x is an integer less than or equal to N, where N is the number of time domain resources included in the first resource set, that is, the first resource set includes N time domain resources, and N is an integer greater than or equal to 1.

For example, when the second time is a start point of a start symbol of a first time domain resource, and the third time is a termination point of a termination symbol of the first time domain resource, the first time value may be a time value of the first time domain resource (i.e., a time value from the start point of the start symbol of the first time domain resource to the termination point of the termination symbol of the first time domain resource).

For another example, the second time is a termination point of a start symbol of the first time domain resource, and the third time is a termination point of a termination symbol of the first time domain resource. At this time, the first time length value may be a time length value from a termination point of a start symbol of a first time domain resource to a termination point of a termination symbol of the first time domain resource. The first time length value may also be determined in an rounding manner, for example, the first time domain resource is 1 slot, the time length value from the termination point of the start symbol of the first time domain resource to the termination point of the end symbol of the first time domain resource is less than one slot, and the time length value from the termination point of the start symbol of one time domain resource to the termination point of the end symbol of the first time domain resource may be rounded up according to the number of slots, so that the first time length value is one slot, that is, the time length value of the first time domain resource.

In which cases the difference between the third time instant and the second time instant is taken as the first time length value and in which cases the sum of the difference and the first parameter is taken as the first time length value.

In one example, when the third time is the end point of the above-described symbol and the second time is the start point of the above-described symbol, the difference between the third time and the second time may be taken as the first time value.

In one example, when the third time instant is the end point of the above-described symbol and the second time instant is the end point of the above-described symbol, the difference between the third time instant and the second time instant may be taken as the first duration value.

In one example, when the third time is the starting point of the above-described symbol and the second time is the starting point of the above-described symbol, the difference between the third time and the second time may be used as the first time value, or the sum of the difference and the time length of one time domain resource may be used as the first time value. When the time for starting the first timer drxinactytimer is the symbol starting point, the first time length value is used, so that the data in the time domain resource indicated by the SCI can be correctly received.

In an example, when the third time is a starting point of the above-described symbol, and the second time is an ending point of the above-described symbol, a difference between the third time and the second time may be determined, and a sum of the difference and a time duration of one time domain resource may be used as the first time duration value.

Since there is a time delay between the receiving time of the first terminal and the transmitting time of the second terminal when the second terminal transmits data or control information to the first terminal, the time delay value may also be taken into account when determining the first time value.

In one example, when the difference between the third time and the second time is taken as the first time value, the sum of the difference and an offset may be taken as the first time value.

In another example, when the sum of the difference between the third time and the second time and the time duration of one time domain resource is taken as the first time duration value, the sum of the difference and the time duration of one time domain resource and the sum of one offset may be taken as the first time duration value.

The one offset may be a delay value of the transmission of the information from the second terminal to the first terminal. The offset may be configured in the first terminal, may be sent to the first terminal by the second terminal, or may be sent to the first terminal by the network device.

In one example, one SCI includes two levels of SCI, a first level SCI and a second level SCI.

Alternatively, there may be the following example, but the structure of the two-stage SCI is not limited thereto.

As in the example of fig. 5a, the first time domain resource occupies 14 symbols, respectively symbol 0 to symbol 13. The first level SCI occupies symbol 1, symbol 2 and symbol 3. The second-level SCI occupies 5 symbols, symbol 5 to symbol 9, respectively. The frequency domain resources occupied by the first-level SCI are a part of the frequency domain resources occupied by the first data resources, and the frequency domain resources occupied by the second-level SCI are a part of the frequency domain resources occupied by the first data resources. Symbol 4 may be the symbol occupied by the reference signal.

As in the example of fig. 5b, the first time domain resource occupies 14 symbols, symbol 0 to symbol 13 respectively. The first level SCI occupies symbol 1, symbol 2 and symbol 3. The second level SCI occupies 3 symbols, symbol 5, symbol 6 and symbol 7 respectively. The frequency domain resources occupied by the first-level SCI are a part of the frequency domain resources occupied by the first data resources, and the frequency domain resources occupied by the second-level SCI are all the frequency domain resources occupied by the first data resources. Symbol 4 may be the symbol occupied by the reference signal.

As in the example of fig. 5c, the first time domain resource occupies 14 symbols, symbol 0 to symbol 13 respectively. The first level SCI occupies symbol 1, symbol 2 and symbol 3. The second-level SCI occupies 5 symbols, symbol 1, symbol 2 and symbol 3, and symbol 5 and symbol 6, respectively. The frequency domain resources occupied by the first-stage SCI are a part of the frequency domain resources occupied by the first data resources, the frequency domain resources occupied in the second-stage SCIs on the symbols 5 and 6 are all the frequency domain resources occupied by the first data resources, and the frequency domain resources occupied in the second-stage SCIs on the symbols 1, 2 and 3 are a part of the frequency domain resources occupied by the first data resources. Symbol 4 may be the symbol occupied by the reference signal.

The SCI received in step 301 may be or include a first level SCI and a second level SCI.

When the SCI in step 301 is a first-level SCI, the SCIs described in the above embodiments may be replaced with the first-level SCI.

For example, when the SCIs in the first and second times described above are replaced with the first-level SCIs: the first time or the second time includes but is not limited to any of the following: in the following examples for the first time instant and the second and third time instants, the "start symbol" may be a start point or an end point of the start symbol; an "end symbol" may be a starting point or an end point of an end symbol; the "next symbol" may be a starting point or an ending point of the next symbol.

A starting symbol of the first-level SCI; such as the start point of the start symbol of the first-level SCI or the end point of the start symbol of the first-level SCI.

A symbol next to the starting symbol of the first-level SCI; such as the start point of the next symbol to the start symbol of the first-level SCI or the end point of the next symbol to the start symbol of the first-level SCI. The following examples are similar and will not be repeated.

A termination symbol of the first-level SCI;

a next symbol to a termination symbol of the first-level SCI;

a starting symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI;

a termination symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a termination symbol of the first time domain resource indicated by the first-level SCI.

For example, when the SCI in the third time described above is replaced with the first-level SCI: the third time includes, but is not limited to, any of the following:

a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI;

a next symbol of a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI;

a termination symbol of an xth time domain resource in a first set of resources indicated by the first-level SCI;

a next symbol of a termination symbol of an xth time domain resource in a first resource combination indicated by the first-level SCI;

a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI;

a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI;

a termination symbol of an xth time domain resource in a yth first resource set in a second resource set indicated by the first-level SCI;

a next symbol of a termination symbol of an xth time domain resource in a yth first resource set in a second resource set indicated by the first-level SCI;

wherein y is an integer greater than or equal to 1, x is an integer greater than or equal to 1, and x is an integer less than or equal to n.

Examples of the first time, the second time, and the third time may be adjusted when the SCIs in step 301 include a first-level SCI and a second-level SCI.

In addition, the following examples may still be in accordance with the foregoing description: the start symbol "may be a start point or an end point of the start symbol; an "end symbol" may be a starting point or an end point of an end symbol; the "next symbol" may be a starting point or an ending point of the next symbol; the starting symbol of the SCI may also be referred to as the SCI start, or the first terminal receives the SCI start; and the termination symbol of the SCI may also be referred to as the SCI end, or the first terminal receives the SCI end, etc., to perform adaptive adjustment. The following is only described by taking the starting symbol of the SCI as an example, and the rest of examples are applicable and are not repeated.

In this application, the "start symbol of the SCI" may be a start symbol of a first-level SCI included in the SCI, or may be a start symbol of a second-level SCI included in the SCI. For example, it may be an end point or a start point of a start symbol of the first-level SCI. At an end point or start point, which may be, for example, the start symbol of the second level SCI.

In this application, "next symbol of the start symbol of the SCI" may be next symbol of the start symbol of the first-level SCI included in the SCI, or may be next symbol of the start symbol of the second-level SCI included in the SCI.

In this application, the "end symbol of the SCI" may be an end symbol of a first-level SCI included in the SCI, or may be an end symbol of a second-level SCI included in the SCI.

In this application, "next symbol of the end symbol of the SCI" may be next symbol of the end symbol of the first-level SCI included in the SCI, or may be next symbol of the end symbol of the second-level SCI included in the SCI.

In this application, "the starting symbol, or the next symbol of the starting symbol, or the ending symbol, or the next symbol of the ending symbol of the indicated first time domain resource of the SCI" may be the starting symbol, or the next symbol of the ending symbol of the indicated first time domain resource of the first level SCI included in the SCI.

In this application, "the starting symbol, or the next symbol of the starting symbol, or the terminating symbol, or the next symbol of the terminating symbol, of the xth time domain resource in the first set of resources indicated by the SCI" may be the starting symbol, or the next symbol of the terminating symbol, of the xth time domain resource indicated by the first-level SCI included in the SCI.

In this application, "the starting symbol, or the next symbol of the starting symbol, or the terminating symbol, or the next symbol of the terminating symbol, of the x-th time domain resource in the y-th first resource set in the second resource set indicated by the SCI" may be the starting symbol, or the next symbol of the terminating symbol, of the x-th time domain resource in the y-th first resource set in the second resource set indicated by the first-level SCI included in the SCI.

In the following examples for the first time instant and the second and third time instants, the "start symbol" may be a start point or an end point of the start symbol; an "end symbol" may be a starting point or an end point of an end symbol; the "next symbol" may be a starting point or an ending point of the next symbol.

Illustratively, the SCIs include a first-level SCI and a second-level SCI, and the first time includes, but is not limited to, any of:

a start symbol of the first-level SCI or a start symbol of the second-level SCI; for example, a start point of a start symbol of the first-level SCI, or an end point of a start symbol of the first-level SCI, or a start point of a start symbol of the second-level SCI, or an end point of a start symbol of the second-level SCI.

A next symbol to the start symbol of the first-level SCI or a next symbol to the start symbol of the second-level SCI; for example, a start point of a next symbol of the start symbol of the first-level SCI, or an end point of a next symbol of the start symbol of the first-level SCI, or a start point of a next symbol of the start symbol of the second-level SCI, or an end point of a next symbol of the start symbol of the second-level SCI. The following examples are similar and will not be repeated.

A termination symbol of the first-level SCI or a termination symbol of the second-level SCI;

a next symbol of a termination symbol of the first-level SCI or a next symbol of a termination symbol of the second-level SCI;

a starting symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI;

a termination symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a termination symbol of the first time domain resource indicated by the first-level SCI.

Illustratively, when the SCI includes a first-level SCI and a second-level SCI, the second time includes, but is not limited to, any of:

a start symbol of the first-level SCI or a start symbol of the second-level SCI;

a next symbol to the start symbol of the first-level SCI or a next symbol to the start symbol of the second-level SCI;

a termination symbol of the first-level SCI or a termination symbol of the second-level SCI;

a next symbol of a termination symbol of the first-level SCI or a next symbol of a termination symbol of the second-level SCI;

a starting symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a starting symbol of a first time domain resource indicated by the first-level SCI;

a termination symbol of a first time domain resource indicated by the first-level SCI;

a symbol next to a termination symbol of the first time domain resource indicated by the first-level SCI.

The third time includes, but is not limited to, any of the following:

a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI;

a next symbol of a starting symbol of an xth time domain resource in a first resource set indicated by the first-level SCI;

a termination symbol of an xth time domain resource in a first set of resources indicated by the first-level SCI;

a next symbol of a termination symbol of an xth time domain resource in a first resource combination indicated by the first-level SCI;

a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI;

a next symbol of a starting symbol of an x-th time domain resource in a y-th first resource set in a second resource set indicated by the first-level SCI;

a termination symbol of an xth time domain resource in a yth first resource set in a second resource set indicated by the first-level SCI;

a next symbol of a termination symbol of an x-th time domain resource in a y-th first resource set in the second resource set indicated by the first-level SCI.

The following is presented for different examples: and determining a plurality of modes of the first time length value according to the time domain resource of the activation period of the discontinuous reception DRX of the first terminal and/or the time domain resource indicated by the SCI.

First, when configuring DRX for a first terminal, the association relationship between the configuration information of DRX and the time domain resource indicated by the SCI is introduced.

In case one, the reserved time domain resources are aperiodic resources. I.e. the resource reservation period value T is equal to 0. That is, the SCI indicates that the reserved time domain resources include a first resource set, where the first resource set includes N time domain resources, and N is an integer greater than or equal to 1.

Alternatively, the reserved time domain resource is an aperiodic resource, and it can also be understood that data transmitted between the terminal device (second terminal) on the transmitting side and the terminal device (first terminal) on the receiving side is aperiodic.

In this case one, an example 1, at least one time domain resource of the N time domain resources of the first set of resources is included in the active period of the DRX. Wherein, a certain time domain resource is included in the active period of the DRX, it can be understood that a starting point of the time domain resource is located in the active period of the DRX, and a terminating point of the time domain resource is located in the active period of the DRX.

This example 1, in a specific implementation, includes, but is not limited to, the following examples 1.1 and 1.2:

example 1.1, a first time domain resource of N time domain resources of the first resource set is included in the active period of the DRX, and N-1 time domain resources other than the first time domain resource may or may not have an overlapping portion with the active period of the DRX, which is not required. For example, the first resource set includes 3 time domain resources, the first time domain resource is included in an active period of the DRX, and no requirement is made as to whether other 2 time domain resources are included in the active period of the DRX.

Example 1.2, the first P time domain resources of the N time domain resources of the first resource set are included in the active period of the DRX, and the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period of the DRX, which is not required.

Optionally, in this example, N is 3, P is 2, that is, the first resource set includes 3 time domain resources, a first time domain resource is included in an active period of the DRX, a second time domain resource is included in an active period of the DRX, and a third time domain resource is not included in the active period of the DRX and is not required.

In this case one, an example 2, the first m symbols of at least one of the N time domain resources of the first set of resources overlap with the active period of the DRX.

This example 2, in a specific implementation, includes but is not limited to the following examples 2.1 and 2.2:

example 2.1, the first m symbols of the first time domain resource of the N time domain resources of the first resource set are included in the active period of the DRX, and the first m symbols of the N-1 time domain resources except the first time domain resource may or may not have an overlapping portion with the active period of the DRX, which is not required. Optionally, in this example, the first resource set includes 3 time domain resources, where the first m symbols of the first time domain resource are included in one active period of the DRX, and whether the first m symbols of the other 2 time domain resources are included in the active period of the DRX is not required.

Example 2.2, the first m symbols of the first P time domain resources of the N time domain resources of the first resource set are included in the active period of the DRX, and the first m symbols of the N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period of the DRX, which is not required. Optionally, in this example, N is 3, P is 2, that is, the first resource set includes 3 time domain resources, first m symbols of the first time domain resource are included in one active period of the DRX, first m symbols of the second time domain resource are included in one active period of the DRX, and whether first m symbols of the third time domain resource are included in the active period of the DRX is not required.

In case two, the reserved time domain resources are periodic resources, that is, the resource reservation period value T is greater than 0. That is, the SCI indicates that the reserved time domain resources include a second resource set, where the second resource set includes a periodic first resource set, where the first resource set includes N time domain resources, and N is an integer greater than or equal to 1.

The reserved time domain resource is a periodic resource, and it can also be understood that data transmitted between the terminal device on the transmitting side and the terminal device on the receiving side is periodic.

In the present application, for the periodic resources contained in the detected SCI:

when the first m symbols of the first time domain resource of the lth resource reservation period overlap with the on duration of the next DRX cycle (relative to the current DRX cycle), or the first time domain resource of the lth resource reservation period is included in the on duration of the next DRX cycle, it is called that the lth resource reservation period is aligned with the next DRX cycle resource, where L takes the values of F, F +1, and … ….

When at least the first m symbols of a time domain resource are located in the active period of DRX, the time domain resource may be said to be aligned with the resource of the active period of DRX or aligned with the time domain resource.

The F-th resource reservation period is the earliest resource reservation period in a plurality of resource reservation periods aligned with any DRX cycle resource except the first DRX period, and the target period refers to the F-1 periods from the first resource reservation period to the F-1-th resource reservation period. It can also be understood that the first resource among the periodic resources aligned earliest with the next DRX cycle resources is the first resource of the F-th cycle, and the target cycle refers to the F-1 cycles from the first resource reservation cycle to the F-1 resource reservation cycle. Or, if the F-th resource reservation period is the only resource reservation period aligned with any DRX cycle resource except the first DRX period, the target period refers to the F-1 periods from the first resource reservation period to the F-1-th resource reservation period. Wherein, the first m symbols of the first resource reservation period overlap with the on duration of the current DRX cycle, or the first resource of the first resource reservation period is included in the on duration of the current DRX cycle. F is an integer of 2 or more, and L is an integer of 2 or more.

For example, when F is 2, the target period is the first period. For another example, when F is 3 and the third resource reservation period and the fourth resource reservation period are both aligned with any one DRX cycle except the first DRX cycle, the target period refers to two periods from the first resource reservation period to the second resource reservation period.

For another example, there are 5 resource reservation periods, at least the first m symbols of the first time domain resource in the first resource reservation period are included in the active period, at least the first m symbols of the first time domain resource in the second resource reservation period are included in the active period, the overlapping portion of any one of the time domain resource of the third time domain reservation period and the fourth time domain reservation period and the active period both includes the first m symbols, and at least the first m symbols of the first time domain resource in the fifth time domain reservation period are included in the active period, then F is 2. The target period refers to a period reserved from the first resource. When the resource is reserved for the 2 nd resource reservation period, the fifth time domain reservation period is the earliest resource reservation period of resource alignment, and the target period refers to 3 periods from the 2 nd resource reservation period to the 4 th time domain resource reservation period.

In this case two, an example 1, at least one time domain resource of the N time domain resources in the target cycle of the second set of resources is included in the active period of the DRX.

The target period herein refers to at least one period of the first Y periods corresponding to the second resource set (or refers to at least one first resource set of the first Y first resource sets included in the second resource set). For example, the target period may be a first period in the first Y periods corresponding to the second resource set, or a first period to a Y-th period in the first Y periods corresponding to the second resource set, or a first period to a Z-th period in the first Y periods corresponding to the second resource set, or any Z periods in the first Y periods corresponding to the second resource set, where Z is a positive integer smaller than Y.

Optionally, the target period herein may also refer to at least one period of Y periods corresponding to the second resource set. For example, the target period may be a first period of Y periods corresponding to the second resource set, or a first period to a Y-th period of Y periods corresponding to the second resource set, or a first period to a Z-th period of Y periods corresponding to the second resource set, or any Z periods of Y periods corresponding to the second resource set, where Z is a positive integer smaller than Y.

This example 1, in a specific implementation, includes, but is not limited to, the following examples 1.1 and 1.2:

example 1.1, a first time domain resource of N time domain resources of the second resource set in the target period is included in the active period of the DRX, and N-1 time domain resources other than the first time domain resource may or may not have an overlapping portion with the active period of the DRX, which is not required.

Optionally, in this example, the second resource set includes resources of two cycles, the target cycle is the two cycles, each cycle includes 3 time domain resources, a first time domain resource in the target cycle is included in one active period of the DRX, and whether other 2 time domain resources in the target cycle are included in the active period of the DRX is not required.

Example 1.2, the first P time domain resources of the N time domain resources in the target cycle of the second resource set are included in the active period of the DRX, and the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period of the DRX, which is not required.

Optionally, in this example, the second resource set includes resources of two cycles, the target cycle is the two cycles, N is 3, P is 2, that is, the target cycle corresponding to the second resource set includes 3 time domain resources, a first time domain resource in the target cycle is included in one active period of the DRX, a second time domain resource in the target cycle is included in one active period of the DRX, and whether a third time domain resource in the target cycle is included in the active period of the DRX is not required.

In this case two, an example 2, the first m symbols of at least one of the N time domain resources of the second set of resources within the target period overlap with the active period of the DRX.

This example 2, in a specific implementation, includes but is not limited to the following examples 2.1 and 2.2:

example 2.1, the first m symbols of the first time domain resource of the N time domain resources in the target period of the second resource set are included in the active period of the DRX, and the first m symbols of the N-1 time domain resources except the first time domain resource may or may not have an overlapping portion with the active period of the DRX, which is not required.

In this application, m of the first m symbols of the first time domain resource of the N time domain resources in the target period may be the same or different for any one time domain resource, and is not limited. That is, m in the first m symbols of the first time domain resource of the N time domain resources in the target period may be all the same, part of different, or all of different for any one time domain resource. Likewise, the first m symbols of the other N-1 time domain resources, except the first time domain resource, follow the above rules.

Example 2.2, the first m symbols of the first P time domain resources of the N time domain resources in the target period of the second resource set are included in the active period, and the first m symbols of the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period, which is not required.

In this application, m of the first m symbols of the first P time domain resources of the N time domain resources in the target period may be the same or different for any one time domain resource, and is not limited. That is, m in the first m symbols of the first P time domain resources of the N time domain resources in the target period may be all the same, part of different, or all of different for any one time domain resource. Similarly, the first m symbols of the other N-P time domain resources except the P time domain resources follow the above rule.

In the application, P is a positive integer less than or equal to N; m is greater than or equal to 1, less than or equal to the number of symbols of the maximum number contained in one slot/subframe. Optionally, when 14 symbols are included in one slot, m is less than or equal to 14; when 12 symbols are included in a slot, m is less than or equal to 12.

Optionally, in this example, the second resource set includes two periods of resources, where the target period is the two periods, N is 3, and P is 2, that is, the second resource set includes 3 time domain resources in each period, where m first symbols of a first time domain resource in the target period are included in the active period, m first symbols of a second time domain resource in the target period are included in the active period, and whether m first symbols of a third time domain resource in the target period are included in the active period is not required.

It should be noted that, in the above-mentioned first and second cases, the first m symbols of one time domain resource are required to overlap with the active period of DRX, because the terminal device on the transmitting side generally carries the SCI in the first one or more symbols of each time domain resource, and therefore, the terminal device on the receiving side can detect the SCI only by ensuring that the terminal device on the receiving side remains in the active period for the first m symbols of one time domain resource, so that data can be correctly received or transmitted according to the control information carried in the SCI. Optionally, when the terminal device on the receiving side detects the SCI, the first timer may be started, so as to ensure that the terminal device on the receiving side is always in the active period during the operation of the first timer, and thus can correctly receive or transmit data. That is, it can be understood that SCI is located in the first m symbols of one time domain resource. When the SCI is a two-level SCI, the first-level SCI may be located in the first m symbols of a time domain resource, or both the first-level SCI and the second-level SCI may be located in the first m symbols of a time domain resource.

The following is in light of the above description, taken in conjunction with the accompanying specific examples. In detail, step 302: and the first terminal determines the specific process of the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI. The configuration information of the discontinuous reception of the first terminal is the duration of the discontinuous reception of the first terminal. Specifically, at least one of the following may be included: and the second terminal also determines the first time length value in the same way and sends the first time length value to the first terminal.

The first terminal determines the first time value according to the discontinuous reception duration of the first terminal and/or the time domain position of the time domain resource indicated by the SCI;

alternatively, the first and second electrodes may be,

the first terminal determines the first time value according to whether the discontinuous reception duration of the first terminal and the time domain resource indicated by the SCI are completely overlapped;

alternatively, the first and second electrodes may be,

and the first terminal determines the first time length value according to the discontinuous reception duration of the first terminal and the overlapping degree of the time domain resources indicated by the SCI.

The relationship between the discontinuous reception duration of the first terminal and the time domain position of the time domain resource indicated by the SCI may be any one of the following: the time domain position of the time domain resource indicated by the SCI is completely within the duration of the discontinuous reception of the first terminal, or at least the first m symbols of the time domain resource indicated by the SCI (or referred to as time domain positions corresponding to at least the first m symbols) are within the duration of the discontinuous reception of the first terminal, or at least the first m symbols of the first time domain resource indicated by the SCI (or referred to as time domain positions corresponding to at least the first m symbols) are within the duration of the discontinuous reception of the first terminal, and at least the first m symbols of other time domain resources except for one time domain resource are not within the duration of the discontinuous reception of the first terminal.

For a time domain resource, when the time domain resource overlaps with the active period of DRX, the overlapping degree may include any of the following examples:

in an example, the time domain resource (or the time domain position of the time domain resource) is completely located in the activation period, which may also be understood that a start point and an end point of the time domain resource are both located in the activation period, and may also be understood that the time domain resource completely overlaps with the activation period.

In one example, at least the first m symbols of the time domain resource are located in an active period, which may also be understood as that a starting point of the time domain resource is located in the active period, and a terminating point of the time domain resource is not located in the active period, and that there is an overlapping portion between the time domain resource and the active period, but the overlapping portion is not completely overlapping.

In one example, the portion of the time domain resource that overlaps with the active period of DRX fails to contain at least the first m symbols of the time domain resource. If the starting point of the time domain resource is located in the active period and the ending point of the time domain resource is not located in the active period, it can be further understood that there is an overlapping portion between the time domain resource and the active period, but the overlapping portion is not completely overlapping. If the starting point of the time domain resource is not located in the activation period, and the ending point of the time domain resource is not located in the activation period, it can also be understood that there is no overlapping portion between the time domain resource and the activation period, and it can also be understood that there is no overlapping portion at all.

If the SCI indicates a time domain resource, whether the duration of discontinuous reception of the first terminal and the time domain resource indicated by the SCI completely overlap, and any one of the degrees of overlap may be: the time domain resource (or the time domain position of the time domain resource) is completely located in the activation period; or at least the first m symbols of the time domain resource are located in an activation period; or the part of the time domain resource which is overlapped with the activation period of the DRX fails to contain at least the first m symbols of the time domain resource; or, no symbol of the time domain resource is located in the activation period.

If the SCI indicates a plurality of time domain resources, whether the duration of the discontinuous reception of the first terminal and the time domain resources indicated by the SCI completely overlap, and the degree of the overlap may be as described below.

The plurality of time domain resources (or the time domain positions of the time domain resources) indicated by the SCI are completely located in the active period, and it may also be understood that starting points and ending points of the plurality of time domain resources are both located in the active period, and it may also be understood that the plurality of time domain resources completely overlap with the active period. In addition, there is an incomplete overlap, since the first time domain resource overlaps with the activator. The SCI does not have multiple time domain resources completely non-overlapping with the DRX activator when implementing the multiple time domain resources.

When the duration of discontinuous reception of the first terminal and the time domain resource indicated by the SCI completely overlap (i.e., the time domain resource or the time domain position of the time domain resource completely lies within the active period), selecting one duration value from a set of duration values as the first duration value; the first time length value may also be determined according to a third time and a second time, where X in the third time is less than or equal to N, and the Y value is not limited. For example, when the first resource set includes 1 time domain resource, X is 1; when the first resource set comprises 2 time domain resources, X is 1 or 2; when the first resource set comprises 3 time domain resources, X is 1, 2 or 3. In any embodiment of the application, optionally, selecting one duration value from the duration value set as the first duration value may be selecting a minimum duration value greater than or equal to a difference between the third time and the second time as the first duration value.

The following is a detailed description of an example of case one in the above embodiments:

for example 1 in case one of the above embodiments, at least one time domain resource of the N time domain resources of the first set of resources is included in the active period of DRX.

Example 1.1, a first time domain resource of N time domain resources of the first resource set is included in an active period of DRX, and N-1 time domain resources other than the first time domain resource may or may not have an overlapping portion with the active period of DRX, which is not required. N-1 is a positive integer greater than or equal to 1.

For example 2 in case one of the above embodiments, the first m symbols of at least one of the N time domain resources of the first set of resources overlap with the active period of DRX.

Example 2.1, the first m symbols of the first time domain resource of the N time domain resources of the first resource set are included in the active period of DRX, and the first m symbols of the N-1 time domain resources except the first time domain resource may or may not have an overlapping portion with the active period of DRX, which is not required. N-1 is a positive integer greater than or equal to 1.

If the other N-1 time domain resources than the first time domain resource in example 1.1 overlap with the active period of DRX and the overlapping part contains at least the first m symbols of the other N-1 time domain resources. If the first m symbols of the N-1 time domain resources other than the first time domain resource in example 2.1 overlap with the active period of DRX. In both cases, it may be that one of the set of duration values is selected as the first duration value; the first duration value may also be determined according to a third time and a second time, where x in the third time is less than or equal to N. For example, when the first resource set includes 1 time domain resource, x is 1; when the first resource set comprises 2 time domain resources, x is 1 or 2; when the first resource set includes 3 time domain resources, x is 1, 2, or 3. The process of determining the first time length value according to the third time instant and the second time instant may refer to the description of the above embodiments, for example, taking a difference between the third time instant and the second time instant as the first time length value, for example, taking a sum of the difference between the third time instant and the second time instant and the first parameter as the first time length value, and for example, taking a minimum number of slots greater than or equal to the difference between the third time instant and the second time instant as the first time length value. Optionally, one of the duration values in the duration value set may be selected as the first duration value, and a minimum duration value greater than or equal to a difference between the third time and the second time may be selected as the first duration value in the duration value set.

As an example, when x is 1, the second time is a starting point of the first time domain resource, and the third time is an ending point of the first time domain resource, the first time value obtained by subtracting the second time from the third time may also be referred to as a time value of one time domain resource. When x is 2, the second time is a start point of the first time domain resource, and the third time is a stop point of the second time domain resource, the first time value obtained by subtracting the second time from the third time may also be referred to as a time value of two time domain resources.

As shown in fig. 6a, the time domain resource indicated by the SCI includes a first resource set, where the first resource set includes 2 time domain resources, the first time domain resource is completely included in the active period of the DRX, an overlapping portion of the second time domain resource and the active period of the DRX at least includes m first symbols, and at this time, when the second time is a start point of the first time domain resource, and the third time is a stop point of the second time domain resource, a first time value obtained by subtracting the second time from the third time may also be referred to as time length values of the two time domain resources.

If none of the other N-1 time domain resources except the first time domain resource in example 1.1 overlap the active period of DRX, or the overlapping portion of the other N-1 time domain resources and the active period of DRX fails to contain at least the first m symbols of the other N-1 time domain resources. If none of the first m symbols of the other N-1 time domain resources except the first time domain resource overlap the active period of DRX or the overlapping part of the other N-1 time domain resources and the active period of DRX fails to contain at least the first m symbols of the other N-1 time domain resources in example 2.1. In both cases, to complete receiving the nth time domain resource in the first set of resources, the termination point of the nth time domain resource needs to be in the active period. In both cases, one of the duration values in the set of duration values may be selected as the first duration value, where the selected duration value is a minimum duration value equal to or greater than a difference between a third time instant and a second time instant, where x in the third time instant is equal to N; the first duration value may also be determined based on a third time instant and a second time instant, where x in the third time instant is equal to N. As an example, at this time, the second time point may be a start point of the first time domain resource, the third time point may be a stop point of the nth time domain resource, and a difference between the start point of the first time domain resource and the stop point of the nth time domain resource is used as the first time length value.

As shown in fig. 6b, the time domain resource indicated by the SCI includes a first resource set, the first resource set includes 3 time domain resources, the first time domain resource is completely included in the active period of DRX, and the overlapping portion of the second time domain resource and the third time domain resource with the active period of DRX does not include the first m symbols. At this time, the first duration value is determined according to a third time and a second time, where x in the third time is 3, that is, the xth resource in the third time is the third resource. For a detailed description of the third moment and the second moment, see above. As an embodiment, the second time point may be a starting point of the first time domain resource, and the third time point is a terminal point of the third time domain resource or a time point after the terminal point of the third time domain resource.

For example 1 and example 1.2 in case one of the above embodiments, the first P time domain resources of the N time domain resources of the first resource set are included in the active period of DRX, and the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period of DRX, which is not required. N-P is a positive integer greater than or equal to 1.

For example 2 and example 2.2 in case one of the above embodiments, the first m symbols of the first P time domain resources of the N time domain resources of the first resource set are included in the active period of DRX, and the first m symbols of the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period of DRX, which is not required. N-P is a positive integer greater than or equal to 1.

If the other N-P time domain resources than the P time domain resources in example 1.2 overlap with the active period of DRX, and the overlapping portion contains at least the first m symbols of the other N-P time domain resources. If the first m symbols of the other N-P time domain resources than the P time domain resources in example 2.2 overlap with the active period of DRX. In both cases, for any of the first P-1 time domain resources, one of a set of duration values may be selected as the first duration value; the first time length value can also be determined according to a third time and a second time, wherein x in the third time is less than or equal to P-1. Because the previous P-1 time domain resources are all aligned with the activation period on duration, the corresponding SCI can be detected by the time domain resource detection device, and the data can be received by determining the first time length value in any mode; of course, the determination may also be directly dependent on the first detected SCI, for example, the difference between the third time and the second time is used to determine the first time value, in an example, the second time is a starting point of the first time domain resource, and the third time is an ending point of the nth time domain resource. The subsequent time domain resources need to rely on the pth time domain resource to trigger the timer to receive the time domain resource. For the pth time domain resource, a duration value in a duration value set may be selected as the first duration value, where the selected duration value is a minimum duration value greater than or equal to a difference between a third time and a second time, where x in the third time is equal to N; the first duration value may also be determined based on a third time instant and a second time instant, where x in the third time instant is equal to N. Because the resources after the P-th time domain resource can not be aligned to the on duration, only the SCI detection of the P-th time domain resource can be relied on, and a timer capable of receiving the last data is started. The process of determining the first time length value according to the third time instant and the second time instant may refer to the description of the above embodiments, for example, taking a difference between the third time instant and the second time instant as the first time length value, for example, taking a sum of the difference between the third time instant and the second time instant and the first parameter as the first time length value, and for example, taking a minimum number of slots greater than or equal to the difference between the third time instant and the second time instant as the first time length value. As an example, at this time, the second time point may be a starting point of a pth time domain resource, the third time point may be an ending point of an nth time domain resource, and a difference between the ending point of the nth time domain resource and the starting point of the pth time domain resource is used as the first time value. As an example, if p is 2, then the second time may be set as a starting point of the second time domain resource, the third time may be set as a terminating point of the nth time domain resource, and a difference between the terminating point of the nth time domain resource and the starting point of the second time domain resource is taken as the first time value.

As shown in FIG. 6c, N is 4 and P is 2. The time domain resource indicated by the SCI includes a first resource set, the first resource set includes 4 time domain resources, the first 2 time domain resources are completely located in the active period of the DRX, and the overlapping portion of the last 2 time domain resources and the active period of the DRX at least includes the first m symbols. In this example, the second time is a starting point of the 1 st time domain resource, and the third time is a termination point of the 1 st time domain resource, or a termination point of the 2 nd time domain resource, or a termination point of the 3 rd time domain resource, or a termination point of the 4 th time domain resource, or a duration value is selected from the set of duration values as the first duration value.

If none of the other N-P time domain resources except the P time domain resources in example 1.2 overlap the active period of DRX, or the overlapping portion of the other N-P time domain resources and the active period of DRX fails to contain at least the first m symbols of the other N-1 time domain resources. If none of the first m symbols of the N-P time domain resources other than the P time domain resources in example 2.2 overlap with the active period of DRX. In both cases, it can be the same as example 1.1. To complete receiving the nth time domain resource in the first resource set, the termination point of the nth time domain resource needs to be in the active period. At this time, the second time may be a starting point of the first time domain resource, the third time may be a termination point of the nth time domain resource, and a difference between the starting point of the first time domain resource and the termination point of the nth time domain resource is used as the first time length value.

As shown in FIG. 6d, N is 4 and P is 2. The time domain resources indicated by the SCI include a first resource set, the first resource set includes 4 time domain resources, the first 2 time domain resources are completely contained in the active period of the DRX, and the overlapping portion of the last two time domain resources and the active period of the DRX does not contain the first m symbols. At this time, the first duration value is determined according to a third time and a second time, where x in the third time is 4, that is, the xth resource in the third time is the fourth time domain resource. For a detailed description of the third moment and the second moment, see above. As an embodiment, the second time point may be a starting point of the first time domain resource, and the third time point is a terminal point of the fourth time domain resource or a time point after the terminal point of the fourth time domain resource.

The explanation of m symbols in this embodiment is the same as that in the previous embodiment, that is, the explanation of any one embodiment in this application is also applicable to other embodiments, and is not repeated.

In addition, when the first resource set includes at least 3 time domain resources (N is greater than or equal to 3), an overlapping portion of the first time domain resource and the active period of the DRX includes first m symbols of the first time domain resource, an overlapping portion of the ith time domain resource and the active period of the DRX does not include first m symbols of the ith time domain resource, an overlapping portion of the (i + 1) th time domain resource and the active period of the DRX includes first m symbols of the (i + 1) th time domain resource, i is an integer greater than or equal to 2, and i is less than or equal to an integer of N-1. In this case, the second time may be a starting point of the first time domain resource, the third time may be a termination point of the ith time domain resource, or the third time is a time after the termination point of the ith time domain resource.

As shown in FIG. 6e, N is 4 and i is 3. The first resource set comprises 4 time domain resources, the overlapping part of the first 2 time domain resources and the active period of the DRX at least comprises the first m symbols, the overlapping part of the 3 rd time domain resource and the active period of the DRX does not comprise the first m symbols of the 3 rd time domain resource, and the overlapping part of the 4 th time domain resource and the active period of the DRX comprises the first m symbols of the 4 th time domain resource. In this case, the second time may be a starting point of the first time domain resource, the third time may be a termination point of the 3 rd time domain resource, or the third time is a time after the termination point of the 3 rd time domain resource, for example, a starting point or a termination point of the fourth time domain resource.

And when the overlapping part of the time domain resource of the ith data in the first resource set and the active period of the DRX at least comprises the first m symbols, and the overlapping part of the time domain resource of the (i + 1) th data and the active period of the DRX at least comprises the first m symbols, receiving the SCI in the ith time domain resource. At this time, when the SCI in the ith time domain resource is detected, the first time length value of the started first timer may be determined as follows. For example, selecting one duration value from a set of duration values as the first duration value; the first duration value may also be determined according to a third time and a second time, where x in the third time is less than or equal to N. For example, when the first resource set includes 1 time domain resource, x is 1; when the first resource set comprises 2 time domain resources, x is 1 or 2; when the first resource set includes 3 time domain resources, x is 1, 2, or 3. The process of determining the first duration value according to the third time and the second time may be referred to the description of the above embodiments.

When the overlapping portion of the time domain resource of the ith data in the first resource set and the active period of the DRX at least includes the first m symbols, and the overlapping portion of the time domain resource of the (i + 1) th data and the active period of the DRX does not include at least the first m symbols, when receiving the SCI in the ith time domain resource, a first time value may be determined according to a second time and a third time, where the first time value may be a start point of the ith time domain resource at the second time, and the third time may be an end point of the (i + 1) th time domain resource. The third time instant may be the end point of the (i + 2) th time domain resource if the overlapping portion of the (i + 2) th time domain resource and the active period of DRX does not contain at least the first m symbols. To summarize, it may be that the third time is the end point of the x + r th time domain resource, and the overlapping portion of the i +1 th to i + r th time domain resources and the active period of DRX does not include at least the first m symbols. r is an integer of 0 or more. Optionally, one of the duration values in the duration value set may be selected as the first duration value, and a minimum duration value greater than or equal to a difference between the third time and the second time may be selected as the first duration value in the duration value set.

As shown in fig. 6f, the first resource set includes 4 time domain resources, the overlapping portion of the first 2 time domain resources and the active period of DRX at least includes the first m symbols, the overlapping portion of the 3 rd time domain resource and the active period of DRX does not include the first m symbols of the 3 rd time domain resource, and the overlapping portion of the 4 th time domain resource and the active period of DRX includes the first m symbols of the 4 th time domain resource. At this time, starting from the starting point of the first time domain resource, the first time length value is one of the time length value sets. Then, the first time value of the first timer is a time value from a start point of the second time domain resource to a termination point of the third time domain resource. Then, the first time length value of the first timer is a time length value from a starting point of the fourth time domain resource to an ending point of the fourth time domain resource.

Referring to fig. 7a, a method for determining a first duration value is further described, where the first duration value may be a discontinuous duration value, where discontinuous means that the first duration value matches the corresponding time domain resource, and it can also be understood that the timing of the first duration value matches the corresponding time domain resource. Optionally, the corresponding time domain resource is a resource used for data initial transmission in the reserved time domain resource, or the corresponding time domain resource is a first time domain resource of each second resource set in the reserved time domain resource. Said non-continuous may be understood as: at least in an active period (the first timer is in a timing state) in a time domain occupied by the reserved time domain resources, and/or in an inactive period (the first timer temporarily stops timing) in a time domain unoccupied by the reserved time domain resources; alternatively, it is understood that: in the active period at least in the time domain occupied by the reserved time domain resources.

As shown in fig. 7a, the first resource set includes three time domain resources, and the duration value of the first timer is a duration value from a starting point of the first time domain resource to a terminating point of the third time domain resource. The first timer starts timing at the starting point of the first time domain resource, stops timing at the ending point of the first time domain resource, continues to time at the starting point of the second time domain resource, stops timing at the ending point of the second time domain resource, continues to time at the starting point of the third time domain resource, and stops timing at the ending point of the third time domain resource.

For example, the first time domain resource occupies 2ms, the second time domain resource occupies 2ms, and the third time domain resource occupies 3ms, so that the first timer counts 7ms at the termination point of the third time domain resource.

Next, a case of periodically reserving time domain resources is described.

Since the reserved resource in the first cycle (i.e. the first time domain resource reservation cycle) is included in the active period of the DRX cycle, but the reserved resource in the second cycle does not overlap with the active period of the DRX cycle, this will cause the terminal device on the receiving side to be in the dormant period at the time corresponding to the reserved resource in the second cycle, and the reserved resource in the second cycle cannot be used. Moreover, if the terminal device on the receiving side uses the first timer configured by the network device, that is, uses the pre-configured fixed duration timer, the terminal device on the receiving side may not overlap the reserved resource of the second cycle with the active period of the DRX cycle. In this case, the terminal device of the receiving side determines the duration of the DRX inactivity timer. For example, if it is only necessary to make the first time domain resource of the second cycle included in the active period of the DRX cycle, the duration of the first timer is required to be equal to the sum of the resource reservation period T and the duration of the first time domain resource of the second cycle. Of course, if both the first time domain resource and the second time domain resource of the second cycle are required to be included in the active period of the DRX cycle, the duration of the second timer is required to be equal to the sum of the resource reservation period T and the duration between the start time of the first time domain resource and the end time of the second resource of the second cycle.

Alternatively, referring to the above explanation regarding resource alignment, it is assumed that the target period refers to F-1 periods starting from the first resource reservation period to the F-1 resource reservation period. Then y-F-1, x-1 at the third instant; alternatively, y is F-1 and x is N at the third time. The difference between the specific third time and the second time may refer to various previous start symbols and description of end symbols, which are not described again. For example, the third time is a termination point of a first or nth time domain resource in an F-1 th first resource set of the second resource set, and the second time is a start point of a first time domain resource in a first resource set of the second resource set.

The following is a detailed description of an example of case two in the above embodiment:

for example 1 in case two of the above embodiments, the second set of resources is included in the active period of DRX in at least one of the N time domain resources in the target period.

Example 1.1, a first time domain resource of N time domain resources of the second resource set in the target period is included in the active period of the DRX, and N-1 time domain resources other than the first time domain resource may or may not have an overlapping portion with the active period of the DRX, which is not required. N-1 is a positive integer greater than or equal to 1.

For example 2 in case two of the above embodiments, the first m symbols of at least one of the N time domain resources of the second set of resources within the target period overlap with the active period of DRX.

Example 2.1, the first m symbols of the first time domain resource of the N time domain resources in the target period of the second resource set are included in the active period of the DRX, and the first m symbols of the N-1 time domain resources except the first time domain resource may or may not have an overlapping portion with the active period of the DRX, which is not required. N-1 is a positive integer greater than or equal to 1.

If the other N-1 time domain resources than the first time domain resource in example 1.1 overlap with the active period of DRX and the overlapping part contains at least the first m symbols of the other N-1 time domain resources. If the first m symbols of the N-1 time domain resources other than the first time domain resource in example 2.1 overlap with the active period of DRX. In both cases, it may be that one of the set of duration values is selected as the first duration value; the first duration value may also be determined according to a third time and a second time, where x in the third time is less than or equal to N, y is less than or equal to F-1, and the F-th resource reservation period (first resource set) is the earliest resource reservation period (first resource set) of all resource reservation periods (first resource sets) aligned with any DRX cycle resource except the first DRX cycle resource.

For example, when the first resource set includes 1 time domain resource, x is 1; when the first resource set comprises 2 time domain resources, x is 1 or 2; when the first resource set includes 3 time domain resources, x is 1, 2, or 3. For example, when the second resource set includes 2 first resource sets, F-1 may be 1, and when the second resource set includes 3 first resource sets, F-1 is 1 or 2. The process of determining the first time length value according to the third time instant and the second time instant may refer to the description of the above embodiments, for example, taking a difference between the third time instant and the second time instant as the first time length value, for example, taking a sum of the difference between the third time instant and the second time instant and the first parameter as the first time length value, and for example, taking a minimum number of slots greater than or equal to the difference between the third time instant and the second time instant as the first time length value.

As shown in fig. 7a, the time domain resources indicated by the SCI include a second set of resources, which includes a periodic first set of resources, which includes 2 time domain resources. The first time domain resource of the two first resource sets is completely contained in the active period of the DRX, and the overlapping part of the second time domain resource of the two first resource sets and the active period of the DRX at least contains the first m symbols. At this time, the second time is a starting point of a first time domain resource in the first resource set, the third time is a terminating point of a second time domain resource in the first resource set, and the terminating point of a second time domain resource in the second first resource set.

If none of the other N-1 time domain resources except the first time domain resource in example 1.1 overlap the active period of DRX, or the overlapping portion of the other N-1 time domain resources and the active period of DRX fails to contain at least the first m symbols of the other N-1 time domain resources. If none of the first m symbols of the other N-1 time domain resources except the first time domain resource overlap the active period of DRX or the overlapping part of the other N-1 time domain resources and the active period of DRX fails to contain at least the first m symbols of the other N-1 time domain resources in example 2.1. In both cases, to complete receiving the nth time domain resource in the first set of resources, the termination point of the nth time domain resource needs to be in the active period. In both cases, one of the set of duration values may be selected as the first duration value, where the selected duration value is a minimum duration value greater than or equal to a difference between a third time and a second time, where x in the third time is equal to 1 or N, y is equal to F-1, and the F-th resource reservation period (the first resource set) is an earliest resource reservation period (the first resource set) of all resource reservation periods (the first resource set) aligned with any DRX cycle resource except the first DRX cycle resource; the first time value may also be determined based on a third time instant and a second time instant, where x in the third time instant is equal to 1 or N, and y is F-1. As an example, at this time, the second time point may be set as a starting point of a first time domain resource in the first resource set, the third time point is a termination point of an nth time domain resource in the F-1 th first resource set, and a difference between the starting point of the first time domain resource in the first resource set and the termination point of the nth time domain resource in the F-1 th first resource set is taken as the first time value.

As shown in fig. 7b, the time domain resource indicated by the SCI includes a second resource set, the second resource set includes 2 first resource sets, the first resource set includes 3 time domain resources, a first time domain resource of the two first resource sets is completely included in the active period of the DRX, and an overlapping portion of a second time domain resource and a third time domain resource of the 2 first resource sets and the active period of the DRX does not include the first m symbols. The 3 time domain resources in the second first set of resources are completely contained within the active period of DRX. In this case, the first time value is determined according to a third time and a second time, where x at the third time is 3, that is, the x-th resource at the third time is a third resource, and y at the third time is 2, that is, the y-th first resource set at the third time is a second first resource set. For a detailed description of the third moment and the second moment, see above. As an embodiment, the second time may be a starting point of a first time domain resource in the first resource set, and the third time is a terminal point of a third time domain resource in the second first resource set or a time after the terminal point of the third time domain resource; the third time may also be a termination point of a first time domain resource in a second first set of resources. When the third time is set to the termination point of the first time domain resource in the second first set of resources, a retransmission timer may be relied upon to receive further time domain resources in the second first set of resources.

As shown in fig. 7d, the second resource set includes 3 first resource sets, the first resource set includes 3 time domain resources, the first time domain resource and the second time domain resource in the first and third first resource sets at least contain the first m symbols with the repeated portion of the active period of DRX, and the third time domain resource in the first and third first resource sets does not overlap with the active period of DRX. There is no overlap of the 3 time domain resources in the second first set of resources with the active period of DRX. At this time, the second time may be set as a starting point of the first time domain resource, and the third time is set as a ending point of a third time domain resource of the second first resource set (i.e. x given in the third time is 3 and y is 2), or the third time is after the ending point of a third time domain resource of the second first resource set, for example, the third time is a starting point of the first time domain resource of the third first resource set (i.e. x given in the third time is 1 and y is 3), and for example, the third time is a starting point of a third time domain resource of the third first resource set (i.e. x given in the third time is 3 and y is 3).

For example 1 and example 1.2 in case two of the above embodiments, the first P time domain resources of the N time domain resources in the target cycle of the second resource set are included in the active period of the DRX, and the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period of the DRX, which is not required. N-P is a positive integer greater than or equal to 1.

For example 2 and example 2.2 in case two of the above embodiments, the first m symbols of the first P time domain resources of the N time domain resources in the target period of the second resource set are included in the active period, and the first m symbols of the other N-P time domain resources except the P time domain resources may or may not have an overlapping portion with the active period, which is not required. N-P is a positive integer greater than or equal to 1.

If the other N-P time domain resources than the P time domain resources in example 1.2 overlap with the active period of DRX, and the overlapping portion contains at least the first m symbols of the other N-P time domain resources. If the first m symbols of the other N-P time domain resources than the P time domain resources in example 2.2 overlap with the active period of DRX.

In both cases, for any of the first P-1 time domain resources, one of a set of duration values may be selected as the first duration value; the first time length value can also be determined according to a third time and a second time, wherein x in the third time is less than or equal to P-1. Because the previous P-1 time domain resources are all aligned with the activation period on duration, the corresponding SCI can be detected by the time domain resource detection device, and the data can be received by determining the first time length value in any mode; of course, the determination may also be directly dependent on the first detected SCI, for example, the difference between the third time and the second time is used to determine the first time value, in an example, the second time is a starting point of the first time domain resource, and the third time is an ending point of the nth time domain resource. The subsequent time domain resources need to rely on the pth time domain resource to trigger the timer to receive the time domain resource. In both cases, for the pth time domain resource, one of the duration values in the duration value set may be selected as the first duration value, where the selected duration value is greater than or equal to a minimum duration value of a difference between a third time and a second time, where x in the third time is equal to 1 or N; the first duration value may also be determined based on a third time instant, where x equals 1 or N and y equals F-1, and a second time instant. The process of determining the first time length value according to the third time instant and the second time instant may refer to the description of the above embodiments, for example, taking a difference between the third time instant and the second time instant as the first time length value, for example, taking a sum of the difference between the third time instant and the second time instant and the first parameter as the first time length value, and for example, taking a minimum number of slots greater than or equal to the difference between the third time instant and the second time instant as the first time length value. As an example, at this time, the second time point may be set as a start point of the first time domain resource, the third time point is a stop point of the nth time domain resource in the F-1 st first resource set, and a difference between the start point of the first time domain resource and the stop point of the nth time domain resource in the F-1 st first resource set is taken as the first time length value.

In the above embodiments, it is considered that x in the third time instant is equal to 1, because the retransmission timer may be relied upon to receive another time domain resource in any one of the first resource sets.

If none of the other N-P time domain resources except the P time domain resources in example 1.2 overlap the active period of DRX, or the overlapping portion of the other N-P time domain resources and the active period of DRX fails to contain at least the first m symbols of the other N-1 time domain resources. If none of the first m symbols of the N-P time domain resources other than the P time domain resources in example 2.2 overlap with the active period of DRX. In both cases, it can be the same as example 1.1. To complete receiving the nth time domain resource in the first resource set, the termination point of the nth time domain resource needs to be in the active period. At this time, the second time may be set as a start point of the first time domain resource, the third time may be set as a termination point of the nth time domain resource, and a difference between the start point of the first time domain resource and the termination point of the nth time domain resource in the F-1 st first resource set is used as the first time length value.

In the above embodiment, the difference between the specific third time and the specific second time may refer to various previous start symbols and description of end symbols, which are not described again. The examples are merely illustrative and not limiting.

In this application, as an example, the difference between a and B, if a < B, may be B minus a; if A > B, it may be A minus B.

In this application, one or more duration values in the duration value set configured by the resource pool or the duration value set configured for the sidelink may configure the length of the active period of the associated DRX, or the cycle length of the DRX. For example, when the length of the active period of DRX is 10sl, the first duration value is 10sl, 15sl, 28sl, or the like; when the active period of DRX has a length of 20sl, the first time length value is 20sl, 25sl, 30sl, or the like. When the DRX period is 20sl, the first time length value is 20sl, 25sl, 28sl and the like; when the DRX cycle is 30sl, the first duration value is 25sl, 30sl, 35sl, or the like. Wherein sl is the short name of slot.

When the first terminal or the second terminal or the network device determines a duration value from the duration value sets as the first duration value, the duration value may be determined according to a length of an active period of DRX of the first terminal or a cycle length of DRX.

The above-described method for determining the first duration value by the first terminal according to the active period of DRX and/or the time domain resource indicated by the SCI may also be applied to the second terminal and the network device.

The first terminal may also be a sending terminal or a receiving terminal.

The foregoing describes a communication method according to an embodiment of the present application, and hereinafter describes a communication apparatus according to an embodiment of the present application. The method and the device are based on the same technical conception, and because the principles of solving the problems of the method and the device are similar, the implementation of the device and the method can be mutually referred, and repeated parts are not repeated.

Based on the same technical concept as the above-mentioned communication method, as shown in fig. 8, a communication apparatus 800 is provided for implementing the functions of the terminal or the network device in the above-mentioned method. The communication device may be a terminal or a network device, or may be a device in the terminal or the network device, or may be a device capable of being used with the terminal or the network device. The apparatus 800 is capable of performing the steps performed by the first terminal in the method of fig. 3, and the apparatus 800 may be the first terminal or a chip applied to the first terminal. The apparatus 800 may also perform the steps executed by the second terminal in fig. 3, and the apparatus 800 may be the second terminal, or may be a chip in the application and the second terminal. The apparatus 800 may also perform the steps performed by the network device, and the apparatus 800 may be a network device, and may also be a chip in the network device. That is, the communication apparatus 800 may be a system on a chip. In the embodiment of the present application, the chip system may be composed of a chip, and may also include a chip and other discrete devices. The apparatus 800 may include: a transceiver module 820, a processing module 810, and optionally, a storage module 830; the processing module 810 may be connected to the storage module 830 and the transceiver module 820, respectively, and the storage module 830 may also be connected to the transceiver module 820. The storage module 830 may include one or more memories, which may be one or more devices, circuits, or other devices for storing programs or data. The storage module 830 may store computer-executable instructions of the first terminal-side method to cause the processing module 820 to perform the first terminal-side method in the above-described embodiments. The storage module 830 may be a register, a cache, or a RAM, etc., and the storage module 830 may be integrated with the processing module 810. The storage module 830 may be a ROM or other type of static storage device that may store static information and instructions, and the storage module 830 may be separate from the processing module 810. The transceiver module 820 may be an input or output interface, pin or circuit, etc.

Illustratively, when the communication device 800 is configured to perform operations performed by a first terminal:

in an example, the transceiver module 820 may be configured to receive sidelink control information SCI from a second terminal, where the SCI indicates a time domain resource of a sidelink; the processing module 810 may be configured to determine a first duration value of a first timer; the first time length value may belong to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set includes at least one time length value; or, the first duration value may also be determined according to configuration information of discontinuous reception, DRX, of the apparatus and/or a time domain resource of a sidelink indicated by the SCI; the processing module 810 may be further configured to start the first timer at a first time, and monitor control information of a sidelink and/or data information of the sidelink in at least one time unit within the first time length value.

In one example, the processing module 810, when configured to determine the first duration value of the inactivity timer, may be specifically configured to: determining a duration value from the set of duration values as the first duration value; or determining the first time length value according to the configuration information of discontinuous reception of the device and/or the time domain resource of the sidelink indicated by the SCI; or receiving the first time value from the second terminal through the transceiving module 820; or receive the first time value from a network device through the transceiving module 820.

In an example, the processing module 810, when configured to determine the first time length value according to the configuration information of the discontinuous reception of the apparatus and/or the time domain resource of the sidelink indicated by the SCI, may be specifically configured to determine by using at least one of: determining the first time length value according to the configuration information of discontinuous reception of the device and/or the time domain position of the time domain resource of the sidelink indicated by the SCI; or, determining the first time length value according to whether the configuration information of the discontinuous reception of the apparatus and the time domain resource of the sidelink indicated by the SCI are completely overlapped; or, determining the first time length value according to the configuration information of the discontinuous reception of the apparatus and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

In an example, the processing module 810, when configured to determine the first time length value according to the configuration information of the discontinuous reception of the apparatus and/or the time domain resource of the sidelink indicated by the SCI, may be specifically configured to: determining the first duration value according to a duration of discontinuous reception of the apparatus and/or a time domain resource of a sidelink indicated by the SCI.

In one example, the processing module 810, when being configured to determine the first time length value according to the configuration information of discontinuous reception, DRX, of the apparatus and/or the time domain resource of the sidelink indicated by the SCI, may be configured to determine the first time length value according to a difference between the third time and the second time. The second time and the third time are already described in the above embodiment of the method, and are not repeated here.

In an example, when the processing module 810 is configured to determine the first time length value according to a difference between the third time and the second time, specifically, to: taking the difference value between the third moment and the second moment as the first time length value; or, taking the sum of the difference between the third time and the second time and the first parameter as the first time length value; or, the minimum number of slot slots greater than or equal to the difference between the third time and the second time is taken as the first time length value. The first parameter is, for example, a duration of a time domain resource, or an offset.

In one example, when the processing module 810 determines a duration value from the duration value sets as the first duration value, it may specifically be configured to: and determining a minimum time length value which is greater than or equal to the difference value between the third moment and the second moment in the time length value set as the first time length value.

In an example, the storage module 830 may store the time length value set, may also store the location of the time domain resource indicated by the SCI, and may also store the determined first time length value.

Illustratively, when the communication apparatus 800 performs an operation performed by the second terminal:

in one example, the transceiver module 820 can be configured to transmit an SCI to a first terminal, where the SCI indicates a time domain resource of a sidelink.

In an example, the transceiver module 820 is specifically configured to send a first time length value to a first terminal, where the first time length value may belong to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set includes at least one time length value; alternatively, the first duration value may be determined according to configuration information of discontinuous reception, DRX, of the first terminal and/or a time domain resource indicated by the SCI.

In one example, the processing module 810 may be configured to determine a duration value from the set of duration values as the first duration value; or, determining the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI.

In an example, when the processing module 810 is configured to determine the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, it may be specifically configured to determine by using at least one of the following: determining the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain position of the time domain resource of the sidelink indicated by the SCI; or, determining the first time length value according to whether the configuration information of the discontinuous reception of the first terminal and the time domain resource of the sidelink indicated by the SCI are completely overlapped; or, determining the first time length value according to the configuration information of the discontinuous reception of the first terminal and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

In an example, when the processing module 810 is configured to determine the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, it may specifically be configured to: and determining the first time value according to the discontinuous reception duration of the first terminal and/or the time domain resource of the sidelink indicated by the SCI.

In an example, the processing module 810, when configured to determine the first time length value according to the configuration information of the discontinuous reception DRX of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, may be configured to determine the first time length value according to a difference between the third time and the second time. The second time and the third time are already described in the above embodiment of the method, and are not repeated here.

In an example, when the processing module 810 is configured to determine the first time length value according to a difference between the third time and the second time, specifically, to: taking the difference value between the third moment and the second moment as the first time length value; or, taking the sum of the difference between the third time and the second time and the first parameter as the first time length value; or, the minimum number of slot slots greater than or equal to the difference between the third time and the second time is taken as the first time length value. The first parameter is, for example, a duration of a time domain resource, or an offset.

In one example, when the processing module 810 determines a duration value from the duration value sets as the first duration value, it may specifically be configured to: and determining a minimum time length value which is greater than or equal to the difference value between the third moment and the second moment in the time length value set as the first time length value.

Illustratively, when the communications apparatus 800 is used to perform operations performed by a network device:

in an example, the transceiver module 820 is specifically configured to send a first duration value to a first terminal, where the first duration value may belong to a duration value set configured for a resource pool or a duration value set configured for a sidelink, and the duration value set includes at least one duration value.

In one example, the processing module 810 may be configured to determine a duration value from the set of duration values as the first duration value.

Fig. 9 is a schematic block diagram of a communication apparatus 900 according to an embodiment of the present application. It is understood that the apparatus 900 is capable of performing the steps performed by the first terminal, the second terminal, and the network device in the method of fig. 3. The apparatus 900 comprises: the processor 910 and the transceiver 920, optionally, further include a memory 930. The transceiver may be configured to receive program instructions and transmit the program instructions to the processor, or the transceiver may be configured to perform communication interaction between the apparatus and other communication devices, such as interaction control signaling and/or service data. The transceiver may be a code and/or data read-write interface circuit, or the transceiver may be a signal transmission interface circuit between the communication processor and the transceiver. The processor 910 and the memory 930 are electrically coupled.

Illustratively, a memory 930 for storing a computer program; the processor 910 may be configured to call the computer program or instructions stored in the memory, to perform the above communication method, or to perform the above communication method through the transceiver 920.

The processing module 810 in fig. 8 may be implemented by the processor 910, the transceiver module 820 may be implemented by the transceiver 820, and the storage module 830 may be implemented by the memory 930.

Illustratively, when the communications apparatus 900 is configured to perform operations performed by a first terminal:

in one example, the transceiver 920 may be configured to receive sidelink control information SCI from a second terminal, the SCI indicating a time domain resource of a sidelink; the processor 910 may be configured to determine a first duration value of a first timer; the first time length value may belong to a time length value set configured for a resource pool or a time length value set configured for a sidelink, and the time length value set includes at least one time length value; or, the first duration value may also be determined according to configuration information of discontinuous reception, DRX, of the apparatus and/or a time domain resource of a sidelink indicated by the SCI; the processor 910 may be further configured to start the first timer at a first time, and monitor the control information of the sidelink and/or the data information of the sidelink in at least one time unit within the first time length value.

In one example, the processor 910, when configured to determine the first duration value of the inactivity timer, may be specifically configured to: determining a duration value from the set of duration values as the first duration value; or determining the first time length value according to the configuration information of discontinuous reception of the device and/or the time domain resource of the sidelink indicated by the SCI; or receiving the first time value from the second terminal through the transceiver 920; or receive the first time value from a network device through the transceiver 920.

In an example, the processor 910, when configured to determine the first time length value according to the configuration information of the discontinuous reception of the apparatus and/or the time domain resource of the sidelink indicated by the SCI, may be specifically configured to determine by using at least one of: determining the first time length value according to the configuration information of discontinuous reception of the device and/or the time domain position of the time domain resource of the sidelink indicated by the SCI; or, determining the first time length value according to whether the configuration information of the discontinuous reception of the apparatus and the time domain resource of the sidelink indicated by the SCI are completely overlapped; or, determining the first time length value according to the configuration information of the discontinuous reception of the apparatus and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

In an example, when the processor 910 is configured to determine the first time length value according to the configuration information of discontinuous reception of the apparatus and/or the time domain resource of the sidelink indicated by the SCI, the processor may be specifically configured to: determining the first duration value according to a duration of discontinuous reception of the apparatus and/or a time domain resource of a sidelink indicated by the SCI.

In one example, the processor 910, when configured to determine the first time value according to configuration information of discontinuous reception, DRX, of the apparatus and/or a time domain resource of a sidelink indicated by the SCI, may be configured to determine the first time value according to a difference between the third time and the second time. The second time and the third time are already described in the above embodiment of the method, and are not repeated here.

In an example, the processor 910, when configured to determine the first time length value according to a difference between the third time and the second time, is specifically configured to: taking the difference value between the third moment and the second moment as the first time length value; or, taking the sum of the difference between the third time and the second time and the first parameter as the first time length value; or, the minimum number of slot slots greater than or equal to the difference between the third time and the second time is taken as the first time length value. The first parameter is, for example, a duration of a time domain resource, or an offset.

In one example, when the processor 910 determines one duration value from the duration value sets as the first duration value, it may be specifically configured to: and determining a minimum time length value which is greater than or equal to the difference value between the third moment and the second moment in the time length value set as the first time length value.

In one example, the memory 930 may store the set of duration values, the location of the time domain resource indicated by the SCI, and the determined first duration value.

Illustratively, when the communication apparatus 900 performs an operation performed by the second terminal:

in one example, the transceiver 920 can be configured to transmit the SCI to the first terminal, the SCI indicating a time domain resource of the sidelink.

In an example, the transceiver 920 is specifically configured to send a first duration value to a first terminal, where the first duration value may belong to a duration value set configured for a resource pool or a duration value set configured for a sidelink, and the duration value set includes at least one duration value; alternatively, the first duration value may be determined according to configuration information of discontinuous reception, DRX, of the first terminal and/or a time domain resource indicated by the SCI.

In one example, the processor 910 may be configured to determine a duration value from the set of duration values as the first duration value; or, determining the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain resource indicated by the SCI.

In an example, when the processor 910 is configured to determine the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, it may be specifically configured to determine by using at least one of the following: determining the first time length value according to the configuration information of the discontinuous reception of the first terminal and/or the time domain position of the time domain resource of the sidelink indicated by the SCI; or, determining the first time length value according to whether the configuration information of the discontinuous reception of the first terminal and the time domain resource of the sidelink indicated by the SCI are completely overlapped; or, determining the first time length value according to the configuration information of the discontinuous reception of the first terminal and the overlapping degree of the time domain resources of the sidelink indicated by the SCI.

In an example, when the processor 910 is configured to determine the first time length value according to the configuration information of discontinuous reception of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, the processor may be specifically configured to: and determining the first time value according to the discontinuous reception duration of the first terminal and/or the time domain resource of the sidelink indicated by the SCI.

In an example, the processor 910, when configured to determine the first time length value according to the configuration information of the discontinuous reception DRX of the first terminal and/or the time domain resource of the sidelink indicated by the SCI, may be configured to determine the first time length value according to a difference between the third time and the second time. The second time and the third time are already described in the above embodiment of the method, and are not repeated here.

In an example, the processor 910, when configured to determine the first time length value according to a difference between the third time and the second time, is specifically configured to: taking the difference value between the third moment and the second moment as the first time length value; or, taking the sum of the difference between the third time and the second time and the first parameter as the first time length value; or, the minimum number of slot slots greater than or equal to the difference between the third time and the second time is taken as the first time length value. The first parameter is, for example, a duration of a time domain resource, or an offset.

In one example, when the processor 910 determines one duration value from the duration value sets as the first duration value, it may be specifically configured to: and determining a minimum time length value which is greater than or equal to the difference value between the third moment and the second moment in the time length value set as the first time length value.

Illustratively, when the communications apparatus 900 is configured to perform operations performed by a network device:

in an example, the transceiver 920 is specifically configured to send a first duration value to a first terminal, where the first duration value may belong to a duration value set configured for a resource pool or a duration value set configured for a sidelink, and the duration value set includes at least one duration value.

In one example, the processor 910 may be configured to determine a duration value from the set of duration values as the first duration value.

The processor may be a Central Processing Unit (CPU), a Network Processor (NP), or a combination of a CPU and an NP. The processor may further include a hardware chip or other general purpose processor. The hardware chip may be an application-specific integrated circuit (ASIC), a Programmable Logic Device (PLD), or a combination thereof. The aforementioned PLDs may be Complex Programmable Logic Devices (CPLDs), field-programmable gate arrays (FPGAs), General Array Logic (GAL) and other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, etc., or any combination thereof. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

It will also be appreciated that the memory referred to in the embodiments of the application may be either volatile memory or nonvolatile memory, or may include both volatile and nonvolatile memory. The non-volatile Memory may be a Read-Only Memory (ROM), a Programmable ROM (PROM), an Erasable PROM (EPROM), an Electrically Erasable PROM (EEPROM), or a flash Memory. Volatile Memory can be Random Access Memory (RAM), which acts as external cache Memory. By way of example, but not limitation, many forms of RAM are available, such as Static random access memory (Static RAM, SRAM), Dynamic Random Access Memory (DRAM), Synchronous Dynamic random access memory (Synchronous DRAM, SDRAM), Double Data Rate Synchronous Dynamic random access memory (DDR SDRAM), Enhanced Synchronous SDRAM (ESDRAM), Synchronous link SDRAM (SLDRAM), and Direct Rambus RAM (DR RAM). It should be noted that the memory described herein is intended to comprise, without being limited to, these and any other suitable types of memory.

The transceiver, the interface circuit, or the transceiver according to the embodiments of the present application may include a separate transmitter and/or a separate receiver, or may be an integrated transmitter and receiver. The transceiver means, interface circuit or transceivers may operate under the direction of a corresponding processor. Alternatively, the sender may correspond to a transmitter in the physical device, and the receiver may correspond to a receiver in the physical device.

The embodiment of the application also provides a computer storage medium, which stores a computer program, and the computer program can be used for executing the communication method when being executed by a computer. Such as performing the method illustrated in fig. 3 described above.

Embodiments of the present application also provide a computer program product containing instructions that, when executed on a computer, enable the computer to perform the method of communication provided above. Such as performing the method illustrated in fig. 3 described above.

An embodiment of the present application further provides a communication system, where the communication system includes: a first terminal and a second terminal performing the above-described method of communication. Optionally, the communication system further includes a network device in the communication method.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

While the preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all alterations and modifications as fall within the scope of the application.

It will be apparent to those skilled in the art that various changes and modifications may be made in the embodiments of the present application without departing from the spirit and scope of the embodiments of the present application. Thus, if such modifications and variations of the embodiments of the present application fall within the scope of the claims of the present application and their equivalents, the present application is also intended to include such modifications and variations.