WO2024016186A1 - 一种多面板增强传输配置方法及其装置 - Google Patents
一种多面板增强传输配置方法及其装置 Download PDFInfo
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Definitions
- the present disclosure relates to the field of communication technology, and in particular, to a multi-panel enhanced transmission configuration method and device.
- the network side device can only configure one sounding reference signal SRS resource set for the terminal device, and the precoding of the terminal device is indicated by the SRS resource indication (ie, SRI) and the precoding matrix indication TPMI, the terminal device's Power control is also associated with the power control parameter set through SRI.
- SRS resource indication ie, SRI
- TPMI precoding matrix indication
- Embodiments of the present disclosure provide a multi-panel enhanced transmission configuration method and device, which can be applied to the Internet of Vehicles, such as vehicle to everything (V2X) communication and workshop communication long term evolution-vehicle (LTE) -V), vehicle to vehicle (V2V) communication, etc., or can be used in fields such as intelligent driving and intelligent connected vehicles.
- the network side device configures an SRS resource set and sends the configuration information of the SRS resource set to the terminal device, so that the terminal device can implement independent precoding and power control based on the configuration information, thereby enhancing the uplink transmission capabilities of different PDCCHs.
- embodiments of the present disclosure provide a multi-panel enhanced transmission configuration method.
- the method is executed by a network side device.
- the method includes: using different beams for multiple antenna panel panels with different associations for different transmitting and receiving points TRP.
- the physical uplink shared channel PUSCH is transmitted on the Internet, and at least one sounding reference signal SRS resource set is configured; wherein the PUSCH is a terminal device with multiple panels based on multiple downlink control information DCI scheduling, using different beams from different panels to face different TRPs at the same time
- Send respective PUSCHs send configuration information corresponding to the at least one sounding reference signal SRS resource set to the terminal device; wherein the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource Collections are associated with different control resource collection pool indexes.
- the PUSCH transmission includes at least one of DG-PUSCH DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indicator SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource subset.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure the authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- the network side device can configure an SRS resource set and send the configuration information of the SRS resource set to the terminal device, so that the terminal device can implement independent precoding and power control based on the configuration information, thereby enhancing different PDCCHs. uplink transmission capability.
- embodiments of the present disclosure provide a multi-panel enhanced transmission configuration method.
- the method is executed by a terminal device equipped with a multi-antenna panel panel.
- the method includes: receiving configuration information sent by a network side device; the configuration information Used to indicate the at least one SRS resource set, and the at least one SRS resource set is associated with different control resource set pool indexes; wherein the at least one SRS resource set is for the network side device and is for multiple associated different panels.
- Different transmitting and receiving points TRP use the physical uplink shared channel PUSCH on different beams to transmit a configured resource set.
- the PUSCH is the terminal device based on multiple downlink control information DCI scheduling and uses different beams from different panels to simultaneously transmit to different TRPs. PUSCH.
- the PUSCH transmission includes at least one of DG-PUSCHDG-PUSCH transmission and CG-PUSCHCG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the value of the control resource set pool index of the activated DCI is associated with different configuration authorization configuration parameters.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure the authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- the terminal device can receive the configuration information of the SRS resource set sent by the network side device, and implement independent precoding and power control based on the configuration information, thereby enhancing the uplink transmission capabilities of different PDCCHs.
- embodiments of the present disclosure provide a communication device, including: a processing module configured to use physical uplink shared channel PUSCH transmission on different beams for different transmitting and receiving points TRP for multiple antenna panel panels with different associations, and configure at least A sounding reference signal SRS resource set; wherein, the PUSCH is for terminal equipment with multiple panels to simultaneously transmit respective PUSCHs from different panels using different beams to different TRPs based on multiple downlink control information DCI scheduling; the transceiver module is used to The terminal device sends configuration information corresponding to the at least one sounding reference signal SRS resource set; wherein the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource set is associated with different control resource sets Pool index.
- the PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource subset.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure the authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- an embodiment of the present disclosure provides another communication device, including: a transceiver module, configured to receive configuration information sent by a network side device; the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource set.
- One SRS resource set is associated with different control resource set pool indexes; wherein, the at least one SRS resource set is that the network side device uses the physical uplink shared channel PUSCH on different beams for multiple panels with different associations for different transmitting and receiving points TRP.
- the PUSCH is for the terminal equipment to simultaneously transmit respective PUSCHs from different panels using different beams for different TRPs based on multiple downlink control information DCI schedules.
- the PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the value of the control resource set pool index of the activated DCI is associated with different configuration authorization configuration parameters.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- an embodiment of the present disclosure provides a communication device.
- the communication device includes a processor.
- the processor calls a computer program in a memory, it executes the method described in the first aspect.
- an embodiment of the present disclosure provides a communication device.
- the communication device includes a processor.
- the processor calls a computer program in a memory, it executes the method described in the second aspect.
- an embodiment of the present disclosure provides a communication device.
- the communication device includes a processor and a memory, and a computer program is stored in the memory; the processor executes the computer program stored in the memory, so that the communication device executes The method described in the first aspect above.
- an embodiment of the present disclosure provides a communication device.
- the communication device includes a processor and a memory, and a computer program is stored in the memory; the processor executes the computer program stored in the memory, so that the communication device executes The method described in the second aspect above.
- an embodiment of the present disclosure provides a communication device.
- the device includes a processor and an interface circuit.
- the interface circuit is used to receive code instructions and transmit them to the processor.
- the processor is used to run the code instructions to cause the The device executes the method described in the first aspect.
- an embodiment of the present disclosure provides a communication device.
- the device includes a processor and an interface circuit.
- the interface circuit is used to receive code instructions and transmit them to the processor.
- the processor is used to run the code instructions to cause the The device performs the method described in the second aspect above.
- embodiments of the present disclosure provide a multi-panel enhanced transmission configuration system.
- the system includes the communication device described in the third aspect and the communication device described in the fourth aspect, or the system includes the communication device described in the fifth aspect.
- embodiments of the present invention provide a computer-readable storage medium for storing instructions used by the above-mentioned terminal equipment. When the instructions are executed, the terminal equipment is caused to execute the above-mentioned first aspect. method.
- embodiments of the present invention provide a readable storage medium for storing instructions used by the above-mentioned network-side device. When the instructions are executed, the network-side device is caused to execute the above-mentioned second aspect. Methods.
- the present disclosure also provides a computer program product including a computer program, which when run on a computer causes the computer to execute the method described in the first aspect.
- the present disclosure also provides a computer program product including a computer program, which, when run on a computer, causes the computer to execute the method described in the second aspect.
- the present disclosure provides a chip system, which includes at least one processor and an interface for supporting a terminal device to implement the functions involved in the first aspect, for example, determining or processing data involved in the above method. and information.
- the chip system further includes a memory, and the memory is used to store necessary computer programs and data for the terminal device.
- the chip system may be composed of chips, or may include chips and other discrete devices.
- the present disclosure provides a chip system.
- the chip system includes at least one processor and an interface for supporting the network side device to implement the functions involved in the second aspect, for example, determining or processing the functions involved in the above method. At least one of data and information.
- the chip system further includes a memory, and the memory is used to store necessary computer programs and data for the network side device.
- the chip system may be composed of chips, or may include chips and other discrete devices.
- the present disclosure provides a computer program that, when run on a computer, causes the computer to execute the method described in the first aspect.
- the present disclosure provides a computer program that, when run on a computer, causes the computer to perform the method described in the second aspect.
- Figure 1 is a schematic architectural diagram of a communication system provided by an embodiment of the present disclosure
- Figure 2 is a schematic flowchart of a multi-panel enhanced transmission configuration method provided by an embodiment of the present disclosure
- Figure 3 is a schematic flowchart of another multi-panel enhanced transmission configuration method provided by an embodiment of the present disclosure
- Figure 4 is a schematic structural diagram of a communication device provided by an embodiment of the present disclosure.
- Figure 5 is a schematic structural diagram of another communication device provided by an embodiment of the present disclosure.
- FIG. 6 is a schematic structural diagram of a chip provided by an embodiment of the present disclosure.
- FIG. 1 is a schematic architectural diagram of a communication system provided by an embodiment of the present disclosure.
- the communication system may include but is not limited to one network side device and one terminal device.
- the number and form of devices shown in Figure 1 are only for examples and do not constitute a limitation on the embodiments of the present disclosure. In actual applications, two or more devices may be included.
- the communication system shown in Figure 1 includes a network side device 101 and a terminal device 102 as an example.
- LTE long term evolution
- 5th generation fifth generation
- NR NR system
- future new mobile communication systems For example: long term evolution (LTE) system, fifth generation (5th generation, 5G) mobile communication system, NR system, or other future new mobile communication systems.
- LTE long term evolution
- 5G fifth generation
- NR NR system
- future new mobile communication systems For example: long term evolution (LTE) system, fifth generation (5th generation, 5G) mobile communication system, NR system, or other future new mobile communication systems.
- the network side device 101 in the embodiment of the present disclosure is an entity on the network side that is used to transmit or receive signals.
- the network side device 101 can be an evolved base station, a transmission reception point (TRP), a next generation base station (next generation NodeB, gNB) in an NR system, a base station in other future mobile communication systems, or a wireless fidelity ( wireless fidelity, access nodes in WiFi) systems, etc.
- TRP transmission reception point
- gNB next generation base station
- gNB next generation base station
- wireless fidelity wireless fidelity, access nodes in WiFi
- the network-side device may be composed of a centralized unit (central unit, CU) and a distributed unit (DU), where the CU may also be called a control unit (control unit), using CU-
- the structure of DU can separate the protocol layers of network-side equipment, such as base stations, with some protocol layer functions placed under centralized control by the CU, while the remaining part or all protocol layer functions are distributed in the DU, and the CU centrally controls the DU.
- the terminal device 102 in the embodiment of the present disclosure is an entity on the user side that is used to receive or transmit signals, such as a mobile phone.
- Terminal equipment can also be called terminal equipment (terminal), user equipment (user equipment, UE), mobile station (mobile station, MS), mobile terminal equipment (mobile terminal, MT), etc.
- the terminal device can be a car with communication functions, a smart car, a mobile phone, a wearable device, a tablet computer (Pad), a computer with wireless transceiver functions, a virtual reality (VR) terminal device, an augmented reality (augmented reality (AR) terminal equipment, wireless terminal equipment in industrial control, wireless terminal equipment in self-driving, wireless terminal equipment in remote medical surgery, smart grid ( Wireless terminal equipment in smart grid, wireless terminal equipment in transportation safety, wireless terminal equipment in smart city, wireless terminal equipment in smart home, etc.
- the embodiments of the present disclosure do not limit the specific technology and specific equipment form used by the terminal equipment.
- multi-panel enhanced transmission configuration method can be applied to SDM (space division multiplexing, space division multiplexing), FDM (frequency division multiplexing, frequency division multiplexing) and TDM (time division multiplexing, time division multiplexing) and other communication methods.
- SDM space division multiplexing, space division multiplexing
- FDM frequency division multiplexing, frequency division multiplexing
- TDM time division multiplexing, time division multiplexing
- Figure 2 is a schematic flowchart of a multi-panel enhanced transmission configuration method provided by an embodiment of the present disclosure. This method is executed by the network side device. As shown in Figure 2, the method may include but is not limited to the following steps:
- Step S201 Use the physical uplink shared channel PUSCH (physical uplink shared channel, physical downlink shared channel) transmission on different beams for multiple antenna panel panels with different associations for different transmitting and receiving points TRP, and configure at least one SRS (sounding reference signal). Detection reference signal) resource collection.
- PUSCH physical uplink shared channel, physical downlink shared channel
- multiple antenna panel panels with different associations use the physical uplink shared channel PUSCH transmission on different beams for different sending and receiving points TRP, which means: multiple different antenna panel panels face different sending and receiving points TRP and perform PUSCH transmission respectively. ; And these different PUSCH transmissions use different beams.
- the network side device configures at least one SRS resource set for multiple PUSCH transmissions, where each PUSCH transmission is a PUSCH transmission on a beam used by a panle facing a TRP, and each PUSCH transmission corresponds to a panle plane.
- TRP and beam are not exactly the same.
- the above-mentioned PUSCH is scheduled by terminal equipment with multiple panels based on multiple DCI (downlink control information, downlink control information), and is sent from different panels using different beams to different TRP (transmitting and receiving point, transmitting and receiving points) simultaneously.
- Respective PUSCH are scheduled by terminal equipment with multiple panels based on multiple DCI (downlink control information, downlink control information), and is sent from different panels using different beams to different TRP (transmitting and receiving point, transmitting and receiving points) simultaneously.
- the above-mentioned PUSCH transmission includes DG-PUSCH (Dynamic Grant Physical Uplink Shared channel, dynamically granted physical uplink shared channel) transmission and CG-PUSCH (Configured Grant Physical Uplink Shared Channel, configured grant physical At least one of uplink shared channel) transmission.
- DG-PUSCH Dynamic Grant Physical Uplink Shared channel, dynamically granted physical uplink shared channel
- CG-PUSCH Configured Grant Physical Uplink Shared Channel, configured grant physical At least one of uplink shared channel
- the above-mentioned PUSCH transmission includes DG-PUSCH transmission.
- the above-mentioned PUSCH transmission includes CG-PUSCH transmission.
- the above-mentioned PUSCH transmission includes both DG-PUSCH transmission and CG-PUSCH transmission.
- the above-mentioned multiple panels with different associations use multiple DG-PUSCH transmissions of different beams for different TRPs, and the control resource set pool index value configured by the scheduling DCI is matched with the corresponding SRS resource. Collections are associated.
- each panel's TRP-oriented DG-PUSCH transmission is associated with an index value in a control resource set pool for scheduling DCI
- the SRS resource set is associated with an index of the control resource set pool for scheduling DCI.
- different DG-PUSCH transmissions correspond to different control resource pool index values.
- different DG-PUSCH transmissions use different beams.
- the SRS resource set associated with the control resource pool index value can be obtained through the control resource pool index value of the scheduled DCI associated with the DG-PUSCH transmission of a beam used by a panel for a TRP, so that Multiple panels with different associations use DG-PUSCH transmission of different beams for different TRPs, and are associated with the corresponding SRS resource set through the control resource set pool index value of the scheduled DCI.
- At least one SRS resource set is configured for each PUSCH.
- the PUSCH refers to the DG-PUSCH using a beam with one panel facing one TRP; different DG-PUSCH is the DG-PUSCH performed by different panels facing different TRPs, and different DG-PUSCH Use different beams.
- Step S202 Send configuration information corresponding to at least one SRS resource set to the terminal device.
- the above configuration information is used to indicate at least one SRS resource set, and the control resource set pool index associated with at least one SRS resource set; if multiple SRS resource sets are included, different SRS resource sets are associated with different control resource set pool indexes. .
- configuration information indicating at least one SRS resource set and a control resource set pool index associated with the at least one SRS resource set is sent to the terminal device.
- multiple different SRS resource sets are sent to the terminal device, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; multiple different SRS resources Collections correspond to different control resource set pool indexes.
- the above-mentioned at least one SRS resource set includes multiple different SRS resource sets.
- Each SRS resource set is associated with a panel for PUSCH transmission on a beam used by a TRP; and different PUSCH transmissions correspond to different controls.
- Resource set pool index is associated with a panel for PUSCH transmission on a beam used by a TRP; and different PUSCH transmissions correspond to different controls.
- the functional configurations of multiple different SRS resource sets are all “codebook” or “non-codebook”.
- the function configuration method of each SRS resource set among multiple different SRS resource sets is a "codebook”.
- the functional configuration mode of each of the multiple different SRS resource sets is "non-codebook”.
- codebook refers to assigning corresponding precodes to available functional configurations, consisting of multiple precodes, and using different sequence numbers for different precode numbers, so that it can be directly based on The sequence number searches for the corresponding precoding from the above table, which is the codebook.
- the number of SRS resources included in the above-mentioned multiple different SRS resource sets is configured independently. That is, each of the above multiple different SRS resource sets may include one or more SRS resources, and the number of SRS resources included in each SRS resource set may be the same or different.
- the above-mentioned multiple different SRS resource sets are respectively associated with different power control parameters and PLRS (Path loss estimation Reference Signal, path loss estimation reference signal) sets.
- PLRS Pulth loss estimation Reference Signal, path loss estimation reference signal
- each SRS resource set among the plurality of different SRS resource sets may be associated with a corresponding different power control parameter and path loss estimation reference signal PLRS set.
- the above-mentioned at least one SRS resource set is associated with different control resource set pool indexes, including: multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- each SRS resource set in multiple different SRS resource sets is associated with a control resource pool index, and different SRS resource sets are associated with different control resource pool indexes.
- the above-mentioned DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- different DG-PUSCHs are associated with different control resource pool index values
- different SRS resource sets are associated with different control resource pool indexes. Therefore, the SRS resource set associated with the control resource pool index can be obtained through the control resource pool index to which the control resource pool index value associated with DG-PUSCH belongs, and different DG-PUSCHs and different SRS resources can be realized. Collections are associated.
- the above-mentioned CG-PUSCH may be a type I CG-PUSCH; wherein, for the above-mentioned type I CG-PUSCH, the RRC (Radio Resource Control, Radio Resource Control) signaling is Configure the authorization configuration parameters to configure the identification of the corresponding SRS resource set, and SRI (Sounding reference signal Resource Identifier, detection reference signal resource indication), or configure the corresponding control resource pool index and corresponding control resource set pool index for the configuration authorization configuration parameters through RRC signaling.
- the RRC Radio Resource Control, Radio Resource Control
- SRI Sounding reference signal Resource Identifier, detection reference signal resource indication
- Type I CG-PUSCH means that uplink authorization is provided by RRC (radio resource control, radio resource control). Configure all transmission parameters through RRC signaling, including period, time offset and frequency resources, as well as the modulation and coding method used for uplink transmission. After the terminal device receives the RRC configuration, it uses the authorization of the received configuration to transmit at a time calculated by the preset period and offset.
- RRC radio resource control, radio resource control
- Uplink transmission authorization is provided by the resource management layer, and the terminal device stores this configuration and uses it as an authorized configuration.
- the network side device configures the identity of the corresponding SRS resource set and the SRI for configuring authorization configuration parameters through RRC signaling.
- the network side device configures the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the above-mentioned CG-PUSCH may be a type II CG-PUSCH; wherein, for a type II CG-PUSCH, different configurations are authorized by activating the control resource set pool index value of the DCI
- the configuration parameters are associated with the corresponding SRS resource set, and the specific SRI is also indicated by activating DCI.
- the network side device associates the corresponding SRS resource set for different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI.
- Type II CG-PUSCH refers to a transmission cycle provided by RRC, and the network side device implements resource activation and configuration of some transmission parameters through DCI, thereby realizing activation and transmission of the authorized configuration; After the terminal device receives the activation command, if there is data to send in the cache, it will be transmitted according to the preconfigured cycle. If there is no data, the terminal will not transmit any data. The moment when the PDCCH is sent determines the activation time.
- the above-mentioned at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes multiple different SRS resource subsets; wherein, the function configuration of the above-mentioned one SRS resource set is "codebook” ” or “non-codebook”.
- the at least one SRS resource set includes one SRS resource set, and the SRS resource set includes a plurality of different SRS resource subsets, and the function configuration mode of the SRS resource set is "codebook".
- the at least one SRS resource set includes one SRS resource set, and the SRS resource set includes a plurality of different SRS resource subsets, and the function configuration mode of the SRS resource set is "non-codebook".
- the SRS resource subsets may be partitioned by default. For example, the same number is allocated by default; or, SRS resource subsets can be divided in a predefined manner, for example, SRS resources are allocated according to the proportion of the maximum number of SRS ports supported by different panels (based on codebooks), or according to different SRS resources are allocated in the same proportion as the maximum number of flow (RANK) layers supported by the panel; alternatively, SRS resource subsets can be divided through base station configuration or instructions.
- SRS resource subsets can be divided through base station configuration or instructions.
- the number of SRS resources included in the above-mentioned multiple different SRS resource subsets is configured independently.
- each of the plurality of different SRS resource subsets may include one or more SRS resources, and the number of SRS resources in each SRS resource subset may be configured independently.
- the above-mentioned multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- each SRS resource subset in the above-mentioned multiple different SRS resource subsets is associated with different power control parameters and PL RS sets respectively.
- the above-mentioned at least one SRS resource set is associated with different control resource set pool indexes, including: multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- each of the plurality of different SRS resource subsets is associated with a control resource pool index, and each SRS resource subset is associated with a different control resource pool index.
- the above-mentioned DG-PUSCH is associated with different SRS resource subsets by scheduling the control resource set pool index value of the DCI.
- different DG-PUSCHs are associated with different control resource pool index values
- different SRS resource subsets are associated with different control resource pool indexes. Therefore, the SRS resource subset associated with the control resource pool index can be obtained through the control resource pool index to which the control resource pool index value associated with DG-PUSCH belongs, and different DG-PUSCHs and different SRSs can be realized. Resource subsets are associated.
- the above-mentioned CG-PUSCH is a type I CG-PUSCH; wherein, for the type I CG-PUSCH, the corresponding SRS is configured to configure authorization configuration parameters through radio resource control RRC signaling.
- the network side device configures the identification of the corresponding SRS resource subset and the SRI for configuring authorization configuration parameters through RRC signaling.
- the network side device configures the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the above-mentioned CG-PUSCH is a type II CG-PUSCH; wherein, for a type II CG-PUSCH, the control resource set pool index value of the activated DCI authorizes configurations for different configurations.
- the parameters are associated with the corresponding SRS resource subset.
- the network side device associates corresponding SRS resource subsets for different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI.
- the above-mentioned at least one SRS resource set includes one SRS resource set, and the above-mentioned one SRS resource set includes multiple different SRS resources; wherein, the function configuration of one SRS resource set is "codebook" or "non-codebook".
- the above-mentioned at least one SRS resource set includes an SRS resource set, and the SRS resource set includes a plurality of different SRS resources; the function configuration mode of the SRS resource set is a "codebook”.
- the above-mentioned at least one SRS resource set includes an SRS resource set, and the SRS resource set includes a plurality of different SRS resources; the function configuration mode of the SRS resource set is "non-codebook”.
- the above-mentioned at least one SRS resource set is associated with different control resource set pool indexes, including: multiple different SRS resources are associated with multiple different control resource set pool indexes.
- each SRS resource among the plurality of different SRS resources included in the at least one SRS resource set is associated with a control resource set pool index, and each SRS resource is associated with a different control resource set pool index.
- the above-mentioned DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- different DG-PUSCHs are associated with different control resource pool index values, and different SRS resources are associated with different control resource pool indexes. Therefore, the SRS resources associated with the control resource pool index can be obtained through the control resource pool index to which the control resource pool index value associated with DG-PUSCH belongs, so that different DG-PUSCHs are related to different SRS resources. Union.
- the above embodiment describes the implementation of the multi-panel enhanced transmission configuration method of the embodiment of the present disclosure from the network side device side.
- the embodiment of the present disclosure also proposes another multi-panel enhanced transmission configuration method.
- the implementation of the multi-panel enhanced transmission configuration method will be described below from the terminal device.
- the network side device can configure an SRS resource set and send the configuration information of the SRS resource set to the terminal device, so that the terminal device can implement independent precoding and power control based on the configuration information, thereby enhancing different The uplink transmission capability of PDCCH.
- control resource pool index in the embodiment of the present disclosure can be any identifier that can identify the control resource pool, and its expression form is not limited to the examples in the above embodiment.
- FIG. 3 is a schematic flowchart of another multi-panel enhanced transmission configuration method provided by an embodiment of the present disclosure. This method is performed by a terminal device with a multi-antenna panel. As shown in Figure 3, the method may include but is not limited to the following steps:
- Step S301 Receive configuration information sent by the network side device.
- the above configuration information is used to indicate at least one SRS resource set, and the control resource set pool index associated with at least one SRS resource set; if multiple SRS resource sets are included, different SRS resource sets Associated with different control resource set pool indexes; the above-mentioned at least one SRS resource set is a resource set configured by the network side device for multiple associated different panels for different transmitting and receiving points TRP using the physical uplink shared channel PUSCH transmission on different beams.
- the PUSCH Based on multiple downlink control information DCI scheduling, the terminal equipment uses different beams from different panels to simultaneously transmit respective PUSCHs to different TRPs.
- the terminal device receives configuration information sent by the network side device indicating at least one SRS resource set and different control resource set pool indexes associated with the SRS resource set.
- the above SRS resource set is a set of resources configured by the network side device for multiple panels with different associations and facing different transmitting and receiving points TRP using the physical uplink shared channel PUSCH on different beams.
- the above PUSCH is a terminal device based on multiple downlink control information DCI Scheduling uses different beams from different panels to simultaneously transmit respective PUSCHs to different TRPs.
- the above-mentioned PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the above-mentioned PUSCH transmission includes DG-PUSCH transmission.
- the above-mentioned PUSCH transmission includes CG-PUSCH transmission.
- the above-mentioned PUSCH transmission includes both DG-PUSCH transmission and CG-PUSCH transmission.
- the above-mentioned multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs, and the control resource set pool index value configured by the scheduling DCI is associated with the corresponding SRS resource set.
- the DG-PUSCH transmission used by each panel for TRP is associated with an index value in a control resource set pool for scheduling DCI
- the SRS resource set is associated with an index of the control resource set pool for scheduling DCI.
- different DG-PUSCH transmissions correspond to different control resource pool index values.
- different DG-PUSCH transmissions use different beams. Therefore, the SRS resource set associated with the control resource pool index value of the scheduled DCI associated with the DG-PUSCH transmission of a beam used by a panel for a TRP can be obtained , so that multiple panels with different associations use different beams for DG-PUSCH transmission for different TRPs, and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs.
- the above-mentioned at least one SRS resource set includes multiple different SRS resource sets, and each SRS resource set is associated with a panel for PUSCH transmission on a beam used by a TRP.
- the functional configurations of multiple different SRS resource sets are all “codebook” or “non-codebook”.
- the function configuration method of each SRS resource set among multiple different SRS resource sets is a "codebook”.
- the functional configuration mode of each of the multiple different SRS resource sets is "non-codebook”.
- the number of SRS resources included in the above-mentioned multiple different SRS resource sets is configured independently.
- each of the plurality of different SRS resource sets may include one or more SRS resources, and the number of SRS resources included in each SRS resource set may be configured independently. That is, each of the above multiple different SRS resource sets may include one or more SRS resources, and the number of SRS resources included in each SRS resource set may be the same or different.
- the above-mentioned multiple different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- each of the above-mentioned multiple different SRS resource sets is associated with a corresponding different power control parameter and path loss estimation reference signal PL RS set.
- the above at least one SRS resource set is associated with different control resource set pool indexes, including: the above multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- each SRS resource set among multiple different SRS resource sets is associated with an index in the control resource set pool, and different SRS resource sets are associated with different indexes.
- the above DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- different DG-PUSCHs are associated with different control resource pool index values
- different SRS resource sets are associated with different control resource pool indexes. Therefore, the SRS resource set associated with the control resource pool index can be obtained through the control resource pool index to which the control resource pool index value associated with DG-PUSCH belongs, and different DG-PUSCHs and different SRS resources can be realized. Collections are associated.
- the above-mentioned CG-PUSCH is a type I CG-PUSCH; wherein, for the type I CG-PUSCH, the authorization configuration parameters are configured through RRC signaling to configure the corresponding SRS resource set. Identity, and sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the terminal device configures the identification of the corresponding SRS resource set and the sounding reference signal resource indication SRI for the configuration authorization configuration parameter through radio resource control RRC signaling.
- the terminal device configures the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the above-mentioned CG-PUSCH is a type II CG-PUSCH; wherein, for a type II CG-PUSCH, the control resource set pool index value of the activated DCI authorizes configurations for different configurations.
- the parameters are associated with the corresponding SRS resource collection.
- the terminal device associates the corresponding SRS resource set for different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI.
- the above-mentioned at least one SRS resource set includes one SRS resource set, and the above-mentioned one SRS resource set includes a plurality of different SRS resource subsets; wherein, the function configuration of the above-mentioned one SRS resource set is "codebook” ” or “non-codebook”.
- the at least one SRS resource set includes one SRS resource set, and the SRS resource set includes a plurality of different SRS resource subsets, and the function configuration mode of the SRS resource set is "codebook".
- the at least one SRS resource set includes one SRS resource set, and the SRS resource set includes a plurality of different SRS resource subsets, and the function configuration mode of the SRS resource set is "non-codebook".
- the number of SRS resources included in the above-mentioned multiple different SRS resource subsets is configured independently.
- each of the multiple different SRS resource subsets may include one or more SRS resources, and the number of SRS resources in each SRS resource subset may be the same or different. of.
- multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- each SRS resource subset in the above-mentioned multiple different SRS resource subsets is associated with different power control parameters and PL RS sets respectively.
- the above-mentioned at least one SRS resource set is associated with different control resource set pool indexes, including: multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- each of the plurality of different SRS resource subsets is associated with a control resource pool index, and each SRS resource subset is associated with a different control resource pool index.
- the above-mentioned DG-PUSCH is associated with different SRS resource subsets by scheduling the control resource set pool index value of the DCI.
- different DG-PUSCHs are associated with different control resource pool index values
- different SRS resource subsets are associated with different control resource pool indexes. Therefore, the SRS resource subset associated with the control resource pool index can be obtained through the control resource pool index to which the control resource pool index value associated with DG-PUSCH belongs, and different DG-PUSCHs and different SRSs can be realized. Resource subsets are associated.
- the above-mentioned CG-PUSCH is a type I CG-PUSCH; wherein, for the type I CG-PUSCH, the corresponding SRS is configured to configure authorization configuration parameters through radio resource control RRC signaling.
- the terminal device configures the identity of the corresponding SRS resource subset and the SRI for configuring authorization configuration parameters through radio resource control RRC signaling.
- the terminal device configures the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the above-mentioned CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the value of the control resource set pool index by activating DCI is a different configuration.
- Authorization configuration parameters are associated with the corresponding SRS resource subset.
- the terminal device associates corresponding SRS resource subsets for different configuration authorization configuration parameters through the value of the control resource set pool index of the activated DCI.
- the above-mentioned at least one SRS resource set includes one SRS resource set, and one SRS resource set includes multiple different SRS resources; wherein, the function configuration of one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the above-mentioned at least one SRS resource set includes an SRS resource set, and the SRS resource set includes a plurality of different SRS resources; the function configuration mode of the SRS resource set is a "codebook".
- the above-mentioned at least one SRS resource set includes an SRS resource set, and the SRS resource set includes a plurality of different SRS resources; the function configuration mode of the SRS resource set is "non-codebook".
- the above-mentioned at least one SRS resource set is associated with different control resource set pool indexes, including: multiple different SRS resources are associated with multiple different control resource set pool indexes.
- each SRS resource in the SRS resource set is associated with a control resource set pool index, and different SRS resources are associated with different control resource set pool indexes.
- the above-mentioned DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- different DG-PUSCHs are associated with different control resource pool index values, and different SRS resources are associated with different control resource pool indexes. Therefore, the SRS resources associated with the control resource pool index can be obtained through the control resource pool index to which the control resource pool index value associated with DG-PUSCH belongs, so that different DG-PUSCHs are related to different SRS resources. Union.
- the above-mentioned CG-PUSCH is a type I CG-PUSCH; wherein, for the type I CG-PUSCH, the identification of the corresponding SRS resource is configured for configuring authorization configuration parameters through RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the terminal device configures the identification of the corresponding SRS resource and the SRI for configuring authorization configuration parameters through RRC signaling.
- the terminal device configures the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the above-mentioned CG-PUSCH is a type II CG-PUSCH; wherein, for a type II CG-PUSCH, the control resource set pool index value of the activated DCI authorizes configurations for different configurations. Parameters are associated with corresponding SRS resources.
- the terminal device associates corresponding SRS resources for different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI.
- the terminal device can receive the configuration information of the SRS resource set sent by the network side device, and implement independent precoding and power control based on the configuration information, thereby enhancing the uplink transmission capabilities of different PDCCHs.
- the methods provided by the embodiments of the present disclosure are introduced from the perspectives of network side equipment and terminal equipment respectively.
- the network side device and the terminal device may include a hardware structure and a software module to implement the above functions in the form of a hardware structure, a software module, or a hardware structure plus a software module.
- a certain function among the above functions can be executed by a hardware structure, a software module, or a hardware structure plus a software module.
- FIG. 4 is a schematic structural diagram of a communication device 40 provided by an embodiment of the present disclosure. The communication device 40 shown in FIG.
- the transceiving module 401 may include a sending module and/or a transceiving module.
- the sending module is used to implement the sending function
- the transceiving module is used to implement the receiving function.
- the transceiving module 401 may implement the sending function and/or the receiving function.
- the communication device 40 may be a network side device, or may be a device in the network side device, or may be a device that can be used in conjunction with the network side device, or the communication device 40 may be a terminal device, or may be a device in the terminal device. , it can also be a device that can be used in conjunction with the terminal device.
- the communication device 40 is a network-side device: the processing module 402 is used to configure at least one sounding reference signal SRS resource set for multiple antenna panel panels with different associations and to use the physical uplink shared channel PUSCH transmission on different beams for different transmitting and receiving points TRP.
- the PUSCH is for a terminal device with multiple panels to simultaneously send respective PUSCHs from different panels using different beams to different TRPs based on multiple downlink control information DCI scheduling; the transceiver module 401 is used to send all PUSCHs to the terminal device.
- Configuration information corresponding to the at least one sounding reference signal SRS resource set wherein the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource set is associated with different control resource set pool indexes.
- the PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource subset.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource and the SRI are configured to configure authorization configuration parameters through Radio Resource Control RRC signaling, Alternatively, configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a Type II CG-PUSCH; wherein, for a Type II CG-PUSCH, different configuration authorization configuration parameters are associated with corresponding SRS resources through the control resource set pool index value of the activated DCI.
- the network side device can configure the SRS resource set and send the configuration information of the SRS resource set to the terminal device, so that the terminal device can implement independent precoding and power control based on the configuration information, thereby enhancing Uplink transmission capabilities of different PDCCHs.
- the communication device 40 is a terminal device: the transceiver module 401 is used to receive configuration information sent by the network side device; the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource set is associated with different control resource sets. Pool index; wherein, the at least one SRS resource set is a resource set configured by the network side device for multiple panels with different associations and facing different transmitting and receiving points TRP using the physical uplink shared channel PUSCH on different beams, and the PUSCH For the terminal equipment, the terminal equipment is scheduled to simultaneously transmit respective PUSCHs from different panels using different beams for different TRPs based on multiple downlink control information DCI schedules.
- the PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the value of the control resource set pool index of the activated DCI is associated with different configuration authorization configuration parameters.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- the terminal equipment can receive the configuration information of the SRS resource set sent by the network side equipment, and implement independent precoding and power control based on the configuration information, thereby enhancing the uplink transmission capabilities of different PDCCHs.
- FIG. 5 is a schematic structural diagram of another communication device 50 provided by an embodiment of the present disclosure.
- the communication device 50 may be a network-side device, a terminal device, a chip, a chip system, a processor, etc. that supports the network-side device to implement the above method, or a chip or a chip system that supports the terminal device to implement the above method. , or processor, etc.
- the device can be used to implement the method described in the above method embodiment. For details, please refer to the description in the above method embodiment.
- Communication device 50 may include one or more processors 501 .
- the processor 501 may be a general-purpose processor or a special-purpose processor, or the like. For example, it can be a baseband processor or a central processing unit.
- the baseband processor can be used to process communication protocols and communication data.
- the central processor can be used to control communication devices (such as base stations, baseband chips, terminal equipment, terminal equipment chips, DU or CU, etc.) and execute computer programs. , processing data for computer programs.
- the communication device 50 may also include one or more memories 502, on which a computer program 503 may be stored.
- the processor 501 executes the computer program 503, so that the communication device 50 performs the steps described in the above method embodiments. method.
- the memory 502 may also store data.
- the communication device 50 and the memory 502 can be provided separately or integrated together.
- the communication device 50 may also include a transceiver 504 and an antenna 505.
- the transceiver 504 may be called a transceiver unit, a transceiver, a transceiver circuit, etc., and is used to implement transceiver functions.
- the transceiver 504 may include a receiver and a transmitter.
- the receiver may be called a receiver or a receiving circuit, etc., used to implement the receiving function;
- the transmitter may be called a transmitter, a transmitting circuit, etc., used to implement the transmitting function.
- the communication device 50 may also include one or more interface circuits 5010.
- the interface circuit 5010 is used to receive code instructions and transmit them to the processor 501 .
- the processor 501 executes the code instructions to cause the communication device 50 to perform the method described in the above method embodiment.
- the communication device 50 is a network-side device: the transceiver 504 is used to perform step S202 in FIG. 2 .
- the processor 501 is used to execute step S201 in FIG. 2 .
- the communication device 50 is a terminal device: the transceiver 504 is used to perform step S301 in FIG. 3 .
- the processor 501 may include a transceiver for implementing receiving and transmitting functions.
- the transceiver may be a transceiver circuit, an interface, or an interface circuit.
- the transceiver circuits, interfaces or interface circuits used to implement the receiving and transmitting functions can be separate or integrated together.
- the above-mentioned transceiver circuit, interface or interface circuit can be used for reading and writing codes/data, or the above-mentioned transceiver circuit, interface or interface circuit can be used for signal transmission or transfer.
- the processor 501 may store a computer program, and the computer program runs on the processor 501 to cause the communication device 50 to perform the method described in the above method embodiment.
- the above computer program may be solidified in the processor 501, in which case the processor 501 may be implemented by hardware.
- the communication device 50 may include a circuit, and the circuit may implement the functions of sending or receiving or communicating in the foregoing method embodiments.
- the processors and transceivers described in this disclosure may be implemented on integrated circuits (ICs), analog ICs, radio frequency integrated circuits (RFICs), mixed signal ICs, application specific integrated circuits (ASICs), printed circuit boards ( printed circuit board (PCB), electronic equipment, etc.
- the processor and transceiver can also be manufactured using various IC process technologies, such as complementary metal oxide semiconductor (CMOS), n-type metal oxide-semiconductor (NMOS), P-type Metal oxide semiconductor (positive channel metal oxide semiconductor, PMOS), bipolar junction transistor (BJT), bipolar CMOS (BiCMOS), silicon germanium (SiGe), gallium arsenide (GaAs), etc.
- CMOS complementary metal oxide semiconductor
- NMOS n-type metal oxide-semiconductor
- PMOS P-type Metal oxide semiconductor
- BJT bipolar junction transistor
- BiCMOS bipolar CMOS
- SiGe silicon germanium
- GaAs gallium arsenide
- the communication device described in the above embodiments may be a network side device or a terminal device, but the scope of the communication device described in this disclosure is not limited thereto, and the structure of the communication device may not be limited by FIG. 5 .
- the communication device may be a stand-alone device or may be part of a larger device.
- the communication device may be:
- the IC collection may also include storage components for storing data and computer programs;
- the communication device may be a chip or a chip system
- the communication device may be a chip or a chip system
- the chip shown in Figure 6 includes a processor 601 and an interface 602.
- the number of processors 601 may be one or more, and the number of interfaces 602 may be multiple.
- the processor 601 is configured to transmit at least one sounding reference signal SRS resource set using the physical uplink shared channel PUSCH on different beams for different transmitting and receiving points TRP for multiple antenna panel panels with different associations; wherein the PUSCH is provided with The terminal equipment of multiple panels sends their respective PUSCHs from different panels using different beams to different TRPs at the same time based on multiple downlink control information DCI scheduling; the interface 602 is used to send the at least one sounding reference signal SRS resource set to the terminal equipment.
- Corresponding configuration information wherein the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource set is associated with different control resource set pool indexes.
- the PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource subset.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure the authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- Interface 602 configured to receive configuration information sent by a network side device; the configuration information is used to indicate the at least one SRS resource set, and the at least one SRS resource set is associated with different control resource set pool indexes; wherein the at least one SRS resource set is associated with different control resource set pool indexes;
- An SRS resource set is a resource set configured by the network side device for multiple panels associated with different panels and facing different transmitting and receiving points TRP using the physical uplink shared channel PUSCH on different beams.
- the PUSCH is a resource set configured by the terminal device based on multiple Downlink control information DCI scheduling uses different beams from different panels to send respective PUSCHs to different TRPs at the same time.
- the PUSCH transmission includes at least one of DG-PUSCH transmission and CG-PUSCH transmission.
- the multiple panels with different associations use DG-PUSCH transmission on different beams for different TRPs and are associated with the corresponding SRS resource set by scheduling the DCI control resource set pool index value.
- the at least one SRS resource set includes multiple different SRS resource sets, and the multiple different SRS resource sets are respectively associated with different panels and use PUSCH transmission on different beams for different TRPs; the multiple different SRS resource sets are respectively associated with different panels.
- the functional configuration of the SRS resource set is "codebook” or “non-codebook”.
- the number of SRS resources included in the multiple different SRS resource sets is configured independently.
- the plurality of different SRS resource sets are respectively associated with different power control parameters and path loss estimation reference signal PL RS sets.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource sets are respectively associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource sets by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource set is configured to configure authorization configuration parameters through radio resource control RRC signaling. and the sounding reference signal resource indication SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. Resource collection.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resource subsets; wherein the function configuration of the one SRS resource set is "codebook” or “Non-codebook”.
- the number of SRS resources included in the multiple different SRS resource subsets is configured independently.
- the multiple different SRS resource subsets are associated with different power control parameters and PL RS sets respectively.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resource subsets are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resource subsets by scheduling a control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource subset is configured to configure authorization configuration parameters through radio resource control RRC signaling. , and SRI, or configure the corresponding control resource pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the value of the control resource set pool index of the activated DCI is associated with different configuration authorization configuration parameters.
- the at least one SRS resource set includes one SRS resource set, and the one SRS resource set includes a plurality of different SRS resources; wherein the function configuration of the one SRS resource set is "codebook” or “non-codebook”. Codebook”.
- the at least one SRS resource set is associated with different control resource set pool indexes, including: the multiple different SRS resources are associated with multiple different control resource set pool indexes.
- the DG-PUSCH is associated with different SRS resources by scheduling the control resource set pool index value of the DCI.
- the CG-PUSCH is a Type I CG-PUSCH; wherein, for the Type I CG-PUSCH, the identification of the corresponding SRS resource is configured to configure the authorization configuration parameters through Radio Resource Control RRC signaling, and SRI, or configure the corresponding control resource set pool index and SRI for configuring authorization configuration parameters through RRC signaling.
- the CG-PUSCH is a type II CG-PUSCH; wherein, for the type II CG-PUSCH, the corresponding SRS is associated with different configuration authorization configuration parameters by activating the control resource set pool index value of the DCI. resource.
- the chip also includes a memory 603, which is used to store necessary computer programs and data.
- Embodiments of the present disclosure also provide a multi-panel enhanced transmission configuration system.
- the system includes a communication device as a terminal device and a communication device as a network side device in the aforementioned embodiment of FIG. 4.
- the system includes a communication device as in the aforementioned embodiment of FIG. 5.
- the present disclosure also provides a readable storage medium on which instructions are stored, and when the instructions are executed by a computer, the functions of any of the above method embodiments are implemented.
- the present disclosure also provides a computer program product, which, when executed by a computer, implements the functions of any of the above method embodiments.
- the computer program product includes one or more computer programs.
- the computer may be a general purpose computer, a special purpose computer, a computer network, or other programmable device.
- the computer program may be stored in or transferred from one computer-readable storage medium to another, for example, the computer program may be transferred from a website, computer, server, or data center Transmission to another website, computer, server or data center through wired (such as coaxial cable, optical fiber, digital subscriber line (DSL)) or wireless (such as infrared, wireless, microwave, etc.) means.
- the computer-readable storage medium may be any available medium that can be accessed by a computer or a data storage device such as a server, data center, etc. that contains one or more available media integrated.
- the available media may be magnetic media (e.g., floppy disks, hard disks, magnetic tapes), optical media (e.g., high-density digital video discs (DVD)), or semiconductor media (e.g., solid state disks, SSD)) etc.
- magnetic media e.g., floppy disks, hard disks, magnetic tapes
- optical media e.g., high-density digital video discs (DVD)
- DVD digital video discs
- semiconductor media e.g., solid state disks, SSD
- At least one in the disclosure can also be described as one or more, and the plurality can be two, three, four or more, and the disclosure is not limited.
- the technical feature is distinguished by “first”, “second”, “third”, “A”, “B”, “C” and “D”, etc.
- the technical features described in “first”, “second”, “third”, “A”, “B”, “C” and “D” are in no particular order or order.
- Predefinition in this disclosure may be understood as definition, pre-definition, storage, pre-storage, pre-negotiation, pre-configuration, solidification, or pre-burning.
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Abstract
本公开实施例公开了一种多面板增强传输配置方法及其装置,其中,上述方法由网络侧设备执行,上述方法包括:为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参考信号SRS资源集合;其中,PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH;向终端设备发送至少一个探测参考信号SRS资源集合对应的配置信息;其中,配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。通过本公开的技术方案,可以使终端设备基于配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
Description
本公开涉及通信技术领域,尤其涉及一种多面板增强传输配置方法及其装置。
相关技术中,由于网络侧设备只能为终端设备配置一个探测参考信号SRS资源集,而终端设备的预编码是通过SRS资源指示(即SRI)和预编码矩阵指示TPMI来指示的,终端设备的功率控制也通过SRI与功率控制参数集相关联的,在上述单个SRS资源集的配置下,终端设备的预编码和功率控制都无法很好的支持上行多收发点传输。
发明内容
本公开实施例提供一种多面板增强传输配置方法及其装置,可以应用于车联网,例如车与任何事物(vehicle to everything,V2X)通信、车间通信长期演进技术(long term evolution-vehicle,LTE-V)、车辆与车辆(vehicle to vehicle,V2V)通信等,或可以用于智能驾驶,智能网联车等领域。通过网络侧设备配置SRS资源集合,并将该SRS资源集合的配置信息发送至终端设备,使终端设备能够基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
第一方面,本公开实施例提供一种多面板增强传输配置方法,所述方法由网络侧设备执行,所述方法包括:为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参考信号SRS资源集合;其中,所述PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH;向所述终端设备发送所述至少一个探测参考信号SRS资源集合对应的配置信息;其中,所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。
在一种实现方式中,所述PUSCH传输包括DG-PUSCHDG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI, 或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
在该技术方案中,网络侧设备可以配置SRS资源集合,并将该SRS资源集合的配置信息发送至终端设备,使终端设备能够基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
第二方面,本公开实施例提供一种多面板增强传输配置方法,所述方法由具备多天线面板panel的终端设备执行,所述方法包括:接收网络侧设备发送的配置信息;所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引;其中,所述至少一个SRS资源集合为所述网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,所述PUSCH为所述终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
在一种实现方式中,所述PUSCH传输包括DG-PUSCHDG-PUSCH传输和CG-PUSCHCG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合 分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
在该技术方案中,终端设备可以接收网络侧设备发送的SRS资源集合的配置信息,并基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
第三方面,本公开实施例提供一种通信装置,包括:处理模块,用于为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参 考信号SRS资源集合;其中,所述PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH;收发模块,用于向所述终端设备发送所述至少一个探测参考信号SRS资源集合对应的配置信息;其中,所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。
在一种实现方式中,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资 源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
第四方面,本公开实施例提供另一种通信装置,包括:收发模块,用于接收网络侧设备发送的配置信息;所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引;其中,所述至少一个SRS资源集合为所述网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,所述PUSCH为所述终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
在一种实现方式中,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
第五方面,本公开实施例提供一种通信装置,该通信装置包括处理器,当该处理器调用存储器中的计算机程序时,执行上述第一方面所述的方法。
第六方面,本公开实施例提供一种通信装置,该通信装置包括处理器,当该处理器调用存储器中的计算机程序时,执行上述第二方面所述的方法。
第七方面,本公开实施例提供一种通信装置,该通信装置包括处理器和存储器,该存储器中存储有计算机程序;所述处理器执行该存储器所存储的计算机程序,以使该通信装置执行上述第一方面所述的方法。
第八方面,本公开实施例提供一种通信装置,该通信装置包括处理器和存储器,该存储器中存储有计算机程序;所述处理器执行该存储器所存储的计算机程序,以使该通信装置执行上述第二方面所述的方法。
第九方面,本公开实施例提供一种通信装置,该装置包括处理器和接口电路,该接口电路用于接收代码指令并传输至该处理器,该处理器用于运行所述代码指令以使该装置执行上述第一方面所述的方法。
第十方面,本公开实施例提供一种通信装置,该装置包括处理器和接口电路,该接口电路用于接收代码指令并传输至该处理器,该处理器用于运行所述代码指令以使该装置执行上述第二方面所述的方法。
第十一方面,本公开实施例提供一种多面板增强传输配置系统,该系统包括第三方面所述的通信装置以及第四方面所述的通信装置,或者,该系统包括第五方面所述的通信装置以及第六方面所述的通信装置,或者,该系统包括第七方面所述的通信装置以及第八方面所述的通信装置,或者,该系统包括第九方面所述的通信装置以及第十方面所述的通信装置。
第十二方面,本发明实施例提供一种计算机可读存储介质,用于储存为上述终端设备所用的指令,当所述指令被执行时,使所述终端设备执行上述第一方面所述的方法。
第十三方面,本发明实施例提供一种可读存储介质,用于储存为上述网络侧设备所用的指令,当所述指令被执行时,使所述网络侧设备执行上述第二方面所述的方法。
第十四方面,本公开还提供一种包括计算机程序的计算机程序产品,当其在计算机上运行时,使得计算机执行上述第一方面所述的方法。
第十五方面,本公开还提供一种包括计算机程序的计算机程序产品,当其在计算机上运行时,使得计算机执行上述第二方面所述的方法。
第十六方面,本公开提供一种芯片系统,该芯片系统包括至少一个处理器和接口,用于支持终端 设备实现第一方面所涉及的功能,例如,确定或处理上述方法中所涉及的数据和信息中的至少一种。在一种可能的设计中,所述芯片系统还包括存储器,所述存储器,用于保存终端设备必要的计算机程序和数据。该芯片系统,可以由芯片构成,也可以包括芯片和其他分立器件。
第十七方面,本公开提供一种芯片系统,该芯片系统包括至少一个处理器和接口,用于支持网络侧设备实现第二方面所涉及的功能,例如,确定或处理上述方法中所涉及的数据和信息中的至少一种。在一种可能的设计中,所述芯片系统还包括存储器,所述存储器,用于保存网络侧设备必要的计算机程序和数据。该芯片系统,可以由芯片构成,也可以包括芯片和其他分立器件。
第十八方面,本公开提供一种计算机程序,当其在计算机上运行时,使得计算机执行上述第一方面所述的方法。
第十九方面,本公开提供一种计算机程序,当其在计算机上运行时,使得计算机执行上述第二方面所述的方法。
为了更清楚地说明本公开实施例或背景技术中的技术方案,下面将对本公开实施例或背景技术中所需要使用的附图进行说明。
图1是本公开实施例提供的一种通信系统的架构示意图;
图2是本公开实施例提供的一种多面板增强传输配置方法的流程示意图;
图3是本公开实施例提供的另一种多面板增强传输配置方法的流程示意图;
图4是本公开实施例提供的一种通信装置的结构示意图;
图5是本公开实施例提供的另一种通信装置的结构示意图;
图6是本公开实施例提供的一种芯片的结构示意图。
下面详细描述本公开的实施例,所述实施例的示例在附图中示出,其中自始至终相同或类似的标号表示相同或类似的元件或具有相同或类似功能的元件。下面通过参考附图描述的实施例是示例性的,旨在用于解释本公开,而不能理解为对本公开的限制。其中,在本公开的描述中,除非另有说明,“/”表示或的意思,例如,A/B可以表示A或B;本文中的“和/或”仅仅是一种描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示:单独存在A,同时存在A和B,单独存在B这三种情况。
需要说明的是,本公开中,任一个实施例提供的方法可以单独执行,或是结合其他实施例中的可能的实现方法一起被执行,还可以结合相关技术中的任一种技术方案一起被执行。
为了更好的理解本公开实施例公开的一种多面板增强传输配置方法,下面首先对本公开实施例适用的通信系统进行描述。
请参见图1,图1为本公开实施例提供的一种通信系统的架构示意图。该通信系统可包括但不限于一个网络侧设备和一个终端设备,图1所示的设备数量和形态仅用于举例并不构成对本公开实施例的限定,实际应用中可以包括两个或两个以上的网络侧设备,两个或两个以上的终端设备。图1所示的通信系统以包括一个网络侧设备101和一个终端设备102为例。
需要说明的是,本公开实施例的技术方案可以应用于各种通信系统。例如:长期演进(long term evolution,LTE)系统、第五代(5th generation,5G)移动通信系统、NR系统,或者其他未来的新型 移动通信系统等。
本公开实施例中的网络侧设备101是网络侧的一种用于发射或接收信号的实体。例如,网络侧设备101可以为演进型基站、传输点(transmission reception point,TRP)、NR系统中的下一代基站(next generation NodeB,gNB)、其他未来移动通信系统中的基站或无线保真(wireless fidelity,WiFi)系统中的接入节点等。本公开的实施例对网络侧设备所采用的具体技术和具体设备形态不做限定。本公开实施例提供的网络侧设备可以是由集中单元(central unit,CU)与分布式单元(distributed unit,DU)组成的,其中,CU也可以称为控制单元(control unit),采用CU-DU的结构可以将网络侧设备,例如基站的协议层拆分开,部分协议层的功能放在CU集中控制,剩下部分或全部协议层的功能分布在DU中,由CU集中控制DU。
本公开实施例中的终端设备102是用户侧的一种用于接收或发射信号的实体,如手机。终端设备也可以称为终端设备(terminal)、用户设备(user equipment,UE)、移动台(mobile station,MS)、移动终端设备(mobile terminal,MT)等。终端设备可以是具备通信功能的汽车、智能汽车、手机(mobile phone)、穿戴式设备、平板电脑(Pad)、带无线收发功能的电脑、虚拟现实(virtual reality,VR)终端设备、增强现实(augmented reality,AR)终端设备、工业控制(industrial control)中的无线终端设备、无人驾驶(self-driving)中的无线终端设备、远程手术(remote medical surgery)中的无线终端设备、智能电网(smart grid)中的无线终端设备、运输安全(transportation safety)中的无线终端设备、智慧城市(smart city)中的无线终端设备、智慧家庭(smart home)中的无线终端设备等等。本公开的实施例对终端设备所采用的具体技术和具体设备形态不做限定。
可以理解的是,本公开实施例描述的通信系统是为了更加清楚的说明本公开实施例的技术方案,
并不构成对于本公开实施例提供的技术方案的限定,本领域普通技术人员可知,随着系统架构的演变和新业务场景的出现,本公开实施例提供的技术方案对于类似的技术问题,同样适用。
下面结合附图对本公开所提供的多面板增强传输配置方法及其装置进行详细地介绍。
需要说明的是,本公开所提供的多面板增强传输配置方法,可以适用于SDM(space division multiplexing,空分复用)、FDM(frequency division multiplexing,频分复用)以及TDM(time division multiplexing,时分复用)等通信方式。
请参见图2,图2是本公开实施例提供的一种多面板增强传输配置方法的流程示意图。该方法由网络侧设备执行。如图2所示,该方法可以包括但不限于如下步骤:
步骤S201:为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH(physical uplink shared channel,物理下行共享信道)传输,配置至少一个SRS(sounding reference signal,探测参考信号)资源集合。
其中,多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,是指:多个不同的天线面板panel,面向不同发送接收点TRP,分别执行PUSCH传输;而这些不同的PUSCH传输使用不同的波束。
举例而言,网络侧设备为多个PUSCH传输配置至少一个SRS资源集合,其中,每个PUSCH传输为一个panle面向一个TRP使用的一种波束上的PUSCH传输,并且每个PUSCH传输对应的panle面、TRP和波束不完全相同。
其中,上述PUSCH为具备多panel的终端设备基于多个DCI(downlink control information,下行控制信息)调度的,分别从不同panel使用不同波束面向不同TRP(transmitting and receiving point,发送和接收点)同时发送各自的PUSCH。
在本公开实施例的一种实现方式中,上述PUSCH传输包括DG-PUSCH(Dynamic Grant Physical Uplink Shared channel,动态授权物理上行共享信道)传输和CG-PUSCH(Configured Grant Physical Uplink Shared Channel,配置授权物理上行共享信道)传输中的至少一种。
作为一种示例,上述PUSCH传输包括DG-PUSCH传输。
作为另一种示例,上述PUSCH传输包括CG-PUSCH传输。
作为又一种示例,上述PUSCH传输同时包括DG-PUSCH传输和CG-PUSCH传输。
可选地,在本公开的实施例中,上述多个关联不同的panel面向不同TRP使用不同波束的多个DG-PUSCH传输,通过调度DCI配置的控制资源集池索引值,与对应的SRS资源集合相关联。
举例而言,每个panel面向TRP的DG-PUSCH传输,与一个调度DCI的控制资源集池中的一个索引值相关联,SRS资源集合与调度DCI的控制资源集池索引相关联。其中,不同的DG-PUSCH传输,对应于不同的控制资源集池索引值。其中,不同的DG-PUSCH传输,使用不同的波束。从而可以通过与一个panel面向一个TRP使用的一种波束的DG-PUSCH传输相关联的调度DCI的控制资源集池索引值,得到与该控制资源集池索引值相关联的SRS资源集合,从而使得多个关联不同的panel面向不同TRP使用不同波束的DG-PUSCH传输,通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
即,本公开实施例中,是为每一个PUSCH配置至少一个SRS资源集合。而该PUSCH,是指通过与一个panel面向一个TRP使用的一种波束的DG-PUSCH;其中不同的DG-PUSCH,是不同的panel面向不同的TRP进行的DG-PUSCH,而不同的DG-PUSCH使用不同的波束。
步骤S202:向终端设备发送至少一个SRS资源集合对应的配置信息。
其中,上述配置信息用于指示至少一个SRS资源集合,以及至少一个SRS资源集合关联的控制资源集池索引;若包括多个SRS资源集合,则不同的SRS资源集合关联不同的控制资源集池索引。
举例而言,向终端设备发送用于指示至少一个SRS资源集合,以及至少一个SRS资源集合关联的控制资源集池索引的配置信息。
在本公开的一些实施例中,向终端设备发送多个不同的SRS资源集合,多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;多个不同的SRS资源集合对应于不同的控制资源集池索引。
举例而言,上述至少一个SRS资源集合包括多个不同的SRS资源集合,每个SRS资源集合分别关联一个panel面向一个TRP使用的一种波束上的PUSCH传输;且不同的PUSCH传输对应不同的控制资源集池索引。
可选地,在本公开的实施例中,多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
作为一种示例,多个不同的SRS资源集合中的每个SRS资源集合的功能配置的方式均为“码本”。
作为另一种示例,多个不同的SRS资源集合中的每个SRS资源集合的功能配置的方式均为“非码本”。
需要说明的是,在本公开的实施例中,“码本”指为可用功能配置赋予对应的预编码,将多个预编码组成,使用不同的序号为不同的预编码编号,从而可以直接根据序号从上述的表中搜索对应的预编码,即为码本。
可选地,在本公开的实施例中,上述多个不同的SRS资源集合包括的SRS资源个数是独立配置的。即:上述多个不同的SRS资源集合中每个SRS资源集合中可以包括一个或多个SRS资源,并且每个SRS资源集合包括的SRS资源个数可以是相同的,也可以是不同的。
可选地,在本公开的实施例中,上述多个不同的SRS资源集合分别关联不同的功率控制参数和PLRS(Path loss estimationReference Signal,路径损耗估计参考信号)集合。
举例而言,上述多个不同的SRS资源集合中的每个SRS资源集合,可以关联对应不同的功率控制参数和路径损耗估计参考信号PLRS集合。
可选地,在本公开的实施例中,上述至少一个SRS资源集合关联不同控制资源集池索引,包括:多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
举例而言,多个不同SRS资源集合中的每个SRS资源集合,分别关联一个控制资源集池索引,并且不同的SRS资源集合关联不同的控制资源集池索引。
可选地,在本公开的实施例中,上述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
举例而言,不同的DG-PUSCH分别与不同的控制资源集池索引值相关联,不同的SRS资源集合分别与不同的控制资源集池索引相关联。从而可以通过与DG-PUSCH相关联的控制资源集池索引值所属的控制资源集池索引,得到与该控制资源集池索引相关联的SRS资源集合,实现不同的DG-PUSCH与不同的SRS资源集合相关联。
可选地,在本公开的实施例中,上述CG-PUSCH可以为类型I的CG-PUSCH;其中,对于上述类型I的CG-PUSCH,通过RRC(Radio Resource Control,无线资源控制)信令为配置授权配置参数配置相应的SRS资源集合的标识、以及SRI(Sounding reference signal Resource Identifier,探测参考信号资源指示),或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及对应的SRI。
需要说明的是,在本公开的实施例中,类型I的CG-PUSCH指由RRC(radio resource control,无线资源控制)提供上行授权。通过RRC信令配置所有的传输参数,包括周期、时间偏移和频率资源,以及上行传输所用的调制编码方式。当终端设备接收到RRC配置后,在由预先设定的周期和偏移计算得到的时刻,采用接收到的配置的授权进行传输。
上行传输授权由资源管理层提供,终端设备存储该配置并将其作为授权配置。
作为一种示例,当上述CG-PUSCH为类型I的CG-PUSCH时,网络侧设备通过RRC信令为配置授权配置参数配置相应的SRS资源集合的标识以及SRI。
作为另一种示例,当上述CG-PUSCH为类型I的CG-PUSCH时,网络侧设备通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,在本公开的实施例中,上述CG-PUSCH可以为类型II的CG-PUSCH;其中,对于类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合,具体的SRI也通过激活DCI指示。
举例而言,当上述CG-PUSCH为类型II的CG-PUSCH时,网络侧设备通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
需要说明的是,在本公开的实施例中,类型II的CG-PUSCH指由RRC提供传输周期,网络侧设备通过DCI实现资源激活和部分传输参数的配置,从而实现该授权配置的激活传输;终端设备接收到激活命令后,如果缓存中有数据发送,会根据预先配置的周期进行传输,如果没有数据,终端不会传输任何数据。PDCCH发送时刻即明确了激活时间。
在本公开的一些实施例中,上述至少一个SRS资源集合包括一个SRS资源集合,该一个SRS资源集合包括多个不同的SRS资源子集;其中,上述一个SRS资源集合的功能配置为“码本”或“非码本”。
作为一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,且该SRS资源集合包括多个不同的SRS资源子集,该SRS资源集合的功能配置方式为“码本”。
作为另一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,且该SRS资源集合包括多个不同的SRS资源子集,该SRS资源集合的功能配置方式为“非码本”。
需要说明的是,在本公开的实施例中,可以通过默认方式进行SRS资源子集的换划分。例如,默认相同个数的分配;或者,可以通过预定义方式进行SRS资源子集的划分,例如,按照不同panel支持的最大SRS端口数比例(基于码本)进行SRS资源的分配,或按照不同panel支持的最大流(RANK)层数相同比例进行SRS资源的分配;或者,可以通过基站配置或指示进行SRS资源子集的划分。
可选地,在本公开的实施例中,上述多个不同的SRS资源子集包括的SRS资源个数独立配置。
举例而言,上述多个不同的SRS资源子集中的每个SRS资源子集可以包括一个或多个SRS资源,并且每个SRS资源子集中的SRS资源个数可以独立配置。
可选地,在本公开的实施例中,上述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
举例而言,上述多个不同的SRS资源子集中的每个SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,在本公开的实施例中,上述至少一个SRS资源集合关联不同控制资源集池索引,包括:多个不同的SRS资源子集关联多个不同的控制资源集池索引。
举例而言,上述多个不同的SRS资源子集中的每个SRS资源子集分别关联一个控制资源集池索引,并且每个SRS资源子集关联不同的控制资源集池索引。
可选地,在本公开的实施例中,上述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
举例而言,不同的DG-PUSCH分别与不同的控制资源集池索引值相关联,不同的SRS资源子集分别与不同的控制资源集池索引相关联。从而可以通过与DG-PUSCH相关联的控制资源集池索引值所属的控制资源集池索引,得到与该控制资源集池索引相关联的SRS资源子集,实现不同的DG-PUSCH与不同的SRS资源子集相关联。
可选地,在本公开的实施例中,上述CG-PUSCH为类型I的CG-PUSCH;其中,对于类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
作为一种示例,当上述CG-PUSCH为类型I的CG-PUSCH时,网络侧设备通过RRC信令为配置授权配置参数配置相应的SRS资源子集的标识,以及SRI。
作为另一种示例,当上述CG-PUSCH为类型I的CG-PUSCH时,网络侧设备通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,在本公开的实施例中,上述CG-PUSCH为类型II的CG-PUSCH;其中,对于类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。举例而言,当上述CG-PUSCH为类型II的CG-PUSCH时,网络侧设备通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。
在本公开实施例的一些实现方式中,上述至少一个SRS资源集合包括一个SRS资源集合,上述一个SRS资源集合包括多个不同的SRS资源;其中,一个SRS资源集合的功能配置为“码本”或“非 码本”。作为一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,该SRS资源集合包括多个不同的SRS资源;该SRS资源集合的功能配置方式为“码本”。作为另一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,该SRS资源集合包括多个不同的SRS资源;该SRS资源集合的功能配置方式为“非码本”。
可选地,在本公开的实施例中,上述至少一个SRS资源集合关联不同控制资源集池索引,包括:多个不同的SRS资源关联多个不同的控制资源集池索引。
举例而言,上述至少一个SRS资源集合中包括的多个不同的SRS资源中的每个SRS资源,分别关联一个控制资源集池索引,并且每个SRS资源关联不同的控制资源集池索引。
可选地,在本公开的实施例中,上述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
举例而言,不同的DG-PUSCH分别与不同的控制资源集池索引值相关联,不同的SRS资源分别与不同的控制资源集池索引相关联。从而可以通过与DG-PUSCH相关联的控制资源集池索引值所属的控制资源集池索引,得到与该控制资源集池索引相关联的SRS资源,实现不同的DG-PUSCH与不同的SRS资源相关联。
可以理解,上述实施例是从网络侧设备侧描述本公开实施例的多面板增强传输配置方法的实现方式。本公开实施例还提出了另一种多面板增强传输配置方法,下面将从终端设备描述该多面板增强传输配置方法的实现方式。
通过实施本公开实施例,网络侧设备可以配置SRS资源集合,并将该SRS资源集合的配置信息发送至终端设备,使终端设备能够基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
需要说明的是,本公开实施例中涉及的“一个”,其是指至少包括一个,不限定必须为只有一个。同样的,对于“两个”,其也是指至少两个,不限定必须为只有两个。在本公开实施例中的“控制资源池索引”可以为任何可以标识出控制资源池的标识符,其表现形式并不限定于以上实施例中的举例说明。
请参见图3,图3是本公开实施例提供的另一种多面板增强传输配置方法的流程示意图。该方法由具备多天线面板panel的终端设备执行。如图3所示,该方法可以包括但不限于如下步骤:
步骤S301:接收网络侧设备发送的配置信息。
其中,在本公开的实施例中,上述配置信息用于指示至少一个SRS资源集合,以及至少一个SRS资源集合关联的控制资源集池索引;若包括多个SRS资源集合,则不同的SRS资源集合关联不同的控制资源集池索引;上述至少一个SRS资源集合为网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,该PUSCH为终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
举例而言,终端设备接收网络侧设备发送的用于指示至少一个SRS资源集合,以及上述SRS资源集合关联的不同控制资源集池索引的配置信息。上述SRS资源集合为该网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,上述PUSCH为终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
在一种实现方式中,上述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
作为一种示例,上述PUSCH传输包括DG-PUSCH传输。
作为另一种示例,上述PUSCH传输包括CG-PUSCH传输。
作为又一种示例,上述PUSCH传输同时包括DG-PUSCH传输和CG-PUSCH传输。
在一种可选地实现方式中,上述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输,通过调度DCI配置的控制资源集池索引值与对应的SRS资源集合相关联。
举例而言,每个panel面向TRP使用的DG-PUSCH传输与一个调度DCI的控制资源集池中的一个索引值相关联,SRS资源集合与调度DCI的控制资源集池索引相关联。其中,不同的DG-PUSCH传输,对应于不同的控制资源集池索引值。其中,不同的DG-PUSCH传输,使用不同的波束。从而可以通过与一个panel面向一个TRP使用的一种波束的DG-PUSCH传输相关联的调度DCI的控制资源集池索引值,得到与该调度DCI的控制资源集池索引值相关联的SRS资源集合,从而使得多个关联不同的panel面向不同TRP使用不同波束的DG-PUSCH传输,通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
在本公开的一些实施例中,上述至少一个SRS资源集合包括多个不同的SRS资源集合,多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输。
举例而言,上述至少一个SRS资源集合包括多个不同的SRS资源集合,每个SRS资源集合分别关联一个panel面向一个TRP使用的一种波束上的PUSCH传输。
可选地,在本公开的实施例中,多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
作为一种示例,多个不同的SRS资源集合中的每个SRS资源集合的功能配置的方式均为“码本”。
作为另一种示例,多个不同的SRS资源集合中的每个SRS资源集合的功能配置的方式均为“非码本”。
可选地,在本公开的实施例中,上述多个不同的SRS资源集合包括的SRS资源个数独立配置。举例而言,上述多个不同的SRS资源集合中每个SRS资源集合中可以包括一个或多个SRS资源,并且每个SRS资源集合包括的SRS资源个数可以独立配置。即:上述多个不同的SRS资源集合中每个SRS资源集合中可以包括一个或多个SRS资源,并且每个SRS资源集合包括的SRS资源个数可以是相同的,也可以是不同的。
可选地,在本公开的实施例中,上述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
举例而言,上述多个不同的SRS资源集中的每个SRS资源集合,分别关联对应的不同功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,在本公开的实施例中,上述至少一个SRS资源集合关联不同控制资源集池索引,包括:上述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
举例而言,多个不同SRS资源集合中的每个SRS资源集合,分别关联一个控制资源集池中的索引,并且不同的SRS资源集合关联不同的索引。
可选地,在本公开的实施例中,上述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
举例而言,不同的DG-PUSCH分别与不同的控制资源集池索引值相关联,不同的SRS资源集合分别与不同的控制资源集池索引相关联。从而可以通过与DG-PUSCH相关联的控制资源集池索引值所属的控制资源集池索引,得到与该控制资源集池索引相关联的SRS资源集合,实现不同的DG-PUSCH与不同的SRS资源集合相关联。
可选地,在本公开的实施例中,上述CG-PUSCH为类型I的CG-PUSCH;其中,对于类型I的CG-PUSCH,通过RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
作为一种示例,当CG-PUSCH为类型I的CG-PUSCH时,终端设备通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI。
作为另一种示例,当当CG-PUSCH为类型I的CG-PUSCH时,终端设备通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,在本公开的实施例中,上述CG-PUSCH为类型II的CG-PUSCH;其中,对于类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
举例而言,当CG-PUSCH为类型II的CG-PUSCH时,终端设备通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
在本公开的一些实施例中,上述至少一个SRS资源集合包括一个SRS资源集合,上述一个SRS资源集合包括多个不同的SRS资源子集;其中,上述一个SRS资源集合的功能配置为“码本”或“非码本”。
作为一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,且该SRS资源集合包括多个不同的SRS资源子集,该SRS资源集合的功能配置方式为“码本”。
作为另一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,且该SRS资源集合包括多个不同的SRS资源子集,该SRS资源集合的功能配置方式为“非码本”。
可选地,在本公开的实施例中,上述多个不同的SRS资源子集包括的SRS资源个数独立配置。
举例而言,上述多个不同的SRS资源子集中的每个SRS资源子集可以包括一个或多个SRS资源,并且每个SRS资源子集中的SRS资源个数可以是相同的,也可以是不同的。
可选地,在本公开的实施例中,多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
举例而言,上述多个不同的SRS资源子集中的每个SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,在本公开的实施例中,上述至少一个SRS资源集合关联不同控制资源集池索引,包括:多个不同的SRS资源子集关联多个不同的控制资源集池索引。
举例而言,上述多个不同的SRS资源子集中的每个SRS资源子集分别关联一个控制资源集池索引,并且每个SRS资源子集关联不同的控制资源集池索引。
可选地,在本公开的实施例中,上述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
举例而言,不同的DG-PUSCH分别与不同的控制资源集池索引值相关联,不同的SRS资源子集分别与不同的控制资源集池索引相关联。从而可以通过与DG-PUSCH相关联的控制资源集池索引值所属的控制资源集池索引,得到与该控制资源集池索引相关联的SRS资源子集,实现不同的DG-PUSCH与不同的SRS资源子集相关联。
可选地,在本公开的实施例中,上述CG-PUSCH为类型I的CG-PUSCH;其中,对于类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
作为一种示例,当CG-PUSCH为类型I的CG-PUSCH时,终端设备通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI。
作为另一种示例,当CG-PUSCH为类型I的CG-PUSCH时,终端设备通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,在本公开的实施例中,上述CG-PUSCH为类型II的CG-PUSCH;其中,对于类型II的CG-PUSCH,通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
举例而言,当CG-PUSCH为类型II的CG-PUSCH时,终端设备通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
在本公开的一些实施例中,上述至少一个SRS资源集合包括一个SRS资源集合,一个SRS资源集合包括多个不同的SRS资源;其中,一个SRS资源集合的功能配置为“码本”或“非码本”。
作为一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,该SRS资源集合包括多个不同的SRS资源;该SRS资源集合的功能配置方式为“码本”。
作为另一种示例,上述至少一个SRS资源集合包括一个SRS资源集合,该SRS资源集合包括多个不同的SRS资源;该SRS资源集合的功能配置方式为“非码本”。
可选地,在本公开的实施例中,上述至少一个SRS资源集合关联不同控制资源集池索引,包括:多个不同的SRS资源关联多个不同的控制资源集池索引。
举例而言,SRS资源集合中的每个SRS资源,分别关联一个控制资源集池索引,并且不同的SRS资源关联不同的控制资源集池索引。
可选地,在本公开的实施例中,上述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
举例而言,不同的DG-PUSCH分别与不同的控制资源集池索引值相关联,不同的SRS资源分别与不同的控制资源集池索引相关联。从而可以通过与DG-PUSCH相关联的控制资源集池索引值所属的控制资源集池索引,得到与该控制资源集池索引相关联的SRS资源,实现不同的DG-PUSCH与不同的SRS资源相关联。
可选地,在本公开的实施例中,上述CG-PUSCH为类型I的CG-PUSCH;其中,对于类型I的CG-PUSCH,通过RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
作为一种示例,当CG-PUSCH为类型I的CG-PUSCH时,终端设备通过RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI。
作为另一种示例,当当CG-PUSCH为类型I的CG-PUSCH时,终端设备通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,在本公开的实施例中,上述CG-PUSCH为类型II的CG-PUSCH;其中,对于类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
举例而言,当CG-PUSCH为类型II的CG-PUSCH时,终端设备通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
通过实施本公开实施例,终端设备可以接收网络侧设备发送的SRS资源集合的配置信息,并基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
上述本公开提供的实施例中,分别从网络侧设备和终端设备的角度对本公开实施例提供的方法进 行了介绍。为了实现上述本公开实施例提供的方法中的各功能,网络侧设备和终端设备可以包括硬件结构、软件模块,以硬件结构、软件模块、或硬件结构加软件模块的形式来实现上述各功能。上述各功能中的某个功能可以以硬件结构、软件模块、或者硬件结构加软件模块的方式来执行。请参见图4,为本公开实施例提供的一种通信装置40的结构示意图。图4所示的通信装置40可包括收发模块401和处理模块402。收发模块401可包括发送模块和/或收发模块,发送模块用于实现发送功能,收发模块用于实现接收功能,收发模块401可以实现发送功能和/或接收功能。
通信装置40可以是网络侧设备,也可以是网络侧设备中的装置,还可以是能够与网络侧设备匹配使用的装置,或者,通信装置40可以是终端设备,也可以是终端设备中的装置,还可以是能够与终端设备匹配使用的装置。
通信装置40为网络侧设备:处理模块402,用于为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参考信号SRS资源集合;其中,所述PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH;收发模块401,用于向所述终端设备发送所述至少一个探测参考信号SRS资源集合对应的配置信息;其中,所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。
在一种实现方式中,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
通过本公开实施例的装置,网络侧设备可以配置SRS资源集合,并将该SRS资源集合的配置信息发送至终端设备,使终端设备能够基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
通信装置40为终端设备:收发模块401,用于接收网络侧设备发送的配置信息;所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引;其中,所述至少一个SRS资源集合为所述网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,所述PUSCH为所述终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
在一种实现方式中,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活 DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
通过本公开实施例的装置,终端设备可以接收网络侧设备发送的SRS资源集合的配置信息,并基于该配置信息实现独立的预编码和功率控制,从而增强不同PDCCH的上行传输能力。
请参见图5,图5是本公开实施例提供的另一种通信装置50的结构示意图。通信装置50可以是网络侧设备,也可以是终端设备,也可以是支持网络侧设备实现上述方法的芯片、芯片系统、或处理器等,还可以是支持终端设备实现上述方法的芯片、芯片系统、或处理器等。该装置可用于实现上述方法实施例中描述的方法,具体可以参见上述方法实施例中的说明。
通信装置50可以包括一个或多个处理器501。处理器501可以是通用处理器或者专用处理器等。例如可以是基带处理器或中央处理器。基带处理器可以用于对通信协议以及通信数据进行处理,中央处理器可以用于对通信装置(如,基站、基带芯片,终端设备、终端设备芯片,DU或CU等)进行控制,执行计算机程序,处理计算机程序的数据。
可选的,通信装置50中还可以包括一个或多个存储器502,其上可以存有计算机程序503,处理器501执行所述计算机程序503,以使得通信装置50执行上述方法实施例中描述的方法。可选的,所述存储器502中还可以存储有数据。通信装置50和存储器502可以单独设置,也可以集成在一起。
可选的,通信装置50还可以包括收发器504、天线505。收发器504可以称为收发单元、收发机、或收发电路等,用于实现收发功能。收发器504可以包括接收器和发送器,接收器可以称为接收机或接收电路等,用于实现接收功能;发送器可以称为发送机或发送电路等,用于实现发送功能。
可选的,通信装置50中还可以包括一个或多个接口电路5010。接口电路5010用于接收代码指令并传输至处理器501。处理器501运行所述代码指令以使通信装置50执行上述方法实施例中描述的方法。
通信装置50为网络侧设备:收发器504用于执行图2中的步骤S202。处理器501用于执行图2中的步骤S201。
通信装置50为终端设备:收发器504用于执行图3中的步骤S301。
在一种实现方式中,处理器501中可以包括用于实现接收和发送功能的收发器。例如该收发器可以是收发电路,或者是接口,或者是接口电路。用于实现接收和发送功能的收发电路、接口或接口电路可以是分开的,也可以集成在一起。上述收发电路、接口或接口电路可以用于代码/数据的读写,或者,上述收发电路、接口或接口电路可以用于信号的传输或传递。
在一种实现方式中,处理器501可以存有计算机程序,该计算机程序在处理器501上运行,可使得通信装置50执行上述方法实施例中描述的方法。上述计算机程序可能固化在处理器501中,该种情况下,处理器501可能由硬件实现。
在一种实现方式中,通信装置50可以包括电路,所述电路可以实现前述方法实施例中发送或接收或者通信的功能。本公开中描述的处理器和收发器可实现在集成电路(integrated circuit,IC)、模拟IC、射频集成电路RFIC、混合信号IC、专用集成电路(application specific integrated circuit,ASIC)、印刷电路板(printed circuit board,PCB)、电子设备等上。该处理器和收发器也可以用各种IC工艺技术来制造,例如互补金属氧化物半导体(complementary metal oxide semiconductor,CMOS)、N型金属氧化物半导体(nMetal-oxide-semiconductor,NMOS)、P型金属氧化物半导体(positive channel metal oxide semiconductor,PMOS)、双极结型晶体管(bipolar junction transistor,BJT)、双极CMOS(BiCMOS)、硅锗(SiGe)、砷化镓(GaAs)等。
以上实施例描述中的通信装置可以是网络侧设备或者终端设备,但本公开中描述的通信装置的范围并不限于此,而且通信装置的结构可以不受图5的限制。通信装置可以是独立的设备或者可以是较大设备的一部分。例如所述通信装置可以是:
(1)独立的集成电路IC,或芯片,或,芯片系统或子系统;
(2)具有一个或多个IC的集合,可选的,该IC集合也可以包括用于存储数据,计算机程序的存储部件;
(3)ASIC,例如调制解调器(Modem);
(4)可嵌入在其他设备内的模块;
(5)接收机、终端设备、智能终端设备、蜂窝电话、无线设备、手持机、移动单元、车载设备、网络侧设备、云设备、人工智能设备等等;
(10)其他等等。
对于通信装置可以是芯片或芯片系统的情况,可参见图6所示的芯片60的结构示意图。图6所示的芯片包括处理器601和接口602。其中,处理器601的数量可以是一个或多个,接口602的数量可以是多个。
对于芯片用于实现本公开实施例中网络侧设备的功能的情况:
处理器601,用于为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参考信号SRS资源集合;其中,所述PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送 各自的PUSCH;接口602,用于向所述终端设备发送所述至少一个探测参考信号SRS资源集合对应的配置信息;其中,所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。
在一种实现方式中,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配 置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
对于芯片用于实现本公开实施例中终端设备的功能的情况:
接口602,用于接收网络侧设备发送的配置信息;所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引;其中,所述至少一个SRS资源集合为所述网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,所述PUSCH为所述终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
在一种实现方式中,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
在一种可选地实现方式中,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
可选地,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
可选地,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
可选地,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
可选地,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同 的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
可选地,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
可选地,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
可选地,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
可选地,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
可选的,芯片还包括存储器603,存储器603用于存储必要的计算机程序和数据。
本领域技术人员还可以了解到本公开实施例列出的各种说明性逻辑块(illustrative logical block)和步骤(step)可以通过电子硬件、电脑软件,或两者的结合进行实现。这样的功能是通过硬件还是软件来实现取决于特定的应用和整个系统的设计要求。本领域技术人员可以对于每种特定的应用,可以使用各种方法实现所述的功能,但这种实现不应被理解为超出本公开实施例保护的范围。
本公开实施例还提供一种多面板增强传输配置系统,该系统包括前述图4实施例中作为终端设备的通信装置和作为网络侧设备的通信装置,或者,该系统包括前述图5实施例中作为终端设备的通信装置和作为网络侧设备的通信装置。
本公开还提供一种可读存储介质,其上存储有指令,该指令被计算机执行时实现上述任一方法实施例的功能。
本公开还提供一种计算机程序产品,该计算机程序产品被计算机执行时实现上述任一方法实施例的功能。
在上述实施例中,可以全部或部分地通过软件、硬件、固件或者其任意组合来实现。当使用软件实现时,可以全部或部分地以计算机程序产品的形式实现。所述计算机程序产品包括一个或多个计算机程序。在计算机上加载和执行所述计算机程序时,全部或部分地产生按照本公开实施例所述的流程或功能。所述计算机可以是通用计算机、专用计算机、计算机网络、或者其他可编程装置。所述计算机程序可以存储在计算机可读存储介质中,或者从一个计算机可读存储介质向另一个计算机可读存储介质传输,例如,所述计算机程序可以从一个网站站点、计算机、服务器或数据中心通过有线(例如同轴电缆、光纤、数字用户线(digital subscriber line,DSL))或无线(例如红外、无线、微波等)方式向另一个网站站点、计算机、服务器或数据中心进行传输。所述计算机可读存储介质可以是计算机能够存取的任何可用介质或者是包含一个或多个可用介质集成的服务器、数据中心等数据存储设备。所述可用介质可以是磁性介质(例如,软盘、硬盘、磁带)、光介质(例如,高密度数字视频光盘(digital video disc,DVD))、或者半导体介质(例如,固态硬盘(solid state disk,SSD))等。
本领域普通技术人员可以理解:本公开中涉及的第一、第二等各种数字编号仅为描述方便进行的区分,并不用来限制本公开实施例的范围,也表示先后顺序。
本公开中的至少一个还可以描述为一个或多个,多个可以是两个、三个、四个或者更多个,本公开不做限制。在本公开实施例中,对于一种技术特征,通过“第一”、“第二”、“第三”、“A”、“B”、“C”和“D”等区分该种技术特征中的技术特征,该“第一”、“第二”、“第三”、“A”、“B”、“C”和“D”描述的技术特征间无先后顺序或者大小顺序。
本公开中的预定义可以理解为定义、预先定义、存储、预存储、预协商、预配置、固化、或预烧 制。
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公开的范围。
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。
以上所述,仅为本公开的具体实施方式,但本公开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公开揭露的技术范围内,可轻易想到变化或替换,都应涵盖在本公开的保护范围之内。因此,本公开的保护范围应以所述权利要求的保护范围为准。
Claims (50)
- 一种多面板增强传输配置方法,其特征在于,所述方法由网络侧设备执行,所述方法包括:为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参考信号SRS资源集合;其中,所述PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH;向所述终端设备发送所述至少一个探测参考信号SRS资源集合对应的配置信息;其中,所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。
- 如权利要求1所述的方法,其特征在于,所述PUSCH传输包括动态授权上行共享信道DG-PUSCH传输和配置授权上行共享信道CG-PUSCH传输中的至少一种。
- 如权利要求2所述的方法,其特征在于,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
- 如权利要求3所述的方法,其特征在于,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
- 如权利要求4所述的方法,其特征在于,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
- 如权利要求4或5所述的方法,其特征在于,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
- 如权利要求4至6中任一项所述的方法,其特征在于,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
- 如权利要求7所述的方法,其特征在于,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
- 如权利要求7所述的方法,其特征在于,所述CG-PUSCH为类型I的CG探测参考信号资源指示PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
- 如权利要求7所述的方法,其特征在于,所述CG-PUSCH为类型II的CG-PUSCH;其中, 对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
- 如权利要求3所述的方法,其特征在于,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
- 如权利要求11所述的方法,其特征在于,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
- 如权利要求11或12所述的方法,其特征在于,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
- 如权利要求11至13中任一项所述的方法,其特征在于,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
- 如权利要求14所述的方法,其特征在于,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
- 如权利要求14所述的方法,其特征在于,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
- 如权利要求14所述的方法,其特征在于,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源子集。
- 如权利要求3所述的方法,其特征在于,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
- 如权利要求18所述的方法,其特征在于,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
- 如权利要求19所述的方法,其特征在于,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
- 如权利要求19所述的方法,其特征在于,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
- 如权利要求19所述的方法,其特征在于,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
- 一种多面板增强传输配置方法,其特征在于,所述方法由具备多天线面板panel的终端设备执行,所述方法包括:接收网络侧设备发送的配置信息;所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引;其中,所述至少一个SRS资源集合为所述网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,所述PUSCH为所述终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
- 如权利要求23所述的方法,其特征在于,所述PUSCH传输包括DG-PUSCH传输和CG-PUSCH传输中的至少一种。
- 如权利要求24所述的方法,其特征在于,所述多个关联不同的panel面向不同TRP使用不同波束上的DG-PUSCH传输通过调度DCI的控制资源集池索引值与对应的SRS资源集合相关联。
- 如权利要求25所述的方法,其特征在于,所述至少一个SRS资源集合包括多个不同的SRS资源集合,所述多个不同的SRS资源集合分别关联不同的panel面向不同TRP使用不同波束上的PUSCH传输;所述多个不同的SRS资源集合的功能配置均为“码本”或“非码本”。
- 如权利要求26所述的方法,其特征在于,所述多个不同的SRS资源集合包括的SRS资源个数独立配置。
- 如权利要求26或27所述的方法,其特征在于,所述多个不同的SRS资源集合分别关联不同的功率控制参数和路径损耗估计参考信号PL RS集合。
- 如权利要求26至28中任一项所述的方法,其特征在于,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源集合分别关联多个不同的控制资源集池索引。
- 如权利要求29所述的方法,其特征在于,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源集合相关联。
- 如权利要求29所述的方法,其特征在于,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源集合的标识、以及探测参考信号资源指示SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
- 如权利要求29所述的方法,其特征在于,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源集合。
- 如权利要求25所述的方法,其特征在于,所述至少一个SRS资源集合包括一个SRS资源集合,所述一个SRS资源集合包括多个不同的SRS资源子集;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
- 如权利要求33所述的方法,其特征在于,所述多个不同的SRS资源子集包括的SRS资源个数独立配置。
- 如权利要求33或34所述的方法,其特征在于,所述多个不同的SRS资源子集分别关联不同的功率控制参数和PL RS集合。
- 如权利要求33至35中任一项所述的方法,其特征在于,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源子集关联多个不同的控制资源集池索引。
- 如权利要求36所述的方法,其特征在于,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源子集相关联。
- 如权利要求36所述的方法,其特征在于,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源子集的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
- 如权利要求36所述的方法,其特征在于,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引的取值为不同的配置授权配置参数关联相应的SRS资源子集。
- 如权利要求25所述的方法,其特征在于,所述至少一个SRS资源集合包括一个SRS资源集 合,所述一个SRS资源集合包括多个不同的SRS资源;其中,所述一个SRS资源集合的功能配置为“码本”或“非码本”。
- 如权利要求40所述的方法,其特征在于,所述至少一个SRS资源集合关联不同控制资源集池索引,包括:所述多个不同的SRS资源关联多个不同的控制资源集池索引。
- 如权利要求41所述的方法,其特征在于,所述DG-PUSCH通过调度DCI的控制资源集池索引值与不同的SRS资源相关联。
- 如权利要求41所述的方法,其特征在于,所述CG-PUSCH为类型I的CG-PUSCH;其中,对于所述类型I的CG-PUSCH,通过无线资源控制RRC信令为配置授权配置参数配置相应的SRS资源的标识、以及SRI,或者,通过RRC信令为配置授权配置参数配置相应的控制资源集池索引以及SRI。
- 如权利要求41所述的方法,其特征在于,所述CG-PUSCH为类型II的CG-PUSCH;其中,对于所述类型II的CG-PUSCH,通过激活DCI的控制资源集池索引值为不同的配置授权配置参数关联相应的SRS资源。
- 一种通信装置,其特征在于,包括:处理模块,用于为多个关联不同的天线面板panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输,配置至少一个探测参考信号SRS资源集合;其中,所述PUSCH为具备多panel的终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH;收发模块,用于向所述终端设备发送所述至少一个探测参考信号SRS资源集合对应的配置信息;其中,所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引。
- 一种通信装置,其特征在于,包括:收发模块,接收网络侧设备发送的配置信息;所述配置信息用于指示所述至少一个SRS资源集合,以及所述至少一个SRS资源集合关联不同控制资源集池索引;其中,所述至少一个SRS资源集合为所述网络侧设备为多个关联不同的panel面向不同发送接收点TRP使用不同波束上的物理上行共享信道PUSCH传输配置的资源集合,所述PUSCH为所述终端设备基于多个下行控制信息DCI调度分别从不同panel使用不同波束面向不同TRP同时发送各自的PUSCH。
- 一种通信装置,其特征在于,所述装置包括处理器和存储器,所述存储器中存储有计算机程序,所述处理器执行所述存储器中存储的计算机程序,以使所述装置执行如权利要求1至22中任一项所述的方法。
- 一种通信装置,其特征在于,所述装置包括处理器和存储器,所述存储器中存储有计算机程序,所述处理器执行所述存储器中存储的计算机程序,以使所述装置执行如权利要求23至44中任一项所述的方法。
- 一种计算机可读存储介质,用于存储有指令,当所述指令被执行时,使如权利要求1至22中任一项所述的方法被实现。
- 一种计算机可读存储介质,用于存储有指令,当所述指令被执行时,使如权利要求23至44所述的方法被实现。
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US20210112561A1 (en) * | 2019-10-11 | 2021-04-15 | Qualcomm Incorporated | Default transmission beams for multiple transmission-reception points in wireless communications |
WO2021163990A1 (zh) * | 2020-02-21 | 2021-08-26 | Oppo广东移动通信有限公司 | 上行传输控制方法、装置及其设备 |
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US20210112561A1 (en) * | 2019-10-11 | 2021-04-15 | Qualcomm Incorporated | Default transmission beams for multiple transmission-reception points in wireless communications |
WO2021163990A1 (zh) * | 2020-02-21 | 2021-08-26 | Oppo广东移动通信有限公司 | 上行传输控制方法、装置及其设备 |
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