WO2019201247A1 - 配置信息的发送方法及装置 - Google Patents

配置信息的发送方法及装置 Download PDF

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Publication number
WO2019201247A1
WO2019201247A1 PCT/CN2019/082912 CN2019082912W WO2019201247A1 WO 2019201247 A1 WO2019201247 A1 WO 2019201247A1 CN 2019082912 W CN2019082912 W CN 2019082912W WO 2019201247 A1 WO2019201247 A1 WO 2019201247A1
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WIPO (PCT)
Prior art keywords
information
configuration information
frequency domain
control channel
channel
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PCT/CN2019/082912
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English (en)
French (fr)
Inventor
张淑娟
鲁照华
李儒岳
张楠
高波
王飞鸣
Original Assignee
中兴通讯股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Application filed by 中兴通讯股份有限公司 filed Critical 中兴通讯股份有限公司
Priority to FIEP19788637.7T priority Critical patent/FI3783977T3/fi
Priority to EP19788637.7A priority patent/EP3783977B1/en
Priority to US17/048,315 priority patent/US12022497B2/en
Priority to EP24175113.0A priority patent/EP4432758A1/en
Publication of WO2019201247A1 publication Critical patent/WO2019201247A1/zh
Priority to US18/666,449 priority patent/US20240306178A1/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0053Allocation of signaling, i.e. of overhead other than pilot signals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/50Allocation or scheduling criteria for wireless resources
    • H04W72/53Allocation or scheduling criteria for wireless resources based on regulatory allocation policies
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0058Allocation criteria
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0058Allocation criteria
    • H04L5/0064Rate requirement of the data, e.g. scalable bandwidth, data priority
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W56/00Synchronisation arrangements
    • H04W56/004Synchronisation arrangements compensating for timing error of reception due to propagation delay
    • H04W56/0045Synchronisation arrangements compensating for timing error of reception due to propagation delay compensating for timing error by altering transmission time
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • H04W72/0446Resources in time domain, e.g. slots or frames
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • H04W72/0453Resources in frequency domain, e.g. a carrier in FDMA
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/20Control channels or signalling for resource management
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/20Control channels or signalling for resource management
    • H04W72/23Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/003Arrangements for allocating sub-channels of the transmission path
    • H04L5/0048Allocation of pilot signals, i.e. of signals known to the receiver

Definitions

  • the present disclosure relates to the field of communications, and in particular to a method and apparatus for transmitting configuration information.
  • a high-level configuration signaling of a data channel or a control channel only needs one set.
  • multiple TRP transmissions multiple panel transmissions, and considering each TRP or each panel
  • a flexible signaling configuration method is required, and since multiple TRPs or multiple panels are relatively independent in transmission, how to avoid collisions between their scheduled resources and reduce interference between them is the core of this paper. problem.
  • the embodiments of the present disclosure provide a method and an apparatus for transmitting configuration information, so as to at least solve the problem that the related art lacks data transmission between multiple TRPs and terminals.
  • a method for transmitting configuration information including: transmitting configuration information, where the configuration information includes at least one of: configuring N sets of data channel configuration information for one frequency domain bandwidth; A set of control channel resource configuration information is configured for one frequency domain bandwidth; and C sets of measurement reference signal configuration information are configured for one frequency domain bandwidth; wherein, the N, M, and C are integers greater than or equal to 1.
  • a method for determining a correspondence relationship includes: determining a correspondence between a P control channel resource and a Q set configuration information of a transmission parameter set; wherein the P is A positive integer greater than or equal to 1, the Q being a positive integer less than or equal to P.
  • a method for determining time advance TA information including: the first communication node determines the TA information according to at least one of the following information: a first channel, a first signal, a second channel, a second signal; wherein the first channel or the first signal is a channel or a signal sent by the first communication node, and the second channel or the second signal is a channel or a signal received by the first communication node; Transmitting a third channel or a third signal according to the TA information.
  • a method for determining TA information including: the second communication node sends signaling information to the first communication node, where the signaling information includes at least one of the following associations: a first channel or an association relationship between the first signal and the TA information; an association relationship between the second channel or the second signal and the TA information; the first channel or the first signal, and the second channel Or a combination of the second signal and the TA information; wherein the first channel or the first signal is a signal sent by the first communication node, and the second channel or the second signal is The signal received by the first communication node.
  • a device for transmitting configuration information comprising: a first sending module, configured to send configuration information, wherein the configuration information includes at least one of: one Configuring N sets of data channel configuration information in the frequency domain bandwidth; configuring M sets of control channel resource configuration information for one frequency domain bandwidth; and configuring C sets of measurement reference signal configuration information for one frequency domain bandwidth; wherein, the N, M, C are greater than Or an integer equal to 1.
  • a determining device for a correspondence relationship comprising: a first determining module configured to determine between P control channel resources and a set of transmission parameter sets of Q sets of configuration information Correspondence relationship; wherein P is a positive integer greater than or equal to 1, and Q is a positive integer less than or equal to P.
  • a determining apparatus for time advance TA information comprising: a second determining module, configured to determine TA information according to at least one of: first channel, first signal, first a second channel, wherein the first channel or the first signal is a channel or a signal sent by the first communication node, and the second channel or the second signal is a channel received by the first communication node Or a signal; the second sending module is configured to send the third channel or the third signal according to the TA information.
  • a device for determining TA information including: a second sending module, configured to send signaling information to a first communications node, where the signaling information includes the following association relationship at least One of: a first channel or an association relationship between the first signal and the TA information; an association relationship between the second channel or the second signal and the TA information; the first channel or the first signal, and the a combination of a second channel or a second signal, and an association relationship between the TA information; wherein the first channel or the first signal is a signal sent by the first communication node, the second channel or The two signals are signals received by the first communication node.
  • a storage medium having stored therein a computer program, wherein the computer program is configured to perform the steps of any one of the method embodiments described above at runtime.
  • an electronic device comprising a memory and a processor, wherein the memory stores a computer program, the processor being configured to execute the computer program to perform any of the above The steps in the method embodiments.
  • the configuration information is sent, where the configuration information includes at least one of: configuring N sets of data channel configuration information for one frequency domain bandwidth; configuring M sets of control channel resource configuration information for one frequency domain bandwidth; The bandwidth configuration C sets the measurement reference signal configuration information; wherein the N, M, and C are integers greater than or equal to 1, and the foregoing technical solution solves the problem that the related art lacks data transmission between the multiple TRPs and the terminal.
  • the configuration information includes at least one of: configuring N sets of data channel configuration information for one frequency domain bandwidth; configuring M sets of control channel resource configuration information for one frequency domain bandwidth;
  • the bandwidth configuration C sets the measurement reference signal configuration information; wherein the N, M, and C are integers greater than or equal to 1, and the foregoing technical solution solves the problem that the related art lacks data transmission between the multiple TRPs and the terminal.
  • FIG. 1 is a flowchart of a method of transmitting configuration information according to an embodiment of the present disclosure
  • FIG. 2 is a schematic diagram 1 of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 3 is a second schematic diagram of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 4 is a schematic diagram 3 of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 5 is a schematic diagram 4 of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 6 is a schematic diagram 5 of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 7 is a schematic diagram 1 of using the same downlink timing when a terminal uses multiple panels to send uplink signals to multiple TRPs according to the present application;
  • FIG. 8 is a schematic diagram 2 of using the same downlink timing when a terminal uses multiple panels to send uplink signals to multiple TRPs according to the present application;
  • FIG. 9 is a schematic diagram 1 of a terminal transmitting a uplink signal to multiple TRPs by using a plurality of panels according to the present application;
  • FIG. 10 is a schematic diagram of different TRPs corresponding to different PUCCH resource sets according to the present application.
  • the first communication node in the present application file may be a terminal, and the second communication node may be a base station, but is not limited thereto.
  • a mobile communication network including but not limited to a 5G mobile communication network
  • the network architecture of the network may include a network side device (for example, a base station) and a terminal.
  • a network side device for example, a base station
  • an information transmission method that can be run on the network architecture is provided. It should be noted that the operating environment of the foregoing information transmission method provided in the embodiment of the present application is not limited to the foregoing network architecture.
  • FIG. 1 is a flowchart of a method for sending configuration information according to an embodiment of the present disclosure. As shown in FIG. 1, the process includes the following steps. :
  • Step S102 determining configuration information, where the configuration information includes at least one of: configuring N sets of data channel configuration information for one frequency domain bandwidth; configuring M sets of control channel resource configuration information for one frequency domain bandwidth; and being a frequency domain bandwidth Configuring C sets of measurement reference signal configuration information; wherein, N, M, and C are integers greater than or equal to 1;
  • step S104 the configuration information is sent.
  • the configuration information of a set of control channel resources may be one of the following configuration information: a set of PDCCH configuration information, a set of CORESET configuration information, a set of search space configuration information, and a set corresponding to a degree of aggregation.
  • Configuration information of the search space a set of PUCCH configuration information.
  • the configuration information is sent by using the foregoing steps, where the configuration information includes at least one of: configuring N sets of data channel configuration information for one frequency domain bandwidth; configuring M sets of control channel resource configuration information for one frequency domain bandwidth; The bandwidth configuration C sets the measurement reference signal configuration information; wherein the N, M, and C are integers greater than or equal to 1, and the foregoing technical solution solves the problem that the related art lacks data transmission between the multiple TRPs and the terminal.
  • the configuration information includes at least one of: configuring N sets of data channel configuration information for one frequency domain bandwidth; configuring M sets of control channel resource configuration information for one frequency domain bandwidth;
  • the bandwidth configuration C sets the measurement reference signal configuration information; wherein the N, M, and C are integers greater than or equal to 1, and the foregoing technical solution solves the problem that the related art lacks data transmission between the multiple TRPs and the terminal.
  • the execution body of the foregoing steps may be a base station, a terminal, or the like, but is not limited thereto.
  • step S102 and step S104 are interchangeable, that is, step S104 may be performed first, and then S102 is performed.
  • the one frequency domain bandwidth is a bandwidth part BWP, and/or the one frequency domain bandwidth is a proprietary frequency domain bandwidth.
  • the method further includes at least one of the following:
  • the physical layer control signaling further indicates which set of configuration information is used by a set of transmission parameters used by the scheduled channel; the generating parameter of the scrambling sequence in this embodiment may be an n ID in the subsequent formula (2) or C-RNTI;
  • N1, N2, N3, N4, M1, M2, D1, D2, M3, C1 are positive integers greater than or equal to one.
  • the foregoing correspondence may be: which data channel is used for the configuration information of the control channel; or which uplink control channel is used for controlling the downlink control channel; or which set of control channel configuration information corresponds to which data channel configuration information.
  • the downlink BWP1 includes the configuration information of the M1 PDCCH
  • the downlink BWP2 includes the configuration information of the N1 set of the PDSCH
  • the PDSCH of the BWP2 that is scheduled to be in one PDCCH in the BWP1 is the N1 set of the PDSCH included in the BWP2.
  • the frequency domain bandwidth of the foregoing embodiment may include at least one of the following:
  • the first frequency domain bandwidth and the second frequency domain bandwidth are both downlink frequency domain bandwidths
  • the first frequency domain bandwidth is an uplink frequency domain bandwidth
  • the second frequency domain bandwidth is a downlink frequency domain bandwidth
  • the third frequency domain bandwidth is an uplink frequency domain bandwidth
  • the fourth frequency domain bandwidth is a downlink frequency domain bandwidth
  • the fifth frequency domain bandwidth and the sixth frequency domain bandwidth are both downlink frequency domain bandwidths
  • the fifth frequency domain bandwidth is an uplink frequency domain bandwidth
  • the sixth frequency domain bandwidth is a downlink frequency domain bandwidth
  • the method comprises at least one of the following:
  • the first control signaling in the second frequency domain bandwidth schedules the first data channel in the first frequency domain bandwidth, where the transmission parameter of the first control signaling is based on the M1 set included in the second frequency domain bandwidth Obtaining, in a set of configuration information of the control channel resource, the transmission parameter of the first data channel is obtained according to a set of data channel configuration information in a second frequency domain bandwidth corresponding to the set of control channel resource configuration information;
  • the second control signaling in the fourth frequency domain bandwidth schedules a third control channel in the third frequency domain bandwidth, where the transmission parameter of the second control signaling is based on the M2 set included in the fourth frequency domain bandwidth Obtaining, in a configuration of the control channel resource, the transmission parameter of the third control channel is obtained according to a set of control channel configuration information in a third frequency domain bandwidth corresponding to the set of control channel resource configuration information;
  • the third control signaling in the sixth frequency domain bandwidth schedules the second data channel in the fifth frequency domain bandwidth, where the transmission parameter of the third control signaling is based on one of the control channel configuration information in the sixth frequency domain bandwidth a set of control channel resource configuration information acquisition (may be one of the D1 sets of control channel resource configuration information included in the sixth frequency domain bandwidth previously described), and the transmission parameter of the second data channel is controlled according to the set Obtaining a set of data channel configuration information in a fifth frequency domain bandwidth in which the channel resource configuration information has a corresponding relationship;
  • the fourth control signaling in the eighth frequency domain bandwidth schedules the fourth control channel in the seventh frequency domain bandwidth, where the transmission parameter of the fourth control signaling is based on a control channel configuration information in the eighth frequency domain bandwidth a set of control channel resource configuration information acquisition (may be one of the D2 sets of control channel resource configuration information included in the eighth frequency domain bandwidth previously recorded), and the transmission parameter of the fourth control channel is based on the set of control A set of control channel configuration information is acquired in the seventh frequency domain bandwidth in which the channel resource configuration information has a corresponding relationship.
  • Sending a first control signaling where the first control signaling is used to configure or schedule one of the frequency domain bandwidths, where the first control signaling includes N5 sets of data channels included in the one frequency domain bandwidth a configuration information index information of the configuration information, where the transmission parameter of the data channel is obtained according to the data channel configuration information corresponding to the index information;
  • Sending a second control signaling where the second control signaling is used to configure or schedule one control channel in a frequency domain bandwidth, where the second control signaling includes N6 sets of control channels included in the one frequency domain bandwidth a configuration information index information of the configuration information, where the transmission parameter of the control channel is obtained according to the control channel resource configuration information corresponding to the index information;
  • Sending a third control signaling where the third control signaling is used to configure or schedule a measurement reference signal resource in a frequency domain bandwidth, where the third control signaling includes a C2 set measurement included in the one frequency domain bandwidth a configuration information index information of the reference signal configuration information, where the transmission parameter of the measurement reference signal resource is obtained according to the measurement reference signal configuration information corresponding to the index information;
  • N5, N6, and C2 are positive integers greater than or equal to 1.
  • the first control signaling is physical layer control signaling
  • the second control signaling is physical layer control signaling
  • the third control signaling is physical layer control signaling
  • a method for determining a correspondence relationship comprising the following steps:
  • Step 1 Determine a correspondence between P control channel resources and Q sets of configuration information of a transmission parameter set; wherein P is a positive integer greater than or equal to 1, and the Q is a positive integer less than or equal to P.
  • the solution of the related art lacks the connection of configuration information of multiple control channel resources and multiple sets of transmission parameters in the related art, and establishes a correspondence relationship between multiple control channel resources and configuration information of multiple sets of transmission parameters, and subsequently Data can be transferred based on this.
  • a set of transmission parameters may be: the parameter set includes multiple parameters, and different sets of configuration information corresponding to multiple sets of control channel resources have different values of the multiple parameters.
  • determining a correspondence between P control channel resources and Q sets of configuration information of a transmission parameter set where the method further includes at least one of: a first control signaling scheduling channel or a signal, where the first The transmission parameter of the control signaling is determined according to a parameter of one of the P control channel resources, and the set of transmission parameters of the channel or the signal is set according to the Q set configuration information corresponding to the one control channel resource.
  • Configuration information is determined;
  • the one transmission parameter set is a transmission parameter set corresponding to a channel or a signal, where the control signaling for scheduling the channel or the signal is included in a control channel included in the P2 control channel resources, or included in the P2 control channel resources. In the channel scheduled by the control channel, wherein the P2 control channel resources belong to the P control channel resources.
  • the P control channel resources and/or the Q set configuration information of the one transmission parameter set meet at least one of the following characteristics:
  • the P control channel resources belong to the same frequency domain bandwidth
  • the Q channels or Q signals corresponding to the Q sets of configuration information of the one transmission parameter set belong to the same frequency domain bandwidth
  • the P control channel resources are control channel resources that the first communication node needs to detect (required that the P control channel resources are for one terminal);
  • the P control channel resources and the Q channels or Q signals corresponding to the Q set configuration information belong to the same frequency domain bandwidth;
  • the first communication node can simultaneously receive the Q-type channel and/or signal corresponding to the Q-set configuration information, where the first communication node is a node that receives the control channel resource;
  • the first communication node can simultaneously receive the P control channel resources, where the first communication node is a node that receives the control channel resource;
  • the first communication node cannot simultaneously receive different control channel resources in the P1 control channel resources, where the P1 control channel resources belong to the P control channel resources, and the same set of configuration information corresponding to one transmission parameter set, the first A communication node is a node that receives control channel resources;
  • the first communication node cannot simultaneously receive a plurality of control channel resources corresponding to the same set of configuration information of a transmission parameter set, wherein the first communication node is a node that receives the control channel resource;
  • the one transmission parameter set is a transmission parameter about the channel or the signal.
  • determining a correspondence between P control channel resources and Q sets of configuration information of a transmission parameter set includes at least one of the following:
  • the one transmission parameter set is a transmission parameter set corresponding to a channel or a signal, wherein the control signaling for scheduling the channel or the signal is included in a control channel included in one control channel resource, or includes a control channel scheduling included in a control channel resource.
  • the control signaling for scheduling the channel or the signal is included in a control channel included in one control channel resource, or includes a control channel scheduling included in a control channel resource.
  • the one transmission parameter set is a transmission parameter set corresponding to a channel or a signal, wherein the control signaling for scheduling the channel or the signal is included in a control channel included in the control channel resource group, or includes a control channel scheduling included in the control channel resource group.
  • the control signaling for scheduling the channel or the signal is included in a control channel included in the control channel resource group, or includes a control channel scheduling included in the control channel resource group.
  • the Q1, Q2 is an integer less than or equal to Q
  • the P1 is an integer less than or equal to P.
  • the bandwidth of the one frequency domain is a component carrier (CC) or a bandwidth component (Band Width Part, Referred to as BWP).
  • the correspondence between the P control channel resources and the Q set configuration information of the one transmission parameter set is indicated by one of the following manners:
  • the configuration information index information of the Q-set configuration information (that is, the configuration information index information including the Q-set configuration information in the control channel resource configuration information) is included in the configuration information of the control channel resource;
  • the control channel resource index information of the P control channel resources is included in the Q set configuration information of the one transmission parameter set.
  • determining a correspondence between P control channel resources and Q sets of configuration information of the one transmission parameter set where the method further includes at least one of the following:
  • the number of bits of the first control signaling is determined according to one set of the Q sets of configuration information
  • the number of bits of the predetermined bit field of the first control signaling is determined according to one set of the Q sets of configuration information
  • the transmission parameter of the control channel where the first control signaling is located is obtained according to a transmission parameter of one of the P control channel resources, and the correspondence between the set of configuration information and the one control channel resource exists. .
  • the first control channel resource in the optional embodiment may be any one of the P control channel resources or a specified one, and is not used to limit the order of P control channel resources.
  • the Nth information in the Nth resource is the same as the Nth resource.
  • the one transmission parameter set includes at least one of the following parameter information: process number set information, BWP set information, uplink control channel resource set information, demodulation reference signal port set information, demodulation reference signal information, and quasi-common reference Signal set information, Transmission Configuration Indication (TCI) state pool indication information, downlink data channel indication information, uplink data channel indication information, uplink control channel indication information, precoding resource granularity PRB bundling size Indication information, rate matching rate mating indication information, carrier carrier indicator indication information, measurement reference signal information, generation parameters of a scrambling sequence, TA information, port information of a control channel, time domain resource allocation parameter, frequency domain resource allocation parameter, non The period measurement reference signal information; wherein one TCI state includes configuration information of a plurality of quasi-co-located reference signal sets of the acquirer.
  • TCI Transmission Configuration Indication
  • control channel resource is a physical layer control channel resource; and/or configuration information of the one transmission parameter set is included in high layer signaling.
  • the method further includes:
  • determining a correspondence between the P control channel resources and the Q set configuration information of a transmission parameter set where: a control channel resource corresponds to a Q1 set configuration information of a transmission parameter set, where the Q1 is greater than Or an integer equal to 1.
  • the following information is indicated by the control signaling transmitted in the one control channel resource: determining the channel or signal scheduled by the control signaling according to the specified set in the Q1 set configuration information.
  • Transmission parameters (It should be noted that the first set in the optional embodiment may be any one of the Q sets of configuration information or a specified set, and is not used to limit the order of the Q sets of configuration information).
  • the P control channel resources include one of the following features:
  • the one control channel resource is a physical downlink control channel PDCCH control channel resource
  • the one control channel resource is a control resource set CORESET resource
  • the one control channel resource is a search space set Search space set resource
  • the one control channel resource is a degree of aggregation of the Search space resource
  • the one control channel resource is a candidate physical downlink control channel Candidate PDCCH resource
  • the scrambling sequence of the one control channel generates parameters.
  • a method for determining time advance TA information comprising the steps of:
  • Step 1 The first communications node determines the TA information according to at least one of the following information: a first channel, a first signal, a second channel, and a first signal; wherein the first channel or the first signal is sent by the first communications node Channel or signal, the second channel or second signal being a channel or signal received by the first communication node;
  • Step 2 Send a third channel or a third signal according to the TA information.
  • the first signal may be a beam signal sent by the terminal.
  • the solution lacking the determined TA value in the related art is solved, and the TA value for transmitting the third signal is determined accurately according to the first signal and/or the second signal.
  • the second channel or the second signal is a channel or a signal received by the first communications node, and further satisfies at least one of the following features:
  • the second channel is a control channel, and the control channel includes a control signaling for scheduling the third channel or the third signal;
  • the second signal and the demodulation reference signal of the control signaling for scheduling the third channel or the third signal satisfy a quasi co-location QCL relationship with respect to at least one quasi co-location parameter, including: the second signal and The QCL relationship is satisfied with respect to delay spread and/or average delay between demodulation reference signals for scheduling control signaling of the third channel or the third signal.
  • the QCL relationship is satisfied at least with respect to the multipath TA and/or the average TA.
  • control signaling for scheduling the first channel and the third channel or the third signal belongs to one and the same control channel resource.
  • the first communications node acquires at least one of the following information of the third channel or the third signal according to the first signal: spatial filtering parameter information of the third channel or the third signal, the third channel or the Power parameter information of the three signals.
  • the TA information is a time difference between a start position of the first time unit and a start position of the second time unit, where the third channel or the third signal corresponds to the first time unit, the first The two channel or third signal corresponds to the second time unit.
  • the first time unit may be an uplink time unit
  • the second time unit may be a downlink time unit.
  • the method further includes at least one of the following:
  • the first channel or the second channel or the third channel includes at least one of the following channels: a data channel, a control channel;
  • the first signal or the third signal includes at least one of the following: a demodulation reference signal, a measurement reference signal, and a random access signal;
  • the second signal includes at least one of the following: a demodulation reference signal, a measurement reference signal, a synchronization signal, and a measurement reference signal of a tracking reference signal TRS (tracking reference signal).
  • TRS tracking reference signal
  • an association relationship between the first channel or the first signal and the TA information an association relationship between the second channel or the second signal and the TA information; the first channel or the first signal, and The association between the second channel or the second signal and the TA information.
  • the association relationship between the setup signal and the TA information includes the at least one of: including the signal information in the configuration information of the TA information; and including the TA information in the configuration information of the signal; The information determines the TA information.
  • determining, by the first communications node, the TA information according to the second channel or the second signal determining, according to the scrambling code information corresponding to the second channel or the second signal, the TA information, according to the second channel or the second signal
  • the transmission parameter of the control channel resource is determined by the TA information, and the TA information is obtained according to the TA information included in the configuration information of the second channel.
  • a method for determining TA information comprising the following steps:
  • Step 1 The second communication node sends signaling information to the first communications node, where the signaling information includes at least one of the following associations:
  • the first channel or the first signal is a signal sent by the first communication node
  • the second channel or the second signal is a signal received by the first communication node
  • the establishing the relationship between the first signal and the TA information includes at least one of: including the first signal information in the configuration information of the TA information; and including the configuration information in the first signal TA information; determining the TA information according to the first signal information.
  • Other related relationships are the same.
  • the above technical solution solves the problem that the solution for determining the TA value of the signal sent by the terminal in the multi-TRP transmission scenario in the related art is solved, and the TA value may be determined according to the association relationship.
  • the TA information is a basis for the first communications node to send the third channel or the third signal, or the TA information is a basis for the first communications node to send the first channel or the second signal.
  • the method further includes: the first channel or the second channel or the third channel includes at least one of: a data channel, a control channel; and the first signal or the third signal includes at least one of the following signals: Demodulating the reference signal, measuring the reference signal, and randomly accessing the signal; the second signal comprises at least one of the following: a demodulation reference signal, a measurement reference signal, and a synchronization signal as a measurement reference signal of the tracking reference signal TRS.
  • the signaling information includes one of the following signaling information: the signaling information is high layer signaling information; and the signaling information is physical layer signaling information.
  • a method for determining TA information includes the following steps:
  • Step 1 The first communication node receives the configuration information of the third signal sent by the second communication node, where the configuration information includes the TA information.
  • Step 2 The first communications node sends the third signal according to the TA information.
  • the above technical solution solves the problem that the terminal cannot determine the TA value of the uplink signal in the multi-TRP transmission scenario in the related art, and provides a scheme for the terminal to determine the TA value according to the configuration information.
  • receiving the configuration information of the third signal including at least one of: receiving high-level configuration information of the third signal, determining that the high-level configuration information of the third signal is configuration information of the third signal, and receiving for scheduling The physical layer control signaling of the third signal, where the physical layer control signaling includes configuration information of the third signal.
  • the TA information is jointly encoded with at least one of the following: a spatial filtering parameter of the third signal; a power parameter of the third signal.
  • Multi-TRP transmission is: a terminal can receive more than one PDSCH at the same time under one BWP, or the number of DMRS groups of one PDSCH is greater than 1, wherein at least one demodulation reference signal port between the demodulation reference signal ports in one DMRS group is at least between Regarding the quasi-co-location parameters of a class satisfying the QCL relationship, different DMRSs in different DMRS groups do not satisfy the QCL relationship.
  • Table 1 is a schematic table of transmission scenarios under multiple TRPs according to the present application:
  • FIG. 2 is a schematic diagram 1 of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 3 is a second schematic diagram of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 5 is a schematic diagram of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure
  • FIG. 6 is a schematic diagram 5 of a transmission scenario of a PDSCH transmitted by a terminal receiving multiple TRPs according to the present disclosure.
  • DCI1 schedules PDSCH1
  • DCI2 schedules PDSCH2.
  • TRP1 and TRP2 there is no ideal Backhaul between TRP1 and TRP2. They independently schedule one terminal. When considering the different settings of TRP1 and TRP2, or considering the different UE groups they serve, one terminal can be in the same time unit.
  • PDSCH1 and PDSCH2 are simultaneously received in one BWP, PDSCH1 is transmitted through TRP1, and PDSCH2 is transmitted through TRP2.
  • the high-level configuration information corresponding to PDSCH1 and PDSCH2 may be different.
  • a plurality of PDSCHs may be included in one BWP, and configurations of multiple PDCCHs are further configured to further configure a relationship between multiple PDSCHs and multiple PDCCHs included in the BWP, so that when a PDSCH is scheduled in the DCI, high-level parameters of the PDSCH It is obtained by the configuration information of the PDSCH corresponding to the PDCCH in which the DCI is located.
  • the configuration information of the PDCCH is configured with information such as CORESET and Searchspace included in the PDCCH, and the following information is further configured in the configuration information of the PDSCH: scrambling information, demodulation reference signal information, TCI state pool, resource allocation information, rate matching information, and MCS reference. Table information, precoding resource group information, rate matching information, etc., such as a PDSCH configuration information configured to correspond to a PDSCH-Config configured in the 3Gpp standard version of 38.331.V15.0.0: a set of PDCCH configurations The information is configured to correspond to one of the PDCCH-Configs in the configuration of 38.331.V15.0.0 of the 3Gpp standard version.
  • different TRPs correspond to different (PDCCH, PDSCH) combinations, and the present embodiment does not exclude that one BWP includes multiple PDSCHs, one PDCCH, and then multiple CORESETs and multiple PDCCHs included in the one PDCCH are established.
  • PDSCHs for example, the following configuration form:
  • the PDCCH includes a plurality of CORESETs, and then a correspondence between the plurality of CORESETs and the plurality of PDSCH configuration information is established.
  • the DCI schedules a PDSCH, and the PDSCH is configured according to the high-level configuration information index of the PDSCH corresponding to the CORESET/Search space of the DCI.
  • the configuration parameter is obtained according to the PDSCH high-level configuration information corresponding to the configuration information index information.
  • the PDCCH includes CORESET1 and CORESET2, CORESET1 and pdsch-Config1 correspond to each other, and CORESET2 and pdsch-Config2 correspond to each other.
  • the high-level parameters of the PDSCH scheduled by the DCI transmitted in the CORESET1 are acquired according to the pdsch-Config1, and the DCI scheduled in the CORESET2 is scheduled.
  • the high-level parameters of the PDSCH are obtained according to pdsch-Config2.
  • CORESET corresponding to two C-RNTIs.
  • one CORESET is associated with only one C-RNTI, but is associated with multiple virtual cell numbers n ID , such as establishing two Corresponds to pdsch-Config1, Corresponding to pdsch-Config2, according to The high-level parameters of the successfully decoded PDI scheduled PDSCH are obtained according to pdsch-Config1, according to The high-level parameters of the successfully decoded PDI scheduled PDSCH are obtained according to pdsch-Config2.
  • n RNTI is determined according to the above C-RNTI when the dedicated control channel is used, and n ID may be a cell ID.
  • One of the control channel resources may be one of the following: a PDCCH corresponding to the PDCCH configuration information, a CORESET, a search space, a search space corresponding to the degree of aggregation, and a parameter corresponding to the scrambling sequence of the DCI.
  • the configuration includes multiple PDSCHs in one BWP.
  • the high-level parameter corresponding to the scheduled PDSCH is further indicated in the DCI of the scheduled PDSCH, which is a set of high-level parameter configuration sets belonging to one transmission parameter set configured in the PDSCH high-level configuration parameter.
  • a correspondence between multiple control channel resources in one BWP and multiple sets of uplink control channel configurations included in one uplink BWP may be established; and/or multiple control channel resources and one uplink BWP in one BWP may be established.
  • the configuration information of one set of PUSCH can be configured to correspond to one PUSCH-Config in the configuration of 38.331.V15.0.0 of the 3Gpp standard version
  • the configuration information of a set of PUCCH can be configured to correspond to the 3Gpp standard version of 38.331.V15.0.0
  • the transmission parameter is a transmission parameter of a channel or signal scheduled by the control channel resource. Determining configuration information of the one transmission parameter set corresponding to a control channel resource.
  • TRP1 and TRP2 independently schedule the UE to increase the spectrum efficiency.
  • TRP1 and TRP2 schedule the UEs in the same BWP, although they consider beam isolation between them. The degree is better, but it is still necessary to guarantee the reference signal, or the robustness between the control channels.
  • And/or users of services under TRP1 and TRP2 are busy with different delay requirements, and need to consider that the configurations of channels/signals that are allowed to be respectively scheduled by them may be different, so that for the UE, one transmission parameter under one BWP may correspond to more Set of configurations.
  • the transmission parameter in the one transmission parameter set includes at least one of the following transmission parameters: process number set information, uplink control channel resource set information, demodulation reference signal port set, demodulation reference signal information, and quasi-common reference signal set information. , TCI state pool information, transmission parameter information of the downlink data channel, transmission parameters of the uplink data channel, uplink control channel information, PRB Bundling size, rate matching information, measurement reference signal information, code block group ( Code Block Group, referred to as CBG) information, generation parameter information of the scrambling sequence, TA information.
  • process number set information uplink control channel resource set information
  • demodulation reference signal port set demodulation reference signal information
  • quasi-common reference signal set information includes at least one of the following transmission parameters: process number set information, uplink control channel resource set information, demodulation reference signal port set, demodulation reference signal information, and quasi-common reference signal set information.
  • TCI state pool information transmission parameter information of the downlink data channel, transmission parameters of the uplink data channel, uplink control channel information
  • CORESET1 is a TRP1 transmission
  • a PDCCH transmitted in CORESET1 schedules a downlink channel/signal sent by the TRP1 to the UE, or an uplink channel/signal sent by the UE to the TRP1
  • CORESET2 is a TRP2 transmission
  • a PDCCH scheduled to be transmitted in the CORESET2 is sent to the UE by the TRP2.
  • TRP1 and TRP2 can schedule PDSCH/CSI-RS/CORESET/PUCCH/PUSCH/SRS/SR in the same BWP, in order to ensure the accuracy of the signal, it is necessary to determine the process number set of the channel scheduled by CORESET1, so that TRP1 can occur. Do not confuse with PDSCH/PUSCH transmitted in TRP2, because TRP1 and TRP2 each independently transmit channels and there is no ideal Backhaul between them.
  • the set of process numbers in CORESET1 is ⁇ 0, 1, 2, 3 ⁇
  • the process ID of the PDSCH/PUSCH indicated in the PDCCH included in CORESET1 is a relative index in the process number set ⁇ 0, 1, 2, 3 ⁇ .
  • the set of process numbers in CORESET2 is ⁇ 4, 5, 6, 7 ⁇
  • the process ID of the PDSCH/PUSCH indicated in the PDCCH included in CORESET2 is the relative index in the process number set ⁇ 4, 5, 6, 7 ⁇ , for example.
  • the process ID relative index is 0 in the PDCCH, and the process number corresponding to the PDSCH/PUSCH is 4. If the process number set and the control channel resource are not matched, CORESET1 will also schedule the process number 0, and CORESET2 will also schedule the process number 0.
  • the terminal will consider the same process data to be merged. In fact, they are sent by different TRPs. Different data cannot be merged.
  • an association between the CORESET and the uplink control channel resource set may be established, for example, the CORESET1 corresponds to the PUCCH resource set 1, the CORESET2 corresponds to the PUCCH resource set 2, and the PUCCH resource set 1 and the PUCCH resource set 2 are empty.
  • the intersection of the PUCCH sets corresponding to the dynamic signaling is non-empty, so that CORESET1 and CORESET2 can independently allocate resources in the PUCCH resource set, wherein one PUCCH resource includes a time domain resource, a frequency domain resource, and an air domain resource, wherein the downlink reference signal
  • the spatial domain resource is obtained by configuring the QCL reference signal of the downlink reference signal of the downlink reference signal by using the TCI-State
  • the spatial domain resource of the uplink reference signal is obtained by using the spatial filtering parameter indication information spatialRelationInfo of the reference signal, or the precoding indication information of the uplink reference signal.
  • the two PUCCH resources are different when any one or more of the time domain resources, the frequency domain resources, and the air domain resources corresponding to the two PUCCH resources are different.
  • PUCCH resource 1 corresponds to ⁇ time domain resource 1, frequency domain resource 1, and air domain resource 1 ⁇
  • PUCCH resource 2 corresponds to ⁇ time domain resource 1, frequency domain resource 1, and spatial domain resource 2 ⁇
  • PUCCH resource 1 and PUCCH resources are considered. 2 is two different resources. Therefore, it is ensured that there is no interaction between CORESET1 and CORESET2, and the PUCCH resources are independently scheduled. Otherwise, they may schedule the same PUCCH resource, so that two uplink control information needs to be simultaneously transmitted on the same PUCCH resource, and the one PUCCH resource is simultaneously transmitted. Only one uplink control information can be transmitted.
  • FIG. 10 is a schematic diagram of different TRPs corresponding to different PUCCH resource sets according to the present application.
  • FIG. 10 due to non-backhaul, if two TRP scheduled PUCCH resources are the same, strong interference between PUCCHs is caused.
  • the above four PUCCHs correspond to the PUCCH resource domain of the 2-bit notification in the DCI.
  • interference can be reduced.
  • a correspondence between the CORESET and the demodulation reference signal port set may be established, so that different TRPs are allowed to correspond to different DMRS port sets, and the PDCCH transmitted in the CORESET further indicates that the scheduled DMRS corresponding to the PDSCH/PUSCH is in the DMRS port set. Relative information.
  • the DMRS information includes at least one of the following: a demodulation reference signal pattern type dmrs-Type, a demodulation reference signal occupying a number of consecutive time domain symbol groups dmrs-AdditionalPosition, and a demodulation reference signal occupying a continuous time domain symbol group a maximum value maxLength of the number of time domain symbols included, a generation parameter for generating a demodulation reference signal sequence, a start time domain symbol position l 0 of the demodulation reference signal, and a continuous time domain symbol group possessed by the demodulation reference signal
  • the number of time domain symbols, whether the channel transform precoding sent by the one or more third communication nodes to the first communication node is enabled can be equivalent to whether SC-OFDM
  • CORESET1 corresponds to TCI state pool1
  • CORESET2 corresponds to TCI state pool2
  • one TCI state pool includes one or more TCI states
  • one TCI state includes one or more.
  • a set of QCL reference signals for indicating a set of QCL reference signals corresponding to one or more port groups a set of QCL reference signals of a port group indicating a port in the port group and a reference signal in the QCL reference signal set
  • a class of QCL parameters satisfy the QCL relationship.
  • the ports in a port group satisfy the QCL relationship.
  • the reference signals in different port groups do not satisfy the QCL relationship.
  • the port can demodulate the reference signal port or the measurement reference signal port.
  • the TCI state corresponding to the QCL reference signal set of the channel or signal corresponding to the CORESET1 is from the TCI state pool1, wherein the channel or signal corresponding to the CORESET1 includes the channel or signal scheduled by the PDCCH in the CORESET1, and/or includes high-level signaling scheduling.
  • Channel or signal, wherein the higher layer signaling corresponds to PDSCH scheduling by PDCCH in CORESET1.
  • the TCI state corresponding to the channel or signal QCL reference signal set corresponding to CORESET2 is taken from TCI state pool 2.
  • one or more sets of PDSCHs corresponding to the high-level configuration may be established, where the configuration information of the set of PDSCHs includes configuration information of multiple transmission parameters of the PDSCH.
  • PDSCH-config as described above; thus, it is possible to allow different TRPs to transmit different parameters to the PDSCH of the UE;
  • the correspondence between the CORESET and the transmission parameters of the uplink data channel can also be established; thereby allowing the configuration information of the uplink data channels sent to different TRPs to be different;
  • the correspondence between the CORESET and the rate matching information may be established, thereby allowing the rate matching information of different TRPs to be different, wherein the rate matching information may be rate matching information configured by RRC signaling, or may be MAC-CE notification. Rate matching information, or a rate matching information set corresponding to the rate matching information notified by the DCI.
  • the uplink measurement reference signal if two TRPs schedule the same SRS resource, especially when the beam terminal of the SRS resource decides itself, when the two TRPs schedule the same SRS resource, the terminal needs to adopt the same SRS resource differently. If the transmit beam is sent to TRP1 and TRP2, the uplink measurement will be inaccurate. On the other hand, if the two TRP scheduling CSI-RSs have the same time-frequency resources and the same receive beam resources, their transmit beams are actually different. One is TRP1.
  • the transmit beam one is the transmit beam of TRP2
  • the terminal actually measures the superimposed channel of the two transmit beams, but since there is no real-time interaction between TRP1 and TRP2, TRP does not know that it is a superposition effect of two, so it is better to be TRP1.
  • TRP2 respectively correspond to respective measurement reference signal pools, and two measurement reference signals in different measurement reference signal pools
  • the resources are preferably different.
  • the different resources of the two measurement reference signals indicate that at least one of the following resources corresponding to the two measurement reference signal resources is different: time domain resources, frequency domain resources, and air domain resources. Or only one TRP in the two TRPs controls the measurement reference signal, but the non-periodic measurement reference signal resource pool corresponding to each CORESET should be different.
  • CORESET and CBG can be established, thereby allowing different resource allocation granularities of different TRPs; of course, CORESET and time domain resource allocation parameters, and/or frequency domain resource allocation parameters, such as resource granularity, resource allocation, can also be established.
  • Mode the way in which physical resources are mapped to virtual resources.
  • the scrambling sequence can be a scrambling sequence of the data channel or a scrambling sequence of the control channel, thereby allowing data channels of different TRPs to be adopted.
  • Different scrambling sequences are used to reduce interference between the two, the scrambling sequence is to first scramble the bit information after channel coding of the data channel, and then perform modulation;
  • the association between the CORESET and the TA information can be established, so that the TA of the uplink channel/signal corresponding to the CORESET adopts the TA value of the CORESET, wherein the channel or signal corresponding to the CORESET indicates that the channel is scheduled.
  • the control signaling of the signal is included in a control channel included in the control channel resource or in a channel scheduled by the control channel included in the control channel resource.
  • the channel/signal is a channel/signal directly scheduled by the PDCCH included in the CORESET, or a high-level signaling scheduling of the channel/signal, such as a periodic or semi-periodic channel/signal, scheduling high-level signaling of the channel/signal.
  • the UE should have two downlink timings, which are respectively used to receive signals sent by TRP1 and TRP2.
  • the transmitted signal such that the TA of the uplink channel/signal corresponding to CORESET1 is the time difference between the start position of the time unit 1 corresponding to the uplink channel/signal and the start position of the time unit 2, the time unit 2 is In the downlink time unit, the time unit index corresponding to the time unit 1 and the time unit 2 is the same, and the start position of the time unit 2 is obtained according to the start position of the time unit used when the terminal receives the CORESET1.
  • the above is to establish a correspondence between the CORESET and the foregoing transmission parameter set, or a CORESET corresponding to a plurality of sets of configuration information of a transmission parameter set, and the DCI signaling indicates the one transmission parameter set of the channel/signal scheduled by the DCI signaling.
  • Which set of transmission parameters corresponds to For example, a CORESET corresponds to multiple sets of PDSCH high-level cooperation information, and then the higher-layer transmission parameters of the PDSCH scheduled by the DCI signaling are based on which set, or the DMRS index indicated in the DCI is relative index of the DMRS port in the set of DMRS ports.
  • the higher layer transmission parameter of the PUCCH scheduled by the DCI is which one of the multiple sets of PUCCH configuration information corresponding to the CORESET.
  • one TRP transmits two DCIs and the other transmits only PDSCH.
  • the two sets of transmission parameter sets corresponding to the CORESET correspond to the TRP1 transmission.
  • one control channel resource is a CORESET
  • one control channel resource in the text may also be one of the following; Search space, corresponding to a search space of a degree of aggregation, a set of high-level PDCCH resources, including only one DCI PDCCH, one candidate, and one CORESET scrambling sequence to generate parameters.
  • Search space corresponding to a search space of a degree of aggregation, a set of high-level PDCCH resources, including only one DCI PDCCH, one candidate, and one CORESET scrambling sequence to generate parameters.
  • an n RNTI and/or n ID in the formula (2) establishes a correspondence between the scrambling sequence generation parameter and one or more sets of configuration information of the above one transmission parameter set.
  • the foregoing is to establish a correspondence between one control channel resource and one or more sets of configuration information of a transmission parameter set, and may also establish a control channel resource group and one or more sets of configuration information of a transmission parameter set. Correspondence relationship.
  • FIG. 9 is a schematic diagram 1 of a terminal using multiple panels to send uplink signals to multiple TRPs according to the present application. As shown in FIG. 9, to different TRPs.
  • the uplink channel/signal sent should use a different TA value. At least one of the following options can be used for this:
  • Solution 1 The TA value corresponding to the channel/signal is established in the channel/signal configuration information, where the configuration information may be high layer configuration information or physical layer dynamic control information.
  • Scheme 2 Configuring TA information in a Sounding Reference Signal (SRS), the TA information of the PUSCH/PUCCH is obtained according to the SRS information, where the spatial filtering parameters of the PUSCH/PUCCH, and/or precoding parameters, and/or Or the power parameter is indicated by the SRS information.
  • SRS Sounding Reference Signal
  • the TA information is configured in the configuration information of a control channel resource, and the TA value of the uplink channel/signal corresponding to the control channel resource is obtained according to the TA information configured in the control channel resource, where one control channel resource corresponds to An uplink channel/signal indicating that control signaling for scheduling the uplink channel/signal is included in a control channel included in the control channel resource, and/or control signaling for scheduling the uplink channel/signal includes control included in the control channel resource Channel scheduling in the PDSCH.
  • the downlink synchronization adopts one set, that is, as shown in FIG. 7 to FIG. 8, the TA values of the signals transmitted by panel1 and panel2 are all for the time when the panel1 receives the downlink synchronization signal. Advance quantity.
  • a TA value corresponds (one downlink a channel/signal, an uplink channel/signal combination, wherein the TA is a time difference of a start position of a time unit 1 transmitting the uplink channel/signal relative to a start position of a time unit 2, wherein the time unit 1 is An uplink time unit, the time unit 2 is a downlink time unit, and the start position of the time unit 2 is based on a start position of a downlink time unit 3 where the downlink channel/signal corresponding to the TA is the terminal, the time unit 2 and time An integer number of time units are included between units 3.
  • the TRP2 does not send the synchronization signal
  • the downlink synchronization of the panel2 of the terminal UE is determined according to the synchronization signal sent by the TRP1, and the amount of TA when the UE sends the uplink signal to the TRP1 by the panel1 is TA1, and the uplink signal sent by the UE to the TRP2 by the panel2
  • the amount of TA is TA2.
  • panel1 receives the downlink signal sent by TRP1, where TRP1 sends the transmission delay received by panel1 to t1, and then sends uplink signals to TRP1 and TRP2 respectively.
  • the uplink transmission delay of the uplink signal sent by panel1 to TRP1 is t1
  • the uplink transmission delay of the uplink signal sent by panel2 to TRP1 is t2.
  • FIG. 7 is a schematic diagram of a same downlink timing when a terminal uses multiple panels to send uplink signals to multiple TRPs according to the present application, and FIG. 7 is a time unit boundary of an uplink signal sent by panel1 according to TRP1 received by panel1.
  • a downlink time unit boundary obtained by the downlink synchronization signal is obtained; and a schematic diagram of the UE receiving the synchronization signal according to the fourth embodiment of the present disclosure.
  • FIG. 8 is a second downlink timing diagram 2 when a terminal uses multiple panels to send uplink signals to multiple TRPs according to the present application.
  • FIG. 8 is a time unit boundary of an uplink signal sent by panel2 according to TRP1 received by panel1.
  • the downlink time unit boundary obtained by the downlink synchronization signal is obtained.
  • T1 is the downlink transmission delay.
  • the beams of the link are different, for example, some are direct path, and some are not direct paths);
  • the arrival time of panel2 except the uplink signal will be earlier or later than the frame timing of panel2.
  • the downlink frame timing of panel2 should be exactly based on the timing at which panel2 receives TRP2. Otherwise, the first time domain symbol transmitted by TRP2 is not the first time domain symbol.
  • TA2 t12+t2
  • the difference between t12 and t1 is because the beam of the synchronization signal sent by the receiving TRP1 of panel2 and the synchronization signal sent by the panel1 receiving TRP1 are received.
  • the beams are different.
  • the TRP2 can adjust the TA amount after receiving the uplink signal sent by the panel2, but the TA amount is only the uplink signal for the panel2, and it is necessary to further determine how the uplink signals of the panel2 and the panel1 are distinguished, for example, by different SRS resource groups, such as panel1.
  • panel2 respectively correspond to SRS resource group 1 and SRS resource group 2, or panel1 and panel2 respectively correspond to uplink signals scheduled by CORESET group 1, and uplink signals scheduled by CORESET group 2, in which the uplink signals are required to be grouped in the same serving cell, different groups Corresponding to different TA amounts;
  • the downlink frame timing of panel2 is based on the synchronization signal sent by panel1 receiving TRP1 (transmission delay is t1), or the synchronization signal sent by TRP1 is received by panel2 (transmission delay is t12), but
  • the downlink timing of the actual panel2 should be based on the synchronization signal sent by the panel2 receiving TRP2 (transmission delay is t3).
  • the difference ratio between t3 and t1/t12 is large, the first time domain symbol sent by TRP2 arrives at panel2. It is not the first time domain symbol. Further consideration is required.
  • the downstream frame timing of Panel2 allows TRP2 to send downlink signals and panel2 to adjust.
  • the advance amount definition for the TA amount should be per-panel level, that is, TA1 is the advance amount of the uplink signal of panel1 relative to the downlink frame timing of panel1, and TA2 is the advance amount of the uplink signal of panel2 relative to the downlink frame timing of panel2. .
  • the base station notifies the terminal, or is predefined:
  • the data of the TRP1 and the data of the TRP2 are independent, and each has its own process number.
  • different TRPs may correspond to different process ID sets, such as a TRP1 corresponding process.
  • the number set ⁇ 1, 2, 3, 4 ⁇ , TRP2 corresponds to the process number ⁇ 5, 6, 7, 8 ⁇ , of course, TRP2 can also be configured in the ideal Backhaul scenario, ⁇ 1, 2, 3, 4 ⁇ , the base station further
  • the number of bits of the process ID in the DCI is obtained according to the configured process number set in the dynamic process number of the process ID.
  • the process ID can be associated with the following information, including: establishing a relationship between the TCI state group or the TCI state and the process number set.
  • the process number is the first set ⁇ 1, 2 3, 4 ⁇
  • the process number is the second set ⁇ 5, 6, 7, 8 ⁇ .
  • the process ID indicated in the DCI is index information in the first process number set, where the first process number set is configured in the TCI state corresponding to the QCL reference signal set of the demodulation reference signal of the data channel, or the first process number.
  • the TCI state corresponding to the QCL reference signal set of the demodulation reference signal collected in the data channel belongs to the TCI state group.
  • At least one of the following information of a data channel may be configured: BWP set information, demodulation reference signal port set information, demodulation reference signal information, quasi-common reference signal set information, pre- Coding resource granularity PRB bundling size indication information, rate matching rate mating indication information, carrier carrier indicator indication information, measurement reference signal information, generation parameters of a scrambling sequence, port information of a control channel, time domain resource allocation parameter, frequency domain resource allocation Parameter, aperiodic measurement reference signal information.
  • the method according to the above embodiment can be implemented by means of software plus a necessary general hardware platform, and of course, by hardware, but in many cases, the former is A better implementation.
  • the technical solution of the present disclosure which is essential or contributes to the related art, may be embodied in the form of a software product stored in a storage medium (such as ROM/RAM, disk, CD-ROM).
  • the instructions include a number of instructions for causing a terminal device (which may be a cell phone, a computer, a server, or a network device, etc.) to perform the methods described in various embodiments of the present disclosure.
  • a device for transmitting configuration information is provided, which is used to implement the foregoing embodiments and preferred embodiments, and details are not described herein.
  • the term "module” may implement a combination of software and/or hardware of a predetermined function.
  • the apparatus described in the following embodiments is preferably implemented in software, hardware, or a combination of software and hardware, is also possible and contemplated.
  • a sending device for configuration information comprising:
  • a first sending module configured to send configuration information, where the configuration information configures N sets of data channel configuration information, and/or M sets of control channel configuration information for one frequency domain bandwidth;
  • N, M is an integer greater than or equal to 1.
  • the configuration information of a set of control channel resources may be one of the following configuration information: a set of PDCCH configuration information, a set of CORESET configuration information, a set of search space configuration information, and a set corresponding to a degree of aggregation.
  • Configuration information of the search space a set of PUCCH configuration information.
  • the above technical solution solves the problem that the related art lacks the data transmission between the multiple TRPs and the terminal, configures multiple sets of configuration information for one frequency domain bandwidth, and can use different configuration information in multiple TRP transmissions to implement multiple TRPs. Data transfer with the terminal.
  • the device further comprises at least one of the following:
  • the physical layer control signaling further indicates which set of configuration information is used by one set of transmission parameters used by the scheduled channel; the generating parameter of the scrambling sequence in this embodiment may be the virtual cell ID in the subsequent formula (2) ;
  • N1, N2, N3, N4, M1, M2, D1, D2, M3, C1 are positive integers greater than or equal to one.
  • the foregoing correspondence may be: which data channel is used for the configuration information of the control channel; or which uplink control channel is used for controlling the downlink control channel; or which set of control channel configuration information corresponds to which data channel configuration information.
  • the downlink BWP1 includes the configuration information of the M1 PDCCH
  • the downlink BWP2 includes the configuration information of the N1 set of the PDSCH
  • the PDSCH of the BWP2 that is scheduled to be in one PDCCH in the BWP1 is the N1 set of the PDSCH included in the BWP2.
  • the frequency domain bandwidth of the foregoing embodiment may include at least one of the following:
  • the first frequency domain bandwidth and the second frequency domain bandwidth are both downlink frequency domain bandwidths
  • the first frequency domain bandwidth is an uplink frequency domain bandwidth
  • the second frequency domain bandwidth is a downlink frequency domain bandwidth
  • the third frequency domain bandwidth is an uplink frequency domain bandwidth
  • the fourth frequency domain bandwidth is a downlink frequency domain bandwidth
  • the fifth frequency domain bandwidth and the sixth frequency domain bandwidth are both downlink frequency domain bandwidths
  • the fifth frequency domain bandwidth is an uplink frequency domain bandwidth
  • the sixth frequency domain bandwidth is a downlink frequency domain bandwidth
  • the device comprises at least one of the following:
  • the first control signaling in the second frequency domain bandwidth schedules the first data channel in the first frequency domain bandwidth, where the transmission parameter of the first control signaling is based on the M1 set included in the second frequency domain bandwidth Obtaining, in a set of configuration information of the control channel resource, the transmission parameter of the first data channel is obtained according to a set of data channel configuration information in a second frequency domain bandwidth corresponding to the set of control channel resource configuration information;
  • the second control signaling in the fourth frequency domain bandwidth schedules a third control channel in the third frequency domain bandwidth, where the transmission parameter of the second control signaling is based on the M2 set included in the fourth frequency domain bandwidth Obtaining, in a configuration of the control channel resource, the transmission parameter of the third control channel is obtained according to a set of control channel configuration information in a third frequency domain bandwidth corresponding to the set of control channel resource configuration information;
  • the third control signaling in the sixth frequency domain bandwidth schedules the second data channel in the fifth frequency domain bandwidth, where the transmission parameter of the third control signaling is based on one of the control channel configuration information in the sixth frequency domain bandwidth a set of control channel resource configuration information acquisition (may be one of the D1 sets of control channel resource configuration information included in the sixth frequency domain bandwidth previously described), and the transmission parameter of the second data channel is controlled according to the set Obtaining a set of data channel configuration information in a fifth frequency domain bandwidth in which the channel resource configuration information has a corresponding relationship;
  • the fourth control signaling in the eighth frequency domain bandwidth schedules the fourth control channel in the seventh frequency domain bandwidth, where the transmission parameter of the fourth control signaling is based on a control channel configuration information in the eighth frequency domain bandwidth a set of control channel resource configuration information acquisition (may be one of the D2 sets of control channel resource configuration information included in the eighth frequency domain bandwidth previously recorded), and the transmission parameter of the fourth control channel is based on the set of control A set of control channel configuration information is acquired in the seventh frequency domain bandwidth in which the channel resource configuration information has a corresponding relationship.
  • Sending a first control signaling where the first control signaling is used to configure or schedule one of the frequency domain bandwidths, where the first control signaling includes N5 sets of data channels included in the one frequency domain bandwidth a configuration information index information of the configuration information, where the transmission parameter of the data channel is obtained according to the data channel configuration information corresponding to the index information;
  • Sending a second control signaling where the second control signaling is used to configure or schedule one control channel in a frequency domain bandwidth, where the second control signaling includes N6 sets of control channels included in the one frequency domain bandwidth a configuration information index information of the configuration information, where the transmission parameter of the control channel is obtained according to the control channel resource configuration information corresponding to the index information;
  • Sending a third control signaling where the third control signaling is used to configure or schedule a measurement reference signal resource in a frequency domain bandwidth, where the third control signaling includes a C2 set measurement included in the one frequency domain bandwidth a configuration information index information of the reference signal configuration information, where the transmission parameter of the measurement reference signal resource is obtained according to the measurement reference signal configuration information corresponding to the index information;
  • N5, N6, and C2 are positive integers greater than or equal to 1.
  • the first control signaling is physical layer control signaling
  • the second control signaling is physical layer control signaling
  • the third control signaling is physical layer control signaling
  • an apparatus for determining an association comprising:
  • a first determining module configured to determine a correspondence between P control channel resources and Q sets of configuration information of a transmission parameter set
  • P is a positive integer greater than or equal to 1
  • Q is a positive integer less than or equal to P.
  • the solution of the related art lacks the connection of configuration information of multiple control channel resources and multiple sets of transmission parameters in the related art, and establishes a correspondence relationship between multiple control channel resources and configuration information of multiple sets of transmission parameters, and subsequently Data can be transferred based on this.
  • a set of transmission parameters may be: the parameter set includes multiple parameters, and different sets of configuration information corresponding to multiple sets of control channel resources have different values of the multiple parameters.
  • the apparatus further includes at least one of: a first control signaling scheduling channel or a signal, where the first The transmission parameter of the control signaling is determined according to a parameter of one of the P control channel resources, and the set of transmission parameters of the channel or the signal is set according to the Q set configuration information corresponding to the one control channel resource.
  • Configuration information is determined;
  • the one transmission parameter set is a transmission parameter set corresponding to a channel or a signal, where the control signaling for scheduling the channel or the signal is included in a control channel included in the P2 control channel resources, or included in the P2 control channel resources. In the channel scheduled by the control channel, wherein the P2 control channel resources belong to the P control channel resources.
  • the P control channel resources and/or the Q set configuration information of the one transmission parameter set meet at least one of the following characteristics:
  • the P control channel resources belong to the same frequency domain bandwidth
  • the Q channels or Q signals corresponding to the Q sets of configuration information of the one transmission parameter set belong to the same frequency domain bandwidth
  • the P control channel resources are control channel resources that the first communication node needs to detect (required that the P control channel resources are for one terminal);
  • the P control channel resources and the Q channels or Q signals corresponding to the Q set configuration information belong to the same frequency domain bandwidth;
  • the first communication node can simultaneously receive the Q-type channel and/or signal corresponding to the Q-set configuration information, where the first communication node is a node that receives the control channel resource;
  • the first communication node can simultaneously receive the P control channel resources, where the first communication node is a node that receives the control channel resource;
  • the first communication node cannot simultaneously receive different control channel resources in the P1 control channel resources, where the P1 control channel resources belong to the P control channel resources, and the same set of configuration information corresponding to one transmission parameter set, the first A communication node is a node that receives control channel resources;
  • the first communication node cannot simultaneously receive a plurality of control channel resources corresponding to the same set of configuration information of a transmission parameter set, wherein the first communication node is a node that receives the control channel resource;
  • the one transmission parameter set is a transmission parameter about the channel or the signal.
  • determining a correspondence between P control channel resources and Q sets of configuration information of a transmission parameter set includes at least one of the following:
  • the one transmission parameter set is a transmission parameter set corresponding to a channel or a signal, wherein the control signaling for scheduling the channel or the signal is included in a control channel included in one control channel resource, or includes a control channel scheduling included in a control channel resource.
  • the control signaling for scheduling the channel or the signal is included in a control channel included in one control channel resource, or includes a control channel scheduling included in a control channel resource.
  • the one transmission parameter set is a transmission parameter set corresponding to a channel or a signal, wherein the control signaling for scheduling the channel or the signal is included in a control channel included in the control channel resource group, or includes a control channel scheduling included in the control channel resource group.
  • the control signaling for scheduling the channel or the signal is included in a control channel included in the control channel resource group, or includes a control channel scheduling included in the control channel resource group.
  • the Q1, Q2 is an integer less than or equal to Q
  • the P1 is an integer less than or equal to P
  • the one frequency domain bandwidth is one CC or one bandwidth part BWP.
  • the correspondence between the P control channel resources and the Q set configuration information of the one transmission parameter set is indicated by one of the following manners:
  • the configuration information index information of the Q-set configuration information (that is, the configuration information index information including the Q-set configuration information in the control channel resource configuration information) is included in the configuration information of the control channel resource;
  • the control channel resource index information of the P control channel resources is included in the Q set configuration information of the one transmission parameter set.
  • the apparatus further includes at least one of the following:
  • the number of bits of the first control signaling is determined according to one set of the Q sets of configuration information
  • the number of bits of the predetermined bit field of the first control signaling is determined according to one set of the Q sets of configuration information
  • the transmission parameter of the control channel where the first control signaling is located is obtained according to a transmission parameter of one of the P control channel resources, and the correspondence between the set of configuration information and the one control channel resource exists. .
  • the first control channel resource in the optional embodiment may be any one of the P control channel resources or a specified one, and is not used to limit the order of P control channel resources.
  • the Nth information in the Nth resource is the same as the Nth resource.
  • the one transmission parameter set includes at least one of the following parameter information: process number set information, BWP set information, uplink control channel resource set information, demodulation reference signal port set information, demodulation reference signal information, and quasi-common reference Signal set information, Transmission configuration indication information (TCI) state pool indication information, indication information of downlink data channel, indication information of uplink data channel, indication information of uplink control channel, precoding resource granularity PRB bundling Size indication information, rate matching rate mating indication information, carrier carrier indicator indication information, measurement reference signal information, generation parameters of a scrambling sequence, TA information, port information of a control channel, time domain resource allocation parameter, frequency domain resource allocation parameter, The aperiodic measurement reference signal information; wherein one TCI state includes configuration information of a plurality of quasi-co-located reference signal sets of the acquirer.
  • TCI Transmission configuration indication information
  • control channel resource is a physical layer control channel resource; and/or configuration information of the one transmission parameter set is included in high layer signaling.
  • the device further includes:
  • determining a correspondence between the P control channel resources and the Q set configuration information of a transmission parameter set where: a control channel resource corresponds to a Q1 set configuration information of a transmission parameter set, where the Q1 is greater than Or an integer equal to 1.
  • the following information is indicated by the control signaling transmitted in the one control channel resource: determining the channel or signal scheduled by the control signaling according to the specified set in the Q1 set configuration information.
  • Transmission parameters (It should be noted that the first set in the optional embodiment may be any one of the Q sets of configuration information or a specified set, and is not used to limit the order of the Q sets of configuration information).
  • the P control channel resources include one of the following features:
  • the one control channel resource is a physical downlink control channel PDCCH control channel resource
  • the one control channel resource is a control resource set CORESET resource
  • the one control channel resource is a search space set Search space set resource
  • the one control channel resource is a degree of aggregation of the Search space resource
  • the one control channel resource is a candidate physical downlink control channel Candidate PDCCH resource
  • the scrambling sequence of the one control channel generates parameters.
  • a determining apparatus for time advance TA information including:
  • a second determining module configured to determine TA information according to the first signal and/or the second signal, where the first signal is a signal sent by the first communications node, and the second signal is a signal received by the first communications node ;
  • a third signal is transmitted according to the TA information.
  • the first signal may be a beam signal sent by the terminal.
  • the solution lacking the determined TA value in the related art is solved, and the TA value for transmitting the third signal is determined accurately according to the first signal and/or the second signal.
  • the second channel or the second signal is a channel or a signal received by the first communications node, and further satisfies at least one of the following features:
  • the second channel is a control channel, and the control channel includes a control signaling for scheduling the third channel or the third signal;
  • the second signal and the demodulation reference signal of the control signaling for scheduling the third channel or the third signal satisfy a quasi co-location QCL relationship with respect to at least one quasi co-location parameter, including: the second signal and The QCL relationship is satisfied with respect to delay spread and/or average delay between demodulation reference signals for scheduling control signaling of the third channel or the third signal.
  • the QCL relationship is satisfied at least with respect to the multipath TA and/or the average TA.
  • control signaling for scheduling the first channel and the third channel or the third signal belongs to one and the same control channel resource.
  • the first communications node acquires at least one of the following information of the third channel or the third signal according to the first signal: spatial filtering parameter information of the third channel or the third signal, the third channel or the Power parameter information of the three signals.
  • the TA information is a time difference between a start position of the first time unit and a start position of the second time unit, where the third channel or the third signal corresponds to the first time unit, the first The two channel or third signal corresponds to the second time unit.
  • the first time unit may be an uplink time unit
  • the second time unit may be a downlink time unit.
  • the device further comprises at least one of the following:
  • the first channel or the second channel or the third channel includes at least one of the following channels: a data channel, a control channel;
  • the first signal or the third signal includes at least one of the following: a demodulation reference signal, a measurement reference signal, and a random access signal;
  • the second signal includes at least one of the following: a demodulation reference signal, a measurement reference signal, a synchronization signal, and a measurement reference signal of a tracking reference signal TRS (tracking reference signal).
  • TRS tracking reference signal
  • an association relationship between the first channel or the first signal and the TA information an association relationship between the second channel or the second signal and the TA information; the first channel or the first signal, and The association between the second channel or the second signal and the TA information.
  • the association relationship between the setup signal and the TA information includes the at least one of: including the signal information in the configuration information of the TA information; and including the TA information in the configuration information of the signal; The information determines the TA information.
  • determining, by the first communications node, the TA information according to the second channel or the second signal determining, according to the scrambling code information corresponding to the second channel or the second signal, the TA information, according to the second channel or the second signal
  • the transmission parameter of the control channel resource is determined by the TA information, and the TA information is obtained according to the TA information included in the configuration information of the second channel.
  • a device for determining TA information including:
  • the second sending module is configured to send signaling information to the first communications node, where the signaling information includes at least one of the following associations:
  • the first signal is a signal sent by the first communication node
  • the second signal is a signal received by the first communication node
  • the establishing the relationship between the first signal and the TA information includes at least one of: including the first signal information in the configuration information of the TA information; and including the configuration information in the first signal TA information; determining the TA information according to the first signal information.
  • Other related relationships are the same.
  • the above technical solution solves the problem that the solution for determining the TA value of the signal sent by the terminal in the multi-TRP transmission scenario in the related art is solved, and the TA value may be determined according to the association relationship.
  • the TA information is a basis for the first communications node to send the third channel or the third signal, or the TA information is a basis for the first communications node to send the first channel or the second signal.
  • the apparatus further includes: the first channel or the second channel or the third channel includes at least one of: a data channel, a control channel; and the first signal or the third signal includes at least one of the following signals: Demodulating the reference signal, measuring the reference signal, and randomly accessing the signal; the second signal comprises at least one of the following: a demodulation reference signal, a measurement reference signal, and a synchronization signal as a measurement reference signal of the tracking reference signal TRS.
  • the signaling information includes one of the following signaling information: the signaling information is high layer signaling information; and the signaling information is physical layer signaling information.
  • a device for determining TA information including:
  • a first receiving module configured to receive configuration information of a third signal sent by the second communications node, where the configuration information includes TA information;
  • the third sending module is configured to send the third signal according to the TA information.
  • the above technical solution solves the problem that the terminal cannot determine the TA value of the uplink signal in the multi-TRP transmission scenario in the related art, and provides a scheme for the terminal to determine the TA value according to the configuration information.
  • receiving the configuration information of the third signal including at least one of: receiving high-level configuration information of the third signal, determining that the high-level configuration information of the third signal is configuration information of the third signal, and receiving for scheduling The physical layer control signaling of the third signal, where the physical layer control signaling includes configuration information of the third signal.
  • the TA information is jointly encoded with at least one of the following: a spatial filtering parameter of the third signal; a power parameter of the third signal.
  • each of the above modules may be implemented by software or hardware.
  • the foregoing may be implemented by, but not limited to, the foregoing modules are all located in the same processor; or, the above modules are in any combination.
  • the forms are located in different processors.
  • a storage medium having stored therein a computer program, wherein the computer program is configured to execute the method described in any of the above embodiments at runtime.
  • an electronic device comprising a memory and a processor, wherein the memory stores a computer program, the processor being configured to execute the computer program to execute The method described in any of the above embodiments.
  • Embodiments of the present disclosure also provide an electronic device including a memory and a processor having a computer program stored therein, the processor being configured to execute a computer program to perform the steps of any one of the method embodiments described above.
  • modules or steps of the present disclosure described above can be implemented by a general-purpose computing device that can be centralized on a single computing device or distributed across a network of multiple computing devices. Alternatively, they may be implemented by program code executable by the computing device such that they may be stored in the storage device by the computing device and, in some cases, may be different from the order herein.
  • the steps shown or described are performed, or they are separately fabricated into individual integrated circuit modules, or a plurality of modules or steps thereof are fabricated as a single integrated circuit module. As such, the disclosure is not limited to any specific combination of hardware and software.

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Abstract

本公开提供了一种配置信息的发送方法及装置,其中,该方法包括:发送配置信息,其中,该配置信息包括以下至少之一:为一个频域带宽配置N套数据信道配置信息;为一个频域带宽配置M套控制信道资源配置信息;为一个频域带宽配置C套测量参考信号配置信息;其中,该N,M,C是大于或者等于1的整数,采用上述技术方案,解决了相关技术中缺乏实现多TRP与终端之间的数据传输的问题,为一个频域带宽配置多套配置信息,可以在多TRP传输时使用不同配置信息,实现了多TRP与终端之间的数据传输。 (图1)

Description

配置信息的发送方法及装置 技术领域
本公开涉及通信领域,具体而言,涉及一种配置信息的发送方法及装置。
背景技术
相关技术中,在单TRP传输,或者单panel传输中,数据信道或者控制信道的高层配置信令只需要一套,当考虑多TRP传输,多panel传输时,且需要考虑各个TRP或者各个panel的传输参数不同时,需要灵活的信令配置方法,而且由于多个TRP或者多个panel的传输相对独立,如何避免他们调度的资源之间的碰撞和降低他们之间的干扰,是本文考虑的核心问题。
针对相关技术中缺乏实现多TRP与终端之间的数据传输的问题,目前还没有有效的解决方案。
发明内容
本公开实施例提供了一种配置信息的发送方法及装置,以至少解决相关技术中缺乏实现多TRP与终端之间的数据传输的问题。
根据本申请的一个实施例,提供了一种配置信息的发送方法,包括:发送配置信息,其中,所述配置信息包括以下至少之一:为一个频域带宽配置N套数据信道配置信息;为一个频域带宽配置M套控制信道资源配置信息;为一个频域带宽配置C套测量参考信号配置信息;其中,所述N,M,C是大于或者等于1的整数。
根据本申请的另一个实施例,还提供了一种对应关系的确定方法,包括:确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系;其中,所述P为大于或者等于1的正整数,所述Q为小于或者等于P的正整数。
根据本公开的另一个实施例,还提供了一种时间提前TA信息的确定方法,包括:第一通信节点根据以下信息至少之一确定TA信息:第一信道,第一信号,第二信道,第二信号;其中,所述第一信道或者第一信号是所述第一通信节点发送的信道或者信号,所述第二信道或者第二信号是所述第一通信节点接收的信道或者信号;根据所述TA信息发送第三信道或者第三信号。
根据本公开的另一个实施例,还提供了一种TA信息的确定方法,包括:第二通信节点发送信令信息至第一通信节点,所述信令信息中包括如下关联关系至少之一:第一信道或者第一信号和TA信息之间的关联关系;第二信道或者第二信号和所述TA信息之间的关联关系;所述第一信道或者第一信号,与所述第二信道或者第二信号的组合,和所述TA信息之间的关联关系;其中,所述第一信道或者第一信号是所述第一通信节点发送的信号,所述第二信道或者第二信号是所述第一通信节点接收的信号。
根据本申请的另一个实施例,还提供了一种配置信息的发送装置,所述装置包括:第一发送模块,设置为发送配置信息,其中,所述配置信息包括以下至少之一:为一个频域带宽配置N套数据信道配置信息;为一个频域带宽配置M套控制信道资源配置信息;为一个频域带宽配置C套测量参考信号配置信息;其中,所述N,M,C是大于或者等于1的整数。
根据本公开的另一个实施例,还提供了一种对应关系的确定装置,所述装置包括:第一确定模块,设置为确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系;其中,所述P为大于或者等于1的正整数,所述Q为小于或者等于P的正整数。
根据本公开的另一个实施例,还提供了一种时间提前TA信息的确定装置,包括:第二确定模块,设置为根据以下信息至少之一确定TA信息:第一信道,第一信号,第二信道,第一信号;其中,所述第一信道或者第一信号是所述第一通信节点发送的信道或者信号,所述第二信道或者第二信号是所述第一通信节点接收的信道或者信号;第二发送模块,设置为根据所述TA信息发送第三信道或者第三信号。
根据本公开的另一个实施例,还提供了一种TA信息的确定装置,包括:第二发送模块,设置为发送信令信息至第一通信节点,所述信令信息中包括如下关联关系至少之一:第一信道或者第一信号和TA信息之间的关联关系;第二信道或者第二信号和所述TA信息之间的关联关系;所述第一信道或者第一信号,与所述第二信道或者第二信号的组合,和所述TA信息之间的关联关系;其中,所述第一信道或者第一信号是所述第一通信节点发送的信号,所述第二信道或者第二信号是所述第一通信节点接收的信号。
根据本公开的又一个实施例,还提供了一种存储介质,所述存储介质中存储有计算机程序,其中,所述计算机程序被设置为运行时执行上述任一项方法实施例中的步骤。
根据本公开的又一个实施例,还提供了一种电子装置,包括存储器和处理器,所述存储器中存储有计算机程序,所述处理器被设置为运行所述计算机程序以执行上述任一项方法实施例中的步骤。
通过本公开,发送配置信息,其中,该配置信息包括以下至少之一:为一个频域带宽配置N套数据信道配置信息;为一个频域带宽配置M套控制信道资源配置信息;为一个频域带宽配置C套测量参考信号配置信息;其中,该N,M,C是大于或者等于1的整数,采用上述技术方案,解决了相关技术中缺乏实现多TRP与终端之间的数据传输的问题,为一个频域带宽配置多套配置信息,可以在多TRP传输时使用不同配置信息,实现了多TRP与终端之间的数据传输。
附图说明
图1是根据本公开实施例的配置信息的发送方法的流程图;
图2是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图一;
图3是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图二;
图4是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图三;
图5是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图四;
图6是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图五;
图7是根据本申请的一个终端采用多个panel给多个TRP发送上行信号时,采用一个相同的下行定时示意图一;
图8是根据本申请的一个终端采用多个panel给多个TRP发送上行信号时,采用一个相同的下行定时示意图二;
图9是根据本申请的一个终端采用多个panel给多个TRP发送上行信号的示意图一;
图10是根据本申请的不同TRP对应不同的PUCCH资源集合的示意图。
具体实施方式
下文中将参考附图并结合实施例来详细说明本公开。需要说明的是,在不冲突的情况下,本申请中的实施例及实施例中的特征可以相互组合。
需要说明的是,本公开的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别类似的对象,而不必用于描述特定的顺序或先后次序。
需要补充的是,本申请文件中的第一通信节点可以是终端,第二通信节点可以基站,但是,不局限于此。
本申请实施例中提供了一种移动通信网络(包括但不限于5G移动通信网络),该网络的网络架构可以包括网络侧设备(例如基站)和终端。在本实施例中提供了一种可运行于上述网络架构上的信息传输方法,需要说明的是,本申请实施例中提供的上述信息传输方法的运行环境并不限于上述网络架构。
实施例一
在本实施例中提供了一种运行于上述网络架构的配置信息的发送方法,图1是根据本公开实施例的配置信息的发送方法的流程图,如图1所示,该流程包括如下步骤:
步骤S102,确定配置信息,其中,该配置信息包括以下至少之一:为一个频域带宽配置N套数据信道配置信息;为一个频域带宽配置M套控制信道资源配置信息;为一个频域带宽配置C套测量参考信号配置信息;其中,该N,M,C是大于或者等于1的整数;
步骤S104,发送该配置信息。
需要补充的是,一套控制信道资源的配置信息,可以为如下配置信息之一:一套PDCCH的配置信息,一套CORESET的配置信息,一套Search space的配置信息,一套对应一个聚合度的Search space的配置信息,一套PUCCH的配置信息。
通过上述步骤,发送配置信息,其中,该配置信息包括以下至少之一:为一个频域带宽配置N套数据信道配置信息;为一个频域带宽配置M套控制信道资源配置信息;为一个频域带宽配置C套测量参考信号配置信息;其中,该N,M,C是大于或者等于1的整数,采用上述技术方案,解决了相关技术中缺乏实现多TRP与终端之间的数据传输的问题,为一个频域带宽配置多套配置信息,可以在多TRP传输时使用不同配置信息,实现了多TRP与终端之间的数据传输。
可选地,上述步骤的执行主体可以为基站、终端等,但不限于此。
可选地,步骤S102和步骤S104的执行顺序是可以互换的,即可以先执行步骤S104,然后再执行S102。
可选地,该一个频域带宽为一个带宽部分BWP,和/或,该一个频域带宽是一个专有频域带宽。
可选地,该方法还包括以下至少之一:
通过信令信息和/或约定方式,建立第一频域带宽包括的N1套数据信道配置信息和第二频域带宽包括的M1套控制信道资源的配置信息之间的对应关系;
通过信令信息和/或约定方式,建立第三频域带宽的N2套控制信道配置信息和第四频域带宽的M2套控制信道资源的配置信息之间的对应关系(可选地,第三频域带宽是上行控制信道的,第四频域带宽是下行控制信道的);
通过信令信息和/或约定方式,建立第五频域带宽包括的C1套参考信号配置信息和第六频域带宽包括的M3套控制信道资源的配置信息之间的对应关系;
通过信令信息和/或约定方式,建立第七频域带宽的N4套控制信道配置信息和第八频域带宽的一套控制信道配置信息中包括的D2套控制信道资源配置信息之间的对应关系;
在一套数据信道配置信息中包括该套数据信道对应的如下信息至少之一:进程号集合信息,TA信息;
在一套数据信道配置信息中包括该套数据信道的一个传输参数集合的多套配置信息,其中该一个传输参数集合包括如下参数至少之一:进程号集合信息,BWP集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,TCI state pool指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数;需要补充的是,可以在信道的高层信令中配置该一个传输参数集合的多套配置信息,在物理层控制信令中进一步指示调度的信道所用的一个传输参数集合对应的是哪一套配置信息;本实施例的中的加扰序列的产生参数可以是后续公式(2)中的n ID或者C-RNTI;
其中N1,N2,N3,N4,M1,M2,D1,D2,M3,C1是大于或者等于1的正整数。
需要补充的是,上述对应关系可以是,控制信道的配置信息用于调度哪个数据信道;或者下行控制信道用于控制哪个上行控制信道;或者哪套数据信道配置信息对应哪套控制信道的配置信息。举例说明,比如下行BWP1中包括M1套PDCCH的配置信息,下行BWP2中包括N1套PDSCH的配置信息,需要指示BWP1中的一个PDCCH中调度的BWP2中的一个PDSCH是BWP2中包括的N1套PDSCH中的哪一套。
可选地,上述实施例的频域带宽可以包括以下至少之一:
该第一频域带宽和该第二频域带宽都是下行频域带宽;
该第一频域带宽是一个上行频域带宽,该第二频域带宽是一个下行频域带宽;
该第三频域带宽是一个上行频域带宽,该第四频域带宽是一个下行频域带宽;
该第五频域带宽和该第六频域带宽都是下行频域带宽;
该第五频域带宽是一个上行频域带宽,该第六频域带宽是一个下行频域带宽。
可选地,该方法包括以下至少之一:
该第二频域带宽中的第一控制信令调度该第一频域带宽中的第一数据信道,其中,该第一控制信令的传输参数根据该第二频域带宽中包括的M1套控制信道资源的配置信息中的一套获取,该第一数据信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第二频域带宽中一套数据信道配置信息获取;
该第四频域带宽中的第二控制信令调度该第三频域带宽中的第三控制信道,其中,该第二控制信令的传输参数根据该第四频域带宽中包括的M2套控制信道资源的配置信息中的一套获取,该第三控制信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第三频域带宽中一套控制信道配置信息获取;
第六频域带宽中的第三控制信令调度该第五频域带宽中的第二数据信道,其中该第三控制信令的传输参数根据该第六频域带宽中一个控制信道配置信息中的一套控制信道资源配置信息获取(可以是之前记载的第六频域带宽中包括的D1套控制信道资源配置信息中的一套),该第二数据信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第五频域带宽中一套数据信道配置信息获取;
第八频域带宽中的第四控制信令调度该第七频域带宽中的第四控制信道,其中该第四控制信令的传输参数根据该第八频域带宽中一个控制信道配置信息中的一套控制信道资源配置信息获取(可以是之前记载的第八频域带宽中包括的D2套控制信道资源配置信息中的一套),该第四控制信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第七频域带宽中一套控制信道配置信息获取。
可选地,包括以下至少之一:
发送第一控制信令,其中,该第一控制信令用于配置或者调度一个频域带宽中的一个数据信道,该第一控制信令中包括该一个频域带宽中包括的N5套数据信道配置信息的配置信息索引信息,其中,该数据信道的传输参数根据该索引信息对应的数据信道配置信息获取;
发送第二控制信令,其中,该第二控制信令用于配置或者调度一个频域带宽中的一个控制信道,该第二控制信令中包括该一个频域带宽中包括的N6套控制信道配置信息的配置信息索引信息,其中,该控制信道的传输参数根据该索引信息对应的控制信道资源配置信息获取;
发送第三控制信令,其中,该第三控制信令用于配置或者调度一个频域带宽中的测量参考信号资源,该第三控制信令中包括该一个频域带宽中包括的C2套测量参考信号配置信息的配置信息索引信息,其中,该测量参考信号资源的传输参数根据该索引信息对应的测量参考信号配置信息获取;
其中,该N5,N6,C2是大于或者等于1的正整数。
可选地,该第一控制信令是物理层控制信令;该第二控制信令是物理层控制信令;该第三控制信令是物理层控制信令。
根据本公开的另一个实施例,还提供了一种对应关系的确定方法,该方法包括以下步骤:
步骤一,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系;其中,该P为大于或者等于1的正整数,该Q为小于或者等于P的正整数。
采用上述方案,解决了相关技术中缺乏多个控制信道资源和多套传输参数的配置信息的联系的方案,在多个控制信道资源和多套传输参数的配置信息之间建立了对应关系,后续可以依据此传输数据。
需要补充的是,终端侧和基站侧均可以执行上述步骤一的方案。一个传输参数集合可以是:该参数集合中包括多个参数,多套控制信道资源对应的不同套配置信息之间,具有该多个参数的不同取值。
可选地,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,该方法还包括以下至少之一:第一控制信令调度信道或者信号,其中,该第一控制信令的传输参数根据该P个控制信道资源中的一个控制信道资源的参数确定,该信道或者信号的传输参数集合根据与该一个控制信道资源存在对应关系的该Q套配置信息中一套配置信息确定;
该一个传输参数集合是信道或者信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在P2个控制信道资源包括的控制信道中,或者包括在该P2个控制信道资源包括的控制信道调度的信道中,其中该P2个控制信道资源属于该P个控制信道资源。
可选地,该P个控制信道资源和/或该一个传输参数集合的Q套配置信息,满足如下特征至少之一:
该P个控制信道资源属于一个相同的频域带宽;
该一个传输参数集合的Q套配置信息对应的Q个信道或者Q个信号属于一个相同的频域带宽;
该P个控制信道资源是一个第一通信节点需要检测的控制信道资源(需要补充的是,该P个控制信道资源是针对一个终端的);
该P个控制信道资源和该Q套配置信息对应的Q个信道或者Q个信号属于一个相同的频域带宽;
第一通信节点能同时接收该Q套配置信息对应的Q类信道和/或信号,其中,该第一通信节点为接收控制信道资源的节点;
第一通信节点能同时接收该P个控制信道资源,其中,该第一通信节点为接收控制信道资源的节点;
第一通信节点不能同时接收P1个控制信道资源中的不同控制信道资源,其中,该P1个控制信道资源属于该P个控制信道资源,且对应该一个传输参数集合的同一套配置信息,该第一通信节点为接收控制信道资源的节点;
第一通信节点不能同时接收对应该一个传输参数集合的同一套配置信息的多个控制信道资源,其中,该第一通信节点为接收控制信道资源的节点;
其中,该一个传输参数集合是关于该信道或者信号的传输参数。
可选地,该确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,包括以下至少之一:
在一个控制信道资源的配置信息中配置该一个控制信道资源对应的该一个传输参数集合的Q1套配置信息;
在该一个传输参数集合的一套配置信息中包括该套配置信息对应的P1个该控制信道资源;
确定一个控制信道资源和,信道或信号对应一个传输参数集合的Q1套配置信息之间的对应关系,其中,调度该信道或者信号的控制信令包括在该控制信道资源包括的控制信道中,或者包括在该控制信道资源包括的控制信道调度的信道中;
确定一个控制信道资源组,和信道或信号对应一个传输参数集合的Q2套配置信息之间的对应关系,其中,调度该信道或者信号的控制信令包括在该控制信道资源组包括的控制信道中,或者包括在该控制信道资源组包括的控制信道调度的信道中;
该一个传输参数集合是信道或信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在一个控制信道资源包括的控制信道中,或者包括在一个控制信道资源包括的控制信道调度的信道中;
该一个传输参数集合是信道或者信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在控制信道资源组包括的控制信道中,或者包括在控制信道资源组包括的控制信道调度的信道中;
确定X个频域带宽中每个频域带宽中的信道和/或信号对应的该一个传输参数集合的Q3套配置信息,确定一个控制信道资源和该Q3套配置信息的对应关系,其中,该X为大于或者等于1的正整数,该控制信道资源中包括的控制信息用于调度该X个频域带宽中的信道或信号;
其中,该Q1,Q2为小于或者等于Q的整数,该P1是小于或者等于P的整数,该一个频域带宽为一个成员载波(Component Carrier,简称为CC)或一个带宽部分(Band Width Part,简称为BWP)。
可选地,通过以下方式之一,指示该P个控制信道资源和该一个传输参数集合的Q套配置信息之间的对应关系:
在该控制信道资源的配置信息中包括该Q套配置信息的配置信息索引信息(即在该控制信道资源配置信息中包括Q套配置信息的配置信息索引信息);
在该一个传输参数集合的Q套配置信息中包括该P个控制信道资源的控制信道资源索引信息。
可选地,确定P个控制信道资源和该一个传输参数集合的Q套配置信息之间的对应关系,该还方法包括以下至少之一:
第一控制信令的比特数根据该Q套配置信息中的一套确定;
第一控制信令的预定比特域的比特数根据该Q套配置信息中的一套确定;
第一控制信令的通知该一个传输参数集合的传输参数的比特域的比特数,根据该Q套配置信息中的一套确定;
其中,该第一控制信令所在的控制信道的传输参数根据该P个控制信道资源中的一个控 制信道资源的传输参数获取,该一套配置信息和该一个控制信道资源之间存在该对应关系。
(需要说明的是,本可选实施例中的第一控制信道资源,可以是P个控制信道资源中的任意一套或指定一套,不用于限定P个控制信道资源的顺序,本申请文件中的第N信息,第N资源的限定同理)。
可选地,该一个传输参数集合包括如下参数信息至少之一:进程号集合信息,BWP集合信息,上行控制信道资源集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,传输配置指示信息(Transmission Configuration Indication,简称为TCI)state pool指示信息,下行数据信道的指示信息,上行数据信道的指示信息,上行控制信道的指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,测量参考信号信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数,非周期测量参考信号信息;其中一个TCI state中包括一个获者多个准共址参考信号集合的配置信息。
可选地,该控制信道资源是物理层控制信道资源;和/或,该一个传输参数集合的配置信息包括在高层信令中。
可选地,该确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,该方法还包括:
根据该一个传输参数集合的一套配置信息获取信道或者信号的第二传输参数,其中,该信道或者信号与该P个控制信道资源中的一个控制信道资源存在对应关系,该一套配置信息与该一个控制信道资源存在对应关系,该第二传输参数属于或者不属于该一个传输参数集合。
可选地,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,包括:一个控制信道资源对应该一个传输参数集合的Q1套配置信息,其中,该Q1为大于或者等于1的整数。
可选地,在该Q1大于1时,通过在该一个控制信道资源中传输的控制信令指示以下信息:根据该Q1套配置信息中的指定一套,确定该控制信令调度的信道或者信号的传输参数。(需要说明的是,本可选实施例中的第一套,可以是Q套配置信息中的任意一套或指定一套,不用于限定Q套配置信息的顺序)。
可选地,所述P个控制信道资源包括如下特征之一:
该一个控制信道资源为一个物理下行控制信道PDCCH控制信道资源;
该一个控制信道资源为一个控制资源集合CORESET资源;
该一个控制信道资源为一个搜索空间集合Search space set资源;
该一个控制信道资源为一个聚合度的Search space资源;
该一个控制信道资源为一个候选物理下行控制信道Candidate PDCCH资源;
该一个控制信道的加扰序列产生参数。
根据本公开的另一个实施例,还提供了一种时间提前TA信息的确定方法,该方法包括以下步骤:
步骤一,第一通信节点根据以下信息至少之一确定TA信息:第一信道,第一信号,第 二信道,第一信号;其中,该第一信道或者第一信号是该第一通信节点发送的信道或者信号,该第二信道或者第二信号是该第一通信节点接收的信道或者信号;
步骤二,根据该TA信息发送第三信道或者第三信号。
需要说明的是,第一信号可以是终端发送的波束信号。
采用上述方案,解决了相关技术中缺乏确定TA值的方案,实现了准确的依据第一信号和/或第二信号,确定发送第三信号的TA值。
可选地,该第二信道或者第二信号是该第一通信节点接收的信道或者信号,还满足以下特征至少之一:
该第二信道为控制信道,在该控制信道中包括调度该第三信道或者第三信号的控制信令;
该第二信号和调度该第三信道或者第三信号的控制信令的解调参考信号之间至少关于一个准共址参数满足准共址(quasi-co-location,简称为QCL)关系;
依据该第二信号的空间滤波参数获取该第三信道或者第三信号的空间滤波参数。
可选地,该第二信号和调度该第三信道或者第三信号的控制信令的解调参考信号之间至少关于一个准共址参数满足准共址QCL关系,包括:该第二信号和调度该第三信道或者第三信号的控制信令的解调参考信号之间,关于延迟扩展(delay spread)和/或平均延迟((average delay))满足QCL关系。
需要补充的是,第二信号和解调参考信号之间,至少关于多径TA和/或平均TA满足QCL关系。
可选地,调度该第一信道和第三信道或者第三信号的控制信令属于一个相同的控制信道资源。
可选地,该第一通信节点根据该第一信号获取该第三信道或者第三信号的如下信息至少之一:该第三信道或者第三信号的空间滤波参数信息,该第三信道或者第三信号的功率参数信息。
可选地,该TA信息是,第一时间单元起始位置相对于第二时间单元的起始位置之间的时间差,其中,该第三信道或者第三信号对应该第一时间单元,该第二信道或者第三信号对应该第二时间单元。需要补充的是,第一时间单元可以是上行时间单元,第二时间单元可以是下行时间单元。
可选地,该方法还包括以下至少之一:
该第一信道或者第二信道或者该第三信道包括如下信道至少之一:数据信道,控制信道;
该第一信号或者该第三信号包括如下信号至少之一:解调参考信号,测量参考信号,随机接入信号;
该第二信号包括如下信号至少之一:解调参考信号,测量参考信号,同步信号,跟踪参考信号TRS(tracking reference signal)的测量参考信号。
可选地,该第一信道或者第一信号和该TA信息之间的关联关系;该第二信道或者第二信号和该TA信息之间的关联关系;该第一信道或者第一信号,与该第二信道或者第二信号的组合,和该TA信息之间的关联关系。
需要补充的是,建立信号和该TA信息之间的关联关系包括该至少之一:在该TA信息的配置信息中包括该信号信息;在该信号的配置信息中包括该TA信息;根据该信号信息确定该TA信息。
可选地,第一通信节点根据第二信道或者第二信号确定该TA信息包括:根据该第二信道或者第二信号对应的扰码信息确定该TA信息;根据该第二信道或者第二信号所在的控制信道资源的传输参数确定该TA信息;根据该第二信道的配置信息中包括的该TA信息获取该TA信息。
根据本公开的另一个实施例,还提供了一种TA信息的确定方法,该方法包括以下步骤:
步骤一,第二通信节点发送信令信息至第一通信节点,该信令信息中包括如下关联关系至少之一:
第一信道或者第一信号和TA信息之间的关联关系;
第二信道或者第二信号和该TA信息之间的关联关系;
该第一信道或者第一信号,与该第二信道或者第二信号的组合,和该TA信息之间的关联关系;
其中,该第一信道或者第一信号是该第一通信节点发送的信号,该第二信道或者第二信号是该第一通信节点接收的信号。
需要补充的是,建立第一信号和该TA信息之间的关联关系包括以下至少之一:在该TA信息的配置信息中包括该第一信号信息;在该第一信号的配置信息中包括该TA信息;根据该第一信号信息确定该TA信息。其他关联关系同理。
采用上述技术方案,解决了相关技术中多TRP传输场景下,缺乏确定终端发送信号的TA值的方案的问题,后续可以依据关联关系确定TA值。
可选地,该TA信息是该第一通信节点发送第三信道或者第三信号的依据,或者该TA信息是该第一通信节点发送该第一信道或者第二信号的依据。
可选地,该方法还包括:该第一信道或者第二信道或者该第三信道包括如下信道至少之一:数据信道,控制信道;该第一信号或者第三信号包括如下信号至少之一:解调参考信号,测量参考信号,随机接入信号;该第二信号包括如下信号至少之一:解调参考信号,测量参考信号,同步信号,作为跟踪参考信号TRS的测量参考信号。
可选地,该信令信息包括如下信令信息之一:该信令信息为高层信令信息;该信令信息为物理层信令信息。
根据本公开的另一个实施例,还提供一种TA信息的确定方法,该包括以下步骤:
步骤一,第一通信节点接收第二通信节点发送的第三信号的配置信息,其中,该配置信息中包括TA信息;
步骤二,该第一通信节点根据该TA信息发送该第三信号。
采用上述技术方案,解决了相关技术中在多TRP传输场景下,终端无法确定发送上行信号的TA值的问题,给出了终端依据配置信息确定TA值的方案。
可选地,接收第三信号的配置信息,包括以下至少之一:接收该第三信号的高层配置信 息,确定该第三信号的高层配置信息为该第三信号的配置信息;接收用于调度该第三信号的物理层控制信令,其中,该物理层控制信令中包括第三信号的配置信息。
可选地,该第三信号的配置信息中,该TA信息和如下信息至少之一之间联合编码:该第三信号的空间滤波参数;该第三信号的功率参数。
下面结合本公开具体实施例进行说明。
具体实施例1:
多TRP传输是,一个BWP下终端可以同时接收多于一个的PDSCH,或者一个PDSCH的DMRS组数大于1,其中一个DMRS组中的解调参考信号端口之间不同解调参考信号端口之间至少关于一类准共址参数满足QCL关系,不同DMRS组中的不同DMRS不满足QCL关系。
具体地,以两个TRP为例,讲述多TRP传输,具体场景罗列在表1中,表1是根据本申请的多TRP下的传输场景的示意表格:
表1:
Figure PCTCN2019082912-appb-000001
图2是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图一;图3是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图二;图4是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图三;图5是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图四,图6是根据本公开一个终端接收多TRP发送的PDSCH的传输场景示意图五。如图2~图5中,DCI1调度PDSCH1,DCI2调度PDSCH2。
在图2中,TRP1和TRP2之间没有理想Backhaul,他们各自独立调度一个终端,当考虑TRP1和TRP2的设置不同时,或者考虑他们各自服务的UE群不同,一个终端可以在相同时间单元中的一个BWP中同时接收PDSCH1和PDSCH2,PDSCH1通过TRP1传输,PDSCH2通过TRP2传输,PDSCH1和PDSCH2对应的高层配置信息可以不同。从而在一个BWP中可以包括多个PDSCH,多个PDCCH的配置,进一步配置该BWP中包括的多个PDSCH和多 个PDCCH之间的关系,从而当DCI中调度一个PDSCH时,该PDSCH的高层参数通过与该DCI所在的PDCCH对应的PDSCH的配置信息获取。
比如进行如下配置:
Figure PCTCN2019082912-appb-000002
PDCCH的配置信息配置该PDCCH中包括的CORESET,Searchspace等信息,PDSCH的配置信息中进一步配置如下信息:加扰信息,解调参考信号信息,TCI state pool,资源分配信息,速率匹配信息,MCS参照的表格信息,预编码资源组信息,速率匹配信息等,如一套PDSCH的配置信息中配置可以对应3Gpp标准版本的38.331.V15.0.0中的配置在中的一个PDSCH-Config:一套PDCCH的配置信息中配置可以对应3Gpp标准版本的38.331.V15.0.0中的配置在中的一个PDCCH-Config。
上述方式中,是不同的TRP对应不同的(PDCCH,PDSCH)组合,本实施例也不排除,一个BWP中包括多个PDSCH,一个PDCCH,然后建立所述一个PDCCH中包括的多个CORESET和多个PDSCH之间的对应关系,例如如下配置形式:
Figure PCTCN2019082912-appb-000003
PDCCH中包括多个CORESET,然后建立多个CORESET和多个PDSCH配置信息之的对应关系,DCI调度一个PDSCH,根据该DCI所在的CORESET/Search space对应的PDSCH的高层配置信息索引,该PDSCH的高层配置参数根据该配置信息索引信息对应的PDSCH高层配置信息获取。具体地,比如PDCCH包括CORESET1和CORESET2,CORESET1和pdsch-Config1对应,CORESET2和pdsch-Config2对应,则CORESET1中传输的DCI调度的PDSCH的高层参数根据pdsch-Config1获取,则CORESET2中传输的DCI调度的PDSCH的高层参数根据pdsch-Config2获取。
或者建立一个BWP包括的N套PDSCH套配置信息和一个CORESET的多个加扰序列产生参数之间的关联,比如一个CORESET对应两个加扰序列产生参数C-RNTI{C-RNTI1,C-RNTI2},建立C-RNTI1和PDSCH1之间存在对应关系,C-RNTI2和PDSCH2之间存在对应关系。则根据C-RNTI1成功解码的DCI调度的PDSCH的高层参数根据pdsch-Config1获取,根据C-RNTI2成功解码的DCI调度的PDSCH的高层参数根据pdsch-Config2获取。上面是一个CORESET对应两个C-RNTI,本实施例中,一个CORESET只关联一个C-RNTI,但是关联多个虚拟小区号n ID,比如建立两个
Figure PCTCN2019082912-appb-000004
和pdsch-Config1对应,
Figure PCTCN2019082912-appb-000005
和pdsch-Config2对应,则根据
Figure PCTCN2019082912-appb-000006
成功解码的DCI调度的PDSCH的高层参数根据 pdsch-Config1获取,根据
Figure PCTCN2019082912-appb-000007
成功解码的DCI调度的PDSCH的高层参数根据pdsch-Config2获取。
其中PDCCH信道编码后的信息序列b(i)用c(i)序列加扰,如公式(1)所述,其中c(i)是一个随机序列的第i个值,这个随机序列的初始化值根据公式(2)获取
Figure PCTCN2019082912-appb-000008
其中n RNTI在专有控制信道的时候根据上述C-RNTI确定,n ID可以小区ID。
上述是建立多个下行控制信道资源和多个PDSCH之间的对应关系,类似地可以建立多个下行控制信道资源和多个PUSCH之间的对应关系,或者建立多个下行控制信道资源和PUCCH之间的对应关系。其中一个控制信道资源可以为如下之一:一个PDCCH配置信息对应的PDCCH,一个CORESET,一个Search space,一个聚合度对应的Search space,DCI的加扰序列对应的参数。
上述实施方式中,是一个BWP中包括多个PDSCH的配置,本实施例的另一种配置信息中,是一个BWP还是包括一个PDSCH,而PDSCH的属于一个传输参数集合的高层参数配置多套,然后在调度PDSCH的DCI中进一步指示调度的PDSCH对应的高层参数,是PDSCH高层配置参数中配置的属于一个传输参数集合的高层参数配置多套中的哪一套。
类似地,可以建立一个BWP中的多个控制信道资源和一个上行BWP中包括的多套上行控制信道配置之间的对应关系;和/或建立一个BWP中的多个控制信道资源和一个上行BWP中包括的多套上行控制信道配置之间的对应关系。其中一套PUSCH的配置信息中配置可以对应3Gpp标准版本的38.331.V15.0.0中的配置在中的一个PUSCH-Config,一套PUCCH的配置信息中配置可以对应3Gpp标准版本的38.331.V15.0.0中的配置在中的一个PUCCH-Config。
具体实施例2:
在本实施例中,需要确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,所述传输参数是所述控制信道资源调度的信道或信号的传输参数.即需要确定一个控制信道资源对应的所述一个传输参数集合的配置信息.
比如图2中的两个TRP传输,两个TRP之间没有理想Backhaul,TRP1和TRP2独立调度UE,从而增加频谱效率,TRP1和TRP2在相同的BWP中调度UE,虽然认为他们之间的波束隔离度比较好,但是还是要保证参考信号,或者控制信道之间的鲁棒性。和/或TRP1和TRP2下服务的用户的业务繁忙,时延要求不同,需要考虑允许他们各自调度的信道/信号的配置可以不同,从而对于UE来说,一个BWP下的一个传输参数可以对应多套配置。
其中所述一个传输参数集合中的传输参数包括如下传输参数至少之一:进程号集合信息,上行控制信道资源集合信息,解调参考信号端口集合,解调参考信号信息,准共参考信号集合信息,TCI state pool信息,下行数据信道的传输参数信息,上行数据信道的传输参数,上行控制信道信息,PRB Bundling size(预编码资源组大小),速率匹配信息,测量参考信号信 息,码块组(Code Block Group,简称为CBG)信息,加扰序列的产生参数信息,TA信息。
比如CORESET1是TRP1发送,CORESET1中传输的PDCCH调度TRP1发送给UE的下行信道/信号,或者UE发给TRP1的上行信道/信号,CORESET2是TRP2发送,CORESET2中传输的PDCCH调度TRP2发送给UE的下行信道/信号,或者UE发给TRP2的上行信道/信号。
由于TRP1和TRP2可以在相同的BWP中调度PDSCH/CSI-RS/CORESET/PUCCH/PUSCH/SRS/SR等,为了保证信号的准确性,需要确定CORESET1调度的信道的进程号集合,从而可以出现TRP1和TRP2中传输的PDSCH/PUSCH之间不要混淆,因为TRP1和TRP2各自独立传输信道而且他们之间没有理想Backhaul不能实时通信。比如CORESET1中配置进程号集合为{0,1,2,3},CORESET1中包括的PDCCH中指示的PDSCH/PUSCH的进程号是进程号集合{0,1,2,3}中的相对索引,CORESET2中配置进程号集合为{4,5,6,7},CORESET2中包括的PDCCH中指示的PDSCH/PUSCH的进程号是进程号集合{4,5,6,7}中的相对索引,比如PDCCH中指示进程号相对索引为0,则PDSCH/PUSCH对应的进程号为4。如果不进行进程号集合和控制信道资源的对应,则CORESET1也会调度进程号0,CORESET2也会调度进程号0,终端就会认为是相同的进程数据,从而进行合并,其实他们是不同TRP发送的不同数据,不能合并。
类似地,可以建立CORESET和上行控制信道资源集合之间的关联,比如CORESET1对应PUCCH资源集合1,CORESET2对应PUCCH资源集合2,PUCCH资源集合1和PUCCH资源集合2中包括的资源交集为空,尤其是动态信令对应的PUCCH集合的交集非空,从而能够让CORESET1和CORESET2独立各自调度PUCCH资源集合中的资源,其中一个PUCCH资源包括时域资源,频域资源,空域资源,其中下行参考信号的空域资源通过TCI-State配置下行参考信号的关于Spatial Rx Parameter的QCL参考信号得到,上行参考信号的空域资源通过该参考信号的空间滤波参数指示信息spatialRelationInfo获取,或者该上行参考信号的预编码指示信息获取。两个PUCCH资源对应的时域资源,频域资源,空域资源中的任意一个或者多个不同,则这两个PUCCH资源就不同。
比如PUCCH资源1对应{时域资源1,频域资源1,空域资源1},PUCCH资源2对应{时域资源1,频域资源1,空域资源2}},则认为PUCCH资源1和PUCCH资源2是两个不同的资源。从而才能保证CORESET1和CORESET2之间不需要交互,各自独立调度PUCCH资源,否则,他们可能调度同一个PUCCH资源,这样在同一个PUCCH资源上需要同时传输两份上行控制信息,而所述一个PUCCH资源上只能传输一份上行控制信息。
图10是根据本申请的不同TRP对应不同的PUCCH资源集合的示意图,如图10所示,由于non-backhaul,如果两个TRP调度的PUCCH资源相同,就会导致PUCCH之间的强干扰。上述四个PUCCH对应DCI中的2比特通知的PUCCH资源域。当保证这两个PUCCH资源集合不同时,即可以使得干扰降低。
类似地,可以建立CORESET和解调参考信号端口集合的对应关系,从而允许不同的TRP对应不同的DMRS端口集合,CORESET中传输的PDCCH进一步指示调度的 PDSCH/PUSCH对应的DMRS在所述DMRS端口集合中相对信息。
类似地,可以建立CORESET和解调参考信号信息之间的对应关系,从而允许不同的TRP对应的DMRS配置不同,或者保证不同TRP对应的DMRS信息相同。其中DMRS信息包括如下信息至少之一:解调参考信号图样类型dmrs-Type、解调参考信号占有连续时域符号组的个数dmrs-AdditionalPosition、解调参考信号占有的一个连续时域符号组中包括的时域符号个数的最大值maxLength、产生解调参考信号序列的产生参数、解调参考信号的起始时域符号位置l 0、解调参考信号占有的一个连续时域符号组中包括的时域符号个数、所述一个或者多个第三通信节点向所述第一通信节点发送的信道transform precoding是否使能(可以相当于SC-OFDM是否使能)、解调参考信号端口信息、解调参考信号所在的频域组、解调参考信号和解调参考信号对应的信道之间的功率差。
类似地,可以建立CORESET和TCI state pool之间的关联,比如CORESET1对应TCI state pool1,CORESET2对应TCI state pool2,其中一个TCI state pool中包括一个或者多个TCI state,一个TCI state中包括一个或者多个QCL参考信号集合,用于指示一个或者多个端口组对应的QCL参考信号集合,一个端口组的QCL参考信号集合表示所述端口组中的端口和所述QCL参考信号集合中的参考信号关于一类QCL参数满足QCL关系。一个端口组中的端口满足QCL关系,不同端口组中的参考信号不满足QCL关系,所述端口可以解调参考信号端口,也可以是测量参考信号端口。所述CORESET1对应的信道或者信号的QCL参考信号集合对应的TCI state都来自于TCI state pool1,其中CORESET1对应的信道或者信号包括CORESET1中的PDCCH调度的信道或者信号,和/或包括高层信令调度的信道或者信号,其中所述高层信令对应PDSCH通过CORESET1中的PDCCH调度。CORESET2对应的信道或者信号的QCL参考信号集合对应的TCI state都取自于TCI state pool2。
类似地,可以建立CORESET和高层配置的一套或者多套PDSCH对应,其中所述一套PDSCH的配置信息中包括PDSCH的多个传输参数的配置信息。如上所述的PDSCH-config;从而可以允许不同TRP发给UE的PDSCH的传输参数不同;
类似地,还可以建立CORESET和上行数据信道的传输参数之间的对应关系;从而允许发给不同TRP的上行数据信道的配置信息不同;
类似地,可以建立CORESET和速率匹配信息之间的对应关系,从而允许不同的TRP的速率匹配信息不同,其中速率匹配信息可以是RRC信令配置的速率匹配信息,也可以是MAC-CE通知的速率匹配信息,或者是DCI通知的速率匹配信息对应的速率匹配信息集合。
类似地,可以建立CORESET和测量参考信号之间的对应关系,从而允许不同的TRP从不同的测量参考信号资源池中调度测量参考信号,而且能保证两个TRP调度的测量参考信号之间没有冲突,特别是上行测量参考信号,如果两个TRP调度了相同的SRS资源,特别是SRS资源的波束终端自己决定时,当两个TRP调度了相同的SRS资源,终端需要采用相同的SRS资源不同的发送波束给TRP1和TRP2发送,会导致上行测量不准,另一方面如果两个TRP调度CSI-RS占有的时频资源相同,接收波束资源也相同,但是他们的发送波束实际不同,一个是TRP1的发送波束,一个是TRP2的发送波束,终端实际测得是两个发送 波束的叠加信道,但是由于TRP1和TRP2之间没有实时交互,TRP不知道是两个的叠加效果,所以最好是TRP1和TRP2各自对应各自的测量参考信号池,不同测量参考信号池中两个测量参考信号资源最好不同,两个测量参考信号的资源不同表示这两个测量参考信号资源对应的如下资源中的至少一个资源不同:时域资源,频域资源,空域资源。或者两个TRP中只有一个TRP控制测量参考信号,但是各个CORESET对应的非周期测量参考信号资源池应该不同。
类似地,可以建立CORESET和CBG之间的关联,从而允许不同TRP的资源分配粒度不同;当然也可以建立CORESET和时域资源分配参数,和/或频域资源分配参数,比如资源粒度,资源分配方式,物理资源到虚拟资源的映射方式。
类似地,可以建立CORESET和加扰序列的产生参数信息之间的关联,其中加扰序列可以是数据信道的加扰序列,也可以是控制信道的加扰序列,从而允许不同TRP的数据信道采用不同的加扰序列,降低两者之间的干扰,所述加扰序列是对数据信道信道编码后的比特信息先进行加扰,然后再进行调制;
类似地,可以建立CORESET和TA信息之间的关联关系,从而这个CORESET对应的上行信道/信号的TA就采用这个CORESET的TA值,其中所述一个CORESET对应的信道或者信号,表示调度所述信道或者信号的控制信令包括在所述控制信道资源包括的控制信道中,或者包括在所述控制信道资源包括的控制信道调度的信道中。比如这个信道/信号是这个CORESET中包括的PDCCH直接调度的信道/信号,或者这个信道/信号的高层信令调度的,比如是周期或者半周期信道/信号,调度这个信道/信号的高层信令包括在这个CORESET包括的PDCCH调度的PDSCH中。从而就允许这个发送到不同TRP的所用的TA不同。可选地,由于不同TRP和UE之间的传输时延不同,而TRP1和TRP2对应的下行slot边界应该是对齐的,UE端应该存在两个下行定时,分别用于接收TRP1发送的信号和TRP2发送的信号,从而CORESET1对应的上行信道/信号的TA是发送上述上行信道/信号对应的时间单元1的起始位置相对于时间单元2的起始位置之间的时间差,所述时间单元2是下行时间单元,时间单元1和时间单元2对应的时间单元索引相同,时间单元2的起始位置根据终端接收CORESET1时所采用的时间单元的起始位置获取。
上述是建立CORESET和上述传输参数集合之间的对应关系,也可以一个CORESET对应一个传输参数集合的多套配置信息,通过DCI信令指示DCI信令调度的信道/信号的所述一个传输参数集合中的传输参数对应的是哪一套。比如一个CORESET对应多套PDSCH高层配合信息,然后通过DCI信令调度的PDSCH的高层传输参数基于哪一套,或者DCI中指示的DMRS索引是相对哪一套DMRS端口集合中DMRS端口的相对索引,或者DCI调度的PUCCH的高层传输参数是CORESET对应的多套PUCCH配置信息中的哪一套。如图3所示,一个TRP传输两个DCI,另一个只传输PDSCH.假设所述DCI1和DCI2在相同的CORESET中传输,则这个CORESET对应的一个传输参数集合的两套配置,分别对应TRP1传输的信道或者信号,TRP2传输的信道或者信号,DCI中具体指示该DCI调度的PDSCH/PUSCH使用其他的哪一套。
上述建立一个控制信道资源和一个传输参数集合的一套或者多套配置信息之间的对应关系,其中一个控制信道资源为一个CORESET,本文中所述一个控制信道资源还可以是如下之一;一个Search space,对应一个聚合度的Search space,一套高层配置的PDCCH资源,只包括一个DCI的PDCCH,一个candidate,一个CORESET的一个加扰序列产生参数。比如一个公式(2)中的n RNTI和/或n ID,建立加扰序列产生参数和上述一个传输参数集合的一套或者多套配置信息之间的对应关系。
上述是建立一个控制信道资源和一个传输参数集合的一套或者多套配置信息之间的对应关系,也可以建立一个控制信道资源组和一个传输参数集合的一套或者多套配置信息之间的对应关系。
具体实施例3
在本实施例中,终端采用多个panel和多个TRP通信,图9是根据本申请的一个终端采用多个panel给多个TRP发送上行信号的示意图一,如图9所示,向不同TRP发送的上行信道/信号应该采用不同的TA值。对此可以采用如下方案至少之一:
方案1:在信道/信号的配置信息中建立该信道/信号对应的TA值,其中所述配置信息可以是高层配置信息,也可以是物理层动态控制信息。
方案2:在上行测量参考信号SRS(Sounding reference signal)中配置TA信息,PUSCH/PUCCH的TA信息根据SRS信息获取,其中所述PUSCH/PUCCH的空间滤波参数,和/或预编码参数,和/或功率参数通过所述SRS信息指示。
方案3:在一个控制信道资源的配置信息中配置TA信息,则这个控制信道资源对应的上行信道/信号的TA值根据所述控制信道资源中配置的TA信息得到,其中一个控制信道资源对应的上行信道/信号,表示调度这个上行信道/信号的控制信令包括在这个控制信道资源包括的控制信道中,和/或调度这个上行信道/信号的控制信令包括在这个控制信道资源包括的控制信道调度的PDSCH中。
上述方案中,只是告知一个上行信道/信号的TA值,下行同步采用一套,即如图7~图8所示,panel1和panel2发送的信号的TA值都是针对panel1接收下行同步信号的时间提前量。更准确地来说,由于不同TRP的下行信号到UE的下行定时也不同,所以告知一个TA值时,应该进一步告知这个TA值是相对哪个下行信号的TA值,即一个TA值对应(一个下行信道/信号,一个上行信道/信号)组合,其中所述TA是发送所述上行信道/信号的时间单元1的起始位置相对时间单元2的起始位置的时间差,其中所述时间单元1是上行时间单元,所述时间单元2是下行时间单元,时间单元2的起始位置根据终端所述TA对应的下行信道/信号所在的下行时间单元3的起始位置,所述时间单元2和时间单元3之间包括整数个时间单元。
具体地,比如TRP2不发送同步信号,终端UE的panel2的下行同步根据TRP1发送的同步信号而确定,UE用panel1给TRP1发送上行信号时的TA量为TA1,UE用panel2给TRP2发送的上行信号时的TA量为TA2,如图7~图8所示,panel1接收TRP1发送的下行 信号,其中TRP1发送panel1接收的传输时延为t1,然后各自给TRP1和TRP2发送上行信号,由于上行传输时延不同,panel1发送的上行信号到TRP1的上行传输时延是t1,panel2发送的上行信号到TRP1的上行传输时延是t2。
图7是根据本申请的一个终端采用多个panel给多个TRP发送上行信号时,采用一个相同的下行定时示意图一,图7是panel1发送的上行信号的时间单元边界根据panel1接收的TRP1发送的下行同步信号得到的下行时间单元边界得到;根据本公开具体实施例4的UE接收同步信号的示意图。
图8是根据本申请的一个终端采用多个panel给多个TRP发送上行信号时,采用一个相同的下行定时示意图二,图8是panel2发送的上行信号的时间单元边界根据panel1接收的TRP1发送的下行同步信号得到的下行时间单元边界得到。
t1是下行传输时延,当panel1给TRP1发送preamble时上行传输时延也假设为t1,TA1=2t1;
当Panel2时下行帧定时以panel1的下行帧定时为准时,TA2准确值应该是TA2=t1+t2,(t2和t1不同主要由于UE到TRP1,TRP2的距离不同,panel1上行链路和panel2的上行链路的波束不同,比如有的是直射径,有的不是直射径);
此时panel2的上行如果以TA1发送时,就会导致panel2除上行信号的到达时间会比panel2处的帧定时提前或者退后。panel2的下行帧定时准确地应该是以panel2接收TRP2的定时为准,要不然TRP2发送的下行第一个时域符号,到达panel2就不是第一个时域符号。
或者panel2的下行帧定时以panel2接收TRP1发送的下行同步信号时,TA2=t12+t2,此时t12和t1的差别是因为panel2的接收TRP1发送的同步信号的波束和panel1接收TRP1发送的同步信号的波束不同。
或者TRP2接收到panel2发送的上行信号之后可以调整TA量,但是这个TA量仅是针对panel2的上行信号,需要进一步确定panel2和panel1的上行信号如何区分,比如通过不同的SRS资源组区分,比如panel1和panel2分别对应SRS资源组1和SRS资源组2,或者panel1和panel2分别对应CORESET组1调度的上行信号,CORESET组2调度的上行信号,总之需要同一服务小区内将上行信号进行分组,不同组对应不同的TA量;
上述方案中,都是让panel2的下行帧定时以panel1接收TRP1发送的同步信号为准(传输时延为t1),或者以panel2接收TRP1发送的同步信号为准(传输时延为t12),但是实际panel2的下行定时应该以panel2接收TRP2发送的同步信号为准(传输时延为t3),当t3和t1/t12差别比大时,就会使得TRP2发送的第一个时域符号到达panel2时就不是第一个时域符号。需要进一步考虑,Panel2的下行帧定时可以让TRP2发送下行信号,panel2进行调整。但是此时对于TA量的提前量定义应该是per-panel级别的,即TA1是panel1的上行信号相对panel1的下行帧定时的提前量,TA2是panel2的上行信号相对panel2的下行帧定时的提前量。
可选地,还可以执行以下方式,有基站通知终端,或者预定义:
建立CORESET/SRS/扰码/小区ID/Spatial parameter和TA之间的关联;
建立下行参考信号和TA之间的关联;
建立(下行参考信号,上行参考信号)的组合和TA之间的关联。
具体实施例4
具体地TRP1的数据和TRP2的数据很独立,则他们各自有各自的进程号,但是为了进一步降低进程号在DCI中占有的比特数,可以不同的TRP对应不同的进程号集合,比如TRP1对应进程号集合{1,2,3,4},TRP2对应进程号{5,6,7,8},当然TRP2也可以在理想Backhaul的场景下,配置{1,2,3,4},基站进一步在动态指示进程号集合中的具体的进程号,根据配置的进程号集合得到DCI中进程号的比特数,。可以将进程号与以下信息建立关联关系,包括:建立TCI state组或者TCI state和进程号集合之间的关联关系,当Candidate的TCI属于组1,则其进程号为第一集合{1,2,3,4},当Candidate的TCI属于组2,则进程号为第二集合{5,6,7,8},当两个PDSCH的进程号相同,只需要反馈一个ACK/NACK。即DCI中指示的进程号是在第一进程号集合中的索引信息,其中第一进程号集合在数据信道的解调参考信号的QCL参考信号集合对应的TCI state中配置,或者第一进程号集合在数据信道的解调参考信号的QCL参考信号集合对应的TCI state属于TCI state组中配置。
类似地,一个TCI state或者TCI state组中还可以配置一个数据信道的如下信息至少之一:BWP集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,测量参考信号信息,加扰序列的产生参数,控制信道的端口信息,时域资源分配参数,频域资源分配参数,非周期测量参考信号信息。
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到根据上述实施例的方法可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件,但很多情况下前者是更佳的实施方式。基于这样的理解,本公开的技术方案本质上或者说对相关技术做出贡献的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质(如ROM/RAM、磁碟、光盘)中,包括若干指令用以使得一台终端设备(可以是手机,计算机,服务器,或者网络设备等)执行本公开各个实施例所述的方法。
实施例二
在本实施例中还提供了一种配置信息的发送装置,该装置用于实现上述实施例及优选实施方式,已经进行过说明的不再赘述。如以下所使用的,术语“模块”可以实现预定功能的软件和/或硬件的组合。尽管以下实施例所描述的装置较佳地以软件来实现,但是硬件,或者软件和硬件的组合的实现也是可能并被构想的。
根据本公开的另一个实施例,还提供了一种配置信息的发送装置,该装置包括:
第一发送模块,用于发送配置信息,其中,该配置信息中为一个频域带宽配置N套数据信道配置信息,和/或M套控制信道配置信息;
其中,该N,M是大于或者等于1的整数。
需要补充的是,一套控制信道资源的配置信息,可以为如下配置信息之一:一套PDCCH 的配置信息,一套CORESET的配置信息,一套Search space的配置信息,一套对应一个聚合度的Search space的配置信息,一套PUCCH的配置信息。
采用上述技术方案,解决了相关技术中缺乏实现多TRP与终端之间的数据传输的问题,为一个频域带宽配置多套配置信息,可以在多TRP传输时使用不同配置信息,实现了多TRP与终端之间的数据传输。
可选地,该装置还包括以下至少之一:
通过信令信息和/或约定方式,建立第一频域带宽包括的N1套数据信道配置信息和第二频域带宽包括的M1套控制信道资源的配置信息之间的对应关系;
通过信令信息和/或约定方式,建立第三频域带宽的N2套控制信道配置信息和第四频域带宽的M2套控制信道资源的配置信息之间的对应关系(可选地,第三频域带宽是上行控制信道的,第四频域带宽是下行控制信道的);
通过信令信息和/或约定方式,建立第五频域带宽包括的C1套参考信号配置信息和第六频域带宽包括的M3套控制信道资源的配置信息之间的对应关系;
通过信令信息和/或约定方式,建立第七频域带宽的N4套控制信道配置信息和第八频域带宽的一套控制信道配置信息中包括的D2套控制信道资源配置信息之间的对应关系;
在一套数据信道配置信息中包括该套数据信道对应的如下信息至少之一:进程号集合信息,TA信息;
在一套数据信道配置信息中包括该套数据信道的一个传输参数集合的多套配置信息,其中该一个传输参数集合包括如下参数至少之一:进程号集合信息,BWP集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,TCI state pool指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数;需要补充的是,可以在信道的高层信令中配置该一个传输参数集合的多套配置信息,在物理层控制信令中进一步指示调度的信道所用的一个传输参数集合对应的是哪一套配置信息;本实施例的中的加扰序列的产生参数可以是后续公式(2)中的虚拟小区ID;
其中N1,N2,N3,N4,M1,M2,D1,D2,M3,C1是大于或者等于1的正整数。
需要补充的是,上述对应关系可以是,控制信道的配置信息用于调度哪个数据信道;或者下行控制信道用于控制哪个上行控制信道;或者哪套数据信道配置信息对应哪套控制信道的配置信息。举例说明,比如下行BWP1中包括M1套PDCCH的配置信息,下行BWP2中包括N1套PDSCH的配置信息,需要指示BWP1中的一个PDCCH中调度的BWP2中的一个PDSCH是BWP2中包括的N1套PDSCH中的哪一套。
可选地,上述实施例的频域带宽可以包括以下至少之一:
该第一频域带宽和该第二频域带宽都是下行频域带宽;
该第一频域带宽是一个上行频域带宽,该第二频域带宽是一个下行频域带宽;
该第三频域带宽是一个上行频域带宽,该第四频域带宽是一个下行频域带宽;
该第五频域带宽和该第六频域带宽都是下行频域带宽;
该第五频域带宽是一个上行频域带宽,该第六频域带宽是一个下行频域带宽。
可选地,该装置包括以下至少之一:
该第二频域带宽中的第一控制信令调度该第一频域带宽中的第一数据信道,其中,该第一控制信令的传输参数根据该第二频域带宽中包括的M1套控制信道资源的配置信息中的一套获取,该第一数据信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第二频域带宽中一套数据信道配置信息获取;
该第四频域带宽中的第二控制信令调度该第三频域带宽中的第三控制信道,其中,该第二控制信令的传输参数根据该第四频域带宽中包括的M2套控制信道资源的配置信息中的一套获取,该第三控制信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第三频域带宽中一套控制信道配置信息获取;
第六频域带宽中的第三控制信令调度该第五频域带宽中的第二数据信道,其中该第三控制信令的传输参数根据该第六频域带宽中一个控制信道配置信息中的一套控制信道资源配置信息获取(可以是之前记载的第六频域带宽中包括的D1套控制信道资源配置信息中的一套),该第二数据信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第五频域带宽中一套数据信道配置信息获取;
第八频域带宽中的第四控制信令调度该第七频域带宽中的第四控制信道,其中该第四控制信令的传输参数根据该第八频域带宽中一个控制信道配置信息中的一套控制信道资源配置信息获取(可以是之前记载的第八频域带宽中包括的D2套控制信道资源配置信息中的一套),该第四控制信道的传输参数根据与该一套控制信道资源配置信息存在对应关系的第七频域带宽中一套控制信道配置信息获取。
可选地,包括以下至少之一:
发送第一控制信令,其中,该第一控制信令用于配置或者调度一个频域带宽中的一个数据信道,该第一控制信令中包括该一个频域带宽中包括的N5套数据信道配置信息的配置信息索引信息,其中,该数据信道的传输参数根据该索引信息对应的数据信道配置信息获取;
发送第二控制信令,其中,该第二控制信令用于配置或者调度一个频域带宽中的一个控制信道,该第二控制信令中包括该一个频域带宽中包括的N6套控制信道配置信息的配置信息索引信息,其中,该控制信道的传输参数根据该索引信息对应的控制信道资源配置信息获取;
发送第三控制信令,其中,该第三控制信令用于配置或者调度一个频域带宽中的测量参考信号资源,该第三控制信令中包括该一个频域带宽中包括的C2套测量参考信号配置信息的配置信息索引信息,其中,该测量参考信号资源的传输参数根据该索引信息对应的测量参考信号配置信息获取;
其中,该N5,N6,C2是大于或者等于1的正整数。
可选地,该第一控制信令是物理层控制信令;该第二控制信令是物理层控制信令;该第三控制信令是物理层控制信令。
根据本公开的另一个实施例,还提供了一种关联关系的确定装置,该装置包括:
第一确定模块,用于确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系;
其中,该P为大于或者等于1的正整数,该Q为小于或者等于P的正整数。
采用上述方案,解决了相关技术中缺乏多个控制信道资源和多套传输参数的配置信息的联系的方案,在多个控制信道资源和多套传输参数的配置信息之间建立了对应关系,后续可以依据此传输数据。
需要补充的是,终端侧和基站侧均可以执行上述步骤一的方案。一个传输参数集合可以是:该参数集合中包括多个参数,多套控制信道资源对应的不同套配置信息之间,具有该多个参数的不同取值。
可选地,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,该装置还包括以下至少之一:第一控制信令调度信道或者信号,其中,该第一控制信令的传输参数根据该P个控制信道资源中的一个控制信道资源的参数确定,该信道或者信号的传输参数集合根据与该一个控制信道资源存在对应关系的该Q套配置信息中一套配置信息确定;
该一个传输参数集合是信道或者信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在P2个控制信道资源包括的控制信道中,或者包括在该P2个控制信道资源包括的控制信道调度的信道中,其中该P2个控制信道资源属于该P个控制信道资源。
可选地,该P个控制信道资源和/或该一个传输参数集合的Q套配置信息,满足如下特征至少之一:
该P个控制信道资源属于一个相同的频域带宽;
该一个传输参数集合的Q套配置信息对应的Q个信道或者Q个信号属于一个相同的频域带宽;
该P个控制信道资源是一个第一通信节点需要检测的控制信道资源(需要补充的是,该P个控制信道资源是针对一个终端的);
该P个控制信道资源和该Q套配置信息对应的Q个信道或者Q个信号属于一个相同的频域带宽;
第一通信节点能同时接收该Q套配置信息对应的Q类信道和/或信号,其中,该第一通信节点为接收控制信道资源的节点;
第一通信节点能同时接收该P个控制信道资源,其中,该第一通信节点为接收控制信道资源的节点;
第一通信节点不能同时接收P1个控制信道资源中的不同控制信道资源,其中,该P1个控制信道资源属于该P个控制信道资源,且对应该一个传输参数集合的同一套配置信息,该第一通信节点为接收控制信道资源的节点;
第一通信节点不能同时接收对应该一个传输参数集合的同一套配置信息的多个控制信道资源,其中,该第一通信节点为接收控制信道资源的节点;
其中,该一个传输参数集合是关于该信道或者信号的传输参数。
可选地,该确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,包括以下至少之一:
在一个控制信道资源的配置信息中配置该一个控制信道资源对应的该一个传输参数集合的Q1套配置信息;
在该一个传输参数集合的一套配置信息中包括该套配置信息对应的P1个该控制信道资源;
确定一个控制信道资源和,信道或信号对应一个传输参数集合的Q1套配置信息之间的对应关系,其中,调度该信道或者信号的控制信令包括在该控制信道资源包括的控制信道中,或者包括在该控制信道资源包括的控制信道调度的信道中;
确定一个控制信道资源组,和信道或信号对应一个传输参数集合的Q2套配置信息之间的对应关系,其中,调度该信道或者信号的控制信令包括在该控制信道资源组包括的控制信道中,或者包括在该控制信道资源组包括的控制信道调度的信道中;
该一个传输参数集合是信道或信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在一个控制信道资源包括的控制信道中,或者包括在一个控制信道资源包括的控制信道调度的信道中;
该一个传输参数集合是信道或者信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在控制信道资源组包括的控制信道中,或者包括在控制信道资源组包括的控制信道调度的信道中;
确定X个频域带宽中每个频域带宽中的信道和/或信号对应的该一个传输参数集合的Q3套配置信息,确定一个控制信道资源和该Q3套配置信息的对应关系,其中,该X为大于或者等于1的正整数,该控制信道资源中包括的控制信息用于调度该X个频域带宽中的信道或信号;
其中,该Q1,Q2为小于或者等于Q的整数,该P1是小于或者等于P的整数,该一个频域带宽为一个CC或一个带宽部分BWP。
可选地,通过以下方式之一,指示该P个控制信道资源和该一个传输参数集合的Q套配置信息之间的对应关系:
在该控制信道资源的配置信息中包括该Q套配置信息的配置信息索引信息(即在该控制信道资源配置信息中包括Q套配置信息的配置信息索引信息);
在该一个传输参数集合的Q套配置信息中包括该P个控制信道资源的控制信道资源索引信息。
可选地,确定P个控制信道资源和该一个传输参数集合的Q套配置信息之间的对应关系,该还装置包括以下至少之一:
第一控制信令的比特数根据该Q套配置信息中的一套确定;
第一控制信令的预定比特域的比特数根据该Q套配置信息中的一套确定;
第一控制信令的通知该一个传输参数集合的传输参数的比特域的比特数,根据该Q套配置信息中的一套确定;
其中,该第一控制信令所在的控制信道的传输参数根据该P个控制信道资源中的一个控制信道资源的传输参数获取,该一套配置信息和该一个控制信道资源之间存在该对应关系。
(需要说明的是,本可选实施例中的第一控制信道资源,可以是P个控制信道资源中的任意一套或指定一套,不用于限定P个控制信道资源的顺序,本申请文件中的第N信息,第N资源的限定同理)。
可选地,该一个传输参数集合包括如下参数信息至少之一:进程号集合信息,BWP集合信息,上行控制信道资源集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,传输配置指示信息(Transmission configuration indication information,简称为TCI)state pool指示信息,下行数据信道的指示信息,上行数据信道的指示信息,上行控制信道的指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,测量参考信号信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数,非周期测量参考信号信息;其中一个TCI state中包括一个获者多个准共址参考信号集合的配置信息。
可选地,该控制信道资源是物理层控制信道资源;和/或,该一个传输参数集合的配置信息包括在高层信令中。
可选地,该确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,该装置还包括:
根据该一个传输参数集合的一套配置信息获取信道或者信号的第二传输参数,其中,该信道或者信号与该P个控制信道资源中的一个控制信道资源存在对应关系,该一套配置信息与该一个控制信道资源存在对应关系,该第二传输参数属于或者不属于该一个传输参数集合。
可选地,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,包括:一个控制信道资源对应该一个传输参数集合的Q1套配置信息,其中,该Q1为大于或者等于1的整数。
可选地,在该Q1大于1时,通过在该一个控制信道资源中传输的控制信令指示以下信息:根据该Q1套配置信息中的指定一套,确定该控制信令调度的信道或者信号的传输参数。(需要说明的是,本可选实施例中的第一套,可以是Q套配置信息中的任意一套或指定一套,不用于限定Q套配置信息的顺序)。
可选地,所述P个控制信道资源包括如下特征之一:
该一个控制信道资源为一个物理下行控制信道PDCCH控制信道资源;
该一个控制信道资源为一个控制资源集合CORESET资源;
该一个控制信道资源为一个搜索空间集合Search space set资源;
该一个控制信道资源为一个聚合度的Search space资源;
该一个控制信道资源为一个候选物理下行控制信道Candidate PDCCH资源;
该一个控制信道的加扰序列产生参数。
根据本公开的另一个实施例,还提供了一种时间提前TA信息的确定装置,包括:
第二确定模块,用于根据第一信号和/或第二信号确定TA信息,其中,该第一信号是该 第一通信节点发送的信号,该第二信号是该第一通信节点接收的信号;
根据该TA信息发送第三信号。
需要说明的是,第一信号可以是终端发送的波束信号。
采用上述方案,解决了相关技术中缺乏确定TA值的方案,实现了准确的依据第一信号和/或第二信号,确定发送第三信号的TA值。
可选地,该第二信道或者第二信号是该第一通信节点接收的信道或者信号,还满足以下特征至少之一:
该第二信道为控制信道,在该控制信道中包括调度该第三信道或者第三信号的控制信令;
该第二信号和调度该第三信道或者第三信号的控制信令的解调参考信号之间至少关于一个准共址参数满足准共址(quasi-co-location,简称为QCL)关系;
依据该第二信号的空间滤波参数获取该第三信道或者第三信号的空间滤波参数。
可选地,该第二信号和调度该第三信道或者第三信号的控制信令的解调参考信号之间至少关于一个准共址参数满足准共址QCL关系,包括:该第二信号和调度该第三信道或者第三信号的控制信令的解调参考信号之间,关于延迟扩展(delay spread)和/或平均延迟((average delay))满足QCL关系。
需要补充的是,第二信号和解调参考信号之间,至少关于多径TA和/或平均TA满足QCL关系。
可选地,调度该第一信道和第三信道或者第三信号的控制信令属于一个相同的控制信道资源。
可选地,该第一通信节点根据该第一信号获取该第三信道或者第三信号的如下信息至少之一:该第三信道或者第三信号的空间滤波参数信息,该第三信道或者第三信号的功率参数信息。
可选地,该TA信息是,第一时间单元起始位置相对于第二时间单元的起始位置之间的时间差,其中,该第三信道或者第三信号对应该第一时间单元,该第二信道或者第三信号对应该第二时间单元。需要补充的是,第一时间单元可以是上行时间单元,第二时间单元可以是下行时间单元。
可选地,该装置还包括以下至少之一:
该第一信道或者第二信道或者该第三信道包括如下信道至少之一:数据信道,控制信道;
该第一信号或者该第三信号包括如下信号至少之一:解调参考信号,测量参考信号,随机接入信号;
该第二信号包括如下信号至少之一:解调参考信号,测量参考信号,同步信号,跟踪参考信号TRS(tracking reference signal)的测量参考信号。
可选地,该第一信道或者第一信号和该TA信息之间的关联关系;该第二信道或者第二信号和该TA信息之间的关联关系;该第一信道或者第一信号,与该第二信道或者第二信号的组合,和该TA信息之间的关联关系。
需要补充的是,建立信号和该TA信息之间的关联关系包括该至少之一:在该TA信息 的配置信息中包括该信号信息;在该信号的配置信息中包括该TA信息;根据该信号信息确定该TA信息。
可选地,第一通信节点根据第二信道或者第二信号确定该TA信息包括:根据该第二信道或者第二信号对应的扰码信息确定该TA信息;根据该第二信道或者第二信号所在的控制信道资源的传输参数确定该TA信息;根据该第二信道的配置信息中包括的该TA信息获取该TA信息。
根据本公开的另一个实施例,还提供了一种TA信息的确定装置,包括:
第二发送模块,用于发送信令信息至第一通信节点,该信令信息中包括如下关联关系至少之一:
第一信号和TA信息之间的关联关系;
第二信号和该TA信息之间的关联关系;
该第一信号与第二信号的组合,和该TA信息之间的关联关系;
其中,该第一信号是该第一通信节点发送的信号,该第二信号是该第一通信节点接收的信号。
需要补充的是,建立第一信号和该TA信息之间的关联关系包括以下至少之一:在该TA信息的配置信息中包括该第一信号信息;在该第一信号的配置信息中包括该TA信息;根据该第一信号信息确定该TA信息。其他关联关系同理。
采用上述技术方案,解决了相关技术中多TRP传输场景下,缺乏确定终端发送信号的TA值的方案的问题,后续可以依据关联关系确定TA值。
可选地,该TA信息是该第一通信节点发送第三信道或者第三信号的依据,或者该TA信息是该第一通信节点发送该第一信道或者第二信号的依据。
可选地,该装置还包括:该第一信道或者第二信道或者该第三信道包括如下信道至少之一:数据信道,控制信道;该第一信号或者第三信号包括如下信号至少之一:解调参考信号,测量参考信号,随机接入信号;该第二信号包括如下信号至少之一:解调参考信号,测量参考信号,同步信号,作为跟踪参考信号TRS的测量参考信号。
可选地,该信令信息包括如下信令信息之一:该信令信息为高层信令信息;该信令信息为物理层信令信息。
根据本公开的另一个实施例,还提供了一种TA信息的确定装置,包括:
第一接收模块,用于接收第二通信节点发送的第三信号的配置信息,其中,该配置信息中包括TA信息;
第三发送模块,用于根据该TA信息发送该第三信号。
采用上述技术方案,解决了相关技术中在多TRP传输场景下,终端无法确定发送上行信号的TA值的问题,给出了终端依据配置信息确定TA值的方案。
可选地,接收第三信号的配置信息,包括以下至少之一:接收该第三信号的高层配置信息,确定该第三信号的高层配置信息为该第三信号的配置信息;接收用于调度该第三信号的物理层控制信令,其中,该物理层控制信令中包括第三信号的配置信息。
可选地,该第三信号的配置信息中,该TA信息和如下信息至少之一之间联合编码:该第三信号的空间滤波参数;该第三信号的功率参数。
需要说明的是,上述各个模块是可以通过软件或硬件来实现的,对于后者,可以通过以下方式实现,但不限于此:上述模块均位于同一处理器中;或者,上述各个模块以任意组合的形式分别位于不同的处理器中。
实施例三
根据本公开的一个实施例,提供了一种存储介质,所述存储介质中存储有计算机程序,其中,所述计算机程序被设置为运行时执行上述实施例任一项中所述的方法。
实施例四
根据本公开的另一个实施例,还提供了一种电子装置,包括存储器和处理器,其特征在于,所述存储器中存储有计算机程序,所述处理器被设置为运行所述计算机程序以执行上述实施例任一项中所述的方法。
本公开的实施例还提供了一种电子装置,包括存储器和处理器,该存储器中存储有计算机程序,该处理器被设置为运行计算机程序以执行上述任一项方法实施例中的步骤。
显然,本领域的技术人员应该明白,上述的本公开的各模块或各步骤可以用通用的计算装置来实现,它们可以集中在单个的计算装置上,或者分布在多个计算装置所组成的网络上,可选地,它们可以用计算装置可执行的程序代码来实现,从而,可以将它们存储在存储装置中由计算装置来执行,并且在某些情况下,可以以不同于此处的顺序执行所示出或描述的步骤,或者将它们分别制作成各个集成电路模块,或者将它们中的多个模块或步骤制作成单个集成电路模块来实现。这样,本公开不限制于任何特定的硬件和软件结合。
以上所述仅为本公开的优选实施例而已,并不用于限制本公开,对于本领域的技术人员来说,本公开可以有各种更改和变化。凡在本公开的精神和原则之内,所作的任何修改、等同替换、改进等,均应包含在本公开的保护范围之内。

Claims (47)

  1. 一种配置信息的发送方法,包括:
    发送配置信息,其中,所述配置信息包括以下至少之一:
    为一个频域带宽配置N套数据信道配置信息;
    为一个频域带宽配置M套控制信道资源配置信息;
    为一个频域带宽配置C套测量参考信号配置信息;
    其中,所述N,M,C是大于或者等于1的整数。
  2. 根据权利要求1所述的方法,其中,所述一个频域带宽为一个带宽部分BWP,和/或,所述一个频域带宽是一个专有频域带宽。
  3. 根据权利要求1所述的方法,其中,所述方法还包括以下至少之一:
    通过信令信息和/或约定方式,建立第一频域带宽包括的N1套数据信道配置信息和第二频域带宽包括的M1套控制信道资源的配置信息之间的对应关系;
    通过信令信息和/或约定方式,建立第三频域带宽的N2套控制信道配置信息和第四频域带宽的M2套控制信道资源的配置信息之间的对应关系;
    通过信令信息和/或约定方式,建立第五频域带宽包括的C1套参考信号配置信息和第六频域带宽包括的M3套控制信道资源的配置信息之间的对应关系;
    在一套数据信道配置信息中包括该套数据信道对应的如下信息至少之一:进程号集合信息,TA信息;
    在一套数据信道配置信息中包括该套数据信道的一个传输参数集合的多套配置信息,其中所述一个传输参数集合包括如下参数至少之一:进程号集合信息,BWP集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,TCI state pool指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数;
    其中N1,N2,M1,M2,M3,C1是大于或者等于1的正整数。
  4. 根据权利要求3所述的方法,其中,所述方法包括以下至少之一:
    所述第一频域带宽和所述第二频域带宽都是下行频域带宽;
    所述第一频域带宽是一个上行频域带宽,所述第二频域带宽是一个下行频域带宽;
    所述第三频域带宽是一个上行频域带宽,所述第四频域带宽是一个下行频域带宽;
    所述第五频域带宽和所述第六频域带宽都是下行频域带宽;
    所述第五频域带宽是一个上行频域带宽,所述第六频域带宽是一个下行频域带宽。
  5. 根据权利要求3所述的方法,其中,所述方法包括以下至少之一:
    所述第二频域带宽中的第一控制信令调度所述第一频域带宽中的第一数据信道,其中,所述第一控制信令的传输参数根据所述第二频域带宽中包括的M1套控制信道资源的配置信息中的一套获取,所述第一数据信道的传输参数根据与所述一套控制信道资源配置信 息存在对应关系的第一频域带宽中一套数据信道配置信息获取;
    所述第四频域带宽中的第二控制信令调度所述第三频域带宽中的第三控制信道,其中,所述第二控制信令的传输参数根据所述第四频域带宽中包括的M2套控制信道资源的配置信息中的一套获取,所述第三控制信道的传输参数根据与所述一套控制信道资源配置信息存在对应关系的第三频域带宽中一套控制信道配置信息获取。
  6. 根据权利要求1所述的方法,其中,包括以下至少之一:
    发送第一控制信令,其中,所述第一控制信令用于配置或者调度一个频域带宽中的一个数据信道,所述第一控制信令中包括所述一个频域带宽中包括的N5套数据信道配置信息的配置信息索引信息,其中,所述数据信道的传输参数根据所述索引信息对应的数据信道配置信息获取;
    发送第二控制信令,其中,所述第二控制信令用于配置或者调度一个频域带宽中的一个控制信道,所述第二控制信令中包括所述一个频域带宽中包括的N6套控制信道配置信息的配置信息索引信息,其中,所述控制信道的传输参数根据所述索引信息对应的控制信道资源配置信息获取;
    发送第三控制信令,其中,所述第三控制信令用于配置或者调度一个频域带宽中的测量参考信号资源,所述第三控制信令中包括所述一个频域带宽中包括的C2套测量参考信号配置信息的配置信息索引信息,其中,所述测量参考信号资源的传输参数根据所述索引信息对应的测量参考信号配置信息获取;
    其中,所述N5,N6,C2是大于或者等于1的正整数。
  7. 根据权利要求6所述的方法,其中,包括以下至少之一:
    所述第一控制信令是物理层控制信令;
    所述第二控制信令是物理层控制信令;
    所述第三控制信令是物理层控制信令。
  8. 一种配置信息的接收方法,包括:
    接收配置信息,其中,所述配置信息包括以下至少之一:
    为一个频域带宽配置N套数据信道配置信息;
    为一个频域带宽配置M套控制信道资源配置信息;
    为一个频域带宽配置C套测量参考信号配置信息;
    其中,所述N,M,C是大于或者等于1的整数。
  9. 根据权利要求8所述的方法,其中,所述一个频域带宽为一个带宽部分BWP,和/或,所述一个频域带宽是一个专有频域带宽。
  10. 根据权利要求8所述的方法,其中,所述方法还包括以下至少之一:
    通过信令信息和/或约定方式,建立第一频域带宽包括的N1套数据信道配置信息和第二频域带宽包括的M1套控制信道资源的配置信息之间的对应关系;
    通过信令信息和/或约定方式,建立第三频域带宽的N2套控制信道配置信息和第四频 域带宽的M2套控制信道资源的配置信息之间的对应关系;
    通过信令信息和/或约定方式,建立第五频域带宽包括的C1套参考信号配置信息和第六频域带宽包括的M3套控制信道资源的配置信息之间的对应关系;
    在一套数据信道配置信息中包括该套数据信道对应的如下信息至少之一:进程号集合信息,TA信息;
    在一套数据信道配置信息中包括该套数据信道的一个传输参数集合的多套配置信息,其中所述一个传输参数集合包括如下参数至少之一:进程号集合信息,BWP集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,TCI state pool指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数;
    其中N1,N2,M1,M2,M3,C1是大于或者等于1的正整数。
  11. 根据权利要求10所述的方法,其中,所述方法包括以下至少之一:
    所述第一频域带宽和所述第二频域带宽都是下行频域带宽;
    所述第一频域带宽是一个上行频域带宽,所述第二频域带宽是一个下行频域带宽;
    所述第三频域带宽是一个上行频域带宽,所述第四频域带宽是一个下行频域带宽;
    所述第五频域带宽和所述第六频域带宽都是下行频域带宽;
    所述第五频域带宽是一个上行频域带宽,所述第六频域带宽是一个下行频域带宽。
  12. 根据权利要求10所述的方法,其中,所述方法包括以下至少之一:
    所述第二频域带宽中的第一控制信令调度所述第一频域带宽中的第一数据信道,其中,所述第一控制信令的传输参数根据所述第二频域带宽中包括的M1套控制信道资源的配置信息中的一套获取,所述第一数据信道的传输参数根据与所述一套控制信道资源配置信息存在对应关系的第一频域带宽中一套数据信道配置信息获取;
    所述第四频域带宽中的第二控制信令调度所述第三频域带宽中的第三控制信道,其中,所述第二控制信令的传输参数根据所述第四频域带宽中包括的M2套控制信道资源的配置信息中的一套获取,所述第三控制信道的传输参数根据与所述一套控制信道资源配置信息存在对应关系的第三频域带宽中一套控制信道配置信息获取。
  13. 根据权利要求8所述的方法,其中,包括以下至少之一:
    接收第一控制信令,其中,所述第一控制信令用于配置或者调度一个频域带宽中的一个数据信道,所述第一控制信令中包括所述一个频域带宽中包括的N5套数据信道配置信息的配置信息索引信息,其中,所述数据信道的传输参数根据所述索引信息对应的数据信道配置信息获取;
    接收第二控制信令,其中,所述第二控制信令用于配置或者调度一个频域带宽中的一个控制信道,所述第二控制信令中包括所述一个频域带宽中包括的N6套控制信道配置信息的配置信息索引信息,其中,所述控制信道的传输参数根据所述索引信息对应的控制信 道资源配置信息获取;
    接收第三控制信令,其中,所述第三控制信令用于配置或者调度一个频域带宽中的测量参考信号资源,所述第三控制信令中包括所述一个频域带宽中包括的C2套测量参考信号配置信息的配置信息索引信息,其中,所述测量参考信号资源的传输参数根据所述索引信息对应的测量参考信号配置信息获取;
    其中,所述N5,N6,C2是大于或者等于1的正整数。
  14. 根据权利要求13所述的方法,其中,包括以下至少之一:
    所述第一控制信令是物理层控制信令;
    所述第二控制信令是物理层控制信令;
    所述第三控制信令是物理层控制信令。
  15. 一种对应关系的确定方法,包括:
    确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系;
    其中,所述P为大于或者等于1的正整数,所述Q为小于或者等于P的正整数。
  16. 根据权利要求15所述的方法,其中,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,所述方法还包括以下至少之一:
    第一控制信令调度信道或者信号,其中,所述第一控制信令的传输参数根据所述P个控制信道资源中的一个控制信道资源的参数确定,该信道或者信号的传输参数集合根据与所述一个控制信道资源存在对应关系的所述Q套配置信息中一套配置信息确定;
    所述一个传输参数集合是信道或者信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在P2个控制信道资源包括的控制信道中,或者包括在所述P2个控制信道资源包括的控制信道调度的信道中,其中所述P2个控制信道资源属于所述P个控制信道资源。
  17. 根据权利要求15所述的方法,其中,所述P个控制信道资源和/或所述一个传输参数集合的Q套配置信息,满足如下特征至少之一:
    所述P个控制信道资源属于一个相同的频域带宽;
    所述一个传输参数集合的Q套配置信息对应的Q个信道或者Q个信号属于一个相同的频域带宽;
    所述P个控制信道资源是一个第一通信节点需要检测的控制信道资源;
    所述P个控制信道资源和所述Q套配置信息对应的Q个信道或者Q个信号属于一个相同的频域带宽;
    第一通信节点能同时接收所述Q套配置信息对应的Q类信道和/或信号,其中,所述第一通信节点为接收控制信道资源的节点;
    第一通信节点能同时接收所述P个控制信道资源,其中,所述第一通信节点为接收控制信道资源的节点;
    第一通信节点不能同时接收P1个控制信道资源中的不同控制信道资源,其中,所述 P1个控制信道资源属于所述P个控制信道资源,且对应所述一个传输参数集合的同一套配置信息,所述第一通信节点为接收控制信道资源的节点;
    第一通信节点不能同时接收对应所述一个传输参数集合的同一套配置信息的多个控制信道资源,其中,所述第一通信节点为接收控制信道资源的节点;
    其中,所述一个传输参数集合是关于所述信道或者信号的传输参数。
  18. 根据权利要求15所述的方法,其中,所述确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,包括以下至少之一:
    在一个控制信道资源的配置信息中配置所述一个控制信道资源对应的所述一个传输参数集合的Q1套配置信息;
    在所述一个传输参数集合的一套配置信息中包括该套配置信息对应的P1个所述控制信道资源;
    确定一个控制信道资源和,信道或信号对应一个传输参数集合的Q1套配置信息之间的对应关系,其中,调度该信道或者信号的控制信令包括在该控制信道资源包括的控制信道中,或者包括在该控制信道资源包括的控制信道调度的信道中;
    确定一个控制信道资源组,和信道或信号对应一个传输参数集合的Q2套配置信息之间的对应关系,其中,调度该信道或者信号的控制信令包括在该控制信道资源组包括的控制信道中,或者包括在所述控制信道资源组包括的控制信道调度的信道中;
    所述一个传输参数集合是信道或信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在一个控制信道资源包括的控制信道中,或者包括在一个控制信道资源包括的控制信道调度的信道中;
    所述一个传输参数集合是信道或者信号对应的传输参数集合,其中,调度该信道或者信号的控制信令包括在控制信道资源组包括的控制信道中,或者包括在控制信道资源组包括的控制信道调度的信道中;
    确定X个频域带宽中每个频域带宽中的信道和/或信号对应的所述一个传输参数集合的Q3套配置信息,确定一个控制信道资源和所述Q3套配置信息的对应关系,其中,所述X为大于或者等于1的正整数,该控制信道资源中包括的控制信息用于调度所述X个频域带宽中的信道或信号;
    其中,所述Q1,Q2为小于或者等于Q的整数,所述P1是小于或者等于P的整数,所述一个频域带宽为一个成员载波CC或一个带宽部分BWP。
  19. 根据权利要求15所述的方法,其中,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,所述方法包括以下至少之一:
    第一控制信令的比特数根据所述Q套配置信息中的一套确定;
    第一控制信令的预定比特域的比特数根据所述Q套配置信息中的一套确定;
    第一控制信令的通知所述一个传输参数集合的传输参数的比特域的比特数,根据所述Q套配置信息中的一套确定;
    其中,所述第一控制信令所在的控制信道的传输参数根据所述P个控制信道资源中的一个控制信道资源的传输参数获取,所述一套配置信息和所述一个控制信道资源之间存在所述对应关系。
  20. 根据权利要求15~19中的任意一项所述的方法,其中,所述一个传输参数集合包括如下参数信息至少之一:
    进程号集合信息,带宽部分BWP集合信息,上行控制信道资源集合信息,解调参考信号端口集合信息,解调参考信号信息,准共参考信号集合信息,传输配置指示信息TCI state pool指示信息,下行数据信道的指示信息,上行数据信道的指示信息,上行控制信道的指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,测量参考信号信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数,非周期测量参考信号信息;
    其中一个TCI state中包括一个获者多个准共址参考信号集合的配置信息。
  21. 根据权利要求20所述的方法,其满足如下至少之一:
    所述一个控制信道资源对应一套TCI state pool信息包括所述一个控制信道资源中的控制信令调度的信道或信号的TCI state属于所述一个控制信道资源对应的TCI state pool中;
    所述速率匹配指示信息包括如下信息至少之一:RRC信令配置的速率匹配信息,MAC-CE通知的速率匹配信息,DCI通知的速率匹配信息;
    所述不同套测量参考信号信息对应的测量参考信号资源之间的交集为空;
    所述不同套非周期测量参考信号信息对应的非周期测量参考信号资源之间的交集为空;
    所述不同套上行控制信道资源集合信息对应的上行控制信道资源集合之间的交集为为空;
    所述一个传输参数集合的Q套配置信息中包括的同一类传输参数的不同套配置信息之间交集为空或不同套配置信息的差值非0。
  22. 根据权利要求15所述的方法,其中,
    所述控制信道资源是物理层控制信道资源;
    和/或,所述一个传输参数集合的配置信息包括在高层信令中。
  23. 根据权利要求15所述的方法,其中,所述确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,所述方法还包括:
    根据所述一个传输参数集合的一套配置信息获取信道或者信号的第二传输参数,其中,所述信道或者信号与所述P个控制信道资源中的一个控制信道资源存在对应关系,所述一套配置信息与所述一个控制信道资源存在对应关系,所述第二传输参数属于或者不属于所述一个传输参数集合。
  24. 根据权利要求15所述的方法,其中,确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系,包括:
    一个控制信道资源对应所述一个传输参数集合的Q1套配置信息,其中,所述Q1为大于或者等于1的整数。
  25. 根据权利要求24所述的方法,其中,在所述Q1大于1时,通过在所述一个控制信道资源中传输的控制信令指示以下信息:
    根据所述Q1套配置信息中的指定一套,确定所述控制信令调度的信道或者信号的传输参数。
  26. 根据权利要求15~25中的任意一项所述的方法,其中,所述P个控制信道资源包括如下特征之一:
    一个控制信道资源为一个物理下行控制信道PDCCH控制信道资源;
    一个控制信道资源为一个控制资源集合CORESET资源;
    一个控制信道资源为一个搜索空间Search space资源;
    一个控制信道资源为一个聚合度的Search space资源;
    一个控制信道资源为一个候选物理下行控制信道Candidate PDCCH资源;
    一个控制信道的加扰序列产生参数。
  27. 根据权利要求15~24中的任意一项所述的方法,其满足如下特征至少之一:
    一个频域带宽中包括的Q套PUCCH资源集合之间的交集为空;
    一个频域带宽中包括的Q套测量参考信号资源之间的交集为空;
    一个频域带宽中包括的Q套解调参考信号资源之间的交集为空;
    一个频域带宽中包括的Q套解调参考信号信息之间不同或相同;
    一个频域带宽中包括的Q套TCI state pool之间的TCI state中的准共址参考信号之间关于一类准共址参数不满足准共址关系;
    所述第一类参数集合的Q套配置信息中的不同套配置信息对应不同的所述控制信道资源或对应不同的所述控制信道资源组,所述控制信道资源包括下行控制信道资源;
    进程号相同的两个PDSCH对应同一个ACK/NACK反馈比特;
    其中所述Q值大于1,所述资源包括如下资源至少之一:时域资源,频域资源,空域资源。
  28. 根据权利要求27或20所述的方法,所述解调参考信号的信息包括如下至少之一:
    解调参考信号图样类型、解调参考信号占有连续时域符号组的个数、解调参考信号占有的一个连续时域符号组中包括的时域符号个数的最大值、产生解调参考信号序列的产生参数、解调参考信号的起始时域符号位置、解调参考信号占有的一个连续时域符号组中包括的时域符号个数、transform precoding是否使能、解调参考信号端口信息、解调参考信号所在的频域组、解调参考信号和解调参考信号对应的信道之间的功率差。
  29. 根据权利要求15~28中的任意一项所述的方法,其特征还包括:
    确定P个控制信道资源和一个传输参数集合的Q套信息之间的对应关系;
    其中,所述P为大于或者等于1的正整数,所述Q为小于或者等于P的正整数。
  30. 根据权利要求15~25中的任意一项所述的方法,其中,还在于:
    建立E个TCI state或TCI state组和所述一个传输参数集合的F套信息之间的关联关系,
    其中所述E,F为大于或等于1的整数。
  31. 根据权利要求30所述的方法,所述建立E个TCI state或TCI state组和所述一个传输参数集合的F套信息之间的关联关系还包括:
    根据所述TCI state或TCI state组信息得到所述一个传输参数集合的信息。
  32. 一种关联关系信息的确定方法,包括:
    建立E个TCI state或TCI state组和一个传输参数集合的F套信息之间的关联关系,
    其中所述E,F为大于或等于1的整数。
  33. 根据权利要求32所述的方法,其中:
    根据所述TCI state或TCI state组信息得到所述一个传输参数集合的信息;和/或
    一个信道和/或信号的所述一个传输参数集合的信息为与所述一个信道和/或信号的TCI state存在对应关系的所述一个传输参数集合的一套信息;或者一个信道和/或信号的所述一个传输参数集合的信息为与所述一个信道和/或信号的TCI state所属的TCI state组存在对应关系的所述一个传输参数集合的一套信息。
  34. 根据权利要求32所述的方法,其中,所述一个传输参数集合包括如下参数至少之一:
    进程号集合信息,带宽部分BWP集合信息,上行控制信道资源集合信息,解调参考信号端口集合信息,解调参考信号信息,准共址参考信号集合信息,传输配置指示信息TCI state pool指示信息,下行数据信道的指示信息,上行数据信道的指示信息,上行控制信道的指示信息,预编码资源粒度PRB bundling size指示信息,速率匹配rate mating指示信息,载波Carrier indicator指示信息,测量参考信号信息,加扰序列的产生参数,TA信息,控制信道的端口信息,时域资源分配参数,频域资源分配参数,非周期测量参考信号信息;
    其中一个TCI state中包括一个获者多个准共址参考信号集合的配置信息。
  35. 一种时间提前量TA信息的确定方法,包括:
    第一通信节点根据以下信息至少之一确定TA信息:第一信道,第一信号,第二信道,第二信号;其中,所述第一信道或者第一信号是所述第一通信节点发送的信道或者信号,所述第二信道或者第二信号是所述第一通信节点接收的信道或者信号;
    根据所述TA信息发送第三信道或者第三信号。
  36. 根据权利要求35所述的方法,其中,所述第二信道或者第二信号是所述第一通信节点接收的信道或者信号,还满足以下特征至少之一:
    所述第二信道为控制信道,在所述控制信道中包括调度所述第三信道或者第三信号的控制信令;
    所述第二信号和调度所述第三信道或者第三信号的控制信令的解调参考信号之间至少关于一个准共址参数满足准共址QCL关系;
    依据所述第二信号的空间滤波参数获取所述第三信道或者第三信号的空间滤波参数。
  37. 根据权利要求36所述的方法,其中,所述第二信号和调度所述第三信道或者第三信号的控制信令的解调参考信号之间至少关于一个准共址参数满足准共址QCL关系,包括:
    所述第二信号和调度所述第三信道或者第三信号的控制信令的解调参考信号之间,关于延迟扩展和/或平均延迟满足QCL关系。
  38. 根据权利要求35所述的方法,其中,所述第一通信节点还根据所述第一信号获取所述第三信道或者第三信号的如下信息至少之一:
    所述第三信道或者第三信号的空间滤波参数信息,
    所述第三信道或者第三信号的功率参数信息。
  39. 根据权利要求35所述的方法,其中,第一通信节点根据第二信道或者第二信号确定所述TA信息包括:
    根据所述第二信道或者第二信号对应的扰码信息确定所述TA信息;
    根据所述第二信道或者第二信号所在的控制信道资源的传输参数确定所述TA信息;
    根据所述第二信道的配置信息中包括的所述TA信息获取所述TA信息。
  40. 一种TA信息的确定方法,其中:
    第二通信节点发送信令信息至第一通信节点,所述信令信息中包括如下关联关系至少之一:
    第一信道或者第一信号和TA信息之间的关联关系;
    第二信道或者第二信号和所述TA信息之间的关联关系;
    所述第一信道或者第一信号,与所述第二信道或者第二信号的组合,和所述TA信息之间的关联关系;
    其中,所述第一信道或者第一信号是所述第一通信节点发送的信道或信号,所述第二信道或者第二信号是所述第一通信节点接收的信道或信号。
  41. 一种配置信息的发送装置,所述装置包括:
    第一发送模块,设置为发送配置信息,其中,所述配置信息包括以下至少之一:
    为一个频域带宽配置N套数据信道配置信息;
    为一个频域带宽配置M套控制信道资源配置信息;
    为一个频域带宽配置C套测量参考信号配置信息;
    其中,所述N,M,C是大于或者等于1的整数。
  42. 一种配置信息的接收装置,其中,所述装置包括:
    第一接收模块,设置为接收配置信息,其中,所述配置信息包括以下至少之一:
    为一个频域带宽配置N套数据信道配置信息;
    为一个频域带宽配置M套控制信道资源配置信息;
    为一个频域带宽配置C套测量参考信号配置信息;
    其中,所述N,M,C是大于或者等于1的整数。
  43. 一种对应关系的确定装置,所述装置包括:
    第一确定模块,设置为确定P个控制信道资源和一个传输参数集合的Q套配置信息之间的对应关系;
    其中,所述P为大于或者等于1的正整数,所述Q为小于或者等于P的正整数。
  44. 一种时间提前TA信息的确定装置,包括:
    第二确定模块,设置为根据以下信息至少之一确定TA信息:第一信道,第一信号,第二信道,第一信号;其中,所述第一信道或者第一信号是第一通信节点发送的信道或者信号,所述第二信道或者第二信号是所述第一通信节点接收的信道或者信号;
    第二发送模块,设置为根据所述TA信息发送第三信道或者第三信号。
  45. 一种TA信息的确定装置,包括:
    第二发送模块,设置为发送信令信息至第一通信节点,所述信令信息中包括如下关联关系至少之一:
    第一信道或者第一信号和TA信息之间的关联关系;
    第二信道或者第二信号和所述TA信息之间的关联关系;
    所述第一信道或者第一信号,与所述第二信道或者第二信号的组合,和所述TA信息之间的关联关系;
    其中,所述第一信道或者第一信号是所述第一通信节点发送的信号,所述第二信道或者第二信号是所述第一通信节点接收的信号。
  46. 一种存储介质,其中,所述存储介质中存储有计算机程序,其中,所述计算机程序被设置为运行时执行所述权利要求1至40任一项中所述的方法。
  47. 一种电子装置,包括存储器和处理器,其中,所述存储器中存储有计算机程序,所述处理器被设置为运行所述计算机程序以执行所述权利要求1至40任一项中所述的方法。
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2021147119A1 (en) * 2020-01-25 2021-07-29 Qualcomm Incorporated Interference-based sounding reference signal beam determination
WO2022030819A1 (ko) * 2020-08-07 2022-02-10 엘지전자 주식회사 무선 통신 시스템에서 상향링크 송수신 방법 및 장치

Families Citing this family (27)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102301625B (zh) * 2009-01-29 2014-07-09 松下电器产业株式会社 无线发送装置和参考信号发送方法
US11895582B2 (en) * 2018-07-24 2024-02-06 Ofinno, Llc Power saving operations in a wireless communication system
CN112956149A (zh) * 2018-11-01 2021-06-11 Oppo广东移动通信有限公司 一种数据加扰方法及装置、通信设备
WO2020091567A1 (ko) * 2018-11-02 2020-05-07 엘지전자 주식회사 무선 통신 시스템에서 coreset 운용 방법 및 상기 방법을 이용하는 단말
ES2971354T3 (es) * 2018-11-09 2024-06-04 Guangdong Oppo Mobile Telecommunications Corp Ltd Método de comunicación inalámbrica, dispositivo de red y dispositivo terminal
EP3949177A4 (en) * 2019-03-29 2022-04-13 ZTE Corporation SYSTEMS AND PROCEDURES FOR CONFIGURATION BASED ON GROUP IDENTIFIERS
WO2020229724A1 (en) * 2019-05-13 2020-11-19 Nokia Technologies Oy Radio resource management
US11818072B2 (en) * 2019-07-02 2023-11-14 Comcast Cable Communications, Llc Wireless resource determination and use
EP4002913A1 (en) * 2019-07-17 2022-05-25 Ntt Docomo, Inc. Terminal and wireless communication method
CN110855410B (zh) * 2019-11-07 2022-05-13 展讯半导体(南京)有限公司 解调参考信号dmrs端口的确定方法及相关产品
US11950212B2 (en) * 2019-12-12 2024-04-02 Qualcomm Incorporated Timing advance signaling for multi-transmit receive point operation
US11678339B2 (en) * 2019-12-13 2023-06-13 Samsung Electronics Co., Ltd. Method and apparatus for group-based multi-beam operation
WO2021155555A1 (en) * 2020-02-07 2021-08-12 Qualcomm Incorporated Transmission configuration indicator state activation for multiple transmission reception points
US11671994B2 (en) * 2020-04-10 2023-06-06 Qualcomm Incorporated Reusing PDSCH TCI and QCL for dynamic coresets
CN115428377B (zh) * 2020-04-10 2024-06-14 Oppo广东移动通信有限公司 信道资源的传输方法、装置、网络设备、终端和系统
EP4158959A4 (en) * 2020-05-29 2024-03-13 Qualcomm Incorporated TIME ADVANCE INDICATOR FOR MULTI-PANEL UPLINK TRANSMISSION
CN114070522B (zh) * 2020-08-07 2023-04-07 北京紫光展锐通信技术有限公司 用于多trp场景的上行信道测量方法及装置
CN114257354B (zh) * 2020-09-22 2023-10-17 中国移动通信有限公司研究院 一种传输方法、终端设备及网络侧设备
CN116325611A (zh) * 2020-10-16 2023-06-23 日本电气株式会社 通信方法、终端设备、网络设备以及计算机可读介质
US11342970B1 (en) 2020-11-25 2022-05-24 Qualcomm Incorporated Techniques for indicating preferred beams in multi-transmission and reception point (multi-TRP) systems based on default operating frequency (DOF) mismatch
CN117177345A (zh) * 2022-05-25 2023-12-05 上海朗帛通信技术有限公司 一种被用于无线通信的节点中的方法和装置
CN117377118A (zh) * 2022-06-23 2024-01-09 夏普株式会社 由用户设备执行的方法及用户设备
CN117545098A (zh) * 2022-07-26 2024-02-09 维沃移动通信有限公司 定时提前ta的维护方法、装置、设备及介质
CN117768071A (zh) * 2022-07-28 2024-03-26 上海朗帛通信技术有限公司 一种被用于无线通信的节点中的方法和装置
WO2024020978A1 (en) * 2022-07-29 2024-02-01 Qualcomm Incorporated Downlink reference timing determination for multiple timing advances in multi-dci/multi-trp
CN117896831A (zh) * 2022-10-14 2024-04-16 上海朗帛通信技术有限公司 一种被用于无线通信的通信节点中的方法和装置
WO2024210690A1 (ko) * 2023-04-07 2024-10-10 현대자동차주식회사 비-지상 네트워크에서 타이밍 조정을 위한 방법 및 장치

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103686772A (zh) * 2012-09-20 2014-03-26 中兴通讯股份有限公司 增强型下行控制信道的配置、检测方法及装置、基站、终端

Family Cites Families (31)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR100381968B1 (ko) * 1998-12-30 2004-03-24 주식회사 하이닉스반도체 고속동작용디램
US20140369324A1 (en) * 2012-01-20 2014-12-18 Zte Corporation Uplink signal sending method and user equipment
EP3343991B1 (en) * 2012-09-13 2020-06-24 Huawei Technologies Co., Ltd. Communication method, base station, radio communication node, and user equipment
US9681482B2 (en) * 2013-01-07 2017-06-13 Lg Electronics Inc. Method and apparatus for transmitting/receiving signals with a value indicated by a TPC command being accumulated for all parameter sets
WO2014109569A1 (ko) * 2013-01-09 2014-07-17 엘지전자 주식회사 신호 전송 방법 및 이를 위한 장치
WO2014171869A1 (en) * 2013-04-16 2014-10-23 Telefonaktiebolaget L M Ericsson (Publ) Wireless device and method for selecting uplink transmission parameters by the network and signalling explicitly with a chosen physical downlink control channel region
CN104521168B (zh) * 2013-08-01 2019-03-08 华为技术有限公司 信息配置以及数据接收的方法和设备
CN104349491A (zh) * 2013-08-08 2015-02-11 中兴通讯股份有限公司 一种物理下行共享信道传输的方法、系统和网络侧设备
CN105515721B (zh) * 2014-09-25 2020-01-07 中兴通讯股份有限公司 比特位数指示方法及装置
US11044701B2 (en) 2016-05-10 2021-06-22 Guangdong Oppo Mobile Telecommunications Corp., Ltd. Communication method and communication apparatus
JP2019125816A (ja) * 2016-05-12 2019-07-25 シャープ株式会社 端末装置および方法
CN107547179A (zh) * 2016-06-23 2018-01-05 中兴通讯股份有限公司 物理层传输参数配置、获取方法及装置
CN107548119B (zh) * 2016-06-24 2020-10-23 华硕电脑股份有限公司 用于无线通信系统中执行用户设备波束成形的方法和设备
KR102271448B1 (ko) * 2016-07-01 2021-07-01 엘지전자 주식회사 무선 통신 시스템에서 기지국과 단말 간 상향링크 신호를 송수신하는 방법 및 이를 지원하는 장치
JP2018023100A (ja) * 2016-07-22 2018-02-08 華碩電腦股▲ふん▼有限公司 無線通信システムにおいてビームフォーミングを使用した送信又は受信のための方法及び装置
EP3276851B1 (en) * 2016-07-29 2024-07-10 ASUSTek Computer Inc. Method and apparatus for channel state information report for beam operation in a wireless communication system
US11071136B2 (en) * 2016-08-25 2021-07-20 Huawei Technologies Co., Ltd. System and method for multiplexing traffic
US10708938B2 (en) * 2016-10-31 2020-07-07 Samsung Electronics Co., Ltd. Transmission of UL control channels with dynamic structures
US10455560B2 (en) * 2017-01-05 2019-10-22 Sharp Kabushiki Kaisha Short physical uplink control channel (PUCCH) design for 5th generation (5G) new radio (NR)
CN109309558B (zh) * 2017-07-28 2021-10-08 株式会社Kt 用于发送和接收上行链路信道的设备和方法
CN109495232B (zh) * 2017-08-11 2020-04-14 华为技术有限公司 发送和接收参考信号的方法、网络设备、终端设备和系统
US11678333B2 (en) * 2017-11-03 2023-06-13 Qualcomm Incorporated Methods and apparatus for bandwidth part enhancement
US10764896B2 (en) * 2017-11-08 2020-09-01 Samsung Electronics Co., Ltd. Method and apparatus for beam management in the unlicensed spectrum
US20200037247A1 (en) * 2018-07-25 2020-01-30 Mediatek Inc. Wake-up signal operation for ue power saving
CN114051705B (zh) * 2019-04-08 2024-04-26 汉尼拔Ip有限责任公司 多面板传输中推导准共位假设的方法及相关装置
US11211990B2 (en) * 2019-05-01 2021-12-28 Ofinno, Llc Beam failure recovery in multi-TRP scenarios
US11395303B2 (en) * 2019-05-02 2022-07-19 Ofinno, Llc Transmission configuration indication state partitioning in multi-beam scenarios
US11678337B2 (en) * 2019-07-18 2023-06-13 Qualcomm Incorporated Quasi co-location related priority rules for multi-downlink control information based multi-transmission/reception point
KR20210022461A (ko) * 2019-08-20 2021-03-03 삼성전자주식회사 무선 통신 시스템에서 단말의 빔 실패 회복 동작을 지시하는 방법 및 장치
US11671977B2 (en) * 2019-11-08 2023-06-06 Qualcomm Incorporated Enhanced group-CC based PDSCH and PDCCH beam update
CN115486016A (zh) * 2020-04-09 2022-12-16 三星电子株式会社 用于在无线通信系统中发送和接收信号的方法和装置

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103686772A (zh) * 2012-09-20 2014-03-26 中兴通讯股份有限公司 增强型下行控制信道的配置、检测方法及装置、基站、终端

Non-Patent Citations (4)

* Cited by examiner, † Cited by third party
Title
3GPP TS 38.331
ERICSSON: "E127-Cleaning up Common vs. Dedicated", 3GPP TSG-RAN WG2 NR AH#3, R2-1801541, 26 January 2018 (2018-01-26), Vancouver, Canada, XP051386998 *
See also references of EP3783977A4
SESSION CHAIR (SAMSUNG): "Session Notes for Agenda Item 7.1.2", 3GPP TSG RAN WGI MEETING #92, RI-1803462, 2 March 2018 (2018-03-02), Athens, Greece, XP051398764 *

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2021147119A1 (en) * 2020-01-25 2021-07-29 Qualcomm Incorporated Interference-based sounding reference signal beam determination
WO2022030819A1 (ko) * 2020-08-07 2022-02-10 엘지전자 주식회사 무선 통신 시스템에서 상향링크 송수신 방법 및 장치

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US20240306178A1 (en) 2024-09-12
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