WO2019091374A1 - 传输信息的方法和通信设备 - Google Patents
传输信息的方法和通信设备 Download PDFInfo
- Publication number
- WO2019091374A1 WO2019091374A1 PCT/CN2018/114175 CN2018114175W WO2019091374A1 WO 2019091374 A1 WO2019091374 A1 WO 2019091374A1 CN 2018114175 W CN2018114175 W CN 2018114175W WO 2019091374 A1 WO2019091374 A1 WO 2019091374A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- time
- sub
- transmission scheme
- uplink
- information
- Prior art date
Links
Images
Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
Definitions
- Embodiments of the present invention relate to the field of communication technologies, and, more particularly, to a method and a communication device for transmitting information.
- the time domain location and length of the time domain resource (hereinafter referred to as the uplink control channel time domain resource) of the information carried by the uplink control channel transmitted by the communication device are variable.
- the time domain location and length of the time domain resource (hereinafter referred to as the uplink shared channel time domain resource) of the information carried by the uplink shared channel transmitted by the communication device are also variable. Therefore, the uplink control channel time domain resource and the uplink shared channel time domain resource may overlap. In this case, it is an urgent problem to select what transmission scheme to transmit the information carried by the uplink control channel and the information carried by the uplink shared channel.
- the embodiment of the present application provides a method for transmitting information and a communication device, which can reasonably transmit the first uplink information and/or the second uplink information.
- the embodiment of the present application provides a method for transmitting information, where the method includes: determining, according to a second time domain resource, a target transmission scheme for transmitting first uplink information and second uplink information, where the first uplink is The information is carried by the uplink control channel, and the second uplink information is carried by the uplink shared channel, and the first time domain resource where the first uplink information is located and the second time domain resource where the second uplink information is located partially overlap in the time domain. Or all overlapping, the first time domain resource includes at least one symbol, the second time domain resource includes at least one symbol, and the first uplink information and/or the second uplink information is transmitted according to the target transmission scheme.
- the communication device may select an appropriate target transmission scheme by using the second time domain resource, so that the first uplink may be reasonably transmitted.
- Information and/or the second uplink information may be selected from the communication device.
- the second time domain resource is composed of N sub-time domain resources, where the N sub-time domain resources belong to N time slots or N mini-times respectively a slot, each of the N sub-time-domain resources is a time slot resource belonging to the second time domain resource in one time slot or one mini-slot, and N is a positive integer greater than or equal to 1,
- Determining, according to the second time domain resource, a target transmission scheme for transmitting the first uplink information and the second uplink information including: determining a set of available sub-time domain resources, where the available sub-time domain resource set includes M available sub-time domains a resource, wherein the available sub-time domain resource belongs to the N sub-time domain resources, and a start time of the available sub-time domain resource is not earlier than a difference between a start time of the first time domain resource and a first time length, and The start time of the available sub-time domain resource is not later than the sum of the end time of the first
- determining, according to the value of M, the target transmission scheme is a first transmission scheme, a second transmission scheme, At least one of the third transmission scheme, the fourth transmission scheme, the fifth transmission scheme, the sixth transmission scheme, and the seventh transmission scheme, including: M is equal to 1, determining that the target transmission scheme is the first transmission scheme; and M is equal to 0 Determining that the target transmission scheme is at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme; and/or M is a positive integer greater than 1, determining the target transmission The scheme is at least one of the sixth transmission scheme and the seventh transmission scheme.
- the foregoing technical solution may determine the target transmission scheme according to the number of available sub-time domain resources, and the number of available sub-time domain resources is different, and the scope of the target transmission scheme is also different. .
- the determining the target transmission scheme is the second transmission scheme, the third transmission scheme, and the fourth transmission At least one of the scheme and the fifth transmission scheme, including: determining, according to at least one of capability information of the terminal device, capability information of the network device, and priority information, the target transmission scheme as the second transmission scheme, the third At least one of the transmission scheme, the fourth transmission scheme, and the fifth transmission scheme, where the capability information of the terminal device is whether the terminal device supports sending uplink information on multiple channels at the same time, and the capability information of the network device is the network Whether the device supports receiving the uplink information sent by the same terminal device on multiple channels at the same time, the priority information is used to indicate the priority of the first uplink information and the priority of the second uplink information.
- the target transmission scheme can be determined by using at least one of capability information of the terminal device, capability information of the network device, and priority information.
- the determining is performed according to at least one of capability information of the terminal device, capability information of the network device, and priority information.
- the target transmission scheme is at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme, including: the terminal device supports sending uplink information on multiple channels at the same time, and/ Or the network device supports receiving the uplink information sent by the same terminal device on the multiple channels, and determining that the target transmission scheme is the second transmission scheme; the priority of the first uplink information is equal to the priority of the second uplink information.
- the target transmission scheme is the third transmission scheme; the priority of the first uplink information is greater than the priority of the second uplink information, determining that the target transmission scheme is the fourth transmission scheme; and/or, the The priority of an uplink information is less than the priority of the second uplink information, and the target transmission scheme is determined to be the fifth transmission scheme.
- the a transmission scheme is: transmitting the first uplink information on the part or all of the available sub-time domain resources; the second transmission scheme is: transmitting the first uplink information on the first time domain resource; the third transmission The solution is: transmitting the first uplink information on the third time domain resource, where the third time domain resource is from the end of the second time domain resource to the first time in the target time can be used to transmit the first a time domain resource of the uplink information, where the target time is the sum of the end time of the first time domain resource and the second time length; the fourth transmission scheme is: transmitting the first uplink information on the first time domain resource, and The second uplink information is punctured on the overlapping time domain resource or the information on the overlapping time-frequency resource, where the overlapping time domain resource is a time domain resource overlapping the first time domain resource and the second time domain resource, and the overlapping
- the specific available sub-time domain resource is the first available sub-time in the available sub-time domain resource set The domain resource, or the particular available sub-time domain resource is the first available sub-time domain resource in the set of available sub-time domain resources that carries the non-self-decoding redundancy version.
- the at least one available sub-time domain resource is all available sub-time domains in the available sub-time domain resource set The resource; or the at least one available sub-time domain resource is any available sub-time domain resource in the set of available sub-time domain resources that carries a non-self-decoding redundancy version.
- the a transmission scheme, a second transmission scheme, a third transmission scheme, a fifth transmission scheme, a sixth transmission scheme, and a seventh transmission scheme further comprising: transmitting second uplink information on the second time domain resource; and/or
- the fourth transmission scheme further includes: transmitting the first uplink information on the time domain resource except the overlapping time domain resource, or removing the overlapping time-frequency resource in the second time-frequency resource The first uplink information is transmitted on the time-frequency resource.
- a method for transmitting information includes: determining a first time domain resource for transmitting the first uplink information, where the first uplink information is carried by an uplink control channel uplink control channel, where The first time domain resource includes N symbols, and the N symbols belong to one time slot; and the second time domain resource for transmitting the second uplink information is determined, where the second uplink information is carried by the uplink shared channel uplink shared channel, where The second time domain resource includes M symbols, the M symbols belong to one time slot; the time slot to which the N symbols belong is the same as the M symbols, and the N symbols do not conflict with the M symbols and the first
- the one-time domain resource and the second time domain resource are consecutive time domain resources, and the target transmission scheme for transmitting the first uplink information and the second uplink information is determined.
- the foregoing technical solution proposes a method for selecting a transmission scheme in which the first time domain resource and the second time domain resource are consecutive time domain resources.
- the determining, by the target transmission scheme, the target transmission scheme is configured to use the target transmission scheme
- the first power sends the first uplink information and the second uplink information to the network device, where the first power is power used to send the first uplink information.
- determining the target transmission scheme for sending the first uplink information and the second uplink information includes: determining the target according to the total sending energy The transmission scheme is to discard the second uplink information and send the first uplink information by using the first power, or reduce the first power, and send the first uplink information and the second uplink information by using the reduced first power, where The first power is power for transmitting the first uplink information, where the total transmission energy is energy for transmitting the first uplink information and the second uplink information by using the first power.
- the foregoing technical solution can preferentially ensure that the first uplink information is sent.
- determining, according to the total transmit energy, the target transmission scheme is to discard the second uplink information and use the first power Sending the first uplink information, or reducing the first power, and transmitting the first uplink information and the second uplink information by using the reduced first power, including: a ratio of a preset threshold to the total transmit energy is greater than the first a preset value, determining that the target transmission scheme is to discard the second uplink information, and sending the first uplink information by using the first power; the ratio of the preset threshold to the total transmission energy is not greater than the first preset value, and determining
- the target transmission scheme is to reduce the first power and send the first uplink information and the second uplink information by using the reduced first power.
- the determining, by the target transmission scheme for transmitting the first uplink information and the second uplink information, determining that the target transmission scheme is The second power sends the first uplink information and the second uplink information to the network device, where the second power is power for transmitting the second uplink information.
- the foregoing technical solution can preferentially ensure that the second uplink information is sent.
- the determining, by the target transmission scheme, the first uplink information and the second uplink information, the determining the target according to the total sending energy is to discard the first uplink information and send the second uplink information by using the second power, or reduce the second power, and send the first uplink information and the second uplink information by using the reduced second power, where
- the second power is power for transmitting the second uplink information, where the total transmission energy is energy for transmitting the first uplink information and the second uplink information by using the first power.
- the determining, by the total transmit energy, the target transmission scheme is to discard the first uplink information and use the second power Transmitting the second uplink information, or reducing the second power, and sending the first uplink information and the second uplink information by using the reduced second power, including: a ratio of a preset threshold to the total transmit energy is greater than a second a preset value, determining that the target transmission scheme is to discard the first uplink information, and sending the second uplink information by using the second power; the ratio of the preset threshold to the total transmission energy is not greater than the second preset value, and determining
- the target transmission scheme is to reduce the second power and send the first uplink information and the second uplink information by using the reduced second power.
- the embodiment of the present application further provides a communication device, where the communication device includes a unit for implementing the first aspect or any possible implementation manner of the first aspect.
- the embodiment of the present application further provides a communication device, where the communication device includes a unit for implementing any of the possible implementations of the second aspect or the second aspect.
- an embodiment of the present application provides a communication device, where the communication device includes: a memory, configured to store a program, and a processor, configured to execute the program stored by the memory, when the program is executed, where The processor is for performing the method of the first aspect or any one of the possible implementations of the first aspect.
- the communication device is a chip or an integrated circuit.
- an embodiment of the present application provides a communications device, where the communications device includes: a memory, configured to store a program, and a processor, configured to execute the program stored by the memory, when the program is executed, where The processor is for performing the method of any of the possible implementations of the second aspect or the second aspect.
- the communication device is a chip or an integrated circuit.
- the embodiment of the present application provides a method for performing the first aspect or any one of the possible implementation manners of the first aspect.
- the embodiment of the present application provides a chip for performing any of the possible implementations of the second aspect or the second aspect.
- the embodiment of the present application provides a method for transmitting information, where the method includes: determining a first time-frequency resource, where the first time-frequency resource is a time-frequency resource of an uplink control channel, and the uplink control channel is used for carrying The uplink control information to be transmitted, the first time-frequency resource is in the first time unit, and the second time-frequency resource is determined, where the second time-frequency resource is a time-frequency resource of the uplink data channel, and the uplink data channel is used for carrying For the uplink data to be transmitted, the second time-frequency resource is composed of N sub-time-frequency resources, where the N sub-time-frequency resources are respectively located in N time units, and the first time-frequency resource and the second time-frequency resource overlap in the time domain.
- N is a positive integer greater than or equal to 2; according to the first time unit, uplink control information and uplink data are transmitted.
- the foregoing technical solution proposes a method for transmitting uplink control information and uplink data when the first time-frequency resource and the second time-frequency resource overlap in the time domain.
- the first time unit is one of the N time units.
- the N time unit numbers may be from 0 to N-1, or the N time unit numbers may be from 1 to N, and may be in a continuous or discontinuous manner.
- the N time units may be numbered in order from small to large or from large to small.
- the N time units may also adopt other numbering methods. There is no limit to this.
- the transmitting the uplink control information and the uplink data according to the time unit in which the first time domain resource is located including: transmitting the first sub-time-frequency resource The uplink control information and the uplink data, where the first sub-time-frequency resource is one of the N sub-time-frequency resources, and the number of the time unit in which the first sub-time-frequency resource is located and the first time The unit numbers are the same.
- the uplink control information and the uplink data may be transmitted by using the time-frequency resource occupied by the uplink data channel, and the uplink control information does not need to be discarded.
- the transmitting the uplink control information and the uplink data according to the first time unit including: transmitting the uplink control information in the first time-frequency resource, not Transmitting the uplink data on the second sub-time-frequency resource, and transmitting the uplink data on the sub-time-frequency resource other than the second sub-time-frequency resource in the second time-frequency resource, where the second sub-time-frequency resource is N sub-times A sub-time-frequency resource in the frequency resource, where the number of the time unit in which the second sub-time-frequency resource is located is the same as the number of the first time unit.
- the transmitting the uplink control information and the uplink data according to the first time unit including: transmitting, by using the M sub-time-frequency resources, the uplink control information and the Upstream data, wherein the M sub-time-frequency resources belong to the N sub-time-frequency resources, and the number of the time unit in which any one of the M sub-time-frequency resources is located is greater than or equal to the number of the first time unit, M Is a positive integer greater than or equal to 1 and less than N.
- the transmitting the uplink control information and the uplink data in the M sub-time-frequency resources including: determining the uplink control Transmitting, on the uplink data channel, a corresponding number of modulation coded symbols per layer; transmitting, according to the uplink control information, a corresponding number of modulation coded symbols per layer, determining a total number of modulation coding symbols of the uplink control information,
- the total modulation coding symbol of the uplink control information is divided into M parts, and the M parts are respectively transmitted on the M sub-time-frequency resources, and the total modulation coding symbol number of the M parts is equal to the total modulation coding of the uplink control information.
- the number of symbols including: determining the uplink control Transmitting, on the uplink data channel, a corresponding number of modulation coded symbols per layer; transmitting, according to the uplink control information, a corresponding number of modulation coded symbols per layer, determining a total number of modulation coding symbols of the uplink control information,
- the determining, by the uplink control information, the corresponding number of each layer of the modulation coding symbol on the uplink data channel including Determining, according to the total number of available resource particles in the M sub-time-frequency resources, determining, by the uplink control information, the number of corresponding modulation coded symbols per layer on the uplink data channel; or
- the uplink control information Determining, according to the number of available resource particles of one of the M sub-time-frequency resources, the uplink control information transmitting the corresponding number of modulation coded symbols per layer on the uplink data channel.
- the method before the transmitting the uplink control information and the uplink data according to the first time unit, further includes: receiving target transmission scheme indication information, where the target transmission scheme indication information is used to indicate a target transmission scheme; determining the target transmission scheme according to the target scheme indication information; and transmitting uplink control information according to the first time unit
- the uplink data includes: transmitting, according to the target transmission scheme, the uplink control information and the uplink data according to the first time unit.
- the target solution indication information is used to indicate that the target transmission scheme is a first transmission scheme or a second transmission scheme; Or the target scheme indication information is used to indicate that the target transmission scheme is the first transmission scheme or the third transmission scheme; or the target scheme indication information is used to indicate that the target transmission scheme is the second transmission scheme or the third transmission scheme.
- the first transmission scheme is: transmitting, by the fourth sub-time-frequency resource, the uplink control information and the uplink data, where the fourth sub-time-frequency resource is one of the N sub-time-frequency resources, where The number of the time unit in which the fourth sub-time-frequency resource is located is the same as the number of the first time unit;
- the second transmission scheme is: transmitting the uplink control information in the first time-frequency resource, and not transmitting on the fifth sub-time-frequency resource Transmitting, in the second time-frequency resource, the uplink data by using a sub-time-frequency resource other than the fifth sub-time-frequency resource, where the fifth sub-time-frequency resource is N sub- a sub-time-frequency resource in the frequency resource, where the number of the time unit in which the fifth sub-time-frequency resource is located is the same as the number of the first time unit;
- the third transmission scheme is: transmitting the uplink control in the T sub-time-frequency resources Information and the uplink data, where the T sub-time-frequency resources belong to the
- the embodiment of the present application further provides a communication device, where the communication device includes a unit for implementing any one of the possible implementations of the ninth aspect or the ninth aspect.
- the embodiment of the present application provides a communication device, where the communication device includes: a memory for storing a program; a processor, configured to execute the program stored by the memory, when the program is executed, The processor is operative to perform the method of any one of the possible implementations of the ninth aspect or the ninth aspect.
- the communication device is a chip or an integrated circuit.
- the embodiment of the present application provides a method for performing the ninth aspect or the ninth aspect of the possible implementation manner.
- Yet another aspect of the present application provides a computer readable storage medium having stored therein instructions that, when executed on a computer, cause the computer to perform the methods described in the various aspects above.
- Yet another aspect of the present application provides a computer program product comprising instructions that, when executed on a computer, cause the computer to perform the methods described in the various aspects above.
- FIG. 1 is a schematic flowchart of a method for transmitting information according to an embodiment of the present application.
- FIG. 2 is a schematic diagram of a method for transmitting information according to an embodiment of the present application.
- FIG. 3 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- FIG. 4 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- FIG. 5 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- FIG. 6 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- FIG. 7 is a schematic flowchart of another transmission method according to an embodiment of the present application.
- FIG. 8 is a structural block diagram of a communication device according to an embodiment of the present application.
- FIG. 9 is a structural block diagram of a communication device according to an embodiment of the present application.
- FIG. 10 is a structural block diagram of another communication device according to an embodiment of the present application.
- FIG. 11 is a structural block diagram of another communication device according to an embodiment of the present application.
- FIG. 12 is a schematic flowchart of another method for transmitting information according to an embodiment of the present application.
- FIG. 13 is a structural block diagram of another communication device according to an embodiment of the present application.
- FIG. 14 is a structural block diagram of another communication device according to an embodiment of the present application.
- the communication device referred to in the embodiment of the present application may be a terminal device.
- the terminal device referred to in the technical solution of the embodiment of the present application may also be referred to as an access terminal, a user equipment (UE), a subscriber unit, a subscriber station, a mobile station, a mobile station, a remote station, a remote terminal, and a mobile device.
- UE user equipment
- the terminal device can communicate with one or more core networks via a radio access network (RAN), or can access the distributed network in an ad hoc or unlicensed manner, and the terminal device can also access through other means.
- RAN radio access network
- the wireless network communicates, and the terminal device can directly perform wireless communication with other terminal devices. This embodiment of the present application does not limit this.
- the communication device referred to in the embodiment of the present application may also be a chip.
- the communication device referred to in the embodiment of the present application may also be a network device.
- the network device referred to in the embodiment of the present application may be a base station (gNB) in a 5G communication system, a base station or a network device in a future communication system, or the like.
- gNB base station
- the uplink control channel referred to in the embodiment of the present application may be a Physical Uplink Control Channel (PUCCH).
- PUCCH Physical Uplink Control Channel
- the uplink shared channel in the embodiment of the present application may also be referred to as an uplink data channel, and may be a physical uplink shared channel (PUSCH).
- PUSCH physical uplink shared channel
- FIG. 1 is a schematic flowchart of a method for transmitting information according to an embodiment of the present application. The method shown in Figure 1 can be performed by a communication device.
- the target transmission scheme for transmitting the first uplink information and the second uplink information is determined according to the second time domain resource, where the first uplink information is carried by the uplink control channel, and the second uplink information is carried by the uplink shared channel.
- the first time domain resource where the first uplink information is located and the second time domain resource where the second uplink information is located partially overlap or overlap in the time domain, the first time domain resource includes at least one symbol, and the second The time domain resource includes at least one symbol.
- the partial overlap of the first time domain resource and the second time domain resource in the time domain means that there is at least one symbol that belongs to both the first time domain resource and the second time domain resource.
- the first time domain resource and the second time domain resource all overlap in the time domain means that the first time domain resource is the same as the second time domain resource.
- the overlapping of the first time domain resource and the second time domain resource in the time domain may further include that the first time domain resource includes the second time domain resource or the second time domain resource includes the first time domain resource.
- the first uplink information may be uplink control information (UCI), including periodic channel state information (P-CSI) report, and semi-persistent channel state information (S).
- UCI uplink control information
- P-CSI periodic channel state information
- S semi-persistent channel state information
- -CSI at least one of a report, an Aperiodic Channel State Information (A-CSI) report, a Hybrid Automatic Request reQuest (HARQ) feedback message, and a Scheduling Request (SR) .
- the unit of the first time domain resource is a symbol.
- the first time domain resource may include a plurality of consecutive symbols.
- the information carried by the uplink control channel may be jointly transmitted in multiple time slots/mini time slots. In this case, the uplink information sent on the uplink control channel in each slot/mini slot can be considered as a single first uplink information.
- the uplink information transmitted on the uplink control channels of different time slots/mini time slots can be processed in the same manner.
- the second uplink information may be at least one of uplink data and A-CSI inclusion.
- the unit of the second time domain resource is a symbol.
- the second time domain resource may include a plurality of consecutive symbols, and may also include a plurality of symbols that are not consecutive.
- the embodiment shown in FIG. 1 discusses how to determine the target transmission scheme if the first time domain resource partially overlaps or completely overlaps the second time domain resource. When the first time domain resource does not overlap with the second time domain resource, how to transmit the first uplink information and the second uplink information is not within the scope discussed in the embodiment shown in FIG. 1.
- the communication device performing the method shown in FIG. 1 may be a terminal device, a chip that can be disposed in the terminal device, a network device, or a chip that can be disposed in the network device.
- the term "transmission" means that the communication device transmits to the network device.
- the term "transport” means that the communication device receives the terminal device for transmission.
- the “determining the target transmission scheme for transmitting the first uplink information and the second uplink information” in step 101 is to determine that the terminal device is configured to send the first uplink information. And a target transmission scheme of the second uplink information.
- the transmitting the first uplink information and/or the second uplink information in step 102 refers to receiving the first uplink information and/or the second uplink information sent by the terminal device.
- the first uplink information referred to in the following embodiments may refer to information carried by the uplink control channel
- the second uplink information may refer to information carried by the uplink shared channel.
- the second time domain resource may be composed of N sub-time domain resources, where the N sub-time domain resources belong to N time slots or N mini time slots, and each of the N sub-time domain resources is 1 All time domain resources belonging to the second time domain resource among the time slots or one mini time slot, and N is a positive integer greater than or equal to 1.
- the terminal device or a chip that can be disposed in the terminal device can determine the first time domain resource and the second time domain resource according to the indication of the network device. .
- the time domain resource indication information of the network device is received in the time slot n-5, where the time domain resource indication information is used to indicate that the first time domain resource is the fifth time slot after the time slot n-5
- the starting symbol is 1.
- it may be determined that the starting position of the first time domain resource is the second symbol of the time slot n, and n is an integer.
- the time domain resource indication information of the network device is received in the time slot n-5, where the time domain resource indication information is used to indicate that the second time domain resource is the fifth time slot after the time slot n-5.
- the starting symbol is 2.
- it may be determined that the starting position of the second time domain resource is the third symbol of the time slot n.
- the network device can also indicate the number of time slots in which the time domain resource continues.
- the time domain resource indication information may be used to indicate that the second time domain resource is the fifth time slot after the time slot n-5 and the start symbol is 2, and may also indicate that the second time domain resource continues. 2 time slots.
- the second time domain resource may include two sub-time domain resources, the starting position of the first sub-time domain resource is the third symbol of the slot n, and the starting position of the second sub-slot resource is the slot n. The second symbol of +1.
- the network device can also indicate the number of mini-slots in which the time domain resources continue.
- the time domain resource indication information may be used to indicate that the second time domain resource is the fifth minislot after the minislot n-5 and the start symbol is 2, and may also indicate the second time domain.
- the resource lasts 2 mini-slots.
- the second time domain resource may include two sub-time domain resources, the starting position of the first sub-time domain resource is the third symbol of the mini-slot n, and the starting position of the second sub-slot resource is mini. The third symbol of the gap n+1.
- the network device can also indicate the number of symbols that the time domain resource continues. For example, the network device may further indicate that the first time domain resource has a duration of 5 symbols; and the second time domain resource has a duration of 2 symbols.
- the communication device is a network device or a chip that can be disposed in the network device
- the network device or a chip that can be disposed in the network device can determine the first time domain resource and the second time domain by itself. Resources.
- determining, according to the second time domain resource, a target transmission scheme for transmitting the first uplink information and the second uplink information including: determining a set of available sub-time domain resources, where the available sub- The time domain resource set includes M available sub-time domain resources, wherein the available sub-time domain resources belong to the N sub-time domain resources, and the start time of the available sub-time domain resources is not earlier than the first time domain resource a difference between the start time and the first time length, and the start time of the available sub-time domain resource is no later than the sum of the end time of the first time domain resource and the second time length, and M is an integer greater than or equal to 0; Determining, according to the value of M, the target transmission scheme is at least one of a first transmission scheme, a second transmission scheme, a third transmission scheme, a fourth transmission scheme, a fifth transmission scheme, a sixth transmission scheme, and a seventh transmission scheme. .
- the value of the first time length may be 0 or may be calculated according to the minimum processing time required by the terminal device to receive the downlink shared channel to generate HARQ feedback information and the time slot data of receiving the downlink shared channel to the feedback HARQ feedback information.
- the maximum allowable delay of the corresponding HARQ feedback information may be 1 time slot or 14 symbols.
- the maximum allowable delay of the corresponding HARQ feedback information may be 2 slots or 28 symbols.
- the maximum allowable delay of the corresponding HARQ feedback information may be 0 slots or 0 symbols.
- the second time length may be a maximum allowable delay transmission delay threshold of the first uplink information.
- the second length of time may be indicated by the network device or determined according to the type of service or the like.
- M is equal to one. In this case, it may be determined that the target transmission scheme is the first transmission scheme.
- M is equal to zero. In this case, it may be determined that the target transmission scheme is at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme.
- M is a positive integer greater than one. In this case, it may be determined that the target transmission scheme is one of the sixth transmission scheme and the seventh transmission scheme.
- the communication device determines, according to the value of M, that the target transmission scheme is a first transmission scheme, a second transmission scheme, a third transmission scheme, a fourth transmission scheme, a fifth transmission scheme, a sixth transmission scheme, and At least one of the seventh transmission schemes includes: the communication device, when determining that M is equal to 1, determining that the target transmission scheme is the first transmission scheme; and determining that M is equal to 0, determining the target transmission
- the solution is at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme; if it is determined that M is a positive integer greater than 1, the target transmission scheme may be determined to be At least one of the sixth transmission scheme and the seventh transmission scheme.
- the communications device may determine, according to a preset rule or a network device indication, that the target transmission scheme is the sixth transmission scheme.
- the communications device may determine, according to a preset rule or a network device indication, that the target transmission scheme is the seventh transmission scheme.
- the communications device may determine, according to a preset rule or a network device indication, that the target transmission scheme is the sixth transmission scheme and the seventh transmission. Program.
- determining the target transmission scheme is at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme, including: according to the terminal device Determining that the target transmission scheme is at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme, at least one of capability information, capability information of the network device, and priority information.
- the capability information of the terminal device is whether the terminal device supports sending uplink information on multiple channels at the same time.
- the capability information of the network device is whether the network device supports receiving uplinks sent by multiple channels on the same terminal device.
- the priority information is used to indicate the priority of the first uplink information and the priority of the second uplink information.
- the priority information may be a specific level including the first priority and a specific level of the second priority. In this way, the first priority and the second priority can be directly compared according to the priority information.
- the priority information may be information that can indicate the first priority and the second priority.
- the priority information may be a Block Error Rate (BLER) of the first uplink information and a block error rate of the second uplink information.
- BLER1 Block Error Rate 1
- BLER2 Block Error Rate 2
- the first priority is equal to the second priority; if BLER1 is smaller than BLER2, the second priority is greater than the first priority; if BLER1 is greater than BLER2, the first priority is greater than This second priority.
- the priority information may further include a first preset value and a second preset value.
- the first priority and the second priority can be compared by comparing BLER1, BLER2, the first preset value, and the second AND setting.
- the first priority is greater than the second priority; if the BLER2/BLER1 is smaller than the second preset value, the first priority is smaller than the second priority Level; otherwise, the first priority is equal to the second priority.
- all or part of the priority information may be indicated by the network device.
- all or part of the information in the priority information may also be preset.
- BLER1 and BLER2 may be indicated by the network device, and the first preset value and the second preset value may be preset.
- BLER1, BLER2, the first preset value, and the second preset value may all be indicated by the network device.
- determining the target transmission scheme is the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission
- One of the solutions includes: receiving, by the network device, transmission scheme indication information, where the transmission scheme indication information is used to indicate that the target transmission scheme is the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the One of five transmission schemes; determining the target transmission scheme based on the transmission scheme indication information.
- the terminal device and the network device may further negotiate with each other to determine that the target transmission scheme is the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission.
- the target transmission scheme is the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission.
- One of the programs may be selected from the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission.
- the terminal device supports sending uplink information on multiple channels simultaneously. In this case, it may be determined that the target transmission scheme is the second transmission scheme.
- the network device supports simultaneously receiving uplink information sent by the same terminal device on multiple channels. In this case, it may be determined that the target transmission scheme is the second transmission scheme.
- the priority of the first uplink information is equal to the priority of the second uplink information. In this case, it may be determined that the target transmission scheme is the third transmission scheme.
- the priority of the first uplink information is greater than the priority of the second uplink information. In this case, it may be determined that the target transmission scheme is the fourth transmission scheme.
- the priority of the first uplink information is smaller than the priority of the second uplink information. In this case, it may be determined that the target transmission scheme is the fifth transmission scheme.
- the communication device can determine that the terminal device supports uplink information transmission on multiple channels and/or the network device supports simultaneous uplink information transmitted by the same terminal device on multiple channels.
- the target transmission scheme is the second transmission scheme; if it is determined that the priority of the first uplink information is equal to the priority of the second uplink information, the target transmission scheme may be determined as the third transmission scheme; In this case, the priority of the first uplink information is greater than the priority of the second uplink information, the target transmission scheme may be determined as the fourth transmission scheme; and the priority of the first uplink information is determined to be smaller than the second uplink information. In this case of priority, the target transmission scheme can be determined as the fifth transmission scheme.
- the first transmission scheme is: transmitting the first uplink information on the part or all of the available sub-time domain resources.
- the second transmission scheme is: transmitting the first uplink information on the first time domain resource.
- the third transmission scheme is: transmitting the first uplink information on the third time domain resource, where the third time domain resource is from the end of the second time domain resource
- the first time domain resource in the target time can be used to transmit the first uplink information, where the target time is the sum of the first time domain resource end time and the second time length.
- the fourth transmission scheme is: transmitting the first uplink information on the first time domain resource, and the second uplink information is on the overlapping time domain resource or the overlapping time-frequency resource.
- Information puncturing, the overlapping time domain resource is a time domain resource overlapping the first time domain resource and the second time domain resource, where the overlapping time-frequency resource is overlapped between the first time-frequency resource and the second time-frequency resource.
- the time-frequency domain resource, wherein the first time-frequency resource is a time-frequency resource for transmitting the first uplink information
- the second time-frequency resource is a time-frequency resource for transmitting the second uplink information.
- the fifth transmission scheme is: transmitting the first uplink information on the fourth time domain or the fourth time-frequency resource, and the first uplink information is in the overlapping time domain resource or The information on the overlapping time-frequency resource is punctured, and the fourth time domain resource is a time domain resource except the time domain resource in the overlapping time domain resource in the first time domain resource, where the fourth time-frequency resource is The time-frequency resource other than the overlapping time-frequency resource is removed from the first time-frequency resource.
- the sixth transmission scheme is: transmitting the first uplink information on a specific available sub-time domain resource in the available sub-time domain resource set.
- the seventh transmission scheme is: transmitting the first uplink information on at least one available sub-time domain resource in the available sub-time domain resource set.
- the specific available sub-time domain resource is the first available sub-time domain resource in the set of available sub-time domain resources.
- the specific available sub-time domain resource is the first sub-time domain resource in the set of available sub-time domain resources that carries the non-self-decoding redundancy version.
- the at least one available sub-time domain resource is all available sub-time domain resources in the set of available sub-time domain resources.
- the at least one available sub-time domain resource is all available sub-time domain resources in the set of available sub-time domain resources that bear non-self-decoding redundancy versions.
- the first transmission scheme, the second transmission scheme, the third transmission scheme, the fifth transmission scheme, the sixth transmission scheme, and the seventh transmission scheme further include, in the second time domain
- the second uplink information is transmitted on the resource.
- the fourth transmission scheme further includes: transmitting, on the time domain resource except the time domain resource in the overlapping time-frequency resource or the overlapping time domain resource in the second time domain resource. And transmitting, by the second uplink information, the first uplink information on the time-frequency resource except the overlapping time-frequency resource.
- the target transmission scheme is the fourth transmission scheme, that is, the first uplink information is transmitted on the first time domain resource, and the second uplink information is punctured on the overlapping time domain resource or the information on the overlapping time-frequency resource.
- the second time domain resource Transmitting, by the second time domain resource, the second uplink information on the time domain resource except the time domain resource in the overlapping time domain resource, where the overlapping time domain resource is the first time domain resource and a time domain resource that overlaps in the second time domain resource, where the overlapping time-frequency resource is a time-frequency domain resource that overlaps between the first time-frequency resource and the second time-frequency resource, where the first time-frequency resource is used for transmitting the A time-frequency resource of the first uplink information, where the second time-frequency resource is a time-frequency resource used for transmitting the second uplink information.
- the information of the second uplink information on the overlapping time domain resource may be punctured.
- the puncturing of the second uplink information on the overlapping time domain resource means that only the first uplink information is transmitted in the overlapping symbol. It is assumed that the first upper information information and the second uplink information are both transmitted in one time slot, and the start symbol of the second uplink information is symbol 2, which lasts for 8 symbols. That is to say, in the case where the first uplink information does not exist, the symbols 2, 3, 4, 5, 6, 7, 8, and 9 are used to transmit the second uplink information.
- the starting symbol of the first uplink information is symbol 7 and lasts 2 symbols. That is to say, in the case where the second uplink information does not exist, both symbol 7 and symbol 8 are used to transmit the first uplink information. Since the first uplink information and the second uplink information exist at the same time, the symbols 7 and 8 are overlapping symbols. In this case, the information of the second uplink information is not transmitted at symbol 7 and symbol 8, and the symbols 7 and 8 are used to transmit the first uplink information, and the information originally carried by symbol 7 and symbol 8 is no longer transmitted. .
- the second uplink information can be transmitted at symbols 2, 3, 4, 5, 6, 9.
- the target transmission scheme is the fifth transmission scheme, that is, transmitting the first uplink information in the fourth time domain, and the first An uplink information is punctured on the overlapping time domain resource or the information on the overlapping time-frequency resource, and the second uplink information is transmitted on the second time domain resource, where the fourth time domain resource is removed from the first time domain resource.
- the time domain resource outside the time domain resource in the overlapping time-frequency resource.
- the information of the first uplink information on the overlapping time domain resource may be punctured.
- the puncturing of the information of the first uplink information on the overlapping time domain resources in the embodiment of the present application means that only the second uplink information is transmitted in the overlapping symbols.
- the first upper information information and the second uplink information are both transmitted in one time slot, and the start symbol of the second uplink information is symbol 2, which lasts for 8 symbols. That is to say, in the case where the first uplink information does not exist, the symbols 2, 3, 4, 5, 6, 7, 8, and 9 are used to transmit the second uplink information. It is assumed that the starting symbol of the first uplink information is symbol 7 and lasts 2 symbols.
- both symbol 7 and symbol 8 are used to transmit the first uplink information. Since the uplink information 2 and the uplink information 3 exist at the same time, the symbols 7 and 8 are overlapping symbols. In this case, the information of the first uplink information is not transmitted in the symbol 7 and the symbol 8, the first uplink information originally carried by the symbol 7 and the symbol 8 is no longer transmitted, and the symbols 7 and 8 are still used for transmission. The second uplink information. In other words, the first uplink information is not transmitted in this case.
- time-frequency domain resources can be punctured in units of Resource Blocks (RBs).
- RBs Resource Blocks
- determining, according to the second time domain resource, a target transmission scheme for transmitting the first uplink information and the second uplink information including: determining at least one included in the second time domain resource The number of time slots Q to which the symbol belongs; the target transmission scheme is determined based on the value of Q.
- Q may be 1. In this case, it may be determined that the first target transmission scheme is one of the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme.
- the Q may be a positive integer greater than one.
- the first target transmission scheme, the second transmission scheme, the third transmission scheme, and the first target transmission scheme may be determined according to a slot position to which the at least one symbol included in the first time domain resource belongs One of the fourth transmission scheme, the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme.
- the selection range of the first target transmission scheme is also different.
- Q is a positive integer greater than 1
- the range of the first target transmission scheme is determined according to whether the value of Q is 1. It can be understood that the range of the first target transmission scheme can also be determined according to whether the value of Q is another value. For example, if the value of Q is a positive integer less than or equal to 2, it is determined that the first target transmission scheme is one of the first transmission scheme to the fourth transmission scheme; if Q is a positive integer greater than or equal to 3, The first target transmission scheme may be determined to be one of the first transmission scheme to the eighth transmission scheme according to a time domain location to which the at least one symbol included in the first time domain resource belongs.
- the selection range of the first target transmission scheme may also be changed accordingly. For example, if the value of Q is a positive integer less than or equal to 2, it is determined that the first target transmission scheme is the first transmission scheme or the second transmission scheme; if Q is a positive integer greater than or equal to 3, according to the Determining, by the first time domain resource, a time domain location to which the at least one symbol belongs, determining that the first target transmission scheme is one of the first transmission scheme to the fourth transmission scheme.
- the time slot to which the at least one symbol included in the first time domain resource belongs is the last one of the Q time slots.
- the first target transmission scheme is one of the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme.
- the time slot to which the at least one symbol included in the first time domain resource belongs is any time slot except the last one of the Q time slots.
- the available time slot set may be determined and determined according to the available time slot set
- the first target transmission scheme is the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme.
- the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme is the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme.
- the communication device may first determine a location of a time slot to which the at least one symbol included in the first time domain resource belongs in the Q time slots, and determine a time slot to which the at least one symbol included in the first time domain resource belongs In the case of the last one of the Q time slots, the first target transmission scheme may be determined to be one of the first transmission scheme to the fourth transmission scheme; and at least one of the first time domain resources is determined to be included If the time slot to which the symbol belongs is any one of the slots other than the last one of the Q time slots, the available time slot set may be determined and the first target transmission plan is determined according to the available time slot set. The first transmission scheme to one of the eighth transmission schemes.
- the selection range of the first target transmission scheme is also different.
- the time slot to which the at least one symbol included in the first time domain resource belongs is any time slot except the last one of the Q time slots, when determining the first target transmission scheme, Consider the available time slots.
- the time slot to which the at least one symbol included in the first time domain resource belongs is whether it is the last time slot of the Q time slots to determine the range of the first target transmission plan. It can be understood that the range of the first target transmission scheme can also be determined according to whether the time slot to which the at least one symbol included in the first time domain resource belongs is whether the other one of the Q time slots is.
- the time slot to which the at least one symbol included in the first time domain resource belongs is one of the last two slots in the Q time slots, determining that the first target transmission scheme is the first a transmission scheme to one of the fourth transmission schemes; if the time slot to which the at least one symbol included in the first time domain resource belongs is one of the first two slots in the Q time slots, Determining a set of available time slots and determining, according to the set of available time slots, the first target transmission scheme is one of the first transmission scheme to the eighth transmission scheme.
- the selection range of the first target transmission scheme may also be changed accordingly. For example, if the time slot to which the at least one symbol included in the first time domain resource belongs is the last one of the Q time slots, the first target transmission scheme may be determined as the first transmission scheme or the a second transmission scheme; if the time slot to which the at least one symbol included in the first time domain resource belongs is any one of the slots other than the last one of the Q time slots, the available time slot set may be determined And determining, according to the set of available time slots, the first target transmission scheme is one of the first transmission scheme to the fourth transmission scheme.
- the set of available time slots may be empty. In this case, it may be determined that the first target transmission scheme is one of the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme.
- the set of available time slots may be non-empty.
- the first target transmission scheme may be one of the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme.
- the communication device may determine whether the available time slot set is empty. If it is determined that the available time slot set is an empty set, determine that the first target transmission plan is one of the first transmission plan to the fourth transmission plan. And determining that the first target transmission scheme is one of the fifth transmission scheme to the eighth transmission scheme, in the case that the available time slot set is determined to be a non-empty set.
- the selection range of the first target transmission scheme is also different according to whether the available time slot set is an empty set.
- determining that the first target transmission scheme may be the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme may be according to a network device.
- the instructions are ok.
- the communication device may receive the indication information sent by the network device, where the indication information is used to indicate that the first target transmission scheme is the fifth transmission scheme if the available time slot set may be non-empty, a sixth transmission scheme, the seventh transmission scheme, or the eighth transmission scheme.
- determining that the first target transmission scheme may be one of the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme may be according to a pre- Set the rules to determine.
- the communication device may determine, according to a preset rule, that the first target transmission scheme is one of the fifth transmission scheme, the sixth transmission scheme, the seventh transmission scheme, and the eighth transmission scheme.
- the second uplink information includes a decodable redundancy version and/or a non-self-decoding redundancy version, it may be determined that the first target transmission scheme is the seventh transmission scheme or the eighth transmission scheme. If the second uplink information does not include a decodable redundancy version or a non-self-decoding redundancy version, it may be determined that the first target transmission scheme is the fifth transmission scheme or the sixth transmission scheme.
- determining that the first target transmission scheme is one of the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme including: according to service information. And determining, by the time information, the first target transmission scheme is one of the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme, where the service information includes a service requirement of an uplink control channel At least one of the information priority information, the time information includes a first time and a second time, the service requirement information of the uplink control channel is used to indicate whether the first uplink information is allowed to be delayed, and the priority information is used to indicate a first priority and a second priority, where the first priority is the priority of the first uplink information, and the second priority is the priority of the second uplink information, where the first time is the first uplink information The second moment is the starting moment of the second time domain resource.
- the first moment is no later than the second moment. In this case, it may be determined that the first target transmission scheme is the first transmission scheme.
- the first uplink information and the second uplink information are both sent in the time slot n, and the start symbol of the first uplink information is S1, and the start symbol of the second uplink information is S2.
- the remaining time from the start symbol of the first uplink information is t symbols. If S 1 -t ⁇ S 2 , the first moment is no later than the second moment. In other words, if S 1 -t ⁇ S 2 , there is sufficient time to generate the first uplink information before transmitting the second uplink information. If S 1 -t>S 2 , the first time is later than the second time. In other words, if S 1 -t>S 2 , there is not enough time to generate the first uplink information before transmitting to the second uplink information.
- the processing time necessary for generating the first uplink information is considered in the above technical solution.
- the first uplink information is allowed to be delayed and the first time is later than the second time and the first priority is equal to the second priority. In this case, it may be determined that the first target transmission scheme is the second transmission scheme.
- the first uplink information is allowed to be delayed and the first time is later than the second time and the first priority is greater than the second priority. In this case, it may be determined that the first target transmission scheme is the third transmission scheme.
- the first uplink information is allowed to be delayed and the first time is later than the second time and the first priority is less than the second priority. In this case, it may be determined that the first target transmission scheme is the fourth transmission scheme.
- the first uplink information does not allow delayed transmission and the first priority is greater than or equal to the second priority. In this case, it may be determined that the first target transmission scheme is the third transmission scheme.
- the first uplink information does not allow delayed transmission and the first priority is less than the second priority. In this case, it may be determined that the first target transmission scheme is the fourth transmission scheme.
- the communication device may first determine whether the first uplink information is allowed to be delayed, whether the first moment is later than the second moment, and whether the first priority is greater than two or all of the second priorities to determine the first A target transmission scheme. Specifically, the determining, by the communication device, that the first time is not later than the second time, determining that the first target transmission plan is the first transmission plan; determining that the first uplink information is allowed to be delayed, and If the first time is later than the second time and the first priority is equal to the second priority, the first target transmission plan may be determined as the second transmission plan; and the first uplink information is determined to be delayed.
- the first target transmission plan may be determined as the third transmission plan; If the first time is later than the second time and the first priority is less than the second priority, the first target transmission plan may be determined as the fourth transmission plan; If the information is not allowed to be delayed and the first priority is greater than or equal to the second priority, the first target transmission scheme may be determined as the third transmission scheme; A case where line information and the first allowed transmission delay priority is lower than the second priority, the first target may be determined transmission scheme for the fourth transmission scheme.
- a plurality of rules for determining that the first target transmission scheme is the first transmission scheme to the fourth transmission scheme are listed in the foregoing embodiment. It can be understood that, in some embodiments, all the above rules may be applied at the same time, or only some of the above rules may be applied. Moreover, those skilled in the art can also determine to utilize other rules for determining the first target transmission scheme based on the above rules.
- any one or all of the service requirement information and the priority information of the uplink control channel may be indicated by the network device to the communications device.
- Information not indicated to the communication device by the network device may be pre-set.
- the service requirement information of the uplink control channel and the priority information may be preset.
- the network device may indicate, by using a display manner, service requirement information of the uplink control channel and the priority information.
- the network device may indicate the service requirement information of the uplink control channel and the priority information in an implicit manner. For example, if the network device sends a compact downlink grant to the communication device, the information carried by the uplink control channel is not allowed to be delayed; if the network device sends a normal downlink grant to the communication device (normal downlink) Grant), the information carried by the uplink control channel is allowed to be delayed by 1 slot transmission.
- the service requirement information of the uplink control channel may be a service type.
- the service types include Enhanced Mobile Broadband (eMBB), Ultra-Reliable Low Latency Communication (URLLC), and Massive Machine-Type Communication (mMTC).
- eMBB Enhanced Mobile Broadband
- URLLC Ultra-Reliable Low Latency Communication
- mMTC Massive Machine-Type Communication
- the service type is URLLC
- the information carried by the uplink control channel does not allow delayed transmission.
- the service type is eMBB or mMTC
- the information carried by the uplink control channel is allowed to be transmitted. In this way, it can be determined whether the information carried by the uplink control channel allows delayed transmission by determining the type of service.
- the communication device can also determine the number of time slots allowed to be delayed to be transmitted according to the type of service. For example, if the service type is eMBB, the number of time slots allowed to be delayed is 1; if the service type is mMTC, the number of time slots allowed to be delayed is 2. The number of time slots allowed to be delayed may be preset or may be indicated by the network device to the communication device.
- the service requirement information of the uplink control channel may be a number of time slots that are allowed to be delayed. For example, if the information carried by the uplink control channel does not allow delayed transmission, the value of the number of time slots allowed to be delayed is 0; if the information carried by the uplink control channel allows delayed transmission T times, the allowed delayed transmission The value of the number of time slots is T, where T is a positive integer greater than or equal to one. In this way, it is possible to directly determine, according to the service requirement information of the uplink control channel, whether the information carried by the uplink control channel allows delayed transmission and allows the number of time slots to be delayed to be transmitted.
- the priority information may be a specific level including the first priority and a specific level of the second priority. In this way, the first priority and the second priority can be directly compared according to the priority information.
- the priority information may be information that can indicate the first priority and the second priority.
- the priority information may be a block error rate (BLER) of the first uplink information and a block error rate of the second uplink information.
- BLER1 block error rate of the first uplink information
- BLER2 block error rate of the second uplink information
- the first priority is equal to the second priority; if BLER1 is smaller than BLER2, the second priority is greater than the first priority; if BLER1 is greater than BLER2, the first priority is greater than This second priority.
- the priority information may further include a first preset value and a second preset value.
- the first priority and the second priority can be compared by comparing BLER1, BLER2, the first preset value, and the second AND setting.
- the first priority is greater than the second priority; if the BLER2/BLER1 is smaller than the second preset value, the first priority is smaller than the second priority Level; otherwise, the first priority is equal to the second priority.
- all or part of the priority information may be indicated by the network device.
- all or part of the information in the priority information may also be preset.
- BLER1 and BLER2 may be indicated by the network device, and the first preset value and the second preset value may be preset.
- BLER1, BLER2, the first preset value, and the second preset value may all be indicated by the network device.
- the first uplink channel information is periodic channel state information (P-CSI) report or semi-persistent channel state information (S-CSI). )report.
- P-CSI periodic channel state information
- S-CSI semi-persistent channel state information
- the first uplink channel information is Hybrid Automatic Request reQuest (HARQ) feedback information or an Aperiodic Channel State Information (A-CSI) report.
- HARQ Hybrid Automatic Request reQuest
- A-CSI Aperiodic Channel State Information
- the time at which the first uplink information is generated is not later than the start time of the second time domain resource.
- the first time slot in the set of available time slots is the first time domain resource (ie, the time slot to which at least one symbol included in the first time domain resource belongs), the available time slot set
- the last time slot is the Mth time slot after the first time domain resource, where M is the maximum number of time slots allowed for the first uplink information, and M is a positive integer greater than or equal to 1.
- the first uplink information is the HARQ feedback information or the A-CSI report, and the time at which the first uplink information is generated is later than the start time of the second time domain resource.
- the first time slot in the set of available time slots is the first time domain resource (ie, the time slot of at least one symbol included in the first time domain resource), the available time slot The last time slot of the set is the Mth time slot after the first time domain resource.
- the communications device may determine the available time slot set according to the type of the uplink information and the time when the first uplink information is generated. Specifically, in the case that the first uplink channel information is determined to be a P-CSI report or an S-CSI report, the first time slot in the set of available time slots may be determined as the first time domain resource (ie, the first The time slot to which the at least one symbol belongs to the time domain resource, the last time slot of the available time slot is the last time slot in the second time domain resource; determining that the first uplink channel information is HARQ feedback information Or the A-CSI reports that the time of generating the first uplink information is not later than the start time of the second time domain resource, and determining that the first time slot of the available time slot set is the first time a domain resource (that is, a time slot to which at least one symbol included in the first time domain resource belongs), and a last time slot of the available time slot set is an Mth time slot after the first time domain resource, where M is the The first time domain resource (ie,
- the first uplink information and the second uplink information are both sent in the time slot n, and the start symbol of the first uplink information is S1, and the start symbol of the second uplink information is S2.
- the remaining time from the start symbol of the first uplink information is t symbols. If S 1 -t ⁇ S 2 , the time at which the first uplink information is generated is not later than the start time of the second time domain resource. In other words, if S 1 -t ⁇ S 2 , there is sufficient time to generate the first uplink information before transmitting the second uplink information.
- the first transmission scheme is: transmitting the first uplink information and the second uplink information by using the uplink shared channel.
- the second transmission scheme is: determining whether to use the first time slot to transmit the first uplink information, where the first time slot is that at least one symbol included in the first time domain resource belongs to The next time slot of the time slot. In this way, if the first uplink information is not transmitted in conjunction with the second uplink information, the first uplink information may be delayed by one time slot processing. In this way, the first uplink information can be successfully sent with a certain probability and the first uplink information or the second uplink information does not need to be punctured.
- the third transmission scheme is: the second uplink information is included in the time slot to which the at least one symbol included in the first time domain resource belongs and at least the first time domain resource includes A symbol overlapping information is punched. Although part of the information of the second uplink information is punctured, part of the information is successfully transmitted. This will reduce the amount of information that needs to be retransmitted.
- the fourth transmission scheme is: the first uplink information is included in the time slot to which the at least one symbol included in the first time domain resource belongs, and at least the first time domain resource includes A symbol overlapping information is punched. Although part of the information of the first uplink information is punctured, part of the information is successfully transmitted. This will reduce the amount of information that needs to be retransmitted.
- the fifth transmission scheme is: receiving, in the first available time slot, the first uplink information sent by the terminal device by using the uplink shared channel, and the second uplink information. The information carried in the first available time slot.
- the sixth transmission scheme is: receiving, in all available time slots, the first uplink information sent by the terminal device by using the uplink shared channel, and the second uplink information is all available by the all Information carried by the time slot.
- the seventh transmission scheme is: when the at least one non-self-decoded redundancy version information is included in the second uplink information, carrying the at least one non-self-decoding redundancy
- the time slot of the first non-self-decoded redundancy version information in the version information receives the first uplink information sent by the terminal device through the uplink shared channel and the first non-self-decoded redundancy version information, where If the second uplink information includes only at least one self-decoded redundancy version information, the terminal device is received in a time slot carrying the first self-decoded redundancy version information of the at least one self-decoded redundancy version information.
- the first uplink information sent by the uplink shared channel and the first self-decoding redundancy version information can circumvent the self-decoding redundant version of the information carried by the uplink shared channel.
- the effect of jointly transmitting the first uplink information and the second uplink information on the second uplink information transmission is reduced.
- the eighth transmission scheme is: in the case that the second uplink information includes at least one non-self-decoded redundancy version information, in the at least one non-self-decoded redundancy version
- Each time slot of each non-self-decoded redundancy version information in the information receives the first uplink information sent by the terminal device through the uplink shared channel and the non-self-decoded redundancy version information, where In the case that the at least one self-decoded redundancy version information is included in the second uplink information, the terminal device is received in each time slot of each of the self-decoded redundancy version information in the at least one self-decoded redundancy version information.
- the first uplink information sent by the uplink shared channel and the each redundancy version information can circumvent the self-decoding redundant version of the information carried by the uplink shared channel.
- the effect of jointly transmitting the first uplink information and the second uplink information on the second uplink information transmission is reduced.
- the specific contents of the foregoing first transmission scheme to the eighth transmission scheme may also be adjusted. I will not list them here.
- the selection range of the first target transmission scheme may be all the transmission schemes in the foregoing first transmission scheme to the eighth transmission scheme.
- the selection range of the first target transmission scheme may also be a partial transmission scheme in the foregoing first transmission scheme to the eighth transmission scheme.
- the selection range of the first target transmission scheme may also be a partial transmission scheme in the foregoing first transmission scheme to the eighth transmission scheme, and other unillustrated transmission schemes.
- determining whether to use the first time slot to send the first uplink information includes: determining whether there is third uplink information in the first time slot, where the third uplink information is carried by the uplink shared channel Determining the result is yes (that is, using the first time slot to send the first uplink information), determining that the start symbol of the first time domain resource is 0, and determining that the second target transmission scheme is the first transmission scheme, the first One of the second transmission scheme, the third transmission scheme, and the fourth transmission scheme; the determination result is no (ie, the first uplink information is not sent by using the first time slot), and the first uplink information does not allow delayed transmission, And discarding the first uplink information; determining whether the first uplink information is sent by using the first time slot, and the first uplink information still allowing delayed transmission, determining whether the fourth uplink information exists in the second time slot, The fourth uplink information is carried by the uplink shared channel, and the second time slot is the next time slot of the first time slot.
- the specific process of one of the transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme is the same, and need not be described here.
- the first uplink information may continue to determine one of the first transmission scheme to the fourth transmission scheme as the target transmission scheme in the next time slot.
- the specific determining process is the same as the specific process of determining that the first target transmission scheme is one of the first transmission scheme, the second transmission scheme, the third transmission scheme, and the fourth transmission scheme. I won't go into details here.
- the number of time slots in which the first uplink information is allowed to be delayed is decremented by one.
- each common time slot of the multiple common time slots carries the first uplink information.
- the common time slot is a time slot carrying the first uplink information and the second uplink information at the same time.
- the number of bits of the first uplink information carried by each common time slot is the same.
- the number of bits of the first uplink carried by each common time slot of the K common time slots is 1/bit of the number of bits of the first uplink information carried by one common time slot.
- K where K is a positive integer greater than one.
- the first uplink information may be copied into 8 bits. That is to say, a total of 4 first uplink information is included. If the number of the common time slots is 1, the common time slot may carry the 8 bits of the first uplink information. If the number of the common slots is 2, each common slot may include 4 bits of first uplink information.
- each public time slot can carry two of the first uplink information.
- the number of the first uplink bits carried by each of the K common time slots is carried by a common time slot.
- the number of bits of the first uplink information is the same. For example, assume that the first uplink information includes 2 bits. The first uplink information may be copied into 8 bits. That is to say, a total of 4 first uplink information is included. If the number of the common time slots is 1, the common time slot may carry the 8 bits of the first uplink information. If the number of the common slots is 2, each common slot may include 8 bits of first uplink information. In other words, each common time slot can carry two of the first uplink information.
- FIG. 2 is a schematic diagram of a method for transmitting information according to an embodiment of the present application.
- the communication device determines to start transmitting uplink information 1 at symbol 1 of the nth slot.
- the uplink information 1 is carried by the uplink control channel.
- the uplink information 1 is HARQ feedback information.
- the uplink information 1 lasts 5 symbols.
- the first time length of the uplink information 1 is 0, and the second time length of the uplink information 1 is 1 time slot.
- the communication device determines to start transmitting uplink information 2 at symbol 2 of the nth time slot.
- the uplink information 2 is carried by the uplink shared channel.
- the communication device determines that the uplink information 2 is transmitted only in the nth time slot.
- the uplink information 2 lasts for 8 symbols.
- the communication device determines to start transmitting uplink information 3 at symbol 7 of the nth time slot.
- the uplink information 3 is carried by the uplink control channel.
- the uplink information 3 is A-CSI feedback information.
- the first time length of the uplink information 3 is 2 symbols, and the second time length of the uplink information 3 is 0.
- the uplink information 3 lasts 2 symbols.
- the time domain resource of the uplink information 1 partially overlaps with the time domain resource of the uplink information 2.
- the time domain resource of the uplink information 2 completely overlaps with the time domain resource of the uplink information 3.
- the second time domain resource may be composed of N sub-time domain resources, and the N sub-time domain resources belong to N time slots, and each of the N sub-time domain resources belongs to the first time domain resource.
- the second time domain resource is all time domain resources, and N is a positive integer greater than or equal to 1. It can be seen that, in the embodiment shown in FIG. 2, the second time domain resource includes one sub-time domain resource, and the sub-time domain resource is symbol 2 to symbol 9 in the nth time slot.
- the available sub-time domain resources belong to the N sub-time domain resources (hereinafter referred to as rule 1), and the start time of the available sub-time domain resources is not earlier than the start time of the first time domain resource and the first time length. a difference (hereinafter referred to as rule 2), and the start time of the available sub-time domain resource is not later than the sum of the end time of the first time domain resource and the second time length (hereinafter referred to as rule 3)
- the start time of the available sub-time domain resource is the symbol 2 of the nth time slot.
- the start time of the available sub-time domain resource is not earlier than the symbol 1 of the nth time slot.
- rule 3 it can be determined that the start time of the available time domain resource is not later than the symbol 6 of the n+1th slot.
- the available sub-time domain resource included in the available sub-time domain resource set is one sub-time domain resource included in the second time domain resource. Therefore, the value of M is equal to one.
- the target transmission scheme may be that the target transmission scheme is the first transmission scheme, that is, the first uplink information is transmitted on part or all of the available sub-time domain resources. Since the available sub-time domain set includes only one available sub-time domain, the uplink information 1 can be transmitted on the available sub-time domain resource and the second time domain resource (ie, the symbol 2 of the n-th time slot) Symbol 9) transmits the uplink information 2.
- the target transmission scheme may be at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme.
- the target transmission scheme may be determined as the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the first, according to at least one of capability information of the terminal device, capability information of the network device, and priority information. At least one of the five transmission schemes, wherein the capability information of the terminal device is whether the terminal device supports sending uplink information on multiple channels at the same time, and the capability information of the network device is whether the network device supports simultaneous reception by the same terminal device.
- the uplink information sent on the channel is used to indicate the priority of the first uplink information and the priority of the second uplink information.
- the target transmission scheme is the second transmission scheme. That is, the first uplink information is transmitted on the first time domain resource, and the second uplink information is transmitted on the second time domain resource.
- the uplink information 3 can be transmitted in the symbols 7 and 8 of the nth slot, and the uplink information 2 can be transmitted in the symbols 2 to 9 of the nth slot.
- the target transmission scheme is the third transmission scheme, that is, the first uplink information is transmitted on the third time domain resource
- the third The time domain resource is the first time domain resource that can be used to transmit the first uplink information from the end time of the second time domain resource to the target time, wherein the target time is the end time of the first time domain resource and The sum of the second length of time.
- the second time length of the uplink information 3 is 0. Therefore, the target moment is the end time of the first time domain resource.
- the uplink information 3 may not be transmitted, and the uplink information 2 may be transmitted in the symbols 2 to 9 of the nth slot.
- the target transmission scheme is the fourth transmission scheme, that is, transmitting the first uplink information on the first time domain resource, and the first
- the second uplink information is punctured on the overlapping time domain resource or the information on the overlapping time-frequency resource, and the first uplink information is transmitted on the time domain resource except the overlapping time domain resource, or
- the second time-frequency resource transmits the first uplink information on the time-frequency resource except the overlapping time-frequency resource, where the overlapping time-domain resource is a time-domain resource that overlaps between the first time domain resource and the second time domain resource,
- the overlapping time-frequency resource is a time-frequency domain resource that is overlapped between the first time-frequency resource and the second time-frequency resource, where the first time-frequency resource is a time-frequency resource used for transmitting the first uplink information, and the second time
- the frequency resource is a time-frequency resource used for transmitting the second uplink information.
- the uplink information 2 and the uplink information 3 overlap only in the time domain resources, so the information of the uplink information 2 on the overlapping time domain resources may be punctured.
- symbols 2, 3, 4, 5, 6, 7, 8, and 9 are used to transmit the uplink information 2.
- both symbol 7 and symbol 8 are used to transmit the uplink information 3.
- the information of the uplink information 2 is not transmitted in the symbol 7 and the symbol 8, and the symbols 7 and 8 are used to transmit the uplink information 3, and the uplink information 2 originally carried by the symbol 7 and the symbol 8 is no longer used. Being transmitted.
- Uplink information 2 can be transmitted at symbols 2, 3, 4, 5, 6, 9.
- the target transmission scheme is the fifth transmission scheme, that is, transmitting the first uplink on the fourth time domain resource or the fourth time-frequency resource.
- the information is punctured on the overlapping time domain resource or the information on the overlapping time-frequency resource, and the second uplink information is transmitted on the second time domain resource, where the fourth time domain resource is the first
- the time domain resource except the overlapping time domain resource is removed from the time domain resource
- the fourth time frequency resource is a time frequency resource except the overlapping time frequency resource in the first time frequency resource.
- the uplink information 2 and the uplink information 3 overlap only in the time domain resources, so the information of the uplink information 2 on the overlapping time domain resources may be punctured.
- symbols 2, 3, 4, 5, 6, 7, 8, and 9 are used to transmit the uplink information 2.
- both symbol 7 and symbol 8 are used to transmit the uplink information 3.
- uplink information 3 is not transmitted at symbol 7 and symbol 8, and symbol 7 and symbol 8 are used for transmitting uplink information 2.
- Uplink information 2 can be transmitted at symbols 2, 3, 4, 5, 6, 7, 89, and uplink information 1 is not transmitted.
- FIG. 3 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- the communication device determines to start transmitting uplink information 1 at symbol 1 of the nth slot.
- the uplink information 1 is carried by the uplink control channel.
- the uplink information 1 is HARQ feedback information.
- the uplink information 1 lasts 5 symbols.
- the first time length of the uplink information 1 is 0, and the second time length of the uplink information 1 is 1 time slot.
- the communication device determines to start transmitting uplink information 2 at symbol 2 of the nth time slot.
- the uplink information 2 is carried by the uplink shared channel.
- the communication device determines that the uplink information 2 is transmitted only in the nth time slot.
- the uplink information 2 lasts for 8 symbols.
- the communication device determines to start transmitting uplink information 3 at symbol 7 of the nth time slot.
- the uplink information 3 is carried by the uplink control channel.
- the uplink information 3 is HARQ feedback information.
- the first time length of the uplink information 3 is 0, and the second time length of the uplink information 3 is 1 time slot.
- the uplink information 3 lasts 2 symbols.
- the specific process of the communication device determining the transmission scheme for transmitting the uplink information 1 and the uplink information 2 is similar to the embodiment shown in FIG. 2, and need not be described here.
- the target transmission scheme may be at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme.
- symbol 3 to symbol 10 in slot n+1 are uplink resources 1, and uplink resource 1 can be used to transmit uplink information 3.
- the target transmission scheme is the third transmission scheme, that is, the first uplink information is transmitted on the third time domain resource
- the third The time domain resource is the first time domain resource that can be used to transmit the first uplink information from the end time of the second time domain resource to the target time, wherein the target time is the end time of the first time domain resource and The sum of the second length of time.
- the second time length of the uplink information 3 is 1 time slot. Therefore, the symbol 8 of the time slot n+1 at the target time.
- the uplink information 3 may be transmitted in the time domain resource between the symbols 3 to 8 of the n+1th slot, and the uplink information 2 may be transmitted in the symbols 2 to 9 of the nth slot.
- FIG. 4 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- the communication device determines to transmit uplink information 1 in the nth to n+3th slots.
- the starting symbol position in each slot is symbol 3 and the duration is 8 symbols.
- the first time length of the uplink information 1 is 0, and the second time length of the uplink information 1 is 0 time slots.
- the uplink information 1 is carried by the uplink control channel.
- the uplink information 1 is HARQ feedback information.
- the communication device determines to start transmitting uplink information 2 at symbol 2 of the nth time slot.
- the uplink information 2 lasts for 8 symbols.
- the uplink information 2 is carried by the uplink shared channel.
- the communication device determines to start transmitting uplink information 3 at symbol 3 of the n+2th slot.
- the uplink information 3 lasts for 10 symbols.
- the uplink information 2 is carried by the uplink shared channel.
- the information carried by the uplink control channel may be jointly transmitted in multiple time slots/mini time slots.
- the uplink information sent on the uplink control channel in each slot/mini slot can be considered as a single first uplink information.
- the uplink information transmitted on the uplink control channels of different time slots/mini time slots can be processed in the same manner. Therefore, for the uplink information 1, it can be considered as four uplink information. Therefore, it can be considered that the uplink information 1 transmitted in the nth slot is the uplink information 1a, and the uplink information 1 transmitted in the n+1th slot is the uplink information 1b, and the uplink information transmitted in the n+2th slot.
- the uplink information 1 is the uplink information 1c
- the uplink information 1 transmitted in the n+3th slot is the uplink information 1d.
- the uplink information 1a time domain resource overlaps with the time domain resource of the uplink information 2
- the time domain resource of the uplink information 1c overlaps with the time domain resource of the uplink information 3. Therefore, it is only necessary to consider how to determine the transmission scheme for transmitting the uplink information 1a and the uplink information 2, and the transmission scheme for transmitting the uplink information 1c and the uplink information 3.
- the uplink information 1b and the uplink information 1d can be directly transmitted.
- the target transmission scheme may be at least one of the second transmission scheme, the third transmission scheme, the fourth transmission scheme, and the fifth transmission scheme.
- the manner of transmitting the uplink information 1a and the uplink information 2 is similar to the manner of transmitting the uplink information 2 and the uplink information 3 in the embodiment shown in FIG. 2, and need not be described here.
- the start time of the available sub-time domain resource is the symbol 3 of the n+2th slot.
- the start time of the available sub-time domain resource is not earlier than the symbol 3 of the n+2th slot.
- it can be determined that the start time of the available sub-time domain resource is no later than the symbol 10 of the n+2th slot.
- the time domain resource for transmitting the uplink information 3 includes one sub-time domain resource, and the sub-time domain resource is the symbol 3 to the symbol 12 in the n+2th.
- the available sub-time domain resource included in the available sub-time domain resource set is the time domain resource used for transmitting the uplink information 3, and includes one sub-time domain resource. Therefore, the value of M is equal to one.
- the target transmission scheme may be that the target transmission scheme is the first transmission scheme, that is, the first uplink information is transmitted on part or all of the available sub-time domain resources. Since the available sub-time domain set includes only one available sub-time domain, the uplink information 1c can be transmitted on the available sub-time domain resource and the time domain resource for transmitting the uplink information 3 (ie, n+2) The symbol 3 to the symbol 12) transmits the uplink information 2.
- FIG. 5 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- the communication device determines that the uplink information 1 is transmitted at symbol 6 of the n+1th slot.
- the uplink information 1 is carried by the uplink control channel.
- the uplink information 1 is a P-CSI report.
- the uplink information 1 lasts for 3 symbols.
- the first time length and the second time length of the P-CSI report and the S-CSI report may be large, for example, may be a plurality of time slots. Therefore, in the following embodiment, the first time length of the uplink information 1 is 2 time slots, and the second time length of the uplink information 2 is 3 time slots.
- the communication device determines to start transmitting uplink information 2 at symbol 7 of the nth time slot.
- the uplink information 2 is carried by the uplink control channel.
- the uplink information 2 is HARQ feedback information.
- the first time length of the uplink information 2 is 0, and the second time length of the uplink information 2 is 1 time slot.
- the uplink information 2 lasts 2 symbols.
- the communication device determines to transmit uplink information 3 in the nth to n+3th slots.
- the starting symbol position in each slot is symbol 1 and the duration is 10 symbols.
- the uplink information 3 is carried by the uplink shared channel.
- the communication device determines to transmit the uplink information 4 at symbol 1 of the n+1th slot.
- the uplink information 4 is carried by the uplink control channel.
- the uplink information 4 is HARQ feedback information.
- the first time length of the uplink information 4 is 0, and the second time length of the uplink information 4 is 2 time slots.
- the uplink information 4 lasts for 4 symbols.
- the time domain resource used for transmitting the uplink information 3 may be composed of four sub-time domain resources, which belong to four time slots, that is, the nth time slot, the n+1th time slot, and the n+th. 2 time slots and n+3 time slots.
- Each of the four sub-time domain resources includes 10 symbols.
- the first sub-time domain resource of the four sub-time domain resources includes symbols 1 to 10 of the n-th time slot
- the second sub-time domain resource of the four sub-time domain resources includes the n+1th Symbol 1 to symbol 10 of the slot
- the third sub-time domain resource of the 4 sub-time domain resources includes symbols 1 to 10 of the n+2 time slots
- 4 sub-time domains of the 4 sub-time domain resources The resource includes symbols 1 through 10 of the n+3th slot.
- the available sub-time domain resource start time is the symbol 1 of the nth time slot, the symbol 1 of the n+1th time slot, and the n+2th time Symbol 1 of the slot or symbol 1 of the n+3th slot.
- the start time of the available sub-time domain resource is not earlier than the symbol 6 of the n-1th time slot.
- it can be determined that the start time of the available sub-time domain resource is not later than the symbol 8 of the n+4th slot.
- the available sub-time domain resource set includes four available sub-time domain resources, that is, the first sub-time domain resource to the fourth sub-time domain resource. That is, the value of M is 4.
- the target transmission scheme may be at least one of the sixth transmission scheme and the seventh transmission scheme.
- the terminal device determines that the target transmission scheme is the sixth transmission scheme, that is, transmits the first uplink information on a specific available sub-time domain resource in the available sub-time domain resource set and transmits the second uplink information on the second time domain resource.
- the second uplink information the terminal device may transmit the uplink information 1 on the specific available sub-time domain resource and in the second time domain resource (ie, symbol 1 to symbol 10 of the nth time slot, the n+1th The symbol 1 to symbol 10 of the slot, the symbols 1 to 10 of the n+2th slot, and the symbols 1 to 10 of the n+3th slot transmit the uplink information 3.
- the particular available sub-time domain resource may be the first available sub-time domain resource in the set of available sub-time domain resources, or the first available sub-time domain resource carrying a non-self-decoding redundancy version. .
- the terminal device may transmit the uplink information 1 on the at least one available sub-time domain resource and in the second time domain resource (ie, symbol 1 to symbol 10 of the nth slot, nth) Symbol 1 to symbol 10 of +1 slot, symbol 1 to symbol 10 of the n+2th slot and symbol 1 to symbol 10 of the n+3th slot transmit the uplink information 3.
- the at least one available sub-time domain resource is all available sub-time domain resources in the available sub-time domain resource set, or all bearer non-self-decoding redundancy versions in the available sub-time domain resource set Sub-time domain resources are available.
- the redundancy version (RV) versions on the nth time slot, the n+1th time slot, the n+2 time slot, and the n+3th time slot are RV0 and RV2, respectively.
- RV3 and RV1 where RV0 and RV3 are RV versions capable of self-decoding, and RV2 and RV1 are non-self-decoding RV versions.
- the target transmission scheme is the seventh transmission scheme and all available sub-time domain resources in the set of available sub-time domain resources carrying the non-self-decoding redundancy version
- the n+1th slot and the nth may be +3 time slots send the uplink information 1 to the network device.
- the number of bits used to carry the uplink information 1 in the n+1th time slot is the same as the number of bits used to carry the uplink information 1 in the n+3 time slots.
- the number of bits for carrying the uplink information 1 in the (n+1)th slot is 1/2 of the number of bits for mapping the uplink information 1 to one slot for transmitting the uplink information 3.
- the number of bits used to carry the uplink information 1 in the n+1th time slot is 10, and the number of bits used to carry the uplink information 1 in the n+3 time slots is also 10.
- RV1 is also a self-decoding RV version. In this case, only the n+1th slot can carry the uplink information 1.
- the number of bits used to carry the uplink information 1 in the (n+1)th time slot is 20. It can be understood that, since the number of time slots for carrying the uplink information 1 is increased, the number of bits used to carry the uplink information 3 in the n+1th slot and the n+3th slot is correspondingly reduced.
- the available sub-time domain resource start time is the symbol 1 of the nth time slot, the symbol 1 of the n+1th time slot, and the n+2th time Symbol 1 of the slot or symbol 1 of the n+3th slot.
- the start time of the available sub-time domain resource is not earlier than the symbol 7 of the nth time slot.
- it can be determined that the start time of the available sub-time domain resource is not later than the symbol 8 of the n+1th slot.
- the available sub-time domain resource set includes one available sub-time domain resource, that is, the second sub-time domain resource. That is, the value of M is 1.
- the target transmission scheme may be that the target transmission scheme is the first transmission scheme, that is, the first uplink information is transmitted on some or all of the available sub-time domain resources. Since the available sub-time domain set includes only one available sub-time domain, the uplink information 2 can be transmitted on the available sub-time domain resource and in the second sub-time domain resource (ie, the n+1th slot) Symbol 1 to symbol 10) transmits the uplink information 2.
- the available sub-time domain resource start time is the symbol 1 of the nth time slot, the symbol 1 of the n+1th time slot, and the n+2th time Symbol 1 of the slot or symbol 1 of the n+3th slot.
- the start time of the available sub-time domain resource is not earlier than the symbol 1 of the n+1th slot.
- it can be determined that the start time of the available sub-time domain resource is no later than the symbol 4 of the n+3th slot.
- the available sub-time domain resource set includes three available sub-time domain resources, namely, the second sub-time domain resource, the third sub-time domain resource, and the fourth sub-time domain resource. . That is, the value of M is a positive integer greater than one.
- the target transmission scheme may be at least one of the sixth transmission scheme and the seventh transmission scheme.
- the terminal device determines that the target transmission scheme is the sixth transmission scheme, that is, transmits the first uplink information on a specific available sub-time domain resource in the available sub-time domain resource set and transmits the second uplink information on the second time domain resource.
- the second uplink information the terminal device may transmit the uplink information 4 on the specific available sub-time domain resource and in the second time domain resource (ie, symbol 1 to symbol 10 of the n+1th slot, n+)
- the uplink information 3 is transmitted by symbols 1 to 10 of the 2 slots and symbols 1 to 10 of the n+3 slots.
- the particular available sub-time domain resource may be the first available sub-time domain resource in the set of available sub-time domain resources, or the first available sub-time domain resource carrying a non-self-decoding redundancy version. .
- the terminal device may transmit the uplink information 4 on the at least one available sub-time domain resource and in the second time domain resource (ie, symbol 1 to symbol 10 of the n+1th slot, The uplink information 3 is transmitted from symbol 1 to symbol 10 of the n+2th slot and symbol 1 to symbol 10 of the n+3th slot.
- the at least one available sub-time domain resource is all available sub-time domain resources in the available sub-time domain resource set, or all bearer non-self-decoding redundancy versions in the available sub-time domain resource set Sub-time domain resources are available.
- the RV versions on the n+1th slot, the n+2th slot, and the n+3th slot are RV2, RV3, and RV1, respectively, where RV3 is a self-decoding RV version, RV2 and RV1 is a non-self-decoding RV version.
- the target transmission scheme is the seventh transmission scheme and all available sub-time domain resources in the set of available sub-time domain resources carrying the non-self-decoding redundancy version
- the n+1th slot and the nth may be +3 time slots send the uplink information 4 to the network device.
- the number of bits used to carry the uplink information 4 in the n+1th time slot is the same as the number of bits used to carry the uplink information 4 in the n+3 time slots. Furthermore, the number of bits used to carry the uplink information 4 in the n+1th slot is 1/2 of the number of bits that map the uplink information 4 to a slot for transmitting the uplink information 3. For example, the number of bits used to carry the uplink information 4 in the n+1th time slot is 10, and the number of bits used to carry the uplink information 4 in the n+3 time slots is also 10. Assume that RV1 is also a self-decoding RV version. In this case, only the n+1th time slot can carry the uplink information 4.
- the number of bits used to carry the uplink information 4 in the n+1th slot is 20. It can be understood that, since the bits for carrying the uplink information 4 are added, the number of bits used to carry the uplink information 3 in the n+1th slot and the n+3th slot is correspondingly reduced.
- FIG. 6 is a schematic diagram of another method for transmitting information according to an embodiment of the present application.
- the communication device determines to start transmitting uplink information 1 at symbol 2 of the nth slot, which is carried by the uplink control channel.
- the uplink information 1 is HARQ feedback information.
- the first time length of the uplink information 1 is 0, and the second time length of the uplink information 1 is 1 time slot.
- the uplink information 1 lasts 4 symbols.
- the communication device determines to start transmitting the uplink information 2 at symbol 1 of the nth time slot.
- the uplink information 2 occupies four mini slots.
- the uplink information 2 is carried by the uplink shared channel.
- Each mini slot includes 3 symbols.
- the time domain resource used for transmitting the uplink information 2 may be composed of four sub-time domain resources, respectively, belonging to four mini-slots, and each of the four sub-time-domain resources is one mini. All time domain resources belonging to the second time domain resource in the time slot. It can be seen that, in the embodiment shown in FIG. 6, the second time domain resource includes four sub-time domain resources, and each of the four sub-time domain resources includes three symbols. Specifically, the first sub-time domain resource of the four sub-time-domain resources includes symbols 1 to 3 of the n-th time slot, and the second sub-time domain resource of the four sub-time domain resources includes the n-th time slot.
- the third sub-time domain resource of the four sub-time domain resources includes symbols 7 to 9 of the nth time slot, and 4 sub-time domain resources of the 4 sub-time domain resources include nth Symbols 10 to 12 of the time slots.
- the start time of the available sub-time domain resource is the symbol 1 of the nth slot, the symbol 4 of the nth slot, and the symbol of the nth slot 7.
- Symbol 10 of the nth time slot it can be determined that the start time of the available sub-time domain resource is not earlier than the symbol 2 of the nth time slot.
- rule 3 it can be determined that the start time of the available sub-time domain resource is no later than the symbol 5 of the n+1th slot.
- the available sub-time domain resource set includes three available sub-time domain resources, namely, the second sub-time domain resource, the third sub-time domain resource, and the fourth sub-time domain resource. . That is, the value of M is a positive integer greater than one.
- the target transmission scheme may be at least one of the sixth transmission scheme and the seventh transmission scheme.
- the terminal device determines that the target transmission scheme is the sixth transmission scheme, that is, transmits the first uplink information on a specific available sub-time domain resource in the available sub-time domain resource set and transmits the second uplink information on the second time domain resource.
- the second uplink information the terminal device may transmit the uplink information 1 on the specific available sub-time domain resource and in the second time domain resource (ie, symbol 1 to symbol 3 of the nth time slot, the nth time slot)
- the symbols 4 to 6, the symbols 7 to 9 of the nth slot, and the symbols 10 to 12 of the nth slot transmit the uplink information 2.
- the particular available sub-time domain resource may be the first available sub-time domain resource in the set of available sub-time domain resources, or the first available sub-time domain resource carrying a non-self-decoding redundancy version. .
- the terminal device may transmit the uplink information 1 on the at least one available sub-time domain resource and in the second time domain resource (ie, symbol 1 to symbol 3 of the nth slot, nth) Symbols 4 to 6 of the time slots, symbols 7 to 9 of the nth time slot, and symbols 10 to 12 of the nth time slot transmit the uplink information 2.
- the at least one available sub-time domain resource is all available sub-time domain resources in the available sub-time domain resource set, or all bearer non-self-decoding redundancy versions in the available sub-time domain resource set Sub-time domain resources are available.
- the Redundancy Version (RV) versions are RV0, RV2, RV3, and RV1, respectively, where RV0 and RV3 are self-decoding RV versions, and RV2 and RV1 are non-self-decoding RV versions.
- the target transmission scheme is the seventh transmission scheme and all available sub-time domain resources in the set of available sub-time domain resources carrying the non-self-decoding redundancy version
- the second sub-time domain resource and the third sub-portion may be used.
- the time domain resource sends the uplink information 1 to the network device.
- the number of bits used by the second sub-time domain resource to carry the uplink information 1 is the same as the number of bits used to carry the uplink information 1 in the third sub-time domain resource.
- the number of bits used to carry the uplink information 1 in the second sub-time domain resource is 1/2 of the number of bits that map the uplink information 1 to an uplink resource for transmitting the uplink information 2.
- the number of bits used to carry the uplink information 1 in the second sub-time domain resource is 10, and the number of bits used to carry the uplink information 1 in the third sub-time domain resource is also 10.
- RV1 is also a self-decoding RV version. In this case, only the second sub-time domain resource can carry the uplink information 4.
- the number of bits used to carry the uplink information 1 in the second sub-time domain resource is 20. It can be understood that the number of bits used to carry the uplink information 2 in the second sub-time domain resource and the third sub-time domain resource is correspondingly reduced due to the addition of the bit for carrying the uplink information 1.
- FIG. 7 is a schematic flowchart of another transmission method according to an embodiment of the present application. The method shown in Figure 7 can be performed by a communication device.
- the time slot to which the N symbols belong is the same as the M symbols, and the N symbols do not conflict with the M symbols, and the first time domain resource and the second time domain resource are consecutive time domain resources. Determining a target transmission scheme for transmitting the first uplink information and the second uplink information.
- the target transmission scheme is used to control a power control scheme for transmitting the first uplink information and the second uplink information.
- resource utilization efficiency can be improved.
- the target transmission scheme for determining the first uplink information and the second uplink information is: determining that the target transmission scheme is to send the first uplink to the network device by using the first power.
- Information and the second uplink information, where the first power is power for transmitting the first uplink information are: determining that the target transmission scheme is to send the first uplink to the network device by using the first power.
- the first power is power for transmitting the first uplink information.
- determining the target transmission scheme for sending the first uplink information and the second uplink information including determining, according to the total transmission energy, that the target transmission scheme is discarding the second uplink information. And transmitting the first uplink information by using the first power, or reducing the first power, and sending the first uplink information and the second uplink information by using the reduced first power, where the first power is used for sending the The power of the first uplink information, where the total transmission energy is energy for transmitting the first uplink information and the second uplink information by using the first power.
- the total transmission energy W P ⁇ (N′+M′), where P represents the first power, N′ is the duration of N symbols included in the first time domain resource, and M′ is the second time The duration of the M symbols included in the domain resource.
- determining, according to the total transmit energy, the target transmission scheme is to discard the second uplink information and send the first uplink information by using the first power, or reduce the first power and use the reduced
- the first uplink information and the second uplink information are sent by the first power, and the ratio of the preset threshold to the total transmit energy is greater than a first preset value, and determining that the target transmission scheme is to discard the second uplink information.
- the first uplink information and the second uplink information are sent by one power.
- the preset threshold may be the total energy of one time slot.
- the preset threshold may be a total energy of multiple symbols in one time slot.
- determining the target transmission scheme for sending the first uplink information and the second uplink information including: determining that the target transmission scheme is to send the first to the network device by using the second power Uplink information and the second uplink information. In this way, when the priority of the first uplink information is lower than the second uplink information, the transmission power of the second uplink information may be preferentially guaranteed.
- determining the target transmission scheme for sending the first uplink information and the second uplink information including: determining, according to the total transmission energy, that the target transmission scheme is to discard the first uplink information. And transmitting the second uplink information by using the second power, or reducing the second power, and sending the first uplink information and the second uplink information by using the reduced second power, where the second power is used for sending the The power of the second uplink information, where the total transmission energy is energy for transmitting the first uplink information and the second uplink information by using the first power.
- the total transmission energy W P ⁇ (N′+M′), where P represents the second power, N′ is the duration of N symbols included in the first time domain resource, and M′ is the second time The duration of the M symbols included in the domain resource.
- determining, according to the total transmit energy, the target transmission scheme is to discard the first uplink information and send the second uplink information by using the second power, or reduce the second power and use the reduced
- the second power transmits the first uplink information and the second uplink information.
- the preset threshold may be the total energy of one time slot.
- the preset threshold may be a total energy of a plurality of symbols in one time slot.
- the uplink information carried by the Grant-Free uplink shared channel has a higher priority than the priority of the Grant-based uplink control channel.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by an unlicensed uplink shared channel.
- the target transmission scheme may be that the first uplink information and the second uplink information are sent to the network device by using the second power.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by an unlicensed uplink shared channel.
- the target transmission scheme may be determined according to the total transmission energy, the target transmission scheme is to discard the first uplink information, and use the second power to send the second uplink information, or reduce the second power and use the reduced The second power transmits the first uplink information and the second uplink information.
- the scheduling-based uplink control channel has a higher priority than the scheduling-based uplink shared channel.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by a scheduling-based uplink shared channel.
- the target transmission scheme may be that the first uplink information and the second uplink information are sent to the network device by using the first power.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by a scheduling-based uplink shared channel.
- the target transmission scheme may be determined according to the total transmission energy, the target transmission scheme is to discard the second uplink information, and the first uplink information is sent by using the first power, or the first power is decreased and the reduced The first power sends the first uplink information and the second uplink information.
- the priority of the uplink information carried by the Grant-Free uplink shared channel is lower than the priority of the Grant-based uplink control channel.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by an unlicensed uplink shared channel.
- the target transmission scheme may be that the first uplink information and the second uplink information are sent to the network device by using the first power.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by an unlicensed uplink shared channel.
- the target transmission scheme may be that, according to the total transmission energy, determining that the target transmission scheme sends the first uplink information by using the first power to discard the second uplink information, or lowering the first power and using the reduced first
- the first uplink information and the second uplink information are sent by one power.
- the priority of the scheduled uplink control channel is lower than the priority of the scheduling-based uplink shared channel.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by a scheduling-based uplink shared channel.
- the target transmission scheme may be that the first uplink information and the second uplink information are sent to the network device by using the second power.
- the first uplink information is carried by a scheduling-based uplink control channel
- the second uplink information is carried by a scheduling-based uplink shared channel.
- the target transmission scheme may be determined according to the total transmission energy, the target transmission scheme is to discard the first uplink information, and use the second power to send the second uplink information, or reduce the second power and use the reduced The second power transmits the first uplink information and the second uplink information.
- FIG. 8 is a structural block diagram of a communication device according to an embodiment of the present application.
- the communication device 800 shown in FIG. 8 includes a processing unit 801 and a transmitting unit 802.
- the processing unit 801 is configured to determine, according to the second time domain resource, a target transmission scheme for transmitting the first uplink information and the second uplink information, where the first uplink information is carried by the uplink control channel, and the second uplink information is used by the uplink.
- the first time domain resource where the first uplink information is located and the second time domain resource where the second uplink information is located partially overlap or overlap in the time domain, the first time domain resource includes at least one symbol.
- the second time domain resource includes at least one symbol.
- the transmitting unit 802 is configured to transmit the first uplink information and/or the second uplink information according to the target transmission scheme determined by the processing unit 801.
- processing unit 801 and the sending unit 802 For specific functions and advantages of the processing unit 801 and the sending unit 802, reference may be made to the embodiment shown in FIG. 1, and details are not described herein.
- Processing unit 801 can be implemented by a processor, and transmission unit 802 can be implemented by a transceiver.
- FIG. 9 is a structural block diagram of a communication device according to an embodiment of the present application.
- the communication device 900 includes a processing unit 901 and a transmitting unit 902.
- the processing unit 901 is configured to determine a first time domain resource for transmitting the first uplink information, where the first uplink information is carried by an uplink control channel uplink control channel, where the first time domain resource includes N symbols, The N symbols belong to one time slot.
- the processing unit 901 is further configured to determine a second time domain resource for transmitting the second uplink information, where the second uplink information is carried by the uplink shared channel uplink shared channel, where the second time domain resource includes M symbols, The M symbols belong to one time slot;
- the processing unit 901 is further configured to: the time slot to which the N symbols belong is the same as the M symbols, and the N symbols do not conflict with the M symbols, and the first time domain resource and the The second time domain resource is a continuous time domain resource, and the target transmission scheme for transmitting the first uplink information and the second uplink information is determined.
- the transmitting unit 902 is configured to send the first uplink information and/or the second uplink information to the network device according to the target transmission scheme determined by the processing unit 901.
- processing unit 901 and the transmission unit 902 For specific functions and advantages of the processing unit 901 and the transmission unit 902, reference may be made to the embodiment shown in FIG. 7, and details are not described herein.
- Processing unit 901 can be implemented by a processor, and transmission unit 902 can be implemented by a transceiver.
- FIG. 10 is a structural block diagram of another communication device according to an embodiment of the present application.
- the communication device 1000 shown in FIG. 10 includes a memory 1001 and a processor 1002.
- the memory 1001 is configured to store a program.
- the processor 1002 is configured to execute a program stored in the memory 1001.
- the communication device 1000 can implement the method provided in the foregoing embodiment of FIG. 1.
- Some or all of the methods shown in FIG. 1 may be implemented by software using the communication device 1000.
- the memory 1001 may be a physically separate unit or may be integrated with the processor 1002.
- the communication device 1000 may also include only the processor 1002.
- the memory 1001 for storing programs is located outside the device 1000, and the processor 1002 is connected to the memory 1001 through circuits/wires for reading and executing programs stored in the memory 1001.
- the processor 1002 may be a central processing unit (CPU), a network processor (NP), or a combination of a CPU and an NP.
- CPU central processing unit
- NP network processor
- the processor 1002 may further include a hardware chip.
- the hardware chip may be an application-specific integrated circuit (ASIC), a programmable logic device (PLD), or a combination thereof.
- the PLD may be a complex programmable logic device (CPLD), a field-programmable gate array (FPGA), a general array logic (GAL), or any combination thereof.
- the memory 1001 may include a volatile memory such as a random-access memory (RAM); the memory 1001 may also include a non-volatile memory such as a flash memory (flash) Memory), hard disk drive (HDD) or solid-state drive (SSD); the memory 1001 may also include a combination of the above types of memory.
- RAM random-access memory
- non-volatile memory such as a flash memory (flash) Memory), hard disk drive (HDD) or solid-state drive (SSD)
- the memory 1001 may also include a combination of the above types of memory.
- FIG. 11 is a structural block diagram of another communication device according to an embodiment of the present application.
- the communication device 1100 shown in FIG. 11 includes a memory 1101 and a processor 1102.
- the memory 1101 is configured to store a program.
- the processor 1102 is configured to execute a program stored in the memory 1101.
- the communication device 1100 can implement the method provided in the foregoing embodiment of FIG. 7.
- Some or all of the methods shown in FIG. 7 may be implemented by software using the communication device 1100.
- the memory 1101 can be a physically separate unit or can be integrated with the processor 1102.
- the communication device 1100 may also include only the processor 1102.
- the memory 1101 for storing programs is located outside the device 1100, and the processor 1102 is connected to the memory 1101 through circuits/wires for reading and executing programs stored in the memory 1101.
- the processor 1102 can be a central processing unit (CPU), a network processor (NP), or a combination of a CPU and an NP.
- CPU central processing unit
- NP network processor
- the processor 1102 can also further include a hardware chip.
- the hardware chip may be an application-specific integrated circuit (ASIC), a programmable logic device (PLD), or a combination thereof.
- the PLD may be a complex programmable logic device (CPLD), a field-programmable gate array (FPGA), a general array logic (GAL), or any combination thereof.
- the memory 1101 may include a volatile memory such as a random-access memory (RAM); the memory 1101 may also include a non-volatile memory such as a flash memory (flash) Memory), hard disk drive (HDD) or solid-state drive (SSD); the memory 1101 may also include a combination of the above types of memories.
- RAM random-access memory
- non-volatile memory such as a flash memory (flash) Memory), hard disk drive (HDD) or solid-state drive (SSD)
- the memory 1101 may also include a combination of the above types of memories.
- Yet another aspect of the present application provides a computer readable storage medium having instructions stored therein that, when executed on a computer, cause the computer to perform the method illustrated in FIG. 1 above.
- Yet another aspect of the present application provides a computer readable storage medium having stored therein instructions that, when executed on a computer, cause the computer to perform the method illustrated in Figure 7 above.
- Yet another aspect of the present application provides a computer program product comprising instructions that, when executed on a computer, cause the computer to perform the method as shown in FIG.
- Yet another aspect of the present application provides a computer program product comprising instructions that, when run on a computer, cause the computer to perform the method as shown in FIG.
- FIG. 12 is a schematic flowchart of another method for transmitting information according to an embodiment of the present application.
- the method shown in Figure 12 can be performed by a communication device.
- the first time-frequency resource is a time-frequency resource of an uplink control channel, where the uplink control channel is used to carry uplink control information to be transmitted, where the first time-frequency resource is in a first time unit.
- the second time-frequency resource is a time-frequency resource occupied by an uplink data channel, where the uplink data channel is used to carry uplink data to be transmitted, and the second time-frequency resource is configured by N sub-time-frequency A resource component, the N sub-time-frequency resources are respectively located in N time units, the first time-frequency resource and the second time-frequency resource overlap in a time domain, and N is a positive integer greater than or equal to 2.
- the embodiment shown in FIG. 12 provides a method for transmitting uplink control information and uplink data in a case where a time domain resource occupied by an uplink control channel overlaps with a time domain resource occupied by an uplink data channel.
- the time unit referred to in the embodiment of the present application may be a time slot, a mini time slot, a subframe, or the like.
- the first time-frequency resource is in a first time unit, and the second time-frequency resource occupies N time-frequency resources. Therefore, if the first time-frequency resource and the second time-frequency resource overlap in the time domain, the first time unit is one of the N time units.
- the first time-frequency resource is located in a time unit, and the time domain resource of the first time-frequency resource may be one or more symbols in the time unit, or may be all symbols included in the time unit.
- Each of the N sub-time-frequency resources may also be one or more symbols in a time unit, or may be all symbols in the time unit.
- the transmitting the uplink control information and the uplink data according to the first time unit including: transmitting, by using the first sub-time-frequency resource, the uplink control information and the uplink data, where the first sub- The time-frequency resource is one of the N sub-time-frequency resources, and the number of the time unit in which the first sub-time-frequency resource is located is the same as the number of the first time unit.
- the communications device does not transmit the uplink control information on the first time-frequency resource.
- modulation coding symbol determining method of the uplink control information may be consistent with the prior art, and is not described herein.
- the second time-frequency resource includes four time units, which are time slot 1, time slot 2, time slot 3, and time slot 4, respectively.
- the first time-frequency resource and the second time-frequency resource overlap in a time domain. That is, the first time unit may be any one of slot 1 to slot 4. It is assumed that the first time unit is time slot 2.
- the communication device can transmit uplink control information and uplink data by using the first sub-time-frequency resource.
- the first sub-time-frequency resource is one of the N sub-time-frequency resources included in the second time-frequency resource, and the time slot in which the first sub-time-frequency resource is located is the time slot in which the first time-frequency resource is located. That is, time slot 2.
- the communication device does not transmit the uplink control information in the first time-frequency resource.
- the communication device can simultaneously transmit uplink data and uplink control information by using time-frequency resources occupied by the uplink data channel.
- the communication device can still transmit uplink data using the remaining sub-time-frequency resources. That is, the communication device can use the time domain resources in the N sub-time-frequency resources to transmit the sub-time-frequency resources corresponding to the slot 1, the slot 3, and the slot 4, which are originally transmitted on the sub-time-frequency resources. Upstream data.
- the uplink control channel referred to in the embodiment of FIG. 12 can be used to carry uplink control information to be transmitted.
- the uplink data channel referred to in the embodiment of FIG. 12 can be used to carry uplink control information to be transmitted. That is, the uplink control information may be carried by the uplink control channel.
- the uplink data can be carried by the uplink data channel. However, in some embodiments, the uplink control information may also be carried by the uplink data channel.
- the sub-time-frequency resources corresponding to the time slot 2 are used to carry both uplink control information and uplink data.
- the transmitting the uplink control information and the uplink data according to the first time unit including: transmitting, by using the first time-frequency resource, the uplink control information, not transmitting the second sub-time-frequency resource Uplink data, in the second time-frequency resource, transmitting the uplink data on a sub-time-frequency resource other than the second sub-time-frequency resource, where the second sub-time-frequency resource is one of the N sub-time-frequency resources
- the number of the time unit in which the second sub-time-frequency resource is located is the same as the number of the first time unit.
- the second time-frequency resource includes four time units, which are time slot 1, time slot 2, time slot 3, and time slot 4, respectively.
- the first time-frequency resource and the second time-frequency resource overlap in a time domain. That is, the first time unit may be any one of slot 1 to slot 4. It is assumed that the first time unit is time slot 2.
- the communication device can transmit uplink control information by using the first time-frequency resource. The communication device does not transmit the uplink data in the second sub-time-frequency resource.
- the second sub-time-frequency resource is one of the N sub-time-frequency resources included in the second time-frequency resource
- the time slot in which the second sub-time-frequency resource is located is the time slot in which the first time-frequency resource is located. , that is, time slot 2.
- the communication device transmits only the uplink control information in a time unit in which the first time-frequency resource collides with the second time-frequency resource.
- the communication device can still transmit uplink data using the remaining sub-time-frequency resources. That is, the communication device can use the time domain resources of the N sub-time-frequency resources to transmit the uplink data for the sub-time-frequency resources of the slot 1, the slot 3, and the slot 4.
- the transmitting the uplink control information and the uplink data according to the first time unit including: transmitting, by using the M sub-time-frequency resources, the uplink control information and the uplink data, where the M sub-time-frequency The resource belongs to the N sub-time-frequency resources, and the number of the time unit in which any one of the M sub-time-frequency resources is located is greater than or equal to the number of the first time unit, and M is greater than or equal to 1 and less than N.
- the second time-frequency resource includes four time units, which are time slot 1, time slot 2, time slot 3, and time slot 4, respectively.
- the first time-frequency resource and the second time-frequency resource overlap in a time domain. That is, the first time unit may be any one of slot 1 to slot 4. It is assumed that the first time unit is time slot 2.
- the communication device may transmit the uplink control information and the uplink data to one or more sub-time-frequency resources in the time slots 2 to 4 in the time domain resources of the four sub-time-frequency resources.
- the terminal device determines M sub-time-frequency resources, where the number of time units in the N sub-time-frequency resources is greater than or equal to the number of the first time unit. Child time-frequency resources.
- the third sub-time-frequency resource may be determined as the first one of the M sub-time-frequency resources.
- Non-self-decoding redundant version of the sub-time-frequency resource if the redundancy version corresponding to one sub-time-frequency resource is not a self-decoding redundancy version, the third sub-time-frequency may be determined
- the resource is the first sub-time-frequency resource in the M sub-time-frequency resources.
- the communications device can transmit the uplink control information and the uplink data on the third sub-time-frequency resource.
- the communication device may not transmit the uplink control information on the first time frequency.
- the communication device may further transmit the uplink data on the other sub-time-frequency resources except the second sub-time-frequency resource in the N sub-time-frequency resources.
- the second time-frequency resource includes four time units, which are time slot 1, time slot 2, time slot 3, and time slot 4, and four time slots.
- the sub-time-frequency resources are respectively corresponding to the self-decoding redundancy version, the non-self-decoding redundancy version, the self-decoding redundancy version, and the non-self-decoding redundancy version.
- the first time-frequency resource and the second time-frequency resource overlap in a time domain. That is, the first time unit may be any one of slot 1 to slot 4. It is assumed that the first time unit is time slot 2.
- the M sub-time-frequency resources are three sub-time-frequency resources in which the time domain resources of the four sub-time-frequency resources are located in slots 2 to 4.
- the communication device may transmit the uplink control information and the uplink data in the first sub-time-frequency resource of the three sub-time-frequency resources, that is, transmit the uplink control information on the sub-time resource of the time slot 2 and the Upstream data.
- the first time unit is time slot 3.
- the M sub-time-frequency resources are the two sub-time-frequency resources of the four sub-time-frequency resources in which the time domain resources are located in slots 3 to 4.
- the communication device may transmit the uplink control information and the uplink data in the second sub-time-frequency resource of the two sub-time-frequency resources, that is, transmit the uplink control information on the sub-time resource of the time slot 4 and the Upstream data.
- the transmitting the uplink control information and the uplink data in the M sub-time-frequency resources includes: determining, by the uplink control information, the number of corresponding modulation coded symbols per layer on the uplink data channel; Determining, according to the uplink control information, a total number of modulation coding symbols of the uplink control information by transmitting a corresponding number of modulation coded symbols per layer, and dividing the total modulation coding symbol of the uplink control information into M parts, respectively
- the M parts are transmitted on the M sub-time-frequency resources, and the total modulation coded symbols of the M parts are equal to the total modulation coded symbols of the uplink control information.
- dividing the total modulation coding symbol of the uplink control information into M parts may be dividing the total modulation coding symbols of the uplink control information into non-overlapping M parts.
- determining, by the uplink control information, the number of corresponding modulation coded symbols per layer on the uplink data channel including: according to the total number of available resource particles in the M sub-time-frequency resources, Determining that the uplink control information transmits a corresponding number of modulation coded symbols per layer on the uplink data channel.
- the available resource particles referred to herein are one time-frequency resource unit, the frequency domain span corresponds to one sub-carrier, and the time domain span corresponds to one Orthogonal Frequency Division Multiplexing (OFDM) symbol.
- OFDM Orthogonal Frequency Division Multiplexing
- the time-frequency span of the resource particles may also be defined by other factors, for example, the frequency domain span is 12 subcarriers, or 1 RB, and the time domain span is 1 time slot, mini time slot, subframe, and the like.
- the number of REs occupied by the uplink control information on the uplink data channel may be determined according to the total number of available resource particles in the M sub-time-frequency resources.
- determining, by the uplink control information, the number of corresponding modulation coded symbols per layer on the uplink data channel including: according to one of the M sub-time-frequency resources The number of available resource particles determines the number of corresponding modulation coded symbols transmitted by the uplink control information on the uplink data channel.
- the total number of available resource particles in the M sub-time-frequency resources refers to the number of resource particles included in all available sub-time domain resources included in the M sub-time domain resources. For example, assuming M is equal to 2, each sub-time domain resource includes 168 available resource particles. In this case, the total number of available resource particles within the M sub-time-frequency resources is 336.
- the number of available resource particles of one of the M sub-time-frequency resources is the number of available resource particles included in one sub-time domain resource. For example, assuming M is equal to 2, each sub-time domain resource includes 168 available resource particles. In this case, the number of available resource particles of one of the M sub-time-frequency resources is 168.
- the number of available resource particles of one of the M sub-time-frequency resources is equal to the total number of available resource particles within the M sub-time-frequency resources.
- the method shown in FIG. 12 may further include: determining a sixth sub-time domain resource, the sixth sub-time domain resource belongs to the N sub-time domain resources, and the sixth sub-time domain
- the uplink control information corresponding to the uplink control channel in the L sub-time domain resources is carried in the resource, and the uplink control information corresponding to the uplink control channel in the L sub-time domain resources belongs to the same type, and L is a positive integer greater than or equal to 2.
- the modulation coding symbols of the uplink control information are transmitted on the sixth sub-time domain resource, and all modulation coding symbols of the uplink control information are concatenation of modulation coding symbols from uplink control information in the L sub-time domain resources.
- the method before step 1203, further includes: receiving target transmission scheme indication information, where the target transmission scheme indication information is used to indicate a target transmission scheme; determining the target according to the target scenario indication information. Transmission scheme.
- the transmitting the uplink control information and the uplink data according to the first time unit includes: transmitting, according to the target transmission scheme, the uplink control information and the uplink data according to the first time unit.
- the target solution indication information is used to indicate that the target transmission scheme is a first transmission scheme or a second transmission scheme.
- the target transmission scheme is the first transmission scheme
- the target scheme indication information is 0, the target transmission scheme is the second transmission scheme.
- the target transmission scheme is the first transmission scheme
- the target scheme indication information is 1, the target transmission scheme is the second transmission scheme.
- the target scheme indicates that the information is positive, the target transmission scheme is the first transmission scheme; and when the target scheme indicates that the information is negative, the target transmission scheme is the second transmission scheme.
- the manner in which the target transmission scheme indication information indicates the target transmission scheme may also be other than the above examples, as long as the target transmission scheme indication information can indicate different transmission schemes.
- the target solution indication information is used to indicate that the target transmission scheme is the first transmission scheme or the third transmission scheme.
- the target transmission scheme is the first transmission scheme
- the target scheme indication information is 0, the target transmission scheme is the third transmission scheme.
- the target transmission scheme is the first transmission scheme
- the target scheme indication information is 1, the target transmission scheme is the third transmission scheme.
- the target scheme indicates that the information is positive, the target transmission scheme is the first transmission scheme; and when the target scheme indicates that the information is negative, the target transmission scheme is the third transmission scheme. It can be understood by those skilled in the art that the manner in which the target transmission scheme indication information indicates the target transmission scheme may also be other than the above examples, as long as the target transmission scheme indication information can indicate different transmission schemes.
- the target solution indication information is used to indicate that the target transmission scheme is the second transmission scheme or the third transmission scheme.
- the target transmission scheme is the third transmission scheme; when the target scheme indication information is 0, the target transmission scheme is the second transmission scheme.
- the target transmission scheme is the third transmission scheme; when the target scheme indication information is 1, the target transmission scheme is the second transmission scheme.
- the target transmission scheme indicates that the information is positive, the target transmission scheme is the third transmission scheme; and when the target scheme indicates that the information is negative, the target transmission scheme is the second transmission scheme. It can be understood by those skilled in the art that the manner in which the target transmission scheme indication information indicates the target transmission scheme may also be other than the above examples, as long as the target transmission scheme indication information can indicate different transmission schemes.
- the target solution indication information is used to indicate that the target transmission scheme is a first transmission scheme, a second transmission scheme, or a third transmission scheme.
- the target scheme indication information is 00
- the target transmission scheme is the first transmission scheme
- the target scheme indication information is 01
- the target transmission scheme is the second transmission scheme
- the target scheme indication information is 10
- the target transmission scheme is the third transmission scheme.
- the target scheme indication information is 11, the target transmission scheme is the first transmission scheme; when the target scheme indication information is 10, the target transmission scheme is the second transmission scheme; and the target scheme indication information is 01.
- the target transmission scheme is the third transmission scheme.
- the first transmission scheme is: transmitting, by the fourth sub-time-frequency resource, the uplink control information and the uplink data, where the fourth sub-time-frequency resource is one of the N sub-time-frequency resources, and the fourth The number of the time unit in which the sub-time-frequency resource is located is the same as the number of the first time unit. Further, the first transmission scheme may further include not transmitting the uplink control information on the first time-frequency resource.
- the second transmission scheme is: transmitting the uplink control information in the first time-frequency resource, not transmitting the uplink data on the fifth sub-time-frequency resource, and selecting the second time-frequency resource other than the fifth sub-time-frequency resource
- the uplink data is transmitted on the time-frequency resource, where the fifth sub-time-frequency resource is one of the N sub-time-frequency resources, and the number of the time unit in which the fifth sub-time-frequency resource is located and the first time unit The numbers are the same.
- the third transmission scheme is: transmitting the uplink control information and the uplink data in the T sub-time-frequency resources, where the T sub-time-frequency resources belong to the N sub-time-frequency resources, and any one of the T sub-time-frequency resources
- the number of the time unit in which the frequency resource is located is greater than or equal to the number of the first time unit, and T is a positive integer greater than or equal to 1 and less than N.
- the receiving target transmission scheme indication information includes: receiving high layer signaling, where the high layer signaling carries the target transmission scheme indication information; or receiving downlink control signaling, where the downlink control signaling is carried The target transmission scheme indicates information.
- FIG. 13 is a structural block diagram of a communication device according to an embodiment of the present application. As shown in FIG. 13, the communication device 1300 includes a processing unit 1301 and a transmitting unit 1302.
- the processing unit 1301 is configured to determine a first time-frequency resource, where the first time-frequency resource is a time-frequency resource of an uplink control channel, and the uplink control channel is used to carry uplink control information to be transmitted, where the first time The frequency resource is in the first time unit.
- the processing unit 1301 is further configured to determine a second time-frequency resource, where the second time-frequency resource is a time-frequency resource of an uplink data channel, and the uplink data channel is used to carry uplink data to be transmitted, where the second time
- the frequency resource is composed of N sub-time-frequency resources, where the N sub-time-frequency resources are respectively located in N time units, and the first time-frequency resource and the second time-frequency resource overlap in the time domain, and N is greater than or equal to 2 Positive integer.
- the communication unit 1302 is configured to transmit the uplink control information and the uplink data according to the first time unit.
- processing unit 1301 and the communication unit 1302 For specific functions and advantages of the processing unit 1301 and the communication unit 1302, reference may be made to the embodiment shown in FIG. 12, and details are not described herein.
- Processing unit 1301 may be implemented by a processor, and communication unit 1302 may be implemented by a transceiver.
- FIG. 14 is a structural block diagram of another communication device according to an embodiment of the present application.
- the communication device 1400 shown in FIG. 14 includes a memory 1401 and a processor 1402.
- the memory 1401 is configured to store a program.
- the processor 1402 is configured to execute a program stored in the memory 1401, and when the program is executed, the communication device 1400 can implement the method provided in the foregoing embodiment of FIG.
- Some or all of the methods shown in FIG. 12 may be implemented by software using the communication device 1400.
- the memory 1401 may be a physically separate unit or may be integrated with the processor 1402.
- the communication device 1400 may also include only the processor 1402.
- the memory 1401 for storing programs is located outside the device 1400, and the processor 1402 is connected to the memory 1401 through circuits/wires for reading and executing programs stored in the memory 1401.
- the processor 1402 may be a central processing unit (CPU), a network processor (NP), or a combination of a CPU and an NP.
- CPU central processing unit
- NP network processor
- the processor 1402 may further include a hardware chip.
- the hardware chip may be an application-specific integrated circuit (ASIC), a programmable logic device (PLD), or a combination thereof.
- the PLD may be a complex programmable logic device (CPLD), a field-programmable gate array (FPGA), a general array logic (GAL), or any combination thereof.
- the memory 1401 may include a volatile memory such as a random-access memory (RAM); the memory 1401 may also include a non-volatile memory such as a flash memory (flash) Memory), hard disk drive (HDD) or solid-state drive (SSD); the memory 1401 may also include a combination of the above types of memories.
- RAM random-access memory
- non-volatile memory such as a flash memory (flash) Memory), hard disk drive (HDD) or solid-state drive (SSD); the memory 1401 may also include a combination of the above types of memories.
- Yet another aspect of the present application provides a computer readable storage medium having stored therein instructions that, when executed on a computer, cause the computer to perform the method illustrated in Figure 12 above.
- Yet another aspect of the present application provides a computer program product comprising instructions which, when run on a computer, cause the computer to perform the method as shown in FIG.
- the disclosed systems, devices, and methods may be implemented in other manners.
- the device embodiments described above are merely illustrative.
- the division of the unit is only a logical function division.
- there may be another division manner for example, multiple units or components may be combined or Can be integrated into another system, or some features can be ignored or not executed.
- the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be in an electrical, mechanical or other form.
- the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
- each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.
- the functions may be stored in a computer readable storage medium if implemented in the form of a software functional unit and sold or used as a standalone product.
- the technical solution of the present invention which is essential or contributes to the prior art, or a part of the technical solution, may be embodied in the form of a software product, which is stored in a storage medium, including
- the instructions are used to cause a computer device (which may be a personal computer, server, or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention.
- the foregoing storage medium includes: a U disk, a mobile hard disk, a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disk, and the like. .
Landscapes
- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
本申请实施例提供一种传输信息的方法和通信设备,该方法包括:确定第一时频资源,其中该第一时频资源为上行控制信道的时频资源,该上行控制信道用于承载待传输的上行控制信息,该第一时频资源在第一时间单元内;确定第二时频资源,其中该第二时频资源为上行数据信道的时频资源,该上行数据信道用于承载待传输的上行数据,该第二时频资源由N个子时频资源组成,该N个子时频资源分别位于N个时间单元,该第一时频资源与该第二时频资源在时域重叠;根据该第一时间单元,传输上行控制信息和上行数据。上述技术方案提出了一种在第一时频资源与该第二时频资源在时域重叠的情况下,传输上行控制信息和上行数据的方法。
Description
本申请要求于2017年11月7日提交中国专利局、申请号为201711086786.3、申请名称为“传输信息的方法和通信设备”的中国专利申请的优先权;于2018年1月12日提交中国专利局、申请号为201810031421.9、申请名称为“传输信息的方法和通信设备”的中国专利申请的优先权;其全部内容通过引用结合在本申请中。
本发明实施例涉及通信技术领域,并且更具体地,涉及传输信息的方法和通信设备。
第五代(5
th Generation,5G)通信技术引入了灵活调度技术。因此,由通信设备发送的由上行控制信道携带的信息的时域资源(以下简称上行控制信道时域资源)的时域位置和长度是可变的。由该通信设备发送的由上行共享信道携带的信息的时域资源(以下简称上行共享信道时域资源)的时域位置和长度也是可变的。因此,上行控制信道时域资源和上行共享信道时域资源可能出现重叠。在此情况下,选择怎样的传输方案来传输由上行控制信道携带的信息和由上行共享信道携带的信息是一个亟待解决的问题。
发明内容
本申请实施例提供一种传输信息的方法和通信设备,能够合理地传输该第一上行信息和/或该第二上行信息。
第一方面,本申请实施例提供一种传输信息的方法,该方法包括:根据第二时域资源,确定用于传输第一上行信息和第二上行信息的目标传输方案,其中该第一上行信息由上行控制信道携带,该第二上行信息由上行共享信道携带,该第一上行信息所在的第一时域资源和该第二上行信息所在的该第二时域资源在时域上部分重叠或全部重叠,该第一时域资源包括至少一个符号,该第二时域资源包括至少一个符号;根据该目标传输方案,传输该第一上行信息和/或该第二上行信息。基于上述技术方案,在该第一时域资源与该第二时域资源重叠的情况下,通信设备可以通过该第二时域资源选择合适的目标传输方案,这样可以合理地传输该第一上行信息和/或该第二上行信息。
结合第一方面,在第一方面的第一种可能的实现方式中,该第二时域资源由N个子时域资源组成,该N个子时域资源分别属于N个时隙或N个迷你时隙,该N个子时域资源中的每个子时域资源为1个时隙或1个迷你时隙中属于该第二时域资源全部时域资源,N为大于或等于1的正整数,该根据第二时域资源,确定用于传输第一上行信息和第二上行信息的目标传输方案,包括:确定可用子时域资源集合,其中该可用子时域资源集合包括M个可用子时域资源,其中该可用子时域资源属于该N个子时域资源,并且该可用子时域资源的起始时刻不早于该第一时域资源的起始时刻与第一时间长度的差,并且该可用子 时域资源的起始时刻不晚于该第一时域资源的结束时刻与第二时间长度的和,M为大于或等于0的整数;根据M的取值,确定该目标传输方案为第一传输方案、第二传输方案、第三传输方案、第四传输方案、第五传输方案、第六传输方案和第七传输方案中的至少一个。上述技术方案可以根据可用子时域资源的数目确定该目标传输方案,可用子时域资源的数目不同,该目标传输方案的范围也不同。
结合第一方面的第一种可能的实现方式,在第一方面的第二种可能的实现方式中,该根据M的取值,确定该目标传输方案为第一传输方案、第二传输方案、第三传输方案、第四传输方案、第五传输方案、第六传输方案和第七传输方案中的至少一个,包括:M等于1,确定该目标传输方案为该第一传输方案;M等于0,确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个;和/或M为大于1的正整数,确定该目标传输方案为该第六传输方案和该第七传输方案中的至少一个。上述技术方案可以根据可用子时域资源的数目确定该目标传输方案,可用子时域资源的数目不同,该目标传输方案的范围也不同。。
结合第一方面的第二种可能的实现方式,在第一方面的第三种可能的实现方式中,该确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个,包括:根据终端设备的能力信息、网络设备的能力信息和优先级信息中的至少一个,确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个,其中,该终端设备的能力信息为终端设备是否支持同时在多个信道发送上行信息,该网络设备的能力信息为该网络设备是否支持同时接收由同一终端设备在多个信道上发送的上行信息,该优先级信息用于指示该第一上行信息的优先级和第二上行信息的优先级。通过上述技术方案,可以利用终端设备的能力信息、网络设备的能力信息和优先级信息中的至少一个确定该目标传输方案。
结合第一方面的第三种可能的实现方式,在第一方面的第四种可能的实现方式中,该根据终端设备的能力信息、网络设备的能力信息和优先级信息中的至少一个,确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个,包括:该终端设备支持同时在多个信道发送上行信息,和/或,该网络设备支持同时接收由同一终端设备在多个信道上发送的上行信息,确定该目标传输方案为该第二传输方案;该第一上行信息的优先级等于该第二上行信息的优先级,确定该目标传输方案为该第三传输方案;该第一上行信息的优先级大于该第二上行信息的优先级,确定该目标传输方案为该第四传输方案;和/或,该第一上行信息的优先级小于该第二上行信息的优先级,确定该目标传输方案为该第五传输方案。
结合第一方面的第一种可能的实现方式至第一方面的第四种可能的实现方式中的任一种可能的实现方式,在第一方面的第五种可能的实现方式中,该第一传输方案为:在部分或全部的该可用子时域资源上传输该第一上行信息;该第二传输方案为:在该第一时域资源上传输该第一上行信息;该第三传输方案为:在该第三时域资源上传输该第一上行信息,该第三时域资源为从该第二时域资源结束时刻起到目标时刻内的第一个能够用于传输该第一上行信息的时域资源,其中该目标时刻为该第一时域资源结束时刻与第二时间长度之和;该第四传输方案为:在该第一时域资源上传输第一上行信息,并将该第二上行信息在重叠时域资源或者重叠时频资源上的信息打孔,该重叠时域资源为该第一时域资源与该 第二时域资源中重叠的时域资源,该重叠时频资源为第一时频资源与第二时频资源中重叠的时频域资源,其中该第一时频资源为用于传输该第一上行信息的时频资源,该第二时频资源为用于传输该第二上行信息的时频资源;该第五传输方案为:在第四时域资源或者第四时频资源上传输该第一上行信息,并将该第一上行信息在该重叠时域资源或者该重叠时频资源上的信息打孔,该第四时域资源为该第一时域资源中除去该重叠时域资源之外的时域资源,该第四时频资源为该第一时频资源中除去该重叠时频资源之外的时频资源;该第六传输方案为:在该可用子时域资源集合中特定可用子时域资源上传输该第一上行信息;该第七传输方案为:在该可用子时域资源集合中的至少一个可用子时域资源上传输该第一上行信息。
结合第一方面的第五种可能的实现方式,在第一方面的第六种可能的实现方式中,该特定可用子时域资源为该可用子时域资源集合中的第一个可用子时域资源,或者,该特定可用子时域资源为该可用子时域资源集合中的第一个承载非自解码冗余版本的可用子时域资源。
结合第一方面的第五种可能的实现方式,在第一方面的第七种可能的实现方式中,该至少一个可用子时域资源为该可用子时域资源集合中的全部可用子时域资源;或者,该至少一个可用子时域资源为该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源。
结合第一方面的第五种可能的实现方式至第一方面的第七种可能的实现方式中的任一种可能的实现方式,在第一方面的第八种可能的实现方式中,该第一传输方案、第二传输方案、第三传输方案、第五传输方案、第六传输方案和第七传输方案,还包括,在该第二时域资源上传输第二上行信息;和/或该第四传输方案还包括,在该第二时域资源除去该重叠时域资源之外的时域资源上传输第一上行信息,或者,在该第二时频资源除去该重叠时频资源之外的时频资源上传输该第一上行信息。
第二方面,本申请实施例一种传输信息的方法,该方法包括:确定用于传输第一上行信息的第一时域资源,其中该第一上行信息为上行控制信道上行控制信道携带,该第一时域资源包括N个符号,该N个符号属于一个时隙;确定用于传输第二上行信息的第二时域资源,其中该第二上行信息由上行共享信道上行共享信道携带,该第二时域资源包括M个符号,该M个符号属于一个时隙;该N个符号所属的时隙与该M个符号所属相同且该N个符号与该M个符号不冲突的且该第一时域资源与该第二时域资源是连续的时域资源,确定用于发送该第一上行信息和该第二上行信息的目标传输方案。上述技术方案提出了一种在第一时域资源与该第二时域资源是连续的时域资源,可以选择传输方案的方法。
结合第二方面,在第二方面的第一种可能的实现方式中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:确定该目标传输方案为使用该第一功率向网络设备发送该第一上行信息和该第二上行信息,其中该第一功率为用于发送该第一上行信息的功率。上述技术方案可以优先保证发送该第一上行信息。
结合第二方面,在第二方面的第二种可能的实现方式中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:根据总发送能量,确定该目标传输方案为丢弃该第二上行信息并使用第一功率发送该第一上行信息,或者降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息,其中该第一功率为用于发送该 第一上行信息的功率,其中该总发送能量为使用该第一功率发送该第一上行信息和该第二上行信息的能量。上述技术方案可以优先保证发送该第一上行信息。
结合第二方面的第二种可能的实现方式,在第二方面的第三种可能的实现方式中,该根据总发送能量,确定该目标传输方案为丢弃该第二上行信息并使用第一功率发送该第一上行信息,或者降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息,包括:预设门限与该总发送能量的比值大于第一预设值,确定该目标传输方案为丢弃该第二上行信息并使用该第一功率发送该第一上行信息;该预设门限与该总发送能量的比值不大于该第一预设值,确定该目标传输方案为降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息。上述技术方案可以优先保证发送该第一上行信息。
结合第二方面,在第二方面的第四种可能的实现方式中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:确定该目标传输方案为使用第二功率向网络设备发送该第一上行信息和该第二上行信息,该第二功率为用于发送该第二上行信息的功率。上述技术方案可以优先保证发送该第二上行信息。
结合第二方面,在第二方面的第五种可能的实现方式中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:根据总发送能量,确定该目标传输方案为丢弃该第一上行信息并使用第二功率发送该第二上行信息,或者降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息,其中该第二功率为用于发送该第二上行信息的功率,其中该总发送能量为使用该第一功率发送该第一上行信息和该第二上行信息的能量。上述技术方案可以优先保证发送该第二上行信息。
结合第二方面的第五种可能的实现方式,在第二方面的第六种可能的实现方式中,该根据总发送能量,确定该目标传输方案为丢弃该第一上行信息并使用第二功率发送该第二上行信息,或者降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息,包括:预设门限与该总发送能量的比值大于第二预设值,确定该目标传输方案为丢弃该第一上行信息并使用该第二功率发送该第二上行信息;该预设门限与该总发送能量的比值不大于该第二预设值,确定该目标传输方案为降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息。上述技术方案可以优先保证发送该第二上行信息。
第三方面,本申请实施例还提供一种通信设备,该通信设备包括用于实现第一方面或第一方面的任一种可能的实现方式的单元。
第四方面,本申请实施例还提供一种通信设备,该通信设备包括用于实现第二方面或第二方面的任一种可能的实现方式的单元。
第五方面,本申请实施例提供一种通信设备,该通信设备包括:存储器,用于存储程序;处理器,用于执行所述存储器存储的所述程序,当所述程序被执行时,所述处理器用于执行第一方面或第一方面的任一种可能的实现方式所述的方法。可选的,该通信设备为芯片或集成电路。
第六方面,本申请实施例提供一种通信设备,该通信设备包括:存储器,用于存储程序;处理器,用于执行所述存储器存储的所述程序,当所述程序被执行时,所述处理器用于执行第二方面或第二方面的任一种可能的实现方式所述的方法。可选的,该通信设备为 芯片或集成电路。
第七方面,本申请实施例提供一种芯片用于执行第一方面或第一方面的任一种可能的实现方式所述的方法。
第八方面,本申请实施例提供一种芯片,用于执行第二方面或第二方面的任一种可能的实现方式。
第九方面,本申请实施例提供一种传输信息的方法,该方法包括:确定第一时频资源,其中该第一时频资源为上行控制信道的时频资源,该上行控制信道用于承载待传输的上行控制信息,该第一时频资源在第一时间单元内;确定第二时频资源,其中该第二时频资源为上行数据信道的时频资源,该上行数据信道用于承载待传输的上行数据,该第二时频资源由N个子时频资源组成,该N个子时频资源分别位于N个时间单元,该第一时频资源与该第二时频资源在时域重叠,N为大于或等于2的正整数;根据该第一时间单元,传输上行控制信息和上行数据。上述技术方案提出了一种在第一时频资源与该第二时频资源在时域重叠的情况下,传输上行控制信息和上行数据的方法。
结合第九方面,在第九方面的第一种可能的实现方式中,所述第一时间单元是所述N个时间单元中的一个。本领域技术人员可以理解的是,可以按照从0到N-1为所述N个时间单元编号,也可以按照从1到N为所述N个时间单元编号,可以按照连续或不连续的方式为所述N个时间单元编号,还可以按照从小到大的顺序或者从大到小的顺序为所述N个时间单元编号,当然所述N个时间单元还可以采用其他的编号方式,本申请对此不作限制。
结合第九方面,在第九方面的第一种可能的实现方式中,该根据该第一时域资源所在的时间单元,传输上行控制信息和上行数据,包括:在第一子时频资源传输该上行控制信息和该上行数据,其中该第一子时频资源为该N个子时频资源中的一个子时频资源,该第一子时频资源所在的时间单元的编号与该第一时间单元的编号相同。基于上述技术方案,在第一时频资源与该第二时频资源在时域重叠的情况下,可以使用上行数据信道占用的时频资源传输上行控制信息和上行数据,并且无需丢弃上行控制信息。
结合第九方面,在第九方面的第二种可能的实现方式中,该根据该第一时间单元,传输上行控制信息和上行数据,包括:在第一时频资源传输该上行控制信息,不在第二子时频资源上传输该上行数据,在第二时频资源中除该第二子时频资源以外的子时频资源上传输该上行数据,该第二子时频资源为N个子时频资源中的一个子时频资源,该第二子时频资源所在的时间单元的编号与该第一时间单元的编号相同。基于上述技术方案,在第一时频资源与该第二时频资源在时域重叠的情况下,可以无需丢弃上行控制信息。
结合第九方面,在第九方面的第三种可能的实现方式中,该根据该第一时间单元,传输上行控制信息和上行数据,包括:在M个子时频资源传输该上行控制信息和该上行数据,其中该M个子时频资源属于该N个子时频资源,该M个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于该第一时间单元的编号,M为大于或等于1且小于N的正整数。基于上述技术方案,在第一时频资源与该第二时频资源在时域重叠的情况下,可以无需丢弃上行控制信息。
结合第九方面的第三种可能的实现方式,在第九方面的第四种可能的实现方式中,该在M个子时频资源传输该上行控制信息和该上行数据,包括:确定该上行控制信息在该 上行数据信道上传输对应的每层调制编码符号数目;根据该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目确定该上行控制信息的总的调制编码符号数目,将该上行控制信息的总调制编码符号分为M个部分,分别在该M个子时频资源上传输该M个部分,该M个部分的总调制编码符号数目等于该上行控制信息的总调制编码符号数目。
结合第九方面的第四种可能的实现方式,在第九方面的第五种可能的实现方式中,该确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目,包括:根据该M个子时频资源内的总的可用资源粒子数目,确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目;或者
根据该M个子时频资源中的一个子时频资源的可用资源粒子数目,确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目。
结合第九方面或第九方面的上述任一种可能的实现方式,在第九方面的第六种可能的实现方式中,该根据该第一时间单元,传输上行控制信息和上行数据之前,该方法还包括:接收目标传输方案指示信息,该目标传输方案指示信息用于指示目标传输方案;根据该目标方案指示信息,确定该目标传输方案;该根据该第一时间单元,传输上行控制信息和上行数据,包括:基于该目标传输方案,根据该第一时间单元,传输该上行控制信息和该上行数据。
结合第九方面的第六中可能的实现方式,在第九方面的第七种可能的实现方式中,该目标方案指示信息用于指示该目标传输方案为第一传输方案或第二传输方案;或者该目标方案指示信息用于指示该目标传输方案为该第一传输方案或第三传输方案;或者该目标方案指示信息用于指示该目标传输方案为该第二传输方案或该第三传输方案,其中该第一传输方案为:在第四子时频资源传输该上行控制信息和该上行数据,其中该第四子时频资源为该N个子时频资源中的一个子时频资源,该第四子时频资源所在的时间单元的编号与该第一时间单元的编号相同;该第二传输方案为:在第一时频资源传输该上行控制信息,不在第五子时频资源上传输该上行数据,在第二时频资源中除该第五子时频资源以外的子时频资源上传输该上行数据,该第五子时频资源为N个子时频资源中的一个子时频资源,该第五子时频资源所在的时间单元的编号与该第一时间单元的编号相同;该第三传输方案为:在T个子时频资源传输该上行控制信息和该上行数据,其中该T个子时频资源属于该N个子时频资源,该T个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于该第一时间单元的编号,T为大于或等于1且小于N的正整数。
第十方面,本申请实施例还提供一种通信设备,该通信设备包括用于实现第九方面或第九方面的任一种可能的实现方式的单元。
第十一方面,本申请实施例提供一种通信设备,该通信设备包括:存储器,用于存储程序;处理器,用于执行所述存储器存储的所述程序,当所述程序被执行时,所述处理器用于执行第九方面或第九方面的任一种可能的实现方式所述的方法。可选的,该通信设备为芯片或集成电路。
第十二方面,本申请实施例提供一种芯片用于执行第九方面或第九方面的任一种可能的实现方式所述的方法。
本申请的又一方面提供了一种计算机可读存储介质,所述计算机可读存储介质中存储有指令,当所述指令在计算机上运行时,使得计算机执行上述各个方面所述的方法。
本申请的又一方面提供了一种包含指令的计算机程序产品,当该计算机程序产品在计算机上运行时,使得计算机执行上述各方面所述的方法。
图1是根据本申请实施例提供的传输信息的方法的示意性流程图。
图2是根据本申请实施例提供的一种传输信息的方法的示意图。
图3是根据本申请实施例提供的另一种传输信息的方法的示意图。
图4是根据本申请实施例提供的另一种传输信息的方法的示意图。
图5是根据本申请实施例提供的另一种传输信息的方法的示意图。
图6是根据本申请实施例提供的另一种传输信息的方法的示意图。
图7是根据本申请实施例提供的另一传输方法的示意性流程图。
图8是根据本申请实施例提供的一种通信设备的结构框图。
图9是根据本申请实施例提供的一种通信设备的结构框图。
图10是根据本申请实施例提供的另一通信设备的结构框图。
图11是根据本申请实施例提供的另一通信设备的结构框图。
图12是根据本申请实施例提供的另一传输信息的方法的示意性流程图。
图13是根据本申请实施例提供的另一通信设备的结构框图。
图14是根据本申请实施例提供的另一通信设备的结构框图。
下面将结合附图,对本发明实施例中的技术方案进行描述。
应理解,本申请实施例的技术方案可以应用于5G网络、新空口(new radio,NR)、以及后续的网络等。
本申请实施例中所称的通信设备可以是终端设备。
本申请实施例的技术方案中所称的终端设备也可以称为接入终端、用户设备(user equipment,UE)、用户单元、用户站、移动站、移动台、远方站、远程终端、移动设备、用户终端、终端、无线通信设备、用户代理或用户装置、具有无线通信功能的手持设备、计算设备或连接到无线调制解调器的其它处理设备、车载设备、可穿戴设备以及未来5G网络中的终端设备。终端设备可以经无线接入网(radio access network,RAN)与一个或多个核心网进行通信,或者可以通过自组织或免授权的方式接入分布式网络,终端设备还可以通过其它方式接入无线网络进行通信,终端设备也可以与其它终端设备直接进行无线通信,本申请的实施例对此不作限定。
本申请实施例中所称的通信设备也可以是芯片。
本申请实施例中所称的通信设备也可以是网络设备。
本申请实施例中所称的网络设备可以是5G通信系统中的基站(gNB)、未来通信系统中的基站或网络设备等。
本申请实施例中所称的上行控制信道可以是物理上行控制信道(Physical Uplink Control Channel,PUCCH)。
本申请实施例中所称的上行共享信道也可以称为上行数据信道,可以是物理上行共享 信道(Physical Uplink Shared Channel,PUSCH)。
图1是根据本申请实施例提供的传输信息的方法的示意性流程图。图1所示的方法可以由通信设备执行。
101,根据第二时域资源,确定用于传输第一上行信息和第二上行信息的目标传输方案,其中该第一上行信息由上行控制信道携带,该第二上行信息由上行共享信道携带,该第一上行信息所在的第一时域资源和该第二上行信息所在的该第二时域资源在时域上部分重叠或全部重叠,该第一时域资源包括至少一个符号,该第二时域资源包括至少一个符号。
102,根据该目标传输方案,传输该第一上行信息和/或该第二上行信息。
该第一时域资源和该第二时域资源在时域上部分重叠是指存在至少一个符号,该符号既属于该第一时域资源又属于该第二时域资源。
该第一时域资源和该第二时域资源在时域上全部重叠是指该第一时域资源与该第二时域资源相同。
该第一时域资源和该第二时域资源在时域上全部重叠还可以指该第一时域资源包括该第二时域资源或者该第二时域资源包括该第一时域资源。
该第一上行信息可以是上行控制信息(Uplink Control Information,UCI),包括周期信道状态信息(Periodic Channel State Information,P-CSI)报告、半持续性信道状态信息(Semi-persistent Channel State Information,S-CSI)报告、非周期性信道状态(Aperiodic Channel State Information,A-CSI)报告、混合自动重传请求(Hybrid Automatic Request reQuest,HARQ)反馈信息和调度请求(Scheduling Request,SR)中的至少一个。该第一时域资源的单位是符号。该第一时域资源可以包括连续的多个符号。由该上行控制信道承载的信息可以是在多个时隙/迷你时隙联合发送。在此情况下,每个时隙/迷你时隙内在该上行控制信道上发送的上行信息可以认为是一个单独的第一上行信息。不同时隙/迷你时隙的上行控制信道上发送的上行信息可以按照相同的方式处理。
该第二上行信息可以是上行数据和A-CSI包括中的至少一个。该第二时域资源的单位是符号。该第二时域资源可以包括连续的多个符号,也可以包括不连续的多个符号。
图1所示的实施例所讨论的是该第一时域资源与该第二时域资源部分重叠或全部重叠的情况下如何确定该目标传输方案。该第一时域资源与该第二时域资源不重叠时,如何传输该第一上行信息和该第二上行信息并不在图1所示的实施例所讨论的范围内。
执行图1所示方法的通信设备可以是终端设备、能够设置在终端设备内的芯片、网络设备或者能够设置在网络设备内的芯片。
在图1所示的方法由终端设备或能够设置在终端设备内的芯片执行的情况下,术语“传输”是指通信设备向网络设备发送。
在图1所示的方法由网络设备或者能够设置在网络设备内的芯片执行的情况下,术语“传输”是指通信设备接收终端设备发送。
例如,若图1所示的方法由网络设备执行,则步骤101中“确定用于传输第一上行信息和第二上行信息的目标传输方案”是指确定终端设备用于发送该第一上行信息和该第二上行信息的目标传输方案。类似的,步骤102中传输该第一上行信息和/或该第二上行信息是指接收该终端设备发送的该第一上行信息和/或该第二上行信息。
为了方便描述,以下实施例中所称的第一上行信息可以指由上行控制信道携带的信息,第二上行信息可以指由上行共享信道携带的信息。
该第二时域资源可以由N个子时域资源组成,所述N个子时域资源分别属于N个时隙或N个迷你时隙,该N个子时域资源中的每个子时域资源为1个时隙或1个迷你时隙中属于该第二时域资源的全部时域资源,N为大于或等于1的正整数。
若该通信设备为终端设备或能够设置在终端设备内的芯片,则终端设备或能够设置在终端设备内的芯片可以根据该网络设备的指示确定该第一时域资源和该第二时域资源。例如,在时隙n-5中接收到该网络设备的时域资源指示信息,该时域资源指示信息用于指示该第一时域资源为时隙n-5后的第5个时隙且起始符号为1。在此情况下,可以确定该第一时域资源的起始位置为时隙n的第二个符号,n为整数。又如,在时隙n-5中接收到该网络设备的时域资源指示信息,该时域资源指示信息用于指示该第二时域资源为时隙n-5后的第5个时隙且起始符号为2。在此情况下,可以确定该第二时域资源的起始位置为时隙n的第三个符号。
此外,该网络设备还可以指示时域资源持续的时隙数目。例如,该时域资源指示信息除了可以用于指示该第二时域资源为时隙n-5后的第5个时隙且起始符号为2外,还可以指示该第二时域资源持续2个时隙。这样,该第二时域资源可以包括两个子时域资源,第一子时域资源的起始位置为时隙n的第三个符号,第二子时隙资源的起始位置为时隙n+1的第二个符号。
此外,该网络设备还可以指示时域资源持续的迷你时隙数目。例如,该时域资源指示信息除了可以用于指示该第二时域资源为迷你时隙n-5后的第5个迷你时隙且起始符号为2外,还可以指示该第二时域资源持续2个迷你时隙。这样,该第二时域资源可以包括两个子时域资源,第一子时域资源的起始位置为迷你时隙n的第三个符号,第二子时隙资源的起始位置为迷你时隙n+1的第三个符号。
此外,该网络设备还可以指示时域资源持续的符号数目。例如,该网络设备还可以指示该第一时域资源持续长度为5个符号;该第二时域资源持续长度为2个符号。
可以理解的是,若该通信设备为网络设备或者能够设置在网络设备内的芯片,则该网络设备或者能够设置在网络设备内的芯片可以自行确定该第一时域资源和该第二时域资源。
可选的,在一些实施例中,该根据第二时域资源,确定用于传输第一上行信息和第二上行信息的目标传输方案,包括:确定可用子时域资源集合,其中该可用子时域资源集合包括M个可用子时域资源,其中该可用子时域资源属于该N个子时域资源,并且该可用子时域资源的起始时刻不早于该第一时域资源的起始时刻与第一时间长度的差,并且该可用子时域资源的起始时刻不晚于该第一时域资源的结束时刻与第二时间长度的和,M为大于或等于0的整数;根据M的取值,确定该目标传输方案为第一传输方案、第二传输方案、第三传输方案、第四传输方案、第五传输方案、第六传输方案和第七传输方案中的至少一个。
该第一时间长度的取值可以为0也可以根据终端设备从接收下行共享信道到生成HARQ反馈信息所需的最低处理时间和接收下行共享信道到反馈HARQ反馈信息的时隙数据计算出来。
该在下行数据为增强移动宽带(Enhanced Mobile Broadband,eMBB)的情况下,对应的HARQ反馈信息的最大允许延迟可以是1个时隙或者14个符号。在下行数据为海量机器类通信(Massive Machine-Type Communication,mMTC)的情况下,对应的HARQ反馈信息的最大允许延迟可以是2个时隙或者28个符号。在下行数据为极高可靠性低时延通信(Ultra-Reliable Low Latency Communication,URLLC)的情况下,对应的HARQ反馈信息的最大允许延迟可以是0个时隙或者0个符号。
该第二时间长度可以是该第一上行信息的最大允许延迟发送时延门限。该第二时间长度可以由网络设备指示、或者根据业务类型等确定。
可选的,在一些实施例中,M等于1。在此情况下,可以确定该目标传输方案为该第一传输方案。
可选的,在另一些实施例中,M等于0。在此情况下,可以确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个。
可选的,在一些实施例中,M为大于1的正整数。在此情况下,可以确定该目标传输方案为该第六传输方案和该第七传输方案中的一个。
也就是说,该通信设备该根据M的取值,确定该目标传输方案为第一传输方案、第二传输方案、第三传输方案、第四传输方案、第五传输方案、第六传输方案和第七传输方案中的至少一个,包括:该通信设备在确定M等于1的情况下,可以确定该目标传输方案为该第一传输方案;在确定M等于0的情况下,可以确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个;在确定M为大于1的正整数的情况下,可以确定该目标传输方案为该第六传输方案和该第七传输方案中的至少一个。
可选的,在一些实施例中,在M为大于1的正整数的情况下,该通信设备可以根据预设规则或者网络设备指示确定该目标传输方案为该第六传输方案。
可选的,在一些实施例中,在M为大于1的正整数的情况下,该通信设备可以根据预设规则或者网络设备指示确定该目标传输方案为该第七传输方案。
可选的,在一些实施例中,在M为大于1的正整数的情况下,该通信设备可以根据预设规则或者网络设备指示确定该目标传输方案为该第六传输方案和该第七传输方案。
可选的,在一些实施例中,该确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个,包括:根据终端设备的能力信息、网络设备的能力信息和优先级信息中的至少一个,确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个,其中,该终端设备的能力信息为终端设备是否支持同时在多个信道发送上行信息,该网络设备的能力信息为该网络设备是否支持同时接收由同一终端设备在多个信道上发送的上行信息,该优先级信息用于指示该第一上行信息的优先级和第二上行信息的优先级。
可选的,在一些实施例中,该优先级信息可以是包括该第一优先级的具体等级和该第二优先级的具体等级。这样,可以直接根据该优先级信息比较该第一优先级和该第二优先级。
可选的,在另一些实施例中,该优先级信息可以是能够指示该第一优先级和该第二优先级的信息。例如,该优先级信息可以是该第一上行信息的误块率(Block Error Rate, BLER)和该第二上行信息的误块率。这样,可以通过比较该第一上行信息的误块率(以下简称BLER1)和该第二上行信息的误块率(以下简称BLER2)来比较该第一优先级和该第二优先级。
例如,若BLER1等于BLER2,则该第一优先级等于该第二优先级;若BLER1小于BLER2,则该第二优先级大于该第一优先级;若BLER1大于BLER2,则该第一优先级大于该第二优先级。
可选的,在一些实施例中,该优先级信息还可以包括第一预设值和第二预设值。这样,可以通过比较BLER1、BLER2、该第一预设值和该第二与设置来比较该第一优先级和该第二优先级。
例如,若BLER1/BLER2小于该第一预设值,则该第一优先级大于该第二优先级;若BLER2/BLER1小于该第二预设值,则该第一优先级小于该第二优先级;否则,该第一优先级等于该第二优先级。
可选的,在一些实施例中,该优先级信息中的全部或者部分信息可以是由该网络设备指示的。相应的,该优先级信息中的全部或者部分信息也可以是预先设置的。例如,BLER1和BLER2可以是该网络设备指示的,该第一预设值和该第二预设值可以是预先设置的。又如,BLER1、BLER2、该第一预设值和该第二预设值可以都是由该网络设备指示的。
可选的,在另一些实施例中,若该通信设备为该终端设备,则该确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的一个,包括:接收网络设备发送的传输方案指示信息,该传输方案指示信息用于指示该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的一个;根据该传输方案指示信息,确定该目标传输方案。
可选的,在另一些实施例中,该终端设备和该网络设备还可以互相协商确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的一个。
可选的,在一些实施例中,该终端设备支持同时在多个信道上发送上行信息。在此情况下,可以确定该目标传输方案为该第二传输方案。
可选的,在一些实施例中,该网络设备支持同时接收由同一终端设备在多个信道上发送的上行信息。在此情况下,可以确定该目标传输方案为该第二传输方案。
可选的,在一些实施例中,该第一上行信息的优先级等于该第二上行信息的优先级。在此情况下,可以确定该目标传输方案为该第三传输方案。
可选的,在一些实施例中,该第一上行信息的优先级大于该第二上行信息的优先级。在此情况下,可以确定该目标传输方案为该第四传输方案。
可选的,在一些实施例中,该第一上行信息的优先级小于该第二上行信息的优先级。在此情况下,可以确定该目标传输方案为该第五传输方案。
换句话说,该通信设备在确定该终端设备支持同时在多个信道上发送上行信息和/或该网络设备支持同时接收由同一终端设备在多个信道上发送的上行信息的情况下,可以确定该目标传输方案为该第二传输方案;在确定该第一上行信息的优先级等于该第二上行信息的优先级的情况下,可以确定该目标传输方案为该第三传输方案;在确定该第一上行信息的优先级大于该第二上行信息的优先级的此情况下,可以确定该目标传输方案为该第四传输方案;在确定该第一上行信息的优先级小于该第二上行信息的优先级的此情况下,可 以确定该目标传输方案为该第五传输方案。
可选的,在一些实施例中,该第一传输方案为:在部分或全部的该可用子时域资源上传输该第一上行信息。
可选的,在一些实施例中,该第二传输方案为:在该第一时域资源上传输该第一上行信息。
可选的,在一些实施例中,该第三传输方案为:在该第三时域资源上传输该第一上行信息,该第三时域资源为从该第二时域资源结束时刻起到目标时刻内的第一个能够用于传输该第一上行信息的时域资源,其中该目标时刻为该第一时域资源结束时刻与第二时间长度之和。
可选的,在一些实施例中,该第四传输方案为:在该第一时域资源上传输第一上行信息,并将该第二上行信息在重叠时域资源或者重叠时频资源上的信息打孔,该重叠时域资源为该第一时域资源与该第二时域资源中重叠的时域资源,该重叠时频资源为第一时频资源与第二时频资源中重叠的时频域资源,其中该第一时频资源为用于传输该第一上行信息的时频资源,该第二时频资源为用于传输该第二上行信息的时频资源。
可选的,在一些实施例中,该第五传输方案为:在第四时域或者第四时频资源上传输该第一上行信息,并将该第一上行信息在该重叠时域资源或者该重叠时频资源上的信息打孔,该第四时域资源为该第一时域资源中除去该重叠时域资源中的时域资源之外的时域资源,该第四时频资源为该第一时频资源中除去该重叠时频资源之外的时频资源。
可选的,在一些实施例中,该第六传输方案为:在该可用子时域资源集合中特定可用子时域资源上传输该第一上行信息。
可选的,在一些实施例中,该第七传输方案为:在该可用子时域资源集合中的至少一个可用子时域资源上传输该第一上行信息。
可选的,在一些实施例中,该特定可用子时域资源为该可用子时域资源集合中的第一个可用子时域资源。
可选的,在一些实施例中,该特定可用子时域资源为该可用子时域资源集合中的第一个承载非自解码冗余版本的可用子时域资源。
可选的,在一些实施例中,该至少一个可用子时域资源为为该可用子时域资源集合中的全部可用子时域资源。
可选的,在一些实施例中,该至少一个可用子时域资源为该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源。
可选的,在一些实施例中,该第一传输方案、第二传输方案、第三传输方案、第五传输方案、第六传输方案和第七传输方案,还包括,在该第二时域资源上传输第二上行信息。
可选的,在一些实施例中,该第四传输方案还包括,在该第二时域资源除去该重叠时频资源或该重叠时域资源中的时域资源之外的时域资源上传输第一上行信息,或者,在该第二时频资源除去该重叠时频资源之外的时频资源上传输该第一上行信息。
假设该第一上行信息的优先级高于该第二上行信息的优先级。则该目标传输方案为该第四传输方案,即在该第一时域资源上传输第一上行信息,并将该第二上行信息在重叠时域资源或者重叠时频资源上的信息打孔,在该第二时域资源除去该重叠时域资源或该重叠时频资源中的时域资源之外的时域资源上传输第二上行信息,该重叠时域资源为该第一时 域资源与该第二时域资源中重叠的时域资源,该重叠时频资源为第一时频资源与第二时频资源中重叠的时频域资源,其中该第一时频资源为用于传输该第一上行信息的时频资源,该第二时频资源为用于传输该第二上行信息的时频资源。
例如,假设该第二上行信息与该第一上行信息仅在时域资源重叠,因此将该第二上行信息在该重叠时域资源上的信息打孔即可。本申请实施例中所称的将该第二上行信息在重叠时域资源上的信息打孔是指在重叠符号内仅传输该第一上行信息。假设该第一上信息信息和该第二上行信息都在一个时隙内传输,且该第二上行信息的起始符号为符号2,持续8个符号。也就是说,在不存在该第一上行信息的情况下,符号2、3、4、5、6、7、8、9均用于传输该第二上行信息。假设该第一上行信息的起始符号为符号7,持续2个符号。也就是说,在不存在该第二上行信息的情况下,符号7和符号8均用于传输该第一上行信息。由于同时存在该第一上行信息和该第二上行信息,因此符号7和符号8是重叠的符号。在此情况下,不会在符号7和符号8传输该第二上行信息的信息,符号7和符号8用于传输该第一上行信息,原本由符号7和符号8携带的信息不再被传输。该第二上行信息可以在符号2、3、4、5、6、9传输。
假设该第二上行信息的优先级高于该第一上行信息的优先级,则该目标传输方案为该第五传输方案,即在第四时域上传输该第一上行信息,并将该第一上行信息在该重叠时域资源或者该重叠时频资源上的信息打孔,在该第二时域资源上传输第二上行信息,该第四时域资源为该第一时域资源中除去该重叠时频资源中的时域资源之外的时域资源。
例如,假设该第二上行信息与该第一上行信息仅在时域资源重叠,因此将该第一上行信息在该重叠时域资源上的信息打孔即可。本申请实施例中所称的将该第一上行信息在重叠时域资源上的信息打孔是指在重叠符号内仅传输该第二上行信息。假设该第一上信息信息和该第二上行信息都在一个时隙内传输,且该第二上行信息的起始符号为符号2,持续8个符号。也就是说,在不存在该第一上行信息的情况下,符号2、3、4、5、6、7、8、9均用于传输该第二上行信息。假设该第一上行信息的起始符号为符号7,持续2个符号。也就是说,在不存在该第二上行信息的情况下,符号7和符号8均用于传输该第一上行信息。由于同时存在上行信息2和上行信息3,因此符号7和符号8是重叠的符号。在此情况下,不会在符号7和符号8传输该第一上行信息的信息,原本由符号7和符号8携带的该第一上行信息不再被传输,符号7和符号8依然用于传输该第二上行信息。换句话说,在此情况下不传输该第一上行信息。
类似的,若该第一频域资源与该第二频域资源重叠且该第一时域资源与该第二时域资源也重叠,则可以在重叠的时频资源上的信息打孔。在时频域资源上的信息打孔可以以资源块(Resource Block,RB)为单位进行打孔。
可选的,在另一些实施例中,该根据第二时域资源,确定用于传输第一上行信息和第二上行信息的目标传输方案,包括:确定该第二时域资源包括的至少一个符号所属的时隙数目Q;根据Q的值,确定该目标传输方案。
可选的,在一些实施例中,Q可以为1。在此情况下,可以确定该第一目标传输方案为第一传输方案、第二传输方案、第三传输方案和第四传输方案中的一个。
可选的,在另一些实施例中,该Q可以为大于1的正整数。在此情形,可以根据该第一时域资源包括的至少一个符号所属的时隙位置,确定该第一目标传输方案为该第一传输 方案、该第二传输方案、该第三传输方案、该第四传输方案、第五传输方案、第六传输方案、第七传输方案和第八传输方案中的一个。
通信设备可以先Q的取值,在Q=1的情况下,确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个;在Q为大于1的正整数的情况下,可以根据该第一时域资源包括的至少一个符号的时域位置,确定该第一目标传输方案为该第一传输方案至该第八传输方案中的一个。
可以看出,在Q的取值不同的情况下,第一目标传输方案的选择范围也是不同的。此外,若Q为大于1的正整数,在确定该第一目标传输方案时,还需要考虑该第一时域资源包括的至少一个符号所属的时域位置。
上述实施例中是根据Q的取值是否为1来确定该第一目标传输方案的范围。可以理解的是,还可以根据Q的取值是否为其他值来确定该第一目标传输方案的范围。例如,若Q的取值为小于或等于2的正整数,确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个;若Q为大于或等于3的正整数,可以根据该第一时域资源包括的至少一个符号所属的时域位置,确定该第一目标传输方案为该第一传输方案至该第八传输方案中的一个。
另外,上述实施例中,该第一目标传输方案的选择范围也可以相应变化。例如,若Q的取值为小于或等于2的正整数,确定该第一目标传输方案为该第一传输方案或该第二传输方案;若Q为大于或等于3的正整数,可以根据该第一时域资源包括的至少一个符号所属的时域位置,确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个。
可选的,在一些实施例中,该第一时域资源包括的至少一个符号所属的时隙为该Q个时隙中的最后一个时隙。在此情况下,可以确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个。
可选的,在另一些实施例中,该第一时域资源包括的至少一个符号所属的时隙为除该Q个时隙中的最后一个时隙以外的任一个时隙。在此情况下,可以确定可用时隙集合并根据该可用时隙集合,确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案、该第四传输方案、该第五传输方案、该第六传输方案、该第七传输方案和该第八传输方案中的一个。
该通信设备可以先确定该第一时域资源包括的至少一个符号所属的时隙在该Q个时隙中的位置,在确定该第一时域资源包括的至少一个符号所属的时隙为该Q个时隙中的最后一个时隙的情况下,可以确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个;在确定该第一时域资源包括的至少一个符号所属的时隙为除该Q个时隙中的最后一个时隙以外的任一个时隙的情况下,可以确定可用时隙集合并根据该可用时隙集合,确定该第一目标传输方案为该第一传输方案至该第八传输方案中的一个。
可以看出,在该第一时域资源包括的至少一个符号所属的时隙位置不同的情况下,该第一目标传输方案的选择范围也是不同的。此外,若该第一时域资源包括的至少一个符号所属的时隙为除该Q个时隙中的最后一个时隙以外的任一个时隙,在确定该第一目标传输方案时,还需要考虑可用时隙。
上述实施例中是该第一时域资源包括的至少一个符号所属的时隙为是否为该Q个时隙中的最后一个时隙来确定该第一目标传输方案的范围。可以理解的是,还可以根据该第 一时域资源包括的至少一个符号所属的时隙为是否为该Q个时隙中的其他一个时隙来确定该第一目标传输方案的范围。例如,若该第一时域资源包括的至少一个符号所属的时隙为是否为该Q个时隙中的最后两个时隙中的一个时隙,确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个;若该第一时域资源包括的至少一个符号所属的时隙为是否为该Q个时隙中的前两个时隙中的一个时隙,可以确定可用时隙集合并根据该可用时隙集合,确定该第一目标传输方案为该第一传输方案至该第八传输方案中的一个。
另外,上述实施例中,该第一目标传输方案的选择范围也可以相应变化。例如,若该第一时域资源包括的至少一个符号所属的时隙为该Q个时隙中的最后一个时隙的情况下,可以确定该第一目标传输方案为该第一传输方案或该第二传输方案;若该第一时域资源包括的至少一个符号所属的时隙为除该Q个时隙中的最后一个时隙以外的任一个时隙的情况下,可以确定可用时隙集合并根据该可用时隙集合,确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个。
可选的,在一些实施例中,该可用时隙集合可以为空。在此情况下,可以确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个。
可选的,在另一些实施例中,该可用时隙集合可以为非空。在此情况下,可以确定该第一目标传输方案可以为该第五传输方案、该第六传输方案、该第七传输方案和该第八传输方案中的一个。
该通信设备可以确定该可用时隙集合是否为空,在确定该可用时隙集合为空集的情况下,确定该第一目标传输方案为该第一传输方案至该第四传输方案中的一个;在确定该可用时隙集合为非空集合的情况下,确定该第一目标传输方案为该第五传输方案至该第八传输方案中的一个。
可以看出,根据该可用时隙集合是否为空集,该第一目标传输方案的选择范围也是不同的。
可选的,在一些实施例中,确定该第一目标传输方案可以为该第五传输方案、该第六传输方案、该第七传输方案和该第八传输方案中的一个可以是根据网络设备的指示确定。换句话说,该通信设备可以接收该网络设备发送的指示信息,该指示信息用于指示在该可用时隙集合可以为非空的情况下该第一目标传输方案为该第五传输方案、该第六传输方案、该第七传输方案或该第八传输方案。
可选的,在另一些实施例中,确定该第一目标传输方案可以为该第五传输方案、该第六传输方案、该第七传输方案和该第八传输方案中的一个可以是根据预设规则确定的。换句话说,该通信设备可以根据预设规则确定该第一目标传输方案为该第五传输方案、该第六传输方案、该第七传输方案和该第八传输方案中的一个。例如,若该第二上行信息包括可解码的冗余版本和/或不可自解码的冗余版本,则可以确定该第一目标传输方案为该第七传输方案或者该第八传输方案。若该第二上行信息不包括可解码的冗余版本或不可自解码的冗余版本,则可以确定该第一目标传输方案为该第五传输方案或者该第六传输方案。
可选的,在一些实施例中,确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个,包括:根据业务信息和时间信息,确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传 输方案中的一个,其中该业务信息包括上行控制信道的业务需求信息优先级信息中的至少一个,该时间信息包括第一时刻和第二时刻,该上行控制信道的业务需求信息用于指示该第一上行信息是否允许延迟发送,该优先级信息用于指示第一优先级和第二优先级,该第一优先级为该第一上行信息的优先级,该第二优先级为该第二上行信息的优先级,该第一时刻为生成该第一上行信息的时刻,该第二时刻为该第二时域资源的起始时刻。
可选的,在一些实施例中,该该第一时刻不晚于该第二时刻。在此情况下,可以确定该第一目标传输方案为该第一传输方案。
例如,假设该第一上行信息和该第二上行信息均在时隙n被发送,且该第一上行信息的起始符号为S1,该第二上行信息的起始符号为S2。该终端设备在生成该第一上行信息后,距离该第一上行信息的起始符号的剩余时间为t个符号。若S
1-t≤S
2,则该第一时刻不晚于该第二时刻。换句话说,若S
1-t≤S
2,则在传输该第二上行信息前,有足够时间生成该第一上行信息。若S
1-t>S
2,则该第一时刻晚于该第二时刻。换句话说,若S
1-t>S
2,则在传输给第二上行信息前,没有足够时间生成该第一上行信息。
上述技术方案中考虑到了生成该第一上行信息所必须的处理时间。
可选的,在一些实施例中,该第一上行信息允许延迟发送且该第一时刻晚于该第二时刻且该第一优先级等于该第二优先级。在此情况下,可以确定该第一目标传输方案为该第二传输方案。
可选的,在一些实施例中,该第一上行信息允许延迟发送且该第一时刻晚于该第二时刻且该第一优先级大于该第二优先级。在此情况下,可以确定该第一目标传输方案为该第三传输方案。
可选的,在一些实施例中,该第一上行信息允许延迟发送且该第一时刻晚于该第二时刻且该第一优先级小于该第二优先级。在此情况下,可以确定该第一目标传输方案为该第四传输方案。
可选的,在一些实施例中,该第一上行信息不允许延迟发送且该第一优先级大于或等于该第二优先级。在此情况下,可以确定该第一目标传输方案为该第三传输方案。
可选的,在一些实施例中,该第一上行信息不允许延迟发送且该第一优先级小于该第二优先级。在此情况下,可以确定该第一目标传输方案为该第四传输方案。
该通信设备可以先确定该第一上行信息是否允许被延迟发送,该第一时刻是否晚于该第二时刻,该第一优先级是否大于该第二优先级中的两个或全部确定该第一目标传输方案。具体地,该通信设备在确定该第一时刻不晚于该第二时刻的情况下,可以确定该第一目标传输方案为该第一传输方案;在确定该第一上行信息允许延迟发送且该第一时刻晚于该第二时刻且该第一优先级等于该第二优先级的情况下,可以确定该第一目标传输方案为该第二传输方案;在确定该第一上行信息允许延迟发送且该第一时刻晚于该第二时刻且该第一优先级大于该第二优先级的情况下,可以确定该第一目标传输方案为该第三传输方案;在确定该第一上行信息允许延迟发送且该第一时刻晚于该第二时刻且该第一优先级小于该第二优先级的情况下,可以确定该第一目标传输方案为该第四传输方案;在确定该第一上行信息不允许延迟发送且该第一优先级大于或等于该第二优先级的情况下,可以确定该第一目标传输方案为该第三传输方案;在确定该第一上行信息不允许延迟发送且该第一优先级小于该第二优先级的情况下,可以确定该第一目标传输方案为该第四传输方案。
上述实施例中列出了多种用于确定该第一目标传输方案为该第一传输方案至该第四传输方案的规则。可以理解的是,在一些实施例中,可以同时应用上述全部规则,也可以仅应用上述规则中的部分规则。此外,本领域技术人员基于上述规则,还可以确定出利用其它用于确定该第一目标传输方案的规则。
可选的,该上行控制信道的业务需求信息和该优先级信息中的任意一个或者全部都可以是由网络设备指示给该通信设备的。未由该网络设备指示给该通信设备的信息可以是预先设定的。或者,该上行控制信道的业务需求信息和该优先级信息可以均是预先设定的。
可选的,在一些实施例中,该网络设备可以通过显示方式指示该上行控制信道的业务需求信息和该优先级信息。在另一些实施例中,该网络设备可以通过隐式方式指示该上行控制信道的业务需求信息和该优先级信息。例如,若该网络设备向该通信设备发送压缩下行授权(compact downlink grant),则由该上行控制信道携带的信息不允许延迟;若该网络设备向该通信设备发送的是正常下行授权(normal downlink grant),则由该上行控制信道携带的信息允许延迟1个时隙发送。
可选的,在一些实施例中,该上行控制信道的业务需求信息可以是业务类型。该业务类型包括增强移动宽带(Enhanced Mobile Broadband,eMBB)、极高可靠性低时延通信(Ultra-Reliable Low Latency Communication,URLLC)、海量机器类通信(Massive Machine-Type Communication,mMTC)。可选的,在一些实施例中,若该业务类型为URLLC,则由该上行控制信道携带的信息不允许延迟发送。若该业务类型为eMBB或mMTC,则该由上行控制信道携带的信息允许发送。这样,可以通过确定业务类型来确定由上行控制信道携带的信息是否允许延迟发送。
更进一步,该通信设备还可以根据该业务类型确定允许延迟发送的时隙数目。例如,若该业务类型为eMBB,则允许延迟发送的时隙数目为1;若该业务类型为mMTC,则允许延迟发送的时隙数目为2。该允许延迟发送的的时隙数目可以是预先设定的,也可以是由该网络设备指示给该通信设备的。
可选的,在一些实施例中,该上行控制信道的业务需求信息可以是允许延迟发送的的时隙数目。例如,若由该上行控制信道携带的信息不允许延迟发送,则该允许延迟发送的时隙数目的值为0;若由该上行控制信道携带的信息允许延迟发送T次,则该允许延迟发送的时隙数目的值为T,其中T为大于或等于1的正整数。这样,可以直接根据该上行控制信道的业务需求信息同时确定由该上行控制信道携带的信息是否允许延迟发送并且允许延迟发送的时隙数目。
可选的,在一些实施例中,该优先级信息可以是包括该第一优先级的具体等级和该第二优先级的具体等级。这样,可以直接根据该优先级信息比较该第一优先级和该第二优先级。
可选的,在另一些实施例中,该优先级信息可以是能够指示该第一优先级和该第二优先级的信息。例如,该优先级信息可以是该第一上行信息的误块率(Block Error Rate,BLER)和该第二上行信息的误块率。这样,可以通过比较该第一上行信息的误块率(以下简称BLER1)和该第二上行信息的误块率(以下简称BLER2)来比较该第一优先级和该第二优先级。
例如,若BLER1等于BLER2,则该第一优先级等于该第二优先级;若BLER1小于 BLER2,则该第二优先级大于该第一优先级;若BLER1大于BLER2,则该第一优先级大于该第二优先级。
可选的,在一些实施例中,该优先级信息还可以包括第一预设值和第二预设值。这样,可以通过比较BLER1、BLER2、该第一预设值和该第二与设置来比较该第一优先级和该第二优先级。
例如,若BLER1/BLER2小于该第一预设值,则该第一优先级大于该第二优先级;若BLER2/BLER1小于该第二预设值,则该第一优先级小于该第二优先级;否则,该第一优先级等于该第二优先级。
可选的,在一些实施例中,该优先级信息中的全部或者部分信息可以是由该网络设备指示的。相应的,该优先级信息中的全部或者部分信息也可以是预先设置的。例如,BLER1和BLER2可以是该网络设备指示的,该第一预设值和该第二预设值可以是预先设置的。又如,BLER1、BLER2、该第一预设值和该第二预设值可以都是由该网络设备指示的。
可选的,在一些实施例中,该第一上行信道信息为周期信道状态信息(Periodic Channel State Information,P-CSI)报告或者半持续性信道状态信息(Semi-persistent Channel State Information,S-CSI)报告。在此情况下,可以确定该可用时隙集合中的第一个时隙为该第一时域资源(即该第一时域资源包括的至少一个符号所属的时隙),该可用时隙的最后一个时隙为该第二时域资源中的最后一个时隙。
可选的,在一些实施例中,该第一上行信道信息为混合自动重传请求(Hybrid Automatic Request reQuest,HARQ)反馈信息或非周期性信道状态(Aperiodic Channel State Information,A-CSI)报告且生成该第一上行信息的时刻不晚于该第二时域资源的起始时刻。在此情况下,可以确定该可用时隙集合中的第一个时隙为该第一时域资源(即该第一时域资源包括的至少一个符号所属的时隙),该可用时隙集合的最后一个时隙为该第一时域资源之后的第M个时隙,其中M为该第一上行信息允许延迟的最大的时隙数目,M为大于或等于1的正整数。
可选的,在一些实施例中,该第一上行信息为该HARQ反馈信息或A-CSI报告且生成该第一上行信息的时刻晚于该第二时域资源的起始时刻。在此情况下,可以确定该可用时隙集合中的第一个时隙为该第一时域资源(即该第一时域资源包括的至少一个符号所述的时隙),该可用时隙集合的最后一个时隙为该第一时域资源之后的第M个时隙。
可选的,在一些实施例中,该通信设备可以根据该上行信息的类型且生成该第一上行信息的时刻,确定该可用时隙集合。具体地,在确定该第一上行信道信息为P-CSI报告或者S-CSI报告的情况下,可以确定该可用时隙集合中的第一个时隙为该第一时域资源(即该第一时域资源包括的至少一个符号所属的时隙),该可用时隙的最后一个时隙为该第二时域资源中的最后一个时隙;在确定该第一上行信道信息为HARQ反馈信息或A-CSI报告且生成该第一上行信息的时刻不晚于该第二时域资源的起始时刻的情况下,可以确定该可用时隙集合中的第一个时隙为该第一时域资源(即该第一时域资源包括的至少一个符号所属的时隙),该可用时隙集合的最后一个时隙为该第一时域资源之后的第M个时隙,其中M为该第一上行信息允许延迟的最大的时隙数目,M为大于或等于1的正整数;在确定该第一上行信息为该HARQ反馈信息或A-CSI报告且生成该第一上行信息的时刻晚于该第二时域资源的起始时刻的情况下,可以确定该可用时隙集合中的第一个时隙为该第 一时域资源(即该第一时域资源包括的至少一个符号所述的时隙),该可用时隙集合的最后一个时隙为该第一时域资源之后的第M个时隙。
例如,假设该第一上行信息和该第二上行信息均在时隙n被发送,且该第一上行信息的起始符号为S1,该第二上行信息的起始符号为S2。该终端设备在生成该第一上行信息后,距离该第一上行信息的起始符号的剩余时间为t个符号。若S
1-t≤S
2,则生成该第一上行信息的时刻不晚于该第二时域资源的起始时刻。换句话说,若S
1-t≤S
2,则在传输该第二上行信息前,有足够时间生成该第一上行信息。若S
1-t>S
2,则生成该第一上行信息的时刻晚于该第二时域资源的起始时刻。换句话说,若S
1-t>S
2,则在传输给第二上行信息前,没有足够时间生成该第一上行信息。
可选的,在一些实施例中,该第一传输方案为:将该第一上行信息与该第二上行信息通过该上行共享信道传输。
可选的,在一些实施例中,该第二传输方案为:确定是否使用第一时隙传输该第一上行信息,其中该第一时隙为该第一时域资源包括的至少一个符号所属的时隙的下一个时隙。这样,若该第一上行信息来不及与该第二上行信息联合传输,则可以将该第一上行信息延迟一个时隙处理。这样还可以有一定的概率成功发送该第一上行信息并且无需对该第一上行信息或该第二上行信息打孔。
可选的,在一些实施例中,该第三传输方案为:将该第二上行信息在该第一时域资源包括的至少一个符号所属的时隙内与该第一时域资源包括的至少一个符号重叠的信息打孔。虽然该第二上行信息的部分信息被打孔了,但是仍有部分信息被成功传输。这样可以减少需要重传的信息。
可选的,在一些实施例中,该第四传输方案为:将该第一上行信息在该第一时域资源包括的至少一个符号所属的时隙内与该第一时域资源包括的至少一个符号重叠的信息打孔。虽然该第一上行信息的部分信息被打孔了,但是仍有部分信息被成功传输。这样可以减少需要重传的信息。
可选的,在一些实施例中,该第五传输方案为:在第一个可用时隙,接收该终端设备通过该上行共享信道发送的该第一上行信息与该第二上行信息中由该第一个可用时隙携带的信息。
可选的,在一些实施例中,该第六传输方案为:在全部可用时隙,接收该终端设备通过该上行共享信道发送的该第一上行信息与该第二上行信息中由该全部可用时隙携带的信息。
可选的,在一些实施例中,该第七传输方案为:在该第二上行信息中包括至少一个非自解码的冗余版本信息的情况下,在携带该至少一个非自解码的冗余版本信息中的第一个非自解码的冗余版本信息的时隙接收该终端设备通过该上行共享信道发送的该第一上行信息与该第一个非自解码的冗余版本信息,在该第二上行信息中仅包括至少一个自解码的冗余版本信息的情况下,在携带该至少一个自解码的冗余版本信息中的第一个自解码冗余版本信息的时隙接收该终端设备通过该上行共享信道发送的该第一上行信息与该第一个自解码冗余版本信息。这样可以规避自解码冗余版本的由上行共享信道携带的信息。降低联合传输该第一上行信息和该第二上行信息对该第二上行信息传输的影响。
可选的,在一些实施例中,该第八传输方案为:在该第二上行信息中包括至少一个非 自解码的冗余版本信息的情况下,在该至少一个非自解码的冗余版本信息中的每个非自解码的冗余版本信息的每个时隙接收该终端设备通过该上行共享信道发送的该第一上行信息与该每个非自解码的冗余版本信息,在该第二上行信息中仅包括至少一个自解码的冗余版本信息的情况下,在该至少一个自解码的冗余版本信息中的每个自解码的冗余版本信息的每个时隙接收该终端设备通过该上行共享信道发送的该第一上行信息与该每个冗余版本信息。这样可以规避自解码冗余版本的由上行共享信道携带的信息。降低联合传输该第一上行信息和该第二上行信息对该第二上行信息传输的影响。
根据实际需求,上述第一传输方案至第八传输方案的具体内容也可以进行调整。在此就不一一列举。此外,可以理解的是,第一目标传输方案的选取范围可以是上述第一传输方案至第八传输方案中的全部传输方案。该第一目标传输方案的选取范围也可以是上述第一传输方案至第八传输方案中的部分传输方案。该第一目标传输方案的选取范围也可以是上述第一传输方案至第八传输方案中的部分传输方案以及其他未列举的传输方案。
可选的,在一些实施例中,该确定是否使用第一时隙发送该第一上行信息包括:确定第一时隙是否存在第三上行信息,其中该第三上行信息由该上行共享信道携带;确定结果为是(即使用该第一时隙发送该第一上行信息),确定该第一时域资源的起始符号为0并确定第二目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个;确定结果为否(即不使用该第一时隙发送该第一上行信息)且该第一上行信息不允许延迟发送,丢弃该第一上行信息;确定结果为否(即不使用该第一时隙发送该第一上行信息)且该第一上行信息仍然允许延迟发送,确定第二时隙是否存在第四上行信息,其中该第四上行信息由该上行共享信道携带,该第二时隙为该第一时隙的下一个时隙。
确定该第二目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个的具体确定过程与确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个的具体过程相同,在此就不必赘述。
如果该第一上行信息仍然允许延迟发送且在下一个时隙存在由上行共享信道携带的信息,则可以继续在下一个时隙确定该第一传输方案至该第四传输方案中的一个为目标传输方案。具体确定过程与确定该第一目标传输方案为该第一传输方案、该第二传输方案、该第三传输方案和该第四传输方案中的一个的具体过程相同。在此就不必赘述。
此外,每进行一次判决,该第一上行信息是否允许延迟发送的的时隙数目就减1。
可选的,在一些实施例中,在该第一上行信息通过多个公共时隙发送至该网络设备的情况下,该多个公共时隙中的每个公共时隙携带该第一上行信息,其中该公共时隙为同时携带该第一上行信息与该第二上行信息的时隙。
该每个公共时隙携带的该第一上行信息的比特数目相同。可选的,在一些实施例中,由K个公共时隙中的每个公共时隙携带的该第一上行的比特数目是由一个公共时隙携带该第一上行信息的比特数目的1/K,其中K为大于1的正整数。例如,假设第一上行信息包括2比特。可以将该第一上行信息复制为8比特。也就是说,总共包括4个第一上行信息。若该公共时隙的数目为1,则该公共时隙可以携带该8比特的第一上行信息。若该公共时隙的数目为2,则每个公共时隙可以包括4比特的第一上行信息。换句话说,每个公 共时隙可以携带两个该第一上行信息。可选的,在一些实施例中,可选的,在一些实施例中,由K个公共时隙中的每个公共时隙携带的该第一上行的比特数目与由一个公共时隙携带该第一上行信息的比特数目相同。例如,假设第一上行信息包括2比特。可以将该第一上行信息复制为8比特。也就是说,总共包括4个第一上行信息。若该公共时隙的数目为1,则该公共时隙可以携带该8比特的第一上行信息。若该公共时隙的数目为2,则每个公共时隙可以包括8比特的第一上行信息。换句话说,每个公共时隙可以携带两个该第一上行信息。
下面将结合具体实施例对本申请技术方案进行描述。
图2是根据本申请实施例提供的一种传输信息的方法的示意图。
如图2所示,通信设备确定在第n个时隙的符号1开始发送上行信息1。上行信息1由上行控制信道携带。该上行信息1为HARQ反馈信息。该上行信息1持续5个符号。该上行信息1的第一时间长度为0,该上行信息1的第二时间长度为1个时隙。
该通信设备确定在第n个时隙的符号2开始发送上行信息2。该上行信息2由上行共享信道携带。该通信设备确定该上行信息2仅在第n个时隙内被发送。该上行信息2持续8个符号。
该通信设备确定在第n个时隙的符号7开始发送上行信息3。上行信息3由上行控制信道携带。该上行信息3为A-CSI反馈信息。该上行信息3的第一时间长度为2个符号,该上行信息3的的第二时间长度为0。该上行信息3持续2个符号。
如图2所示,该上行信息1的时域资源与该上行信息2的时域资源部分重叠,该上行信息2的时域资源与该上行信息3的时域资源完全重叠。
该第二时域资源可以由N个子时域资源组成,该N个子时域资源分别属于N个时隙,该N个子时域资源中的每个子时域资源为1个时隙中属于该第二时域资源全部时域资源,N为大于或等于1的正整数。可以看出,图2所示的实施例中,该第二时域资源包括1个子时域资源,该子时域资源为第n个时隙中的符号2至符号9。
该可用子时域资源属于该N个子时域资源(以下简称规则1),并且该可用子时域资源的起始时刻不早于该第一时域资源的起始时刻与第一时间长度的差(以下简称规则2),并且该可用子时域资源的起始时刻不晚于该第一时域资源的结束时刻与第二时间长度的和(以下简称规则3)
对于上行信息1和上行信息2而言,根据规则1,可以确定该可用子时域资源的起始时刻为第n个时隙的符号2。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n个时隙的符号1。根据规则3,可以确定该可用时域资源的起始时刻不晚于第n+1个时隙的符号6。根据上述三个规则确定的结果,可以确定该可用子时域资源集合所包括的可用子时域资源为该第二时域资源包括的1个子时域资源。因此,M的值等于1。在此情况下,该目标传输方案可以是该目标传输方案为该第一传输方案,即在部分或全部的该可用子时域资源上传输该第一上行信息。由于该可用子时域集合中仅包括一个可用子时域,因此可以在该可用子时域资源上传输该上行信息1并在该第二时域资源(即第n个时隙的符号2至符号9)传输该上行信息2。
对于上行信息2和上行信息3而言,根据规则1,可以确定该可用子时域资源的起始时刻为第n个时隙的符号2。根据规则2,可以确定该可用子时域资源的起始时刻不早于 为第n个时隙的符号5。根据规则3,可以确定该可用时域资源的起始时刻不晚于第n个时隙的符号8。根据上述三个规则确定的结果,可以确定该可用子时域资源集合所包括的可用子时域的数目为0。也就是说,M的值等于0。在此情况下,该目标传输方案可以是该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个。
因此,可以根据终端设备的能力信息、网络设备的能力信息和优先级信息中的至少一个,确定该目标传输方案为该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个,其中,该终端设备的能力信息为终端设备是否支持同时在多个信道发送上行信息,该网络设备的能力信息为该网络设备是否支持同时接收由同一终端设备在多个信道上发送的上行信息,该优先级信息用于指示该第一上行信息的优先级和第二上行信息的优先级。
假设该终端设备支持同时在多个信道发送上行信息,和/或,该网络设备支持同时接收由同一终端设备在多个信道上发送的上行信息,则该目标传输方案为该第二传输方案,即在该第一时域资源上传输该第一上行信息,在该第二时域资源上传输第二上行信息。换句话说,可以在该第n个时隙的符号7和符号8传输上行信息3,在第n个时隙的符号2至符号9传输上行信息2。
假设该第一上行信息的优先级等于该第二上行信息的优先级,则该目标传输方案为该第三传输方案,即在该第三时域资源上传输该第一上行信息,该第三时域资源为从该第二时域资源结束时刻起到目标时刻内的第一个能够用于传输该第一上行信息的时域资源,其中该目标时刻为该第一时域资源结束时刻与第二时间长度之和。由于该上行信息3的第二时间长度为0。因此,该目标时刻即为该第一时域资源结束时刻。在此情况下,并第二时域资源结束时刻到该目标时刻之间没有能够用于传输该上行信息3的时域资源。在此情况下,可以不发送该上行信息3,在第n个时隙的符号2至符号9传输上行信息2。
假设该第一上行信息的优先级大于该第二上行信息的优先级,则该目标传输方案为该第四传输方案,即在该第一时域资源上传输第一上行信息,并将该第二上行信息在重叠时域资源或者重叠时频资源上的信息打孔,在该第二时域资源除去该重叠时域资源之外的时域资源上传输第一上行信息,或者,在该第二时频资源除去该重叠时频资源之外的时频资源上传输该第一上行信息,该重叠时域资源为该第一时域资源与该第二时域资源中重叠的时域资源,该重叠时频资源为第一时频资源与第二时频资源中重叠的时频域资源,其中该第一时频资源为用于传输该第一上行信息的时频资源,该第二时频资源为用于传输该第二上行信息的时频资源。
如图2所示,上行信息2与上行信息3仅在时域资源重叠,因此将上行信息2在该重叠时域资源上的信息打孔即可。如图2所示,在不存在上行信息3的情况下,符号2、3、4、5、6、7、8、9均用于传输该上行信息2。在不存在上行信息2的情况下,符号7和符号8均用于传输该上行信息3。根据该第四传输方案,不会在符号7和符号8传输该上行信息2的信息,符号7和符号8用于传输上行信息3,原本由符号7和符号8携带的上行信息2的不再被传输。上行信息2可以在符号2、3、4、5、6、9传输。
假设该第一上行信息的优先级小于该第二上行信息的优先级,则该目标传输方案为该第五传输方案,即在第四时域资源或者第四时频资源上传输该第一上行信息,并将该第一上行信息在该重叠时域资源或者该重叠时频资源上的信息打孔,在该第二时域资源上传输 第二上行信息,该第四时域资源为该第一时域资源中除去该重叠时域资源之外的时域资源,该第四时频资源为该第一时频资源中除去该重叠时频资源之外的时频资源。
如图2所示,上行信息2与上行信息3仅在时域资源重叠,因此将上行信息2在该重叠时域资源上的信息打孔即可。如图2所示,在不存在上行信息3的情况下,符号2、3、4、5、6、7、8、9均用于传输该上行信息2。在不存在上行信息2的情况下,符号7和符号8均用于传输该上行信息3。根据该第五传输方案,不会在符号7和符号8传输上行信息3,符号7和符号8用于发送上行信息2。上行信息2可以在符号2、3、4、5、6、7、89传输,而上行信息1不会被传输。
图3是根据本申请实施例提供的另一种传输信息的方法的示意图。
如图3所示,通信设备确定在第n个时隙的符号1开始发送上行信息1。上行信息1由上行控制信道携带。该上行信息1为HARQ反馈信息。该上行信息1持续5个符号。该上行信息1的第一时间长度为0,该上行信息1的第二时间长度为1个时隙。
该通信设备确定在第n个时隙的符号2开始发送上行信息2。该上行信息2由上行共享信道携带。该通信设备确定该上行信息2仅在第n个时隙内被发送。该上行信息2持续8个符号。
该通信设备确定在第n个时隙的符号7开始发送上行信息3。上行信息3由上行控制信道携带。该上行信息3为HARQ反馈信息。该上行信息3的第一时间长度为0,该上行信息3的的第二时间长度为1个时隙。该上行信息3持续2个符号。
该通信设备确定用于发送该上行信息1和该上行信息2的传输方案的具体过程与图2所示的实施例类似,在此就不必赘述。
对于上行信息2和上行信息3而言,根据规则1,可以确定该可用子时域资源的起始时刻为第n个时隙的符号2。根据规则2,可以确定该可用子时域资源的起始时刻不早于为第n个时隙的符号5。根据规则3,可以确定该可用时域资源的起始时刻不晚于第n个时隙的符号8。根据上述三个规则确定的结果,可以确定该可用子时域资源集合所包括的可用子时域的数目为0。也就是说,M的值等于0。在此情况下,该目标传输方案可以是该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个。
使用该第二传输方案、该第四传输方案和该第五传输方案的具体实现方式与图2所示的实施例相同,在此就不必赘述。
如图3所示在时隙n+1的符号3至符号10为上行资源1,上行资源1能够用于传输上行信息3。假设该第一上行信息的优先级等于该第二上行信息的优先级,则该目标传输方案为该第三传输方案,即在该第三时域资源上传输该第一上行信息,该第三时域资源为从该第二时域资源结束时刻起到目标时刻内的第一个能够用于传输该第一上行信息的时域资源,其中该目标时刻为该第一时域资源结束时刻与第二时间长度之和。由于该上行信息3的第二时间长度为1个时隙。因此,该目标时刻时隙n+1的符号8。在此情况下,并第二时域资源结束时刻到该目标时刻之间有能够用于传输上行信息3的时域资源。在此情况下,可以在该第n+1个时隙的符号3至符号8之间的时域资源发送该上行信息3,在第n个时隙的符号2至符号9传输上行信息2。
图4是根据本申请实施例提供的另一种传输信息的方法的示意图。
如图4所示,通信设备确定在第n至n+3个时隙发送上行信息1。每个时隙内起始的 符号位置为符号3,持续长度为8个符号。该上行信息1的第一时间长度为0,该上行信息1的第二时间长度为0个时隙。该上行信息1由上行控制信道携带。该上行信息1为HARQ反馈信息。
该通信设备确定在第n个时隙的符号2开始发送上行信息2。该上行信息2持续8个符号。该上行信息2由上行共享信道携带。
该通信设备确定在第n+2个时隙的符号3开始发送上行信息3。该上行信息3持续10个符号。该上行信息2由上行共享信道携带。
如前所述,由该上行控制信道承载的信息可以是在多个时隙/迷你时隙联合发送。在此情况下,每个时隙/迷你时隙内在该上行控制信道上发送的上行信息可以认为是一个单独的第一上行信息。不同时隙/迷你时隙的上行控制信道上发送的上行信息可以按照相同的方式处理。因此,对于上行信息1而言,可以认为是四个上行信息。因此,可以认为在第n个时隙发送的上行信息1为上行信息1a,在第n+1个时隙发送的上行信息1为上行信息1b,在第n+2个时隙发送的上行信息1为上行信息1c,在第n+3个时隙发送的上行信息1为上行信息1d。如图4所示,上行信息1a时域资源与上行信息2的时域资源重叠,上行信息1c的时域资源与上行信息3的时域资源重叠。因此,只需要考虑如何确定用于传输上行信息1a和上行信息2的传输方案,以及用于传输上行信息1c和上行信息3的传输方案即可。上行信息1b和上行信息1d可以直接传输。
对于上行信息1a和上行信息2,根据规则1,可以确定该可用子时域资源的起始时刻为第n个时隙的符号2。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n个时隙的符号4。根据规则3,可以确定该可用子时域资源的起始时刻不晚于第n个时隙的符号11。根据上述三个规则确定的结果,可以确定该可用子时域资源集合所包括的可用子时域的数目为0。也就是说,M的值等于0。在此情况下,该目标传输方案可以是该第二传输方案、该第三传输方案、该第四传输方案和该第五传输方案中的至少一个。
传输上行信息1a和上行信息2的方式与图2所示的实施例中传输上行信息2和上行信息3的方式类似,在此就不必赘述。
对于上行信息1c和上行信息3,根据规则1,可以确定该可用子时域资源的起始时刻为第n+2个时隙的符号3。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n+2个时隙的符号3。根据规则3,可以确定该可用子时域资源的起始时刻不晚于第n+2个时隙的符号10。在图4所示的实施例中,用于传输上行信息3的时域资源包括1个子时域资源,该子时域资源为第n+2个中的符号3至符号12。根据上述三个规则确定的结果,可以确定该可用子时域资源集合所包括的可用子时域资源为该用于传输上行信息3的时域资源包括1个子时域资源。因此,M的值等于1。在此情况下,该目标传输方案可以是该目标传输方案为该第一传输方案,即在部分或全部的该可用子时域资源上传输该第一上行信息。由于该可用子时域集合中仅包括一个可用子时域,因此可以在该可用子时域资源上传输该上行信息1c并在该用于传输上行信息3的时域资源(即第n+2个中的符号3至符号12)传输该上行信息2。
图5是根据本申请实施例提供的另一种传输信息的方法的示意图。
如图5所示,通信设备确定在第n+1个时隙的符号6发送上行信息1。该上行信息1由上行控制信道带。该上行信息1为P-CSI报告。该上行信息1持续3个符号。P-CSI报 告和S-CSI报告的第一时间长度和第二时间长度可以很大,例如可以是多个个时隙。因此,以下实施例中,该上行信息1的第一时间长度为2个时隙,该上行信息2的第二时间长度为3个时隙。
该通信设备确定在第n个时隙的符号7开始发送上行信息2。上行信息2由上行控制信道携带。该上行信息2为HARQ反馈信息。该上行信息2的第一时间长度为0,该上行信息2的第二时间长度为1个时隙。该上行信息2持续2个符号。
该通信设备确定在第n至n+3个时隙发送上行信息3。每个时隙内起始的符号位置为符号1,持续长度为10个符号,该上行信息3由上行共享信道携带。
该通信设备确定在第n+1个时隙的符号1发送上行信息4。该上行信息4由上行控制信道携带。该上行信息4为HARQ反馈信息。该上行信息4的第一时间长度为0,该上行信息4的第二时间长度为2个时隙。该上行信息4持续4个符号。
用于传输上行信息3的时域资源可以由4个子时域资源组成,该N个子时域资源分别属于4个时隙,即第n个时隙、第n+1个时隙、第n+2个时隙和第n+3个时隙。该4个子时域资源中的每个子时域资源包括10个符号。具体地,该4个子时域资源中的第1个子时域资源包括第n个时隙的符号1至符号10,该4个子时域资源中的第2个子时域资源包括第n+1个时隙的符号1至符号10,该4个子时域资源中的第3个子时域资源包括第n+2个时隙的符号1至符号10,该4个子时域资源中的4个子时域资源包括第n+3个时隙的符号1至符号10。
对于上行信息1和上行信息3,根据规则1,可以确定可用子时域资源起始时刻为第n个时隙的符号1,第n+1个时隙的符号1,第n+2个时隙的符号1或第n+3个时隙的符号1。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n-1个时隙的符号6。根据规则3,可以确定该可用子时域资源的起始时刻不晚于第n+4个时隙的符号8。根据上述三个规则确定的结果,可以确定该可用该子时域资源集合包括4个可用子时域资源,即第1个子时域资源至第4个子时域资源。也就是说,M的值为4。在此情况下,该目标传输方案可以该第六传输方案和该第七传输方案中的至少一个。
假设该终端设备确定该目标传输方案是该第六传输方案,即在该可用子时域资源集合中特定可用子时域资源上传输该第一上行信息且在该第二时域资源上传输第二上行信息,则该终端设备可以在该特定可用子时域资源上传输该上行信息1并在该第二时域资源(即第n个时隙的符号1至符号10,第n+1个时隙的符号1至符号10,第n+2个时隙的符号1至符号10和第n+3个时隙的符号1至符号10)传输该上行信息3。如前所述,该特定可用子时域资源可以是该可用子时域资源集合中的第一个可用子时域资源,或者,第一个承载非自解码冗余版本的可用子时域资源。
假设该终端设备确定该目标传输方案是该第七传输方案,即在该可用子时域资源集合中的至少一个可用子时域资源上传输该第一上行信息且在该第二时域资源上传输第二上行信息,则该终端设备可以在该至少一个可用子时域资源上传输该上行信息1并在该第二时域资源(即第n个时隙的符号1至符号10,第n+1个时隙的符号1至符号10,第n+2个时隙的符号1至符号10和第n+3个时隙的符号1至符号10)传输该上行信息3。如前所述,该至少一个可用子时域资源为为该可用子时域资源集合中的全部可用子时域资源,或者,该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源。
例如,假设第n个时隙、第n+1个时隙、第n+2个时隙和第n+3个时隙上的冗余版本(Redundancy Version,RV)版本分别为RV0、RV2、RV3和RV1,其中RV0和RV3是能够自解码的RV版本,RV2和RV1是非自解码的RV版本。在该目标传输方案为该第七传输方案且该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源的情况下,可以在第n+1个时隙和第n+3个时隙将该上行信息1发送至该网络设备。
可选的,在一些实施例中,第n+1个时隙中用于携带上行信息1的比特数目与第n+3个时隙中用于携带上行信息1的比特数目相同。此外,第n+1个时隙中用于携带上行信息1的比特数目是将该上行信息1映射到一个用于发送上行信息3的时隙的比特数目的1/2。例如,该第n+1个时隙中用于携带该上行信息1的比特数目为10,该第n+3个时隙中用于携带该上行信息1的比特数目也为10。假设RV1也是能够自解码的RV版本。在此情况下,只有第n+1个时隙能够携带该上行信息1。在此情况下,该第n+1个时隙中用于携带该上行信息1的比特数目为20。可以理解的是,由于增加了用于携带上行信息1的时隙数目,在第n+1个时隙和第n+3个时隙中用于携带上行信息3的比特数目就相应减少。
对于上行信息2和上行信息3,根据规则1,可以确定可用子时域资源起始时刻为第n个时隙的符号1,第n+1个时隙的符号1,第n+2个时隙的符号1或第n+3个时隙的符号1。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n个时隙的符号7。根据规则3,可以确定该可用子时域资源的起始时刻不晚于第n+1个时隙的符号8。根据上述三个规则确定的结果,可以确定该可用该子时域资源集合包括1个可用子时域资源,即第2个子时域资源。也就是说,M的值为1。此情况下,该目标传输方案可以是该目标传输方案为该第一传输方案,即在部分或全部的该可用子时域资源上传输该第一上行信息。由于该可用子时域集合中仅包括一个可用子时域,因此可以在该可用子时域资源上传输该上行信息2并在该第2个子时域资源(即第n+1个时隙的符号1至符号10)传输该上行信息2。
对于上行信息3和上行信息4,根据规则1,可以确定可用子时域资源起始时刻为第n个时隙的符号1,第n+1个时隙的符号1,第n+2个时隙的符号1或第n+3个时隙的符号1。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n+1个时隙的符号1。根据规则3,可以确定该可用子时域资源的起始时刻不晚于第n+3个时隙的符号4。根据上述三个规则确定的结果,可以确定该可用该子时域资源集合包括三个可用子时域资源,分别为第2子时域资源、第3子时域资源和第4子时域资源。也就是说,M的值为大于1的正整数。在此情况下,该目标传输方案可以是该第六传输方案和该第七传输方案中的至少一个。
假设该终端设备确定该目标传输方案是该第六传输方案,即在该可用子时域资源集合中特定可用子时域资源上传输该第一上行信息且在该第二时域资源上传输第二上行信息,则该终端设备可以在该特定可用子时域资源上传输该上行信息4并在该第二时域资源(即第n+1个时隙的符号1至符号10,第n+2个时隙的符号1至符号10和第n+3个时隙的符号1至符号10)传输该上行信息3。如前所述,该特定可用子时域资源可以是该可用子时域资源集合中的第一个可用子时域资源,或者,第一个承载非自解码冗余版本的可用子时域资源。
假设该终端设备确定该目标传输方案是该第七传输方案,即在该可用子时域资源集合 中的至少一个可用子时域资源上传输该第一上行信息且在该第二时域资源上传输第二上行信息,则该终端设备可以在该至少一个可用子时域资源上传输该上行信息4并在该第二时域资源(即第n+1个时隙的符号1至符号10,第n+2个时隙的符号1至符号10和第n+3个时隙的符号1至符号10)传输该上行信息3。如前所述,该至少一个可用子时域资源为为该可用子时域资源集合中的全部可用子时域资源,或者,该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源。
例如,假设第n+1个时隙、第n+2个时隙和第n+3个时隙上的RV版本分别为RV2、RV3和RV1,其中RV3是能够自解码的RV版本,RV2和RV1是非自解码的RV版本。在该目标传输方案为该第七传输方案且该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源的情况下,可以在第n+1个时隙和第n+3个时隙将该上行信息4发送至该网络设备。
可选的,在一些实施例中,第n+1个时隙中用于携带上行信息4的比特数目与第n+3个时隙中用于携带上行信息4的比特数目相同。此外,第n+1个时隙中用于携带上行信息4的比特数目是将该上行信息4映射到一个用于发送上行信息3的时隙的比特数目的1/2。例如,该第n+1个时隙中用于携带该上行信息4的比特数目为10,该第n+3个时隙中用于携带该上行信息4的比特数目也为10。假设RV1也是能够自解码的RV版本。在此情况下,只有第n+1个时隙能够携带该上行信息4。在此情况下,该第n+1个时隙中用于携带该上行信息4的比特数目为20。可以理解的是,由于增加了用于携带上行信息4的比特,在第n+1个时隙和第n+3个时隙中用于携带上行信息3的比特数目就相应减少。
图6是根据本申请实施例提供的另一种传输信息的方法的示意图。
如图6所示,通信设备确定在第n个时隙的符号2开始发送上行信息1,该上行信息1由上行控制信道携带。该上行信息1为HARQ反馈信息。该上行信息1的第一时间长度为0,该上行信息1的第二时间长度为1个时隙。该上行信息1持续4个符号。
通信设备确定在第n个时隙的符号1开始发送上行信息2。该上行信息2占用四个迷你时隙。该上行信息2由上行共享信道携带。每个迷你时隙包括3个符号。
用于传输上行信息2的时域资源可以由4个子时域资源组成,该4个子时域资源分别属于4个迷你时隙,该4个子时域资源中的每个子时域资源为1个迷你时隙中属于该第二时域资源的全部时域资源。可以看出,图6所示的实施例中,该第二时域资源包括4个子时域资源,该4个子时域资源中的每个子时域资源包括3个符号。具体地,该4个子时域资源中的第1个子时域资源包括第n个时隙的符号1至符号3,该4个子时域资源中的第2个子时域资源包括第n个时隙的符号4至符号6,该4个子时域资源中的第3个子时域资源包括第n个时隙的符号7至符号9,该4个子时域资源中的4个子时域资源包括第n个时隙的符号10至符号12。
对于上行信息1和上行信息2,根据规则1,可以确定可用子时域资源的起始时刻为第n个时隙的符号1,第n个时隙的符号4,第n个时隙的符号7,第n个时隙的符号10。根据规则2,可以确定该可用子时域资源的起始时刻不早于第n个时隙的符号2。根据规则3,可以确定该可用子时域资源的起始时刻不晚于第n+1个时隙的符号5。根据上述三个规则确定的结果,可以确定该可用该子时域资源集合包括三个可用子时域资源,分别为第2子时域资源、第3子时域资源和第4子时域资源。也就是说,M的值为大于1的正整 数。在此情况下,该目标传输方案可以是该第六传输方案和该第七传输方案中的至少一个。
假设该终端设备确定该目标传输方案是该第六传输方案,即在该可用子时域资源集合中特定可用子时域资源上传输该第一上行信息且在该第二时域资源上传输第二上行信息,则该终端设备可以在该特定可用子时域资源上传输该上行信息1并在该第二时域资源(即第n个时隙的符号1至符号3,第n个时隙的符号4至符号6,第n个时隙的符号7至符号9和第n个时隙的符号10至符号12)传输该上行信息2。如前所述,该特定可用子时域资源可以是该可用子时域资源集合中的第一个可用子时域资源,或者,第一个承载非自解码冗余版本的可用子时域资源。
假设该终端设备确定该目标传输方案是该第七传输方案,即在该可用子时域资源集合中的至少一个可用子时域资源上传输该第一上行信息且在该第二时域资源上传输第二上行信息,则该终端设备可以在该至少一个可用子时域资源上传输该上行信息1并在该第二时域资源(即第n个时隙的符号1至符号3,第n个时隙的符号4至符号6,第n个时隙的符号7至符号9和第n个时隙的符号10至符号12)传输该上行信息2。如前所述,该至少一个可用子时域资源为为该可用子时域资源集合中的全部可用子时域资源,或者,该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源。
例如,假设第n个时隙的符号1至符号3,第n个时隙的符号4至符号6,第n个时隙的符号7至符号9和第n个时隙的符号10至符号23上的冗余版本(Redundancy Version,RV)版本分别为RV0、RV2、RV3和RV1,其中RV0和RV3是能够自解码的RV版本,RV2和RV1是非自解码的RV版本。在该目标传输方案为该第七传输方案且该可用子时域资源集合中所有承载非自解码冗余版本的可用子时域资源的情况下,可以在第2个子时域资源和第3个子时域资源将该上行信息1发送至该网络设备。
可选的,在一些实施例中,第2个子时域资源用于携带上行信息1的比特数目与第3个子时域资源中用于携带上行信息1的比特数目相同。此外,第2个子时域资源中用于携带上行信息1的比特数目是将该上行信息1映射到一个用于发送上行信息2的上行资源的比特数目的1/2。例如,该第2个子时域资源中用于携带该上行信息1的比特数目为10,该第3个子时域资源中用于携带该上行信息1的比特数目也为10。假设RV1也是能够自解码的RV版本。在此情况下,只有第2个子时域资源能够携带该上行信息4。在此情况下,该第2个子时域资源中用于携带该上行信息1的比特数目为20。可以理解的是,由于增加了用于携带上行信息1的比特,在第2个子时域资源和第3个子时域资源中用于携带上行信息2的比特数目就相应减少。
图7是根据本申请实施例提供的另一传输方法的示意性流程图。图7所示的方法可以由通信设备执行。
701,确定用于传输第一上行信息的第一时域资源,其中该第一上行信息为上行控制信道上行控制信道携带,该第一时域资源包括N个符号,该N个符号属于一个时隙。
702,确定用于传输第二上行信息的第二时域资源,其中该第二上行信息由上行共享信道上行共享信道携带,该第二时域资源包括M个符号,该M个符号属于一个时隙;
703,该N个符号所属的时隙与该M个符号所属相同且该N个符号与该M个符号不冲突的且该第一时域资源与该第二时域资源是连续的时域资源,确定用于发送该第一上行信息和该第二上行信息的目标传输方案。
该目标传输方案用于控制发送该第一上行信息和该第二上行信息的功率控制方案。利用图7所示的方法,可以提升资源利用效率。
可选的,在一些实施例中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案为,确定该目标传输方案为使用第一功率向网络设备发送该第一上行信息和该第二上行信息,其中该第一功率为用于发送该第一上行信息的功率。这样,在该第一上行信息的优先级高于该第二上行信息的情况下,可以优先保证该第一上行信息的发送功率。
可选的,在一些实施例中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:根据总发送能量,确定该目标传输方案为丢弃该第二上行信息并使用第一功率发送该第一上行信息,或者降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息,其中该第一功率为用于发送该第一上行信息的功率,其中该总发送能量为使用该第一功率发送该第一上行信息和该第二上行信息的能量。该总发送能量W=P×(N'+M'),其中P表示所述第一功率,N’为所述第一时域资源包括的N个符号的时长,M’为该第二时域资源包括的M个符号的时长。
可选的,在一些实施例中,该根据总发送能量,确定该目标传输方案为丢弃该第二上行信息并使用第一功率发送该第一上行信息,或者降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息,包括:预设门限与该总发送能量的比值大于第一预设值,确定该目标传输方案为丢弃该第二上行信息并使用该第一功率发送该第一上行信息;该预设门限与该总发送能量的比值不大于该第一预设值,确定该目标传输方案为降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,该预设门限可以是一个时隙的总能量。可选的,在另一些实施例中,该预设门限可以是一个时隙中的多个符号的总能量。
可选的,在一些实施例中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:确定该目标传输方案为使用第二功率向网络设备发送该第一上行信息和该第二上行信息。这样,在该第一上行信息的优先级低于该第二上行信息的情况下,可以优先保证该第二上行信息的发送功率。
可选的,在一些实施例中,该确定用于发送该第一上行信息和该第二上行信息的目标传输方案,包括:根据总发送能量,确定该目标传输方案为丢弃该第一上行信息并使用第二功率发送该第二上行信息,或者降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息,其中该第二功率为用于发送该第二上行信息的功率,其中该总发送能量为使用该第一功率发送该第一上行信息和该第二上行信息的能量。该总发送能量W=P×(N'+M'),其中P表示所述第二功率,N’为所述第一时域资源包括的N个符号的时长,M’为该第二时域资源包括的M个符号的时长。
可选的,在一些实施例中,该根据总发送能量,确定该目标传输方案为丢弃该第一上行信息并使用第二功率发送该第二上行信息,或者降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息,包括:预设门限与该总发送能量的比值大于第二预设值,确定该目标传输方案为丢弃该第一上行信息并使用该第二功率发送该第二上行信息;该预设门限与该总发送能量的比值不大于该第二预设值,确定该目标传输方案为降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,该预设门限可以是一个时隙的总能量。可选的,在另一些 实施例中,该预设门限可以是一个时隙中的多个符号的总能量。
可选的,在一些实施例中,免授权(Grant-Free)的上行共享信道携带的上行信息的优先级高于基于调度(Grant-based)的上行控制信道的优先级。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由免授权的上行共享信道携带。在此情况下,目标传输方案可以是使用第二功率向网络设备发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由免授权的上行共享信道携带。此情况下,目标传输方案可以是根据总发送能量,确定该目标传输方案为丢弃该第一上行信息并使用第二功率发送该第二上行信息,或者降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,基于调度的上行控制信道的优先级高于基于调度的上行共享信道的优先级。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由基于调度的上行共享信道携带。在此情况下,目标传输方案可以是使用第一功率向网络设备发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由基于调度的上行共享信道携带。此情况下,目标传输方案可以是根据总发送能量,确定该目标传输方案为丢弃该第二上行信息并使用第一功率发送该第一上行信息,或者降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,免授权(Grant-Free)的上行共享信道携带的上行信息的优先级低于基于调度(Grant-based)的上行控制信道的优先级。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由免授权的上行共享信道携带。在此情况下,目标传输方案可以是使用第一功率向网络设备发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由免授权的上行共享信道携带。此情况下,目标传输方案可以是根据总发送能量,确定该目标传输方案为丢弃该第二上行信息使用第一功率发送该第一上行信息,或者降低该第一功率并使用降低后的该第一功率发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,基于调度的上行控制信道的优先级低于基于调度的上行共享信道的优先级。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由基于调度的上行共享信道携带。在此情况下,目标传输方案可以是使用第二功率向网络设备发送该第一上行信息和该第二上行信息。
可选的,在一些实施例中,该第一上行信息由基于调度的上行控制信道携带,该第二上行信息由基于调度的上行共享信道携带。此情况下,目标传输方案可以是根据总发送能量,确定该目标传输方案为丢弃该第一上行信息并使用第二功率发送该第二上行信息,或者降低该第二功率并使用降低后的该第二功率发送该第一上行信息和该第二上行信息。
图8是根据本申请实施例提供的一种通信设备的结构框图。如图8所示通信设备800包括处理单元801和发送单元802。
处理单元801,用于根据第二时域资源,确定用于传输第一上行信息和第二上行信息的目标传输方案,其中该第一上行信息由上行控制信道携带,该第二上行信息由上行共享信道携带,该第一上行信息所在的第一时域资源和该第二上行信息所在的该第二时域资源在时域上部分重叠或全部重叠,该第一时域资源包括至少一个符号,该第二时域资源包括至少一个符号。
传输单元802,用于根据处理单元801确定的该目标传输方案,传输该第一上行信息和/或该第二上行信息。
处理单元801和发送单元802的具体功能和有益效果,可以参见图1所示的实施例,在此就不必赘述。
处理单元801可以由处理器实现,传输单元802可以由收发器实现。
图9是根据本申请实施例提供的一种通信设备的结构框图。如图9所示,通信设备900包括处理单元901和发送单元902。
处理单元901,用于确定用于传输第一上行信息的第一时域资源,其中所述第一上行信息为上行控制信道上行控制信道携带,所述第一时域资源包括N个符号,所述N个符号属于一个时隙。
处理单元901,还用于确定用于传输第二上行信息的第二时域资源,其中所述第二上行信息由上行共享信道上行共享信道携带,所述第二时域资源包括M个符号,所述M个符号属于一个时隙;
处理单元901,还用于所述N个符号所属的时隙与所述M个符号所属相同且所述N个符号与所述M个符号不冲突的且所述第一时域资源与所述第二时域资源是连续的时域资源,确定用于发送所述第一上行信息和所述第二上行信息的目标传输方案。
传输单元902,用于根据处理单元901确定的该目标传输方案,向网络设备发送该第一上行信息和/或该第二上行信息。
处理单元901和传输单元902的具体功能和有益效果,可以参见图7所示的实施例,在此就不必赘述。
处理单元901可以由处理器实现,传输单元902可以由收发器实现。
图10是根据本申请实施例提供的另一通信设备的结构框图。如图10所示的通信设备1000包括存储器1001和处理器1002。
存储器1001,用于存储程序。
处理器1002,用于执行存储器1001存储的程序,当程序被执行时,使得通信设备1000可以实现上述图1实施例提供的方法。
利用通信设备1000可以将图1所示的方法中的部分或全部通过软件来实现。
存储器1001可以是物理上独立的单元,也可以与处理器1002集成在一起。
可选的,当图1所示的方法中的部分或全部通过软件实现时,通信设备1000也可以只包括处理器1002。用于存储程序的存储器1001位于装置1000之外,处理器1002通过电路/电线与存储器1001连接,用于读取并执行存储器1001中存储的程序。
处理器1002可以是中央处理器(central processing unit,CPU),网络处理器(network processor,NP)或者CPU和NP的组合。
处理器1002还可以进一步包括硬件芯片。上述硬件芯片可以是专用集成电路 (application-specific integrated circuit,ASIC),可编程逻辑器件(programmable logic device,PLD)或其组合。上述PLD可以是复杂可编程逻辑器件(complex programmable logic device,CPLD),现场可编程逻辑门阵列(field-programmable gate array,FPGA),通用阵列逻辑(generic array logic,GAL)或其任意组合。
存储器1001可以包括易失性存储器(volatile memory),例如随机存取存储器(random-access memory,RAM);存储器1001也可以包括非易失性存储器(non-volatile memory),例如快闪存储器(flash memory),硬盘(hard disk drive,HDD)或固态硬盘(solid-state drive,SSD);存储器1001还可以包括上述种类的存储器的组合。
图11是根据本申请实施例提供的另一通信设备的结构框图。如图11所示的通信设备1100包括存储器1101和处理器1102。
存储器1101,用于存储程序。
处理器1102,用于执行存储器1101存储的程序,当程序被执行时,使得通信设备1100可以实现上述图7实施例提供的方法。
利用通信设备1100可以将图7所示的方法中的部分或全部通过软件来实现。
存储器1101可以是物理上独立的单元,也可以与处理器1102集成在一起。
可选的,当图7所示的方法中的部分或全部通过软件实现时,通信设备1100也可以只包括处理器1102。用于存储程序的存储器1101位于装置1100之外,处理器1102通过电路/电线与存储器1101连接,用于读取并执行存储器1101中存储的程序。
处理器1102可以是中央处理器(central processing unit,CPU),网络处理器(network processor,NP)或者CPU和NP的组合。
处理器1102还可以进一步包括硬件芯片。上述硬件芯片可以是专用集成电路(application-specific integrated circuit,ASIC),可编程逻辑器件(programmable logic device,PLD)或其组合。上述PLD可以是复杂可编程逻辑器件(complex programmable logic device,CPLD),现场可编程逻辑门阵列(field-programmable gate array,FPGA),通用阵列逻辑(generic array logic,GAL)或其任意组合。
存储器1101可以包括易失性存储器(volatile memory),例如随机存取存储器(random-access memory,RAM);存储器1101也可以包括非易失性存储器(non-volatile memory),例如快闪存储器(flash memory),硬盘(hard disk drive,HDD)或固态硬盘(solid-state drive,SSD);存储器1101还可以包括上述种类的存储器的组合。
本申请的又一方面提供了一种计算机可读存储介质,所述计算机可读存储介质中存储有指令,当所述指令在计算机上运行时,使得计算机执行上述如图1所示的方法。
本申请的又一方面提供了一种计算机可读存储介质,所述计算机可读存储介质中存储有指令,当所述指令在计算机上运行时,使得计算机执行上述如图7所示的方法。
本申请的又一方面提供了一种包含指令的计算机程序产品,当该计算机程序产品在计算机上运行时,使得计算机执行如图1所示的方法。
本申请的又一方面提供了一种包含指令的计算机程序产品,当该计算机程序产品在计算机上运行时,使得计算机执行如图7所示的方法。
图12是根据本申请实施例提供的另一传输信息的方法的示意性流程图。图12所示的方法可以由通信设备执行。
1201,确定第一时频资源,其中该第一时频资源为上行控制信道的时频资源,该上行控制信道用于承载待传输的上行控制信息,该第一时频资源在第一时间单元内。
1202,确定第二时频资源,其中该第二时频资源为上行数据信道占用的时频资源,该上行数据信道用于承载待传输的上行数据,该第二时频资源由N个子时频资源组成,该N个子时频资源分别位于N个时间单元,该第一时频资源与该第二时频资源在时域重叠,N为大于或等于2的正整数。
1203,根据该第一时间单元,传输上行控制信息和上行数据。
图12所示的实施例提供了一种在上行控制信道占用的时域资源与上行数据信道占用的时域资源重叠的情况下,如何传输上行控制信息和上行数据的方法。
本申请实施例中所称的时间单元可以是时隙、迷你时隙、子帧等。该第一时频资源在第一时间单元内,而该第二时频资源占用N个时频资源。因此,如果该第一时频资源与该第二时频资源在时域重叠,则该第一时间单元为该N个时间单元中的一个时间单元。
该第一时频资源位于一个时间单元内,该第一时频资源的时域资源可以是该时间单元内的一个或多个符号,或者也可以是该时间单元包括的全部符号。该N个子时频资源中的每个子时频资源也可以是一个时间单元内的一个或多个符号,或者也可以是该时间单元内的全部符号。
可选的,在一些实施例中,该根据该第一时间单元,传输上行控制信息和上行数据,包括:在第一子时频资源传输该上行控制信息和该上行数据,其中该第一子时频资源为该N个子时频资源中的一个子时频资源,该第一子时频资源所在的时间单元的编号与该第一时间单元的编号相同。
进一步,该通信设备不在该第一时频资源上传输该上行控制信息。
更进一步,该上行控制信息的调制编码符号确定方法可以和现有技术一致,在此就不白赘述。
例如,假设该时间单元为时隙,假设该第二时频资源包括4个时间单元,该4个时间单元分别为时隙1、时隙2、时隙3和时隙4。该第一时频资源与该第二时频资源在时域重叠。也就是说,该第一时间单元可以是时隙1至时隙4中的任一个时隙。假设该第一时间单元为时隙2。在此情况下,该通信设备可以第一子时频资源传输上行控制信息和上行数据。该第一子时频资源为该第二时频资源包括的N个子时频资源中的一个子时频资源,且该第一子时频资源所在时隙为第一时频资源所在时隙,即时隙2。该通信设备不在该第一时频资源传输该上行控制信息。换句话说,在此情况下,该通信设备可以利用由上行数据信道占用的时频资源同时传输上行数据和上行控制信息。此外,该通信设备可以依然使用剩余的子时频资源传输上行数据。也就是说,该通信设备可以利用该N个子时频资源中的时域资源为时隙1、时隙3和时隙4对应的子时频资源传输原本就在这些子时频资源上传输的上行数据。
图12实施例中所称的上行控制信道可以用于承载待传输的上行控制信息。图12实施例中所称的上行数据信道可以用于承载待传输的上行控制信息。也就是说,上行控制信息可以由该上行控制信道承载。上行数据可以由上行数据信道承载。但是在一些实施例中,上行控制信息也可以由上行数据信道承载。例如,上述实施例中,时隙2对应的子时频资源既用于承载上行控制信息也用于承载上行数据。
可选的,在一些实施例中,该根据该第一时间单元,传输上行控制信息和上行数据,包括:在第一时频资源传输该上行控制信息,不在第二子时频资源上传输该上行数据,在第二时频资源中除该第二子时频资源以外的子时频资源上传输该上行数据,该第二子时频资源为N个子时频资源中的一个子时频资源,该第二子时频资源所在的时间单元的编号与该第一时间单元的编号相同。
例如,假设该时间单元为时隙,假设该第二时频资源包括4个时间单元,该4个时间单元分别为时隙1、时隙2、时隙3和时隙4。该第一时频资源与该第二时频资源在时域重叠。也就是说,该第一时间单元可以是时隙1至时隙4中的任一个时隙。假设该第一时间单元为时隙2。在此情况下,该通信设备可以第一时频资源传输上行控制信息。该通信设备不在第二子时频资源传输该上行数据。该第二子时频资源为该第二时频资源包括的N个子时频资源中的一个子时频资源,且该第二子时频资源所在时隙为第一时频资源所在时间时隙,即时隙2。换句话说,在此情况下,该通信设备在该第一时频资源与该第二时频资源发生冲突的时间单元仅传输该上行控制信息。此外,该通信设备可以依然使用剩余的子时频资源传输上行数据。也就是说,该通信设备可以利用该N个子时频资源中时域资源为时隙1、时隙3和时隙4的子时频资源传输该上行数据。
可选的,在一些实施例中,该根据该第一时间单元,传输上行控制信息和上行数据,包括:在M个子时频资源传输该上行控制信息和该上行数据,其中该M个子时频资源属于该N个子时频资源,该M个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于该第一时间单元的编号,M为大于或等于1且小于N的正整数。
例如,假设该时间单元为时隙,假设该第二时频资源包括4个时间单元,该4个时间单元分别为时隙1、时隙2、时隙3和时隙4。该第一时频资源与该第二时频资源在时域重叠。也就是说,该第一时间单元可以是时隙1至时隙4中的任一个时隙。假设该第一时间单元为时隙2。在此情况下,该通信设备可以在该4个子时频资源中的时域资源为时隙2至时隙4中的一个或多个子时频资源传输该上行控制信息和该上行数据。
可选的,在一些实施例中,该终端设备确定M个子时频资源,该M个子时频资源为该N个子时频资源中所在的时间单元的编号大于或等于该第一时间单元的编号的子时频资源。在该M个子时频资源内包括一个子时频资源对应的冗余版本是非自解码冗余版本的情况下,可以确定第三子时频资源为该M个子时频资源中的第一个对应非自解码冗余版本的子时频资源;在该M个子时频资源内不包括一个子时频资源对应的冗余版本是非自解码冗余版本的情况下,可以确定该第三子时频资源为该M个子时频资源内的第一个子时频资源。该通信设备可以在该第三子时频资源上传输该上行控制信息和该上行数据。该通信设备可以不在该第一时频上传输该上行控制信息。该通信设备还可以在该N个子时频资源中除该第二子时频资源以外的其他子时频资源上传输该上行数据。
例如,假设该时间单元为时隙,假设该第二时频资源包括4个时间单元,该4个时间单元分别为时隙1、时隙2、时隙3和时隙4,四个时隙内的子时频资源分别对应自解码冗余版本、非自解码冗余版本、自解码冗余版本、非自解码冗余版本。该第一时频资源与该第二时频资源在时域重叠。也就是说,该第一时间单元可以是时隙1至时隙4中的任一个时隙。假设该第一时间单元为时隙2。在此情况下,该M个子时频资源即为该4个子时频资源中时域资源位于时隙2至时隙4的三个子时频资源。在此情况下,该通信设备可以 在该三个子时频资源中的第1个子时频资源传输该上行控制信息和该上行数据,即时隙2所在子时频资源上传输该上行控制信息和该上行数据。假设该第一时间单元为时隙3。在此情况下,该M个子时频资源即为该4个子时频资源中时域资源位于时隙3至时隙4的2个子时频资源。在此情况下,该通信设备可以在该2个子时频资源中的第2个子时频资源传输该上行控制信息和该上行数据,即时隙4所在子时频资源上传输该上行控制信息和该上行数据。
可选的,在一些实施例中,该在M个子时频资源传输该上行控制信息和该上行数据,包括:确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目;根据该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目确定该上行控制信息的总的调制编码符号数目,将该上行控制信息的总调制编码符号分为M个部分,分别在该M个子时频资源上传输该M个部分,该M个部分的总调制编码符号数目等于该上行控制信息的总调制编码符号数目。
可选的,在一些实施例中,将上行控制信息的总调制编码符号分为M个部分可以是将该上行控制信息的总调制编码符号分为非重叠的M个部分。
可选的,在一些实施例中,该确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目,包括:根据该M个子时频资源内的总的可用资源粒子数目,确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目。这里所称的可用资源粒子是一个时频资源单位,频域跨度对应1个子载波,时域跨度对应1个正交频分复用(Orthogonal Frequency Division Multiplexing,OFDM)符号。当然,所述资源粒子的时频跨度也可以由其他定义,例如频域跨度为12个子载波,或者说1个RB,时域跨度为1个时隙、迷你时隙、子帧等。换句话说,可以根据该M个子时频资源内的总的可用资源粒子数目,确定该上行能控制信息在该上行数据信道上传输占据的RE数目。
可选的,在另一些实施例中,该确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目,包括:根据该M个子时频资源中的一个子时频资源的可用资源粒子数目,确定该上行控制信息在该上行数据信道上传输对应的每层调制编码符号数目。
该M个子时频资源内的总的可用资源粒子数目是指M个子时域资源包括的全部可用子时域资源内包含的资源粒子数目。例如,假设M等于2,每个子时域资源包括168个可用资源粒子。在此情况下,该M个子时频资源内的总的可用资源粒子数目为336。
该M个子时频资源中的一个子时频资源的可用资源粒子数目是一个子时域资源包括的可用资源粒子数目。例如,假设M等于2,每个子时域资源包括168个可用资源粒子。在此情况下,该M个子时频资源中的一个子时频资源的可用资源粒子数目为168。
可以理解的是,若M等于1,则该M个子时频资源中的一个子时频资源的可用资源粒子数目等于该M个子时频资源内的总的可用资源粒子数目。
可选的,在一些实施例中,图12所示的方法还可以包括:确定第六子时域资源,该第六子时域资源属于该N个子时域资源,且该第六子时域资源上承载来自L个子时域资源内的上行控制信道对应的上行控制信息,该来自L个子时域资源内的上行控制信道对应的上行控制信息属于同一类型,L为大于等于2的正整数。在该第六子时域资源上传输该上行控制信息的调制编码符号,所有该上行控制信息的调制编码符号是来自该L个子时域资源内的上行控制信息的调制编码符号的串接。
可选的,在一些实施例中,在步骤1203之前,该方法还包括:接收目标传输方案指示信息,该目标传输方案指示信息用于指示目标传输方案;根据该目标方案指示信息,确定该目标传输方案。在此情况下,该根据该第一时间单元,传输上行控制信息和上行数据,包括:基于该目标传输方案,根据该第一时间单元,传输该上行控制信息和该上行数据。
可选的,在一些实施例中,该目标方案指示信息用于指示该目标传输方案为第一传输方案或第二传输方案。例如,该目标方案指示信息为1时,该目标传输方案为该第一传输方案;该目标方案指示信息为0时,该目标传输方案为该第二传输方案。又如,该目标方案指示信息为0时,该目标传输方案为该第一传输方案;该目标方案指示信息为1时,该目标传输方案为该第二传输方案。又如,该目标方案指示信息为肯定(positive)时,该目标传输方案为该第一传输方案;该目标方案指示信息为否定(negative)时,该目标传输方案为该第二传输方案。本领域技术人员可以理解的是,该目标传输方案指示信息指示目标传输方案的方式还可以是除以上例子以外的其他方式,只要该目标传输方案指示信息能够指示不同的传输方案即可。
可选的,在另一些实施例中,该目标方案指示信息用于指示该目标传输方案为该第一传输方案或第三传输方案。例如,该目标方案指示信息为1时,该目标传输方案为该第一传输方案;该目标方案指示信息为0时,该目标传输方案为该第三传输方案。又如,该目标方案指示信息为0时,该目标传输方案为该第一传输方案;该目标方案指示信息为1时,该目标传输方案为该第三传输方案。又如,该目标方案指示信息为肯定(positive)时,该目标传输方案为该第一传输方案;该目标方案指示信息为否定(negative)时,该目标传输方案为该第三传输方案。本领域技术人员可以理解的是,该目标传输方案指示信息指示目标传输方案的方式还可以是除以上例子以外的其他方式,只要该目标传输方案指示信息能够指示不同的传输方案即可。
可选的,在另一些实施例中,该目标方案指示信息用于指示该目标传输方案为该第二传输方案或该第三传输方案。例如,该目标方案指示信息为1时,该目标传输方案为该第三传输方案;该目标方案指示信息为0时,该目标传输方案为该第二传输方案。又如,该目标方案指示信息为0时,该目标传输方案为该第三传输方案;该目标方案指示信息为1时,该目标传输方案为该第二传输方案。又如,该目标方案指示信息为肯定(positive)时,该目标传输方案为该第三传输方案;该目标方案指示信息为否定(negative)时,该目标传输方案为该第二传输方案。本领域技术人员可以理解的是,该目标传输方案指示信息指示目标传输方案的方式还可以是除以上例子以外的其他方式,只要该目标传输方案指示信息能够指示不同的传输方案即可。
可选的,在另一些实施例中,该目标方案指示信息用于指示该目标传输方案为第一传输方案、第二传输方案或第三传输方案。例如,该目标方案指示信息为00时,该目标传输方案为该第一传输方案;该目标方案指示信息为01时,该目标传输方案为该第二传输方案;该目标方案指示信息为10时,该目标传输方案为该第三传输方案。又如,该目标方案指示信息为11时,该目标传输方案为该第一传输方案;该目标方案指示信息为10时,该目标传输方案为该第二传输方案;该目标方案指示信息为01时,该目标传输方案为该第三传输方案。
该第一传输方案为:在第四子时频资源传输该上行控制信息和该上行数据,其中该第 四子时频资源为该N个子时频资源中的一个子时频资源,该第四子时频资源所在的时间单元的编号与该第一时间单元的编号相同。进一步,该第一传输方案还可以包括,不在该第一时频资源上传输该上行控制信息。
该第二传输方案为:在第一时频资源传输该上行控制信息,不在第五子时频资源上传输该上行数据,在第二时频资源中除该第五子时频资源以外的子时频资源上传输该上行数据,该第五子时频资源为N个子时频资源中的一个子时频资源,该第五子时频资源所在的时间单元的编号与该第一时间单元的编号相同。
该第三传输方案为:在T个子时频资源传输该上行控制信息和该上行数据,其中该T个子时频资源属于该N个子时频资源,该T个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于该第一时间单元的编号,T为大于或等于1且小于N的正整数。
可选的,在一些实施例中,该接收目标传输方案指示信息包括:接收高层信令,该高层信令携带该目标传输方案指示信息;或者,接收下行控制信令,该下行控制信令携带该目标传输方案指示信息。
图13是根据本申请实施例提供的一种通信设备的结构框图。如图13所示,通信设备1300包括处理单元1301和发送单元1302。
处理单元1301,用于确定第一时频资源,其中所述第一时频资源为上行控制信道的时频资源,所述上行控制信道用于承载待传输的上行控制信息,所述第一时频资源在第一时间单元内。
处理单元1301,还用于确定第二时频资源,其中所述第二时频资源为上行数据信道的时频资源,所述上行数据信道用于承载待传输的上行数据,所述第二时频资源由N个子时频资源组成,所述N个子时频资源分别位于N个时间单元,所述第一时频资源与所述第二时频资源在时域重叠,N为大于或等于2的正整数。
通信单元1302,用于根据所述第一时间单元,传输该上行控制信息和该上行数据。
处理单元1301和通信单元1302的具体功能和有益效果,可以参见图12所示的实施例,在此就不必赘述。
处理单元1301可以由处理器实现,通信单元1302可以由收发器实现。
图14是根据本申请实施例提供的另一通信设备的结构框图。如图14所示的通信设备1400包括存储器1401和处理器1402。
存储器1401,用于存储程序。
处理器1402,用于执行存储器1401存储的程序,当程序被执行时,使得通信设备1400可以实现上述图12实施例提供的方法。
利用通信设备1400可以将图12所示的方法中的部分或全部通过软件来实现。
存储器1401可以是物理上独立的单元,也可以与处理器1402集成在一起。
可选的,当图1所示的方法中的部分或全部通过软件实现时,通信设备1400也可以只包括处理器1402。用于存储程序的存储器1401位于装置1400之外,处理器1402通过电路/电线与存储器1401连接,用于读取并执行存储器1401中存储的程序。
处理器1402可以是中央处理器(central processing unit,CPU),网络处理器(network processor,NP)或者CPU和NP的组合。
处理器1402还可以进一步包括硬件芯片。上述硬件芯片可以是专用集成电路 (application-specific integrated circuit,ASIC),可编程逻辑器件(programmable logic device,PLD)或其组合。上述PLD可以是复杂可编程逻辑器件(complex programmable logic device,CPLD),现场可编程逻辑门阵列(field-programmable gate array,FPGA),通用阵列逻辑(generic array logic,GAL)或其任意组合。
存储器1401可以包括易失性存储器(volatile memory),例如随机存取存储器(random-access memory,RAM);存储器1401也可以包括非易失性存储器(non-volatile memory),例如快闪存储器(flash memory),硬盘(hard disk drive,HDD)或固态硬盘(solid-state drive,SSD);存储器1401还可以包括上述种类的存储器的组合。
本申请的又一方面提供了一种计算机可读存储介质,所述计算机可读存储介质中存储有指令,当所述指令在计算机上运行时,使得计算机执行上述如图12所示的方法。
本申请的又一方面提供了一种包含指令的计算机程序产品,当该计算机程序产品在计算机上运行时,使得计算机执行如图12所示的方法。
本领域普通技术人员可以意识到,结合本文中所公开的实施例描述的各示例的单元及算法步骤,能够以电子硬件、或者计算机软件和电子硬件的结合来实现。这些功能究竟以硬件还是软件方式来执行,取决于技术方案的特定应用和设计约束条件。专业技术人员可以对每个特定的应用来使用不同方法来实现所描述的功能,但是这种实现不应认为超出本发明的范围。
所属领域的技术人员可以清楚地了解到,为描述的方便和简洁,上述描述的系统、装置和单元的具体工作过程,可以参考前述方法实施例中的对应过程,在此不再赘述。
在本申请所提供的几个实施例中,应该理解到,所揭露的系统、装置和方法,可以通过其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如,所述单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个系统,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性,机械或其它的形式。
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。
另外,在本发明各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。
所述功能如果以软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。基于这样的理解,本发明的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本发明各个实施例所述方法的全部或部分步骤。而前述的存储介质包括:U盘、移动硬盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、磁碟或者光盘等各种可以存储程序代码的介质。
以上所述,仅为本发明的具体实施方式,但本发明的保护范围并不局限于此,任何熟 悉本技术领域的技术人员在本发明揭露的技术范围内,可轻易想到变化或替换,都应涵盖在本发明的保护范围之内。因此,本发明的保护范围应所述以权利要求的保护范围为准。
Claims (19)
- 一种传输信息的方法,其特征在于,所述方法包括:确定第一时频资源,其中所述第一时频资源为上行控制信道的时频资源,所述上行控制信道用于承载待传输的上行控制信息,所述第一时频资源在第一时间单元内;确定第二时频资源,其中所述第二时频资源为上行数据信道的时频资源,所述上行数据信道用于承载待传输的上行数据,所述第二时频资源由N个子时频资源组成,所述N个子时频资源分别位于N个时间单元,所述第一时频资源与所述第二时频资源在时域重叠,N为大于或等于2的正整数;根据所述第一时间单元,传输所述上行控制信息和所述上行数据。
- 如权利要求1所述的方法,其特征在于,所述根据所述第一时间单元,传输上行控制信息和上行数据,包括:在第一子时频资源传输所述上行控制信息和所述上行数据,其中所述第一子时频资源为所述N个子时频资源中的一个子时频资源,所述第一子时频资源所在的时间单元的编号与所述第一时间单元的编号相同。
- 如权利要求1所述的方法,其特征在于,所述根据所述第一时间单元,传输上行控制信息和上行数据,包括:在第一时频资源传输所述上行控制信息,不在第二子时频资源上传输所述上行数据,在第二时频资源中除所述第二子时频资源以外的子时频资源上传输所述上行数据,所述第二子时频资源为N个子时频资源中的一个子时频资源,所述第二子时频资源所在的时间单元的编号与所述第一时间单元的编号相同。
- 如权利要求1所述的方法,其特征在于,所述根据所述第一时间单元,传输上行控制信息和上行数据,包括:在M个子时频资源传输所述上行控制信息和所述上行数据,其中所述M个子时频资源属于所述N个子时频资源,所述M个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于所述第一时间单元的编号,M为大于或等于1且小于N的正整数。
- 如权利要求4所述的方法,其特征在于,所述在M个子时频资源传输所述上行控制信息和所述上行数据,包括:确定所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目;根据所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目确定所述上行控制信息的总的调制编码符号数目,将所述上行控制信息的总调制编码符号分为M个部分,分别在所述M个子时频资源上传输所述M个部分,所述M个部分的总调制编码符号数目等于所述上行控制信息的总调制编码符号数目。
- 如权利要求5所述的方法,其特征在于,所述确定所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目,包括:根据所述M个子时频资源内的总的可用资源粒子数目,确定所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目;或者根据所述M个子时频资源中的一个子时频资源的可用资源粒子数目,确定所述上行 控制信息在所述上行数据信道上传输对应的每层调制编码符号数目。
- 如权利要求1至6中任一项所述的方法,其特征在于,所述根据所述第一时间单元,传输上行控制信息和上行数据之前,所述方法还包括:接收目标传输方案指示信息,所述目标传输方案指示信息用于指示目标传输方案;根据所述目标方案指示信息,确定所述目标传输方案;所述根据所述第一时间单元,传输上行控制信息和上行数据,包括:基于所述目标传输方案,根据所述第一时间单元,传输所述上行控制信息和所述上行数据。
- 如权利要求7所述的方法,其特征在于,所述目标方案指示信息用于指示所述目标传输方案为第一传输方案或第二传输方案;或者所述目标方案指示信息用于指示所述目标传输方案为所述第一传输方案或第三传输方案;或者所述目标方案指示信息用于指示所述目标传输方案为所述第二传输方案或所述第三传输方案,其中所述第一传输方案为:在第四子时频资源传输所述上行控制信息和所述上行数据,其中所述第四子时频资源为所述N个子时频资源中的一个子时频资源,所述第四子时频资源所在的时间单元的编号与所述第一时间单元的编号相同;所述第二传输方案为:在第一时频资源传输所述上行控制信息,不在第五子时频资源上传输所述上行数据,在第二时频资源中除所述第五子时频资源以外的子时频资源上传输所述上行数据,所述第五子时频资源为N个子时频资源中的一个子时频资源,所述第五子时频资源所在的时间单元的编号与所述第一时间单元的编号相同;所述第三传输方案为:在T个子时频资源传输所述上行控制信息和所述上行数据,其中所述T个子时频资源属于所述N个子时频资源,所述T个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于所述第一时间单元的编号,T为大于或等于1且小于N的正整数。
- 一种通信设备,其特征在于,所述通信设备包括:处理单元,用于确定第一时频资源,其中所述第一时频资源为上行控制信道的时频资源,所述上行控制信道用于承载待传输的上行控制信息,所述第一时频资源在第一时间单元内;所述处理单元,还用于确定第二时频资源,其中所述第二时频资源为上行数据信道的时频资源,所述上行数据信道用于承载待传输的上行数据,所述第二时频资源由N个子时频资源组成,所述N个子时频资源分别位于N个时间单元,所述第一时频资源与所述第二时频资源在时域重叠,N为大于或等于2的正整数;通信单元,用于根据所述第一时间单元,传输所述上行控制信息和所述上行数据。
- 如权利要求9所述的通信设备,其特征在于,所述通信单元,具体用于在第一子时频资源传输所述上行控制信息和所述上行数据,其中所述第一子时频资源为所述N个子时频资源中的一个子时频资源,所述第一子时频资源所在的时间单元的编号与所述第一时间单元的编号相同。
- 如权利要求9所述的通信设备,其特征在于,所述通信单元,具体用于在第一时 频资源传输所述上行控制信息,不在第二子时频资源上传输所述上行数据,在第二时频资源中除所述第二子时频资源以外的子时频资源上传输所述上行数据,所述第二子时频资源为N个子时频资源中的一个子时频资源,所述第二子时频资源所在的时间单元的编号与所述第一时间单元的编号相同。
- 如权利要求9所述的通信设备,其特征在于,所述通信单元,具体用于在M个子时频资源传输所述上行控制信息和所述上行数据,其中所述M个子时频资源属于所述N个子时频资源,所述M个子时频资源中的任一个子时频资源所在的时间单元的编号大于或等于所述第一时间单元的编号,M为大于或等于1且小于N的正整数。
- 如权利要求12所述的通信设备,其特征在于,所述处理单元,还用于确定所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目,根据所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目确定所述上行控制信息的总的调制编码符号数目,将所述上行控制信息的总调制编码符号分为M个部分;所述通信单元,具体用于分别在所述M个子时频资源上传输所述M个部分,所述M个部分的总调制编码符号数目等于所述上行控制信息的总调制编码符号数目。
- 如权利要求13所述的通信设备,其特征在于,所述处理单元,具体用于根据所述M个子时频资源内的总的可用资源粒子数目,确定所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目;或者根据所述M个子时频资源中的一个子时频资源的可用资源粒子数目,确定所述上行控制信息在所述上行数据信道上传输对应的每层调制编码符号数目。
- 如权利要求9至14中任一项所述的通信设备,其特征在于,所述通信单元,还用于接收目标传输方案指示信息,所述目标传输方案指示信息用于指示目标传输方案;所述处理单元,还用于根据所述目标方案指示信息,确定所述目标传输方案;所述通信单元,具体用于基于所述目标传输方案,根据所述第一时间单元,传输所述上行控制信息和所述上行数据。
- 如权利要求15所述的通信设备,其特征在于,所述目标方案指示信息用于指示所述目标传输方案为第一传输方案或第二传输方案;或者所述目标方案指示信息用于指示所述目标传输方案为所述第一传输方案或第三传输方案;或者所述目标方案指示信息用于指示所述目标传输方案为所述第二传输方案或所述第三传输方案,其中所述第一传输方案为:在第四子时频资源传输所述上行控制信息和所述上行数据,其中所述第四子时频资源为所述N个子时频资源中的一个子时频资源,所述第四子时频资源所在的时间单元的编号与所述第一时间单元的编号相同;所述第二传输方案为:在第一时频资源传输所述上行控制信息,不在第五子时频资源上传输所述上行数据,在第二时频资源中除所述第五子时频资源以外的子时频资源上传输所述上行数据,所述第五子时频资源为N个子时频资源中的一个子时频资源,所述第五子时频资源所在的时间单元的编号与所述第一时间单元的编号相同;所述第三传输方案为:在T个子时频资源传输所述上行控制信息和所述上行数据,其中所述T个子时频资源属于所述N个子时频资源,所述T个子时频资源中的任一个子时 频资源所在的时间单元的编号大于或等于所述第一时间单元的编号,T为大于或等于1且小于N的正整数。
- 一种计算机可读存储介质,其特征在于,所述计算机可读存储介质中存储有指令,当所述指令在计算机上运行时,使得计算机执行权利要求1至权利要求8中任一项所述的方法。
- 一种包含指令的计算机程序产品,其特征在于,当所述计算机程序产品在计算机上运行时,使得所述计算机执行权利要求1至权利要求8中任一项所述的方法。
- 一种通信设备,其特征在于,所述通信设备包括存储器和处理器,所述存储器,用于存储程序;所述处理器,用于执行所述存储器存储的所述程序,当所述程序被执行时,所述处理器用于执行权利要求1至权利要求8中任一项所述的方法。
Applications Claiming Priority (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201711086786 | 2017-11-07 | ||
CN201711086786.3 | 2017-11-07 | ||
CN201810031421.9 | 2018-01-12 | ||
CN201810031421.9A CN109756979B (zh) | 2017-11-07 | 2018-01-12 | 传输信息的方法和通信设备 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2019091374A1 true WO2019091374A1 (zh) | 2019-05-16 |
Family
ID=66401756
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/CN2018/114175 WO2019091374A1 (zh) | 2017-11-07 | 2018-11-06 | 传输信息的方法和通信设备 |
Country Status (2)
Country | Link |
---|---|
CN (1) | CN109756979B (zh) |
WO (1) | WO2019091374A1 (zh) |
Families Citing this family (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111817830B (zh) * | 2019-07-10 | 2023-06-09 | 维沃移动通信有限公司 | 传输、接收控制方法、终端及网络侧设备 |
CN112242884A (zh) * | 2019-07-19 | 2021-01-19 | 大唐移动通信设备有限公司 | 信息传输方法及装置 |
WO2021108988A1 (zh) * | 2019-12-03 | 2021-06-10 | Oppo广东移动通信有限公司 | 资源冲突的处理方法、装置、终端及存储介质 |
CN113747587A (zh) * | 2020-05-28 | 2021-12-03 | 上海朗帛通信技术有限公司 | 一种被用于无线通信的节点中的方法和装置 |
WO2022027692A1 (zh) * | 2020-08-07 | 2022-02-10 | 华为技术有限公司 | 用于上行传输的方法、设备、通信装置及存储介质 |
CN114258135A (zh) * | 2020-09-25 | 2022-03-29 | 维沃移动通信有限公司 | 上行信道传输方法、装置及终端 |
WO2022188724A1 (zh) * | 2021-03-11 | 2022-09-15 | 华为技术有限公司 | 确定物理上行信道传输资源的方法及其装置 |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2016170425A1 (en) * | 2015-04-19 | 2016-10-27 | Alcatel Lucent | Methods and apparatuses for preventing collision among uplink control messages for lc-mtc devices |
US20170223695A1 (en) * | 2016-02-03 | 2017-08-03 | Lg Electronics Inc. | Method and apparatus for transmitting an uplink channel in a wireless communication system |
Family Cites Families (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR101763602B1 (ko) * | 2013-12-03 | 2017-08-01 | 엘지전자 주식회사 | 기계타입통신을 지원하는 무선 접속 시스템에서 상향링크 전송 방법 및 장치 |
-
2018
- 2018-01-12 CN CN201810031421.9A patent/CN109756979B/zh active Active
- 2018-11-06 WO PCT/CN2018/114175 patent/WO2019091374A1/zh active Application Filing
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2016170425A1 (en) * | 2015-04-19 | 2016-10-27 | Alcatel Lucent | Methods and apparatuses for preventing collision among uplink control messages for lc-mtc devices |
US20170223695A1 (en) * | 2016-02-03 | 2017-08-03 | Lg Electronics Inc. | Method and apparatus for transmitting an uplink channel in a wireless communication system |
Non-Patent Citations (1)
Title |
---|
SHARP: "Simultaneous PUCCH and PUSCH Transmission and Collision Handling", 3GPP TSG RAN WG1 NR#90BIS MEETING R1-1718418, 2 October 2017 (2017-10-02), XP051352530 * |
Also Published As
Publication number | Publication date |
---|---|
CN109756979B (zh) | 2020-12-08 |
CN109756979A (zh) | 2019-05-14 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
WO2019091374A1 (zh) | 传输信息的方法和通信设备 | |
CN110463121B (zh) | 用于接收下行链路数据传输的方法和装置 | |
US10834737B2 (en) | Wireless communication method and apparatus | |
WO2021027604A1 (zh) | 传输方法、装置、通信节点及介质 | |
US11212036B2 (en) | Data communication method, device, and system | |
TWI699132B (zh) | 用於行動通訊系統之基地台及使用者裝置 | |
CN106470089B (zh) | 一种上行控制信息的发送方法及装置 | |
KR101159944B1 (ko) | 보조 자원 할당의 이용 | |
CN111436153B (zh) | 一种信息处理方法、终端设备及网络设备 | |
CN107431577B (zh) | 控制信息的发送方法、用户设备和基站 | |
WO2020192609A1 (zh) | 资源的确定、接收方法、装置、电子装置及存储介质 | |
CN108696936B (zh) | 数据发送方法、接收方法和相关设备 | |
WO2019028771A1 (zh) | 传输数据的方法和终端设备 | |
EP3105873B1 (en) | Technique for storing softbits | |
WO2017194016A1 (zh) | 传输方法、设备和传输系统、及存储介质 | |
WO2018201915A1 (zh) | 数据处理方法和装置 | |
WO2018209803A1 (zh) | 一种传输信息的方法和装置 | |
EP3595220A1 (en) | Method and apparatus for sending and receiving feedback information | |
WO2021147103A1 (zh) | 一种译码方法、装置及系统 | |
WO2020228542A1 (zh) | 一种发送和接收harq-ack消息的方法及装置 | |
WO2017028606A1 (zh) | 一种上行控制信息的发送方法及装置 | |
CN108076519A (zh) | 一种被用于低延迟的ue、基站中的方法和设备 | |
WO2018223279A1 (zh) | 实现数据映射传输的方法及相关产品 | |
CN110972325B (zh) | 一种数据传输方法、设备及装置 | |
US20210307004A1 (en) | Service conflict processing method, user terminal and computer readable storage medium |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 18876237 Country of ref document: EP Kind code of ref document: A1 |
|
NENP | Non-entry into the national phase |
Ref country code: DE |
|
122 | Ep: pct application non-entry in european phase |
Ref document number: 18876237 Country of ref document: EP Kind code of ref document: A1 |