WO2021063318A1 - 指示方法和装置、接收处理方法和装置、终端和存储介质 - Google Patents
指示方法和装置、接收处理方法和装置、终端和存储介质 Download PDFInfo
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- WO2021063318A1 WO2021063318A1 PCT/CN2020/118441 CN2020118441W WO2021063318A1 WO 2021063318 A1 WO2021063318 A1 WO 2021063318A1 CN 2020118441 W CN2020118441 W CN 2020118441W WO 2021063318 A1 WO2021063318 A1 WO 2021063318A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W28/00—Network traffic management; Network resource management
- H04W28/16—Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]
- H04W28/26—Resource reservation
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/004—Arrangements for detecting or preventing errors in the information received by using forward error control
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0001—Arrangements for dividing the transmission path
- H04L5/0003—Two-dimensional division
- H04L5/0005—Time-frequency
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0053—Allocation of signaling, i.e. of overhead other than pilot signals
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
- H04W72/0446—Resources in time domain, e.g. slots or frames
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
- H04W72/0453—Resources in frequency domain, e.g. a carrier in FDMA
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
Definitions
- This application relates to a wireless communication network, for example, to an indication method and device, a receiving and processing method and device, a terminal, and a storage medium.
- V2X Vehicle to Everything, V2X for short
- a resource reservation mechanism is often used for the resource reservation mechanism.
- the terminal in addition to indicating the current PSSCH (Pysical Sidelink Share Channel, physical side link shared channel) resource allocation, the terminal also needs to further indicate the following in the SCI (Sidelink Control Information) Which resources are reserved by the terminal.
- SCI Servicelink Control Information
- the PSSCH may be a PSSCH with a fixed frequency domain bandwidth, or may not be a PSSCH with a fixed frequency domain bandwidth.
- it is impossible to determine which type of PSSCH the PSSCH to be received is, and therefore, it is impossible to determine the frequency domain bandwidth and frequency domain position for receiving the PSSCH, which may lead to reception errors.
- the embodiments of the present application provide an indication method and device, a receiving processing method and device, a terminal, and a storage medium.
- the embodiment of the present application provides an indication method, including:
- the type of the first channel is the type of the first channel
- the type of information carried in the first channel is the type of information carried in the first channel
- the type of the first channel and the type of the second channel are The type of the first channel and the type of the second channel;
- the frequency domain resources of the first channel and the frequency domain resources of the second channel overlap.
- the embodiment of the present application also provides a receiving processing method, including:
- the frequency domain resources of the first channel overlap with the frequency domain resources of the second channel.
- An embodiment of the present application provides an indicating device, which includes:
- the indication module is used to indicate at least one of the following according to the indication mode through the first channel:
- the type of the first channel is the type of the first channel
- the type of information carried in the first channel is the type of information carried in the first channel
- the type of the first channel and the type of the second channel are The type of the first channel and the type of the second channel;
- the frequency domain resources of the first channel and the frequency domain resources of the second channel overlap.
- An embodiment of the present application provides a receiving processing device, which includes:
- An indication information obtaining module configured to receive a first channel, and obtain indication information of the first channel with respect to the first channel and/or the second channel;
- a receiving module configured to receive the second channel based on the indication information
- the frequency domain resources of the first channel overlap with the frequency domain resources of the second channel.
- An embodiment of the present application provides a terminal, which includes a memory and one or more processors;
- the memory is configured to store one or more programs
- the one or more processors When the one or more programs are executed by the one or more processors, the one or more processors implement any one of the methods in the embodiments of the present application.
- the embodiment of the present application provides a storage medium that stores a computer program, and the computer program implements any one of the methods in the embodiments of the present application when the computer program is executed by a processor.
- FIG. 1 is a schematic diagram of transmission according to an embodiment of the application
- FIG. 2 is another schematic diagram of transmission provided by an embodiment of this application.
- FIG. 3 is a schematic diagram of a channel structure provided by an embodiment of the application.
- FIG. 4 is a method flowchart of a method for indicating resource reservation and resource allocation according to an embodiment of the application
- FIG. 5 is another schematic diagram of transmission provided by an embodiment of this application.
- FIG. 6 is a schematic diagram of another transmission provided by an embodiment of this application.
- FIG. 7 is another schematic diagram of transmission provided by an embodiment of this application.
- FIG. 8 is another schematic diagram of transmission provided by an embodiment of this application.
- FIG. 9 is another schematic diagram of transmission provided by an embodiment of this application.
- Fig. 10 is an enlarged view of a part of frequency domain resources of a time slot in Fig. 9;
- FIG. 11 is a schematic diagram of a resource structure in a time slot provided by an embodiment of the application.
- FIG. 12 is another schematic diagram of transmission provided by an embodiment of this application.
- FIG. 13 is another schematic diagram of transmission provided by an embodiment of this application.
- FIG. 14 is a method flowchart of a receiving processing method according to an embodiment of the application.
- FIG. 15 is a structural block diagram of a receiving processing apparatus provided by an embodiment of the application.
- a sidelink communication system when there is a business to be transmitted between User Equipment (UE, also called a terminal), the UE The service does not pass through the network side, that is, does not pass through the cellular link between the UE and the base station, but is directly transmitted by the data source UE to the target UE through Sidelink.
- This direct communication mode between the UE and the UE has a greater To a certain extent, it is different from the characteristics of the traditional cellular system communication mode.
- Typical applications of sidelink communication include device-to-device (D2D) communication and vehicle-to-everything (V2X) communication.
- D2D device-to-device
- V2X vehicle-to-everything
- V2X Vehicle to Vehicle
- V2P Vehicle to Pedestrian
- V2I Vehicle to Infrastructure
- Sidelink communication not only saves wireless spectrum resources, but also reduces the data transmission pressure of the core network, which can reduce system resource occupation, increase the spectrum efficiency of cellular communication systems, and reduce communication delays. And to a large extent save network operating costs.
- the terminal indicates the current PSSCH resource allocation through an SCI, and also indicates which resources are reserved by the terminal at the same time. Other terminals obtain the current PSSCH resource allocation status and resource reservation status of the terminal through the reception of the SCI.
- Figures 1 and 2 are both schematic diagrams of transmission provided by an embodiment of the present application.
- the Physical Sidelink Control Channel may be the PSCCH that schedules a single sub-channel PSSCH, or it may be the PSSCH that schedules a variable number of sub-channels. PSCCH.
- V2X communication there are two ways to select resources.
- One way is through the scheduling of a central node (for example, a base station), the central node determines the resources used by the device for transmission, and informs the terminal through signaling.
- the other method is the resource selection method based on competition.
- the device monitors the usage of resources within the resource pool, and through the monitoring results, it autonomously chooses to send signaling/data in the resource pool. Resources.
- the terminal performs two processes of resource sensing and resource selection.
- the sensing process the terminal obtains the reserved resource information of other terminals and RSRP (Reference Signal Receiving Power) information through the reception of the SCI.
- the terminal excludes some high-interference resources based on the sensing result in the sensing operation, for example, within the resource selection window, excludes resources reserved by other terminals and whose RSRP is higher than a preset threshold.
- the terminal further selects resources from the remaining resources for sending V2X data and signaling.
- the terminal uses L consecutive sub-channels as a resource unit to select and exclude resources.
- FIG. 3 is a schematic diagram of a channel structure provided by an embodiment of the application. As shown in Figure 3, each sub-channel includes multiple consecutive resource blocks. It can be seen from the above introduction that in the process of resource perception and resource selection, it is necessary to obtain resource reservations of other terminals. Regarding resource allocation and resource reservation, instructions are given through SCI.
- Fig. 4 is a method flowchart of a method for indicating resource reservation and resource allocation provided by an embodiment of the application. As shown in FIG.
- the method for indicating resource reservation and resource allocation includes: step S410, obtaining the number of scheduled PSSCH and reserved PSSCH subchannels; step S420, determining the scheduled PSSCH and the number of reserved PSSCHs according to the number of subchannels. Frequency domain resources and time domain resources of the reserved PSSCH; step S430, indicating the frequency domain resources and time domain resources of the scheduled PSSCH and the reserved PSSCH.
- the embodiment of the present application provides an indication method to avoid the problem that the receiving terminal cannot determine the frequency domain bandwidth and the frequency domain position for receiving the PSSCH.
- the embodiment of the present application provides an indication method, which may be executed by an indication device, which may be implemented by software and/or hardware, and is usually integrated in a terminal.
- the indication method includes: instructing at least one of the following according to an indication manner through a first channel: the type of the first channel; the type of information carried in the first channel; the type of the second channel; the type of the first channel and the second The type of the channel; whether the specific bit in the information carried in the first channel is used for resource allocation of the second channel; wherein, within the set time interval, the frequency domain resources of the first channel and the frequency domain resources of the second channel overlap .
- This embodiment provides an indication method.
- the type of the first channel, the type of information carried in the first channel, the type of the second channel, the type of the first channel, and the type of the second channel are determined according to the indication mode through the first channel. , Whether a specific bit in the information carried in the first channel is used for one or a combination of one or several items in the resource allocation of the second channel is used to indicate operation, so that information about the first channel and/or the second channel is carried in the first channel Therefore, after other terminals receive the first channel, the frequency domain resource used to receive the second channel can be determined through the instruction information, which improves the reception accuracy.
- the set time interval contains one time slot, or contains multiple time slots.
- the frequency domain resources of the first channel and the frequency domain resources of the second channel overlap. It does not mean that all types of second channels and the first channel exist on the frequency domain resources in the set time interval. Overlap refers to that, among one or more types of second channels, at least one type of second channel overlaps with the first channel in frequency domain resources within a set time interval.
- Frequency domain resources include frequency domain bandwidth and frequency domain location.
- the frequency domain bandwidth of the first channel is fixed, and the frequency domain bandwidth of the second channel is fixed, that is, the frequency domain size of the first channel is fixed, and the frequency domain size of the second channel is also fixed.
- the frequency domain resource size of the first channel is fixed, which means that the terminal can know the frequency domain size of the first channel before receiving the first channel without any physical channel or physical signal indication before receiving the first channel.
- the frequency domain resource size of the second channel is fixed. It also means that the terminal can know the frequency of the second channel before receiving the second channel without passing any physical channel or physical signal indication. Domain size.
- the second channel is fixed, which means that the frequency domain size of the second channel is not indicated by physical layer signaling, but can be configured through RRC (Radio Resource Control) signaling to configure the frequency domain resources of the second channel size.
- RRC Radio Resource Control
- the frequency domain resource size of the second channel can be configured through RRC signaling, it can still be guaranteed that the frequency domain resource size of the second channel remains unchanged within a period of time (for example, within 100ms), so the second channel can still be fixed The size of the frequency domain resources.
- the first channel is a physical side link control channel.
- the first channel is used to carry side link control information.
- the second channel is a physical side link shared channel.
- the second channel is a physical side link control channel.
- the second channel carries side link control information.
- the second channel when the second channel is PSCCH, it carries SCI.
- the PSSCH when the second channel is the PSSCH, the PSSCH may also carry the SCI.
- Specific bits include: frequency domain resource allocation bits in side link control information, reserved frequency domain resource indication bits in side link control information, or frequency domain resource allocation bits and reserved frequency resources in side link control information. Domain resource indicator bit.
- the advance instruction method includes at least one of the following:
- Manner 1 Based on the sequence generated by the Radio Network Temporary Identifier (RNTI), the cyclic redundancy check (CRC) bit carried by the first channel is scrambled and indicated.
- RNTI Radio Network Temporary Identifier
- CRC cyclic redundancy check
- Manner 2 Based on the sequence generated by the wireless network temporary identification, the method of scrambling the payload carried by the first channel is indicated; wherein, the payload may include only SCI, or may include SCI and CRC.
- Manner 3 Bit indication of a specific position in the side link control information carried by the first channel.
- the information bits carried in the second channel are interception or repetition of the information bits in the first channel.
- the first channel has 20 bits. After modulating and encoding these 20 bits, the modulation symbols are obtained and then mapped to the first channel.
- the second channel replicates the 20 bits before modulation and decoding, and the second channel encodes and modulates them. After the modulation symbols are obtained, they are mapped to the second channel to obtain the information carried in the second channel.
- the information bits carried in the second channel are time-domain repetitions of modulation symbols on the time-frequency resources in the first channel. For example, suppose that the first channel has 20 bits. After modulating and encoding these 20 bits, the modulation symbols are obtained and then mapped to the first channel. The information carried in the second channel is obtained by time-domain repetition of modulation symbols.
- indicating the type of the first channel through the first channel may be: indicating whether the first channel is used to indicate the second channel of the fixed frequency domain bandwidth.
- indicating the type of the first channel through the first channel may be: indicating whether the first channel is used to indicate a second channel having the same frequency domain resource as the first channel.
- indicating the type of information carried in the first channel through the first channel may be: indicating whether the information carried in the first channel is used to indicate a second channel with a fixed frequency domain bandwidth.
- the indication of the type of information carried in the first channel through the first channel may be: indicating whether the information carried in the first channel is used to indicate a second channel having the same frequency domain resources as the first channel.
- the frequency domain resource of the second channel includes: the frequency domain resource of the second channel is the same as the frequency domain resource of the first channel, and/or the frequency domain resource of the second channel is the subchannel where the first channel is located.
- the first terminal indicates whether a specific bit in the SCI carried in the first channel is used for PSSCH frequency domain resource allocation.
- the first terminal indicates whether the frequency domain resource allocation bit (or reserved frequency domain resource indication bit) in the SCI is used for frequency domain resource allocation of the PSSCH.
- the first terminal arrives at an aperiodic service packet, and the aperiodic service packet is split into one or more TBs (Transport Blocks). Assume that the acyclic service package corresponds to one TB. For the transmission of the TB, it is assumed that the physical layer has transmitted a total of three times. The first transmission corresponds to the initial transmission of the TB (may be referred to as the initial transmission), and the remaining two transmissions are retransmissions of the TB.
- the first terminal uses specific bits in the SCI, for example, the SCI contains 40 bits of information, where the 6th to 10th bits are used to indicate the frequency domain resources of the PSSCH currently scheduled by the SCI. In addition, the 6th to 10th bits of information may also be used to indicate reserved PSSCH frequency domain resources.
- FIG. 5 is another schematic diagram of transmission provided by an embodiment of this application.
- the first transmission uses a fixed frequency domain bandwidth, and the fixed frequency domain bandwidth is one sub-channel.
- the first transmission of the TB it is mainly used to indicate the frequency domain resources reserved for the second transmission, so as to prevent other terminals from choosing to be reserved by the terminal and RSRP (Reference Signal Received Power) is higher than the threshold Resources.
- RSRP Reference Signal Received Power
- a single subchannel includes PSCCH and PSSCH, and the SCI is carried by the PSCCH.
- the first terminal indicates whether the resource allocation bit in the SCI is used to indicate the current PSSCH resource allocation.
- the first terminal indicates whether a specific bit in the current SCI is used for the frequency domain resource allocation of the current PSSCH in one of the following ways:
- scramble the CRC bit carried by the first channel to indicate whether the specific bit in the SCI is used for the frequency domain resource allocation of the second channel, including: using the sequence pair generated by the first RNTI number
- the CRC bits carried by the first channel are scrambled, which means that the specific bits in the SCI are not used for the frequency domain resource allocation of the second channel; the sequence generated by the second RNTI number is used to add the CRC bits carried by the first channel
- the scrambling operation such as the RNTI value numbered 200, indicates that a specific bit in the SCI is used for the frequency domain resource allocation of the second channel.
- scramble the payload carried by the first channel to indicate whether a specific bit in the SCI is used for the frequency domain resource allocation of the second channel, including: using the sequence pair generated by the first RNTI number
- the payload carried by the first channel is scrambled, which means that the specific bit in the SCI is not used for the frequency domain resource allocation of the second channel; the sequence generated by the second RNTI number is used to increase the payload carried by the first channel
- the scrambling operation such as the RNTI value numbered 200, indicates that a specific bit in the SCI is used for the frequency domain resource allocation of the second channel.
- indicating whether a specific bit in the SCI is used for frequency domain resource allocation of the second channel through a bit in a specific position in the side link control information carried in the first channel including: setting a specific bit in the SCI carried in the first channel The value of a bit in the position is 0, which means that the specific bit in the SCI is not used for the frequency domain resource allocation of the second channel; or, the value of a bit in the specific position is set to 1, which means that the specific bit in the SCI is used for the second channel Frequency domain resource allocation.
- PSCCH and PSSCH are transmitted in consecutive L subchannel regions, where L is an integer greater than zero.
- the PSCCH is located in the first subchannel among the L subchannels. The same manner as described above is used to indicate that the specific bit in the SCI is used for the second channel frequency domain resource allocation, which will not be repeated here.
- the second terminal obtains the current resource allocation bits in the SCI through the PSCCH detection, and the indication information about whether the resource allocation bits are used for the frequency domain resource allocation of the current PSSCH. If the current PSSCH frequency domain resource allocation is not used for the current PSSCH frequency domain resource allocation, the second terminal's receiving behavior for the current PSSCH is: the second terminal receives the current PSSCH according to the fixed frequency domain bandwidth, and the fixed frequency domain bandwidth is a sub-channel , And the sub-channel is the sub-channel corresponding to the PSCCH where the current SCI is located.
- the second terminal's receiving behavior for the current PSSCH is: the second terminal follows the indication of the current resource indicator bits (6-10 bits) in the SCI, Determine the starting position of the current PSSCH resource and the number of subchannels; receive the current PSSCH based on the starting position of the current PSSCH resource and the number of subchannels.
- the second terminal obtains the current SCI for indicating whether the frequency domain resource indicator bit is valid through the PSCCH detection, and 0 indicates that the frequency domain resource indicator bit is invalid, so the second terminal The terminal determines that the bit used to indicate the frequency domain resource in the SCI is invalid. It is determined that the frequency domain resource indicator bit in the SCI is not used for the frequency domain resource allocation of the second channel, and the second terminal's receiving behavior for the current PSSCH is: the second terminal receives the current PSSCH according to the frequency domain bandwidth of a subchannel, and the subchannel is The sub-channel corresponding to the PSCCH where the current SCI is located.
- the second terminal obtains the current SCI bit used to indicate whether the frequency domain resource is valid through the PSCCH detection, which means that the frequency domain resource indicator bit is valid, so the second The terminal determines that the bit used to indicate the frequency domain resource in the SCI is valid. It is determined that the frequency domain resource indicator bits in the SCI are used for the frequency domain resource allocation of the second channel, and the second terminal's receiving behavior for the current PSSCH is: the second terminal follows the indication of the current resource indicator bits (6-10 bits) in the SCI, Determine the starting position of the current PSSCH resource and the number of subchannels; receive the current PSSCH based on the starting position of the current PSSCH resource and the number of subchannels.
- the second terminal obtains the current SCI bit used to indicate whether the frequency domain resource is valid through the PSCCH detection, which indicates that the frequency domain resource indicator bit is valid, so the second terminal The terminal determines that the bit used to indicate the frequency domain resource indication in the SCI is valid. It is determined that the frequency domain resource indicator bits in the SCI are used for the frequency domain resource allocation of the second channel, and the second terminal's receiving behavior for the current PSSCH is: the second terminal follows the indication of the current resource indicator bits (6-10 bits) in the SCI, Determine the starting position of the current PSSCH resource and the number of subchannels; receive the current PSSCH based on the starting position of the current PSSCH resource and the number of subchannels.
- the first channel carries the indication information about the second channel, so that After receiving the first channel, other terminals can determine the frequency domain resources used to receive the second channel through the indication information, which improves the reception accuracy.
- the first terminal indicates the type of PSCCH. Further, the first terminal indicates whether the PSCCH is used to indicate a PSSCH with a fixed frequency domain bandwidth. If the PSCCH is not a PSSCH for scheduling a fixed frequency domain bandwidth, the frequency domain resources of the PSSCH are indicated by the resource allocation bit in the SCI. SCI is carried by PSCCH.
- the first terminal arrives at an aperiodic service package, and the aperiodic service package is split into one or more TBs. Assume that the acyclic service package corresponds to one TB. For the transmission of this TB, it is assumed that the physical layer has been transmitted three times in total.
- FIG. 6 is a schematic diagram of another transmission provided by an embodiment of the application. As shown in Figure 6, for three transmissions of the same TB, the first transmission uses a fixed frequency domain bandwidth, and the fixed frequency domain bandwidth is one sub-channel.
- the first terminal indicates whether the PSCCH is used to indicate the PSSCH of the fixed frequency domain bandwidth.
- the first terminal indicates whether the PSCCH is used to indicate the PSSCH of the fixed frequency domain bandwidth in one of the following ways:
- scrambling the CRC bits carried by the first channel to indicate whether the PSCCH is used to indicate the PSSCH with a fixed frequency domain bandwidth includes: using the sequence generated by the first RNTI number on the first channel The carried CRC bits are scrambled, which means that the PSCCH is used to indicate the PSSCH with a fixed frequency domain bandwidth; the sequence generated by the second RNTI number is used to scramble the CRC bits carried by the first channel, for example, the number 200 The RNTI value indicates that the PSCCH is used to indicate a PSSCH that is not a fixed frequency domain bandwidth.
- scramble the payload carried by the first channel to indicate whether the PSCCH is used to indicate the PSSCH with a fixed frequency domain bandwidth, including: using the sequence generated by the first RNTI number to perform the scrambling on the first channel
- the carried payload is scrambled, which means that the PSCCH is used to indicate the PSSCH with a fixed frequency domain bandwidth; the sequence generated by the second RNTI number is used to scramble the payload carried by the first channel, for example, the number 200
- the RNTI value indicates that the PSCCH is used to indicate a PSSCH that is not a fixed frequency domain bandwidth.
- indicating whether the PSCCH is used to indicate a PSSCH with a fixed frequency domain bandwidth through a bit in a specific position in the side link control information carried in the first channel including: setting a bit in a specific position in the SCI carried in the first channel The value of is 0, which means that the PSCCH is used to indicate a PSSCH with a fixed frequency domain bandwidth; or, the value of a bit in the specific position is set to 1, which means that the PSCCH is used to indicate a PSSCH with a fixed frequency domain bandwidth.
- PSCCH and PSSCH are transmitted through consecutive L subchannel regions, where L is an integer greater than zero.
- the PSCCH is located in the first subchannel among the L subchannels. The same manner as described above is used to indicate whether the PSCCH is used to indicate the PSSCH of the fixed frequency domain bandwidth, which will not be repeated here.
- the first terminal carries the indication information through the PSCCH in the above manner, and sends the SCI and data information through the PSCCH and PSSCH respectively.
- the second terminal obtains the indication information through PSCCH detection. If the indication information indicates that the PSSCH is a channel with a fixed frequency domain bandwidth, the second terminal's receiving behavior for the current PSSCH is: the second terminal receives the current PSSCH according to the frequency domain bandwidth of a subchannel, and the subchannel is the PSCCH where the current SCI is located Corresponding sub-channel.
- the second terminal's receiving behavior for the current PSSCH is: the second terminal determines the current PSSCH according to the indication of the frequency domain resource indicator bits (6-10 bits) in the current SCI The starting position of the resource and the number of subchannels; the PSSCH is received based on the starting position of the current PSSCH resource and the number of subchannels.
- the second terminal obtains that the bit in a specific position in the current SCI is 0 through PSCCH detection, and 0 means that PSCCH is a PSSCH used to indicate a fixed frequency domain bandwidth, and the second terminal receives the current PSSCH
- the behavior is: the second terminal receives the current PSSCH according to the frequency domain bandwidth of one subchannel, and the subchannel is a subchannel corresponding to the PSCCH where the current SCI is located.
- the second terminal obtains a bit of a specific position in the current SCI as 1, through detection of the PSCCH, and 1 indicates that the PSCCH is not a PSSCH used to indicate a fixed frequency domain bandwidth. Then the second terminal's receiving behavior for the current PSSCH is; the second terminal determines the starting position of the current PSSCH resource and the number of subchannels according to the indication of the resource indicator bits (6-10 bits) in the current SCI; based on the start of the current PSSCH resource Start position and number of sub-channels, and receive the current PSSCH.
- the second terminal obtains a bit of a specific position in the current SCI as 1, through detection of the PSCCH, and 1 indicates that the PSCCH is not a PSSCH for indicating a fixed frequency domain bandwidth. Then the second terminal’s receiving behavior for the current PSSCH is: the second terminal determines the starting position of the current PSSCH resource and the number of subchannels according to the indication of the resource indicator bits (6 to 10 bits) in the current SCI; based on the start of the current PSSCH resource Start position and number of sub-channels, and receive the current PSSCH.
- the first channel carries the indication information about the second channel, so that other terminals receive the first channel Later, the frequency domain resource for receiving the second channel can be determined through the indication information, which improves the receiving accuracy.
- indicating the type of the second channel includes: indicating whether the second channel is used to carry sensing information.
- the sensing information includes information obtained by receiving side link control information of other terminals, and/or reference signal received power measurement results.
- the terminal can exclude some high-interference resources based on the perception information.
- the implementation method is as described above and will not be repeated here.
- indicating the type of the second channel includes: indicating whether the second channel is used to carry resource reservation information.
- the resource reservation information may be information bits indicating which resources are reserved by the current terminal.
- indicating the type of the second channel includes: indicating whether the second channel carries empty packets.
- the first terminal indicates the type of PSSCH. Further, the first terminal indicates whether the PSSCH carries an empty packet (or called an empty data packet). SCI is carried by PSCCH.
- the first terminal arrives at an aperiodic service package, and the aperiodic service package is split into one TB.
- the physical layer has been transmitted twice.
- FIG. 7 is a schematic diagram of another transmission provided by an embodiment of this application. As shown in Figure 7, the first transmission corresponds to the initial transmission of the TB, and the second transmission is the retransmission of the TB.
- the first terminal transmits the PSCCH and PSSCH in a fixed frequency domain bandwidth, and the PSSCH in the fixed frequency domain bandwidth is used to carry empty packets.
- the first terminal indicates whether the current PSSCH carries an empty packet in one of the following ways:
- scrambling the CRC bits carried by the first channel to indicate whether the PSSCH carries empty packets including: using the sequence generated by the first RNTI number to add the CRC bits carried by the first channel
- the scrambling operation means that the PSSCH carries empty packets; the sequence generated by the second RNTI number is used to scramble the CRC bits carried by the first channel.
- the RNTI value numbered 200 means that the PSSCH does not carry empty packets.
- scrambling the payload carried by the first channel to indicate whether the PSCCH carries an empty packet including: using the sequence generated by the first RNTI number to add the payload carried by the first channel
- the scrambling operation means that the PSSCH carries empty packets; the sequence generated by the second RNTI number is used to scramble the payload carried by the first channel.
- the RNTI value numbered 200 means that the PSSCH does not carry empty packets.
- indicating whether the PSSCH carries a null packet through a bit in a specific position in the side link control information carried in the first channel including: setting a bit in a specific position in the SCI carried in the first channel to a value of 0, which means The PSSCH carries empty packets; or, setting a bit in the specific position to 1 indicates that the PSSCH does not carry empty packets.
- the second terminal learns whether the current PSSCH type is an empty data packet through the reception of the PSCCH.
- the filling bit is generated through the media access control layer, and the filling bit is sent to the physical layer; Fill bits are subjected to modulation and coding processing to obtain modulation symbols, and the modulation symbols are mapped on the second channel.
- padding bits are generated through the physical layer, the padding bits are modulated to obtain modulation symbols, and the obtained modulation symbols are mapped on On the second channel.
- padding bits are generated through the physical layer, and the padding bits are modulated and encoded to obtain modulation symbols, and the obtained modulation The symbols are mapped on the second channel.
- the method further includes: indicating that the first channel and/or the second channel are located in the first sub-channel in the target resource; wherein the target resource includes at least one sub-channel, that is, the target resource Contains one sub-channel or at least two consecutive sub-channels.
- the objects involved in the instruction may be the physical layer and the media access control layer of the same terminal.
- the objects involved in the indication may also be different terminals, that is, the current terminal indicates to other terminals.
- indicating that the first channel and/or the second channel are located in the first subchannel in the target resource may be indicating a resource set to the media access control layer through the physical layer. Selecting a target resource in the resource set by the medium access control layer indicates that the first channel and/or the second channel are located in the first subchannel of the target resource.
- the selection basis of the target resource can be random selection, sequential selection, or selection based on availability.
- the first sub-channel indicating that the first channel and/or the second channel are located in the target resource may also be indicating the resource allocation of the target resource through the side link control information, indicating that the first channel and/or the second channel are located in the target resource. In the first subchannel of the target resource.
- the sending mode of the first channel and the second channel may be: the physical layer of the terminal indicates (reports) the candidate resource set to the MAC (Medium Access Control) layer, and the MAC layer is in the physical layer.
- the set of layer indication (report) candidate resources one or more candidate resources are selected for sending data and signaling.
- Each resource in the candidate resource set contains L consecutive sub-channels, and L is an integer greater than zero.
- the resource selection method is: the physical layer indicates (reports) the candidate resource set to the MAC, and the MAC layer selects one or more candidate resources. For a candidate resource selected by the MAC layer, the MAC layer further selects the first subchannel among the L subchannels in the candidate resource, which is used for the transmission of V2X data and control signaling.
- the MAC layer After the first terminal has service arrival, the MAC layer indicates the number of sub-channels L and the length of the resource selection window to the physical layer. After the physical layer receives an indication from the MAC layer on the number of channels L and the number of resource selection window lengths, the physical layer obtains L and resource selection window information.
- the physical layer obtains the RSRP value of the unit resource in the resource selection window based on operations such as receiving SCI from other terminals and RSRP measurement.
- the time domain of the one resource unit is a time slot, and the frequency domain is L continuous subchannels.
- For a unit resource RSRP it is obtained by averaging the RSRP of L sub-channels in the unit resource.
- the terminal excludes unit resources whose RSRP is higher than the threshold, and obtains resource set A. Taking set A as the candidate resource set, the physical layer of the terminal indicates (reports) the candidate resource set to the MAC layer.
- the terminal further sorts the resources in resource set A by RSSI (Received Signal Strength Indicator), and selects resources with low RSSI energy to form the resources Set B.
- the terminal can use set B as a candidate resource set to indicate (report) to the MAC layer.
- each candidate resource in the candidate resource set received by the MAC layer contains L continuous subchannels.
- the MAC layer selects the first target candidate resource from the candidate resource set, and the MAC layer further selects the first target candidate resource.
- the first subchannel is used for data and signaling transmission.
- the illustration is illustrated by using FIG. 5 as an example.
- the MAC layer decides to perform three transmissions, the first transmission is the initial transmission of the TB, and the second and third transmissions are the retransmissions of the TB.
- the MAC layer selects a candidate resource from the candidate resource set, and only uses the first subchannel of the L subchannels in the candidate resource for sending data and signaling.
- the MAC layer selects a candidate resource from the candidate resource set, and all L subchannels in the candidate resource are used for data and signaling transmission.
- the frequency domain resource sizes of the initial transmission and retransmission of the same TB are different. If the terminal separately calculates the size of the two frequency domain resources to determine which resources are idle and can be used for the transmission of data and control information, additional resource selection complexity will be introduced. Through the above method, the physical layer of the terminal only needs to select idle resources according to a frequency domain resource size and report to the MAC layer, thereby saving the complexity of resource selection.
- a specific bit in the SCI indicates the resource allocation of the current PSSCH, indicating that the frequency domain resources of the current PSSCH are L continuous subchannels, but the first terminal is only in one of the L subchannels Send data and signaling on the Internet. For example, the terminal only sends data and signaling on the first subchannel among the L subchannels.
- FIG. 8 is another schematic diagram of transmission provided by an embodiment of this application.
- the first transmission is used for the initial transmission of a PSSCH
- the second and third transmissions are used for the retransmission of a PSSCH.
- the bits in the SCI used to indicate the PSSCH frequency domain resource allocation indicate that L consecutive sub-channel positions are used as the PSSCH frequency domain resource allocation.
- L subchannel frequency domain resources are indicated, however, the first terminal only transmits the PSSCH on the first subchannel of the L subchannels, that is, among the L subchannels, only the first subchannel is used to carry the first terminal's PSSCH.
- the bits in the SCI used to indicate the PSSCH frequency domain resource allocation indicate that L consecutive subchannel positions are used as the PSSCH frequency domain resource allocation.
- the first terminal transmits the PSSCH on all of the L subchannels.
- the second terminal After detecting the frequency domain resource allocation indication indicated by the SCI of the first terminal, the second terminal receives the PSSCH scheduled by the SCI according to the frequency domain resource allocation situation.
- the second terminal receives the PSSCH according to the L frequency domain subchannels indicated by the first terminal SCI.
- the initial PSSCH transmission is mainly used to indicate the reserved resources of the retransmission resources, and there is retransmission after the initial transmission. Therefore, it does not matter even if the second terminal cannot successfully receive the PSSCH transmitted for the first time. But doing so can bring additional benefits that reduce the indication overhead in the SCI.
- specific bits can be used to indicate the frequency domain resources of the scheduled resources at the same time, and the frequency domain resources of the reserved resources can be indicated at the same time.
- indicating the type of the second channel includes: indicating the format of the side link control information carried in the second channel through the first channel.
- the first channel is PSCCH and the second channel is PSSCH.
- the SCI signaling is divided into two parts.
- the first part (stage) of the SCI is carried by the first channel, and the second part (stage) of the SCI is carried by the second channel.
- the first stage of SCI it corresponds to an SCI format.
- the second stage of SCI two SCI formats are included.
- the frequency domain bandwidth and frequency domain position of the second channel used to carry the SCI are the same as those of the first channel.
- the frequency domain bandwidth and frequency domain position of the second channel used to carry the SCI are indicated by the first channel, and the first channel is not limited.
- the frequency domain bandwidth and frequency domain position of the second channel are the same as those of the first channel.
- the first terminal indicates the format of the side link control information carried in the second channel in one of the following ways:
- scrambling the CRC bits to indicate the format of the SCI carried by the second channel includes: using the sequence generated by the first RNTI number to scramble the CRC bits carried by the first channel Operation means that the format of the SCI carried by the second channel is the first SCI format; use the sequence generated by the second RNTI number to scramble the CRC bits carried by the first channel, for example, the RNTI value numbered 200 , Indicates that the format of the SCI carried by the second channel is the second SCI format.
- the format of the SCI carried in the second channel is the first SCI format; if the value of the bit is 1 , Indicates that the format of the SCI carried by the second channel is the second SCI format.
- FIG. 9 is a schematic diagram of another transmission provided by an embodiment of this application.
- the leftmost first channel indicates that the SCI format carried by the second channel is the first SCI format.
- the first channel in the middle indicates that the SCI format carried by the second channel is the second SCI format.
- the first channel on the far right indicates that the SCI format carried by the second channel is the second SCI format.
- Different SCI formats have different information bits in SCI. Or, although different SCI formats have the same number of SCI bits, at least a part of the bit positions in the SCI are used for different indication purposes.
- the first channel in addition to indicating the SCI format carried by the second channel through the first channel, the first channel may also be used to indicate which time-frequency resources are reserved by the terminal. This allows other terminals to avoid the reserved resources after receiving the reservation information and avoid resource conflicts between different terminals.
- the SCI carried by the second channel can be used to indicate the time-frequency resource allocation of the PSSCH.
- the SCI of the second channel When the SCI of the second channel is the first format, the SCI of the second channel does not include PSSCH time-frequency resource allocation information. However, the SCI of the second channel contains some other information, such as reserved bit information or reserved resource indication information.
- the SCI of the second channel When the SCI of the second channel is in the second format, the SCI of the second channel includes time-frequency resource allocation information of the PSSCH. But it does not include reserved bit information and reserved resource indication information.
- the time-frequency resource corresponding to the frequency domain resource position of the first channel removes GP (Guard Period, guard time interval) symbols and PSFCH (Physical Sidelink Feedback) CHannel, physical side link feedback channel) symbol, and the remaining resources are the target resource area.
- the SCI carried by the second channel is the first SCI format
- the resource location of the second channel is: within the frequency domain resource range of the first channel, except for the first channel and AGC (Automatic Gain Control) symbols And all remaining resources except PSFCH symbols.
- AGC Automatic Gain Control
- the GP (Guard Period) symbol is used to send and receive conversion symbols.
- the terminal usually receives before the GP symbol and transmits after the GP symbol. Or, the terminal usually transmits before the GP symbol and receives after the GP symbol.
- PSFCH Physical Sidelink Feedback Channel
- the terminal can receive feedback information from other terminals, and the terminal can also send feedback information to other terminals through the PSFCH.
- the first terminal transmits the SCI through the first channel and the second channel, and indicates the type of the second channel through the first channel.
- the first channel sent by the first terminal is received.
- the first stage SCI carried by the first channel is obtained, and through the reception of the first channel, the format of the side link control information carried in the second channel is determined.
- the second terminal determines the format of the side link control information carried in the second channel in one of the following ways:
- descrambling the CRC carried by the first channel, and determining the format of the SCI carried by the second channel includes: using the sequence generated by the first RNTI number to determine the format of the SCI carried by the first channel.
- CRC bits are descrambled, and CRC check is performed after descrambling. If the CRC check passes, it means that the format of the SCI carried by the second channel is the first SCI format; for the same reason, the second RNTI number is used.
- the sequence of, the CRC bit carried by the first channel is descrambled, and the CRC check is performed after descrambling. If the CRC check passes, it means that the format of the SCI carried by the second channel is the second SCI format.
- a bit in a specific position in the SCI carried in the first channel received by the terminal determines that the format of the SCI carried in the second channel is the first SCI format; if this bit If the value is 1, the terminal determines that the format of the SCI carried by the second channel is the second SCI format.
- the terminal determines the time-frequency resource position of the second channel as: within the set time zone (for example, the time slot where the first channel is located), the first Within the channel frequency domain resource range, all remaining resources except the first channel, AGC symbols, and PSFCH symbols.
- the terminal determines the position of the time-frequency resource of the second channel as: in the set time zone, the resource in the SCI carried in the second channel Indicates the frequency domain resource indicated by the bit.
- the receiving terminal After obtaining the time-frequency resource position of the second channel, the receiving terminal further receives the second channel.
- the first channel indicates the format of the side link control information carried in the second channel, so that the first channel carries the instruction information about the second channel, so that other terminals receive the first channel.
- the frequency domain resource used for receiving the second channel can be determined through the indication information, which improves the receiving accuracy.
- the first channel includes PSCCH and PSCCH DMRS used for PSCCH reception, and the PSCCH carries SCI.
- the time-frequency resource corresponding to the frequency domain resource position of the first channel removes the GP symbol and the PSFCH symbol, and the remaining resource is the target resource area.
- the second channel is mapped on all remaining resources except the first channel in the target resource area.
- FIG. 11 is a schematic diagram of a resource structure in a time slot provided by an embodiment of the application. As shown in FIG. 11, the second channel is obtained by resource repetition on the first channel.
- the first channel includes 4 symbols, m RBs, and the numbers of the 4 symbols are 0, 1, 2, and 3, respectively.
- the second channel contains 7 symbols, numbered 4, 5, 6, 7, 8, 9, and 10.
- the frequency domain resource of the second channel is the same as the frequency domain resource of the first channel, and the second channel is obtained by performing symbol repetition on the first channel.
- the resources on the m RBs of the symbol numbered 4 in the second channel are obtained by duplicating the m RBs on the symbol numbered 0 in the first channel.
- the resources on the m RBs of the symbol numbered 5 in the second channel are obtained by duplicating the m RBs on the symbol numbered 1 in the first channel.
- the resources on the m RBs of the symbol numbered 6 in the second channel are obtained by duplicating the m RBs on the symbol numbered 2 in the first channel.
- the resources on the m RBs of the symbol numbered 7 in the second channel are obtained by duplicating the m RBs on the symbol numbered 3 in the first channel.
- the resources on the m RBs of the symbol numbered 8 in the second channel are obtained by duplicating the m RBs on the symbol numbered 0 in the first channel.
- the resources on the m RBs of the symbol numbered 9 in the second channel are obtained by duplicating the m RBs on the symbol numbered 1 in the first channel.
- the resources on the m RBs of the symbol numbered 10 in the second channel are obtained by duplicating the m RBs on the symbol numbered 2 in the first channel.
- the terminal transmits information through the first channel (PSCCH) and the second channel as shown in FIG. 11.
- indicating the type of the second channel includes: indicating whether there is side link control information of the second stage.
- the first channel is used to indicate whether there is a second-stage SCI, and then the type of the second channel is indicated according to the indication information. In this way of indicating, whether there is an association between the SCI of the second stage and the type of the second channel. If it indicates that there is no second-stage SCI, it means that the type of the second channel is the second channel of the first type. If it indicates that there is a second-stage SCI, it means that the type of the second channel is the second channel of the second type.
- the first channel is used to indicate whether there is side link control information of the second stage.
- Figures 12 and 13 are respectively another schematic diagrams of transmission provided by an embodiment of the application.
- the first channel is PSCCH
- the second channel is PSSCH, which is used to carry data information
- the third channel is PSSCH or PSCCH.
- SCI signaling is divided into two parts, the first part (phase) of the SCI is carried by the first channel (PSCCH), and the second part (phase) of the SCI is carried by the third channel.
- the second channel includes two types, with the following characteristics:
- the frequency domain resource of the second channel is the subchannel where the SCI of the first stage is located, and the time domain resource Within the same set time as the first stage of SCI.
- the frequency domain resource of the second channel is the frequency domain resource indicated by the second stage SCI, and the time domain resource is the same as the first stage
- the SCI is within the same set time, for example, in the same time slot as the SCI (Phase 2 SCI) of the first stage.
- the first terminal indicates whether there is a second-stage SCI in one of the following ways:
- scrambling the CRC bits based on the sequence generated by the RNTI indicates whether there is a second stage of SCI, including: using the sequence generated by the first RNTI number to scramble the CRC bits carried by the first channel, indicating the first The first-stage SCI has no corresponding second-stage SCI; the sequence generated by the second RNTI number is used to scramble the CRC bits carried by the first channel.
- the RNTI value numbered 200 indicates that the first-stage SCI has a corresponding The second stage of SCI.
- the leftmost first channel indicates that there is no second-stage SCI.
- the first channel in the middle indicates the second stage of SCI.
- the first channel on the far right indicates that there is a second stage of SCI.
- the information indicated by the SCI at the first stage includes reserved resource indication information.
- the reserved resource indication information includes the frequency domain resource indication bit of the reserved resource and the time domain resource indication bit of the reserved resource.
- the bits used to indicate the frequency domain resources of the reserved resources in the first stage SCI are also used to indicate the current frequency domain resources of the second channel. That is, the specific bit in the first stage SCI, the indicated frequency domain resource, indicates the frequency domain resource of the reserved resource, and also indicates the current frequency domain resource of the second channel.
- the specific bit in the first stage SCI indicates L continuous subchannel frequency domain resources as the current resource allocation indicator for the second channel, but the current second channel only occupies the first subchannel.
- indicating that the first channel and/or the second channel are located in the first subchannel in the target resource includes: indicating at least two consecutive subchannels, and performing operations on the remaining subchannels other than the first subchannel Puncturing processing; or, indicating at least two consecutive sub-channels, for the time-frequency resources corresponding to the at least two consecutive sub-channels in the set time interval, the remaining time excluding the time-frequency resources corresponding to the first channel Frequency resources are punched.
- indicating that the first channel and/or the second channel are located in the first subchannel in the target resource includes: indicating at least one subchannel, and performing rate matching on the first subchannel; or, indicating at least one For sub-channels, rate matching is performed on the frequency domain resources of the first channel.
- the second terminal receives the first channel. Through the reception of the first channel, the second terminal obtains the first-stage SCI carried by the first channel, and through the reception of the first channel, determines whether there is a second-stage SCI associated with the first-stage SCI.
- the second terminal determines whether there is second-stage side link control information by one of the following methods:
- the CRC bits carried by the first channel are descrambled, and then the CRC check is performed after descrambling. If the CRC check passes, it means that there is no second-stage SCI associated with the first-stage SCI; for the same reason, use the second one
- the sequence generated by the RNTI number is used to descramble the CRC bits carried by the first channel, and then perform a CRC check after descrambling. If the CRC check passes, it means that there is a second-stage SCI associated with the first-stage SCI .
- the terminal determines that there is no second-stage SCI associated with the first-stage SCI; if the value of this bit is If it is 1, the terminal determines that there is a second-stage SCI associated with the first-stage SCI.
- the second terminal After determining whether there is a second-stage SCI associated with the first-stage SCI, the second terminal determines the type of the second channel based on the presence or absence of the second-stage SCI. That is to say, whether there is a second-stage SCI is bound to the type of the second channel. If there is no second-stage SCI, it can be determined that the type of the second channel is the second channel of the first type. If there is a second-stage SCI, the terminal determines that the type of the second channel is the second type of the second channel.
- the manner in which the second terminal determines the frequency domain resource of the second channel of the first type includes at least one of the following manners:
- the frequency domain resources of the second channel are determined as follows: The channel is the second channel of the first type, and the frequency domain resource of the second channel is the first subchannel of the L subchannels indicated by the specific bit in the SCI.
- the frequency domain resource of the second channel based only on the indication of the second channel type: if the second channel is the second channel of the first type, the frequency domain resource of the second channel is the subchannel where the first channel is located, or The same frequency domain resource for the first channel.
- the second terminal further determines that the time-frequency resources of the second channel of the first type are: within the set time region (for example, the time slot where the first channel is located), and within the frequency domain resource range of the second channel determined by the second terminal, except All remaining resources except the first channel, AGC symbols, and PSFCH symbols.
- the second terminal determines the time-frequency resource location of the second channel as: in the set time region (for example, the time slot where the first channel is located), the frequency domain resource indicated by the second stage SCI , Remove all remaining resources except the first channel, third channel, AGC symbol, and PSFCH symbol.
- the second terminal After obtaining the time-frequency resource position of the second channel, the second terminal further receives the second channel.
- the first channel indicates whether there is side link control information of the second stage, so that the first channel carries the instruction information about the second channel, so that after other terminals receive the first channel ,
- the frequency domain resource used for receiving the second channel can be determined through the indication information, which improves the receiving accuracy.
- indicating the type of the second channel includes: indicating the purpose of the reserved bit information carried by the second channel.
- the purpose of indicating the reserved bit information carried by the second channel includes one of the following: indicating the version protocol of the second channel; indicating the protocol version of the information carried in the second channel.
- the first channel refers to PSCCH, which carries SCI.
- the second channel may be PSCCH or PSSCH, and is used to carry reserved bit information. Next, let's take the second channel as PSCCH as an example for description.
- the first channel indicates the type of the second channel
- the manner of indicating the type of the second channel may be one of the following methods: indicating whether the second channel carries reserved bit information; indicating the protocol version of the second channel ; Indicates the protocol version of the information (such as SCI) carried in the second channel.
- a bit in a specific position in the SCI carried by the first channel indicates the protocol version, which can be indicated as version 0 or version 1. If a bit in a specific position in the SCI is 0, it indicates version 0, and if a bit in a specific position in the SCI is 1, it indicates version 1.
- the value of the reserved bit information carried in the second channel is 0, indicating that the reserved bit information is not used to indicate any information.
- the reserved bit information carried in the second channel is used to indicate some information about the future protocol version. What information each bit area is used to indicate in the future version of the reserved bit information can be determined in the future version of the protocol.
- the second channel is not received.
- the second terminal of the future version receives the first channel of other transmitting terminals, if the version indicated by the first channel is version 0, the second channel is not received. If the version indicated by the first channel is version 1, then the second channel is received.
- the first channel is used to indicate whether the reserved bit information carried by the second channel is assigned a certain purpose, so that the first channel carries the indication information about the second channel, so that it can be received in other terminals. After arriving at the first channel, the indication information can be used to determine whether to receive the second channel.
- indicating the type of the second channel includes: indicating the type of the second channel through new data indication information and redundancy version indication information carried in the first channel.
- the method of indicating the type of the second channel through the first channel is: indicating the second channel through New Data Indicator (NDI) information and Redundant Version (RV) indicator information type.
- NDI New Data Indicator
- RV Redundant Version
- the frequency domain resources of the first channel overlap with the frequency domain resources of the second channel.
- the set time interval includes one time slot, or includes multiple time slots.
- the first channel is PSCCH, which is used to carry SCI
- the second channel is PSSCH.
- the frequency domain position of the second channel is: the subchannel where the first channel is located.
- the frequency domain bandwidth and frequency domain position of the second channel are indicated by the first channel.
- the type of the second channel is indicated through the first channel. It is indicated in the following manner: the NDI bit in the SCI carried by the first channel indicates the initial transmission, and the RV value indicated by the RV in the SCI is not equal to 0, indicating that the type of the second channel is the first type.
- the NDI bit in the SCI carried by the first channel indicates the initial transmission, and the RV value indicated by the RV indicator bit in the SCI is equal to 0, which indicates that the type of the second channel is the second type.
- the NDI bit in the SCI carried by the first channel indicates retransmission, and the type of the second channel is the second type.
- the first terminal terminal transmits V2X through the first channel and the second channel.
- the first channel sent by the first terminal is received.
- the NDI bit indication and the RV value are obtained.
- the type of the second channel is determined to be the first type; if the received NDI bit indicates the initial transmission and the RV value is equal to 0, then the type of the second channel is determined It is the second type; if the received NDI bit indicates a retransmission, the type of the second channel is the second type.
- the second terminal determines that the frequency domain resource of the second channel is: when the second channel is of the first type, the time-frequency resource position of the second channel is determined as: within the set time zone ( For example, the time slot where the first channel is located), in the sub-channel where the first channel is located, all remaining resources except the first channel, AGC symbols, and PSFCH symbols.
- the time-frequency resource location of the second channel is determined as: within the set time area (for example, the time slot where the first channel is located), the resource indicator bit in the SCI carried on the second channel
- the indicated frequency domain resources are all remaining resources except the first channel, AGC symbols, and PSFCH symbols.
- the second terminal After obtaining the time-frequency resource position of the second channel, the second terminal further receives the second channel.
- the type of the second channel is indicated by indicating the new data indication information and the redundancy version indication information carried in the first channel, so that the indication information about the second channel is carried in the first channel. Therefore, after other terminals receive the first channel, the frequency domain resource used to receive the second channel can be determined through the indication information, which improves the reception accuracy.
- FIG. 14 is a method flowchart of a receiving processing method provided by an embodiment of this application.
- the method may be executed by a receiving processing device, which may be implemented by software and/or hardware, and is usually integrated in a terminal. As shown in Figure 14, the method includes:
- Step 100 Receive a first channel, and obtain indication information of the first channel with respect to the first channel and/or the second channel.
- the frequency domain resources of the first channel overlap with the frequency domain resources of the second channel.
- obtaining the indication information of the first channel with respect to the first channel and/or the second channel may be: descrambling the cyclic redundancy check bit carried by the first channel based on the sequence generated by the temporary identification of the wireless network In the manner of obtaining the indication information of the first channel with respect to the first channel and/or the second channel.
- the payload carried by the first channel is descrambled to obtain the indication information of the first channel with respect to the first channel and/or the second channel.
- acquiring a bit at a specific position in the side link control information carried by the first channel and using the obtained bit at a specific position as the indication information.
- Step 200 Receive the second channel based on the indication information.
- the indication information is that the second channel carries an empty packet, then abandon the receiving operation on the second channel.
- receiving the second channel based on the indication information includes: when the indication information includes side link control information scheduled through the first channel, according to the frequency in the side link control information The frequency domain resource indicated by the domain resource allocation bit is received on the second channel; in the case that the indication information does not include side link control information scheduled through the first channel, according to the same frequency as the first channel Domain resources, receiving the second channel; in the case that the indication information does not include side link control information scheduled through the first channel, the second channel is received according to the sub-channel where the first channel is located.
- receiving the second channel based on the indication information includes: in a case where the indication information indicates that the second channel is a channel with a fixed frequency domain bandwidth, receiving the second channel according to the subchannel where the first channel is located In the case where the indication information indicates that the second channel is not a channel with a fixed frequency domain bandwidth, the second channel is received according to the frequency domain resource indicated by the frequency domain resource indicator bit carried by the first channel.
- receiving the second channel based on the indication information includes: when the indication information indicates that the second channel is a channel with a fixed frequency domain bandwidth, receiving the second channel according to the same frequency domain resource as the first channel Two channels; in the case where the indication information indicates that the second channel is not a channel with a fixed frequency domain bandwidth, the second channel is received according to the frequency domain resources indicated by the frequency domain resource indicator bits carried by the first channel.
- receiving the second channel based on the indication information includes: when the indication information indicates that the frequency domain resource indication bit carried by the first channel is not used to indicate the second channel with a fixed frequency domain bandwidth, according to The second channel is received by the same frequency domain resource as the first channel; when the indication information indicates that the frequency domain resource indicator bit carried by the first channel is used to indicate the second channel with a fixed frequency domain bandwidth, the second channel is carried according to the first channel The frequency domain resource indicated by the frequency domain resource indicator bit is used to receive the second channel.
- receiving the second channel based on the indication information includes: when the indication information indicates that the frequency domain resources of the first channel and the second channel are the same, according to the same frequency domain resources as the first channel Receiving the second channel; when the indication information indicates that the frequency domain resources of the first channel and the second channel are not the same, the frequency domain resources indicated by the frequency domain resource indicator bits carried by the first channel are compared to the second channel To receive.
- receiving the second channel based on the indication information includes: when the indication information indicates that the first channel and the second channel are the same sub-channel, receiving according to the same frequency domain resource as the first channel The second channel; in the case where the indication information indicates that the first channel and the second channel are not the same subchannel, the second channel is received according to the frequency domain resource indicated by the frequency domain resource indicator bit carried by the first channel.
- receiving the second channel based on the indication information includes: determining a frequency domain resource for receiving the second channel based on the type of the second channel and the resource allocation bits carried in the first channel; The frequency domain resource receives the second channel.
- determining the frequency domain resource for receiving the second channel based on the type of the second channel and the resource allocation bits carried in the first channel includes: when the type of the second channel is a channel with a fixed frequency domain bandwidth In the case of, it is determined that the first subchannel of the at least one subchannel indicated by the resource allocation bit carried in the first channel is used to receive the second channel; the type of the second channel is not a channel with a fixed frequency domain bandwidth. In this case, it is determined that at least one subchannel indicated by the resource allocation bit carried in the first channel is used for receiving the second channel.
- determining the frequency domain resource for receiving the second channel based on the type of the second channel and the resource allocation bits carried in the first channel includes: when the type of the second channel is a channel with a fixed frequency domain bandwidth In the case of, determine the sub-channel where the first channel is located, or the same frequency domain resource as the first channel is used to receive the second channel; in the case that the type of the second channel is not a channel with a fixed frequency domain bandwidth, determine the first channel At least one sub-channel indicated by the resource allocation bit carried in the second channel is used for receiving the second channel.
- the receiving the second channel based on the indication information includes: when the new data indication information indicates that the current transmission is an initial transmission, And when the redundancy version indication information is 0, the second channel is received according to the frequency domain resources indicated by the frequency domain resource indication bits carried in the first channel; when the new data indication information indicates that the current transmission is the first transmission, And when the redundancy version indication information is non-zero, the second channel is received according to one of the following: the same frequency domain resource as the first channel; the sub-channel where the first channel is located.
- the method further includes: acquiring sensing information carried by the second channel, and performing resource selection based on the sensing information, and the sensing information includes at least one of the following Information: Information obtained by receiving side link control information of other terminals; reference signal received power measurement results.
- the method further includes: when the received first channel and the second channel are located in the same sub-channel, measuring the received power of the reference signal of the second channel As a result, it is the measurement result of the reference signal received power of any subchannel in the target resource reserved by the first channel.
- the target resource reserved by the first channel includes at least one continuous subchannel.
- the receiving terminal can be regarded as the second terminal in the above solution, and the process of receiving the second channel based on the indication information is as described above, and will not be repeated here.
- An embodiment of the present application also provides an indication device, which implements the indication information on the first channel and/or the second channel to be carried in the first channel by executing the indication method.
- the device may be implemented by software and/or hardware, and is usually configured in a transmitting terminal.
- the device includes: an indication module, configured to indicate at least one of the following according to an indication manner through a first channel: the type of the first channel; The type of information carried in the channel; the type of the second channel; the type of the first channel and the type of the second channel; whether a specific bit in the information carried in the first channel is used for the resource allocation of the second channel; In a certain time interval, the frequency domain resources of the first channel and the frequency domain resources of the second channel overlap.
- the indicating device provided in the embodiment of the present application is configured to implement the indicating method of the foregoing embodiment, and the implementation principle and technical effect of the indicating device are similar to the indicating method, and will not be repeated here.
- FIG. 15 is a structural block diagram of a receiving processing apparatus provided by an embodiment of the application.
- the device executes the receiving processing method to receive the second channel based on the indication information on the first channel and/or the second channel in the first channel.
- the device can be implemented by software and/or hardware, and is usually configured in a receiving terminal.
- the device includes: an indication information obtaining module 300, which is used to receive a first channel, and obtain indication information about the first channel and/or the second channel of the first channel; and a receiving module 400, which is used to The instruction information receives the second channel.
- the frequency domain resources of the first channel overlap with the frequency domain resources of the second channel.
- the receiving processing device provided in the embodiment of the present application is configured to implement the receiving processing method of the foregoing embodiment.
- the implementation principle and technical effect of the receiving processing device are similar to the receiving processing method, and will not be repeated here.
- the embodiment of the present application provides a terminal including a memory and one or more processors; the memory is configured to store one or more programs; when the one or more programs are processed by the one or more The processor executes, so that the one or more processors implement the method described in the embodiment of the present application.
- the terminal provided above can be configured to execute the method provided in any of the above embodiments, and has corresponding functions and effects.
- the embodiment of the present application also provides a storage medium of executable instructions, and the computer-executable instruction implements the method described in the embodiment of the present application when executed by a computer processor.
- the block diagram of any logic flow in the drawings of the present application may represent program steps, or may represent interconnected logic circuits, modules, and functions, or may represent a combination of program steps and logic circuits, modules, and functions.
- the computer program can be stored on the memory.
- the memory can be of any type suitable for the local technical environment and can be implemented using any suitable data storage technology, such as but not limited to read-only memory (Read-Only Memory, ROM), random access memory (Random Access Memory, RAM), optical Memory devices and systems (Digital Versatile Disc (DVD) or Compact Disc (CD)), etc.
- Computer-readable media may include non-transitory storage media.
- the data processor can be any type suitable for the local technical environment, such as but not limited to general-purpose computers, special-purpose computers, microprocessors, digital signal processors (Digital Signal Processors, DSP), application specific integrated circuits (ASICs) ), programmable logic devices (Field Programmable Gate Array, FPGA), and processors based on multi-core processor architecture.
- DSP Digital Signal Processors
- ASICs application specific integrated circuits
- FPGA Field Programmable Gate Array
- processors based on multi-core processor architecture such as but not limited to general-purpose computers, special-purpose computers, microprocessors, digital signal processors (Digital Signal Processors, DSP), application specific integrated circuits (ASICs) ), programmable logic devices (Field Programmable Gate Array, FPGA), and processors based on multi-core processor architecture.
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Abstract
Description
Claims (50)
- 一种指示方法,包括:通过第一信道根据指示方式对以下至少之一进行指示:所述第一信道的类型;所述第一信道中承载的信息的类型;第二信道的类型;所述第一信道的类型和第二信道的类型;所述第一信道中承载的信息中特定比特是否用于第二信道的资源分配;其中,在设定时间区间内,所述第一信道的频域资源和第二信道的频域资源存在重叠。
- 根据权利要求1所述的方法,其中,所述第一信道的频域带宽是固定的,所述第二信道的频域带宽是固定的。
- 根据权利要求1所述的方法,其中,所述第一信道是物理边链路控制信道。
- 根据权利要求1所述的方法,其中,所述第一信道用于承载边链路控制信息。
- 根据权利要求1所述的方法,其中,所述第二信道承载感知信息。
- 根据权利要求1所述的方法,其中,所述第二信道是物理边链路共享信道。
- 根据权利要求1所述的方法,其中,所述第二信道是物理边链路控制信道。
- 根据权利要求6或7所述的方法,其中,所述第二信道承载边链路控制信息。
- 根据权利要求1所述的方法,其中,所述指示方式包括以下至少之一:基于无线网络临时标识产生的序列,对所述第一信道承载的循环冗余校验比特进行加扰的方式指示;基于无线网络临时标识产生的序列,对所述第一信道承载的有效载荷进行加扰的方式指示;通过所述第一信道承载的边链路控制信息中的特定位置的比特指示。
- 根据权利要求1所述的方法,其中,对所述第一信道的类型进行指示,包括:指示所述第一信道是否用于指示固定频域带宽的第二信道。
- 根据权利要求1所述的方法,其中,对所述第一信道的类型进行指示,包括:指示所述第一信道是否用于指示与所述第一信道具有相同频域资源的第二信道。
- 根据权利要求1所述的方法,其中,对所述第一信道中承载的信息的类型进行指示,包括:指示所述第一信道中承载的信息是否用于指示固定频域带宽的第二信道。
- 根据权利要求1所述的方法,其中,对所述第一信道中承载的信息的类型进行指示,包括:指示所述第一信道中承载的信息是否用于指示与所述第一信道具有相同频域资源的第二信道。
- 根据权利要求13所述的方法,其中,所述第二信道的频域资源包括以下至少之一:所述第二信道的频域资源与所述第一信道的频域资源相同;所述第二信道的频域资源为所述第一信道所在的子信道。
- 根据权利要求1所述的方法,其中,对所述第二信道的类型进行指示,包括:指示所述第二信道是否用于承载感知信息。
- 根据权利要求1所述的方法,其中,对所述第二信道的类型进行指示,包括:指示所述第二信道是否用于承载资源预留信息。
- 根据权利要求1所述的方法,其中,对所述第二信道的类型进行指示,包括:指示所述第二信道是否承载空包。
- 根据权利要求17所述的方法,其中,在所述第二信道承载空包的情况下,通过媒体接入控制层产生填充比特,并将所述填充比特发送给物理层;通过所述物理层对所述填充比特进行调制编码处理,得到调制符号,并将所述调制符号映射在所述第二信道上。
- 根据权利要求17所述的方法,其中,在所述第二信道用于承载空包的 情况下,通过物理层产生填充比特,对所述填充比特进行调制处理或调制编码处理,得到调制符号,并将所述调制符号映射在所述第二信道上。
- 根据权利要求1所述的方法,其中,对所述第二信道的类型进行指示,包括:指示所述第二信道中承载的边链路控制信息的格式。
- 根据权利要求1所述的方法,其中,对所述第二信道的类型进行指示,包括:指示所述第二信道所承载的预留比特信息的用途。
- 根据权利要求21所述的方法,其中,所述指示所述第二信道所承载的预留比特信息的用途,包括:指示所述第二信道的版本协议,或者,指示所述第二信道中承载的信息的协议版本。
- 根据权利要求1所述的方法,其中,对所述第二信道的类型进行指示,包括:通过所述第一信道中承载的新数据指示信息和冗余版本指示信息,对所述第二信道的类型进行指示。
- 根据权利要求1所述的方法,其中,所述第二信道中承载的信息比特为对所述第一信道中的信息比特的截取或重复。
- 根据权利要求1所述的方法,其中,所述第二信道中承载的信息比特为对所述第一信道中的时频资源上的调制符号的时域重复。
- 根据权利要求1所述的方法,其中,所述第二信道中承载的信息比特包括边链路控制信息和填充比特。
- 根据权利要求1所述的方法,还包括:指示所述第一信道和所述第二信道中的至少之一位于目标资源中的第一个子信道;其中,所述目标资源包含至少一个子信道。
- 根据权利要求27所述的方法,其中,所述指示第一信道和所述第二信道中的至少之一位于目标资源中的第一个子信道,包括:通过物理层向媒体接入控制层指示一个资源集合;通过所述媒体接入控制层在所述资源集合中选择目标资源,指示所述第一信道和所述第二信道中的至少之一位于所述目标资源的第一个子信道中。
- 根据权利要求27所述的方法,其中,所述指示所述第一信道和所述第二信道中的至少之一位于目标资源中的第一个子信道,包括:通过边链路控制信息指示目标资源的资源分配,指示所述第一信道和第二信道中的至少之一位于所述目标资源的第一个子信道中。
- 根据权利要求27所述的方法,其中,所述指示所述第一信道和所述第二信道中的至少之一位于目标资源中的第一个子信道,包括:指示至少两个连续的子信道,对第一个子信道以外的剩余子信道进行打孔处理;或者,指示至少两个连续的子信道,对设定时间区间内所述至少两个连续的子信道对应的时频资源中,除第一信道对应的时频资源以外的剩余时频资源进行打孔处理。
- 根据权利要求27所述的方法,其中,所述指示所述第一信道和所述第二信道中的至少之一位于目标资源中的第一个子信道,包括:指示至少一个子信道,在第一个子信道进行速率匹配;或者,指示至少一个子信道,在所述第一信道的频域资源上进行速率匹配。
- 一种接收处理方法,包括:接收第一信道,获得所述第一信道关于第一信道和第二信道中的至少之一的指示信息;基于所述指示信息接收所述第二信道;其中,在设定时间区间内,所述第一信道的频域资源与所述第二信道的频域资源存在重叠。
- 根据权利要求32所述的方法,其中,所述获得所述第一信道关于第一信道和第二信道中的至少之一的指示信息,包括:通过以下至少一种方式获得所述第一信道关于第一信道和第二信道中的至少之一的指示信息:基于无线网络临时标识产生的序列,对所述第一信道承载的循环冗余校验比特进行解扰;基于无线网络临时标识产生的序列,对所述第一信道承载的有效载荷进行解扰;获取所述第一信道承载的边链路控制信息中的特定位置的比特。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述 第二信道,包括:在所述指示信息是所述第二信道承载空包的情况下,放弃对所述第二信道执行接收操作。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:在所述指示信息包含通过所述第一信道调度的边链路控制信息的情况下,按照所述边链路控制信息中的频域资源分配比特所指示的频域资源,对所述第二信道进行接收;在所述指示信息不包含通过所述第一信道调度的边链路控制信息的情况下,按照与所述第一信道相同的频域资源,对所述第二信道进行接收;在所述指示信息不包含通过所述第一信道调度的边链路控制信息的情况下,按照所述第一信道所在的子信道接收所述第二信道。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:在所述指示信息指示所述第二信道是固定频域带宽的信道的情况下,按照所述第一信道所在的子信道接收所述第二信道;在所述指示信息指示所述第二信道不是固定频域带宽的信道的情况下,按照所述第一信道承载的频域资源指示比特所指示的频域资源,对所述第二信道进行接收。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:在所述指示信息指示所述第二信道是固定频域带宽的信道的情况下,按照与所述第一信道相同的频域资源接收所述第二信道;在所述指示信息指示所述第二信道不是固定频域带宽的信道的情况下,按照所述第一信道承载的频域资源指示比特所指示的频域资源,对所述第二信道进行接收。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:在所述指示信息指示所述第一信道承载的频域资源指示比特不用于指示固定频域带宽的第二信道的情况下,按照与所述第一信道相同的频域资源接收所述第二信道;在所述指示信息指示所述第一信道承载的频域资源指示比特用于指示固定 频域带宽的第二信道的情况下,按照所述第一信道承载的频域资源指示比特所指示的频域资源,对所述第二信道进行接收。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:在所述指示信息指示所述第一信道和所述第二信道的频域资源相同的情况下,按照与所述第一信道相同的频域资源接收所述第二信道;在所述指示信息指示所述第一信道和所述第二信道的频域资源不相同的情况下,按照所述第一信道承载的频域资源指示比特所指示的频域资源,对所述第二信道进行接收。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:在所述指示信息指示所述第一信道和所述第二信道是同一个子信道的情况下,按照与所述第一信道相同的频域资源接收所述第二信道;在所述指示信息指示所述第一信道和所述第二信道不是同一子信道的情况下,按照所述第一信道承载的频域资源指示比特所指示的频域资源,对所述第二信道进行接收。
- 根据权利要求32所述的方法,其中,所述基于所述指示信息接收所述第二信道,包括:基于所述第二信道的类型和所述第一信道中承载的资源分配比特,确定用于接收所述第二信道的频域资源;基于所述频域资源,对所述第二信道进行接收。
- 根据权利要求41所述的方法,其中,所述基于所述第二信道的类型和所述第一信道中承载的资源分配比特,确定用于接收所述第二信道的频域资源,包括:在所述第二信道的类型是固定频域带宽的信道的情况下,确定所述第一信道中承载的资源分配比特所指示的至少一个子信道中的第一子信道用于接收所述第二信道;在所述第二信道的类型不是固定频域带宽的信道的情况下,确定所述第一信道中承载的资源分配比特所指示的至少一个子信道用于接收所述第二信道。
- 根据权利要求41所述的方法,其中,所述基于第二信道的类型和所述第一信道中承载的资源分配比特,确定用于接收所述第二信道的频域资源,包括:在所述第二信道的类型是固定频域带宽的信道的情况下,确定所述第一信道所在的子信道,或者与所述第一信道相同的频域资源用于接收所述第二信道;在第二信道的类型不是固定频域带宽的信道的情况下,确定所述第一信道中承载的资源分配比特所指示的至少一个子信道用于接收所述第二信道。
- 根据权利要求32所述的方法,其中,在所述指示信息包括新数据指示信息和冗余版本指示信息的情况下,所述基于所述指示信息接收所述第二信道,包括:在所述新数据指示信息指示当前传输为初传,且所述冗余版本指示信息为0的情况下,按照所述第一信道中承载的频域资源指示比特所指示的频域资源,对所述第二信道进行接收;在所述新数据指示信息指示当前传输为初传,且所述冗余版本指示信息为非0的情况下,按照以下之一接收所述第二信道:与所述第一信道相同的频域资源;所述第一信道所在的子信道。
- 根据权利要求32所述的方法,在基于所述指示信息接收所述第二信道之后,还包括:获取所述第二信道承载的感知信息,基于所述感知信息进行资源选择,其中,所述感知信息包括以下至少一项信息:通过接收其它终端的边链路控制信息获取的信息;参考信号接收功率测量结果。
- 根据权利要求45所述的方法,在获取所述第二信道承载的参考信号接收功率测量结果之后,还包括:在接收的第一信道和第二信道位于同一个子信道内的情况下,将所述第二信道的参考信号接收功率测量结果,作为被所述第一信道预留的目标资源中任一子信道的参考信号接收功率测量结果;其中,被所述第一信道预留的目标资源包含至少一个子信道。
- 一种指示装置,包括:指示模块,设置为通过第一信道根据指示方式对以下至少之一进行指示:所述第一信道的类型;所述第一信道中承载的信息的类型;第二信道的类型;所述第一信道的类型和第二信道的类型;所述第一信道中承载的信息中特定比特是否用于第二信道的资源分配;其中,在设定时间区间内,所述第一信道的频域资源和第二信道的频域资源存在重叠。
- 一种接收处理装置,包括:指示信息获取模块,设置为接收第一信道,获得所述第一信道关于第一信道和第二信道中的至少之一的指示信息;接收模块,位置为基于所述指示信息接收所述第二信道;其中,在设定时间区间内,所述第一信道的频域资源与所述第二信道的频域资源存在重叠。
- 一种终端,包括:存储器,以及至少一个处理器;所述存储器,设置为存储至少一个程序;当所述至少一个程序被所述至少一个处理器执行,使得所述至少一个处理器实现权利要求1-46中任一所述的方法。
- 一种存储介质,存储有计算机程序,所述计算机程序被处理器执行时实现权利要求1-46中任一项所述的方法。
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WO2021159474A1 (zh) * | 2020-02-14 | 2021-08-19 | 北京小米移动软件有限公司 | 资源预留方法、装置及终端 |
CN113498200B (zh) * | 2020-03-19 | 2023-06-06 | 维沃移动通信有限公司 | 一种传输配置方法及终端 |
CN115399024A (zh) * | 2020-04-24 | 2022-11-25 | 华为技术有限公司 | 用于资源选择的方法和终端装置 |
CN115553005A (zh) * | 2020-05-21 | 2022-12-30 | Oppo广东移动通信有限公司 | 侧行反馈资源配置方法、终端设备和网络设备 |
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