WO2023131316A1 - 探测参考信号的端口映射方法和终端 - Google Patents
探测参考信号的端口映射方法和终端 Download PDFInfo
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- H04L5/003—Arrangements for allocating sub-channels of the transmission path
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
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- the present application belongs to the technical field of communication, and in particular relates to a port mapping method and a terminal of a sounding reference signal.
- the Sounding Reference Signal can be used for beam management, codebook-based transmission, non-codebook-based transmission, antenna switching (antenna switching) )send.
- the terminal can obtain multiple SRS resource sets through high-level signaling, and the configuration of each SRS resource set includes configurations such as its purpose and period characteristics.
- SRS resources can occupy the last 6 symbols, high-level signaling can configure SRS to occupy 1/2/4 symbols for transmission, and support the comb structure comb in the frequency domain -2, comb-4 structure.
- enhancements are made on the basis of Release-15/16.
- the starting position of the symbol of the SRS resource can be on any symbol in one time slot. And also supports the comb-8 structure.
- the number of ports that only support SRS is 1, 2, and 4.
- the number of SRS ports is 6 or 8. Since the orthogonality between different SRS ports needs to be ensured as much as possible, the existing SRS port mapping method cannot fully apply to the cases where the number of SRS ports is 6 or 8.
- Embodiments of the present application provide a method for port mapping of sounding reference signals and a terminal, which can solve the problem of port mapping for SRSs with 6 and 8 ports.
- a method for port mapping of a sounding reference signal includes:
- the terminal determines the cyclic shift CS corresponding to each port of the first SRS and/or the comb comb mapped to each port of the first SRS Location;
- the size of the comb structure of the first SRS is N, and N is 2, 4, 6 or 8.
- a port mapping device for sounding reference signals including:
- the first determining unit is configured to determine the cyclic shift CS corresponding to each port of the first SRS and/or the first SRS when the number of ports of the first Sounding Reference Signal SRS is 6 or 8. Comb comb position mapped by each port;
- the size of the comb structure of the first SRS is N, and N is 2, 4, 6 or 8.
- a terminal in a third aspect, includes a processor and a memory, the memory stores programs or instructions that can run on the processor, and when the programs or instructions are executed by the processor, the following The steps of the method in one aspect.
- a terminal including a processor and a communication interface, wherein the processor is configured to determine each of the first SRS when the number of ports of the first Sounding Reference Signal SRS is 6 or 8.
- a readable storage medium is provided, and a program or an instruction is stored on the readable storage medium, and when the program or instruction is executed by a processor, the steps of the method according to the first aspect are implemented.
- a sixth aspect provides a chip, the chip includes a processor and a communication interface, the communication interface is coupled to the processor, and the processor is used to run programs or instructions to implement the method as described in the first aspect .
- a computer program/program product is provided, the computer program/program product is stored in a storage medium, and the computer program/program product is executed by at least one processor to implement the method described in the first aspect Steps of a port mapping method for a sounding reference signal.
- a solution for port mapping is provided when the SRS is configured as a different comb, which can improve the orthogonality of SRS reference signal transmission on each port, Thereby, the performance of uplink transmission is improved.
- FIG. 1 is a block diagram of a wireless communication system to which an embodiment of the present application is applicable;
- FIG. 2 is a schematic flowchart of a port mapping method for sounding reference signals provided in an embodiment of the present application
- FIG. 3 is a schematic structural diagram of a port mapping device for sounding reference signals provided in an embodiment of the present application
- FIG. 4 is a schematic structural diagram of a communication device provided by an embodiment of the present application.
- FIG. 5 is a schematic diagram of a hardware structure of a terminal implementing an embodiment of the present application.
- first, second and the like in the specification and claims of the present application are used to distinguish similar objects, and are not used to describe a specific sequence or sequence. It should be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments of the present application can be implemented in sequences other than those illustrated or described herein and that "first" and “second” distinguish objects. It is usually one category, and the number of objects is not limited. For example, there may be one or more first objects.
- “and/or” in the description and claims means at least one of the connected objects, and the character “/” generally means that the related objects are an "or” relationship.
- LTE Long Term Evolution
- LTE-Advanced LTE-Advanced
- LTE-A Long Term Evolution-Advanced
- CDMA Code Division Multiple Access
- TDMA Time Division Multiple Access
- FDMA Frequency Division Multiple Access
- OFDMA Orthogonal Frequency Division Multiple Access
- SC-FDMA Single-carrier Frequency Division Multiple Access
- system and “network” in the embodiments of the present application are often used interchangeably, and the described technology can be used for the above-mentioned system and radio technology, and can also be used for other systems and radio technologies.
- NR New Radio
- the following description describes the New Radio (NR) system for illustrative purposes, and uses NR terminology in most of the following descriptions, but these techniques can also be applied to applications other than NR system applications, such as the 6th generation (6 th Generation, 6G) communication system.
- 6G 6th Generation
- Fig. 1 shows a block diagram of a wireless communication system to which the embodiment of the present application is applicable.
- the wireless communication system includes a terminal 11 and a network side device 12 .
- the terminal 11 can be a mobile phone, a tablet computer (Tablet Personal Computer), a laptop computer (Laptop Computer) or a notebook computer, a personal digital assistant (Personal Digital Assistant, PDA), a palmtop computer, a netbook, a super mobile personal computer (ultra-mobile personal computer, UMPC), mobile Internet device (Mobile Internet Device, MID), augmented reality (augmented reality, AR) / virtual reality (virtual reality, VR) equipment, robot, wearable device (Wearable Device) , vehicle equipment (VUE), pedestrian terminal (PUE), smart home (home equipment with wireless communication functions, such as refrigerators, TVs, washing machines or furniture, etc.), game consoles, personal computers (personal computers, PCs), teller machines or self-service Wearable devices include: smart watches, smart bracelets, smart headphones, smart glasses, smart jewelry (
- the network side device 12 may include an access network device or a core network device, where the access network device 12 may also be called a radio access network device, a radio access network (Radio Access Network, RAN), a radio access network function, or Wireless access network unit.
- RAN Radio Access Network
- RAN Radio Access Network
- Wireless access network unit Wireless access network unit
- the access network device 12 may include a base station, a WLAN access point, or a WiFi node, etc., and the base station may be called a Node B, an evolved Node B (eNB), an access point, a Base Transceiver Station (Base Transceiver Station, BTS), a radio Base station, radio transceiver, Basic Service Set (BSS), Extended Service Set (ESS), Home Node B, Home Evolved Node B, Transmitting Receiving Point (TRP) or all As long as the same technical effect is achieved, the base station is not limited to a specific technical vocabulary. It should be noted that in this embodiment of the application, only the base station in the NR system is used as an example for introduction, and The specific type of the base station is not limited.
- the core network equipment may include but not limited to at least one of the following: core network node, core network function, mobility management entity (Mobility Management Entity, MME), access mobility management function (Access and Mobility Management Function, AMF), session management function (Session Management Function, SMF), user plane function (User Plane Function, UPF), policy control function (Policy Control Function, PCF), policy and charging rules function unit (Policy and Charging Rules Function, PCRF), edge application service Discovery function (Edge Application Server Discovery Function, EASDF), unified data management (Unified Data Management, UDM), unified data storage (Unified Data Repository, UDR), home subscriber server (Home Subscriber Server, HSS), centralized network configuration ( Centralized network configuration, CNC), network storage function (Network Repository Function, NRF), network exposure function (Network Exposure Function, NEF), local NEF (Local NEF, or L-NEF), binding support function (Binding Support Function, BSF), application function (Application Function, AF), etc. It should
- FIG. 2 is a schematic flowchart of a method for port mapping of sounding reference signals provided in an embodiment of the present application. As shown in FIG. 2 , the method includes:
- Step 200 when the number of ports of the first Sounding Reference Signal SRS is 6 or 8, the terminal determines the cyclic shift (cyclic shift, CS) corresponding to each port of the first SRS and/or the first SRS The comb comb position mapped by each port of ;
- the size of the comb structure of the first SRS is N, and N is 2, 4, 6 or 8.
- the comb position can be understood as the subcarrier position mapped by the SRS in the frequency domain.
- the solution of port mapping is provided when the SRS is configured as different combs, so that the orthogonality of SRS reference signal transmission on each port can be improved .
- the CS corresponding to each port of the first SRS is determined according to at least one of a cyclic shift offset value, a maximum cyclic shift offset value, a first parameter, a comb structure size, a port sequence number, and a port number ;and / or,
- the comb position mapped to each port of the first SRS is determined according to at least one of a comb offset value, a comb structure size, a cyclic shift offset value, a maximum cyclic shift offset value, a first parameter, and a port sequence number.
- the first parameter is a value agreed by default between the network side device and the terminal and/or a value indicated by the network side device and/or a value reported by the terminal.
- a method for determining the CS corresponding to each port of the SRS and the comb position mapped by each port is provided, which can improve the orthogonality of SRS reference signal transmission on each port, thereby improving the performance of uplink transmission.
- CS mapping method 1 is as follows:
- Different ports of the first SRS correspond to different CSs, that is, 8 ports adopt different CSs;
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- K TC is the size of the comb structure.
- the corresponding comb position mapping method 1 is as follows:
- Each port of the first SRS is mapped to the same comb position, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- the corresponding comb position mapping method 2 is as follows:
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions.
- port ⁇ 1001, 1003, 1005, 1007 ⁇ is a group, mapped to the same first comb position
- port ⁇ 1000, 1002, 1004, 1006 ⁇ is a group, mapped to the same second comb position.
- the first comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the corresponding comb position mapping method 3 is as follows:
- the comb position mapped by each port of the first SRS is related to the cyclic shift offset value.
- the 8 ports of the first SRS are divided into 2 groups, and the same group
- the comb position of the port mapping is the same, and the ports of different groups are mapped to different comb positions.
- Ports are grouped, and ports of different groups are mapped to different comb positions for a specific cyclic shift offset value.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- CS mapping method 2 is used as follows:
- Ports are grouped, ports in different groups correspond to different CSs, and ports in the same group use the same CS.
- the 8 ports of the first SRS are divided into 4 groups, and ports in the same group use the same CS, and ports in different groups use different CSs.
- port ⁇ 1000,1001 ⁇ is a group, using the same CS
- port ⁇ 1002,1003 ⁇ is a group, using the same CS
- port ⁇ 1004,1005 ⁇ is a group, using the same CS
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the corresponding comb position mapping method 4 is as follows:
- Ports are grouped, and ports in different groups are mapped to different comb positions.
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions.
- port ⁇ 1001, 1003, 1005, 1007 ⁇ is mapped to the same first comb position
- port ⁇ 1000, 1002, 1004, 1006 ⁇ is mapped to the same second comb position.
- the first comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the CS mapping method and the comb position mapping method can be used to improve the orthogonality of SRS reference signal transmission on each port, and then Improve uplink transmission performance.
- CS mapping method three is as follows:
- Ports are grouped, ports in different groups correspond to different CSs, and ports in the same group use the same CS.
- the 8 ports of the first SRS are divided into 4 groups, and ports in the same group use the same CS, and ports in different groups use different CSs, that is, port ⁇ 1000, 1001 ⁇ uses the same CS; port ⁇ 1002,1003 ⁇ uses the same CS; port ⁇ 1004,1005 ⁇ uses the same CS; port ⁇ 1006,1007 ⁇ uses the same CS.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the corresponding Comb position mapping method 5 is as follows:
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions, that is, port ⁇ 1001, 1003, 1005, 1007 ⁇ is mapped to The same first comb position, port ⁇ 1000,1002,1004,1006 ⁇ is mapped to the same second comb position.
- the comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the corresponding Comb position mapping method six is as follows:
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, the ports are grouped, and for a specific cyclic shift offset value, different groups of ports are mapped to different comb positions.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- CS mapping method 4 is used as follows: ports are grouped, ports in different groups correspond to different CSs, and ports in the same group use the same CS .
- the 8 ports of the first SRS are divided into 2 groups, and ports in the same group use the same CS, and ports in different groups use different CSs.
- port ⁇ 1000,1001,1002,1003 ⁇ adopts the same CS
- port ⁇ 1004,1005,1006,1007 ⁇ adopts the same CS.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- x is the value agreed by default between the network side device and the terminal and/or the value indicated by the network side device and/or the value reported by the terminal
- x 4
- K TC is the value The size of the comb structure.
- the corresponding Comb position mapping method 7 is as follows:
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions, that is, port ⁇ 1000, 1004 ⁇ is mapped to the same first Comb position; port ⁇ 1001,1005 ⁇ is mapped in the same second comb position; port ⁇ 1002,1006 ⁇ is mapped in the same third comb position; port ⁇ 1003,1007 ⁇ is mapped in the same fourth comb position; where, The first comb position, the second comb position are different, the third comb position is different and the fourth comb position is different.
- Comb location mapped for port i is the comb offset value
- x is the first parameter
- x is the value agreed by default between the network side device and the terminal and/or the value indicated by the network side device and/or the value reported by the terminal
- x 4.
- a CS mapping method and a comb position mapping method are provided when the number of SRS ports is 8 and the size of the comb structure is 4, which can be used to improve the orthogonality of SRS reference signal transmission on each port, and further Improve uplink transmission performance.
- the CS mapping method five is as follows:
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups use different CSs, that is, port ⁇ 1000, 1001, 1002, 1003 ⁇ use the same CS; port ⁇ 1004,1005,1006,1007 ⁇ uses the same CS.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the corresponding Comb position mapping method 8 is as follows:
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions, that is, port ⁇ 1000, 1004 ⁇ is mapped to the same first Comb position; port ⁇ 1001,1005 ⁇ is mapped in the same second comb position; port ⁇ 1002,1006 ⁇ is mapped in the same third comb position; port ⁇ 1003,1007 ⁇ is mapped in the same fourth comb position; where, The first comb position, the second comb position are different, the third comb position is different and the fourth comb position is different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure
- x is the first parameter
- CS mapping method six is used:
- the 8 ports of the first SRS all use the same CS, and the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the corresponding Comb position mapping method 9 is as follows:
- Different ports of the first SRS are mapped to different comb positions.
- mapping different ports of the first SRS to different comb positions can also be understood as grouping ports, each port forms a group, and port groups of different groups are mapped to different comb positions, that is, different ports Mapped to different comb positions.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- a CS mapping method and a comb position mapping method are provided when the number of SRS ports is 8 and the size of the comb structure is 8, which can be used to improve the orthogonality of SRS reference signal transmission on each port, and further Improve uplink transmission performance.
- CS mapping method seven is used:
- Different ports of the first SRS use different CSs, and different ports correspond to different CSs rounded down.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the corresponding Comb position mapping method 10 is as follows:
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions.
- port ⁇ 1000, 1002, 1003, 1005 ⁇ is a group and mapped to the same first comb position
- port ⁇ 1001, 1004 ⁇ is a group and mapped to the same second comb position.
- the first comb position and the second comb position are different.
- the port of the second SRS is allowed to be mapped to the same comb position as the port ⁇ 1001, 1004 ⁇ of the first SRS.
- the second SRS is a 2-port SRS; or, the second SRS is an N-port SRS, N>2, and the 2 ports are mapped to the same The comb position.
- the cyclic shift offset value corresponding to the second SRS is equal to the maximum cyclic shift offset value corresponding to the first SRS after adding 3 to the cyclic shift offset value corresponding to the first SRS The value obtained by performing the remainder.
- the comb position mapped to each port of the first SRS is calculated by the following formula:
- the port of the second SRS is allowed to be mapped to the same comb position as the port ⁇ 1001, 1004 ⁇ of the first SRS, the second SRS is a 2-port SRS; or the second SRS is an N-port SRS, N>2, where two ports are mapped to the same comb position as ports ⁇ 1001, 1004 ⁇ of the first SRS.
- the cyclic shift offset value corresponding to the second SRS is equal to the cyclic shift offset value corresponding to the first SRS plus 3, and then the maximum cyclic shift offset value corresponding to the first SRS is calculated to obtain value.
- a group of ports ⁇ 1000, 1002, 1004 ⁇ is mapped to the same first comb position, and a group of ports ⁇ 1001, 1003, 1005 ⁇ is mapped to the same second comb position.
- the first comb position and the second comb position are different.
- the comb position of each port mapping of the first SRS is calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- CS mapping method eight is adopted:
- Different ports of the first SRS use different CSs, and different ports correspond to different CSs rounded up.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the corresponding Comb position mapping method 11 is as follows:
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports in different groups are mapped to different comb positions, and the number of ports in each group can be different.
- port ⁇ 1000, 1001, 1003, 1004 ⁇ is a group and is mapped to the same first comb position
- port ⁇ 1002, 1005 ⁇ is a group and is mapped to the same second comb position.
- the first comb position and the second comb position are different.
- the ports of the third SRS are allowed to be mapped to the same comb position as the ports ⁇ 1002, 1005 ⁇ of the first SRS.
- the third SRS is a 2-port SRS, or the third SRS is an N-port SRS, N>2, and the 2 ports are mapped to the same Comb position.
- the cyclic shift offset value corresponding to the third SRS is equal to the cyclic shift offset value corresponding to the first SRS plus 1, and then the maximum cyclic shift offset value corresponding to the first SRS is calculated to obtain value.
- the comb position mapped to each port of the first SRS is calculated by the following formula:
- the ports of the third SRS are allowed to be mapped to the same comb position as the ports ⁇ 1002, 1005 ⁇ of the first SRS.
- the third SRS is a 2-port SRS, or the third SRS is an N-port SRS, N>2, and the 2 ports are mapped to the same Comb position.
- the cyclic shift offset value corresponding to the third SRS is equal to the cyclic shift offset value corresponding to the first SRS plus 1, and then the maximum cyclic shift offset value corresponding to the first SRS is calculated to obtain value.
- a group of ports ⁇ 1000, 1002, 1004 ⁇ is mapped to the same first comb position, and a group of ports ⁇ 1001, 1003, 1005 ⁇ is mapped to the same second comb position.
- the first comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- Different ports of the first SRS use different CSs, and some ports are rounded up, and some ports are rounded down.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the corresponding Comb position mapping method twelve is as follows:
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports in different groups are mapped to different comb positions, and the number of ports in each group can be different.
- port ⁇ 1001, 1002, 1004, 1005 ⁇ is a group and mapped to the same first comb position
- port ⁇ 1000, 1003 ⁇ is a group and mapped to the same second comb position.
- the first comb position and the second comb position are different.
- the port of the fourth SRS is allowed to be mapped to the same comb position as the port ⁇ 1000, 1003 ⁇ of the first SRS.
- the fourth SRS is a 2-port SRS, or the fourth SRS is an N-port SRS, N>2, and the 2 ports are mapped to the same Comb position.
- the cyclic shift offset value corresponding to the fourth SRS is equal to the cyclic shift offset value corresponding to the first SRS plus 2, and then the maximum cyclic shift offset value corresponding to the first SRS is calculated to obtain value.
- the comb position mapped to each port of the first SRS is calculated by the following formula:
- the port of the fourth SRS is allowed to be mapped to the same comb position as the port ⁇ 1000, 1003 ⁇ of the first SRS.
- the fourth SRS is a 2-port SRS, or the fourth SRS is an N-port SRS, N>2, and the 2 ports are mapped to the same Comb position.
- the cyclic shift offset value corresponding to the fourth SRS is equal to the cyclic shift offset value corresponding to the first SRS plus 2, and then the maximum cyclic shift offset value corresponding to the first SRS is calculated to obtain value.
- a group of ports ⁇ 1000, 1002, 1004 ⁇ is mapped to the same first comb position, and a group of ports ⁇ 1001, 1003, 1005 ⁇ is mapped to the same second comb position.
- the first comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- Different ports of the first SRS use different CSs, and some ports are rounded up, and some ports are rounded down.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the corresponding Comb position mapping method 13 is as follows:
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, the ports in different groups are mapped to different comb positions, and the number of ports in each group is the same.
- port ⁇ 1000, 1002, 1004 ⁇ is a group, mapped to the same first comb position
- port ⁇ 1001, 1003, 1005 ⁇ is a group, mapped to the same second comb position.
- the first comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- a CS mapping method and a comb position mapping method are provided when the number of SRS ports is 6 and the size of the comb structure is 2, which can be used to improve the orthogonality of SRS reference signal transmission on each port, and further Improve uplink transmission performance.
- Different ports of the first SRS use different CSs, that is, 6 ports use different CSs.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the corresponding Comb position mapping method fourteen is as follows:
- the comb position mapped by each port of the first SRS is related to the cyclic shift offset value.
- the 6 ports of the first SRS are divided into 2 groups, and the same group
- the comb position of the port mapping of the first SRS is the same, and the ports of different groups are mapped to different comb positions, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- a CS mapping method and a comb position mapping method are provided when the number of SRS ports is 6 and the comb structure size is 4, which can be used to improve the orthogonality of SRS reference signal transmission on each port, and further Improve uplink transmission performance.
- the CS mapping method adopted is as follows:
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups use different CSs, that is, port ⁇ 1000, 1001, 1002 ⁇ is a group, and the same CS is used CS; port ⁇ 1003, 1004, 1005 ⁇ is a group, using the same CS.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the corresponding Comb position mapping method 15 is as follows:
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions, that is, port ⁇ 1000, 1003 ⁇ is mapped to the same first Comb position, port ⁇ 1000,1004 ⁇ is mapped to the same second comb position, and port ⁇ 1002,1005 ⁇ is mapped to the same third comb position.
- the first comb position, the second comb position and the third comb position are different.
- n 1 is the value agreed by default between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal ;
- n 2 is the default agreed value between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal;
- n 3 is the default agreed value between the network side device and the terminal, and/or Or the value indicated by the network side device, and/or the value reported by the terminal.
- a CS mapping method and a comb position mapping method are provided when the number of SRS ports is 6 and the size of the comb structure is 6, which can be used to improve the orthogonality of SRS reference signal transmission on each port, and further Improve uplink transmission performance.
- CS mapping method 13 is adopted, as follows:
- Different ports of the first SRS use different CSs, that is, 6 ports use different CSs.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the comb position mapped by each port of the first SRS is related to the cyclic shift offset value.
- the 6 ports of the first SRS are divided into 2 groups, and the same group
- the comb positions of the port mapping are the same, the ports of different groups are mapped to different comb positions, and the comb positions of each port mapping of the first SRS are calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the CS mapping method 14 is adopted, as follows:
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group use the same CS, and the ports in different groups use different CSs, that is, port ⁇ 1000, 1001 ⁇ is a group and uses the same CS; port ⁇ 1002,1003 ⁇ is a group, using the same CS; port ⁇ 1004,1005 ⁇ is a group, using the same CS.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions, that is, port ⁇ 1001, 1003, 1005 ⁇ Mapped in the same first comb position, port ⁇ 1000,1002,1004 ⁇ is mapped in the same second comb position.
- the first comb position and the second comb position are different.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- CS mapping method 15 is adopted:
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups use different CSs, that is, port ⁇ 1000, 1001, 1002 ⁇ is a group, and the same CS is used CS; port ⁇ 1003, 1004, 1005 ⁇ is a group, using the same CS.
- the CS of the sequence mapped to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the corresponding Comb position mapping method 18 is as follows:
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions, that is, port ⁇ 1000, 1003 ⁇ is mapped to the same first Comb position, port ⁇ 1000,1004 ⁇ is mapped to the same second comb position, and port ⁇ 1002,1005 ⁇ is mapped to the same third comb position.
- the first comb position, the second comb position and the third comb position are different.
- n 1 is the value agreed by default between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal ;
- n 2 is the default agreed value between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal;
- n 3 is the default agreed value between the network side device and the terminal, and/or Or the value indicated by the network side device, and/or the value reported by the terminal.
- a CS mapping method and a comb position mapping method are provided when the number of SRS ports is 6 and the size of the comb structure is 8, which can be used to improve the orthogonality of SRS reference signal transmission on each port, and then Improve uplink transmission performance.
- the port mapping method for sounding reference signals provided in the embodiment of the present application may be executed by an apparatus for port mapping for sounding reference signals.
- the port mapping device for the SRS provided by the embodiment of the present application is described by taking the port mapping method for the SRS performed by the port mapping device for the SRS as an example.
- FIG. 3 is a schematic structural diagram of a port mapping device for sounding reference signals provided in an embodiment of the present application. As shown in FIG. 3 , the device 300 includes:
- the first determining unit 310 is configured to determine the cyclic shift CS corresponding to each port of the first SRS and/or each port of the first SRS when the number of ports of the first Sounding Reference Signal SRS is 6 or 8. Comb comb position for port mapping;
- the size of the comb structure of the first SRS is N, and N is 2, 4, 6 or 8.
- the CS corresponding to each port of the first SRS is determined according to at least one of a cyclic shift offset value, a maximum cyclic shift offset value, a first parameter, a comb structure size, a port sequence number, and a port number ;and / or,
- the comb position mapped to each port of the first SRS is determined according to at least one of a comb offset value, a comb structure size, a cyclic shift offset value, a maximum cyclic shift offset value, a first parameter, and a port sequence number.
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- each port of the first SRS is mapped to the same comb position, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, and for a specific cyclic shift offset value, the 8 ports of the first SRS are divided into 2 groups, And the comb position of the port mapping in the same group is the same, and the ports of different groups are mapped to different comb positions.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- x is the value agreed by default between the network side device and the terminal and/or the value indicated by the network side device and/or the value reported by the terminal
- x 4
- K TC is the value The size of the comb structure.
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS all use the same CS
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the port of the second SRS is mapped to the same comb position as the port ⁇ 1001, 1004 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the second SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 3 to the offset value.
- the port of the second SRS is mapped to the same comb position as the port ⁇ 1001, 1004 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the second SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 3 to the offset value.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the port of the third SRS is mapped to the same comb position as the port ⁇ 1002, 1005 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the third SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 1 to the offset value.
- the port of the third SRS is mapped to the same comb position as the port ⁇ 1002, 1005 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the third SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 1 to the offset value.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the port of the fourth SRS is mapped to the same comb position as the port ⁇ 1000, 1003 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the fourth SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 2 to the offset value.
- the port of the fourth SRS is mapped to the same comb position as the port ⁇ 1000, 1003 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the fourth SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 2 to the offset value.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, and for a specific cyclic shift offset value, the 6 ports of the first SRS are divided into 2 groups, And the comb position of the port mapping in the same group is the same, and the ports of different groups are mapped to different comb positions, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- n 1 is the value agreed by default between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal ;
- n 2 is the default agreed value between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal;
- n 3 is the default agreed value between the network side device and the terminal, and/or Or the value indicated by the network side device, and/or the value reported by the terminal.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, and for a specific cyclic shift offset value, the 6 ports of the first SRS are divided into 2 groups, And the comb position of the port mapping in the same group is the same, and the ports of different groups are mapped to different comb positions, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS of the sequence mapped to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- n 1 is the value agreed by default between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal ;
- n 2 is the default agreed value between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal;
- n 3 is the default agreed value between the network side device and the terminal, and/or Or the value indicated by the network side device, and/or the value reported by the terminal.
- a solution for port mapping is provided when the SRS is configured as a different comb, which can improve the orthogonality of SRS reference signal transmission on each port, Thereby, the performance of uplink transmission is improved.
- the port mapping apparatus for the sounding reference signal in the embodiment of the present application may be an electronic device, such as an electronic device with an operating system, or a component in the electronic device, such as an integrated circuit or a chip.
- the electronic device may be a terminal, or other devices other than the terminal.
- the terminal may include, but not limited to, the types of terminal 11 listed above, and other devices may be servers, Network Attached Storage (NAS), etc., which are not specifically limited in this embodiment of the present application.
- NAS Network Attached Storage
- the port mapping device for the sounding reference signal provided by the embodiment of the present application can realize each process realized by the method embodiment in FIG. 2 and achieve the same technical effect. To avoid repetition, details are not repeated here.
- this embodiment of the present application also provides a communication device 400, including a processor 401 and a memory 402, and the memory 402 stores programs or instructions that can run on the processor 401, such as , when the communication device 400 is a terminal, when the program or instruction is executed by the processor 401, each step of the above embodiment of the method for port mapping of the sounding reference signal is implemented, and the same technical effect can be achieved.
- the communication device 400 is a network-side device, when the program or instruction is executed by the processor 401, the steps in the above embodiment of the port mapping method for sounding reference signals can be achieved, and the same technical effect can be achieved. To avoid repetition, it is not repeated here repeat.
- the embodiment of the present application also provides a terminal, including a processor and a communication interface, where the processor is configured to determine that each port of the first SRS corresponds to The cyclic shift of CS and/or the comb comb position mapped by each port of the first SRS, wherein the size of the comb structure of the first SRS is N, and N is 2, 4, 6 or 8.
- This terminal embodiment corresponds to the above-mentioned terminal-side method embodiment, and each implementation process and implementation mode of the above-mentioned method embodiment can be applied to this terminal embodiment, and can achieve the same technical effect.
- FIG. 5 is a schematic diagram of a hardware structure of a terminal implementing an embodiment of the present application.
- the terminal 500 includes, but is not limited to: a radio frequency unit 501, a network module 502, an audio output unit 503, an input unit 504, a sensor 505, a display unit 506, a user input unit 507, an interface unit 508, a memory 509, and a processor 510. At least some parts.
- the terminal 500 can also include a power supply (such as a battery) for supplying power to various components, and the power supply can be logically connected to the processor 510 through the power management system, so as to manage charging, discharging, and power consumption through the power management system. Management and other functions.
- a power supply such as a battery
- the terminal structure shown in FIG. 5 does not constitute a limitation on the terminal, and the terminal may include more or fewer components than shown in the figure, or combine certain components, or arrange different components, which will not be repeated here.
- the input unit 504 may include a graphics processing unit (Graphics Processing Unit, GPU) 5041 and a microphone 5042, and the graphics processor 5041 is used in a video capture mode or an image capture mode by an image capture device (such as the image data of the still picture or video obtained by the camera) for processing.
- the display unit 506 may include a display panel 5061, and the display panel 5061 may be configured in the form of a liquid crystal display, an organic light emitting diode, or the like.
- the user input unit 507 includes at least one of a touch panel 5071 and other input devices 5072 .
- the touch panel 5071 is also called a touch screen.
- the touch panel 5071 may include two parts, a touch detection device and a touch controller.
- Other input devices 5072 may include, but are not limited to, physical keyboards, function keys (such as volume control keys, switch keys, etc.), trackballs, mice, and joysticks, which will not be repeated here.
- the radio frequency unit 501 may transmit the downlink data from the network side device to the processor 510 for processing after receiving it; in addition, the radio frequency unit 501 may send uplink data to the network side device.
- the radio frequency unit x01 includes, but is not limited to, an antenna, an amplifier, a transceiver, a coupler, a low noise amplifier, a duplexer, and the like.
- the memory 509 can be used to store software programs or instructions as well as various data.
- the memory 509 may mainly include a first storage area for storing programs or instructions and a second storage area for storing data, wherein the first storage area may store an operating system, an application program or instructions required by at least one function (such as a sound playing function, image playback function, etc.), etc.
- memory 509 may include volatile memory or nonvolatile memory, or, memory 509 may include both volatile and nonvolatile memory.
- the non-volatile memory can be read-only memory (Read-Only Memory, ROM), programmable read-only memory (Programmable ROM, PROM), erasable programmable read-only memory (Erasable PROM, EPROM), electronically programmable Erase Programmable Read-Only Memory (Electrically EPROM, EEPROM) or Flash.
- ROM Read-Only Memory
- PROM programmable read-only memory
- Erasable PROM Erasable PROM
- EPROM erasable programmable read-only memory
- Electrical EPROM Electrical EPROM
- EEPROM electronically programmable Erase Programmable Read-Only Memory
- Volatile memory can be random access memory (Random Access Memory, RAM), static random access memory (Static RAM, SRAM), dynamic random access memory (Dynamic RAM, DRAM), synchronous dynamic random access memory (Synchronous DRAM, SDRAM), double data rate synchronous dynamic random access memory (Double Data Rate SDRAM, DDRSDRAM), enhanced synchronous dynamic random access memory (Enhanced SDRAM, ESDRAM), synchronous connection dynamic random access memory (Synch link DRAM , SLDRAM) and Direct Memory Bus Random Access Memory (Direct Rambus RAM, DRRAM).
- RAM Random Access Memory
- SRAM static random access memory
- DRAM dynamic random access memory
- DRAM synchronous dynamic random access memory
- SDRAM double data rate synchronous dynamic random access memory
- Double Data Rate SDRAM Double Data Rate SDRAM
- DDRSDRAM double data rate synchronous dynamic random access memory
- Enhanced SDRAM, ESDRAM enhanced synchronous dynamic random access memory
- Synch link DRAM , SLDRAM
- Direct Memory Bus Random Access Memory Direct Rambus
- the processor 510 may include one or more processing units; optionally, the processor 510 integrates an application processor and a modem processor, wherein the application processor mainly processes operations related to the operating system, user interface, and application programs, etc., Modem processors mainly process wireless communication signals, such as baseband processors. It can be understood that the foregoing modem processor may not be integrated into the processor 510 .
- the processor 510 is configured to, when the number of ports of the first Sounding Reference Signal SRS is 6 or 8, the terminal determines the cyclic shift CS corresponding to each port of the first SRS and/or the first SRS Comb comb position mapped by each port; wherein, the size of the comb structure of the first SRS is N, and N is 2, 4, 6 or 8.
- the CS corresponding to each port of the first SRS is determined according to at least one of a cyclic shift offset value, a maximum cyclic shift offset value, a first parameter, a comb structure size, a port sequence number, and a port number ;and / or,
- the comb position mapped to each port of the first SRS is determined according to at least one of a comb offset value, a comb structure size, a cyclic shift offset value, a maximum cyclic shift offset value, a first parameter, and a port sequence number.
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- each port of the first SRS is mapped to the same comb position, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, and for a specific cyclic shift offset value, the 8 ports of the first SRS are divided into 2 groups, And the comb position of the port mapping in the same group is the same, and the ports of different groups are mapped to different comb positions.
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- x is the value agreed by default between the network side device and the terminal and/or the value indicated by the network side device and/or the value reported by the terminal
- x 4
- K TC is the value The size of the comb structure.
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- the 8 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 8 ports of the first SRS are divided into 4 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 8 ports of the first SRS all use the same CS
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the port of the second SRS is mapped to the same comb position as the port ⁇ 1001, 1004 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the second SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 3 to the offset value.
- the port of the second SRS is mapped to the same comb position as the port ⁇ 1001, 1004 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the second SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 3 to the offset value.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the port of the third SRS is mapped to the same comb position as the port ⁇ 1002, 1005 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the third SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 1 to the offset value.
- the port of the third SRS is mapped to the same comb position as the port ⁇ 1002, 1005 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the third SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 1 to the offset value.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the port of the fourth SRS is mapped to the same comb position as the port ⁇ 1000, 1003 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the fourth SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 2 to the offset value.
- the port of the fourth SRS is mapped to the same comb position as the port ⁇ 1000, 1003 ⁇ of the first SRS, and the cyclic shift offset value corresponding to the fourth SRS is equal to the cyclic shift corresponding to the first SRS A value obtained by performing a remainder on the maximum cyclic shift offset value corresponding to the first SRS after adding 2 to the offset value.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, and for a specific cyclic shift offset value, the 6 ports of the first SRS are divided into 2 groups, And the comb position of the port mapping in the same group is the same, and the ports of different groups are mapped to different comb positions, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- n 1 is the value agreed by default between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal ;
- n 2 is the default agreed value between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal;
- n 3 is the default agreed value between the network side device and the terminal, and/or Or the value indicated by the network side device, and/or the value reported by the terminal.
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS corresponding to port i is the CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number, is the number of ports.
- the comb position mapped to each port of the first SRS is related to the cyclic shift offset value, and for a specific cyclic shift offset value, the 6 ports of the first SRS are divided into 2 groups, And the comb position of the port mapping in the same group is the same, and the ports of different groups are mapped to different comb positions, and the comb position of each port mapping of the first SRS is calculated by the following formula:
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS corresponding to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- Comb location mapped for port i is the comb offset value
- K TC is the size of the comb structure.
- the 6 ports of the first SRS are divided into 2 groups, and the ports in the same group use the same CS, and the ports in different groups ports with different CS,
- the CS of the sequence mapped to each port of the first SRS is calculated by the following formula:
- CS CS corresponding to port i
- cyclic shift offset value is the maximum cyclic shift offset value
- p i is the port serial number
- x is the first parameter
- the 6 ports of the first SRS are divided into 3 groups, and the ports in the same group are mapped to the same comb position, and the ports of different groups are mapped to different comb positions,
- n 1 is the value agreed by default between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal ;
- n 2 is the default agreed value between the network side device and the terminal, and/or the value indicated by the network side device, and/or the value reported by the terminal;
- n 3 is the default agreed value between the network side device and the terminal, and/or Or the value indicated by the network side device, and/or the value reported by the terminal.
- a solution for port mapping is provided when the SRS is configured as a different comb, which can improve the orthogonality of SRS reference signal transmission on each port, Thereby, the performance of uplink transmission is improved.
- the embodiment of the present application also provides a readable storage medium, where a program or an instruction is stored on the readable storage medium, and when the program or instruction is executed by the processor, each process in the above embodiment of the port mapping method for the sounding reference signal is implemented, And can achieve the same technical effect, in order to avoid repetition, no more details here.
- the processor is the processor in the terminal described in the foregoing embodiments.
- the readable storage medium includes a computer-readable storage medium, such as a computer read-only memory ROM, a random access memory RAM, a magnetic disk or an optical disk, and the like.
- the embodiment of the present application further provides a chip, the chip includes a processor and a communication interface, the communication interface is coupled to the processor, and the processor is used to run programs or instructions to realize the above-mentioned port mapping of the detection reference signal
- the chip includes a processor and a communication interface
- the communication interface is coupled to the processor
- the processor is used to run programs or instructions to realize the above-mentioned port mapping of the detection reference signal
- the chip mentioned in the embodiment of the present application may also be called a system-on-chip, a system-on-chip, a system-on-a-chip, or a system-on-a-chip.
- An embodiment of the present application further provides a computer program/program product, the computer program/program product is stored in a storage medium, and the computer program/program product is executed by at least one processor to realize the above-mentioned detection reference signal port
- a computer program/program product is stored in a storage medium
- the computer program/program product is executed by at least one processor to realize the above-mentioned detection reference signal port
- the embodiment of the present application also provides a communication system, including: a terminal and a network side device, the terminal can be configured to perform the steps of the port mapping method for sounding reference signals as described above.
- the term “comprising”, “comprising” or any other variation thereof is intended to cover a non-exclusive inclusion such that a process, method, article or apparatus comprising a set of elements includes not only those elements, It also includes other elements not expressly listed, or elements inherent in the process, method, article, or device. Without further limitations, an element defined by the phrase “comprising a " does not preclude the presence of additional identical elements in the process, method, article, or apparatus comprising that element.
- the scope of the methods and devices in the embodiments of the present application is not limited to performing functions in the order shown or discussed, and may also include performing functions in a substantially simultaneous manner or in reverse order according to the functions involved. Functions are performed, for example, the described methods may be performed in an order different from that described, and various steps may also be added, omitted, or combined. Additionally, features described with reference to certain examples may be combined in other examples.
- the methods of the above embodiments can be implemented by means of software plus a necessary general-purpose hardware platform, and of course also by hardware, but in many cases the former is better implementation.
- the technical solution of the present application can be embodied in the form of computer software products, which are stored in a storage medium (such as ROM/RAM, magnetic disk, etc.) , CD-ROM), including several instructions to make a terminal (which may be a mobile phone, a computer, a server, an air conditioner, or a network device, etc.) execute the methods described in the various embodiments of the present application.
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Abstract
本申请公开了一种探测参考信号的端口映射方法和终端,属于通信技术领域,本申请实施例的探测参考信号的端口映射方法包括:在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
Description
相关申请的交叉引用
本申请要求于2022年01月07日提交的申请号为202210016659.0,发明名称为“探测参考信号的端口映射方法和终端”的中国专利申请的优先权,其通过引用方式全部并入本申请。
本申请属于通信技术领域,具体涉及一种探测参考信号的端口映射方法和终端。
在NR***中,探测参考信号(Sounding Reference Signal,SRS)可用于波束管理(beam management)、基于码本(codebook)的传输、基于非码本(non-codebook)的传输、天线切换(antenna switching)发送。终端可以通过高层信令获取多个SRS资源集合,每个SRS资源集合配置中包含其用途、周期特性等配置。
在Release-15/16中,在1个时隙内,SRS资源可占用最后6个符号,高层信令可配置SRS占用1/2/4个符号传输,并支持频域上的梳状结构comb-2,comb-4结构。在Release-17中,在Release-15/16的基础上进行了增强,在1个时隙内,SRS资源的符号起始位置可以在一个时隙内的任意符号上。并且还支持了comb-8的结构。
在现有的NR协议中,只支持SRS的端口数为1、2、4。为了进一步提升上行传输的性能,需要引入支持更多端口数的SRS,例如SRS端口数为6、8。由于不同的SRS端口之间需要尽可能地保证正交性,现有的SRS端口映射方式不能完全适用于SRS端口数为6和8的情况。
发明内容
本申请实施例提供一种探测参考信号的端口映射方法和终端,能够解决端口数为6和8的SRS进行端口映射的问题。
第一方面,提供了一种探测参考信号的端口映射方法,该方法包括:
在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;
其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
第二方面,提供了一种探测参考信号的端口映射装置,包括:
第一确定单元,用于在第一探测参考信号SRS的端口数为6或8的情况下,终 端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;
其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
第三方面,提供了一种终端,该终端包括处理器和存储器,所述存储器存储可在所述处理器上运行的程序或指令,所述程序或指令被所述处理器执行时实现如第一方面所述的方法的步骤。
第四方面,提供了一种终端,包括处理器及通信接口,其中,所述处理器用于在第一探测参考信号SRS的端口数为6或8的情况下,确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置,其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
第五方面,提供了一种可读存储介质,所述可读存储介质上存储程序或指令,所述程序或指令被处理器执行时实现如第一方面所述的方法的步骤。
第六方面,提供了一种芯片,所述芯片包括处理器和通信接口,所述通信接口和所述处理器耦合,所述处理器用于运行程序或指令,实现如第一方面所述的方法。
第七方面,提供了一种计算机程序/程序产品,所述计算机程序/程序产品被存储在存储介质中,所述计算机程序/程序产品被至少一个处理器执行以实现如第一方面所述的探测参考信号的端口映射方法的步骤。
在本申请实施例中,提供了SRS的端口数为6和8时,在SRS配置为不同comb的情况下进行端口映射的解决方案,可以提高SRS参考信号在各端口上传输的正交性,从而提升上行传输的性能。
图1是本申请实施例可应用的一种无线通信***的框图;
图2为本申请实施例提供的探测参考信号的端口映射方法的流程示意图;
图3为本申请实施例提供的探测参考信号的端口映射装置的结构示意图;
图4为本申请实施例提供的通信设备的结构示意图;
图5为实现本申请实施例的一种终端的硬件结构示意图。
下面将结合本申请实施例中的附图,对本申请实施例中的技术方案进行清楚描述,显然,所描述的实施例是本申请一部分实施例,而不是全部的实施例。基于本申请中的实施例,本领域普通技术人员所获得的所有其他实施例,都属于本申请保护的范围。
本申请的说明书和权利要求书中的术语“第一”、“第二”等是用于区别类似的对象,而不用于描述特定的顺序或先后次序。应该理解这样使用的术语在适当情况下可以互换, 以便本申请的实施例能够以除了在这里图示或描述的那些以外的顺序实施,且“第一”、“第二”所区别的对象通常为一类,并不限定对象的个数,例如第一对象可以是一个,也可以是多个。此外,说明书以及权利要求中“和/或”表示所连接对象的至少其中之一,字符“/”一般表示前后关联对象是一种“或”的关系。
值得指出的是,本申请实施例所描述的技术不限于长期演进型(Long Term Evolution,LTE)/LTE的演进(LTE-Advanced,LTE-A)***,还可用于其他无线通信***,诸如码分多址(Code Division Multiple Access,CDMA)、时分多址(Time Division Multiple Access,TDMA)、频分多址(Frequency Division Multiple Access,FDMA)、正交频分多址(Orthogonal Frequency Division Multiple Access,OFDMA)、单载波频分多址(Single-carrier Frequency Division Multiple Access,SC-FDMA)和其他***。本申请实施例中的术语“***”和“网络”常被可互换地使用,所描述的技术既可用于以上提及的***和无线电技术,也可用于其他***和无线电技术。以下描述出于示例目的描述了新空口(New Radio,NR)***,并且在以下大部分描述中使用NR术语,但是这些技术也可应用于NR***应用以外的应用,如第6代(6
th Generation,6G)通信***。
图1示出本申请实施例可应用的一种无线通信***的框图。无线通信***包括终端11和网络侧设备12。其中,终端11可以是手机、平板电脑(Tablet Personal Computer)、膝上型电脑(Laptop Computer)或称为笔记本电脑、个人数字助理(Personal Digital Assistant,PDA)、掌上电脑、上网本、超级移动个人计算机(ultra-mobile personal computer,UMPC)、移动上网装置(Mobile Internet Device,MID)、增强现实(augmented reality,AR)/虚拟现实(virtual reality,VR)设备、机器人、可穿戴式设备(Wearable Device)、车载设备(VUE)、行人终端(PUE)、智能家居(具有无线通信功能的家居设备,如冰箱、电视、洗衣机或者家具等)、游戏机、个人计算机(personal computer,PC)、柜员机或者自助机等终端侧设备,可穿戴式设备包括:智能手表、智能手环、智能耳机、智能眼镜、智能首饰(智能手镯、智能手链、智能戒指、智能项链、智能脚镯、智能脚链等)、智能腕带、智能服装等。需要说明的是,在本申请实施例并不限定终端11的具体类型。网络侧设备12可以包括接入网设备或核心网设备,其中,接入网设备12也可以称为无线接入网设备、无线接入网(Radio Access Network,RAN)、无线接入网功能或无线接入网单元。接入网设备12可以包括基站、WLAN接入点或WiFi节点等,基站可被称为节点B、演进节点B(eNB)、接入点、基收发机站(Base Transceiver Station,BTS)、无线电基站、无线电收发机、基本服务集(Basic Service Set,BSS)、扩展服务集(Extended Service Set,ESS)、家用B节点、家用演进型B节点、发送接收点(Transmitting Receiving Point,TRP)或所述领域中其他某个合适的术语,只要达到相同的技术效果,所述基站不限于特定技术词汇,需要说明的是,在本申请实施例中仅以NR***中的基站为例进行介绍,并不限定基站的具体类型。核心网设备可以包含但不限于如下至少一项:核心网节点、核心网功能、移动管理实体(Mobility Management Entity,MME)、接入移动管理功能(Access and Mobility Management Function,AMF)、会话管理功能(Session Management Function,SMF)、用户平面功能(User Plane Function,UPF)、策略控制功能(Policy Control Function,PCF)、策略与计费规则功能单元(Policy and Charging Rules Function,PCRF)、边缘应用服务发现功能(Edge Application Server Discovery Function,EASDF)、统一数据管理(Unified Data Management,UDM),统一数据仓储(Unified Data Repository,UDR)、归属用户服务器(Home Subscriber Server,HSS)、集中式网络配置(Centralized network configuration,CNC)、网络存储功能(Network Repository Function,NRF),网络开放功能(Network Exposure Function,NEF)、本地NEF(Local NEF,或L-NEF)、绑定支持功能(Binding Support Function,BSF)、应用功能(Application Function,AF)等。需要说明的是,在本申请实施例中仅以NR***中的核心网设备为例进行介绍,并不限定核心网设备的具体类型。
下面结合附图,通过一些实施例及其应用场景对本申请实施例提供的探测参考信号的端口映射方法进行详细地说明。
图2为本申请实施例提供的探测参考信号的端口映射方法的流程示意图,如图2所示,该方法包括:
步骤200、在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位(cyclic shift,CS)和/或所述第一SRS的各端口映射的梳状comb位置;
其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
需要说明的是,comb位置可以理解为SRS在频域上映射的子载波位置。
在本申请实施例中,提供了SRS的端口数为6和8时,在SRS配置为不同comb的情况下进行端口映射的解决方案,从而可以提高SRS参考信号在各端口上传输的正交性。
可选地,所述第一SRS的各端口对应的CS根据循环移位偏移值、最大循环移位偏移值、第一参数、comb结构大小、端口序号和端口数中的至少一项确定;和/或,
所述第一SRS的各端口映射的comb位置根据comb偏移值、comb结构大小、循环移位偏移值、最大循环移位偏移值、第一参数和端口序号中的至少一项确定。
其中,第一参数为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值。
在本申请实施例中,提供了SRS的各端口对应的CS和各端口映射的comb位置的确定方法,可以提高SRS参考信号在各端口上传输的正交性,从而提升上行传输的性能。
可选地,在所述端口数为8,且comb结构大小为2的情况下,CS映射方法一如下:
所述第一SRS的不同端口对应不同的CS,即8个端口采用不同的CS;
其中,所述第一SRS的各端口对应的CS通过如下公式计算:
其中,p
i=1000+i,
需要说明的是,
是网络侧设备通过RRC信令配置的cyclic shift偏移值。最大循环移位偏移值即
为:
if K
TC=8,
if K
TC=4,
if K
TC=2。K
TC为comb结构大小。
采用此CS映射方法一,各端口对应的具体的CS数值如表1所示。
表1各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | 1006 | 1007 | |
初始CS 0 | 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 |
初始CS 1 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 0 |
初始CS 2 | 2 | 3 | 4 | 5 | 6 | 7 | 0 | 1 |
初始CS 3 | 3 | 4 | 5 | 6 | 7 | 0 | 1 | 2 |
初始CS 4 | 4 | 5 | 6 | 7 | 0 | 1 | 2 | 3 |
初始CS 5 | 5 | 6 | 7 | 0 | 1 | 2 | 3 | 4 |
初始CS 6 | 6 | 7 | 0 | 1 | 2 | 3 | 4 | 5 |
初始CS 7 | 7 | 0 | 1 | 2 | 3 | 4 | 5 | 6 |
可选地,在所述端口数为8,且comb结构大小为2,采用上述CS映射方法一的情况下,对应的comb位置映射方法一如下:
所述第一SRS的各端口映射在相同的comb位置,所述第一SRS的各端口映射的comb位置通过如下公式计算:
可选地,在所述端口数为8,且comb结构大小为2,采用上述CS映射方法一的情况下,对应的comb位置映射方法二如下:
所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置。
即port{1001,1003,1005,1007}为一组,映射在相同的第一comb位置,port{1000,1002,1004,1006}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为2,采用上述CS映射方法一的情况下,对应的comb位置映射方法三如下:
所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为2的情况下,采用CS映射方法二如下:
将端口分组,不同组的端口对应不同CS,同一组内的端口采用相同的CS。
可选地,所述第一SRS的8个端口划分为4组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS。
即port{1000,1001}为一组,采用相同的CS;port{1002,1003}为一组,采用相同的CS;port{1004,1005}为一组,采用相同的CS;port{1006,1007}为一组,采用相同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
采用此映射方法二,各端口对应的具体的CS数值如表2所示。
表2各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | 1006 | 1007 | |
初始CS 0 | 0 | 0 | 2 | 2 | 4 | 4 | 6 | 6 |
初始CS 1 | 1 | 1 | 3 | 3 | 5 | 5 | 7 | 7 |
初始CS 2 | 2 | 2 | 4 | 4 | 6 | 6 | 0 | 0 |
初始CS 3 | 3 | 3 | 5 | 5 | 7 | 7 | 1 | 1 |
初始CS 4 | 4 | 4 | 6 | 6 | 0 | 0 | 2 | 2 |
初始CS 5 | 5 | 5 | 7 | 7 | 1 | 1 | 3 | 3 |
初始CS 6 | 6 | 6 | 0 | 0 | 2 | 2 | 4 | 4 |
初始CS 7 | 7 | 7 | 1 | 1 | 3 | 3 | 5 | 5 |
可选地,在所述端口数为8,且comb结构大小为2,采用CS映射方法二的情况下,对应的comb位置映射方法四,如下:
将端口分组,不同组的端口映射到不同的comb位置。
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置。
即port{1001,1003,1005,1007}映射在相同的第一comb位置,port{1000,1002,1004,1006}映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
在本申请实施例中,提供了SRS的端口数为8、comb结构大小为2时,CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
可选地,在所述端口数为8,且comb结构大小为4的情况下,CS映射方法三如下:
将端口分组,不同组的端口对应不同CS,同一组内的端口采用相同的CS。
可选地,所述第一SRS的8个端口划分为4组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,即port{1000,1001}采用相同的CS;port{1002,1003}采用相同的CS;port{1004,1005}采用相同的CS;port{1006,1007}采用相同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
采用上述CS映射方法三,各端口对应的具体的CS数值如表3所示。
表3各端口对应的具体的CS数值
可选地,在所述端口数为8,且comb结构大小为4,采用CS映射方法三的情况下,对应的Comb位置映射方法五如下:
所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,即port{1001,1003,1005,1007}映射在相同的第一comb位置,port{1000,1002,1004,1006}映射在相同的第二comb位置。其中,第一
comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为4的情况下,采用CS映射方法三的 情况下,对应的Comb位置映射方法六如下:
所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,将端口分组,对于特定循环移位偏移值,不同组的端口映射到不同的comb位置。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为4的情况下,采用CS映射方法四如下:将端口分组,不同组的端口对应不同CS,同一组内的端口采用相同的CS。所述第一SRS的8个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS。
即port{1000,1001,1002,1003}采用相同的CS;port{1004,1005,1006,1007}采用相同 的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
或者,
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4,K
TC为所述comb结构大小。
采用CS映射方法四,各端口对应的具体的CS数值如表4所示。
表4各端口对应的具体的CS数值
可选地,在所述端口数为8,且comb结构大小为4,采用CS映射方法四情况下,对应的Comb位置映射方法七如下:
所述第一SRS的8个端口划分为4组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,即port{1000,1004}映射在相同的第一comb位置;port{1001,1005}映射在相同的第二comb位置;port{1002,1006}映射在相同的第三comb位置;port{1003,1007}映射在相同的第四comb位置;其中,第一comb位置、第二comb位置不同、第三comb位置不同和第四comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
或者,
在本申请实施例中,提供了SRS的端口数为8、comb结构大小为4时的CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
可选地,在所述端口数为8,且comb结构大小为8的情况下,采用CS映射方法五如下:
所述第一SRS的8个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,即port{1000,1001,1002,1003}采用相同的CS;port{1004,1005,1006,1007}采用相同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4。
采用CS映射方法五,各端口对应的具体的CS数值如表5所示。
表5各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | 1006 | 1007 | |
初始CS 0 | 0 | 0 | 0 | 0 | 3 | 3 | 3 | 3 |
初始CS 1 | 1 | 1 | 1 | 1 | 4 | 4 | 4 | 4 |
初始CS 2 | 2 | 2 | 2 | 2 | 5 | 5 | 5 | 5 |
初始CS 3 | 3 | 3 | 3 | 3 | 0 | 0 | 0 | 0 |
初始CS 4 | 4 | 4 | 4 | 4 | 1 | 1 | 1 | 1 |
初始CS 5 | 5 | 5 | 5 | 5 | 2 | 2 | 2 | 2 |
可选地,在所述端口数为8,且comb结构大小为8,采用CS映射方法五的情况下,对应的Comb位置映射方法八如下:
所述第一SRS的8个端口划分为4组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,即port{1000,1004}映射在相同的第一comb位置;port{1001,1005}映射在相同的第二comb位置;port{1002,1006}映射在相同的第三comb位置;port{1003,1007}映射在相同的第四comb位置;其中,第一comb位置、第二comb位置不同、第三comb位置不同和第四comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4。
可选地,在所述端口数为8,且comb结构大小为8的情况下,采用CS映射方法六:
所述第一SRS的8个端口均采用相同的CS,所述第一SRS的各端口对应的CS通过如下公式计算:
或者,
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=8。
采用CS映射方法六,各端口对应的具体的CS数值如表6所示。
表6各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | 1006 | 1007 | |
初始CS 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
初始CS 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 |
初始CS 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 |
初始CS 3 | 3 | 3 | 3 | 3 | 3 | 3 | 3 | 3 |
初始CS 4 | 4 | 4 | 4 | 4 | 4 | 4 | 4 | 4 |
初始CS 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 | 5 |
可选地,在所述端口数为8,且comb结构大小为8,采用CS映射方法六的情况下,对应的Comb位置映射方法九如下:
所述第一SRS的不同端口映射到不同的comb位置。
需要说明的是,将第一SRS的不同端口映射到不同的comb位置也可以理解为将端口分组,每个端口各成一组,不同组的端口组映射到不同的comb位置,也即不同的端口映射到不同的comb位置。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
在本申请实施例中,提供了SRS的端口数为8、comb结构大小为8时的CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
可选地,在所述端口数为6,且comb结构大小为2的情况下,采用CS映射方法七:
所述第一SRS的不同端口采用不同的CS,不同端口对应不同的CS向下取整。
所述第一SRS的各端口对应的CS通过如下公式计算:
采用此CS映射方法七,各端口对应的具体的CS数值如表7所示。
表7各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 1 | 2 | 4 | 5 | 6 |
初始CS 1 | 1 | 2 | 3 | 5 | 6 | 7 |
初始CS 2 | 2 | 3 | 4 | 6 | 7 | 0 |
初始CS 3 | 3 | 4 | 5 | 7 | 0 | 1 |
初始CS 4 | 4 | 5 | 6 | 0 | 1 | 2 |
初始CS 5 | 5 | 6 | 7 | 1 | 2 | 3 |
初始CS 6 | 6 | 7 | 0 | 2 | 3 | 4 |
初始CS 7 | 7 | 0 | 1 | 3 | 4 | 5 |
可选地,在所述端口数为6,且comb结构大小为2下,采用CS映射方法七的情况下,对应的Comb位置映射方法十如下:
所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置。
一种实施方式中,port{1000,1002,1003,1005}为一组,映射在相同的第一comb位置,port{1001,1004}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
在此情况下,允许第二SRS的端口与所述第一SRS的端口{1001,1004}映射到相同的comb位置。
需要说明的是,第二SRS为一个2端口的SRS;或者,第二SRS为一个N端口的SRS,N>2,其中的2个端口与第一SRS的端口{1001,1004}映射到相同的comb位置。
或者,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
在此情况下,允许第二SRS的端口与所述第一SRS的端口{1001,1004}映射到相同的comb位置,第二SRS为一个2端口的SRS;或者第二SRS为一个N端口的SRS,N>2,其中的2个端口与第一SRS的端口{1001,1004}映射到相同的comb位置。
并且所述第二SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加3之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
另一种实施方式中,port{1000,1002,1004}为一组,映射在相同的第一comb位置,port{1001,1003,1005}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述端口数为6,且comb结构大小为2的情况下,采用CS映射方法八:
所述第一SRS的不同端口采用不同的CS,不同端口对应不同的CS向上取整。
所述第一SRS的各端口对应的CS通过如下公式计算:
采用此CS映射方法八,各端口对应的具体的CS数值如表8所示。
表8各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 2 | 3 | 4 | 6 | 7 |
初始CS 1 | 1 | 3 | 4 | 5 | 7 | 0 |
初始CS 2 | 2 | 4 | 5 | 6 | 0 | 1 |
初始CS 3 | 3 | 5 | 6 | 7 | 1 | 2 |
初始CS 4 | 4 | 6 | 7 | 0 | 2 | 3 |
初始CS 5 | 5 | 7 | 0 | 1 | 3 | 4 |
初始CS 6 | 6 | 0 | 1 | 2 | 4 | 5 |
初始CS 7 | 7 | 1 | 2 | 3 | 5 | 6 |
可选地,在所述端口数为6,且comb结构大小为2,采用CS映射方法八的情况下,对应的Comb位置映射方法十一如下:
所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,且各组内的端口数量可以不同。
一种实施方式中,port{1000,1001,1003,1004}为一组,映射在相同的第一comb位 置,port{1002,1005}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
在此情况下,允许第三SRS的端口与所述第一SRS的端口{1002,1005}映射到相同的comb位置。
需要说明的是,第三SRS为一个2端口的SRS,或者第三SRS为一个N端口的SRS,N>2,其中的2个端口与第一SRS的端口{1002,1005}映射到相同的comb位置。
并且所述第三SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加1之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
或者,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
在此情况下,允许第三SRS的端口与所述第一SRS的端口{1002,1005}映射到相同的comb位置。
需要说明的是,第三SRS为一个2端口的SRS,或者第三SRS为一个N端口的SRS,N>2,其中的2个端口与第一SRS的端口{1002,1005}映射到相同的comb位置。
并且所述第三SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加1之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
另一种实施方式中,port{1000,1002,1004}为一组,映射在相同的第一comb位置,port{1001,1003,1005}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述端口数为6,且comb结构大小为2的情况下,采用CS映射方法九:
所述第一SRS的不同端口采用不同的CS,且部分端口向上取整,部分端口向下取整。
所述第一SRS的各端口对应的CS通过如下公式计算:
采用此CS映射方法九,各端口对应的具体的CS数值如表9所示。
表9各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 1 | 3 | 4 | 5 | 7 |
初始CS 1 | 1 | 2 | 4 | 5 | 6 | 0 |
初始CS 2 | 2 | 3 | 5 | 6 | 7 | 1 |
初始CS 3 | 3 | 4 | 6 | 7 | 0 | 2 |
初始CS 4 | 4 | 5 | 7 | 0 | 1 | 3 |
初始CS 5 | 5 | 6 | 0 | 1 | 2 | 4 |
初始CS 6 | 6 | 7 | 1 | 2 | 3 | 5 |
初始CS 7 | 7 | 0 | 2 | 3 | 4 | 6 |
可选地,在所述端口数为6,且comb结构大小为2,采用CS映射方法九的情况下,对应的Comb位置映射方法十二如下:
所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,且各组内的端口数量可以不同。
一种实施方式中,port{1001,1002,1004,1005}为一组,映射在相同的第一comb位置,port{1000,1003}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
在此情况下,允许第四SRS的端口与所述第一SRS的端口{1000,1003}映射到相同的comb位置。
需要说明的是,第四SRS为一个2端口的SRS,或者第四SRS为一个N端口的SRS,N>2,其中的2个端口与第一SRS的端口{1000,1003}映射到相同的comb位置。
并且所述第四SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加2之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
或者,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
在此情况下,允许第四SRS的端口与所述第一SRS的端口{1000,1003}映射到相同的comb位置。
需要说明的是,第四SRS为一个2端口的SRS,或者第四SRS为一个N端口的SRS,N>2,其中的2个端口与第一SRS的端口{1000,1003}映射到相同的comb位置。
并且所述第四SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加2之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
另一种实施方式中,port{1000,1002,1004}为一组,映射在相同的第一comb位置,port{1001,1003,1005}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述端口数为6,且comb结构大小为2的情况下,采用CS映射方法时:
所述第一SRS的不同端口采用不同的CS,且部分端口向上取整,部分端口向下取整。
所述第一SRS的各端口对应的CS通过如下公式计算:
采用此CS映射方法十,各端口对应的具体的CS数值如表10所示。
表10各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 1 | 3 | 4 | 6 | 7 |
初始CS 1 | 1 | 2 | 4 | 5 | 7 | 0 |
初始CS 2 | 2 | 3 | 5 | 6 | 0 | 1 |
初始CS 3 | 3 | 4 | 6 | 7 | 1 | 2 |
初始CS 4 | 4 | 5 | 7 | 0 | 2 | 3 |
初始CS 5 | 5 | 6 | 0 | 1 | 3 | 4 |
初始CS 6 | 6 | 7 | 1 | 2 | 4 | 5 |
初始CS 7 | 7 | 0 | 2 | 3 | 5 | 6 |
可选地,在所述端口数为6,且comb结构大小为2,采用CS映射方法十的情况下,对应的Comb位置映射方法十三如下:
所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,各组内的端口数量相同。
即port{1000,1002,1004}为一组,映射在相同的第一comb位置,port{1001,1003,1005}为一组,映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
在本申请实施例中,提供了SRS的端口数为6、comb结构大小为2时的CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
可选地,在所述端口数为6,且comb结构大小为4的情况下,采用CS映射方法十一:
所述第一SRS的不同端口采用不同的CS,即6个port采用不同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
采用此CS映射方法十一,各端口对应的具体的CS数值如表11所示。
表11各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 |
初始CS 0 | 0 | 2 | 4 | 6 | 8 | 10 |
初始CS 1 | 1 | 3 | 5 | 7 | 9 | 11 |
初始CS 2 | 2 | 4 | 6 | 8 | 10 | 0 |
初始CS 3 | 3 | 5 | 7 | 9 | 11 | 1 |
初始CS 4 | 4 | 6 | 8 | 10 | 0 | 2 |
初始CS 5 | 5 | 7 | 9 | 11 | 1 | 3 |
初始CS 6 | 6 | 8 | 10 | 0 | 2 | 4 |
初始CS 7 | 7 | 9 | 11 | 1 | 3 | 5 |
初始CS 8 | 8 | 10 | 0 | 2 | 4 | 6 |
初始CS 9 | 9 | 11 | 1 | 3 | 5 | 7 |
初始CS 10 | 10 | 0 | 2 | 4 | 6 | 8 |
初始CS 11 | 11 | 1 | 3 | 5 | 7 | 9 |
可选地,在所述端口数为6,且comb结构大小为4,采用上述CS映射方法十一的情况下,对应的Comb位置映射方法十四如下:
所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
在本申请实施例中,提供了SRS的端口数为6、comb结构大小为4时的CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
可选地,在所述端口数为6,且comb结构大小为6的情况下,采用的CS映射方法十二如下:
所述第一SRS的6个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,即port{1000,1001,1002}为一组,采用相同的CS;port{1003,1004,1005}为一组,采用相同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=3。
采用此CS映射方法十二,各端口对应的具体的CS数值如表12所示。
表12各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 0 | 0 | 4 | 4 | 4 |
初始CS 1 | 1 | 1 | 1 | 5 | 5 | 5 |
初始CS 2 | 2 | 2 | 2 | 6 | 6 | 6 |
初始CS 3 | 3 | 3 | 3 | 7 | 7 | 7 |
初始CS 4 | 4 | 4 | 4 | 0 | 0 | 0 |
初始CS 5 | 5 | 5 | 5 | 1 | 1 | 1 |
初始CS 6 | 6 | 6 | 6 | 2 | 2 | 2 |
初始CS 7 | 7 | 7 | 7 | 3 | 3 | 3 |
可选地,在所述端口数为6,且comb结构大小为6,采用上述CS映射方法十二的情况下,对应的Comb位置映射方法十五如下:
所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,即port{1000,1003}映射在相同的第一comb位置,port{1000,1004}映射在相同的第二comb位置,port{1002,1005}映射在相同的第三comb位置。其中,第一comb位置、第二comb位置和第三comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,n
1为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
2为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
3为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值。
可选地,n
1=2和n
2=4。
可选地,n
1=0,n
2=2和n
3=4。
在本申请实施例中,提供了SRS的端口数为6、comb结构大小为6时的CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
可选地,在所述端口数为6,且comb结构大小为8的情况下,采用CS映射方法十三,如下:
所述第一SRS的不同端口采用不同的CS,即6个port采用不同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
采用此CS映射方法十三,各端口对应的具体的CS数值如表13所示。
表13各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 1 | 2 | 3 | 4 | 5 |
初始CS 1 | 1 | 2 | 3 | 4 | 5 | 0 |
初始CS 2 | 2 | 3 | 4 | 5 | 0 | 1 |
初始CS 3 | 3 | 4 | 5 | 0 | 1 | 2 |
初始CS 4 | 4 | 5 | 0 | 1 | 2 | 3 |
初始CS 5 | 5 | 0 | 1 | 2 | 3 | 4 |
可选地,在所述端口数为6,且comb结构大小为8,采用上述CS映射方法十三的情况下,对应的Comb位置映射方法十六:
所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为8的情况下,采用CS映射方法十四,如下:
所述第一SRS的6个端口划分为3组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,即port{1000,1001}为一组,采用相同的CS;port{1002,1003}为一组,采用相同的CS;port{1004,1005}为一组,采用相同的CS。
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
采用此CS映射方法十四,各端口对应的具体的CS数值如表14所示。
表14各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 0 | 2 | 2 | 4 | 4 |
初始CS 1 | 1 | 1 | 3 | 3 | 5 | 5 |
初始CS 2 | 2 | 2 | 4 | 4 | 0 | 0 |
初始CS 3 | 3 | 3 | 5 | 5 | 1 | 1 |
初始CS 4 | 4 | 4 | 0 | 0 | 2 | 2 |
初始CS 5 | 5 | 5 | 1 | 1 | 3 | 3 |
在所述端口数为6,且comb结构大小为8,采用CS映射方法十四的情况下,对应的Comb位置映射方法十七:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,即port{1001,1003,1005}映射在相同的第一comb位置,port{1000,1002,1004}映射在相同的第二comb位置。其中,第一comb位置和第二comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为8的情况下,采用CS映射方法十 五:
所述第一SRS的6个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,即port{1000,1001,1002}为一组,采用相同的CS;port{1003,1004,1005}为一组,采用相同的CS。
所述第一SRS的各端口映射的序列的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=3。
采用此CS映射方法十五,各端口对应的具体的CS数值如表15所示。
表15各端口对应的具体的CS数值
1000 | 1001 | 1002 | 1003 | 1004 | 1005 | |
初始CS 0 | 0 | 0 | 0 | 3 | 3 | 3 |
初始CS 1 | 1 | 1 | 1 | 4 | 4 | 4 |
初始CS 2 | 2 | 2 | 2 | 5 | 5 | 5 |
初始CS 3 | 3 | 3 | 3 | 0 | 0 | 0 |
初始CS 4 | 4 | 4 | 4 | 1 | 1 | 1 |
初始CS 5 | 5 | 5 | 5 | 2 | 2 | 2 |
可选地,在所述端口数为6,且comb结构大小为8,采用CS映射方法十五的情况下,对应的Comb位置映射方法十八如下:
所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,即port{1000,1003}映射在相同的第一comb位置,port{1000,1004}映射在相同的第二comb位置,port{1002,1005}映射在相同的第三comb位置。其中,第一comb位置、第二comb位置和第三comb位置不同。
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,n
1为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终 端上报的值;n
2为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
3为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值。
可选地,n
1=3和n
2=6。
可选地,n
1=0,n
2=3和n
3=6。
在本申请实施例中,提供了SRS的端口数为6、comb结构大小为8时的CS映射方法和comb位置映射方法,可以用于提高SRS参考信号在各端口上传输的正交性,进而提高上行传输性能。
本申请实施例提供的探测参考信号的端口映射方法,执行主体可以为探测参考信号的端口映射装置。本申请实施例中以探测参考信号的端口映射装置执行探测参考信号的端口映射方法为例,说明本申请实施例提供的探测参考信号的端口映射装置。
图3为本申请实施例提供的探测参考信号的端口映射装置的结构示意图,如图3所示,该装置300包括:
第一确定单元310,在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;
其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
可选地,所述第一SRS的各端口对应的CS根据循环移位偏移值、最大循环移位偏移值、第一参数、comb结构大小、端口序号和端口数中的至少一项确定;和/或,
所述第一SRS的各端口映射的comb位置根据comb偏移值、comb结构大小、循环移位偏移值、最大循环移位偏移值、第一参数和端口序号中的至少一项确定。
可选地,在所述端口数为8,且comb结构大小为2的情况下,所述第一SRS的不同端口对应不同的CS,所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的各端口映射在相同的comb位置,所述第一SRS的各端口映射的comb位置通过如下公式计算:
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为2的情况下,所述第一SRS的8个端口划分为4组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为4的情况下,所述第一SRS的8个端口划分为4组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为4的情况下,所述第一SRS的8个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
或者,
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4,K
TC为所述comb结构大小。
可选地,所述第一SRS的8个端口划分为4组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为8的情况下,所述第一SRS的8个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4。
可选地,所述第一SRS的8个端口划分为4组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为8的情况下,所述第一SRS的8个端口均采用相同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
或者,
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=8。
可选地,所述第一SRS的不同端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第二SRS的端口与所述第一SRS的端口{1001,1004}映射到相同的comb位置,且所述第二SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加3之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第二SRS的端口与所述第一SRS的端口{1001,1004}映射到相同的comb位置,且所述第二SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加3之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第三SRS的端口与所述第一SRS的端口{1002,1005}映射到相同的comb位置,且所述第三SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加1之后对 所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第三SRS的端口与所述第一SRS的端口{1002,1005}映射到相同的comb位置,且所述第三SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加1之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第四SRS的端口与所述第一SRS的端口{1000,1003}映射到相同的comb位置,且所述第四SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加2之后对 所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第四SRS的端口与所述第一SRS的端口{1000,1003}映射到相同的comb位置,且所述第四SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加2之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为4的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于 特定循环移位偏移值,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为6的情况下,所述第一SRS的6个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=3。
可选地,所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,n
1为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
2为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
3为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值。
可选地,在所述端口数为6,且comb结构大小为8的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为8的情况下,所述第一SRS的6个端口划分为3组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为8的情况下,所述第一SRS的6个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口映射的序列的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=3。
可选地,所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,n
1为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
2为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
3为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值。
在本申请实施例中,提供了SRS的端口数为6和8时,在SRS配置为不同comb的情况下进行端口映射的解决方案,可以提高SRS参考信号在各端口上传输的正交性,从而提升上行传输的性能。
本申请实施例中的探测参考信号的端口映射装置可以是电子设备,例如具有操作***的电子设备,也可以是电子设备中的部件,例如集成电路或芯片。该电子设备可以是终端,也可以为除终端之外的其他设备。示例性的,终端可以包括但不限于上述所列举的终端11的类型,其他设备可以为服务器、网络附属存储器(Network Attached Storage,NAS)等,本申请实施例不作具体限定。
本申请实施例提供的探测参考信号的端口映射装置能够实现图2的方法实施例实现的各个过程,并达到相同的技术效果,为避免重复,这里不再赘述。
可选的,如图4所示,本申请实施例还提供一种通信设备400,包括处理器401和存储器402,存储器402上存储有可在所述处理器401上运行的程序或指令,例如,该通信设备400为终端时,该程序或指令被处理器401执行时实现上述探测参考信号的端口映射方法实施例的各个步骤,且能达到相同的技术效果。该通信设备400为网络侧设备时,该 程序或指令被处理器401执行时实现上述探测参考信号的端口映射方法实施例的各个步骤,且能达到相同的技术效果,为避免重复,这里不再赘述。
本申请实施例还提供一种终端,包括处理器和通信接口,所述处理器用于在第一探测参考信号SRS的端口数为6或8的情况下,确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置,其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。该终端实施例与上述终端侧方法实施例对应,上述方法实施例的各个实施过程和实现方式均可适用于该终端实施例中,且能达到相同的技术效果。具体地,图5为实现本申请实施例的一种终端的硬件结构示意图。
该终端500包括但不限于:射频单元501、网络模块502、音频输出单元503、输入单元504、传感器505、显示单元506、用户输入单元507、接口单元508、存储器509以及处理器510等中的至少部分部件。
本领域技术人员可以理解,终端500还可以包括给各个部件供电的电源(比如电池),电源可以通过电源管理***与处理器510逻辑相连,从而通过电源管理***实现管理充电、放电、以及功耗管理等功能。图5中示出的终端结构并不构成对终端的限定,终端可以包括比图示更多或更少的部件,或者组合某些部件,或者不同的部件布置,在此不再赘述。
应理解的是,本申请实施例中,输入单元504可以包括图形处理单元(Graphics Processing Unit,GPU)5041和麦克风5042,图形处理器5041对在视频捕获模式或图像捕获模式中由图像捕获装置(如摄像头)获得的静态图片或视频的图像数据进行处理。显示单元506可包括显示面板5061,可以采用液晶显示器、有机发光二极管等形式来配置显示面板5061。用户输入单元507包括触控面板5071以及其他输入设备5072中的至少一种。触控面板5071,也称为触摸屏。触控面板5071可包括触摸检测装置和触摸控制器两个部分。其他输入设备5072可以包括但不限于物理键盘、功能键(比如音量控制按键、开关按键等)、轨迹球、鼠标、操作杆,在此不再赘述。
本申请实施例中,射频单元501接收来自网络侧设备的下行数据后,可以传输给处理器510进行处理;另外,射频单元501可以向网络侧设备发送上行数据。通常,射频单元x01包括但不限于天线、放大器、收发信机、耦合器、低噪声放大器、双工器等。
存储器509可用于存储软件程序或指令以及各种数据。存储器509可主要包括存储程序或指令的第一存储区和存储数据的第二存储区,其中,第一存储区可存储操作***、至少一个功能所需的应用程序或指令(比如声音播放功能、图像播放功能等)等。此外,存储器509可以包括易失性存储器或非易失性存储器,或者,存储器509可以包括易失性和非易失性存储器两者。其中,非易失性存储器可以是只读存储器(Read-Only Memory,ROM)、可编程只读存储器(Programmable ROM,PROM)、可擦除可编程只读存储器(Erasable PROM,EPROM)、电可擦除可编程只读存储器(Electrically EPROM,EEPROM)或闪存。易失性存储器可以是随机存取存储器(Random Access Memory,RAM),静态随机存取存储器(Static RAM,SRAM)、动态随机存取存储器(Dynamic RAM,DRAM)、同步动态随机存取存储器 (Synchronous DRAM,SDRAM)、双倍数据速率同步动态随机存取存储器(Double Data Rate SDRAM,DDRSDRAM)、增强型同步动态随机存取存储器(Enhanced SDRAM,ESDRAM)、同步连接动态随机存取存储器(Synch link DRAM,SLDRAM)和直接内存总线随机存取存储器(Direct Rambus RAM,DRRAM)。本申请实施例中的存储器509包括但不限于这些和任意其它适合类型的存储器。
处理器510可包括一个或多个处理单元;可选的,处理器510集成应用处理器和调制解调处理器,其中,应用处理器主要处理涉及操作***、用户界面和应用程序等的操作,调制解调处理器主要处理无线通信信号,如基带处理器。可以理解的是,上述调制解调处理器也可以不集成到处理器510中。
其中,处理器510,用于在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
可选地,所述第一SRS的各端口对应的CS根据循环移位偏移值、最大循环移位偏移值、第一参数、comb结构大小、端口序号和端口数中的至少一项确定;和/或,
所述第一SRS的各端口映射的comb位置根据comb偏移值、comb结构大小、循环移位偏移值、最大循环移位偏移值、第一参数和端口序号中的至少一项确定。
可选地,在所述端口数为8,且comb结构大小为2的情况下,所述第一SRS的不同端口对应不同的CS,所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的各端口映射在相同的comb位置,所述第一SRS的各端口映射的comb位置通过如下公式计算:
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为2的情况下,所述第一SRS的8个端口划分为4组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为8,且comb结构大小为4的情况下,所述第一SRS的8个端口划分为4组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环 移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
可选地,所述第一SRS的8个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为4的情况下,所述第一SRS的8个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
或者,
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4,K
TC为所述comb结构大小。
可选地,所述第一SRS的8个端口划分为4组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为8的情况下,所述第一SRS的8个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=4。
可选地,所述第一SRS的8个端口划分为4组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
可选地,在所述端口数为8,且comb结构大小为8的情况下,所述第一SRS的8个端口均采用相同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
或者,
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=8。
可选地,所述第一SRS的不同端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
或者,
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第二SRS的端口与所述第一SRS的端口{1001,1004}映射到相同的comb位置,且所述第二SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加3之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第二SRS的端口与所述第一SRS的端口{1001,1004}映射到相同的comb位置,且所述第二SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加3之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第三SRS的端口与所述第一SRS的端口{1002,1005}映射到相同的comb位置,且所述第三SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加1之后对 所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第三SRS的端口与所述第一SRS的端口{1002,1005}映射到相同的comb位置,且所述第三SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加1之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第四SRS的端口与所述第一SRS的端口{1000,1003}映射到相同的comb位置,且所述第四SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加2之后对 所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述第一SRS的各端口映射的comb位置,通过如下公式计算的情况下:
第四SRS的端口与所述第一SRS的端口{1000,1003}映射到相同的comb位置,且所述第四SRS对应的循环移位偏移值等于所述第一SRS对应的循环移位偏移值加2之后对所述第一SRS对应的最大循环移位偏移值进行求余得到的值。
可选地,在所述端口数为6,且comb结构大小为2的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为4的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于 特定循环移位偏移值,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为6的情况下,所述第一SRS的6个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=3。
可选地,所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,n
1为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
2为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
3为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值。
可选地,在所述端口数为6,且comb结构大小为8的情况下,所述第一SRS的不同端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
可选地,所述第一SRS的各端口映射的comb位置与所述循环移位偏移值相关,对于特定循环移位偏移值,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为8的情况下,所述第一SRS的6个端口划分为3组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口对应的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=2。
可选地,所述第一SRS的6个端口划分为2组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
可选地,在所述端口数为6,且comb结构大小为8的情况下,所述第一SRS的6个端口划分为2组,且同一组内的端口采用相同的CS,不同组的端口采用不同的CS,
所述第一SRS的各端口映射的序列的CS通过如下公式计算:
其中,
为端口i对应的CS,
为所述循环移位偏移值,
为所述最大循环移位偏移值,p
i为端口序号,
为端口数,x为所述第一参数,x为网络侧设备和终端默认约定的数值和/或由网络侧设备指示的数值和/或由终端上报的数值,x=3。
可选地,所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,
所述第一SRS的各端口映射的comb位置,通过如下公式计算:
或者,
其中,
为端口i映射的comb位置,
为所述comb偏移值,K
TC为所述comb结构大小,n
1为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
2为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值;n
3为网络侧设备和终端默认约定的值,和/或为网络侧设备指示的值,和/或为由终端上报的值。
在本申请实施例中,提供了SRS的端口数为6和8时,在SRS配置为不同comb的情况下进行端口映射的解决方案,可以提高SRS参考信号在各端口上传输的正交性,从而提升上行传输的性能。
本申请实施例还提供一种可读存储介质,所述可读存储介质上存储有程序或指令,该程序或指令被处理器执行时实现上述探测参考信号的端口映射方法实施例的各个过程,且能达到相同的技术效果,为避免重复,这里不再赘述。
其中,所述处理器为上述实施例中所述的终端中的处理器。所述可读存储介质,包括计算机可读存储介质,如计算机只读存储器ROM、随机存取存储器RAM、磁碟或者光盘等。
本申请实施例另提供了一种芯片,所述芯片包括处理器和通信接口,所述通信接口和所述处理器耦合,所述处理器用于运行程序或指令,实现上述探测参考信号的端口映射方法实施例的各个过程,且能达到相同的技术效果,为避免重复,这里不再赘述。
应理解,本申请实施例提到的芯片还可以称为***级芯片,***芯片,芯片***或片上***芯片等。
本申请实施例另提供了一种计算机程序/程序产品,所述计算机程序/程序产品被存储在存储介质中,所述计算机程序/程序产品被至少一个处理器执行以实现上述探测参考信号的端口映射方法实施例的各个过程,且能达到相同的技术效果,为避免重复,这里不再赘述。
本申请实施例还提供了一种通信***,包括:终端及网络侧设备,所述终端可用于执行如上所述的探测参考信号的端口映射方法的步骤。
需要说明的是,在本文中,术语“包括”、“包含”或者其任何其他变体意在涵盖非排他性的包含,从而使得包括一系列要素的过程、方法、物品或者装置不仅包括那些要素,而且还包括没有明确列出的其他要素,或者是还包括为这种过程、方法、物品或者装置所固有的要素。在没有更多限制的情况下,由语句“包括一个……”限定的要素,并不排除在包括该要素的过程、方法、物品或者装置中还存在另外的相同要素。此外,需要指出的是,本申请实施方式中的方法和装置的范围不限按示出或讨论的顺序来执行功能,还可包括根据所涉及的功能按基本同时的方式或按相反的顺序来执行功能,例如,可以按不同于所描述的次序来执行所描述的方法,并且还可以添加、省去、或组合各种步骤。另外,参照某些示例所描述的特征可在其他示例中被组合。
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到上述实施例方法可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件,但很多情况下前者是更佳的实施方式。基于这样的理解,本申请的技术方案本质上或者说对现有技术做出贡献的部分可以以计算机软件产品的形式体现出来,该计算机软件产品存储在一个存储介质(如ROM/RAM、磁碟、光盘)中,包括若干指令用以使得一台终端(可以是手机,计算机,服务器,空调器,或者网络设备等)执行本申请各个实施例所述的方法。
上面结合附图对本申请的实施例进行了描述,但是本申请并不局限于上述的具体实施方式,上述的具体实施方式仅仅是示意性的,而不是限制性的,本领域的普通技术人员在本申请的启示下,在不脱离本申请宗旨和权利要求所保护的范围情况下,还可做出很多形式,均属于本申请的保护之内。
Claims (44)
- 一种探测参考信号的端口映射方法,包括:在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
- 根据权利要求1所述的探测参考信号的端口映射方法,其中,所述第一SRS的各端口对应的CS根据循环移位偏移值、最大循环移位偏移值、第一参数、comb结构大小、端口序号和端口数中的至少一项确定;和/或,所述第一SRS的各端口映射的comb位置根据comb偏移值、comb结构大小、循环移位偏移值、最大循环移位偏移值、第一参数和端口序号中的至少一项确定。
- 根据权利要求34所述的探测参考信号的端口映射方法,其中,所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:或者,
- 根据权利要求40所述的探测参考信号的端口映射方法,其中,所述第一SRS的6个端口划分为3组,且同一组内的端口映射的comb位置相同,不同组的端口映射到不同的comb位置,所述第一SRS的各端口映射的comb位置,通过如下公式计算:或者,
- 一种探测参考信号的端口映射装置,包括:第一确定单元,用于在第一探测参考信号SRS的端口数为6或8的情况下,终端确定所述第一SRS的各端口对应的循环移位CS和/或所述第一SRS的各端口映射的梳状comb位置;其中,所述第一SRS的comb结构大小为N,N为2,4,6或8。
- 一种终端,包括处理器和存储器,所述存储器存储可在所述处理器上运行的程序或指令,所述程序或指令被所述处理器执行时实现如权利要求1至41任一项所述的探测参考信号的端口映射方法的步骤。
- 一种可读存储介质,所述可读存储介质上存储程序或指令,所述程序或指令被处理器执行时实现如权利要求1至41任一项所述的探测参考信号的端口映射方法。
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CN (1) | CN116455536A (zh) |
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Citations (4)
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CN109391395A (zh) * | 2017-08-09 | 2019-02-26 | 索尼公司 | 无线通信***中的装置和方法、计算机可读存储介质 |
CN110168954A (zh) * | 2017-01-09 | 2019-08-23 | 高通股份有限公司 | 在新无线电中发送经复用的探测参考信号端口 |
CN111835488A (zh) * | 2019-08-15 | 2020-10-27 | 维沃移动通信有限公司 | 一种确定天线端口映射方法和终端 |
US20210112498A1 (en) * | 2019-10-09 | 2021-04-15 | Qualcomm Incorporated | Srs antenna switching for multiple receive antennas |
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2022
- 2022-01-07 CN CN202210016659.0A patent/CN116455536A/zh active Pending
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- 2023-01-06 WO PCT/CN2023/071093 patent/WO2023131316A1/zh unknown
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN110168954A (zh) * | 2017-01-09 | 2019-08-23 | 高通股份有限公司 | 在新无线电中发送经复用的探测参考信号端口 |
CN109391395A (zh) * | 2017-08-09 | 2019-02-26 | 索尼公司 | 无线通信***中的装置和方法、计算机可读存储介质 |
CN111835488A (zh) * | 2019-08-15 | 2020-10-27 | 维沃移动通信有限公司 | 一种确定天线端口映射方法和终端 |
US20210112498A1 (en) * | 2019-10-09 | 2021-04-15 | Qualcomm Incorporated | Srs antenna switching for multiple receive antennas |
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