WO2021030954A1 - 传输模式确定方法及装置 - Google Patents
传输模式确定方法及装置 Download PDFInfo
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- H04W80/00—Wireless network protocols or protocol adaptations to wireless operation
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- H04L1/0002—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate
- H04L1/0003—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate by switching between different modulation schemes
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- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
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Definitions
- the embodiments of the present application relate to the field of communication technologies, and in particular to a method and device for determining a transmission mode.
- 5 th -generation communication system or a new air interface (new radio, NR)
- 5G system comprising three scenarios, respectively, moving Enhanced Bandwidth (enhanced mobile broadband, eMBB), ultra reality and low latency communication (uRLLC), and massive machine type communications (mMTC).
- eMBB enhanced mobile broadband
- uRLLC ultra reality and low latency communication
- mMTC massive machine type communications
- repeated transmission is used in uRLLC scenarios to improve the robustness of transmission.
- the repeated transmission may be one or more of repeated transmission in the space domain, repeated transmission in the frequency domain, or repeated transmission in the time domain.
- Repetitive transmission in the spatial domain namely spatial domain multiplexing (SDM) corresponds to one transmission mode; repetitive transmission in the frequency domain is (frequency domain multiplexing, FDM), corresponding to two transmission modes; repetition in the time domain Transmission is (time domain multiplexing, TDM), corresponding to two transmission modes.
- SDM spatial domain multiplexing
- FDM frequency domain multiplexing
- TDM time domain multiplexing
- the embodiments of the present application provide a method and device for determining a transmission mode, which can identify the transmission mode adopted by the network side, so that the terminal side can perform reception processing according to the transmission mode.
- the first aspect of the embodiments of the present application provides a method for determining a transmission mode, including:
- the configuration indication information is one or more of modulation reference signal (demodulation reference signal, DMRS) indication information, repeated transmission indication information, or transmission configuration indication information;
- DMRS modulation reference signal
- the transmission mode is determined according to the configuration instruction information, and the transmission mode is one or more of space division multiplexing mode, frequency division multiplexing mode, or time division multiplexing mode.
- the method provided in the first aspect of the embodiments of the present application may be executed by a terminal device, or may be executed by a component of the terminal device (for example, a processor, a chip, or a chip system, etc.).
- the terminal device recognizes the transmission mode adopted by the network device according to the configuration instruction information, and then the terminal device can perform corresponding receiving processing according to the transmission mode.
- the DMRS indication information may be used to indicate the DMRS port identifier, and may also be used to indicate the DMRS port identifier and the number of code division multiplexing (CDM) groups that do not carry data.
- CDM code division multiplexing
- the DMRS indication information in the embodiment of the present application may also be described as antenna port indication information.
- the repeated transmission indication information is used to indicate the time domain repeated transmission parameter, or used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter, or used to indicate the time domain repeated transmission parameter and the frequency domain repeated transmission parameter, or Used to indicate the frequency domain repeated transmission parameter, the first time domain repeated transmission parameter, and the second time domain repeated transmission parameter.
- the transmission configuration indication (transmission configuration indication, TCI) information is used to indicate the TCI status of the transmission process.
- the TCI information may be a TCI codepoint (codepoint). In the case of multi-station transmission, a TCI codepoint may indicate two or more TCI states.
- the foregoing configuration indication information is repeated transmission indication information, and the repeated transmission indication information is used to indicate the time domain repeated transmission parameters.
- the terminal device obtains the configuration indication information, it obtains the time domain repeated transmission parameter, and determines the transmission mode to be the time division multiplexing mode according to the time domain repeated transmission parameter. In this manner, it is recognized that the transmission mode is the time division multiplexing mode through the acquired time domain repeated transmission parameters.
- the terminal device does not obtain the configuration information, that is, the time domain repeated transmission parameters are not obtained, it is determined that the transmission mode cannot be the time division multiplexing mode, that is, it may be the frequency division multiplexing mode or space division multiplexing mode. Or any of the combined modes of frequency division multiplexing mode and space division multiplexing mode.
- the transmission mode when the transmission mode is identified as the time division multiplexing mode through the time domain repeated transmission parameters, it can be further distinguished whether the time division multiplexing mode is the first time division multiplexing mode or the second time division multiplexing mode. mode.
- the first time division multiplexing mode is a time division multiplexing mode within a time slot unit
- the second time division multiplexing mode is a time division multiplexing mode between time slot units.
- the time division multiplexing mode can be determined to be the first time division multiplexing mode; if the time domain repeated transmission parameter is the second time domain repeated transmission parameter, then the time division can be determined
- the multiplexing mode is the second time division multiplexing mode.
- the time domain repeated transmission parameters include the unique parameters of the first time division multiplexing mode, then it can be determined that the time division multiplexing mode is the first time division multiplexing mode.
- the time domain repeated transmission parameters include offset information (offset), then the time division multiplexing mode can be determined to be the first time division multiplexing mode; otherwise, the time division multiplexing mode can be determined to be the second time division multiplexing mode.
- the offset information may indicate the offset information of the time domain positions of multiple physical downlink shared channels (physical downlink shared channels, PDSCH).
- the foregoing configuration indication information is repeated transmission indication information
- the repeated transmission indication information is used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter.
- the terminal device obtains the configuration instruction information, it obtains the first time-domain repeated transmission parameter and the second time-domain repeated transmission parameter, according to the values of the first time-domain repeated transmission parameter and the second time-domain repeated transmission parameter To determine whether the transmission mode is time division multiplexing mode. If the terminal device does not obtain the configuration information, that is, the first time domain repetitive transmission parameter and the second time domain repetitive transmission parameter are not obtained, the transmission mode is determined to be frequency division multiplexing mode, space division multiplexing mode or frequency division multiplexing mode. Combination mode of multiplexing mode and space division multiplexing mode.
- the transmission mode is the time division multiplexing mode according to the values of the first time domain repeated transmission parameter and the second time domain repeated transmission parameter, which may include: if the first time domain repeated transmission parameter and the second time domain repeated transmission parameter have values Both are the first preset values, then it is determined that the transmission mode is frequency division multiplexing mode, space division multiplexing mode, or a combined mode of frequency division multiplexing mode and space division multiplexing mode; if the value of the first time domain repeated transmission parameter Or one or more of the values of the second time domain repeated transmission parameters are greater than the first preset value, and it is determined that the transmission mode is the time division multiplexing mode.
- the first preset value may be "1".
- the first time division multiplexing mode and the second time domain repeated transmission parameter can be further distinguished.
- the second time division multiplexing mode is a time division multiplexing mode within a time slot unit, and the second time division multiplexing mode is a time division multiplexing mode between time slot units.
- the time division multiplexing mode is the second time division multiplexing mode;
- the value of the time domain repeated transmission parameter is the first preset value, and the value of the first time domain repeated transmission parameter is greater than the first preset value, then it is determined that the time division multiplexing mode is the first time division multiplexing mode; if the first time domain The value of the repeated transmission parameter and the value of the second time-domain repeated transmission parameter are both greater than the first preset value, then it is determined that the time division multiplexing mode is a combined mode of the first time division multiplexing mode and the second time division multiplexing mode.
- the space division multiplexing mode and the frequency division multiplexing mode can be distinguished according to the configuration indication information as the DMRS indication information.
- the DMRS port identifier is determined according to the DMRS indication information, and the transmission mode is determined according to the DMRS port identifier.
- Method 1 If the number of CDM groups corresponding to the DMRS port identifier is the second preset value, then the transmission mode is determined to be the frequency division multiplexing mode; if the number of CDM groups corresponding to the DMRS port identifier is the third preset value, then determine The transmission mode is space division multiplexing mode.
- the second preset value may be 1, which means 1 CDM group.
- Method 2 If the DMRS port identifier belongs to the same CDM group, then the transmission mode is determined to be the frequency division multiplexing mode; otherwise, the transmission mode is determined to be the space division multiplexing mode.
- the transmission mode is determined to be the frequency division multiplexing mode; otherwise, the transmission mode is determined to be the space division multiplexing mode.
- the second preset value may be 1, which means 1 CDM group; the third preset value may be 2, which means 2 CDM groups.
- Method 4 If the DMRS port identifier belongs to the preset identifier, then the transmission mode is determined to be the frequency division multiplexing mode; otherwise, the transmission mode is determined to be the space division multiplexing mode.
- the preset identifier can be [0], [1] or [0,1].
- the number of CDM groups is determined according to the DMRS indication information, and the transmission mode is determined according to the number of CDM groups. If the number of CDM groups is the second preset value, the transmission mode is determined to be the frequency division multiplexing mode; if the number of CDM groups is the third preset value, then the transmission mode is determined to be the space division multiplexing mode.
- the frequency division multiplexing mode when it is determined that the transmission mode is the frequency division multiplexing mode, it can be further distinguished whether the frequency division multiplexing mode is the first frequency division multiplexing mode or the second frequency division multiplexing mode.
- the first frequency division multiplexing mode is a frequency division multiplexing mode based on a single codeword
- the second frequency division multiplexing mode is a frequency division multiplexing mode based on multiple codewords.
- the frequency division multiplexing mode is determined to be the second frequency division multiplexing mode; if the frequency domain repetitive transmission parameters are not obtained, then the frequency division multiplexing mode is determined to be the first frequency division multiplexing mode .
- the foregoing configuration indication information is repeated transmission indication information
- the repeated transmission indication information is used to indicate the time domain repeated transmission parameters.
- the transmission mode is determined to be the second time division multiplexing mode according to the time domain repeated transmission parameters, and the second time division multiplexing mode is the time division multiplexing mode between time slot units.
- the other transmission modes may be distinguished according to the configuration indication information as the DMRS indication information.
- the DMRS port information is determined according to the DMRS indication information, and the remaining transmission modes are determined according to the DMRS port information.
- the DMRS port information includes the DMRS port identifier and the number of CDM groups that do not carry data. According to the number of CDM groups corresponding to the DMRS port identifier and the number of CDM groups that do not carry data, the transmission mode is determined to be Space division multiplexing mode, frequency division multiplexing mode or first time division multiplexing mode; if it is determined that the transmission mode is frequency division multiplexing mode, the transmission mode is determined to be the first frequency according to the group ID of the CDM group corresponding to the DMRS port ID Division multiplexing mode or second frequency division multiplexing mode.
- the first time division multiplexing mode is the time division multiplexing mode in the time slot unit
- the first frequency division multiplexing mode is the frequency division multiplexing mode based on a single codeword
- the second frequency division multiplexing mode is based on the multicode The frequency division multiplexing mode of the word.
- the transmission mode is determined to be the space division multiplexing mode; if the number of CDM groups corresponding to the DMRS port identifier is the second preset value, no The number of CDM groups carrying data is the second preset value, then it is determined that the transmission mode is the first time division multiplexing mode, and the first time division multiplexing mode is the time division multiplexing mode in the time slot unit; if the DMRS port identifier corresponds If the number of CDM port groups is the second preset value, and the number of DMRS CDM groups is the third preset value, it is determined that the transmission mode is the frequency division multiplexing mode.
- the transmission mode is determined to be the first frequency division multiplexing mode; if the DMRS port identifier corresponds to If the group identifier of the CDM group is the second identifier, it is determined that the transmission mode is the second frequency division multiplexing mode.
- the above configuration indication information is DMRS indication information and repeated transmission indication information
- the repeated transmission indication information is used to indicate the frequency domain repeated transmission parameters, the first time domain repeated transmission parameters, and the second time domain repeated transmission parameter.
- the repeated transmission indication information can be represented by ⁇ a, b, c ⁇ , for example, a represents a frequency domain repeated transmission parameter, b represents a first time domain repeated transmission parameter, and c represents a second time domain repeated transmission parameter.
- the number of CDM groups is determined according to the DMRS indication information, and the transmission mode is determined according to the number of CDM groups, frequency domain repeated transmission parameters, first time domain repeated transmission parameters, and second time domain repeated transmission parameters. For example, if the number of CDM groups is determined to be two according to the DMRS indication information, and the repeated transmission indication information is ⁇ 1,1,1 ⁇ , then it can be determined that the transmission mode is the space division multiplexing mode.
- the foregoing configuration indication information is TCI information
- the TCI information is used to indicate the TCI state. If the number of TCI states is the fourth preset value, then it can be determined that the transmission mode is frequency division multiplexing mode or space division multiplexing mode; if the number of TCI states is greater than the fourth preset value, then it can be determined that the transmission mode is time division multiplexing Use mode.
- the fourth preset value may be 2, which represents 2 TCI states.
- the above configuration indication information is TCI information and repeated transmission indication information.
- the TCI information is used to indicate the TCI status
- the repeated transmission indication information is used to indicate the time domain repeated transmission parameters, according to the number and time of the TCI status.
- the domain repeats the transmission parameters and determines that the transmission mode is the time division multiplexing mode.
- a second aspect of the embodiments of the present application provides a method for determining a transmission mode, including:
- obtaining transmission mode indication information where the transmission mode indication information is used to indicate the transmission mode
- the transmission mode is determined according to the transmission mode indication information.
- the method provided in the second aspect of the embodiments of the present application may be executed by a terminal device, or may be executed by a component of the terminal device (for example, a processor, a chip, or a chip system, etc.).
- a component of the terminal device for example, a processor, a chip, or a chip system, etc.
- the configuration information can be understood as the configuration information indicating the uRLLC scenario, thereby distinguishing the multi-site uRLLC scenario from the multi-site eMBB scenario.
- the configuration information can be used to indicate the exclusive characteristics of the multi-site uRLLC scenario, for example, to indicate that the terminal device can use a bit rate lower than a preset bit rate, or to instruct the terminal device to use a preset bit rate.
- Modulation coding strategy table The preset code rate may be 120*1024 (kbps), and the preset modulation and coding strategy table may be the modulation and coding strategy table 3, and only a code rate lower than 120*1024 (kbps) exists in Table 3.
- the configuration information may be a newly defined radio network temporary identity (RNTI) or a newly defined downlink control information (downlink control information, DCI) domain.
- RNTI radio network temporary identity
- DCI downlink control information
- the configuration information can reuse the configuration information related to the existing multi-site uRLLC scenario, such as modulation and coding strategy cell radio network temporary identity (MCS-C-TNTI) ).
- MCS-C-TNTI modulation and coding strategy cell radio network temporary identity
- the configuration information can be used to directly indicate that the current transmission scene is a multi-site uRLLC scene.
- the terminal device detects the configuration information, the current transmission scene can be considered as a multi-site uRLLC scene, otherwise it can be considered
- the current transmission scene is a multi-station eMBB scene.
- the configuration information may be a newly defined RNTI or a domain in the newly defined DCI.
- the configuration information can be understood as the configuration information indicating the eMBB scene, for example indicating the exclusive characteristics of the multi-site eMBB scene, or multiplexing the configuration information related to the existing multi-site eMBB scene, or the configuration information can be used for Directly indicate that the current transmission scene is a multi-station eMBB scene.
- the transmission mode indication information can be carried in downlink control information or carried in radio resource control signaling.
- the transmission mode is one or more of space division multiplexing transmission mode, first frequency division multiplexing transmission mode, second frequency division multiplexing transmission mode, first time division multiplexing transmission mode or second time division multiplexing transmission mode Among them, the first frequency division multiplexing mode is based on a single codeword frequency division multiplexing mode, the second frequency division multiplexing mode is based on multiple codeword frequency division multiplexing mode; the first time division multiplexing mode is The time division multiplexing mode in the time slot unit, the second time division multiplexing mode is the time division multiplexing mode between time slot units.
- a third aspect of the embodiments of the present application provides a communication device.
- the communication device may be a terminal device, a device in a terminal device, or a device that can be used in combination with the terminal device.
- the communication device can implement part or all of the functions of the terminal device in the method example of the first aspect or the second aspect.
- the function of the terminal device may have some or all of the functions in the embodiments of the present application, or may have The functions of any of the embodiments in this application are implemented separately. This function can be realized by hardware, or by hardware executing corresponding software.
- the hardware or software includes one or more units or modules corresponding to the above-mentioned functions.
- the structure of the terminal device may include a processing unit and a transceiver unit.
- the processing unit is configured to support the terminal device to perform the corresponding function in the above method.
- the transceiver unit is used to support communication between the terminal device and other devices.
- the terminal device may also include a storage unit, which is used for coupling with the processing unit and the transceiver unit, and stores necessary program instructions and data for the terminal device.
- the terminal device includes a processing unit and a transceiver unit;
- the transceiver unit is configured to obtain configuration indication information, where the configuration indication information is one or more of DMRS indication information, repeated transmission indication information, or transmission configuration indication information;
- the processing unit is configured to determine a transmission mode according to the configuration instruction information, and the transmission mode is one or more of space division multiplexing mode, frequency division multiplexing mode or time division multiplexing mode.
- the processing unit may be a processor
- the communication unit may be a transceiver
- the storage unit may be a memory
- the terminal device includes a processing unit and a transceiver unit;
- a transceiver configured to obtain configuration indication information, where the configuration indication information is one or more of DMRS indication information, repeated transmission indication information, or transmission configuration indication information;
- the processor is configured to determine the transmission mode according to the configuration instruction information, and the transmission mode is one or more of space division multiplexing mode, frequency division multiplexing mode, or time division multiplexing mode.
- the processor can be used to perform, for example, but not limited to, baseband related processing
- the transceiver can be used to perform, for example, but not limited to, radio frequency transceiving.
- the above-mentioned devices may be respectively arranged on independent chips, or at least partly or fully arranged on the same chip.
- the processor can be further divided into an analog baseband processor and a digital baseband processor.
- the analog baseband processor can be integrated with the transceiver on the same chip, and the digital baseband processor can be set on a separate chip. With the continuous development of integrated circuit technology, more and more devices can be integrated on the same chip.
- a digital baseband processor can be combined with a variety of application processors (such as but not limited to graphics processors, multimedia processors, etc.) Integrated on the same chip.
- application processors such as but not limited to graphics processors, multimedia processors, etc.
- Such a chip can be called a system on chip. Whether each device is independently arranged on different chips or integrated on one or more chips often depends on the specific needs of product design. The embodiment of the present invention does not limit the specific implementation form of the foregoing device.
- a fourth aspect of the embodiments of the present application provides a processor, configured to execute the foregoing various methods.
- the process of sending the above information or data and receiving the above information or data in the above methods can be understood as the process of outputting the above information or data by the processor, and the processor receiving the above information or data input. the process of.
- the processor when outputting the above information or data, the processor outputs the above information or data to the transceiver for transmission by the transceiver.
- other processing may be required before it reaches the transceiver.
- the transceiver receives the aforementioned information or data and inputs it into the processor. Furthermore, after the transceiver receives the above information or data, the above information or data may need to undergo other processing before being input to the processor.
- the acquisition of configuration information mentioned in the foregoing method can be understood as the transceiver inputting the received configuration information into the processor.
- the processor outputs and receives, inputs and other operations, instead of transmitting, sending and receiving directly by the radio frequency circuit and antenna.
- the foregoing processor may be a processor dedicated to executing these methods, or a processor that executes computer instructions in a memory to execute these methods, such as a general-purpose processor.
- the above-mentioned memory may be a non-transitory memory, such as a read only memory (ROM), which may be integrated with the processor on the same chip, or may be arranged on different chips.
- ROM read only memory
- the present invention The embodiment does not limit the type of the memory and the setting mode of the memory and the processor.
- a fifth aspect of the embodiments of the present application provides a chip system, which includes at least one processor and an interface, and is used to support a terminal device to implement the functions involved in the first aspect or the second aspect, for example, determine a transmission mode according to configuration instruction information .
- the chip system also includes a memory, which is used to store necessary program instructions and data for the terminal device.
- the chip system may be composed of chips, or may include chips and other discrete devices.
- the sixth aspect of the embodiments of the present application provides a computer-readable storage medium for storing computer software instructions used by the above-mentioned terminal device, which includes a program for executing the first aspect or the second aspect of the above-mentioned method.
- the seventh aspect of the embodiments of the present application provides a computer program product including instructions, which when run on a computer, causes the computer to execute the method described in the first aspect or the second aspect.
- the eighth aspect of the embodiments of the present application provides a computer program including instructions, which when run on a computer, causes the computer to execute the method described in the first aspect or the second aspect.
- Figure 1 is a schematic diagram of a network architecture to which an embodiment of the present application is applied;
- Figure 2 is a schematic diagram of another network architecture to which an embodiment of the present application is applied;
- Figure 3a is a transmission example diagram of space division multiplexing mode
- Figure 3b is a simplified schematic diagram of the physical layer processing flow in the space division multiplexing mode
- Figure 4a is a diagram of a transmission example in a frequency division multiplexing mode
- 4b is a simplified schematic diagram of the physical layer processing flow of the first frequency division multiplexing mode
- 4c is a simplified schematic diagram of the physical layer processing flow of the first frequency division multiplexing mode
- Figure 5a is a diagram of an example of transmission in the first time division multiplexing mode
- Figure 5b is a diagram of an example of transmission in the second time division multiplexing mode
- Figure 5c is a simplified schematic diagram of a physical layer processing flow in a time division multiplexing mode
- FIG. 6 is a schematic flowchart of a method for determining a transmission mode according to an embodiment of the application
- FIG. 7 is a schematic flowchart of another method for determining a transmission mode according to an embodiment of the application.
- FIG. 8 is a schematic structural diagram of a communication device provided by an embodiment of this application.
- FIG. 9 is a schematic structural diagram of a terminal device provided by an embodiment of the application.
- a, b, or c can mean: a, b, c, a and b, a and c, b and c, or a and b and c, where a, b, c can be single or multiple.
- words such as “first” and “second” are used to distinguish technical features that have substantially the same or similar functions and functions. Those skilled in the art can understand that words such as “first” and “second” do not limit the quantity and order of execution, and words such as “first” and “second” do not limit the difference.
- the embodiments of the present application can be applied to Long Term Evolution (LTE) systems, NR systems, and can also be applied to future communication systems, such as future networks or sixth-generation communication systems.
- LTE Long Term Evolution
- NR NR systems
- future communication systems such as future networks or sixth-generation communication systems.
- the embodiments of the present application can be applied to a device to device (D2D) system, a machine to machine (M2M) system, a vehicle to everything (V2X) system in which vehicles communicate with everything, etc.
- D2D device to device
- M2M machine to machine
- V2X vehicle to everything
- V2X communication The communication methods in the V2X system are collectively referred to as V2X communication.
- V2X communication is aimed at high-speed devices represented by vehicles. It is the basic technology and key technology applied in scenarios with very high communication delay requirements in the future, such as smart cars, autonomous driving, and intelligent transportation systems.
- the V2X communication includes: vehicle-to-vehicle (V2V) communication, vehicle to roadside infrastructure (vehicle to infrastructure, V2I) communication, vehicle to pedestrian communication (vehicle to vehicle, V2V) pedestrian, V2P) or vehicle-to-network (V2N) communication, etc.
- V2V vehicle-to-vehicle
- V2V vehicle to roadside infrastructure
- V2I vehicle to pedestrian communication
- V2N vehicle-to-network
- the communication between the terminal devices involved in the V2X system is widely referred to as slide link (SL) communication.
- the terminal described in this application may also be a vehicle or a vehicle component applied to a vehicle.
- Fig. 1 is a schematic diagram of a V2X system provided by an embodiment of the present application.
- the diagram includes V2V communication, V2P communication, and V2I/N communication.
- vehicles or vehicle components communicate through V2V.
- Vehicles or vehicle components can broadcast their own speed, driving direction, specific location, whether emergency brakes are stepped on, and other information to surrounding vehicles.
- Drivers of surrounding vehicles can better perceive traffic conditions outside the line of sight by obtaining such information , So as to make advance judgments of dangerous situations and make avoidance;
- vehicles or vehicle components communicate with roadside infrastructure through V2I, and roadside infrastructure can provide various types of service information and data network access for vehicles or vehicle components .
- non-stop charging, in-car entertainment and other functions have greatly improved traffic intelligence.
- Roadside infrastructure for example, roadside unit (RSU) includes two types: one is a terminal device type RSU.
- the RSU of this terminal equipment type Since the RSU is distributed on the roadside, the RSU of this terminal equipment type is in a non-mobile state, and there is no need to consider mobility; the other is the RSU of the network equipment type.
- the RSU of this network device type can provide timing synchronization and resource scheduling for vehicles or vehicle components communicating with network devices. Vehicles or vehicle components communicate with people through V2P; vehicles or vehicle components communicate with the network through V2N.
- V2P vehicles or vehicle components communicate with the network through V2N.
- the network architecture and business scenarios described in the embodiments disclosed in this application are intended to more clearly illustrate the technical solutions of the embodiments disclosed in this application, and do not constitute a limitation on the technical solutions provided in the embodiments disclosed in this application. Ordinary technicians can know that with the evolution of network architecture and the emergence of new business scenarios, the technical solutions provided by the embodiments disclosed in this application are equally applicable to similar technical problems.
- FIG. 2 is a schematic diagram of another network architecture to which an embodiment of the present application is applied.
- the network architecture may include three network devices and one terminal device.
- the number and form of the devices shown in FIG. 2 are used as examples and do not constitute a limitation to the embodiment of this application.
- Actual applications may include one, two or more networks.
- the network device can be used to communicate with the terminal device through a wireless interface under the control of a network device controller (not shown).
- the network device controller may be a part of the core network, or it may be integrated into the network device.
- the network device can be used to transmit control information or user data to the core network through a backhaul interface.
- Network devices can also communicate with each other directly or indirectly through backhaul interfaces.
- the network device may be any device with wireless transceiver function. Including but not limited to: the base station in the LTE system or the base station (gNodeB or gNB) in the NR system or the transmission receiving point/transmission reception point (TRP) in the NR system, the base station of the subsequent evolution of 3GPP, and the WiFi system
- the base station can be: a macro base station, a micro base station, a pico base station, a small station, a relay station, or a balloon station, etc. Multiple base stations can support networks of the same technology mentioned above, or networks of different technologies mentioned above.
- the base station can contain one or more co-site or non-co-site TRPs.
- TRP can be a network device such as a base station, or an antenna panel or panel of the base station.
- the network device may also be a wireless controller, a centralized unit (CU), and/or a distributed unit (DU) in a cloud radio access network (cloud radio access network, CRAN) scenario.
- the network device can also be a server, a wearable device, or a vehicle-mounted device.
- the following description takes the network device as a base station as an example.
- the multiple network devices may be base stations of the same type, or base stations of different types.
- the base station can communicate with the terminal equipment, and it can also communicate with the terminal equipment through the relay station.
- a terminal device is a device with wireless transceiver function, which can be deployed on land, including indoor or outdoor, handheld, wearable or vehicle-mounted; it can also be deployed on the water (such as ships, etc.); it can also be deployed in the air (such as airplanes, Balloons and satellites are classy).
- the terminal device may be a mobile phone (mobile phone), a tablet computer (Pad), a computer with wireless transceiver function, virtual reality (VR) terminal equipment, augmented reality (AR) terminal equipment, industrial control ( Wireless terminals in industrial control, in-vehicle terminal equipment, wireless terminals in self-driving, wireless terminals in remote medical, wireless terminals in smart grid, transportation safety (transportation) Wireless terminals in safety), wireless terminals in smart cities, wireless terminals in smart homes, wearable terminal devices, and so on.
- the embodiment of this application does not limit the application scenario.
- Terminal equipment can sometimes be called terminal, user equipment (UE), access terminal equipment, vehicle-mounted terminal, industrial control terminal, UE unit, UE station, mobile station, mobile station, remote station, remote terminal equipment, mobile Equipment, UE agent or UE device, etc.
- the terminal device can also be fixed or mobile.
- a common method is to use the diversity gain of the channel.
- the increase in diversity includes the diversity of the channel in at least one dimension such as the time domain, frequency domain, and space domain.
- the diversity gain of the channel refers to the low correlation of the channel in at least one dimension in the time domain, frequency domain, and space domain, or the statistical independence of multiple transmissions in at least one dimension of the channel in the time domain, frequency domain, and space domain. This feature enables the communication process to use these independent channels, reducing the impact of channel fading.
- the spatial diversity gain of the channel may be, for example, the independent channel diversity gain of multiple stations.
- multiple network devices in the network and multiple network devices can perform coordinated transmission, that is, multi-station coordinated transmission technology.
- the terminal device may be scheduled by multiple network devices. For example, multiple network devices schedule the terminal device to receive multiple copies of data, which can increase the user's throughput and increase the user's perception rate.
- the terminal device can also send data to multiple network devices respectively, and multiple network devices can receive data respectively, and can also combine data.
- Multiple network devices can be geographically different, resulting in low correlation between multiple network devices and multiple independent channels of terminal devices. Therefore, the multi-station cooperative transmission technology can be applied to scenarios that require high communication reliability, so that the system can utilize low-correlation channel diversity gains.
- the uRLLC scenario of the NR system can support multiple repeated transmission methods based on multi-station cooperative transmission technology.
- the repeated transmission methods can be divided into repeated transmission methods in the space, frequency, or time domain.
- Network equipment can use one or more transmission modes to send data to terminal equipment. The terminal equipment needs to identify the transmission mode adopted by the network equipment. In order to carry out the corresponding reception processing.
- the embodiments of the present application provide a method and device for determining a transmission mode, and a terminal device can identify a transmission mode adopted by a network device so as to perform corresponding reception processing.
- the embodiments of the present application can be applied to distinguish multiple transmission modes in the uRLLC scenario, and the multiple transmission modes are not limited to the current five transmission modes.
- the embodiments of the present application may also be applied to distinguish between multi-site uRLLC scenarios and multi-site eMBB scenarios.
- the SDM mode is a repetitive transmission mode in the airspace. It means that multiple TRPs jointly transmit the same transmission block. Different TRPs schedule the same time-frequency resources and map different antenna ports. Therefore, the diversity gain in the space can be used.
- the data sent from the media access control (MAC) layer to the physical layer is composed of a transport block (TB).
- TB transport block
- One TB is sent from the MAC layer to the physical layer.
- the network device performs channel coding processing on each TB, and performs rate matching on the transmission block after the channel coding processing and stores it in the ring buffer.
- the code word (CW) obtained from the ring buffer based on the redundancy version (redundancy version, RV) can be regarded as a TB with error protection.
- the codeword is mapped to one or more data transmission layers (Layer for short), and each data transmission layer corresponds to a valid data stream.
- the data flow of each layer is mapped to the antenna port (antenna port) through the antenna port mapping.
- the process of antenna port mapping can also be referred to as precoding, that is, the process of mapping data streams of each layer to antenna ports through a precoding matrix.
- precoding that is, the process of mapping data streams of each layer to antenna ports through a precoding matrix.
- the pre-coded data stream is mapped to physical time-frequency resources, converted into signals and sent out by network equipment.
- Fig. 3a is a transmission example diagram of the space division multiplexing mode.
- TRP 1 and TRP 2 schedule exactly the same time-frequency resources, and the time-domain scheduling unit of the time-frequency resources is a slot or mini-slot.
- the antenna port of TRP 1 that transmits the physical downlink shared channel (PDSCH) 1 is different from the antenna port of TRP 2 that transmits PDSCH.
- the difference in antenna port involves the physical layer processing flow, see Figure 3b, which is space division multiplexing
- Figure 3b which is space division multiplexing
- TRP 1 and TRP 2 jointly transmit a transport block, and TRP 1 or TRP 2 can perform channel coding and rate matching processing on the transport block.
- the transmission block is processed by channel coding and rate matching, and a CW is obtained based on the single redundancy version.
- the CW is mapped to two data transmission layers, such as Layer 0 and Layer 1, during the layer mapping process.
- the data stream of Layer 0 of the data transmission layer is mapped to antenna port 0 through antenna port mapping; the data stream of Layer 1 of the data transmission layer is mapped to antenna port 2 through antenna port mapping.
- the data stream of antenna port 0 obtains PDSCH 1 through resource mapping; the data stream of antenna port 2 obtains PDSCH 2 through resource mapping, and PDSCH 1 and PDSCH 2 are mapped to the same time-frequency resource.
- TRP 1 can transmit PDSCH 1
- TRP 2 can transmit PDSCH 2.
- PDSCH 1 carries half of the information bits of the transport block, and PDSCH 2 carries the other half of the information bits of the transport block.
- the data flow of the data transmission layer Layer 0 is mapped to CDM group 0 through the antenna port mapping; the data flow of the data transmission layer Layer 1 is mapped through the antenna port mapping Go to CDM group 1. That is, for the SDM mode, in the antenna port mapping process, data streams of different data transmission layers can be mapped to different CDM groups.
- the SDM mode is the same as the current multi-station eMBB transmission mode.
- the SDM mode can also be referred to as scheme 1a (scheme 1a) or space division multiplexing scheme.
- the FDM mode is a repetitive transmission mode in the frequency domain. It means that multiple TRPs jointly transmit the same transmission block, or multiple TRPs transmit one transmission block separately. Different TRPs schedule different frequency domain resources and the same time domain resources. In FDM mode, multiple TRPs can use one or more antenna ports during transmission.
- FIG. 4a is an example diagram of transmission in the frequency division multiplexing mode.
- the time domain resources scheduled by TRP 1 and TRP 2 are the same, but the frequency domain resources are different and do not overlap at all.
- Two TRPs perform FDM transmission, which is equivalent to each TRP scheduling half of the frequency domain resources. Therefore, there is a power boost of 3 decibels (dB), which is the main source of gain in the FDM mode.
- dB decibels
- FDM mode can be divided into FDM mode based on single codeword and FDM mode based on multiple codewords.
- FDM mode based on single codeword is FDM mode based on a single redundancy version of one codeword, and FDM mode based on multiple codewords It is the FDM mode based on multiple codewords with multiple redundancy versions.
- the FDM mode based on a single codeword is referred to as the first FDM mode, and the FDM mode based on multiple codewords is referred to as the second FDM mode.
- the FDM mode based on a single codeword may also be referred to as scheme 2a, etc.
- the FDM mode based on multiple codewords may also be referred to as scheme 2b, etc.
- TRP 1 and TRP 2 jointly transmit a transport block, and TRP 1 or TRP 2 can perform channel coding and rate matching processing on the transport block.
- the transmission block is processed by channel coding and rate matching, and a CW is obtained based on the single redundancy version. After that, the CW is mapped to one or two data transmission layers in the layer mapping process. Then, in the antenna port mapping process, it is mapped to one or two antenna ports.
- PDSCH 1 carries half of the information bits of the transport block
- PDSCH 2 carries the other half of the information bits of the transport block.
- TRP 1 and TRP 2 respectively transmit an identical transmission block.
- One transmission block is processed by channel coding and rate matching.
- a CW is obtained based on redundancy version 0, and the other transmission block is subjected to channel coding and rate matching.
- Processing obtain another CW based on redundancy version 1, and the redundancy versions of the two CWs are different.
- the two CWs are mapped to the same data transmission layer in the layer mapping process. Later, in the antenna port mapping process, it is mapped to the same antenna port, such as port 0.
- PDSCH 1 and PDSCH 2 both carry information bits of the same transport block, but different redundant bits are added, and the terminal device can combine soft bits of information to obtain a combined gain.
- the TDM mode is a repetitive transmission mode in the time domain. It means that multiple TRPs transmit one transmission block separately.
- the time domain resources of different TRP transmission schedules are different and do not overlap at all, and the frequency domain resources are the same.
- multiple TRPs can use one or more antenna ports during transmission.
- the TDM mode utilizes the low correlation of the channel in time to improve the robustness of transmission.
- the TDM mode can be divided into the TDM mode in the time slot unit and the TDM mode between the time slot units.
- the time slot unit can be a slot or a mini-slot.
- a slot can include 14 symbols, and it can also be designed in the future. Including other numbers of symbols, the number of symbols included in a mini-slot is less than the number of symbols included in the slot. For example, a mini-slot can include 2, 6, or 7 symbols.
- the symbols can be orthogonal frequency division multiplexing (OFDM) symbols, discrete Fourier transform spreading orthogonal frequency division multiplexing (discrete Fourier transform spread spectrum orthogonal frequency division multiplexing, DFT-S-OFDM) Symbols etc.
- the embodiment of the present application refers to the TDM mode in the time slot unit as the first TDM mode, and the TDM mode between the time slot units as the second TDM mode.
- the TDM mode in the time slot unit can also be called scheme 3, or the TDM mode based on mini-slot, etc.
- the TDM mode between time slot units can also be called scheme 4, the TDM mode based on slot or the TDM across time slot units Mode etc.
- FIG. 5a is an example diagram of transmission in the first time division multiplexing mode.
- the frequency domain resources scheduled by TRP1 and TRP2 are the same, and the time domain resources are all located in slot n and do not overlap at all.
- FIG. 5b is an example diagram of transmission in the second time division multiplexing mode.
- the frequency domain resources scheduled by TRP 1 and TRP 2 are the same, the time domain resources scheduled by TRP 1 are located in slot n, and the time domain resources scheduled by TRP 2 are located in slot n+1, which are different and do not overlap at all. .
- TRP 1 and TRP 2 respectively transmit an identical transmission block, one transmission block is processed by channel coding and rate matching, a CW is obtained based on the redundancy version, and the other transmission block is processed by channel coding and rate matching. Another CW is obtained based on the redundancy version.
- the redundancy versions of the two CWs can be the same or different. The difference is taken as an example in Figure 5c.
- the layer mapping process it is mapped to one or more data transmission layers, and in the antenna port mapping process, it is mapped to one or more antenna ports.
- the resource mapping process two PDSCHs are mapped to the same frequency domain resources, but are transmitted in time sharing, so the time domain resources of PDSCH 1 and PDSCH 2 are different.
- the TDM mode can also include a combined transmission mode of the first TDM mode and the second TDM mode.
- the repeated transmission of PDSCH simultaneously occupies both the slot and the slot. symbol.
- the PDSCH is repeatedly transmitted within slots and repeated between slots.
- the time domain resource occupied by the PDSCH may include the third and fourth symbols in slot n. , The ninth and tenth symbols, and the third, fourth, ninth, and tenth symbols in slot n+1.
- the PDSCH on the third and fourth symbols in slot n and the PDSCH on the ninth and tenth symbols in slot n are repetitions in slot n
- the third and fourth symbols in slot n are repetitions between slots.
- the indication content is the TCI state (state) of each data transmission process.
- the dynamic control signaling may be downlink control information (downlink control information, DCI).
- the TCI state is a field in DCI used to indicate the quasi co-location (QCL) of the PDSCH antenna port. It is used to configure the quasi co-location relationship between one or two downlink reference signals and the DMRS of the PDSCH, which can be understood as this Channel characteristics of the secondary PDSCH transmission process. Therefore, the terminal device can learn the indication information of the received PDSCH channel large-scale parameter relationship based on the TCI state, and then demodulate the data transmitted on the PDSCH based on the channel estimation. In the scenario of multi-station coordinated transmission, for terminal devices, different TRPs have different TCI states during PDSCH transmission.
- the TCI state is the indication information used to indicate the large-scale parameters of the PDSCH channel. Therefore, the biggest feature of the multi-station transmission scenario is that there are multiple TRPs with completely different channel conditions. Therefore, the diversity gain of the channel can be used. Then there are multiple TCI states.
- the terminal device may consider the current transmission scene to be a multi-station transmission scene.
- the QCL relationship is used to indicate that multiple resources have one or more identical or similar communication characteristics. For example, if two antenna ports have a quasi co-location relationship, the large-scale characteristics of the channel for one antenna port to transmit a signal can be inferred from the large-scale characteristics of the channel for the other antenna port to transmit a signal.
- the signals corresponding to the antenna ports with the QCL relationship have the same parameters, or the parameters of one antenna port can be used to determine the parameters of the other antenna port that has the QCL relationship with the antenna port, or the two antenna ports have the same parameters , Or, the parameter difference between the two antenna ports is less than a certain preset value.
- the parameters may include one or more of the following large-scale channel parameters: delay spread, Doppler spread, Doppler shift, average delay (average delay) delay), average gain, spatial reception parameters (spatial Rx parameters).
- the spatial receiving parameters can include the angle of arrival (AOA), the dominant angle of emission (Dominant AoA), the average angle of arrival (Average AoA), the angle of arrival (Angle of departure, AOD), the channel correlation matrix, and the angle of arrival Power angle spread spectrum, average firing angle (Average AoD), power angle spread spectrum of departure angle, transmit channel correlation, receive channel correlation, transmit beamforming, receive beamforming, spatial channel correlation, spatial filter, or, One or more of spatial filtering parameters, or spatial reception parameters, etc.
- TRP 1 and TRP 2 send different QCLs to the terminal device.
- the terminal device knows that the data comes from different TRPs according to different QCLs, and the terminal device can determine the current transmission scene according to multiple QCLs. Station transmission scene.
- the CDM group can also be described as a CDM antenna port group. Multiple antenna ports in the CDM group can occupy the same time-frequency resources, but use different code domain resources.
- the terminal equipment assumes that the DMRS ports in a CDM group have a QCL relationship, that is, the channel condition characteristics of the DMRS ports in a CDM group are similar, which can be understood as coming from the same TRP, and can also be regarded as being transmitted by the antenna ports in the same CDM group Data can be received simultaneously.
- DMRS ports of different TRPs are generally considered to have no QCL relationship, that is, non-QCL (non-QCL).
- the DMRS CDM group can also be described as the CDM antenna port group of the DMRS, which is used to indicate the CDM group to which the DMRS port for DMRS transmission belongs.
- FIG. 6 is a schematic flowchart of a method for determining a transmission mode according to an embodiment of this application.
- the process may include but is not limited to the following steps:
- Step 601 The network device sends configuration instruction information to the terminal device.
- the terminal device receives the configuration instruction information from the network device.
- the configuration indication information is one or more of DMRS indication information, repeated transmission indication information, or TCI information.
- the network device can configure the DMRS indication information for the terminal device and send the DMRS indication information to the terminal device.
- the network equipment may indicate information to the terminal equipment DMRS through dynamic control signaling, and the dynamic control signaling may be DCI, that is, the DMRS indication information may be carried in the DCI.
- the DMRS indication information may be a value (value) or an index (index), which is used as an entry of the DMRS table (table), so as to find the DMRS parameter corresponding to the value in the DMRS table.
- the DMRS table is used as an example, and does not constitute a limitation to the embodiments of the present application.
- Table 1 is known for both network equipment and terminal equipment.
- DMRS tables are configured on both the network equipment and the terminal equipment.
- the terminal device can obtain two DMRS parameters corresponding to a certain value by looking up the table.
- the two DMRS parameters are the number of CDM groups that do not carry data and the DMRS port.
- the number of CDM groups that do not carry data is the number of DMRS CDM groups that do not carry data (number of DMRS CDM group(s) without data), which is used for rate matching.
- the DMRS port (DMRS port) is used to notify the terminal equipment of the DMRS port and CDM group used.
- DMRS ports include four port identifiers: [0], [1], [2], and [3].
- DMRS port[0] and DMRS port[1] belong to CDM group ⁇ 0 ⁇ , namely CDM group ⁇ 0 ⁇ Includes DMRS port[0] and DMRS port[1]; DMRS port[2] and DMRS port[3] belong to CDM group ⁇ 1 ⁇ , that is, CDM group ⁇ 1 ⁇ includes DMRS port[2] and DMRS port[ 3].
- the terminal device can look up the table to obtain that the CDM group that does not carry data is group 1, and the DMRS port is [0] and [1], these two DMRS ports belong to the CDM group ⁇ 0 ⁇ .
- the value indicated by the DMRS indication information is 11, the terminal device can look up the table to obtain that the CDM groups that do not carry data are 2 groups, and the DMRS ports are [0] and [2]. These two DMRS ports belong to the CDM group ⁇ 0 ⁇ And CDM group ⁇ 1 ⁇ .
- the DMRS indication information can directly indicate a value in the DMRS table, and then indirectly indicate the DMRS port ID corresponding to the value, or indirectly indicate the CDM group corresponding to the value, or indirectly indicate the number and number of CDM groups that do not carry data corresponding to the value.
- DMRS port ID It can be understood that the DMRS indication information is used to indicate the DMRS port identifier, or to indicate the DMRS port identifier and the CDM group that does not carry data.
- the DMRS indication information may be used to distinguish the SDM mode and the FDM mode.
- the distinction is made based on the DMRS port identifier.
- transmission in SDM mode uses at least 2 DMRS ports, and these DMRS ports come from different CDM groups; while transmission in FDM mode uses one or more DMRS ports, and is limited to the maximum rank (rank) It is transmitted in the case of 2, so the SDM mode and the FDM mode are distinguished according to the DMRS port identifier.
- the DMRS indication information when used to indicate the DMRS port identifier and the CDM group that does not carry data, the DMRS indication information may be used to distinguish the SDM mode, the FDM mode, and the first TDM mode. In this way, the transmission mode corresponding to each value in Table 1 can be determined.
- the network device may configure repeated transmission indication information for the terminal device, and send the repeated transmission indication information to the terminal device.
- the network device may send repeated transmission indication information to the terminal device through high-level signaling.
- the high-level signaling may be, for example, radio resource control (RRC) signaling, that is, the repeated transmission indication information is carried in the RRC signaling.
- RRC radio resource control
- the repeated transmission indication information may be used to indicate the time domain repeated transmission parameters.
- Manner 1 The time domain repeated transmission parameter is used to indicate the number of repetitions in the time domain, and may be an aggregation factor (AggregationFactor). AggregationFactor can be used for terminal equipment to distinguish TDM mode from other transmission modes.
- Manner 2 The time domain repeated transmission parameter may be a PDSCH aggregation factor (pdsch-AggregationFactor), and the value of pdsch-AggregationFactor may be 2, 4, or 8, which is used to indicate repeated transmission on consecutive pdsch-AggregationFactor slots.
- the pdsch-AggregationFactor can be used for terminal equipment to distinguish the second TDM mode from other transmission modes.
- the repeated transmission indication information is also used to indicate frequency domain repeated transmission parameters, and the frequency domain repeated transmission parameters are used to distinguish between the first FDM mode and the second FDM mode.
- the repeated transmission indication information may be used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter.
- the first time domain repetitive transmission parameter may be expressed as a mini-slot aggregation factor (MiniSlot AggregationFactor), and the second time domain repetitive transmission parameter may be expressed as a slot aggregation factor (Slot AggregationFactor).
- MiniSlot AggregationFactor mini-slot aggregation factor
- Slot AggregationFactor slot aggregation factor
- the first time domain repeated transmission parameter and the second time domain repeated transmission parameter can be used to distinguish the TDM mode from other transmission modes, and in the case of determining the TDM mode, it can also be used to further distinguish the first TDM mode and the second TDM mode.
- the repeated transmission indication information may be used to indicate the frequency domain repeated transmission parameter, the first time domain repeated transmission parameter, and the second time domain repeated transmission parameter.
- the repeated transmission indication information may be expressed as ⁇ a,b,c ⁇ , for example, a represents a frequency domain repeated transmission parameter, b represents a first time domain repeated transmission parameter, and c represents a second time domain repeated transmission parameter.
- the terminal device can determine the transmission mode according to the repeated transmission indication information and the number of CDM groups.
- the network device can configure TCI information for the terminal device and send the TCI information to the terminal device.
- the network equipment may indicate information to the terminal equipment DMRS through dynamic control signaling, and the dynamic control signaling may be DCI, that is, the DMRS indication information may be carried in the DCI.
- the network device can send TCI information and DMRS indication information to the terminal device through the same DCI, or can send TCI information and DMRS indication information to the terminal device through different DCIs.
- TCI information is used to indicate the TCI status of the transmission process.
- the TCI information may be a TCI codepoint (codepoint), and one TCI codepoint corresponds to one or more TCI states. In the case of multi-station transmission, one TCI codepoint can indicate two or more TCI states. If the TCI information indicates two or more TCI states, the terminal device can determine that the current transmission scene is a multi-station transmission scene.
- Step 602 The terminal device determines a transmission mode according to the configuration instruction information.
- the terminal device Before determining the transmission mode according to the configuration instruction information, the terminal device may first determine whether the current transmission scene is a multi-station transmission scene, and in the case of determining that the current transmission scene is a multi-station transmission scene, determine the transmission mode according to the configuration instruction information.
- the terminal device can determine whether the current transmission scene is a multi-station transmission scene according to the number of TCI states indicated by the TCI information. If the number of TCI states is greater than or equal to 2, then it can be determined that the current transmission scene is a multi-station transmission scene. .
- the terminal device can determine whether the current transmission scene is a multi-station transmission scene according to the received QCL, and if multiple different QCLs are received, it can determine that the current transmission scene is a multi-station transmission scene.
- the terminal device obtains the configuration indication information, and determines the transmission mode according to the obtained configuration indication information.
- the determination of the transmission mode of the terminal device will be introduced through the following embodiments according to the difference of the configuration instruction information.
- the configuration indication information is repeated transmission indication information.
- the repeated transmission indication information can be used to indicate the time domain repeated transmission parameter, or used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter, or used to indicate the frequency domain repeated transmission parameter, the first time domain repeated transmission The parameters and the second time domain repeat transmission parameters.
- the repeated transmission indication information is used to indicate the time domain repeated transmission parameters:
- the time domain repeated transmission parameter is used to indicate the number of repetitions in the time domain, and may be an AggregationFactor.
- the terminal device determines that the current transmission scenario is a multi-station transmission scenario, if the terminal device obtains the time domain repeated transmission parameters, it indicates that the network device has configured the time domain repeated transmission parameters for the terminal device, and the terminal device can determine that the transmission mode is TDM mode. If the terminal device does not obtain the time domain repetitive transmission parameters, indicating that the network device has not configured the time domain repetitive transmission parameters for the terminal device, the terminal device can determine that the transmission mode is SDM mode, FDM mode, or a combined mode of SDM mode and FDM mode. For the case where the terminal device does not obtain the time domain repeated transmission parameters, the terminal device can use the DMRS indication information in the second embodiment to indicate the DMRS port identifier to distinguish between the SDM mode and the FDM mode.
- the time domain repeated transmission parameter may be pdsch-AggregationFactor, which means that it is transmitted on consecutive slots of pdsch-AggregationFactor. For example, if the pdsch-AggregationFactor is 4, it means that the transmission is repeated on 4 consecutive slots.
- the terminal device determines that the current transmission scenario is a multi-station transmission scenario, the terminal device obtains the time domain repeated transmission parameters, and can determine that the transmission mode is the second TDM mode, that is, the TDM mode between time slot units.
- the terminal device does not obtain the time domain repeated transmission parameter, and may determine that the transmission mode is one or more of the first TDM mode, SDM mode, or FDM mode.
- the terminal device can use the DMRS indication information in the third embodiment to indicate the DMRS port identifier and the number of CDM groups that do not carry data, and distinguish the first TDM mode, SDM mode, and FDM mode.
- the terminal device in the case of determining the TDM mode, can further distinguish whether it is the first TDM mode or the second TDM mode.
- the time domain repeated transmission parameter is the first time domain repeated transmission parameter, then the time division multiplexing mode can be determined to be the first time division multiplexing mode; if the time domain repeated transmission parameter is the second time domain Repeat the transmission parameters, then it can be determined that the time division multiplexing mode is the second time division multiplexing mode.
- the first time-domain repeated transmission parameter may be expressed as MiniSlotAggregationFactor, and the second time-domain repeated transmission parameter may be expressed as SlotAggregationFactor.
- the time-domain repeated transmission parameters may include the unique parameters of the first TDM mode, and then it is determined that the transmission mode is the first TDM mode. For example, if the time domain repetitive transmission parameter includes offset information (offset), then the transmission mode can be determined to be the first TDM mode; otherwise, the transmission mode can be determined to be the second TDM mode.
- the offset information may indicate the offset information of the time domain positions of multiple PDSCHs.
- the time-domain repeated transmission parameter indicates the number of repeated transmissions, but does not indicate whether the number of repeated transmissions is within a slot or the number of repeated transmissions between slots.
- the terminal device can determine it through other information.
- the other information is a certain characteristic bit in the RRC signaling carrying repeated transmission indication information. For example, if the bit is set to "0", it means that the number of repeated transmissions is the number of repeated transmissions in the slot, and the terminal device can determine The transmission mode is the first TDM mode; this bit is set to "1" to indicate that the number of repeated transmissions is the number of repeated transmissions between slots, and the terminal device can determine that the transmission mode is the second TDM mode.
- setting this bit to "0" means that the number of repeated transmissions is the number of repeated transmissions between slots, and the terminal device can determine that the transmission mode is the second TDM mode; setting this bit to "1" means that the number of repeated transmissions is within the slot The number of repeated transmissions, and the terminal device can determine that the transmission mode is the first TDM mode.
- the other information is additional RRC signaling ⁇ mini-slot, slot ⁇ .
- the additional RRC signaling refers to another piece of RRC signaling, which is different from the RRC signaling that carries repeated transmission indication information.
- the additional RRC signaling ⁇ mini-slot, slot ⁇ indicates whether the number of repeated transmissions is within a slot or the number of repeated transmissions between slots.
- ⁇ 1,0 ⁇ means that the number of repeated transmissions is the number of repeated transmissions in the slot, and the terminal device can determine that the transmission mode is the first TDM mode; ⁇ 0,1 ⁇ means that the number of repeated transmissions is the number of repeated transmissions between slots, and then the terminal The device may determine that the transmission mode is the second TDM mode.
- ⁇ 1,0 ⁇ indicates that the number of repeated transmissions is the number of repeated transmissions between slots, and the terminal device can determine that the transmission mode is the second TDM mode;
- ⁇ 0,1 ⁇ indicates that the number of repeated transmissions is the number of repeated transmissions in the slot, Furthermore, the terminal device may determine that the transmission mode is the first TDM mode.
- the repeated transmission indication information is used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter:
- the transmission mode can be determined to be the SDM mode, the FDM mode, or the combined mode of the SDM mode and the FDM mode.
- the terminal device obtains the first time domain repeated transmission parameter and the second time domain repeated transmission parameter, but the values of the first time domain repeated transmission parameters and the second time domain repeated transmission parameters are both the first preset values, Then it can be determined that the transmission mode is SDM mode, FDM mode, or a combined mode of SDM mode and FDM mode.
- the terminal equipment can determine that the transmission mode is TDM mode.
- the terminal device determines the TDM mode, it can further distinguish whether it is the first TDM mode or the second TDM mode. If the value of the first time domain repeated transmission parameter is the first preset value, and the second time domain repeated transmission parameter is greater than the first preset value, then the time division multiplexing mode can be determined to be the second TDM mode; if the second time domain repeats The transmission parameter is the first preset value, and the first time domain repeated transmission parameter is greater than the first preset value, then the time division multiplexing mode is determined to be the first TDM mode; if the first time domain repeated transmission parameter and the second time domain repeated transmission If the parameters are all greater than the first preset value, it is determined that the time division multiplexing mode is a combined mode of the first TDM mode and the second TDM mode. Wherein, the first preset value may be 1.
- the repeated transmission indication information is used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter, it can be represented by Table 2 below.
- the first preset value is 1, and the first time domain is repeated
- the transmission parameter represents MiniSlotAggregationFactor
- the second time domain repeated transmission parameter is represented as SlotAggregationFactor as an example.
- Not configured in Table 2 means that the network device has not configured the first time domain repeated transmission parameter and the second time domain repeated transmission parameter for the terminal device, and the terminal device has not acquired the first time domain repeated transmission parameter and the second time domain repeated transmission parameter.
- the specific value of ">1" in Table 2 can represent the number of repetitions. For example, MiniSlotAggregationFactor is 4, which means that the transmission is repeated 4 times in a slot; for another example, the SlotAggregationFactor is 4, which means that the transmission is repeated on 4 consecutive slots.
- the first time domain repeated transmission parameter and the second time domain repeated transmission parameter may also be expressed as ⁇ x, y ⁇ .
- x represents the first time domain repeated transmission parameter, and the number of repeated transmissions in the slot
- the repeated transmission indication information is used to indicate the frequency domain repeated transmission parameter, the first time domain repeated transmission parameter, and the second time domain repeated transmission parameter:
- the repeated transmission indication information can be represented by ⁇ a,b,c ⁇ , for example, a represents the frequency domain repeated transmission parameter, that is, the number of repeated transmissions in the frequency domain; b represents the first time domain repeated transmission parameter, that is, in the time domain The number of repeated transmissions in the slot; c represents the second time domain repeated transmission parameter, that is, the number of repeated transmissions between slots in the time domain. If there is no repeated transmission in the time domain or the frequency domain, the values of a, b, and c can be 0 or 1, and the embodiment of the present application takes 1 as an example.
- the terminal device confirms that the transmission mode is the TDM mode according to the obtained repeated transmission instruction information, and no additional instruction information is required to indicate.
- the configuration indication information is DMRS indication information
- the DMRS indication information may be used to indicate the DMRS port identifier.
- the terminal device determines that the current transmission scenario is a multi-station transmission scenario, the terminal device obtains the DMRS indication information, and determines the DMRS port identifier according to the DMRS indication information, that is, the DMRS port identifier can be obtained by checking the DMRS table according to the indicated value.
- the DMRS port identifier determines the transmission mode. In this case, the terminal device determines whether the transmission mode is FDM mode or SDM mode according to the DMRS port identifier.
- the terminal device can use the following four methods to determine the transmission mode according to the DMRS port identifier.
- the terminal device can determine that the transmission mode is the FDM mode. If the number of CDM groups corresponding to the DMRS port identifier is the third preset value, the terminal device may determine that the transmission mode is the SDM mode.
- the second preset value may be 1, which means 1 CDM group; the third preset value may be 2, which means 2 CDM groups.
- the DMRS port identifier is [0,1,2], corresponding to two CDM groups, that is, for CDM group ⁇ 0 ⁇ and CDM group ⁇ 1 ⁇ , then the terminal device can determine the transmission mode as SDM mode.
- the transmission mode can be determined as SDM mode.
- the DMRS port identifier is [0,1], which corresponds to a CDM group, that is, for CDM group ⁇ 0 ⁇ , then the terminal device can determine that the transmission mode is FDM mode.
- Method 2 If the DMRS port identifier belongs to the same CDM group, the terminal device can determine that the transmission mode is the FDM mode; otherwise, it can determine that the transmission mode is the empty SDM mode. For example, when the value in Table 1 is 7, the DMRS port identifier is [0,1], belonging to the same CDM group, that is, belonging to the CDM group ⁇ 0 ⁇ , then the terminal device can determine that the transmission mode is FDM mode. For another example, when the value in Table 1 is 9, the DMRS port identifier is [0,1,2] and belongs to two CDM groups, then the terminal device can determine that the transmission mode is the SDM mode.
- the terminal device may determine that the transmission mode is the FDM mode; otherwise, it may determine that the transmission mode is the SDM mode.
- the second preset value may be one. For example, when the value in Table 1 is 4, and the DMRS port is identified as one, the terminal device can determine that the transmission mode is the FDM mode. For another example, when the value in Table 1 is 9, and the DMRS port identifier is three, the terminal device can determine that the transmission mode is the SDM mode.
- Method 4 If the DMRS port identifier belongs to the preset identifier, the terminal device can determine that the transmission mode is the FDM mode; otherwise, it can determine that the transmission mode is the SDM mode.
- the preset identifier can be [0], [1] or [0,1].
- the terminal device can determine that the transmission mode is the FDM mode.
- the DMRS port identifier includes other identifiers in addition to the preset identifier, and the terminal device can determine that the transmission mode is the SDM mode.
- the terminal device determines the number of CDM groups according to the DMRS indication information, and determines the transmission mode according to the number of CDM groups. If the number of CDM groups is the second preset value (for example, one CDM group), then the terminal device can determine that the transmission mode is FDM mode; if the number of CDM groups is the third preset value (for example, two CDM groups) , Then the terminal device can determine that the transmission mode is SDM mode.
- the difference between this method and the first method is that the first method determines the DMRS port identifier according to the value, and the number of CDM groups is determined according to the port identifier, while this method directly determines the number of CDM groups according to the value.
- the terminal device determines the FDM mode, it can further distinguish whether it is the first FDM mode or the second FDM mode.
- the terminal device obtains the frequency domain repetitive transmission parameters.
- the transmission mode can be determined to be the second FDM mode; if the frequency domain repetitive transmission parameters are not obtained, the transmission mode can be determined to be the first FDM mode.
- the frequency domain repeated transmission parameters can be carried in the RRC signaling together with the time domain repeated transmission parameters, that is, the repeated transmission indication information carried in the RRC signaling can indicate the time domain repeated transmission parameters and the frequency domain repeated transmission parameters, or RRC signaling
- the carried repeated transmission indication information indicates the time domain repeated transmission parameter, and other information in the RRC signaling indicates the frequency domain repeated transmission parameter.
- Frequency domain repeated transmission parameters may also be indicated by additional RRC signaling, for example, RRC signaling 1 indicates time domain repeated transmission parameters, and RRC signaling 2 indicates frequency domain repeated transmission parameters.
- the terminal device determines the transmission mode according to the third column in Table 1.
- the configuration indication information is DMRS indication information
- the DMRS indication information is used to indicate the DMRS port identifier and the number of CDM groups that do not carry data.
- the terminal equipment determines whether the transmission mode is space division multiplexing mode, frequency division multiplexing mode or first time division multiplexing mode according to the number of CDM groups corresponding to the DMRS port identifier and the number of CDM groups not carrying data; if the transmission is determined
- the mode is a frequency division multiplexing mode, and the transmission mode is determined to be the first frequency division multiplexing mode or the second frequency division multiplexing mode according to the group identifier of the CDM group corresponding to the DMRS port identifier.
- the terminal device can determine that the transmission mode is SDM mode; if there is one CDM group corresponding to the DMRS port identifier, and the number of CDM groups that do not carry data is one, then The terminal device may determine that the transmission mode is the first TDM mode; if the CDM port group corresponding to the DMRS port identifier is one and the number of CDM groups that do not carry data is two, then the terminal device may determine that the transmission mode is the FDM mode.
- the terminal device can determine that the transmission mode is the first FDM mode; if the CDM group corresponding to the DMRS port identifier The group identifier is the second identifier, and the terminal device can determine that the transmission mode is the second FDM mode.
- the group ID of the CDM group is ⁇ 0 ⁇ , and the transmission mode is determined to be the first FDM mode; the group ID of the CDM group is ⁇ 1 ⁇ , and the transmission mode is determined to be the second FDM mode.
- the group ID of the CDM group is ⁇ 1 ⁇ , and the transmission mode is determined to be the first FDM mode; the group ID of the CDM group is ⁇ 0 ⁇ , and the transmission mode is determined to be the second FDM mode.
- the transmission mode corresponding to each value in Table 1 can be determined. For details, see Table 3 below.
- each transmission mode has a corresponding DMRS table entry. For example, using ⁇ 2,7,8,11 ⁇ four entries can distinguish the first TDM mode, the first FDM mode, the second FDM mode and SDM mode.
- the transmission mode adopted by the network device is the first FDM mode
- the network device can implicitly inform the terminal device that the current transmission mode is the first by configuring the index of the DMRS table to be one of ⁇ 3,4,7 ⁇ FDM mode.
- the terminal device determines the transmission mode according to the second column and the third column in Table 1.
- the terminal device distinguishes the SDM mode and the FDM mode according to the acquired DMRS indication information, without additional indication information for instructions.
- the configuration instruction information is TCI information.
- the terminal device determines that the current transmission scene is a multi-station transmission scene, if the number of TCI states is the fourth preset value, the terminal device can determine that the transmission mode is FDM mode or SDM mode; if the number of TCI states is greater than the first Four preset values, then the terminal device can determine that the transmission mode is the TDM mode.
- the fourth preset value may be 2, which represents 2 TCI states.
- the terminal device when the terminal device determines that the current transmission scenario is a multi-station transmission scenario, if the number of TCI states is the fourth preset value, the terminal device may determine that the transmission mode is FDM mode or SDM mode; if the number of TCI states is the fifth preset value, the terminal device can determine that the transmission mode is the TDM mode.
- the fourth preset value may be 2, which means 2 TCI states
- the fifth preset value may be 4, which means 4 TCI states.
- the configuration indication information is TCI information and repeated transmission indication information.
- the repeated transmission indication information is used to indicate the time domain repeated transmission parameters.
- the terminal device determines that the current transmission scenario is a multi-station transmission scenario, the terminal device acquires the repeated transmission indication information, and the number of TCI states is greater than or equal to the fourth preset value, and the transmission mode can be determined to be the TDM mode.
- the repeated transmission indication information is used to indicate the first time domain repeated transmission parameter and the second time domain repeated transmission parameter.
- the terminal device determines that the current transmission scenario is a multi-station transmission scenario, the terminal device acquires the repeated transmission indication information, and the number of TCI states is greater than or equal to the fourth preset value, and the transmission mode can be determined to be the TDM mode. Further, the terminal device can distinguish whether it is the first TDM mode or the second TDM mode.
- the terminal device determines the transmission mode in the case of acquiring the TCI information and the repeated transmission instruction information without additional instruction information.
- the configuration indication information is repeated transmission indication information and DMRS indication information, and the repeated transmission indication information is used to indicate the frequency domain repeated transmission parameter, the first time domain repeated transmission parameter, and the second time domain repeated transmission parameter.
- the repeated transmission indication information can be represented by ⁇ a,b,c ⁇ , for example, a represents the frequency domain repeated transmission parameter, that is, the number of repeated transmissions in the frequency domain; b represents the first time domain repeated transmission parameter, that is, when The number of repeated transmissions in the slot in the domain; c represents the second time domain repeated transmission parameter, that is, the number of repeated transmissions between slots in the time domain.
- the terminal device when the terminal device determines that the current transmission scenario is a multi-station transmission scenario, the terminal device can determine the number of CDM groups according to the DMRS indication information, and can distinguish the SDM mode from other modes according to the number of CDM groups Transmission mode.
- Example 1 The number of CDM groups is two, the repeated transmission indication information is ⁇ 1,1,1 ⁇ , and the terminal device can determine that the transmission mode is the SDM mode. Or, if the number of CDM groups is two, and the terminal device does not obtain the repeated transmission indication information, it can be determined that the transmission mode is the SDM mode.
- Example 2 The number of CDM groups is one, the repeated transmission indication information is ⁇ 1,1,1 ⁇ , and the terminal device can determine that the transmission mode is the first FDM mode. Or, if the number of CDM groups is one, and the terminal device does not obtain the repeated transmission indication information, it can be determined that the transmission mode is the first FDM mode.
- Example 3 The number of CDM groups is one, the repeated transmission indication information is a value other than ⁇ 1,1,1 ⁇ , and the terminal device can determine that the transmission mode is the second FDM mode or the TDM mode.
- the terminal device when the terminal device determines that the current transmission scenario is a multi-station transmission scenario, the terminal device can determine the number of CDM groups according to the DMRS indication information, and according to the number of CDM groups and frequency domain repeated transmission parameters , The first time domain repeated transmission parameter and the second time domain repeated transmission parameter determine the transmission mode.
- the number of CDM groups is two
- the repeated transmission indication information is ⁇ 1,x,1 ⁇ or ⁇ 1,1,x ⁇
- the terminal device may determine that the transmission mode is a combined mode of the TDM mode and the SDM mode.
- the transmission mode is a combined mode of the first TDM mode and the SDM mode
- the transmission mode is the second Combination mode of TDM mode and SDM mode.
- the number of CDM groups is one
- the repeated transmission indication information is ⁇ x, y, 1 ⁇ or ⁇ x, 1, z ⁇
- the terminal device may determine that the transmission mode is a combined mode of the TDM mode and the FDM mode.
- x, y, and z are integers greater than 1
- x represents the number of repeated transmissions in the frequency domain
- y represents the number of repeated transmissions in a slot
- z represents the number of repeated transmissions between slots.
- the transmission mode is a combination mode of the first TDM mode and the second FDM mode; when the repeated transmission indication information is ⁇ x,1,z ⁇ , the transmission mode is The combined mode of the second TDM mode and the second FDM mode; when the repeated transmission indication information is ⁇ 1, y, z ⁇ , the transmission mode is the combined mode of the first TDM mode and the second TDM mode.
- the terminal device determines the transmission mode in the case of acquiring the DMRS indication information and the repeated transmission indication information without additional indication information.
- the terminal device when the terminal device determines that the current transmission scene is a multi-station transmission scene, the terminal device determines the transmission mode according to the acquired configuration indication information, without additional indication information, which can save indication signaling overhead .
- FIG. 7 is an example flow chart of another transmission mode determination method provided by this embodiment of the application.
- the flow may include but is not limited to the following steps:
- Step 701 The network device sends configuration information to the terminal device.
- the terminal device receives configuration information from the network device.
- the configuration information can be understood as the configuration information indicating the uRLLC scenario, thereby distinguishing the multi-site uRLLC scenario from the multi-site eMBB scenario.
- the configuration information is used to indicate that the terminal device can use a code rate lower than the preset code rate, or used to instruct the terminal device to use a preset modulation and coding strategy (modulation and coding scheme, MCS) table.
- the preset code rate may be 120*1024 (kbps)
- the preset MCS table may be modulation coding strategy table 3
- the MCS table 3 has a code rate lower than 120*1024 (kbps).
- the code rate is the target code rate (target code rate).
- MCS Table 3 can be seen in Table 4 below, that is, Table 4 below is MCS Table 3.
- the network device instructs the terminal device to use MCS table 3, indicating that the current transmission scene is the uRLLC scene.
- the configuration information may be a newly defined radio network temporary identity (RNTI) or a newly defined DCI domain.
- RNTI radio network temporary identity
- the terminal device detects the configuration information, it can consider the current transmission scene as a multi-station uRLLC scene; otherwise, it can consider the current transmission scene as a multi-station eMBB scene.
- the configuration information can be the configuration information related to the reuse of the existing multi-site uRLLC scenario, for example, it can be the modulation and coding strategy cell radio network temporary identity (modulation and coding scheme cell radio network temporary identity, MCS) -C-TNTI).
- MCS modulation and coding scheme cell radio network temporary identity
- the terminal device can consider the current transmission scene to be a multi-station uRLLC scene. If the terminal device does not obtain the MCS-C-RNTI, the terminal device may consider the current transmission scene to be an eMBB scene.
- the configuration information can be used to directly indicate that the current transmission scene is a multi-station uRLLC scene.
- the terminal device detects the configuration information, the current transmission scene can be considered as a multi-station uRLLC scene, otherwise it can be It is considered that the current transmission scene is a multi-station eMBB scene.
- the configuration information may be a newly defined RNTI or a newly defined DCI domain.
- the configuration information can be understood as the configuration information indicating the eMBB scene, for example indicating the exclusive characteristics of the multi-site eMBB scene, or multiplexing the configuration information related to the existing multi-site eMBB scene, or the configuration information can be used for Directly indicate that the current transmission scene is a multi-station eMBB scene.
- Step 702 The network device sends transmission mode indication information to the terminal device.
- the terminal device receives the transmission mode indication information from the network device.
- the transmission mode indication information can be carried in DCI or in RRC signaling.
- the transmission mode is one or more of SDM transmission mode, first FDM transmission mode, second FDM transmission mode, first TDM transmission mode or second TDM transmission mode.
- the transmission mode indication information may be "SchemeSelection" in RRC signaling, which is used to indicate the transmission mode.
- the transmission mode indication information can include five parameters, which are ⁇ 1,2,3,4,5 ⁇ , corresponding to the SDM transmission mode, the first FDM transmission mode, the second FDM transmission mode, the first TDM transmission mode, or the second transmission mode. TDM transmission mode, through indicating one of the parameters to realize the indication of the transmission mode.
- the transmission mode indication information may also use 3 bits to indicate the transmission mode, and the specific indication is not limited in the embodiment of the present application.
- step 701 and step 702 are not limited in the embodiment of this application.
- step 702 is performed before step 701, and the terminal device obtains configuration information from the received RRC signaling. Obtain the transmission mode indication information. It can be understood that there is a binding relationship between the configuration information and the transmission mode indication information.
- Step 703 The terminal device determines the transmission mode according to the transmission mode indication information.
- the terminal device When the terminal device obtains the transmission mode indication information, it directly determines the transmission mode adopted by the network device according to the transmission mode indicated by the transmission mode indication information, which is simple to implement.
- the terminal device when the terminal device determines that the current transmission scenario is a multi-station uRLLC scenario, if the terminal device uses a certain RNTI to successfully descramble the physical downlink control channel (PDCCH), then The terminal device can determine which transmission mode in the multi-station uRLLC scenario according to the RNTI.
- the terminal equipment and the network equipment store the correspondence between various RNTIs and the transmission modes of the multi-station uRLLC scenario.
- the terminal equipment can directly determine the current transmission mode of the network equipment according to the RNTI adopted by the PDCCH successfully descrambled.
- the terminal device can implement dynamic switching between the multi-station uRLLC scene and the multi-station eMBB scene according to the configuration information, without adding additional indication overhead.
- the transmission mode in the multi-station uRLLC scene is determined according to the transmission mode indication information, which is simple to implement.
- an embodiment of the present application also provides a corresponding communication device, and the communication device includes a corresponding module for executing the foregoing embodiment.
- the module can be software, hardware, or a combination of software and hardware.
- the communication device may be a terminal device, a device in a terminal device, or a device that can be matched and used with the terminal device.
- the communication device may include a transceiver unit and a processing unit.
- the transceiver unit is configured to obtain configuration indication information, where the configuration indication information is one or more of DMRS indication information, repeated transmission indication information, or transmission configuration indication information; the processing unit uses After determining the transmission mode according to the configuration indication information, the transmission mode is one or more of a space division multiplexing mode, a frequency division multiplexing mode, or a time division multiplexing mode.
- the processing unit determines that the configuration indication information is the repeated transmission indication information, and the repeated transmission indication information is used to indicate a time domain repeated transmission parameter.
- the processing unit is specifically configured to determine that the transmission mode is the time division multiplexing mode according to the time domain repeated transmission parameter.
- the processing unit is specifically configured to: the time-domain repeated transmission parameter is a first time-domain repeated transmission parameter, and it is determined that the time-division multiplexing mode is the first time-division multiplexing mode; the time-domain repeated transmission parameter is the second Time-domain repeated transmission parameters, determine that the time-division multiplexing mode is the second time-division multiplexing mode; or, if the time-domain repeated transmission parameters include offset information, determine that the time-division multiplexing mode is the first time-division multiplexing mode; otherwise, determine The time division multiplexing mode is the second time division multiplexing mode;
- the first time division multiplexing mode is a time division multiplexing mode within a time slot unit
- the second time division multiplexing mode is a time division multiplexing mode between time slot units.
- the processing unit determines that the configuration indication information is the repeated transmission indication information, and the repeated transmission indication information is used to indicate a first time domain repeated transmission parameter and a second time domain repeated transmission parameter;
- the processing unit is specifically configured to: the first time domain repeated transmission parameter and the second time domain repeated transmission parameter are both first preset values, and the transmission mode is determined to be the space division multiplexing mode, frequency division multiplexing mode or empty A combined mode of the frequency division multiplexing mode and the frequency division multiplexing mode; one or more of the first time domain repeated transmission parameter or the second time domain repeated transmission parameter is greater than a first preset value, and it is determined that the transmission mode is time division Multiplexing mode.
- processing unit is specifically used for:
- the first time domain repeated transmission parameter is the first preset value
- the second time domain repeated transmission parameter is greater than the first preset value, and it is determined that the time division multiplexing mode is the second time division multiplexing mode
- the second time domain repeated transmission parameter is the first preset value, the first time domain repeated transmission parameter is greater than the first preset value, and it is determined that the time division multiplexing mode is the first time division multiplexing mode;
- the first time domain repetitive transmission parameter and the second time domain repetitive transmission parameter are both greater than the first preset value, and it is determined that the time division multiplexing mode is the difference between the first time division multiplexing mode and the second time division multiplexing mode Combination mode
- the first time division multiplexing mode is a time division multiplexing mode within a time slot unit
- the second time division multiplexing mode is a time division multiplexing mode between time slot units.
- the processing unit is further configured to determine whether the transmission mode is a space division multiplexing mode, a frequency division multiplexing mode, or a space division multiplexing mode and a frequency division multiplexing mode when the configuration instruction information is not obtained by the transceiver. Combination mode of multiplexing mode.
- the processing unit determines that the configuration indication information is DMRS indication information
- the processing unit is specifically configured to determine a DMRS port identifier according to the DMRS indication information, and determine a transmission mode according to the DMRS port identifier.
- processing unit is specifically used for:
- the number of CDM groups corresponding to the DMRS port identifier is the second preset value, and the transmission mode is determined to be frequency division multiplexing mode; the number of CDM groups corresponding to the DMRS port identifier is the third preset value, and the transmission mode is determined to be Space division multiplexing mode;
- the DMRS port identifiers belong to the same CDM group, and the transmission mode is determined to be the frequency division multiplexing mode; otherwise, the transmission mode is determined to be the space division multiplexing mode;
- the number of the DMRS port identifiers is the second preset value, and the transmission mode is determined to be the frequency division multiplexing mode; otherwise, the transmission mode is determined to be the space division multiplexing mode;
- the DMRS port identifier is a preset identifier, and the transmission mode is determined to be the frequency division multiplexing mode; otherwise, the transmission mode is determined to be the space division multiplexing mode.
- the processing unit determines that the configuration indication information is DMRS indication information
- the processing unit is specifically configured to determine the number of CDM groups according to the DMRS indication information, and determine the transmission mode according to the number of CDM groups.
- the processing unit is specifically configured to: the number of CDM groups is a second preset value, and the transmission mode is determined to be a frequency division multiplexing mode; the number of CDM groups is a third preset value, and the transmission mode is determined to be Space division multiplexing mode.
- the processing unit is specifically configured to: if the frequency domain repeated transmission parameters are obtained, determine that the frequency division multiplexing mode is the second frequency division multiplexing mode; otherwise, determine that the frequency division multiplexing mode is the first frequency division multiplexing mode ;
- the first frequency division multiplexing mode is a frequency division multiplexing mode based on a single codeword
- the second frequency division multiplexing mode is a frequency division multiplexing mode based on multiple codewords.
- the processing unit is specifically configured to determine that the transmission mode is a second time division multiplexing mode according to the time domain repeated transmission parameter, and the second time division multiplexing mode is a time division multiplexing mode between time slot units.
- the processing unit determines that the configuration indication information is DMRS indication information
- the processing unit is specifically configured to determine DMRS port information according to the DMRS indication information, and determine a transmission mode according to the DMRS port information.
- the processing unit determines that the DMRS port information includes the DMRS port identifier and the number of CDM groups that do not carry data;
- the processing unit is specifically used for:
- the transmission mode is space division multiplexing mode, frequency division multiplexing mode or first time division multiplexing mode.
- the time division multiplexing mode is the time division multiplexing mode in the time slot unit;
- the transmission mode is the frequency division multiplexing mode
- the transmission mode is determined to be the first frequency division multiplexing mode or the second frequency division multiplexing mode according to the group identification of the CDM group corresponding to the DMRS port identification, and the first frequency division multiplexing mode
- the frequency division multiplexing mode is a frequency division multiplexing mode based on a single codeword
- the second frequency division multiplexing mode is a frequency division multiplexing mode based on multiple codewords.
- the processing unit determines that the configuration indication information is the DMRS indication information and the repeated transmission indication information, and the repeated transmission indication information is used to indicate frequency domain repeated transmission parameters, first time domain repeated transmission parameters, and Repeated transmission parameters in the second time domain;
- the processing unit is specifically configured to determine the number of CDM groups according to the DMRS indication information, and according to the number of CDM groups, the frequency domain repeated transmission parameters, the first time domain repeated transmission parameters, and the second time domain
- the repeated transmission parameters determine the transmission mode.
- the processing unit determines that the configuration indication information is the transmission configuration indication information, and the transmission configuration indication information is used to indicate a transmission configuration indication state;
- the processing unit is specifically used for:
- the number of transmission configuration indication states is a fourth preset value, and it is determined that the transmission mode is frequency division multiplexing mode or space division multiplexing mode;
- the number of transmission configuration indication states is greater than the fourth preset value, and it is determined that the transmission mode is the time division multiplexing mode.
- the processing unit determines that the configuration indication information is the transmission configuration indication information and the repeated transmission indication information; the transmission configuration indication information is used to indicate the transmission configuration indication state; the repeated transmission indication information is used for Indicate repeated transmission parameters in the time domain;
- the processing unit is specifically configured to determine that the transmission mode is the time division multiplexing mode according to the number of transmission configuration indication states and the time domain repeated transmission parameter.
- the processing unit is configured to obtain transmission mode indication information when the transceiver unit obtains the configuration information, where the transmission mode indication information is used to indicate the transmission mode; according to the transmission mode indication information Determine the transmission mode.
- the transmission mode is a space division multiplexing transmission mode, a first frequency division multiplexing transmission mode, a second frequency division multiplexing transmission mode, a first time division multiplexing transmission mode, or a second time division multiplexing transmission mode One or more of;
- the first frequency division multiplexing mode is a frequency division multiplexing mode based on a single codeword
- the second frequency division multiplexing mode is a frequency division multiplexing mode based on multiple codewords
- the first time division multiplexing mode The multiplexing mode is a time division multiplexing mode within a time slot unit
- the second time division multiplexing mode is a time division multiplexing mode between time slot units.
- the configuration information is used to indicate that the terminal device can use a code rate lower than a preset code rate, or used to instruct the terminal device to use a preset modulation and coding strategy table.
- FIG. 8 shows a schematic diagram of the structure of a communication device.
- the communication device 800 may be a network device, a terminal device, a chip, a chip system, or a processor that supports the network device to implement the above method, or a chip or a chip system that supports the terminal device to implement the above method. , Or processor, etc.
- the device can be used to implement the method described in the foregoing method embodiment, and for details, please refer to the description in the foregoing method embodiment.
- the communication device 800 may include one or more processors 801.
- the processor 801 may be a general-purpose processor or a special-purpose processor. For example, it can be a baseband processor or a central processing unit.
- the baseband processor can be used to process communication protocols and communication data
- the central processor can be used to control communication devices (such as base stations, baseband chips, terminals, terminal chips, DU or CU, etc.), execute software programs, and process Software program data.
- the communication device 800 may include one or more memories 802, on which instructions 804 may be stored, and the instructions may be executed on the processor 801, so that the device 800 executes the foregoing method implementation.
- the memory 802 may also store data.
- the processor 801 and the memory 802 can be provided separately or integrated together.
- the communication device 800 may further include a transceiver 805 and an antenna 806.
- the transceiver 805 may be referred to as a transceiver unit, a transceiver, a transceiver circuit, or a transceiver, etc., for implementing the transceiver function.
- the communication device 800 is a terminal device: the processor 801 is configured to perform step 602 in FIG. 6; and step 703 in FIG. 7 is performed.
- the transceiver 805 is used to execute step 601 in FIG. 6; execute step 701 and step 702 in FIG. Or, the transceiver 805 and the antenna 806 are used to perform step 601 in FIG. 6; and step 701 and step 702 in FIG. 7 are performed.
- the communication device 800 is a network device: the transceiver 805 is used to perform step 601 in FIG. 6; and step 701 and step 702 in FIG. 7 are performed. Or, the transceiver 805 and the antenna 806 are used to perform step 601 in FIG. 6; and step 701 and step 702 in FIG. 7 are performed.
- the processor 801 may also store an instruction 803, and the instruction 803 may be executed by the processor, so that the communication device 800 executes the method described in the foregoing method embodiment.
- the processor 801 may include a transceiver for implementing receiving and sending functions.
- the transceiver may be a transceiver circuit, or an interface, or an interface circuit.
- the transceiver circuits, interfaces, or interface circuits used to implement the receiving and sending functions can be separate or integrated.
- the foregoing transceiver circuit, interface, or interface circuit can be used for code/data reading and writing, or the foregoing transceiver circuit, interface, or interface circuit can be used for signal transmission or transmission.
- the communication device 800 may include a circuit, which may implement the sending or receiving or communication function in the foregoing method embodiment.
- the processor and transceiver described in this application can be implemented in integrated circuit (IC), analog IC, radio frequency integrated circuit RFIC, mixed signal IC, application specific integrated circuit (ASIC), printed circuit board ( printed circuit board, PCB), electronic equipment, etc.
- the processor and transceiver can also be manufactured using various IC process technologies, such as complementary metal oxide semiconductor (CMOS), nMetal-oxide-semiconductor (NMOS), and P-type Metal oxide semiconductor (positive channel metal oxide semiconductor, PMOS), bipolar junction transistor (Bipolar Junction Transistor, BJT), bipolar CMOS (BiCMOS), silicon germanium (SiGe), gallium arsenide (GaAs), etc.
- CMOS complementary metal oxide semiconductor
- NMOS nMetal-oxide-semiconductor
- PMOS bipolar junction transistor
- BiCMOS bipolar CMOS
- SiGe silicon germanium
- GaAs gallium arsenide
- the communication device described in the above embodiment may be a network device or a terminal device, but the scope of the communication device described in this application is not limited to this, and the structure of the communication device may not be limited by FIG. 8.
- the communication device may be a stand-alone device or may be part of a larger device.
- the communication device may be:
- the IC collection can also include storage components for storing data and instructions;
- ASIC such as modem (MSM)
- FIG. 9 provides a schematic structural diagram of a terminal device.
- the terminal device 900 includes a processor, a memory, a control circuit, an antenna, and an input and output device.
- the processor is mainly used to process the communication protocol and communication data, and to control the entire terminal, execute the software program, and process the data of the software program.
- the memory is mainly used to store software programs and data.
- the radio frequency circuit is mainly used for the conversion of baseband signal and radio frequency signal and the processing of radio frequency signal.
- the antenna is mainly used to send and receive radio frequency signals in the form of electromagnetic waves.
- Input and output devices such as touch screens, display screens, and keyboards, are mainly used to receive data input by users and output data to users.
- the processor can read the software program in the storage unit, parse and execute the instructions of the software program, and process the data of the software program.
- the processor performs baseband processing on the data to be sent, and outputs the baseband signal to the radio frequency circuit.
- the radio frequency circuit processes the baseband signal to obtain a radio frequency signal and sends the radio frequency signal out in the form of electromagnetic waves through the antenna. .
- the radio frequency circuit receives the radio frequency signal through the antenna, the radio frequency signal is further converted into a baseband signal, and the baseband signal is output to the processor, and the processor converts the baseband signal into data and performs processing on the data. deal with.
- FIG. 9 only shows a memory and a processor. In actual terminal devices, there may be multiple processors and memories.
- the memory may also be referred to as a storage medium or a storage device, etc., which is not limited in the embodiment of the present invention.
- the processor may include a baseband processor and a central processing unit.
- the baseband processor is mainly used to process communication protocols and communication data.
- the central processing unit is mainly used to control the entire terminal device and execute Software program, processing the data of the software program.
- the processor in FIG. 9 integrates the functions of the baseband processor and the central processing unit.
- the baseband processor and the central processing unit may also be independent processors, which are interconnected by technologies such as buses.
- the terminal device may include multiple baseband processors to adapt to different network standards, the terminal device may include multiple central processors to enhance its processing capabilities, and various components of the terminal device may be connected through various buses.
- the baseband processor can also be expressed as a baseband processing circuit or a baseband processing chip.
- the central processing unit can also be expressed as a central processing circuit or a central processing chip.
- the function of processing the communication protocol and communication data can be built in the processor, or can be stored in the storage unit in the form of a software program, and the processor executes the software program to realize the baseband processing function.
- the present application also provides a computer-readable medium on which a computer program is stored, and when the computer program is executed by a computer, the function of any of the foregoing method embodiments is realized.
- This application also provides a computer program product, which, when executed by a computer, realizes the functions of any of the foregoing method embodiments.
- the computer program product includes one or more computer instructions.
- the computer may be a general-purpose computer, a special-purpose computer, a computer network, or other programmable devices.
- the computer instructions may be stored in a computer-readable storage medium or transmitted from one computer-readable storage medium to another computer-readable storage medium. For example, the computer instructions may be transmitted from a website, computer, server, or data center.
- the computer-readable storage medium may be any available medium that can be accessed by a computer or a data storage device such as a server or a data center integrated with one or more available media.
- the usable medium may be a magnetic medium (for example, a floppy disk, a hard disk, a magnetic tape), an optical medium (for example, a high-density digital video disc (digital video disc, DVD)), or a semiconductor medium (for example, a solid state disk, SSD)) etc.
- the corresponding relationships shown in the tables in this application can be configured or pre-defined.
- the value of the information in each table is only an example and can be configured to other values, which is not limited in this application.
- it is not necessarily required to configure all the correspondences indicated in the tables.
- the corresponding relationship shown in some rows may not be configured.
- appropriate deformation adjustments can be made based on the above table, such as splitting, merging, and so on.
- the names of the parameters shown in the titles in the above tables may also be other names that can be understood by the communication device, and the values or expressions of the parameters may also be other values or expressions that can be understood by the communication device.
- other data structures can also be used, such as arrays, queues, containers, stacks, linear tables, pointers, linked lists, trees, graphs, structures, classes, heaps, hash tables, or hash tables. Wait.
- the pre-definition in this application can be understood as definition, pre-definition, storage, pre-storage, pre-negotiation, pre-configuration, curing, or pre-fired.
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Abstract
本申请实施例提供一种传输模式确定方法及装置,用于区分uRLLC场景和eMBB场景中的多种传输模式。该方法可以包括如下步骤:终端设备获取配置指示信息,该配置指示信息为DMRS指示信息、重复传输指示信息或传输配置信息中的一种或多种;根据该配置指示信息确定传输模式,传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。采用本申请实施例,终端设备可以识别网络设备采用的传输模式,进而终端设备可以根据确定的传输模式进行相应的接收处理。
Description
本申请实施例涉及通信技术领域,具体涉及一种传输模式确定方法及装置。
随着通信技术的发展,第五代(5
th-generation)通信系统(或称为新空口(new radio,NR))应运而生,5G系统包括三大应用场景,分别为移动增强带宽(enhanced mobile broadband,eMBB)、高可靠低时延通信(ultra reality and low latency communication,uRLLC)和海量机器类通信(massive machine type communications,mMTC)。
目前,在uRLLC场景中采用重复传输以提高传输的鲁棒性,该重复传输可以是空域上的重复传输、频域上的重复传输或时域上的重复传输中的一种或多种。空域上的重复传输即空域复用(spatial domain multiplexing,SDM),对应一种传输模式;频域上的重复传输即为(frequency domain multiplexing,FDM),对应两种传输模式;时域上的重复传输即为(time domain multiplexing,TDM),对应两种传输模式。针对eMBB场景以及uRLLC场景中的多种传输模式,终端侧如何识别网络侧采用的传输模式是亟待解决的技术问题。
发明内容
本申请实施例提供一种传输模式确定方法及装置,可以识别网络侧采用的传输模式,以便终端侧根据该传输模式进行接收处理。
本申请实施例第一方面提供一种传输模式确定方法,包括:
获取配置指示信息,该配置指示信息为调制解调参考信号(demodulation reference signal,DMRS)指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;
根据该配置指示信息确定传输模式,传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
本申请实施例第一方面提供的方法,可以由终端设备执行,也可以由终端设备的部件(例如处理器、芯片、或芯片系统等)执行。终端设备根据配置指示信息,识别网络设备采用的传输模式,进而终端设备可根据该传输模式进行相应的接收处理。
其中,DMRS指示信息可以用于指示DMRS端口标识,还可以用于指示DMRS端口标识和未承载数据的码分复用(code division multiplexing,CDM)组的数量。
本申请实施例中的DMRS指示信息也可以描述为天线端口指示信息。DMRS端口的索引与天线端口的索引之间的关系为:DMRS端口的索引+1000=天线端口的索引。
重复传输指示信息用于指示时域重复传输参数,或用于指示第一时域重复传输参数和第二时域重复传输参数,或用于指示时域重复传输参数和频域重复传输参数,或用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数。
传输配置指示(transmission configuration indication,TCI)信息用于指示传输过程的TCI状态。TCI信息可以是TCI码点(codepoint),在多站传输的情况下,一个TCI codepoint可以指示两个或两个以上的TCI状态。在一种可能的实现方式中,上述配置指示信息为重复传输指示信息,重复传输指示信息用于指示时域重复传输参数。终端设备在获取到该配 置指示信息的情况下,即获取到时域重复传输参数,根据时域重复传输参数确定传输模式为时分复用模式。该方式中,通过获取到的时域重复传输参数识别出传输模式为时分复用模式。反之,终端设备未获取到该配置信息的情况下,即未获取到时域重复传输参数,确定传输模式不可能为时分复用模式,即有可能为频分复用模式、空分复用模式或频分复用模式与空分复用模式的组合模式中的任一种。
在一种可能的实现方式中,在通过时域重复传输参数识别出传输模式为时分复用模式的情况下,可进一步区分时分复用模式为第一时分复用模式还是第二时分复用模式。第一时分复用模式为时隙单元内的时分复用模式,第二时分复用模式为时隙单元间的时分复用模式。
若时域重复传输参数为第一时域重复传输参数,那么可确定时分复用模式为第一时分复用模式;若时域重复传输参数为第二时域重复传输参数,那么可确定时分复用模式为第二时分复用模式。
若时域重复传输参数包括第一时分复用模式的特有参数,那么可确定时分复用模式为第一时分复用模式。例如时域重复传输参数包括偏移信息(offset),那么可确定时分复用模式为第一时分复用模式;反之,可确定时分复用模式为第二时分复用模式。其中,偏移信息可表示多个物理下行共享信道(physical downlink shared channel,PDSCH)的时域位置的偏移信息。
在一种可能的实现方式中,上述配置指示信息为重复传输指示信息,重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数。终端设备在获取到该配置指示信息的情况下,即获取到第一时域重复传输参数和第二时域重复传输参数,根据第一时域重复传输参数和第二时域重复传输参数的数值来确定传输模式是否为时分复用模式。终端设备未获取到该配置信息的情况下,即未获取到第一时域重复传输参数和第二时域重复传输参数,确定传输模式为频分复用模式、空分复用模式或频分复用模式与空分复用模式的组合模式。
根据第一时域重复传输参数和第二时域重复传输参数的数值来确定传输模式是否为时分复用模式,可包括:若第一时域重复传输参数和第二时域重复传输参数的数值均为第一预设值,那么确定传输模式为频分复用模式、空分复用模式或频分复用模式与空分复用模式的组合模式;若第一时域重复传输参数的数值或第二时域重复传输参数的数值中一个或多个大于第一预设值,确定传输模式为时分复用模式。其中,第一预设值可以为“1”。
在一种可能的实现方式中,在通过第一时域重复传输参数和第二时域重复传输参数识别出传输模式为时分复用模式的情况下,可进一步区分第一时分复用模式和第二时分复用模式。第一时分复用模式为时隙单元内的时分复用模式,第二时分复用模式为时隙单元间的时分复用模式。
若第一时域重复传输参数的数值为第一预设值,第二时域重复传输参数的数值大于第一预设值,那么确定时分复用模式为第二时分复用模式;若第二时域重复传输参数的数值为第一预设值,第一时域重复传输参数的数值大于第一预设值,那么确定时分复用模式为第一时分复用模式;若第一时域重复传输参数的数值和第二时域重复传输参数的数值均大于第一预设值,那么确定时分复用模式为第一时分复用模式与第二时分复用模式的组合模 式。
在区分出时分复用模式的情况下,可根据配置指示信息为DMRS指示信息区分空分复用模式和频分复用模式。
在一种可能的实现方式中,根据DMRS指示信息确定DMRS端口标识,根据DMRS端口标识确定传输模式。
方式一,若DMRS端口标识对应的CDM组的数量为第二预设值,那么确定传输模式为频分复用模式;若DMRS端口标识对应的CDM组的数量为第三预设值,那么确定传输模式为空分复用模式。其中,第二预设值可以为1,表示1个CDM组。
方式二,若DMRS端口标识属于同一个CDM组,那么确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式。
方式三,若DMRS端口标识的数量为第二预设值,那么确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式。其中,第二预设值可以为1,表示1个CDM组;第三预设值可以为2,表示2个CDM组。
方式四,若DMRS端口标识属于预设标识,那么确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式。其中,预设标识可以是[0],[1]或[0,1]。
上述四种根据DMRS端口标识确定传输模式的方式用于举例,并不构成对本申请实施例的限定。
在一种可能的实现方式中,根据DMRS指示信息确定CDM组的数量,根据CDM组的数量确定传输模式。若CDM组的数量为第二预设值,那么确定传输模式为频分复用模式;若CDM组的数量为第三预设值,那么确定传输模式为空分复用模式。
在一种可能的实现方式中,在确定出传输模式为频分复用模式的情况下,可进一步区分频分复用模式为第一频分复用模式还是第二频分复用模式。第一频分复用模式为基于单码字的频分复用模式,第二频分复用模式为基于多码字的频分复用模式。
若获取到频域重复传输参数,那么确定频分复用模式为第二频分复用模式;若未获取到频域重复传输参数,那么确定频分复用模式为第一频分复用模式。
在一种可能的实现方式中,上述配置指示信息为重复传输指示信息,重复传输指示信息用于指示时域重复传输参数。根据时域重复传输参数确定传输模式为第二时分复用模式,第二时分复用模式为时隙单元间的时分复用模式。
在一种可能的实现方式中,在区分出传输模式为第二时分复用模式的情况下,可根据配置指示信息为DMRS指示信息区分其余几种传输模式。根据DMRS指示信息确定DMRS端口信息,根据DMRS端口信息确定其余几种传输模式。
在一种可能的实现方式中,DMRS端口信息包括DMRS端口标识和未承载数据的CDM组的数量,根据DMRS端口标识对应的CDM组的数量和未承载数据的CDM组的数量,确定传输模式为空分复用模式、频分复用模式或第一时分复用模式;若确定出传输模式为频分复用模式,根据DMRS端口标识对应的CDM组的组标识确定传输模式为第一频分复用模式或第二频分复用模式。其中,第一时分复用模式为时隙单元内的时分复用模式,第一频分复用模式为基于单码字的频分复用模式,第二频分复用模式为基于多码字的频分复用模式。
示例性的,若DMRS端口标识对应的CDM组的数量为第三预设值,那么确定传输模式为空分复用模式;若DMRS端口标识对应的CDM组的数量为第二预设值,未承载数据的CDM组的数量为第二预设值,那么确定传输模式为第一时分复用模式,第一时分复用模式为时隙单元内的时分复用模式;若DMRS端口标识对应的CDM端口组的数量为第二预设值,DMRS CDM的组的数量为第三预设值,那么确定传输模式为频分复用模式。在确定出传输模式为频分复用模式的情况下,若DMRS端口标识对应的CDM组的组标识为第一标识,那么确定传输模式为第一频分复用模式;若DMRS端口标识对应的CDM组的组标识为第二标识,那么确定传输模式为第二频分复用模式。
在一种可能的实现方式中,上述配置指示信息为DMRS指示信息和重复传输指示信息,重复传输指示信息用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数。重复传输指示信息可通过{a,b,c}来表示,例如a表示频域重复传输参数,b表示第一时域重复传输参数,c表示第二时域重复传输参数。
根据DMRS指示信息确定CDM组的数量,根据CDM组的数量、频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数确定传输模式。例如,根据DMRS指示信息确定出CDM组的数量为两个,重复传输指示信息为{1,1,1},那么可确定传输模式为空分复用模式。
在一种可能的实现方式中,上述配置指示信息为TCI信息,TCI信息用于指示TCI状态。若TCI状态的数量为第四预设值,那么可确定传输模式为频分复用模式或空分复用模式;若TCI状态的数量大于第四预设值,那么可确定传输模式为时分复用模式。其中,第四预设值可以为2,表示2个TCI状态。
在一种可能的实现方式中,上述配置指示信息为TCI信息和重复传输指示信息,TCI信息用于指示TCI状态,重复传输指示信息用于指示时域重复传输参数,根据TCI状态的数量和时域重复传输参数,确定传输模式为时分复用模式。
本申请实施例第二方面提供一种传输模式确定方法,包括:
在获取到配置信息的情况下,获取传输模式指示信息,该传输模式指示信息用于指示传输模式;
根据传输模式指示信息确定传输模式。
本申请实施例第二方面提供的方法,可以由终端设备执行,也可以由终端设备的部件(例如处理器、芯片、或芯片系统等)执行。通过配置信息与传输模式指示信息,可以实现多站uRLLC的特定场景与多站eMBB场景的动态切换,不需要增加额外的指示开销。
其中,配置信息可以理解为指示uRLLC场景的配置信息,从而区别多站uRLLC场景与多站eMBB场景。
在一种可能的实现方式中,配置信息可用于指示多站uRLLC场景的专属特性,例如用于指示终端设备能够使用低于预设码率的码率,或者用于指示终端设备使用预设的调制编码策略表。预设码率可以是为120*1024(kbps),预设的调制编码策略表可以是调制编码策略表3,表3中才会存在低于120*1024(kbps)的码率。该方式中,配置信息可以是新定义的无线网络临时标识(radio network temporary identity,RNTI)或新定义的下行控制信息(downlink control information,DCI)中的域。终端设备在检测到该配置信息的情况下,可 以认为当前传输场景为多站uRLLC场景;否则可以认为当前传输场景为多站eMBB场景。
在一种可能的实现方式中,配置信息可以复用已有多站uRLLC场景相关的配置信息,例如调制编码策略小区无线网络临时标识(modulation and coding scheme cell radio network temporary identity,MCS-C-TNTI)。终端设备检测到MCS-C-RNTI的情况下,终端设备可认为当前传输场景为多站uRLLC场景;否则可认为当前传输场景为多站eMBB场景。
在一种可能的实现方式中,配置信息可用于直接指示当前传输场景为多站uRLLC场景,终端设备在检测到该配置信息的情况下,可认为当前传输场景为多站uRLLC场景,否则可认为当前传输场景为多站eMBB场景。该方式中,配置信息可以是新定义的RNTI或新定义的DCI中的域。
另一种可能的实现方式中,配置信息可以理解为指示eMBB场景的配置信息,例如指示多站eMBB场景的专属特性,或者复用已有多站eMBB场景相关的配置信息,或者配置信息可用于直接指示当前传输场景为多站eMBB场景。
其中,传输模式指示信息可以携带在下行控制信息中,或携带在无线资源控制信令中。传输模式为空分复用传输模式、第一频分复用传输模式、第二频分复用传输模式、第一时分复用传输模式或第二时分复用传输模式中的一种或多种;其中,第一频分复用模式为基于单码字的频分复用模式,第二频分复用模式为基于多码字的频分复用模式;第一时分复用模式为时隙单元内的时分复用模式,第二时分复用模式为时隙单元间的时分复用模式。
本申请实施例第三方面提供一种通信装置,该通信装置可以是终端设备,也可以是终端设备中的装置,或者是能够与终端设备匹配使用的装置。该通信装置具有实现第一方面或第二方面所述方法示例中终端设备的部分或全部功能,例如终端设备的功能可具备本申请实施例中的部分或全部实施例中的功能,也可以具备单独实施本申请中的任一个实施例的功能。该功能可以通过硬件实现,也可以通过硬件执行相应的软件实现。该硬件或软件包括一个或多个与上述功能相对应的单元或模块。
一种可能的设计中,终端设备的结构中可包括处理单元和收发单元。处理单元被配置为支持终端设备执行上述方法中相应的功能。收发单元用于支持终端设备与其他设备之间的通信。终端设备还可以包括存储单元,存储单元用于与处理单元和收发单元耦合,其保存终端设备必要的程序指令和数据。
一种实施方式中,终端设备包括处理单元和收发单元;
收发单元,用于获取配置指示信息,该配置指示信息为DMRS指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;
处理单元,用于根据配置指示信息确定传输模式,传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
作为示例,处理单元可以为处理器,通信单元可以为收发器,存储单元可以为存储器。
一种实施方式中,终端设备包括处理单元和收发单元;
收发器,用于获取配置指示信息,该配置指示信息为DMRS指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;
处理器,用于根据配置指示信息确定传输模式,传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
在具体实现过程中,处理器可用于进行,例如但不限于,基带相关处理,收发器可用于进行,例如但不限于,射频收发。上述器件可以分别设置在彼此独立的芯片上,也可以至少部分的或者全部的设置在同一块芯片上。例如,处理器可以进一步划分为模拟基带处理器和数字基带处理器。其中,模拟基带处理器可以与收发器集成在同一块芯片上,数字基带处理器可以设置在独立的芯片上。随着集成电路技术的不断发展,可以在同一块芯片上集成的器件越来越多,例如,数字基带处理器可以与多种应用处理器(例如但不限于图形处理器,多媒体处理器等)集成在同一块芯片之上。这样的芯片可以称为系统芯片(system on chip)。将各个器件独立设置在不同的芯片上,还是整合设置在一个或者多个芯片上,往往取决于产品设计的具体需要。本发明实施例对上述器件的具体实现形式不做限定。
本申请实施例第四方面提供一种处理器,用于执行上述各种方法。在执行这些方法的过程中,上述方法中有关发送上述信息或数据和接收上述信息或数据的过程,可以理解为由处理器输出上述信息或数据的过程,以及处理器接收输入的上述信息或数据的过程。具体来说,在输出上述信息或数据时,处理器将上述信息或数据输出给收发器,以便由收发器进行发射。更进一步的,上述信息或数据在由处理器输出之后,还可能需要进行其他的处理,然后才到达收发器。类似的,处理器接收输入的上述信息或数据时,收发器接收上述信息或数据,并将其输入处理器。更进一步的,在收发器收到上述信息或数据之后,上述信息或数据可能需要进行其他的处理,然后才输入处理器。
基于上述原理,举例来说,前述方法中提及的获取配置信息可以理解为收发器将其接收到的配置信息输入处理器。
如此一来,对于处理器所涉及的发射、发送和接收等操作,如果没有特殊说明,或者,如果未与其在相关描述中的实际作用或者内在逻辑相抵触,则均可以更加一般性的理解为处理器输出和接收、输入等操作,而不是直接由射频电路和天线所进行的发射、发送和接收操作。
在具体实现过程中,上述处理器可以是专门用于执行这些方法的处理器,也可以是执行存储器中的计算机指令来执行这些方法的处理器,例如通用处理器。上述存储器可以为非瞬时性(non-transitory)存储器,例如只读存储器(read only memory,ROM),其可以与处理器集成在同一块芯片上,也可以分别设置在不同的芯片上,本发明实施例对存储器的类型以及存储器与处理器的设置方式不做限定。
本申请实施例第五方面提供一种芯片系统,该芯片系统包括至少一个处理器和接口,用于支持终端设备实现第一方面或第二方面所涉及的功能,例如根据配置指示信息确定传输模式。在一种可能的设计中,该芯片系统还包括存储器,存储器用于保存终端设备必要的程序指令和数据。该芯片系统,可以由芯片构成,也可以包括芯片和其他分立器件。
本申请实施例第六方面提供一种计算机可读存储介质,用于储存为上述终端设备所用的计算机软件指令,其包括用于执行上述方法的第一方面或第二方面所涉及的程序。
本申请实施例第七方面提供一种包括指令的计算机程序产品,当其在计算机上运行时,使得计算机执行上述第一方面或第二方面所述的方法。
本申请实施例第八方面提供一种包括指令的计算机程序,当其在计算机上运行时,使得计算机执行上述第一方面或第二方面所述的方法。
图1为应用本申请实施例的一种网络架构示意图;
图2为应用本申请实施例的另一种网络架构示意图;
图3a为空分复用模式的传输示例图;
图3b为空分复用模式的物理层处理流程的简化示意图;
图4a为频分复用模式的传输示例图;
图4b为第一频分复用模式的物理层处理流程的简化示意图;
图4c为第一频分复用模式的物理层处理流程的简化示意图;
图5a为第一时分复用模式的传输示例图;
图5b为第二时分复用模式的传输示例图;
图5c为时分复用模式的物理层处理流程的简化示意图;
图6为本申请实施例提供的一种传输模式确定方法的流程示意图;
图7为本申请实施例提供的另一种传输模式确定方法的流程示意图;
图8为本申请实施例提供的一种通信装置的结构示意图;
图9为本申请实施例提供的一种终端设备的结构示意图。
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描述。其中,在本申请实施例的描述中,除非另有说明,“/”表示前后关联的对象是一种“或”的关系,例如,A/B可以表示A或B。在本申请的描述中,除非另有说明,“多个”是指两个或多于两个。“以下至少一项(个)”或其类似表达,是指的这些项中的任意组合,包括单项(个)或复数项(个)的任意组合。例如,a,b,或c中的至少一项(个),可以表示:a,b,c,a和b,a和c,b和c,或a和b和c,其中a,b,c可以是单个,也可以是多个。另外,为了便于清楚描述本申请实施例的技术方案,在本申请的实施例中,采用了“第一”、“第二”等字样对功能和作用基本相同或相似的技术特征进行区分。本领域技术人员可以理解“第一”、“第二”等字样并不对数量和执行次序进行限定,并且“第一”、“第二”等字样也并不限定一定不同。
本申请实施例可以应用于长期演进(Long Term Evolution,LTE)系统、NR系统,还可以应用于未来通信系统,例如未来网络或第六代通信系统等。本申请实施例可以应用于设备到设备(device to device,D2D)系统,机器到机器(machine to machine,M2M)系统、车与任何事物通信的车联网(vehicle to everything,V2X)系统等。
V2X系统中的通信方式统称为V2X通信。V2X通信针对以车辆为代表的高速设备,是未来对通信时延要求非常高的场景下应用的基础技术和关键技术,如智能汽车、自动驾驶、智能交通运输系统等场景。例如,该V2X通信包括:车辆与车辆(vehicle to vehicle,V2V)之间的通信,车辆与路边基础设施(vehicle to infrastructure,V2I)之间的通信、车辆与行人之间的通信(vehicle to pedestrian,V2P)或车辆与网络(vehicle to network,V2N)之间的通信等。V2X系统中所涉及的终端设备之间进行的通信被广泛称为侧行链路(slidelink,SL)通信。也就是说,本申请所述的终端也可以为车辆或应用于车辆中的车辆组件。
图1是本申请实施例提供的V2X系统的示意图。该示意图包括V2V通信、V2P通信 以及V2I/N通信。
如图1所示,车辆或车辆组件之间通过V2V通信。车辆或车辆组件可以将自身的车速、行驶方向、具体位置、是否踩了紧急刹车等信息广播给周围车辆,周围车辆的驾驶员通过获取该类信息,可以更好的感知视距外的交通状况,从而对危险状况做出提前预判进而做出避让;车辆或车辆组件与路侧基础设施通过V2I通信,路边基础设施,可以为车辆或车辆组件提供各类服务信息和数据网络的接入。其中,不停车收费、车内娱乐等功能都极大的提高了交通智能化。路边基础设施,例如,路侧单元(road side unit,RSU)包括两种类型:一种是终端设备类型的RSU。由于RSU分布在路边,该终端设备类型的RSU处于非移动状态,不需要考虑移动性;另一种是网络设备类型的RSU。该网络设备类型的RSU可以给与网络设备通信的车辆或车辆组件提供定时同步及资源调度。车辆或车辆组件与人通过V2P通信;车辆或车辆组件与网络通过V2N通信。其中,本申请公开的实施例描述的网络架构以及业务场景是为了更加清楚的说明本申请公开的实施例的技术方案,并不构成对于本申请公开的实施例提供的技术方案的限定,本领域普通技术人员可知,随着网络架构的演变和新业务场景的出现,本申请公开的实施例提供的技术方案对于类似的技术问题,同样适用。
请参见图2,为应用本申请实施例的另一种网络架构示意图。该网络架构可包括三个网络设备和一个终端设备,图2所示的设备数量和形态用于举例并不构成对本申请实施例的限定,实际应用中可以包括一个、两个或更多个网络设备,两个或更多个终端设备。其中:网络设备可用于在网络设备控制器(未示出)的控制下,通过无线接口与终端设备通信。在一些实施例中,网络设备控制器可以是核心网的一部分,也可以集成到网络设备中。网络设备可用于通过回传(backhaul)接口向核心网传输控制信息或者用户数据。网络设备之间也可以通过回传(backhaul)接口,直接地或者间接地,相互通信。
本申请实施例中,网络设备可以是任意一种具有无线收发功能的设备。包括但不限于:LTE系统中的基站或NR系统中的基站(gNodeB或gNB)或NR系统中的传输接收点(transmission receiving point/transmission reception point,TRP),3GPP后续演进的基站,WiFi系统中的接入节点,无线中继节点,无线回传节点等。基站可以是:宏基站,微基站,微微基站,小站,中继站,或,气球站等。多个基站可以支持上述提及的同一种技术的网络,也可以支持上述提及的不同技术的网络。基站可以包含一个或多个共站或非共站的TRP。TRP在一种实现中,可以是网络设备例如基站,还可以是基站的天线面板、面板等。网络设备还可以是云无线接入网络(cloud radio access network,CRAN)场景下的无线控制器、集中单元(centralized unit,CU),和/或,分布单元(distributed unit,DU)。网络设备还可以是服务器,可穿戴设备,或车载设备等。以下以网络设备为基站为例进行说明。所述多个网络设备可以为同一类型的基站,也可以为不同类型的基站。基站可以与终端设备进行通信,也可以通过中继站与终端设备进行通信。
终端设备是一种具有无线收发功能的设备,可以部署在陆地上,包括室内或室外、手持、穿戴或车载;也可以部署在水面上(如轮船等);还可以部署在空中(例如飞机、气球和卫星上等)。所述终端设备可以是手机(mobile phone)、平板电脑(Pad)、带无线收发功能的电脑、虚拟现实(virtual reality,VR)终端设备、增强现实(augmented reality,AR) 终端设备、工业控制(industrial control)中的无线终端、车载终端设备、无人驾驶(self driving)中的无线终端、远程医疗(remote medical)中的无线终端、智能电网(smart grid)中的无线终端、运输安全(transportation safety)中的无线终端、智慧城市(smart city)中的无线终端、智慧家庭(smart home)中的无线终端、可穿戴终端设备等等。本申请的实施例对应用场景不做限定。终端设备有时也可以称为终端、用户设备(user equipment,UE)、接入终端设备、车载终端、工业控制终端、UE单元、UE站、移动站、移动台、远方站、远程终端设备、移动设备、UE代理或UE装置等。终端设备也可以是固定的或者移动的。
为了提高可靠性,常用的方法是利用信道的分集增益,分集增加包括了信道在时域、频域、空域等至少一个维度中的分集。信道的分集增益,是指通过信道在时域、频域、空域等至少一个维度的低相关性,或者信道在时域、频域、空域等至少一个维度的多次传输具有统计意义上的独立特征,使得通信过程能够利用这些独立的信道,降低信道衰落的影响。
其中,信道的空域分集增益,例如可以是多站的独立信道分集增益。网络中可能存在多个网络设备,多个网络设备之间可以进行协作传输,即多站协作传输技术。在多站协作传输技术中,终端设备可能会被多个网络设备调度,例如多个网络设备调度终端设备接收多份数据,这样可以提高用户的吞吐率,提高用户感知速率。反之,终端设备也可以向多个网络设备分别发送数据,多个网络设备可分别接收数据,还可对数据进行合并。多个网络设备在地理上可以不同,从而造成多个网络设备到终端设备的多个独立信道具有低相关性。因此,多站协作传输技术可以应用于对通信可靠性要求较高的场景中,使得系统可以利用低相关性的信道分集增益。
目前,NR系统的uRLLC场景可以支持多种基于多站协作传输技术的重复传输方式,重复传输方式可分为空域、频域或时域上的重复传输方式。目前存在五种重复传输方式,本文中将这五种重复传输方式称为传输模式,网络设备可采用一种或多种传输模式向终端设备发送数据,终端设备需识别网络设备采用的传输模式,以便进行相应的接收处理。
本申请实施例提供一种传输模式确定方法及装置,终端设备可以识别网络设备采用的传输模式,以便进行相应的接收处理。本申请实施例可以应用于在uRLLC场景中区分多种传输模式,多种传输模式不局限于目前的五种传输模式。本申请实施例还可以应用于区分多站uRLLC场景和多站eMBB场景。
本申请实施例描述的网络架构以及业务场景是为了更加清楚的说明本申请实施例的技术方案,并不构成对于本申请实施例提供的技术方案的限定,本领域普通技术人员可知,随着网络架构的演变和新业务场景的出现,本申请实施例提供的技术方案对于类似的技术问题,同样适用。
首先,在描述本申请实施例之前,对本申请实施例涉及的名称或术语进行介绍。
(1)本申请实施例涉及的几种的传输模式。
1、空分复用模式
SDM模式,为空域上的重复传输模式,指的是多个TRP共同传输同一传输块,不同TRP调度相同的时频资源,映射的天线端口不同,因此可以利用空域的分集增益。
媒体接入控制(media access control,MAC)层发往物理层的数据是以传输块(transport block,TB)的形式组成的。MAC层发往物理层的是一个TB。网络设备对每个TB进行信道编码处理,并将信道编码处理后的传输块进行速率匹配存储到环形缓冲器中。基于冗余版本(redundancy version,RV)从该环形缓冲器中获取的码字(code word,CW)可以看作是具有出错保护的TB。码字进行层映射后,会映射到一个或多个数据传输层(简称Layer),每个数据传输层对应一条有效的数据流。每层的数据流经过天线端口映射,映射到天线端口(antenna port)。天线端口映射的过程也可以称为预编码,即通过预编码矩阵将每层的数据流映射到天线端口的过程。预编码后的数据流被映射到物理时频资源上,转换为信号由网络设备发送出去。
示例性的,可参见图3a,为空分复用模式的传输示例图。图3a中,TRP 1与TRP 2调度完全相同的时频资源,该时频资源的时域调度单位是时隙(slot),或微时隙(mini-slot)。TRP 1传输物理下行共享信道(physical downlink shared channel,PDSCH)1的天线端口与TRP 2传输PDSCH 2的天线端口不同,天线端口的不同涉及物理层处理流程,可参见图3b,为空分复用模式的物理层处理流程的简化示意图。
图3b中,TRP 1和TRP 2共同传输一个传输块,TRP 1或TRP 2可对该传输块进行信道编码和速率匹配处理。该传输块经过信道编码和速率匹配的处理,基于单冗余版本获得一个CW。之后,该CW在层映射过程中映射到两个数据传输层,例如Layer 0、Layer 1。数据传输层Layer 0的数据流通过天线端口映射,映射到天线端口0;数据传输层Layer 1的数据流通过天线端口映射,映射到天线端口2。之后,天线端口0的数据流通过资源映射,获得PDSCH1;天线端口2的数据流通过资源映射,获得PDSCH 2,PDSCH 1和PDSCH 2映射到相同的时频资源上。进而,TRP 1可以发送PDSCH 1,TRP 2可以发送PDSCH 2。其中,PDSCH 1携带该传输块的一半信息比特,PDSCH 2携带该传输块的另一半信息比特。
在另一种可能的实现方式中,在天线端口映射过程中,数据传输层Layer 0的数据流通过天线端口映射,映射到CDM组0;数据传输层Layer 1的数据流通过天线端口映射,映射到CDM组1。即对于SDM模式,在天线端口映射过程中,可以将不同数据传输层的数据流映射到不同的CDM组。
SDM模式与目前多站eMBB的传输模式相同。SDM模式也可以称为方案1a(scheme 1a)或空分复用方案等。
2、频分复用模式
FDM模式,为频域上的重复传输模式,指的是多个TRP共同传输同一传输块,或多个TRP分别传输一个传输块,不同TRP调度的频域资源不同,时域资源相同。FDM模式中,多个TRP在传输过程中,可以使用一个或多个天线端口。
示例性的,可参见图4a,为频分复用模式的传输示例图。图4a中,TRP 1与TRP 2调度的时域资源相同,频域资源不同且完全不交叠。两个TRP进行FDM传输,相当于每个TRP调度一半的频域资源,因此存在一个3分贝(dB)的功率提升(power boost),这便是FDM模式的主要增益来源。
FDM模式可以分为基于单码字的FDM模式和基于多码字的FDM模式,基于单码字的FDM模式即为基于一个码字的单冗余版本的FDM模式,基于多码字的FDM模式即为基于多个码字的多冗余版本的FDM模式。
为了便于区分,本申请实施例中将基于单码字的FDM模式称为第一FDM模式,将基于多码字的FDM模式称为第二FDM模式。基于单码字的FDM模式也可以称为scheme 2a等,基于多码字的FDM模式也可以称为scheme 2b等。
对于第一FDM模式,可参见图4b所示的第一频分复用模式的物理层处理流程的简化示意图。图4b中,TRP 1和TRP 2共同传输一个传输块,TRP 1或TRP 2可对该传输块进行信道编码和速率匹配处理。该传输块经过信道编码和速率匹配的处理,基于单冗余版本获得一个CW。之后,该CW在层映射过程中映射到一个或两个数据传输层。之后,在天线端口映射过程中,映射到一个或两个天线端口。若在层映射过程中映射到一个数据传输层,那么在天线端口映射过程中,映射到一个天线端口;若在层映射过程中映射到两个数据传输层,那么在天线端口映射过程中,映射到两个天线端口。之后,在资源映射过程中,映射到两部分完全不交叠的频域资源上,获得PDSCH 1和PDSCH 2。其中,PDSCH 1携带该传输块的一半信息比特,PDSCH 2携带该传输块的另一半信息比特。
对于第二FDM模式,可参见图4c所示的第二频分复用模式的物理层处理流程的简化示意图。图4c中,TRP 1和TRP 2分别传输一个完全相同的传输块,一个传输块经过信道编码和速率匹配的处理,基于冗余版本0获得一个CW,另一个传输块经过信道编码和速率匹配的处理,基于冗余版本1获得另一个CW,这两个CW的冗余版本不同。之后,这两个CW在层映射过程中映射到相同的数据传输层。之后,在天线端口映射过程中,映射到相同的天线端口,例如端口0。之后,在资源映射过程中,映射到两部分完全不交叠的频域资源上,获得PDSCH 1和PDSCH 2。其中,PDSCH 1与PDSCH 2均携带同一个传输块的信息比特,但是添加了不同的冗余比特,终端设备可以进行信息的软比特合并,得到合并增益。
3、时分复用模式
TDM模式,为时域上的重复传输模式,指的是多个TRP分别传输一个传输块,不同TRP传输调度的时域资源不同且完全不交叠,频域资源相同。TDM模式中,多个TRP在传输过程中,可以使用一个或多个天线端口。TDM模式利用信道在时间上的低相关性以提高传输的鲁棒性。
TDM模式可分为时隙单元内的TDM模式和时隙单元间的TDM模式,时隙单元可以是slot或微时隙(mini-slot),一个slot可以包括14个符号,未来也可以设计成包括其他数量的符号数,一个mini-slot包括的符号数小于slot包括的符号数,例如一个mini-slot可以包括2个、6个或7个符号。符号可以是正交频分复用(orthogonal frequency division multiplexing,OFDM)符号、离散傅里叶变换扩频的正交频分复用(discrete Fourier transform spread spectrum orthogonal frequency division multiplexing,DFT-S-OFDM)符号等。
为了便于区分,本申请实施例将时隙单元内的TDM模式称为第一TDM模式,将时隙单元间的TDM模式称为第二TDM模式。时隙单元内的TDM模式也可以称为scheme 3、或基于mini-slot的TDM模式等,时隙单元间的TDM模式也可以称为scheme 4、基于slot的TDM模式或跨时隙单元的TDM模式等。
示例性的,可参见图5a,为第一时分复用模式的传输示例图。图5a中,TRP 1与TRP2调度的频域资源相同,时域资源均位于slot n内且完全不交叠。
示例性的,可参见图5b,为第二时分复用模式的传输示例图。图5b中,TRP 1与TRP 2调度的频域资源相同,TRP 1调度的时域资源的位置位于slot n,TRP 2调度的时域资源的位置位于slot n+1,不同且完全不交叠。
可参见图5c,为时分复用模式的物理层处理流程的简化示意图。图5c中,TRP 1和TRP 2分别传输一个完全相同的传输块,一个传输块经过信道编码和速率匹配的处理,基于冗余版本获得一个CW,另一个传输块经过信道编码和速率匹配的处理,基于冗余版本获得另一个CW,这两个CW的冗余版本可以相同也可以不同,图5c中以不同为例。在层映射过程中,映射到一个或多个数据传输层,在天线端口映射过程中,映射到一个或多个天线端口。最后,在资源映射过程中,两个PDSCH映射到相同的频域资源上,但是分时传输,因此PDSCH 1和PDSCH 2的时域资源不同。
TDM模式除了包括第一TDM模式和第二TDM模式外,还可以包括第一TDM模式和第二TDM模式组合的传输模式,该组合传输模式中,PDSCH的重复传输同时占用slot内和slot间的符号。换句话说,该PDSCH既在slot内的重复传输,又在slot间的重复传输。示例性的,假设PDSCH占用的时域资源长度为两个连续的符号,TRP 1和TRP 2在一次重复传输过程中,PDSCH占用的时域资源可包括slot n内的第三个、第四个、第九个和第十个符号,以及slot n+1内的第三个、第四个、第九个和第十个符号。其中,slot n内的第三个和第四个符号上的PDSCH与slot n内的第九个和第十个符号上的PDSCH是slot内的重复,slot n内的第三个和第四个符号上的PDSCH与slot n+1内的第三个和第四个符号上的PDSCH是slot间的重复。
上述几种传输模式的物理层处理流程中,天线端口的索引与DMRS端口的索引的关系为:天线端口的索引=DMRS端口的索引+1000。
需要说明的是,上述几种传输模式的名称用于举例,并不构成对本申请实施例的限定,上述几种传输模式还可以用其他名称来表示,只要描述上述几种传输模式的技术本质或原理相同或相似,则属于本申请实施例的保护范围。
(2)传输配置指示(transmission configuration indication,TCI)
TCI,动态控制信令中的一个指示域,指示的内容为每次数据传输过程的TCI状态(state)。其中,动态控制信令可以是下行控制信息(downlink control information,DCI)。
TCI状态为DCI中用于指示PDSCH天线端口准共址(quasi co location,QCL)的字段,用于在一个或两个下行参考信号和PDSCH的DMRS之间配置准共址关系,可以理解为此次PDSCH传输过程的信道特性。从而,终端设备能够基于该TCI状态,获知所接收到的PDSCH的信道大尺度参数关系的指示信息,进而基于信道估计,解调出PDSCH上传输的数据。在多站协作传输场景中,对于终端设备而言,不同TRP在PDSCH传输过程中具有不同的TCI state。
根据TCI状态的数量可以区分单站传输场景和多站传输场景。TCI状态是用于指示PDSCH的信道大尺度参数的指示信息,因此多站传输场景的最大特性为存在信道条件完全不同的多个TRP,因此可以利用信道的分集增益,那么在存在多个TCI状态的情况下,终端设备可以认为当前传输场景为多站传输场景。
(3)准共址
QCL关系用于表示多个资源之间具有一个或多个相同或者相类似的通信特征。例如,如果两个天线端口具有准共址关系,那么一个天线端口传送一个信号的信道大尺度特性可 以从另一个天线端口传送一个信号的信道大尺度特性推断出来。具有QCL关系的天线端口对应的信号中具有相同的参数,或者,一个天线端口的参数可用于确定与该天线端口具有QCL关系的另一个天线端口的参数,或者,两个天线端口具有相同的参数,或者,两个天线端口间的参数差小于某预设值。其中,所述参数可以包括以下一项或多项信道大尺度参数:时延扩展(delay spread),多普勒扩展(Doppler spread),多普勒频移(Doppler shift),平均时延(average delay),平均增益,空间接收参数(spatial Rx parameters)。其中,空间接收参数可以包括发射角(Angle of arrival,AOA)、主发射角(Dominant AoA)、平均到达角(Average AoA)、到达角(Angle of departure,AOD)、信道相关矩阵,到达角的功率角度扩展谱,平均触发角(Average AoD)、出发角的功率角度扩展谱、发射信道相关性、接收信道相关性、发射波束成型、接收波束成型、空间信道相关性、空间滤波器,或,空间滤波参数,或,空间接收参数等中的一项或多项。
图3a、图4a以及图5a中,TRP 1与TRP 2向终端设备发送的QCL不同,终端设备根据不同的QCL可知数据来自不同的TRP,进而终端设备可根据多个QCL确定当前传输场景为多站传输场景。
(4)CDM组
CDM组也可以描述为CDM天线端口组。CDM组内的多个天线端口可以占据相同的时频资源,但使用不同的码域资源。终端设备假设一个CDM组内的DMRS端口是具有QCL关系的,也即一个CDM组中的DMRS端口的信道条件特征类似,可以理解为来自同一TRP,还可以认为同一CDM组内的天线端口传输的数据能够被同时接收。
需要说明的是,不同TRP的DMRS端口通常被认为是不具有QCL关系的,即非QCL(non-QCL)。
DMRS CDM组,也可以描述为DMRS的CDM天线端口组,用于表示DMRS传输的DMRS端口所属的CDM组。
基于图1或图2所示的网络架构,下面将对本申请实施例提供的传输模式确定方法进行详细介绍。需要说明的是,介绍过程中,终端设备与网络设备之间交互的信息或数据的名称用于举例,并不构成对本申请实施例的限定。
请参见图6,为本申请实施例提供的一种传输模式确定方法的流程示意图,该流程可以包括但不限于如下步骤:
步骤601,网络设备向终端设备发送配置指示信息。相应的,终端设备从网络设备接收配置指示信息。
其中,配置指示信息为DMRS指示信息、重复传输指示信息或TCI信息中的一种或多种。
网络设备可为终端设备配置DMRS指示信息,并向终端设备发送DMRS指示信息。网络设备可通过动态控制信令向终端设备DMRS指示信息,动态控制信令可以是DCI,即DMRS指示信息可携带在DCI中。
DMRS指示信息可以一个值(value),或者为索引(index),用于作为DMRS表(table)的输入(entry),以便查找DMRS表中与该value值对应的DMRS参数。示例性的,下表1为版本(Release)15中的一种DMRS表,该DMRS表为DMRS类型(type)=1,1符号 的DMRS表。该DMRS表用于举例,并不构成对本申请实施例的限定。
表1
表1对于网络设备和终端设备而言均可知。换句话说,网络设备和终端设备上均配置了DMRS表。终端设备可通过查表获得某个value对应的两个DMRS参数,这两个DMRS参数为未承载数据的CDM组的数量和DMRS端口。未承载数据的CDM组的数量即未承载数据的DMRS CDM组的数量(number of DMRS CDM group(s)without data),用于进行速率匹配。DMRS端口(DMRS port)用于通知终端设备使用的DMRS端口与CDM组。表1中,DMRS端口包括[0]、[1]、[2]和[3]四种端口标识,其中,DMRS port[0]和DMRS port[1]属于CDM组{0},即CDM组{0}包括DMRS port[0]和DMRS port[1];DMRS port[2]和DMRS port[3]属于CDM组{1},即CDM组{1}包括DMRS port[2]和DMRS port[3]。
例如,DMRS指示信息指示的value为2,终端设备可查表获得未承载数据的CDM组为1组,以及DMRS port为[0]和[1],这两个DMRS端口属于CDM组{0}。再例如,DMRS指示信息指示的value为11,终端设备可查表获得未承载数据的CDM组为2组,DMRS port为[0]和[2],这两个DMRS端口分别属于CDM组{0}和CDM组{1}。
DMRS指示信息可以直接指示DMRS表中的一个value,进而间接指示该value对应的DMRS端口标识,或间接指示该value对应的CDM组,或间接指示该value对应的未承载数据的CDM组的数量和DMRS端口标识。可以理解的是,DMRS指示信息用于指示DMRS端口标识,或用于指示DMRS端口标识和未承载数据的CDM组。
在一种可能的实现方式中,在DMRS指示信息用于指示DMRS端口标识的情况下,DMRS指示信息可用于区分SDM模式和FDM模式。该种方式,鉴于SDM模式和FDM模式的物理层处理特性,根据DMRS端口标识进行区分。基于物理层处理流程,SDM模式下的传输至少使用2个DMRS端口,并且这些DMRS端口来自不同的CDM组;而FDM模式下的传输使用一个或多个DMRS端口,且限制在最大秩(rank)为2的情况下传输, 因此根据DMRS端口标识区分SDM模式和FDM模式。
在一种可能的实现方式中,在DMRS指示信息用于指示DMRS端口标识和未承载数据的CDM组的情况下,DMRS指示信息可用于区分SDM模式、FDM模式以及第一TDM模式。该种方式,可确定出表1各个value对应的传输模式。
网络设备可为终端设备配置重复传输指示信息,并向终端设备发送重复传输指示信息。网络设备可通过高层信令向终端设备发送重复传输指示信息,高层信令例如可以是无线资源控制(radio resource control,RRC)信令,即重复传输指示信息携带在RRC信令中。
在一种可能的实现的方式中,重复传输指示信息可用于指示时域重复传输参数。方式一,该时域重复传输参数用于表示时域上的重复次数,可以是聚合因子(AggregationFactor)。AggregationFactor可用于终端设备区分TDM模式与其他传输模式。方式二,该时域重复传输参数可以是PDSCH聚合因子(pdsch-AggregationFactor),pdsch-AggregationFactor的取值可以为2、4或8,用于表示在pdsch-AggregationFactor个连续的slot上重复传输。pdsch-AggregationFactor可用于终端设备区分第二TDM模式与其他传输模式。可选的,重复传输指示信息还用于指示频域重复传输参数,频域重复传输参数用于区分第一FDM模式和第二FDM模式。
在一种可能的实现方式中,重复传输指示信息可用于指示第一时域重复传输参数和第二时域重复传输参数。第一时域重复传输参数可表示为微时隙聚合因子(MiniSlotAggregationFactor),第二时域重复传输参数可表示为时隙聚合因子(SlotAggregationFactor)。第一时域重复传输参数和第二时域重复传输参数可用于区分TDM模式和其他传输模式,在确定为TDM模式的情况下,还可用于进一步区分第一TDM模式和第二TDM模式。
在一种可能的实现方式中,重复传输指示信息可用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数,该种情况下,重复传输指示信息可表示为{a,b,c},例如a表示频域重复传输参数,b表示第一时域重复传输参数,c表示第二时域重复传输参数。该种方式中,终端设备可根据重复传输指示信息和CDM组的数量确定传输模式。
网络设备可为终端设备配置TCI信息,并向终端设备发送TCI信息。网络设备可通过动态控制信令向终端设备DMRS指示信息,动态控制信令可以是DCI,即DMRS指示信息可携带在DCI中。在网络设备为终端设备配置TCI信息和DMRS信息的情况下,网络设备可通过同一DCI向终端设备发送TCI信息和DMRS指示信息,也可通过不同DCI向终端设备发送TCI信息和DMRS指示信息。
TCI信息用于指示传输过程的TCI状态。TCI信息可以是TCI码点(codepoint),一个TCI codepoint对应一个或多个TCI状态。在多站传输的情况下,一个TCI codepoint可以指示两个或两个以上的TCI状态。若TCI信息指示两个或两个以上的TCI状态,那么终端设备可确定当前传输场景为多站传输场景。
步骤602,终端设备根据配置指示信息确定传输模式。
终端设备在根据配置指示信息确定传输模式之前,可先确定当前传输场景是否为多站传输场景,在确定出当前传输场景为多站传输场景的情况下,根据配置指示信息确定传输 模式。
具体的,终端设备可根据TCI信息所指示的TCI状态的数量来确定当前传输场景是否为多站传输场景,若TCI状态的数量大于或等于2个,那么可确定当前传输场景为多站传输场景。终端设备可根据接收的QCL来确定当前传输场景是否为多站传输场景,若接收到多个不同的QCL,那么可确定当前传输场景为多站传输场景。
终端设备获取配置指示信息,根据获取到的配置指示信息确定传输模式。下面将根据配置指示信息的不同,通过如下几个实施例对终端设备确定传输模式进行介绍。
实施例一,配置指示信息为重复传输指示信息。
重复传输指示信息可以用于指示时域重复传输参数,或用于指示第一时域重复传输参数和第二时域重复传输参数,或用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数。
对于重复传输指示信息用于指示时域重复传输参数的情况:
方式一,该时域重复传输参数用于表示时域上的重复次数,可以是AggregationFactor。在终端设备确定出当前传输场景为多站传输场景的情况下,若终端设备获取到时域重复传输参数,表明网络设备为终端设备配置了时域重复传输参数,那么终端设备可确定传输模式为TDM模式。若终端设备未获取到时域重复传输参数,表明网络设备未为终端设备配置时域重复传输参数,那么终端设备可确定传输模式为SDM模式、FDM模式或SDM模式与FDM模式的组合模式。对于终端设备未获取到时域重复传输参数的情况,终端设备可根据实施例二中DMRS指示信息用于指示DMRS端口标识,区分SDM模式和FDM模式。
方式二,该时域重复传输参数可以是pdsch-AggregationFactor,表示在pdsch-AggregationFactor个连续的slot上传输。例如,pdsch-AggregationFactor为4,那么表示在4个连续的slot上重复传输。在终端设备确定出当前传输场景为多站传输场景的情况下,终端设备获取到该时域重复传输参数,可确定传输模式为第二TDM模式,即时隙单元间的TDM模式。终端设备未获取到该时域重复传输参数,可确定传输模式为第一TDM模式、SDM模式或FDM模式中的一种或多种。对于终端设备未获取到时域重复传输参数的情况,终端设备可根据实施例三中DMRS指示信息用于指示DMRS端口标识和未承载数据的CDM组的数量,区分第一TDM模式、SDM模式和FDM模式。
对于上述方式一,终端设备在确定出TDM模式的情况下,可进一步区分是第一TDM模式还是第二TDM模式。
在一种可能的实现方式中,时域重复传输参数为第一时域重复传输参数,那么可确定时分复用模式为第一时分复用模式;若时域重复传输参数为第二时域重复传输参数,那么可确定时分复用模式为第二时分复用模式。例如,第一时域重复传输参数可表示为MiniSlotAggregationFactor,第二时域重复传输参数可表示为SlotAggregationFactor。
在一种可能的实现方式中,对于第一TDM模式,时域重复传输参数中可以包括第一TDM模式的特有参数,进而确定传输模式为第一TDM模式。例如,时域重复传输参数包括偏移信息(offset),那么可确定传输模式为第一TDM模式;反之,可确定传输模式为第二TDM模式。其中,偏移信息可表示多个PDSCH的时域位置的偏移信息。
在一种可能的实现方式中,时域重复传输参数表示重复传输次数,但是并未指示该重 复传输次数是slot内的还是slot间的重复传输次数,终端设备可通过其他信息来确定。示例性的,其他信息为携带重复传输指示信息的RRC信令中的某个特征比特位,例如该比特位设置为“0”表示重复传输次数为slot内的重复传输次数,进而终端设备可确定传输模式为第一TDM模式;该比特位设置为“1”表示重复传输次数为slot间的重复传输次数,进而终端设备可确定传输模式为第二TDM模式。再例如,该比特位设置为“0”表示重复传输次数为slot间的重复传输次数,进而终端设备可确定传输模式为第二TDM模式;该比特设置为“1”表示重复传输次数为slot内的重复传输次数,进而终端设备可确定传输模式为第一TDM模式。示例性的,其他信息为额外的RRC信令{mini-slot,slot},额外的RRC信令指的是另外一条RRC信令,不同于携带重复传输指示信息的RRC信令。额外的RRC信令{mini-slot,slot}指示该重复传输次数是slot内的还是slot间的重复传输次数。例如{1,0}表示重复传输次数为slot内的重复传输次数,进而终端设备可确定传输模式为第一TDM模式;{0,1}表示重复传输次数为slot间的重复传输次数,进而终端设备可确定传输模式为第二TDM模式。再例如,{1,0}表示重复传输次数为slot间的重复传输次数,进而终端设备可确定传输模式为第二TDM模式;{0,1}表示重复传输次数为slot内的重复传输次数,进而终端设备可确定传输模式为第一TDM模式。对于重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数的情况:
在终端设备确定出当前传输场景为多站传输场景的情况下,若终端设备未获取到第一时域重复传输参数和第二时域重复传输参数,即网络设备未为终端设备配置第一时域重复传输参数和第二时域重复传输参数,那么可确定传输模式为SDM模式、FDM模式或SDM模式与FDM模式的组合模式。终端设备获取到第一时域重复传输参数和第二时域重复传输参数,但是第一时域重复传输参数的数值和所述第二时域重复传输参数的数值均为第一预设值,那么可确定传输模式为SDM模式、FDM模式或SDM模式与FDM模式的组合模式。若终端设备获取到第一时域重复传输参数和第二时域重复传输参数,且第一时域重复传输参数的数值或第二时域重复传输参数的数值中一个或多个大于第一预设值,那么终端设备可确定传输模式为TDM模式。
终端设备在确定出TDM模式的情况下,可进一步区分是第一TDM模式还是第二TDM模式。若第一时域重复传输参数的数值为第一预设值,第二时域重复传输参数大于第一预设值,那么可确定时分复用模式为第二TDM模式;若第二时域重复传输参数为第一预设值,第一时域重复传输参数大于第一预设值,那么确定时分复用模式为第一TDM模式;若第一时域重复传输参数和第二时域重复传输参数均大于第一预设值,那么确定时分复用模式为第一TDM模式与第二TDM模式的组合模式。其中,第一预设值可以为1。
对于重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数的情况,可通过下表2表示,表2中以第一预设值为1,第一时域重复传输参数表示MiniSlotAggregationFactor,第二时域重复传输参数表示为SlotAggregationFactor为例。
表2
MiniSlotAggregationFactor | SlotAggregationFactor | 传输模式 |
未配置 | 未配置 | SDM模式或FDM模式 |
=1 | =1 | SDM模式或FDM模式 |
>1 | =1 | 第一TDM模式 |
=1 | >1 | 第二TDM模式 |
>1 | >1 | 第一TDM模式+第二TDM模式 |
表2中的未配置,表示网络设备未为终端设备配置第一时域重复传输参数和第二时域重复传输参数,终端设备未获取到第一时域重复传输参数和第二时域重复传输参数。表2中“>1”的具体数值可表示重复次数,例如MiniSlotAggregationFactor为4,表示在一个slot内重复传输4次;再例如SlotAggregationFactor为4,表示在4个连续的slot上重复传输。
可选的,第一时域重复传输参数和第二时域重复传输参数也可以表示为{x,y}。示例性的,x表示第一时域重复传输参数,在slot内的重复传输次数;y表示第二时域重复传输参数,在y个连续的slot上重复传输。若x>1,y=1,那么终端设备可确定传输模式为第一TDM传输模式;若x=1,y>1,那么终端设备可确定传输模式为第二TDM传输模式。
对于重复传输指示信息用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数的情况:
重复传输指示信息可通过{a,b,c}来表示,例如a表示频域重复传输参数,即在频域上的重复传输次数;b表示第一时域重复传输参数,即在时域上slot内的重复传输次数;c表示第二时域重复传输参数,即在时域上slot间的重复传输次数。若在时域上或频域上不存在重复传输,那么a、b和c的取值可为0或1,本申请实施例以1为例。
在终端设备确定出当前传输场景为多站传输场景的情况下,示例性的,重复传输指示信息为{x,1,1},x为大于1的整数,例如x=2,那么终端设备可确定传输模式为第二FDM模式。示例性的,重复传输指示信息为{1,1,x},那么终端设备可确定传输模式为第二TDM模式。示例性的,重复传输指示信息为{1,x,1},那么终端设备可确定传输模式为第一TDM模式。
实施本申请提供的实施例一,终端设备根据获取的重复传输指示信息确实出传输模式为TDM模式,无需额外的指示信息进行指示。
实施例二,配置指示信息为DMRS指示信息,DMRS指示信息可以用于指示DMRS端口标识。
在终端设备确定出当前传输场景为多站传输场景的情况下,终端设备获取到DMRS指示信息,根据DMRS指示信息确定DMRS端口标识,即根据所指示的value查DMRS表可获得DMRS端口标识,根据DMRS端口标识确定传输模式。该种情况下,终端设备根据DMRS端口标识确定传输模式为FDM模式还是SDM模式。
终端设备可采用如下四种方式根据DMRS端口标识确定传输模式。
方式一,若DMRS端口标识对应的CDM组的数量为第二预设值,那么终端设备可确定传输模式为FDM模式。若DMRS端口标识对应的CDM组的数量为第三预设值,那么终端设备可确定传输模式为SDM模式。其中,第二预设值可以为1,表示1个CDM组;第三预设值可以为2,表示2个CDM组。例如,表1中value为9时,DMRS端口标识为[0,1,2],对应两个CDM组,即对于CDM组{0}和CDM组{1},那么终端设备可确定传输模式为SDM模式,同理value为10或11时,可确定传输模式为SDM模式。再例如,表1中value为7时,DMRS端口标识为[0,1],对应一个CDM组,即对于CDM组{0},那么终 端设备可确定传输模式为FDM模式。
方式二,若DMRS端口标识属于同一个CDM组,那么终端设备可确定传输模式为FDM模式;反之,可确定传输模式为空SDM模式。例如,表1中value为7时,DMRS端口标识为[0,1],属于同一个CDM组,即属于CDM组{0},那么终端设备可确定传输模式为FDM模式。再例如,表1中value为9时,DMRS端口标识为[0,1,2],属于两个CDM组,那么终端设备可确定传输模式为SDM模式。
方式三,若DMRS端口标识的数量为第二预设值,那么终端设备可确定传输模式为FDM模式;反之,可确定传输模式为SDM模式。其中,第二预设值可以为一个。例如,表1中value为4时,DMRS端口标识为一个,那么终端设备可确定传输模式为FDM模式。再例如,表1中value为9时,DMRS端口标识为三个,那么终端设备可确定传输模式为SDM模式。
方式四,若DMRS端口标识属于预设标识,那么终端设备可确定传输模式为FDM模式;反之,可确定传输模式为SDM模式。其中,预设标识可以是[0],[1]或[0,1]。例如,表1中value为1、2或7时,DMRS端口标识属于预设标识,那么终端设备可确定传输模式为FDM模式。再例如,表1中value为9、10或11时,DMRS端口标识除了包括预设标识外,还包括其他标识,那么终端设备可确定传输模式为SDM模式。
上述四种根据DMRS端口标识确定传输模式的方式用于举例,并不构成对本申请实施例的限定。
在另一种可能的实现方式中,终端设备根据DMRS指示信息确定CDM组的数量,根据CDM组的数量确定传输模式。若CDM组的数量为第二预设值(例如为1个CDM组),那么终端设备可确定传输模式为FDM模式;若CDM组的数量为第三预设值(例如为两个CDM组),那么终端设备可确定传输模式为SDM模式。该方式与上述方式一的不同之处在于,上述方式一根据value确定DMRS端口标识,根据端口标识确定CDM组的数量,而该方式直接根据value确定CDM组的数量。
终端设备确定出FDM模式的情况下,可进一步区分是第一FDM模式还是第二FDM模式。终端设备获取频域重复传输参数,在获取到频域重复传输参数的情况下,可确定传输模式为第二FDM模式;若未获取到频域重复传输参数,那么可确定传输模式为第一FDM模式。其中,频域重复传输参数可与时域重复传输参数一同携带在RRC信令中,即RRC信令携带的重复传输指示信息可以指示时域重复传输参数和频域重复传输参数,或RRC信令携带的重复传输指示信息指示时域重复传输参数,该RRC信令中的其他信息指示频域重复传输参数。频域重复传输参数也可以通过额外的RRC信令进行指示,例如RRC信令1指示时域重复传输参数,RRC信令2指示频域重复传输参数。
可以理解的是,实施例二,对于DMRS用于指示DMRS端口标识的情况,终端设备根据表1中的第三列确定传输模式。
实施例三,配置指示信息为DMRS指示信息,DMRS指示信息用于指示DMRS端口标识和未承载数据的CDM组的数量。
终端设备根据DMRS端口标识对应的CDM组的数量和未承载数据的CDM组的数量,确定传输模式为空分复用模式、频分复用模式或第一时分复用模式;若确定出传输模式为 频分复用模式,根据DMRS端口标识对应的CDM组的组标识确定传输模式为第一频分复用模式或第二频分复用模式。
示例性的,若DMRS端口标识对应的CDM组为两个,那么终端设备可确定传输模式为SDM模式;若DMRS端口标识对应的CDM组为一个,未承载数据的CDM组的数量为一个,那么终端设备可确定传输模式为第一TDM模式;若DMRS端口标识对应的CDM端口组为一个,未承载数据的CDM的组的数量为两个,那么终端设备可确定传输模式为FDM模式。在确定出传输模式为FDM模式的情况下,若DMRS端口标识对应的CDM组的组标识为第一标识,那么终端设备可确定传输模式为第一FDM模式;若DMRS端口标识对应的CDM组的组标识为第二标识,那么终端设备可确定传输模式为第二FDM模式。例如,CDM组的组标识为{0},确定传输模式为第一FDM模式;CDM组的组标识为{1},确定传输模式为第二FDM模式。再例如,CDM组的组标识为{1},确定传输模式为第一FDM模式;CDM组的组标识为{0},确定传输模式为第二FDM模式。
基于上述示例,可确定表1中各个value对应的传输模式,具体可参见下表3所示。
表3
表3中,CDM组的组标识为{0},对应的传输模式为第一FDM模式;CDM组的组标识为{1},对应的传输模式为第二FDM模式。表3中,每一种传输方式均会有对应的DMRS table entry,例如使用{2,7,8,11}四个entry便能区分第一TDM模式、第一FDM模式、第二FDM模式和SDM模式。
基于表3,若网络设备采用的传输模式为SDM模式,那么网络设备可通过配置DMRS type=1,1符号的DMRS table的索引(index)为9、10或11中的一个,即DMRS指示信息用于指示表3的value 9,隐式告知终端设备当前传输模式为SDM模式。再例如,若网络设备采用的传输模式为第一FDM模式,那么网络设备可通过配置该DMRS表的索引为{3,4,7}中的一个,隐式告知终端设备当前传输模式为第一FDM模式。
可以理解的是,实施例三,对于DMRS用于指示DMRS端口标识和未承载数据的CDM组的数量的情况,终端设备根据表1中的第二列和第三列确定传输模式。
实施本申请提供的实施例二和实施例三,终端设备根据获取的DMRS指示信息区分SDM模式和FDM模式,无需额外的指示信息进行指示。
实施例四,配置指示信息为TCI信息。
在终端设备确定出当前传输场景为多站传输场景的情况下,若TCI状态的数量为第四预设值,那么终端设备可确定传输模式为FDM模式或SDM模式;若TCI状态的数量大于第四预设值,那么终端设备可确定传输模式为TDM模式。其中,第四预设值可以为2,表示2个TCI状态。
在另一种可能的实现方式中,在终端设备确定出当前传输场景为多站传输场景的情况下,若TCI状态的数量为第四预设值,那么终端设备可确定传输模式为FDM模式或SDM模式;若TCI状态的数量为第五预设值,那么终端设备可确定传输模式为TDM模式。其中,第四预设值可以为2,表示2个TCI状态,第五预设值可以为4,表示4个TCI状态。
实施例五,配置指示信息为TCI信息和重复传输指示信息。
在一种可能的实现方式中,重复传输指示信息用于指示时域重复传输参数。在终端设备确定出当前传输场景为多站传输场景的情况下,终端设备获取到该重复传输指示信息,且TCI状态的数量大于或等于第四预设值,可确定传输模式为TDM模式。
在另一种可能的实现方式中,重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数。在终端设备确定出当前传输场景为多站传输场景的情况下,终端设备获取到该重复传输指示信息,且TCI状态的数量大于或等于第四预设值,可确定传输模式为TDM模式。进一步,终端设备可区分是第一TDM模式还是第二TDM模式。
实施本申请提供的实施例五,终端设备在获取到TCI信息和重复传输指示信息的情况下,确定传输模式,无需额外的指示信息。
实施例六,配置指示信息为重复传输指示信息和DMRS指示信息,重复传输指示信息用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数。
其中,重复传输指示信息可通过{a,b,c}来表示,例如a表示频域重复传输参数,即在频域上的重复传输次数;b表示第一时域重复传输参数,即在时域上slot内的重复传输次数;c表示第二时域重复传输参数,即在时域上slot间的重复传输次数。
在一种可能的实现方式中,在终端设备确定出当前传输场景为多站传输场景的情况下,终端设备可根据DMRS指示信息确定CDM组的数量,根据CDM组的数量可区分SDM模式与其他传输模式。
示例1,CDM组的数量为2个,重复传输指示信息为{1,1,1},终端设备可确定传输模式为SDM模式。或者,CDM组的数量为2个,终端设备未获取到重复传输指示信息,那么可确定传输模式为SDM模式。示例2,CDM组的数量为1个,重复传输指示信息为{1,1,1},终端设备可确定传输模式为第一FDM模式。或者,CDM组的数量为1个,终端设备未获取到重复传输指示信息,那么可确定传输模式为第一FDM模式。示例3,CDM组的数量为1个,重复传输指示信息为除{1,1,1}之外的其他数值,终端设备可确定传输模式为第二FDM模式或TDM模式。
在一种可能的实现方式中,在终端设备确定出当前传输场景为多站传输场景的情况下,终端设备可根据DMRS指示信息确定CDM组的数量,根据CDM组的数量、频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数确定传输模式。
示例性的,CDM组的数量为2个,重复传输指示信息为{1,x,1}或{1,1,x},终端设备可确定传输模式为TDM模式与SDM模式的组合模式。具体的,重复传输指示信息为{1,x,1}时,传输模式为第一TDM模式与SDM模式的组合模式;重复传输指示信息为{1,1,x}时,传输模式为第二TDM模式与SDM模式的组合模式。
示例性的,CDM组的数量为1个,重复传输指示信息为{x,y,1}或{x,1,z},终端设备可确定传输模式为TDM模式与FDM模式的组合模式。其中,x,y,z为大于1的整数,x表示频域上的重复传输次数,y表示slot内的重复传输次数,z表示slot间的重复传输次数。具体的,重复传输指示信息为{x,y,1}时,传输模式为第一TDM模式与第二FDM模式的组合模式;重复传输指示信息为{x,1,z}时,传输模式为第二TDM模式与第二FDM模式的组合模式;重复传输指示信息为{1,y,z}时,传输模式为第一TDM模式与第二TDM模式的组合模式。
实施本申请提供的实施例六,终端设备在获取到DMRS指示信息和重复传输指示信息的情况下,确定传输模式,无需额外的指示信息。
在图6所示的实施例中,终端设备在确定出当前传输场景为多站传输场景的情况下,根据获取到的配置指示信息确定传输模式,无需额外的指示信息,可节省指示信令开销。
请参见图7,为本申请实施例提供的另一种传输模式确定方法的流程示例图,该流程可以包括但不限于如下步骤:
步骤701,网络设备向终端设备发送配置信息。相应的,终端设备从网络设备接收配置信息。
其中,配置信息可以理解为指示uRLLC场景的配置信息,从而区别多站uRLLC场景与多站eMBB场景。
在第一种可能的实现方式中,配置信息用于指示终端设备能够使用低于预设码率的码率,或者用于指示终端设备使用预设的调制编码策略(modulation and coding scheme,MCS)表。预设码率可以是120*1024(kbps),预设的MCS表可以是调制编码策略表3,MCS表3中存在低于120*1024(kbps)的码率。码率为目标码率(target code rate)。
其中,MCS表3可参见下表4所示,即下表4即为MCS表3。
表4
表4中存在6个低于120*1024(kbps)的码率。网络设备指示终端设备使用MCS表3,表示当前传输场景为uRLLC场景。
在第一种可能的实现方式中,配置信息可以是新定义的无线网络临时标识(radio network temporary identity,RNTI)或新定义的DCI域。终端设备在检测到该配置信息的情况下,可以认为当前传输场景为多站uRLLC场景;否则可以认为当前传输场景为多站eMBB场景。
在第二种可能的实现方式中,配置信息可以是复用已有多站uRLLC场景相关的配置信息,例如可以是调制编码策略小区无线网络临时标识(modulation and coding scheme cell radio network temporary identity,MCS-C-TNTI)。终端设备在检测到MCS-C-RNTI的情况下,终端设备可认为当前传输场景为多站uRLLC场景。若终端设备未获取到MCS-C-RNTI, 那么终端设备可认为当前传输场景为eMBB场景。
在第三种可能的实现方式中,配置信息可用于直接指示当前传输场景为多站uRLLC场景,终端设备在检测到该配置信息的情况下,可认为当前传输场景为多站uRLLC场景,否则可认为当前传输场景为多站eMBB场景。该方式中,配置信息可以是新定义的RNTI或新定义的DCI域。
另一种可能的实现方式中,配置信息可以理解为指示eMBB场景的配置信息,例如指示多站eMBB场景的专属特性,或者复用已有多站eMBB场景相关的配置信息,或者配置信息可用于直接指示当前传输场景为多站eMBB场景。
步骤702,网络设备向终端设备发送传输模式指示信息。相应的,终端设备从网络设备接收传输模式指示信息。
其中,传输模式指示信息可以携带在DCI中,或携带在RRC信令中。传输模式为SDM传输模式、第一FDM传输模式、第二FDM传输模式、第一TDM传输模式或第二TDM传输模式中的一种或多种。
示例性的,传输模式指示信息可以是RRC信令中的“SchemeSelection”,用于指示传输模式。传输模式指示信息可包括五个参数,为{1,2,3,4,5},分别对应于SDM传输模式、第一FDM传输模式、第二FDM传输模式、第一TDM传输模式或第二TDM传输模式,通过指示其中一个参数便实现对传输模式的指示。传输模式指示信息也可采用3比特对传输模式进行指示,具体如何指示在本申请实施例中不作限定。
需要说明的是,本申请实施例中不限定步骤701与步骤702执行的先后顺序,例如步骤702在步骤701之前,终端设备在获取到配置信息的情况下,从已接收到的RRC信令中获取传输模式指示信息。可以理解为,配置信息与传输模式指示信息存在绑定关系。
步骤703,终端设备根据传输模式指示信息确定传输模式。
终端设备在获取到传输模式指示信息的情况下,直接根据传输模式指示信息所指示的传输模式确定网络设备采用的传输模式,实现简单。
在一种可能的实现方式中,终端设备在确定出当前传输场景为多站uRLLC场景的情况下,若终端设备使用某种RNTI成功解扰物理下行控制信道(physical downlink control channel,PDCCH),那么终端设备可根据该RNTI确定是多站uRLLC场景中的哪种传输模式。终端设备和网络设备保存有各种RNTI与多站uRLLC场景的传输模式之间的对应关系,终端设备根据成功解扰PDCCH所采用的RNTI,便能直接确定网络设备当前的传输模式。
在图7所示的实施例中,终端设备根据配置信息可以实现多站uRLLC场景与多站eMBB场景的动态切换,不需要增加额外的指示开销。在终端设备确定出当前传输场景为多站uRLLC场景的情况下,根据传输模式指示信息确定多站uRLLC场景下的传输模式,实现简单。
相应于上述方法实施例给出的方法,本申请实施例还提供了相应的通信装置,所述通信装置包括用于执行上述实施例相应的模块。所述模块可以是软件,也可以是硬件,或者是软件和硬件结合。
通信装置可以是终端设备,也可以终端设备中的装置,还可以是能够与终端设备匹配使用的装置。一种设计中,该通信装置可以包括收发单元和处理单元。
在一种可能的实现方式中,收发单元,用于获取配置指示信息,所述配置指示信息为DMRS指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;处理单元,用于根据所述配置指示信息确定传输模式,所述传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
可选的,处理单元确定出所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示时域重复传输参数。
可选的,处理单元具体用于根据所述时域重复传输参数确定传输模式为时分复用模式。
可选的,处理单元具体用于:所述时域重复传输参数为第一时域重复传输参数,确定时分复用模式为第一时分复用模式;所述时域重复传输参数为第二时域重复传输参数,确定时分复用模式为第二时分复用模式;或者,所述时域重复传输参数包括偏移信息,确定时分复用模式为第一时分复用模式;反之,确定时分复用模式为第二时分复用模式;
其中,所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
可选的,处理单元确定出所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数;
处理单元具体用于:所述第一时域重复传输参数和所述第二时域重复传输参数均为第一预设值,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式;所述第一时域重复传输参数或所述第二时域重复传输参数中一个或多个大于第一预设值,确定传输模式为时分复用模式。
可选的,处理单元具体用于:
所述第一时域重复传输参数为所述第一预设值,所述第二时域重复传输参数大于所述第一预设值,确定时分复用模式为第二时分复用模式;
所述第二时域重复传输参数为所述第一预设值,所述第一时域重复传输参数大于所述第一预设值,确定时分复用模式为第一时分复用模式;
所述第一时域重复传输参数和所述第二时域重复传输参数均大于所述第一预设值,确定时分复用模式为第一时分复用模式与第二时分复用模式的组合模式;
其中,所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
可选的,处理单元还用于在所述收发器未获取到所述配置指示信息的情况下,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式。
可选的,处理单元确定出所述配置指示信息为DMRS指示信息;
处理单元具体用于:根据所述DMRS指示信息确定DMRS端口标识,根据所述DMRS端口标识确定传输模式。
可选的,处理单元具体用于:
所述DMRS端口标识对应的CDM组的数量为第二预设值,确定传输模式为频分复用模式;所述DMRS端口标识对应的CDM组的数量为第三预设值,确定传输模式为空分复用模式;
或者,所述DMRS端口标识属于同一个CDM组,确定传输模式为频分复用模式;反 之,确定传输模式为空分复用模式;
或者,所述DMRS端口标识的数量为第二预设值,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式;
或者,所述DMRS端口标识属于预设标识,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式。
可选的,处理单元确定出所述配置指示信息为DMRS指示信息;
处理单元具体用于:根据所述DMRS指示信息确定CDM组的数量,根据所述CDM组的数量确定传输模式。
可选的,处理单元具体用于:所述CDM组的数量为第二预设值,确定传输模式为频分复用模式;所述CDM组的数量为第三预设值,确定传输模式为空分复用模式。
可选的,处理单元具体用于:若获取到频域重复传输参数,确定频分复用模式为第二频分复用模式;反之,确定频分复用模式为第一频分复用模式;
其中,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式。
可选的,处理单元具体用于:根据所述时域重复传输参数确定传输模式为第二时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
可选的,处理单元确定出所述配置指示信息为DMRS指示信息;
处理单元具体用于:根据所述DMRS指示信息确定DMRS端口信息,根据所述DMRS端口信息确定传输模式。
可选的,处理单元确定出所述DMRS端口信息包括DMRS端口标识和未承载数据的CDM组的数量;
处理单元具体用于:
根据所述DMRS端口标识对应的CDM组的数量和所述未承载数据的CDM组的数量,确定传输模式为空分复用模式、频分复用模式或第一时分复用模式,第一时分复用模式为时隙单元内的时分复用模式;
若传输模式为所述频分复用模式,根据所述DMRS端口标识对应的CDM组的组标识确定传输模式为第一频分复用模式或第二频分复用模式,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式。
可选的,处理单元确定出所述配置指示信息为所述DMRS指示信息和所述重复传输指示信息,所述重复传输指示信息用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数;
处理单元具体用于:根据所述DMRS指示信息确定CDM组的数量,根据所述CDM组的数量、所述频域重复传输参数、所述第一时域重复传输参数和所述第二时域重复传输参数确定传输模式。
可选的,处理单元确定出所述配置指示信息为所述传输配置指示信息,所述传输配置指示信息用于指示传输配置指示状态;
处理单元具体用于:
所述传输配置指示状态的数量为第四预设值,确定传输模式为频分复用模式或空分复 用模式;
所述传输配置指示状态的数量大于第四预设值,确定传输模式为时分复用模式。
可选的,处理单元确定出所述配置指示信息为所述传输配置指示信息和所述重复传输指示信息;所述传输配置指示信息用于指示传输配置指示状态;所述重复传输指示信息用于指示时域重复传输参数;
处理单元具体用于:根据所述传输配置指示状态的数量和所述时域重复传输参数,确定传输模式为时分复用模式。
在一种可能的实现方式中,处理单元,用于在收发单元获取到配置信息的情况下,获取传输模式指示信息,所述传输模式指示信息用于指示传输模式;根据所述传输模式指示信息确定所述传输模式。
可选的,所述传输模式为空分复用传输模式、第一频分复用传输模式、第二频分复用传输模式、第一时分复用传输模式或第二时分复用传输模式中的一种或多种;
其中,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式;所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
可选的,所述配置信息用于指示终端设备能够使用低于预设码率的码率,或者用于指示终端设备使用预设的调制编码策略表。
图8给出了一种通信装置的结构示意图。所述通信装置800可以是网络设备,也可以是终端设备,也可以是支持网络设备实现上述方法的芯片、芯片系统、或处理器等,还可以是支持终端设备实现上述方法的芯片、芯片系统、或处理器等。该装置可用于实现上述方法实施例中描述的方法,具体可以参见上述方法实施例中的说明。
所述通信装置800可以包括一个或多个处理器801。所述处理器801可以是通用处理器或者专用处理器等。例如可以是基带处理器或中央处理器。基带处理器可以用于对通信协议以及通信数据进行处理,中央处理器可以用于对通信装置(如,基站、基带芯片,终端、终端芯片,DU或CU等)进行控制,执行软件程序,处理软件程序的数据。
可选的,所述通信装置800中可以包括一个或多个存储器802,其上可以存有指令804,所述指令可在所述处理器801上被运行,使得所述装置800执行上述方法实施例中描述的方法。可选的,所述存储器802中还可以存储有数据。所述处理器801和存储器802可以单独设置,也可以集成在一起。
可选的,所述通信装置800还可以包括收发器805、天线806。所述收发器805可以称为收发单元、收发机、收发电路或者收发器等,用于实现收发功能。
所述通信装置800为终端设备:处理器801用于执行图6中的步骤602;执行图7中的步骤703。收发器805用于执行图6中的步骤601;执行图7中的步骤701和步骤702。或,收发器805和天线806用于执行图6中的步骤601;执行图7中的步骤701和步骤702。
所述通信装置800为网络设备:收发器805用于执行图6中的步骤601;执行图7中的步骤701和步骤702。或,收发器805和天线806用于执行图6中的步骤601;执行图7中的步骤701和步骤702。在一种可选的设计中,处理器801也可以存有指令803,所述指令803可以被所述处理器运行,使得所述通信装置800执行上述方法实施例中描述的方法。
在另一种可选的设计中,处理器801中可以包括用于实现接收和发送功能的收发器。例如该收发器可以是收发电路,或者是接口,或者是接口电路。用于实现接收和发送功能的收发电路、接口或接口电路可以是分开的,也可以集成在一起。上述收发电路、接口或接口电路可以用于代码/数据的读写,或者,上述收发电路、接口或接口电路可以用于信号的传输或传递。
在又一种可能的设计中,通信装置800可以包括电路,所述电路可以实现前述方法实施例中发送或接收或者通信的功能。
本申请中描述的处理器和收发器可实现在集成电路(integrated circuit,IC)、模拟IC、射频集成电路RFIC、混合信号IC、专用集成电路(application specific integrated circuit,ASIC)、印刷电路板(printed circuit board,PCB)、电子设备等上。该处理器和收发器也可以用各种IC工艺技术来制造,例如互补金属氧化物半导体(complementary metal oxide semiconductor,CMOS)、N型金属氧化物半导体(nMetal-oxide-semiconductor,NMOS)、P型金属氧化物半导体(positive channel metal oxide semiconductor,PMOS)、双极结型晶体管(Bipolar Junction Transistor,BJT)、双极CMOS(BiCMOS)、硅锗(SiGe)、砷化镓(GaAs)等。
以上实施例描述中的通信装置可以是网络设备或者终端设备,但本申请中描述的通信装置的范围并不限于此,而且通信装置的结构可以不受图8的限制。通信装置可以是独立的设备或者可以是较大设备的一部分。例如所述通信装置可以是:
(1)独立的集成电路IC,或芯片,或,芯片系统或子系统;
(2)具有一个或多个IC的集合,可选的,该IC集合也可以包括用于存储数据,指令的存储部件;
(3)ASIC,例如调制解调器(MSM);
(4)可嵌入在其他设备内的模块;
(5)接收机、终端、智能终端、蜂窝电话、无线设备、手持机、移动单元、车载设备、网络设备、云设备、人工智能设备等等;
(6)其他等等。
图9提供了一种终端设备的结构示意图。为了便于说明,图9仅示出了终端设备的主要部件。如图9所示,终端设备900包括处理器、存储器、控制电路、天线以及输入输出装置。处理器主要用于对通信协议以及通信数据进行处理,以及对整个终端进行控制,执行软件程序,处理软件程序的数据。存储器主要用于存储软件程序和数据。射频电路主要用于基带信号与射频信号的转换以及对射频信号的处理。天线主要用于收发电磁波形式的射频信号。输入输出装置,例如触摸屏、显示屏,键盘等主要用于接收用户输入的数据以及对用户输出数据。
当终端设备开机后,处理器可以读取存储单元中的软件程序,解析并执行软件程序的指令,处理软件程序的数据。当需要通过无线发送数据时,处理器对待发送的数据进行基带处理后,输出基带信号至射频电路,射频电路将基带信号进行处理后得到射频信号并将射频信号通过天线以电磁波的形式向外发送。当有数据发送到终端设备时,射频电路通过天线接收到射频信号,该射频信号被进一步转换为基带信号,并将基带信号输出至处理器, 处理器将基带信号转换为数据并对该数据进行处理。
为了便于说明,图9仅示出了一个存储器和处理器。在实际的终端设备中,可以存在多个处理器和存储器。存储器也可以称为存储介质或者存储设备等,本发明实施例对此不做限制。
作为一种可选的实现方式,处理器可以包括基带处理器和中央处理器,基带处理器主要用于对通信协议以及通信数据进行处理,中央处理器主要用于对整个终端设备进行控制,执行软件程序,处理软件程序的数据。图9中的处理器集成了基带处理器和中央处理器的功能,本领域技术人员可以理解,基带处理器和中央处理器也可以是各自独立的处理器,通过总线等技术互联。本领域技术人员可以理解,终端设备可以包括多个基带处理器以适应不同的网络制式,终端设备可以包括多个中央处理器以增强其处理能力,终端设备的各个部件可以通过各种总线连接。所述基带处理器也可以表述为基带处理电路或者基带处理芯片。所述中央处理器也可以表述为中央处理电路或者中央处理芯片。对通信协议以及通信数据进行处理的功能可以内置在处理器中,也可以以软件程序的形式存储在存储单元中,由处理器执行软件程序以实现基带处理功能。
本领域技术人员还可以了解到本申请实施例列出的各种说明性逻辑块(illustrative logical block)和步骤(step)可以通过电子硬件、电脑软件,或两者的结合进行实现。这样的功能是通过硬件还是软件来实现取决于特定的应用和整个系统的设计要求。本领域技术人员可以对于每种特定的应用,可以使用各种方法实现所述的功能,但这种实现不应被理解为超出本申请实施例保护的范围。
本申请还提供了一种计算机可读介质,其上存储有计算机程序,该计算机程序被计算机执行时实现上述任一方法实施例的功能。
本申请还提供了一种计算机程序产品,该计算机程序产品被计算机执行时实现上述任一方法实施例的功能。
在上述实施例中,可以全部或部分地通过软件、硬件、固件或者其任意组合来实现。当使用软件实现时,可以全部或部分地以计算机程序产品的形式实现。所述计算机程序产品包括一个或多个计算机指令。在计算机上加载和执行所述计算机指令时,全部或部分地产生按照本申请实施例所述的流程或功能。所述计算机可以是通用计算机、专用计算机、计算机网络、或者其他可编程装置。所述计算机指令可以存储在计算机可读存储介质中,或者从一个计算机可读存储介质向另一个计算机可读存储介质传输,例如,所述计算机指令可以从一个网站站点、计算机、服务器或数据中心通过有线(例如同轴电缆、光纤、数字用户线(digital subscriber line,DSL))或无线(例如红外、无线、微波等)方式向另一个网站站点、计算机、服务器或数据中心进行传输。所述计算机可读存储介质可以是计算机能够存取的任何可用介质或者是包含一个或多个可用介质集成的服务器、数据中心等数据存储设备。所述可用介质可以是磁性介质(例如,软盘、硬盘、磁带)、光介质(例如,高密度数字视频光盘(digital video disc,DVD))、或者半导体介质(例如,固态硬盘(solid state disk,SSD))等。
本领域普通技术人员可以理解:本申请中涉及的第一、第二等各种数字编号仅为描述方便进行的区分,并不用来限制本申请实施例的范围,也表示先后顺序。
本申请中各表所示的对应关系可以被配置,也可以是预定义的。各表中的信息的取值仅仅是举例,可以配置为其他值,本申请并不限定。在配置信息与各参数的对应关系时,并不一定要求必须配置各表中示意出的所有对应关系。例如,本申请中的表格中,某些行示出的对应关系也可以不配置。又例如,可以基于上述表格做适当的变形调整,例如,拆分,合并等等。上述各表中标题示出参数的名称也可以采用通信装置可理解的其他名称,其参数的取值或表示方式也可以通信装置可理解的其他取值或表示方式。上述各表在实现时,也可以采用其他的数据结构,例如可以采用数组、队列、容器、栈、线性表、指针、链表、树、图、结构体、类、堆、散列表或哈希表等。
本申请中的预定义可以理解为定义、预先定义、存储、预存储、预协商、预配置、固化、或预烧制。
本领域普通技术人员可以意识到,结合本文中所公开的实施例描述的各示例的单元及算法步骤,能够以电子硬件、或者计算机软件和电子硬件的结合来实现。这些功能究竟以硬件还是软件方式来执行,取决于技术方案的特定应用和设计约束条件。专业技术人员可以对每个特定的应用来使用不同方法来实现所描述的功能,但是这种实现不应认为超出本申请的范围。
所属领域的技术人员可以清楚地了解到,为描述的方便和简洁,上述描述的系统、装置和单元的具体工作过程,可以参考前述方法实施例中的对应过程,在此不再赘述。
以上所述,仅为本申请的具体实施方式,但本申请的保护范围并不局限于此,任何熟悉本技术领域的技术人员在本申请揭露的技术范围内,可轻易想到变化或替换,都应涵盖在本申请的保护范围之内。因此,本申请的保护范围应以所述权利要求的保护范围为准。
Claims (45)
- 一种传输模式确定方法,其特征在于,包括:获取配置指示信息,所述配置指示信息为调制解调参考信号DMRS指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;根据所述配置指示信息确定传输模式,所述传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
- 根据权利要求1所述的方法,其特征在于,所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示时域重复传输参数。
- 根据权利要求2所述的方法,其特征在于,所述根据所述配置指示信息确定传输模式,包括:根据所述时域重复传输参数确定传输模式为时分复用模式。
- 根据权利要求3所述的方法,其特征在于,所述根据所述时域重复传输参数确定传输模式为时分复用模式,包括:所述时域重复传输参数为第一时域重复传输参数,确定时分复用模式为第一时分复用模式;或者所述时域重复传输参数为第二时域重复传输参数,确定时分复用模式为第二时分复用模式;或者所述时域重复传输参数包括偏移信息,确定时分复用模式为第一时分复用模式;反之,确定时分复用模式为第二时分复用模式;其中,所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求1所述的方法,其特征在于,所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数;所述根据所述配置指示信息确定传输模式,包括:所述第一时域重复传输参数和所述第二时域重复传输参数均为第一预设值,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式;所述第一时域重复传输参数或所述第二时域重复传输参数中一个或多个大于第一预设值,确定传输模式为时分复用模式。
- 根据权利要求5所述的方法,其特征在于,所述确定传输模式为时分复用模式,包括:所述第一时域重复传输参数为所述第一预设值,所述第二时域重复传输参数大于所述第一预设值,确定时分复用模式为第二时分复用模式;所述第二时域重复传输参数为所述第一预设值,所述第一时域重复传输参数大于所述第一预设值,确定时分复用模式为第一时分复用模式;所述第一时域重复传输参数和所述第二时域重复传输参数均大于所述第一预设值,确定时分复用模式为第一时分复用模式与第二时分复用模式的组合模式;其中,所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求2或5所述的方法,其特征在于,所述方法还包括:未获取到所述配置指示信息,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式。
- 根据权利要求2或5所述的方法,其特征在于,所述配置指示信息为所述DMRS指示信息;所述根据所述配置指示信息确定传输模式,包括:根据所述DMRS指示信息确定DMRS端口标识,根据所述DMRS端口标识确定传输模式。
- 根据权利要求8所述的方法,其特征在于,所述根据所述DMRS端口标识确定传输模式,包括:所述DMRS端口标识对应的码分复用CDM组的数量为第二预设值,确定传输模式为频分复用模式;所述DMRS端口标识对应的CDM组的数量为第三预设值,确定传输模式为空分复用模式;或者,所述DMRS端口标识属于同一个CDM组,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式;或者,所述DMRS端口标识的数量为第二预设值,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式;或者,所述DMRS端口标识属于预设标识,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式。
- 根据权利要求2或5所述的方法,其特征在于,所述配置指示信息为所述DMRS指示信息;所述根据所述配置指示信息确定传输模式,包括:根据所述DMRS指示信息确定CDM组的数量,根据所述CDM组的数量确定传输模式。
- 根据权利要求10所述的方法,其特征在于,所述根据所述CDM组的数量确定传输模式,包括:所述CDM组的数量为第二预设值,确定传输模式为频分复用模式;所述CDM组的数 量为第三预设值,确定传输模式为空分复用模式。
- 根据权利要求9或11所述的方法,其特征在于,所述确定传输模式为频分复用模式,包括:获取到频域重复传输参数,确定频分复用模式为第二频分复用模式;反之,确定频分复用模式为第一频分复用模式;其中,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式。
- 根据权利要求2所述的方法,其特征在于,所述根据所述配置指示信息确定传输模式,包括:根据所述时域重复传输参数确定传输模式为第二时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求13所述的方法,其特征在于,所述配置指示信息为DMRS指示信息;所述根据所述配置指示信息确定传输模式,包括:根据所述DMRS指示信息确定DMRS端口信息,根据所述DMRS端口信息确定传输模式。
- 根据权利要求14所述的方法,其特征在于,所述DMRS端口信息包括DMRS端口标识和未承载数据的CDM组的数量;所述根据所述DMRS端口信息确定传输模式,包括:根据所述DMRS端口标识对应的CDM组的数量和所述未承载数据的CDM组的数量,确定传输模式为空分复用模式、频分复用模式或第一时分复用模式;第一时分复用模式为时隙单元内的时分复用模式;若传输模式为所述频分复用模式,根据所述DMRS端口标识对应的CDM组的组标识确定传输模式为第一频分复用模式或第二频分复用模式;所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式。
- 根据权利要求1所述的方法,其特征在于,所述配置指示信息为所述DMRS指示信息和所述重复传输指示信息,所述重复传输指示信息用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数;所述根据所述配置指示信息确定传输模式,包括:根据所述DMRS指示信息确定CDM组的数量,根据所述CDM组的数量、所述频域重复传输参数、所述第一时域重复传输参数和所述第二时域重复传输参数确定传输模式。
- 根据权利要求1所述的方法,其特征在于,所述配置指示信息为所述传输配置指 示信息,所述传输配置指示信息用于指示传输配置指示状态;所述根据所述配置指示信息确定传输模式,包括:所述传输配置指示状态的数量为第四预设值,确定传输模式为频分复用模式或空分复用模式;所述传输配置指示状态的数量大于第四预设值,确定传输模式为时分复用模式。
- 根据权利要求1所述的方法,其特征在于,所述配置指示信息为所述传输配置指示信息和所述重复传输指示信息;所述传输配置指示信息用于指示传输配置指示状态;所述重复传输指示信息用于指示时域重复传输参数;所述根据所述配置指示信息确定传输模式,包括:根据所述传输配置指示状态的数量和所述时域重复传输参数,确定传输模式为时分复用模式。
- 一种传输模式确定方法,其特征在于,包括:在获取到配置信息的情况下,获取传输模式指示信息,所述传输模式指示信息用于指示传输模式;根据所述传输模式指示信息确定所述传输模式。
- 根据权利要求19所述的方法,其特征在于,所述传输模式为空分复用传输模式、第一频分复用传输模式、第二频分复用传输模式、第一时分复用传输模式或第二时分复用传输模式中的一种或多种;其中,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式;所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求19所述的方法,其特征在于,所述配置信息用于指示终端设备能够使用低于预设码率的码率,或者用于指示终端设备使用预设的调制编码策略表。
- 一种通信装置,其特征在于,包括至少一个处理器和收发器;所述收发器,用于获取配置指示信息,所述配置指示信息为DMRS指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;所述处理器,用于根据所述配置指示信息确定传输模式,所述传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
- 根据权利要求22所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示时域重复传输参数。
- 根据权利要求23所述的通信装置,其特征在于,所述处理器具体用于根据所述时 域重复传输参数确定传输模式为时分复用模式。
- 根据权利要求24所述的通信装置,其特征在于,所述处理器具体用于:所述时域重复传输参数为第一时域重复传输参数,确定时分复用模式为第一时分复用模式;或者,所述时域重复传输参数为第二时域重复传输参数,确定时分复用模式为第二时分复用模式;或者,所述时域重复传输参数包括偏移信息,确定时分复用模式为第一时分复用模式;反之,确定时分复用模式为第二时分复用模式;其中,所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求22所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数;所述处理器具体用于:所述第一时域重复传输参数和所述第二时域重复传输参数均为第一预设值,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式;所述第一时域重复传输参数或所述第二时域重复传输参数中一个或多个大于第一预设值,确定传输模式为时分复用模式。
- 根据权利要求26所述的通信装置,其特征在于,所述处理器具体用于:所述第一时域重复传输参数为所述第一预设值,所述第二时域重复传输参数大于所述第一预设值,确定时分复用模式为第二时分复用模式;所述第二时域重复传输参数为所述第一预设值,所述第一时域重复传输参数大于所述第一预设值,确定时分复用模式为第一时分复用模式;所述第一时域重复传输参数和所述第二时域重复传输参数均大于所述第一预设值,确定时分复用模式为第一时分复用模式与第二时分复用模式的组合模式;其中,所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求23或26所述的通信装置,其特征在于,所述处理器,还用于在所述收发器未获取到所述配置指示信息的情况下,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式。
- 根据权利要求23或26所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为DMRS指示信息;所述处理器具体用于:根据所述DMRS指示信息确定DMRS端口标识,并根据所述DMRS端口标识确定传输模式。
- 根据权利要求29所述的通信装置,其特征在于,所述处理器具体用于:所述DMRS端口标识对应的CDM组的数量为第二预设值,确定传输模式为频分复用模式;所述DMRS端口标识对应的CDM组的数量为第三预设值,确定传输模式为空分复用模式;所述DMRS端口标识属于同一个CDM组,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式;所述DMRS端口标识的数量为第二预设值,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式;所述DMRS端口标识属于预设标识,确定传输模式为频分复用模式;反之,确定传输模式为空分复用模式。
- 根据权利要求23或26所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为DMRS指示信息;所述处理器具体用于:根据所述DMRS指示信息确定CDM组的数量,并根据所述CDM组的数量确定传输模式。
- 根据权利要求31所述的通信装置,其特征在于,所述处理器具体用于:所述CDM组的数量为第二预设值,确定传输模式为频分复用模式;所述CDM组的数量为第三预设值,确定传输模式为空分复用模式。
- 根据权利要求30或32所述的通信装置,其特征在于,所述处理器具体用于:获取到频域重复传输参数,确定频分复用模式为第二频分复用模式;反之,确定频分复用模式为第一频分复用模式;其中,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式。
- 根据权利要求23所述的通信装置,其特征在于,所述处理器具体用于:根据所述时域重复传输参数确定传输模式为第二时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求34所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为DMRS指示信息;所述处理器具体用于:根据所述DMRS指示信息确定DMRS端口信息,并根据所述DMRS端口信息确定传输模式。
- 根据权利要求35所述的通信装置,其特征在于,所述处理器确定出所述DMRS端口信息包括DMRS端口标识和未承载数据的CDM组的数量;所述处理器具体用于:根据所述DMRS端口标识对应的CDM组的数量和所述未承载数据的CDM组的数量, 确定传输模式为空分复用模式、频分复用模式或第一时分复用模式;第一时分复用模式为时隙单元内的时分复用模式;若传输模式为所述频分复用模式,根据所述DMRS端口标识对应的CDM组的组标识确定传输模式为第一频分复用模式或第二频分复用模式;所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式。
- 根据权利要求22所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为所述DMRS指示信息和所述重复传输指示信息,所述重复传输指示信息用于指示频域重复传输参数、第一时域重复传输参数和第二时域重复传输参数;所述处理器具体用于:根据所述DMRS指示信息确定CDM组的数量,根据所述CDM组的数量、所述频域重复传输参数、所述第一时域重复传输参数和所述第二时域重复传输参数确定传输模式。
- 根据权利要求22所述的通信装置,其特征在于,所述处理器确定出所述配置指示信息为所述传输配置指示信息,所述传输配置指示信息用于指示传输配置指示状态;所述处理器具体用于:所述传输配置指示状态的数量为第四预设值,确定传输模式为频分复用模式或空分复用模式;所述传输配置指示状态的数量大于第四预设值,确定传输模式为时分复用模式。
- 根据权利要求22所述的装置,其特征在于,所述处理器确定出所述配置指示信息为所述传输配置指示信息和所述重复传输指示信息;所述传输配置指示信息用于指示传输配置指示状态;所述重复传输指示信息用于指示时域重复传输参数;所述处理器具体用于:根据所述传输配置指示状态的数量和所述时域重复传输参数,确定传输模式为时分复用模式。
- 一种通信装置,其特征在于,包括至少一个处理器和收发器;所述处理器,用于在所述收发器获取到配置信息的情况下,获取传输模式指示信息,所述传输模式指示信息用于指示传输模式;根据所述传输模式指示信息确定所述传输模式。
- 根据权利要求40所述的通信装置,其特征在于,所述处理器确定出所述传输模式为空分复用传输模式、第一频分复用传输模式、第二频分复用传输模式、第一时分复用传输模式或第二时分复用传输模式中的一种或多种;其中,所述第一频分复用模式为基于单码字的频分复用模式,所述第二频分复用模式为基于多码字的频分复用模式;所述第一时分复用模式为时隙单元内的时分复用模式,所述第二时分复用模式为时隙单元间的时分复用模式。
- 根据权利要求40所述的通信装置,其特征在于,所述配置信息用于指示终端设备 能够使用低于预设码率的码率,或者用于指示终端设备使用预设的调制编码策略表。
- 一种芯片系统,其特征在于,包括至少一个处理器和接口;所述接口,用于将配置指示信息输入所述处理器,所述配置指示信息为DMRS指示信息、重复传输指示信息或传输配置指示信息中的一种或多种;所述处理器,用于根据所述配置指示信息确定传输模式,所述传输模式为空分复用模式、频分复用模式或时分复用模式中的一种或多种。
- 根据权利要求43所述的芯片系统,其特征在于,所述处理器确定出所述配置指示信息为所述重复传输指示信息,所述重复传输指示信息用于指示第一时域重复传输参数和第二时域重复传输参数;所述处理器具体用于:所述第一时域重复传输参数和所述第二时域重复传输参数均为第一预设值,确定传输模式为空分复用模式、频分复用模式或空分复用模式与频分复用模式的组合模式;所述第一时域重复传输参数或所述第二时域重复传输参数中一个或多个大于第一预设值,确定传输模式为时分复用模式。
- 一种芯片系统,其特征在于,包括至少一个处理器和接口;所述处理器,用于在接收到所述接口输入的配置信息的情况下,获取传输模式指示信息,所述传输模式指示信息用于指示传输模式;所述处理器,还用于根据所述传输模式指示信息确定所述传输模式。
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KR1020227008667A KR20220047828A (ko) | 2019-08-16 | 2019-09-28 | 전송 모드를 결정하기 위한 방법 및 장치 |
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CN112583523B (zh) * | 2019-09-30 | 2022-04-15 | 大唐移动通信设备有限公司 | 一种传输模式的指示方法、装置、基站、终端及存储介质 |
CN117813885A (zh) * | 2022-08-01 | 2024-04-02 | 北京小米移动软件有限公司 | 传输复用方式的指示方法、装置、介质及产品 |
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US20220173866A1 (en) | 2022-06-02 |
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