WO2022206884A1 - Sps pdsch接收方法、装置、终端和存储介质 - Google Patents

Sps pdsch接收方法、装置、终端和存储介质 Download PDF

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Publication number
WO2022206884A1
WO2022206884A1 PCT/CN2022/084327 CN2022084327W WO2022206884A1 WO 2022206884 A1 WO2022206884 A1 WO 2022206884A1 CN 2022084327 W CN2022084327 W CN 2022084327W WO 2022206884 A1 WO2022206884 A1 WO 2022206884A1
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Prior art keywords
sps pdsch
target
tci state
determined
sps
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PCT/CN2022/084327
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English (en)
French (fr)
Inventor
王钰华
王化磊
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展讯半导体(南京)有限公司
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Publication of WO2022206884A1 publication Critical patent/WO2022206884A1/zh

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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
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W88/00Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
    • H04W88/08Access point devices

Definitions

  • the present application relates to the field of communication technologies, and in particular, to a method, apparatus, terminal and storage medium for receiving an SPS PDSCH.
  • SPS Semi-Persistent Scheduling
  • PDSCH Physical Downlink Shared Channel
  • TCI state transmission configuration indicator state
  • the embodiments of the present application provide an SPS PDSCH receiving method, device, terminal, and storage medium, which can solve the problem of how to receive the SPS PDSCH when at least part of the SPS PDSCH to be received corresponds to two TCI states when a conflict occurs.
  • an embodiment of the present application provides a method for receiving a semi-persistently scheduled physical downlink shared channel SPS PDSCH, including:
  • the first SPS PDSCH set determines the first SPS PDSCH set, where the first SPS PDSCH set is a set of conflicting SPS PDSCHs to be received;
  • the target TCI state is a TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the target SPS PDSCH is determined in the first SPS PDSCH set, and based on
  • the process of receiving the target SPS PDSCH by the target TCI state includes:
  • the one with the smallest or largest SPS configuration index value is determined as the target SPS PDSCH, and if the target SPS PDSCH corresponds to multiple TCI states, one of the multiple TCI states is determined Determine the target TCI state, and receive the target SPS PDSCH based on the target TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the target SPS PDSCH is determined in the first SPS PDSCH set, and based on
  • the process of receiving the target SPS PDSCH by the target TCI state includes:
  • the target TCI state includes a first target TCI state and a second target TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the target SPS PDSCH is determined in the first SPS PDSCH set, and based on
  • the process of receiving the target SPS PDSCH by the target TCI state includes:
  • the first target SPS PDSCH is received based on the first target TCI state
  • the second target SPS PDSCH is received based on the second target TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the target SPS PDSCH is determined in the first SPS PDSCH set, and based on
  • the process of receiving the target SPS PDSCH by the target TCI state includes:
  • Two of the multiple TCI states corresponding to the target SPS PDSCH are respectively determined as the first target TCI state and the second target TCI state;
  • the target SPS PDSCH is received based on the first target TCI state and the second target TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the target SPS PDSCH is determined in the first SPS PDSCH set, and based on
  • the process of receiving the target SPS PDSCH by the target TCI state includes:
  • the second SPS PDSCH set and the second TCI state set are determined in the first SPS PDSCH set; the second SPS PDSCH set corresponds to multiple TCIs in the first SPS PDSCH set state of the SPS PDSCH; the second TCI state set is the TCI state corresponding to the SPS PDSCH in the second SPS PDSCH set;
  • the second TCI state set includes the TCI state corresponding to the first to-be-determined SPS PDSCH, then the one with the smallest or largest SPS configuration index value in the first SPS PDSCH subset is determined as the target SPS PDSCH, Two of the multiple TCI states corresponding to the target SPS PDSCH are respectively determined as the first target TCI state and the second target TCI state, and the second SPS PDSCH set includes the first SPS PDSCH sub-state Set, the multiple TCI states corresponding to each SPS PDSCH in the first SPS PDSCH subset include the TCI state corresponding to the first to-be-determined SPS PDSCH, and the second SPS PDSCH set except the first SPS PDSCH The multiple TCI states corresponding to each SPS PDSCH in the SPS PDSCH subset do not include the TCI state corresponding to the first to-be-determined SPS PDSCH;
  • the target SPS PDSCH is received based on the first target TCI state and the second target TCI state.
  • the third SPS PDSCH set with the smallest or largest SPS configuration index value is determined as the second to-be-determined SPS PDSCH , the third SPS PDSCH set is the SPS PDSCH set other than the first SPS PDSCH to be determined in the first SPS PDSCH set;
  • the second to-be-determined SPS PDSCH corresponds to multiple TCI states, a second receiving process is performed.
  • the first receiving process includes:
  • the first SPS PDSCH to be determined is determined as the first target SPS PDSCH
  • the TCI state of the first SPS PDSCH to be determined is determined as the first target TCI state
  • the second SPS PDSCH to be determined is determined as the second target SPS PDSCH
  • the TCI state of the second to-be-determined SPS PDSCH is determined as the second target TCI state
  • the first target SPS PDSCH is received based on the first target TCI state
  • the second target SPS PDSCH is received based on the second target TCI state.
  • the first receiving process includes:
  • the second TCI state set includes the TCI state corresponding to the second to-be-determined SPS PDSCH, then determine the target SPS PDSCH with the smallest or largest SPS configuration index value in the second SPS PDSCH subset, as the target SPS PDSCH, Determining two of the multiple TCI states corresponding to the target SPS PDSCH as the first target TCI state and the second target TCI state respectively, and the second SPS PDSCH set includes the second SPS PDSCH sub-state Set, the multiple TCI states corresponding to each SPS PDSCH in the second SPS PDSCH subset include the TCI state corresponding to the second to-be-determined SPS PDSCH, except the second SPS PDSCH set in the second SPS PDSCH set.
  • the multiple TCI states corresponding to each SPS PDSCH in the SPS PDSCH subset do not include the TCI state corresponding to the second to-be-determined SPS PDSCH;
  • the target SPS PDSCH is received based on the first target TCI state and the second target TCI state.
  • the second receiving process includes:
  • the second to-be-determined SPS PDSCH is determined as the target SPS PDSCH, and two of the multiple TCI states corresponding to the second to-be-determined SPS PDSCH are respectively determined as the first target TCI state and the first target TCI state.
  • the target SPS PDSCH is received based on the first target TCI state and the second target TCI state.
  • the second receiving process includes:
  • the first SPS PDSCH to be determined as the first target SPS PDSCH determines the TCI state corresponding to the first SPS PDSCH to be determined as the first target TCI state, determine the second SPS PDSCH to be determined For the second target SPS PDSCH, one of the multiple TCI states corresponding to the second to-be-determined SPS PDSCH is determined as the second target TCI state;
  • the first target SPS PDSCH is received based on the first target TCI state
  • the second target SPS PDSCH is received based on the second target TCI state.
  • the process of judging whether the first to-be-determined SPS PDSCH corresponds to one TCI state or multiple TCI states further includes:
  • the first to-be-determined SPS PDSCH corresponds to multiple TCI states
  • the first to-be-determined SPS PDSCH is determined to be the target SPS PDSCH, and the first to-be-determined SPS PDSCH corresponds to the multiple TCI states.
  • the two are respectively determined as the first TCI state and the second TCI state;
  • the target SPS PDSCH is received based on the first TCI state and the second TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the target SPS PDSCH is determined in the first SPS PDSCH set, and based on
  • the process of receiving the target SPS PDSCH by the target TCI state includes:
  • the second SPS PDSCH set is the SPS PDSCH set corresponding to multiple TCI states
  • the TCI state corresponding to the first target SPS PDSCH is determined as the first target TCI state
  • the first TCI state corresponding to the first target SPS PDSCH is determined as the first target TCI state
  • the first target SPS PDSCH is received based on the first target TCI state
  • the second target SPS PDSCH is received based on the second target TCI state.
  • one of the multiple TCI states is the first TCI state, the last TCI state, the one with the smallest TCI state index value, or the one with the largest TCI state index value.
  • the combination of two of the plurality of TCI states is any one of the following:
  • the combination of the first TCI state and the second TCI state, the combination of the penultimate TCI state and the penultimate TCI state, the combination of the first TCI state and the penultimate TCI state, the minimum TCI state index value The combination of the one with the second smallest TCI state index value, the combination of the one with the largest TCI state index value and the one with the second largest TCI state index value, the one with the smallest TCI state index value and the TCI state index value A combination of the largest one.
  • an embodiment of the present application provides a semi-persistent scheduling physical downlink shared channel SPS PDSCH receiving apparatus, including:
  • a first determining module configured to determine a first SPS PDSCH set according to a high-level parameter, where the first SPS PDSCH set is a set of conflicting SPS PDSCHs to be received;
  • the second determination module is configured to determine the SPS configuration index value, the transmission configuration indication state TCI state and the TCI state index value corresponding to each SPS PDSCH according to the high-level parameters, and at least one SPS PDSCH in the first SPS PDSCH set corresponds to more a TCI state;
  • a receiving module configured to determine the target TCI state in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and determine the target SPS PDSCH in the first SPS PDSCH set, and receive based on the target TCI state the target SPS PDSCH.
  • an embodiment of the present application provides a semi-persistent scheduling physical downlink shared channel SPS PDSCH receiving device, including:
  • a processor and a memory where the memory is used to store at least one instruction, and when the instruction is loaded and executed by the processor, the above-mentioned SPS PDSCH receiving method is implemented.
  • an embodiment of the present application provides a terminal, including the SPS PDSCH receiving apparatus of the second aspect or the third aspect.
  • an embodiment of the present application provides a computer-readable storage medium, where a computer program is stored in the computer-readable storage medium, and when it runs on a computer, the computer executes the above-mentioned SPS PDSCH receiving method.
  • the SPS PDSCH can be solved by determining the target TCI state and the target SPS PDSCH in the conflicting SPS PDSCHs to be received, and receiving the target SPS PDSCH based on the target TCI state.
  • FIG. 1 is a flowchart of a method for receiving an SPS PDSCH in an embodiment of the application
  • FIG. 2 is a schematic diagram of a first SPS PDSCH set in an embodiment of the application
  • FIG. 3 is a schematic diagram of an SPS PDSCH to be received in a first time slot in an embodiment of the application
  • Fig. 4 is a kind of concrete flow chart of step 103 in Fig. 1;
  • FIG. 5 is a schematic diagram of another first SPS PDSCH set in an embodiment of the present application.
  • Fig. 6 is another specific flow chart of step 103 in Fig. 1;
  • Fig. 7 is another specific flow chart of step 103 in Fig. 1;
  • Fig. 8 is another specific flow chart of step 103 in Fig. 1;
  • FIG. 9 is a schematic diagram of another first SPS PDSCH set in an embodiment of the present application.
  • Fig. 10 is a specific schematic diagram of the first receiving process in Fig. 8.
  • FIG. 11 is a schematic diagram of another first SPS PDSCH set in an embodiment of the application.
  • Fig. 12 is another specific schematic diagram of the first receiving process in Fig. 8;
  • Fig. 13 is another specific schematic diagram of the first receiving process in Fig. 8;
  • FIG. 14 is a schematic diagram of another first SPS PDSCH set in an embodiment of the application.
  • Fig. 15 is a specific schematic diagram of the second receiving process in Fig. 8.
  • 16 is a schematic diagram of another first SPS PDSCH set in an embodiment of the application.
  • Fig. 17 is another specific schematic diagram of the second receiving process in Fig. 8;
  • FIG. 18 is a schematic diagram of another first SPS PDSCH set in an embodiment of the present application.
  • Fig. 19 is another specific flow chart of step 103 in Fig. 1;
  • FIG. 20 is a schematic diagram of another first SPS PDSCH set in an embodiment of the application.
  • FIG. 21 is a structural block diagram of an apparatus for receiving an SPS PDSCH in an embodiment of the present application.
  • an embodiment of the present application provides a semi-persistent scheduling physical downlink shared channel SPS PDSCH receiving method, including:
  • Step 101 determine the first SPS PDSCH set, the first SPS PDSCH set is a set of conflicting SPS PDSCHs to be received; wherein, high-level parameters can be configured by, for example, Radio Resource Control (RRC), or Medium Access Control (Medium Access Control, MAC)-Control Element (Control Element, CE) configuration, or Downlink Control Information (Downlink Control Information, DCI) indication, which is not specifically limited.
  • RRC Radio Resource Control
  • MAC Medium Access Control
  • CE Control Element
  • DCI Downlink Control Information
  • Step 102 determine the SPS configuration index value, transmission configuration indication state TCI state and TCI state index value corresponding to each SPS PDSCH, at least one SPS PDSCH in the first SPS PDSCH set corresponds to multiple TCI states;
  • FIG. 2 an example of a first SPS PDSCH set is illustrated in FIG. 2, where the number after "#" represents the SPS configuration index value (Config Index), the brackets represent the TCI state corresponding to the SPS PDSCH, and the number after the TCI Indicates the index value of the TCI state, where the SPS PDSCH without padding corresponds to one TCI state, and the SPS PDSCH with padding corresponds to two TCI states.
  • Config Index SPS configuration index value
  • Step 103 Determine the target TCI state in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and determine the target SPS PDSCH in the first SPS PDSCH set, and receive the target SPS PDSCH based on the target TCI state.
  • step 101 first determine an SPS PDSCH among the SPS PDSCHs to be received in a time slot as shown in FIG. 3, for example, use the SPS PDSCH#0 with the smallest SPS configuration index value as the determined SPS PDSCH SPS PDSCH, the set of the SPS PDSCH#0 and other SPS PDSCHs that conflict with the SPS PDSCH#0 in the time slot is determined as the first SPS PDSCH set as shown in FIG. 2 . Then, for the first SPS PDSCH set, the target SPS PDSCH to be received is determined based on steps 102 and 103.
  • SPS PDSCH#0 is the target SPS PDSCH and TCI1 is the target TCI state
  • SPS PDSCH#0 can be received based on TCI1, wherein the TCI state is used to determine the beam direction for receiving the SPS PDSCH.
  • the target SPS PDSCH can be selected for reception to solve the problem of SPS PDSCH conflict.
  • the first SPS PDSCH set composed of SPS PDSCH#0, SPS PDSCH#1, SPS PDSCH#3, SPS PDSCH#5 and SPS PDSCH#7 in FIG. 3 is determined.
  • another SPS PDSCH other than SPS PDSCH#0, SPS PDSCH#1, SPS PDSCH#3, SPS PDSCH#5 and SPS PDSCH#7 can be determined in the time slot.
  • One SPS PDSCH that is, among the remaining SPS PDSCHs of SPS PDSCH#8, SPS PDSCH#9, and SPS PDSCH#10, the SPS PDSCH#8 with the smallest SPS configuration index value is used as the determined SPS PDSCH, and the SPS PDSCH#8 And the SPS PDSCH conflicting with SPS PDSCH#8 is determined as the new first SPS PDSCH set, and the target TCI state and the target SPS PDSCH are determined and received according to the same method, and so on.
  • the SPS PDSCH receiving method in the embodiment of the present application by determining the target TCI state and the target SPS PDSCH in the conflicting SPS PDSCHs to be received, and receiving the target SPS PDSCH based on the target TCI state, how to receive the SPS when the SPS PDSCH conflict can be solved Problems with PDSCH.
  • the target TCI state is a TCI state. If the terminal only supports receiving beams in one direction at the same time, it can receive the target SPS PDSCH based on one TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and the first SPS PDSCH
  • the process of determining the target SPS PDSCH in the PDSCH set and receiving the target SPS PDSCH based on the target TCI state includes:
  • Step 201 in the first SPS PDSCH set, determine the one with the smallest or largest SPS configuration index value as the target SPS PDSCH;
  • Step 202 determine whether the target SPS PDSCH corresponds to one TCI state or multiple TCI states, if the target SPS PDSCH corresponds to one TCI state, then enter step 203, if the target SPS PDSCH corresponds to multiple TCI states, then enter step 204;
  • Step 203 determine the TCI corresponding to the target SPS PDSCH as the target TCI state, and receive the target SPS PDSCH based on the target TCI state;
  • Step 204 Determine one of the multiple TCI states as the target TCI state, and receive the target SPS PDSCH based on the target TCI state.
  • step 201 it is assumed that the one with the smallest SPS configuration index value is determined as the target SPS PDSCH according to a preset rule, that is, SPS PDSCH#0 If it is determined to be the target SPS PDSCH, then in step 202, it is determined that SPS PDSCH#0 corresponds to TCI1, that is, only corresponds to one TCI state, so step 203 is entered, and SPS PDSCH#0 is received based on TCI1 corresponding to SPS PDSCH#0.
  • a preset rule that is, SPS PDSCH#0
  • step 201 it is assumed that the one with the smallest SPS configuration index value is determined as the target SPS PDSCH according to a preset rule, that is, SPS PDSCH #0 is determined as The target SPS PDSCH, then in step 202, it is determined that SPS PDSCH#0 corresponds to TCI2 and TCI3, that is, corresponding to two TCI states, so step 204 is entered, and one of the TCI2 and TCI3 is determined as the target TCI state according to preset rules, for example, according to The preset rule determines the one with the smallest TCI state index value as the target TCI state.
  • a preset rule that is, SPS PDSCH #0 is determined as The target SPS PDSCH
  • the preset The rule can also be other rules, for example, the one with the largest TCI state index value among multiple TCI states, the first TCI state or the last TCI state is determined as the target TCI state.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set
  • the process of determining the target SPS PDSCH in the first SPS PDSCH set, and receiving the target SPS PDSCH based on the target TCI state includes: the SPS configuration index value of the SPS PDSCH corresponding to a TCI state in the first SPS PDSCH set is the smallest or the largest one.
  • the target SPS PDSCH is determined as the target SPS PDSCH
  • the TCI state corresponding to the target SPS PDSCH is determined as the target TCI state
  • the target SPS PDSCH is received based on the target TCI state.
  • the SPS PDSCH corresponding to a TCI state in the first SPS PDSCH set are SPS PDSCH#1, SPS PDSCH#3 and SPS PDSCH#5, assuming that the The one with the smallest SPS configuration index value is determined as the target SPS PDSCH, that is, the SPS PDSCH#1 is determined as the target SPS PDSCH, the TCI4 corresponding to the SPS PDSCH#1 is determined as the target TCI state, and the SPS PDSCH#1 is received based on TCI4. That is to say, in this embodiment, SPS PDSCHs corresponding to multiple TCI states are excluded, and a target SPS PDSCH and a corresponding target TCI state are determined in the remaining SPS PDSCHs to receive.
  • the target TCI state includes a first target TCI state and a second target TCI state. If the terminal supports receiving beams in both directions at the same time, it can receive the target SPS PDSCH based on the two TCI states.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and in the first SPS PDSCH set.
  • the process of determining the target SPS PDSCH and receiving the target SPS PDSCH based on the target TCI state includes:
  • Step 301 Determine the one with the smallest or largest SPS configuration index value in the SPS PDSCH corresponding to a TCI state in the first SPS PDSCH set as the first target SPS PDSCH, and determine the TCI state corresponding to the first target SPS PDSCH as the first target SPS PDSCH.
  • target TCI state
  • Step 302 Determine the one with the smallest or largest SPS configuration index value in the SPS PDSCH corresponding to a TCI state except the first target SPS PDSCH in the first SPS PDSCH set as the second target SPS PDSCH, and the second target SPS PDSCH The TCI state corresponding to the PDSCH is determined as the second target TCI state;
  • Step 303 Receive the first target SPS PDSCH based on the first target TCI state, and receive the second target SPS PDSCH based on the second target TCI state.
  • the SPS PDSCH #1 with the smallest SPS configuration index value among the unfilled SPS PDSCHs in FIG. 5 is determined as the first target SPS PDSCH, and its corresponding The TCI4 is determined as the first target TCI state
  • the SPS PDSCH#3 with the smallest SPS configuration index value in the remaining unfilled SPS PDSCH is determined as the second target SPS PDSCH
  • its corresponding TCI1 is determined as the second target TCI state, based on TCI4 receives SPS PDSCH#1, and receives SPS PDSCH#3 based on TCI1. That is to say, in this embodiment, SPS PDSCHs corresponding to multiple TCI states are excluded, and two target SPS PDSCHs and two corresponding target TCI states are determined in the remaining SPS PDSCHs to receive.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and in the first SPS PDSCH set.
  • the process of determining the target SPS PDSCH and receiving the target SPS PDSCH based on the target TCI state includes:
  • Step 401 Determine the one with the smallest or largest SPS configuration index value in the SPS PDSCH corresponding to multiple TCI states in the first SPS PDSCH set as the target SPS PDSCH;
  • Step 402 determine two of the multiple TCI states corresponding to the target SPS PDSCH as the first target TCI state and the second target TCI state respectively;
  • Step 403 Receive the target SPS PDSCH based on the first target TCI state and the second target TCI state.
  • the SPS PDSCH#3 with the smallest SPS configuration index value among the filled SPS PDSCHs in FIG. 2 is determined as the target SPS PDSCH, and the SPS PDSCH#3
  • the corresponding TCI2 and TCI3 are respectively determined as the first target TCI state and the second target TCI state, wherein, the determination method of the two target TCI states in the multiple TCI states may be, for example, the first TCI state and the last TCI state respectively.
  • two target TCI states can be determined from a plurality of TCI states according to other preset rules, and SPS PDSCH#3 is received based on TCI2 and TCI3. That is to say, in this embodiment, one target SPS PDSCH and two corresponding target TCI states are determined in the SPS PDSCH corresponding to multiple TCI states to receive.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and in the first SPS PDSCH set.
  • the process of determining the target SPS PDSCH and receiving the target SPS PDSCH based on the target TCI state includes:
  • Step 501 determining the one with the smallest or largest SPS configuration index value in the first SPS PDSCH set as the first SPS PDSCH to be determined;
  • Step 502 determine whether the first SPS PDSCH to be determined corresponds to one TCI state or multiple TCI states; if the first SPS PDSCH to be determined corresponds to one TCI state, then enter step 503;
  • Step 503 Determine the second SPS PDSCH set and the second TCI state set in the first SPS PDSCH set; the second SPS PDSCH set is the SPS PDSCH corresponding to multiple TCI states in the first SPS PDSCH set; the second TCI state set is The TCI state corresponding to the SPS PDSCH in the second SPS PDSCH set, and then enter step 504;
  • Step 504 determine whether the second TCI state set includes the TCI state corresponding to the first SPS PDSCH to be determined; if so, that is, if the second TCI state set includes the TCI state corresponding to the first SPS PDSCH to be determined, then enter step 505;
  • Step 505 Determine the one with the smallest or largest SPS configuration index value in the first SPS PDSCH subset as the target SPS PDSCH, and determine two of the multiple TCI states corresponding to the target SPS PDSCH as the first target TCI state and The second target TCI state, the second SPS PDSCH set includes the first SPS PDSCH subset, and the multiple TCI states corresponding to each SPS PDSCH in the first SPS PDSCH subset include the TCI state corresponding to the first SPS PDSCH to be determined, In the second SPS PDSCH set, the multiple TCI states corresponding to each SPS PDSCH except the first SPS PDSCH subset do not include the TCI state corresponding to the first SPS PDSCH to be determined, and then enter step 506;
  • Step 506 Receive the target SPS PDSCH based on the first target TCI state and the second target TCI state.
  • step 501 the SPS PDSCH #0 with the smallest SPS configuration index value in FIG. 2 is determined as the first SPS PDSCH to be determined, and then in step 502 It is judged that SPS PDSCH#0 only corresponds to TCI1, that is, corresponds to a TCI state. According to the judgment result, step 503 is entered. In step 503, the second SPS PDSCH set and the second TCI state set are determined.
  • the second SPS PDSCH set is filled with SPS PDSCH is composed of SPS PDSCH#7 and SPS PDSCH#3, and the second TCI state set is composed of TCI states corresponding to the filled SPS PDSCH, namely TCI1, TCI3 and TCI4, and then enters step 504, in step 504 to determine the first Two TCI state sets include TCI1.
  • the first SPS PDSCH subset is composed of SPS PDSCH#7 and SPS PDSCH#3, and TCI4 and TCI1 corresponding to SPS PDSCH#7 include TCI1 corresponding to SPS PDSCH#0, and SPS TCI1 and TCI3 corresponding to PDSCH#3 include TCI1 corresponding to SPS PDSCH#0.
  • the first SPS PDSCH subset is exactly the same as the second SPS PDSCH set.
  • step 502 after the process of judging whether the first to-be-determined SPS PDSCH corresponds to one TCI state or multiple TCI states, it also includes: if the first to-be-determined SPS PDSCH corresponds to one TCI state or multiple TCI states SPS PDSCH corresponds to multiple TCI states, then enter step 506;
  • Step 507 determining the first SPS PDSCH to be determined as the target SPS PDSCH, and determining two of the multiple TCI states corresponding to the first SPS PDSCH to be determined as the first TCI state and the second TCI state;
  • Step 508 Receive the target SPS PDSCH based on the first TCI state and the second TCI state.
  • the SPS PDSCH#0 with the smallest SPS configuration index value is determined as the target SPS PDSCH, and in step 502, it is determined that the SPS PDSCH#0 corresponds to TCI2 and TCI3 correspond to multiple TCI states, respectively determine TCI2 and TCI3 as the first target TCI state and the second target TCI state, and receive SPS PDSCH#0 based on TCI2 and TCI3.
  • step 504 is entered to determine whether the second TCI state set contains the first to-be-determined SPS PDSCH corresponding to the After the process of the TCI state, it also includes: if no, that is, if the second TCI state set does not contain the TCI state corresponding to the first to be determined SPS PDSCH, then enter step 509;
  • Step 509 Determine the one with the smallest or largest SPS configuration index value in the third SPS PDSCH set as the second to-be-determined SPS PDSCH, and the third SPS PDSCH set is the first SPS PDSCH set except for the first to-be-determined SPS PDSCH. the SPS PDSCH set;
  • Step 510 determine whether the second to-be-determined SPS PDSCH corresponds to one TCI state or multiple TCI states; if the second to-be-determined SPS PDSCH corresponds to one TCI state, execute the first receiving process; if the second to-be-determined SPS PDSCH corresponds to multiple TCI states state, the second receiving process is executed.
  • the first receiving process includes:
  • Step 601 Determine the first SPS PDSCH to be determined as the first target SPS PDSCH, determine the TCI state of the first SPS PDSCH to be determined as the first target TCI state, and determine the second SPS PDSCH to be determined as the second target SPS PDSCH , the TCI state of the second to-be-determined SPS PDSCH is determined as the second target TCI state;
  • Step 602 Receive the first target SPS PDSCH based on the first target TCI state, and receive the second target SPS PDSCH based on the second target TCI state.
  • step 501 the SPS PDSCH #0 with the smallest SPS configuration index value in FIG. 11 is determined as the first SPS PDSCH to be determined, and then in step 502 It is judged that SPS PDSCH#0 only corresponds to TCI1, that is, corresponds to a TCI state. According to the judgment result, enter step 503 to determine the second SPS PDSCH set and the second TCI state set, and the second SPS PDSCH set is composed of filled SPS PDSCH.
  • the second TCI state set is composed of the TCI states corresponding to the filled SPS PDSCH, namely TCI2, TCI3 and TCI4, and then enters step 504, and judges the second TCI state set in step 504.
  • Does not contain TCI1 enter step 509, determine SPS PDSCH#1 with the smallest SPS configuration index value in SPS PDSCH except SPS PDSCH#0 as the second SPS PDSCH to be determined, and then judge SPS PDSCH in step 510 #1 corresponds to TCI4, that is, only corresponds to one TCI state, and executes the first receiving process.
  • step 601 SPS PDSCH#0 is determined as the first target SPS PDSCH, TCI1 is determined as the first target TCI state, and SPS PDSCH# 1 is determined as the second target SPS PDSCH, and TCI4 is determined as the second target TCI state, and in step 602, SPS PDSCH#0 is received based on TCI1, and SPS PDSCH#1 is received based on TCI4.
  • the first receiving process includes: if the second TCI state set includes the TCI state corresponding to the second to-be-determined SPS PDSCH, then Enter step 701;
  • Step 701 Determine the one with the smallest or largest SPS configuration index value in the second SPS PDSCH subset as the target SPS PDSCH, and determine two of the multiple TCI states corresponding to the target SPS PDSCH as the first target TCI state and The second target TCI state, the second SPS PDSCH set includes the second SPS PDSCH subset, and the multiple TCI states corresponding to each SPS PDSCH in the second SPS PDSCH subset include the second TCI state corresponding to the SPS PDSCH to be determined, The multiple TCI states corresponding to each SPS PDSCH in the second SPS PDSCH set except the second SPS PDSCH subset do not include the TCI state corresponding to the second SPS PDSCH to be determined;
  • Step 702 Receive the target SPS PDSCH based on the first target TCI state and the second target TCI state.
  • the second TCI state set may include the TCI state corresponding to the second to-be-determined SPS PDSCH through configuration on the network side.
  • the first receiving process may include:
  • Step 703 determine whether the second TCI state set contains the TCI state corresponding to the second to-be-determined SPS PDSCH, and if so, that is, if the second TCI state set contains the second to-be-determined SPS PDSCH corresponding to the TCI state, then enter step 701 , if no, that is, if the second TCI state set does not contain the TCI state corresponding to the second to-be-determined SPS PDSCH, then enter step 601 and step 602, the specific process of step 601 and step 602 is the same as the above-mentioned embodiment, and does not Repeat. For example, if the current first SPS PDSCH set is shown in FIG.
  • step 501 determine the SPS PDSCH #0 with the smallest SPS configuration index value in FIG. 14 as the first SPS PDSCH to be determined, and then determine the SPS in step 502 PDSCH#0 only corresponds to TCI1, that is, corresponds to a TCI state. According to the judgment result, go to step 503.
  • step 503 determine the second SPS PDSCH set and the second TCI state set.
  • the second SPS PDSCH set is composed of filled SPS PDSCH.
  • the second TCI state set consists of the TCI states corresponding to the filled SPS PDSCH, namely TCI2 and TCI4, and then enters step 504, in step 504, it is judged that in the second TCI state set Do not include TCI1, enter step 509, determine SPS PDSCH#1, which has the smallest SPS configuration index value in SPS PDSCH except SPS PDSCH#0, as the second to-be-determined SPS PDSCH, and then judge SPS PDSCH# in step 510 1 corresponds to TCI4, that is, only corresponds to one TCI state, and executes the first receiving process.
  • SPS PDSCH#0 is determined as the first target SPS
  • TCI1 is determined as the first target TCI state
  • the second SPS PDSCH subset is composed of SPS PDSCH#4 and SPS PDSCH#7
  • TCI2 and TCI4 corresponding to SPS PDSCH#4 include TCI4
  • TCI4 and TCI4 corresponding to SPS PDSCH#7 TCI2 includes TCI4.
  • the second SPS PDSCH subset is exactly the same as the second SPS PDSCH set.
  • the second SPS PDSCH set except The multiple TCI states corresponding to each SPS PDSCH in the second SPS PDSCH subset do not contain TCI4, and the SPS PDSCH# with the smallest SPS configuration index value in SPS PDSCH#7 and SPS PDSCH#4 (the second SPS PDSCH subset) 4.
  • Determine as the target SPS PDSCH determine its corresponding TCI4 and TCI2 as the first target TCI state and the second target TCI state respectively, and receive SPS PDSCH#4 based on TCI4 and TCI2 in step 702.
  • the second receiving process includes:
  • Step 801 determining the second SPS PDSCH to be determined as the target SPS PDSCH, and determining two of the multiple TCI states corresponding to the second SPS PDSCH to be determined as the first target TCI state and the second target TCI state respectively;
  • Step 802 Receive the target SPS PDSCH based on the first target TCI state and the second target TCI state.
  • step 501 the SPS PDSCH #0 with the smallest SPS configuration index value in FIG. 16 is determined as the first SPS PDSCH to be determined, and then in step 502 It is judged that SPS PDSCH#0 only corresponds to TCI1, that is, corresponds to a TCI state. According to the judgment result, enter step 503 to determine the second SPS PDSCH set and the second TCI state set, and the second SPS PDSCH set is composed of filled SPS PDSCH. That is, SPS PDSCH#7 and SPS PDSCH#1, the second TCI state set consists of padded
  • the TCI state corresponding to the SPS PDSCH is composed of TCI3 and TCI4, and then enters step 504, in step 504, it is judged that the second TCI state set does not contain TCI1, and enters step 509, the SPS PDSCH in the SPS PDSCH except SPS PDSCH#0
  • One SPS PDSCH#1 with the smallest configuration index value is determined as the second to-be-determined SPS PDSCH, then in step 510, it is judged that the SPS PDSCH#1 corresponds to TCI3 and TCI4, that is, corresponding to multiple TCI states, and the second receiving process is performed, in step 510
  • the SPS PDSCH#1 is determined as the target SPS PDSCH
  • the corresponding TCI3 and TCI4 are respectively determined as the first target TCI state and the second target TCI state
  • the SPS PDSCH#1 is received based on TCI3 and TCI4.
  • the second receiving process includes:
  • Step 901 Determine the first SPS PDSCH to be determined as the first target SPS PDSCH, determine the TCI state corresponding to the first SPS PDSCH to be determined as the first target TCI state, and determine the second SPS PDSCH to be determined as the second target SPS PDSCH, one of the multiple TCI states corresponding to the second to-be-determined SPS PDSCH is determined as the second target TCI state;
  • Step 902 Receive the first target SPS PDSCH based on the first target TCI state, and receive the second target SPS PDSCH based on the second target TCI state.
  • step 501 the SPS PDSCH #0 with the smallest SPS configuration index value in FIG. 18 is determined as the first SPS PDSCH to be determined, and then in step 502 It is judged that SPS PDSCH#0 only corresponds to TCI1, that is, corresponds to a TCI state. According to the judgment result, enter step 503 to determine the second SPS PDSCH set and the second TCI state set, and the second SPS PDSCH set is composed of filled SPS PDSCH.
  • the second TCI state set is composed of TCI states corresponding to the filled SPS PDSCH, namely TCI2 and TCI3, and then enters step 504, in step 504, it is judged that the second TCI state set is not in the Including TCI1, enter step 509, determine SPS PDSCH#1, which has the smallest SPS configuration index value in SPS PDSCH except SPS PDSCH#0, as the second SPS PDSCH to be determined, and then judge SPS PDSCH#1 in step 510 Corresponding to TCI2 and TCI3, that is, corresponding to a plurality of TCI states, the second receiving process is performed.
  • step 901 SPS PDSCH#0 is determined as the first target SPS PDSCH, and its corresponding TCI1 is determined as the first target TCI state, and the SPS PDSCH#1 is determined as the second target SPS PDSCH, and one of the corresponding multiple TCI states, such as TCI2, is determined as the second target TCI state, in step 902, SPS PDSCH#0 is received based on TCI1, and received based on TCI2 SPS PDSCH #1.
  • the target TCI state is determined in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and in the first SPS PDSCH set
  • the process of determining the target SPS PDSCH and receiving the target SPS PDSCH based on the target TCI state includes:
  • Step 1011 Determine the one with the smallest or largest SPS configuration index value in the first SPS PDSCH set as the first target SPS PDSCH, and determine the one with the smallest or largest SPS configuration index value in the second SPS PDSCH set as the second target.
  • SPS PDSCH, the second SPS PDSCH set is the SPS PDSCH set corresponding to multiple TCI states;
  • Step 1012 determining the last TCI state corresponding to the second target SPS PDSCH as the second target TCI state
  • Step 1013 determine whether the first target SPS PDSCH corresponds to one TCI state or multiple TCI states, if the first target SPS PDSCH corresponds to one TCI state, then enter step 1014, if the first target SPS PDSCH corresponds to multiple TCI states, then enter the step 1015;
  • Step 1014 determine the TCI state corresponding to the first target SPS PDSCH as the first target TCI state, and then enter step 1016;
  • Step 1015 determine the first TCI state corresponding to the first target SPS PDSCH as the first target TCI state, and then enter step 1016;
  • Step 1016 Receive the first target SPS PDSCH based on the first target TCI state, and receive the second target SPS PDSCH based on the second target TCI state.
  • the SPS PDSCH #0 with the smallest SPS configuration index value is determined as the first target SPS PDSCH, and the SPS PDSCH in the padded SPS PDSCH will be filled with SPS PDSCH #0.
  • the SPS PDSCH#1 with the smallest configuration index value is determined as the second target SPS PDSCH, and in step 1012, the last TCI state corresponding to the SPS PDSCH#1 is determined as the second target TCI state, that is, TCI3 is determined as the second target TCI state, In step 1013, it is judged that SPS PDSCH#0 corresponds to TCI1, that is, it corresponds to a TCI state, then go to step 1014, determine its corresponding TCI1 as the first target TCI state, then go to step 1016, receive SPS PDSCH#0 based on TCI1, and based on TCI3 SPS PDSCH#1 is received.
  • one of the multiple TCI states in step 204 or step 901 is the first TCI state, the last TCI state, the one with the smallest TCI state index value, or the largest TCI state index value one of.
  • the target TCI state may be determined according to one of these four rules
  • the second target TCI state may be determined according to one of these four rules.
  • the combination of two of the multiple TCI states is any one of the following: the first TCI The combination of state and the second TCI state, the combination of the penultimate TCI state and the penultimate TCI state, the combination of the first TCI state and the penultimate TCI state, the one with the smallest TCI state index value, and The combination of the one with the second smallest TCI state index value, the one with the largest TCI state index value and the one with the second largest TCI state index value, the one with the smallest TCI state index value, and the one with the largest TCI state index value The combination.
  • the two TCI states determined according to one of the above combinations may be used as the first target TCI state and the second target TCI state, respectively.
  • an embodiment of the present application further provides a semi-persistent scheduling physical downlink shared channel SPS PDSCH receiving apparatus, including: a first determining module 1, configured to determine a first SPS PDSCH set according to high-level parameters, a first SPS PDSCH set, and a first SPS PDSCH set.
  • a first determining module 1 configured to determine a first SPS PDSCH set according to high-level parameters, a first SPS PDSCH set, and a first SPS PDSCH set.
  • the PDSCH set is a set of conflicting SPS PDSCHs to be received;
  • the second determination module 2 is used to determine the SPS configuration index value, the transmission configuration indication state TCI state and the TCI state index value corresponding to each SPS PDSCH according to the high-level parameters, and the first At least one SPS PDSCH in an SPS PDSCH set corresponds to multiple TCI states;
  • the receiving module 3 is used to determine the target TCI state in the TCI state corresponding to the SPS PDSCH in the first SPS PDSCH set, and in the first SPS PDSCH set Determine the target SPS PDSCH, and receive the target SPS PDSCH based on the target TCI state.
  • the SPS PDSCH receiving apparatus may apply the SPS PDSCH receiving method in the above-mentioned embodiment, and the specific process and principle are the same as those in the above-mentioned embodiment, which will not be repeated here.
  • the above division of the SPS PDSCH receiving apparatus shown in FIG. 21 is only a division of logical functions, and in actual implementation, all or part of it may be integrated into one physical entity, or it may be physically separated.
  • these modules can all be implemented in the form of software calling through processing elements; they can also all be implemented in hardware; some modules can also be implemented in the form of software calling through processing elements, and some modules can be implemented in hardware.
  • any one of the first determining module 1, the second determining module 2 and the receiving module 3 may be a separately established processing element, or may be integrated in the SPS PDSCH receiving apparatus, for example, integrated in one of the SPS PDSCH receiving apparatuses
  • it can also be stored in the memory of the SPS PDSCH receiving device in the form of a program, and is called by a certain processing element of the SPS PDSCH receiving device and executes the functions of the above modules.
  • the implementation of other modules is similar.
  • all or part of these modules can be integrated together, and can also be implemented independently.
  • the processing element described here may be an integrated circuit with signal processing capability.
  • each step of the above-mentioned method or each of the above-mentioned modules can be completed by an integrated logic circuit of hardware in the processor element or an instruction in the form of software.
  • the modules of the first determination module 1, the second determination module 2 and the receiving module 3 may be one or more integrated circuits configured to implement the above method, for example: one or more specific integrated circuits (Application Specific Integrated Circuit, ASIC), or, one or more microprocessors (digital singnal processor, DSP), or, or, one or more Field Programmable Gate Array (Field Programmable Gate Array, FPGA), etc.
  • ASIC Application Specific Integrated Circuit
  • DSP digital singnal processor
  • FPGA Field Programmable Gate Array
  • the processing element may be a general-purpose processor, such as a central processing unit (Central Processing Unit, CPU) or other processors that can invoke programs.
  • these modules can be integrated together and implemented in the form of a system-on-a-chip (SOC).
  • SOC system-on-a-chip
  • the target TCI state is a TCI state.
  • the receiving module 3 is specifically configured to determine, in the first SPS PDSCH set, the one with the smallest or largest SPS configuration index value as the target SPS PDSCH, if the target SPS PDSCH corresponds to multiple TCI states, Then, one of the multiple TCI states is determined as the target TCI state, and the target SPS PDSCH is received based on the target TCI state.
  • the receiving module 3 is specifically configured to determine the one with the smallest or largest SPS configuration index value among the SPS PDSCHs corresponding to a TCI state in the first SPS PDSCH set as the target SPS PDSCH, and the target SPS PDSCH The TCI state corresponding to the PDSCH is determined as the target TCI state, and the target SPS PDSCH is received based on the target TCI state.
  • the target TCI state includes a first target TCI state and a second target TCI state.
  • the receiving module 3 is specifically configured to determine the one with the smallest or largest SPS configuration index value among the SPS PDSCHs corresponding to a TCI state in the first SPS PDSCH set as the first target SPS PDSCH, and The TCI state corresponding to the first target SPS PDSCH is determined as the first target TCI state; the one with the smallest or largest SPS configuration index value in the SPS PDSCH corresponding to a TCI state except the first target SPS PDSCH in the first SPS PDSCH set is determined.
  • the second target SPS PDSCH is determined as the second target SPS PDSCH, and the TCI state corresponding to the second target SPS PDSCH is determined as the second target TCI state; the first target SPS PDSCH is received based on the first target TCI state, and the second target is received based on the second target TCI state.
  • SPS PDSCH is determined as the second target SPS PDSCH, and the TCI state corresponding to the second target SPS PDSCH is determined as the second target TCI state; the first target SPS PDSCH is received based on the first target TCI state, and the second target is received based on the second target TCI state.
  • the receiving module 3 is specifically configured to determine the one with the smallest or largest SPS configuration index value among the SPS PDSCHs corresponding to multiple TCI states in the first SPS PDSCH set as the target SPS PDSCH; Two of the multiple TCI states corresponding to the SPS PDSCH are respectively determined as the first target TCI state and the second target TCI state; the target SPS PDSCH is received based on the first target TCI state and the second target TCI state.
  • the receiving module 3 is specifically configured to determine the one with the smallest or largest SPS configuration index value in the first SPS PDSCH set as the first to-be-determined SPS PDSCH; determine that the first to-be-determined SPS PDSCH corresponds to One TCI state or multiple TCI states; if the first SPS PDSCH to be determined corresponds to one TCI state, the second SPS PDSCH set and the second TCI state set are determined in the first SPS PDSCH set; the second SPS PDSCH set is the first SPS The SPS PDSCH corresponding to multiple TCI states in the PDSCH set; the second TCI state set is the TCI state corresponding to the SPS PDSCH in the second SPS PDSCH set; determine whether the second TCI state set includes the first pending SPS PDSCH Corresponding TCI state; if the second TCI state set includes the TCI state corresponding to the first to-be-determined SPS PDSCH, then the one with the smallest or largest SPS configuration
  • the receiving module 3 is further configured to, if the second TCI state set does not contain the TCI state corresponding to the first SPS PDSCH to be determined, set the SPS configuration index value in the third SPS PDSCH set to the smallest value Or the largest one is determined as the second SPS PDSCH to be determined, and the third SPS PDSCH set is the SPS PDSCH set other than the first SPS PDSCH to be determined in the first SPS PDSCH set; it is judged that the second SPS PDSCH to be determined corresponds to a TCI
  • the state is still multiple TCI states; if the second to-be-determined SPS PDSCH corresponds to one TCI state, the first receiving process is performed; if the second to-be-determined SPS PDSCH corresponds to multiple TCI states, the second receiving process is performed.
  • the first receiving process includes: determining the first SPS PDSCH to be determined as the first target SPS PDSCH, determining the TCI state of the first SPS PDSCH to be determined as the first target TCI state, The second to-be-determined SPS PDSCH is determined to be the second target SPS PDSCH, and the TCI state of the second to-be-determined SPS PDSCH is determined to be the second target TCI state; the first target SPS PDSCH is received based on the first target TCI state, based on the second target The TCI state receives the second target SPS PDSCH.
  • the first receiving process includes: if the second TCI state set includes the TCI state corresponding to the second to-be-determined SPS PDSCH, then configure the index of the SPS in the second SPS PDSCH subset The one with the smallest value or the largest value is determined as the target SPS PDSCH, and two of the multiple TCI states corresponding to the target SPS PDSCH are respectively determined as the first target TCI state and the second target TCI state,
  • the second SPS PDSCH set includes the second SPS PDSCH subset, and the multiple TCI states corresponding to each SPS PDSCH in the second SPS PDSCH subset include the TCI corresponding to the second to-be-determined SPS PDSCH state, the second SPS PDSCH set does not contain the TCI state corresponding to the second to-be-determined SPS PDSCH except the multiple TCI states corresponding to each SPS PDSCH in the second SPS PDSCH subset; based on the first target The TCI state and the second target TCI
  • the second receiving process includes: determining the second SPS PDSCH to be determined as the target SPS PDSCH, and determining two of the multiple TCI states corresponding to the second SPS PDSCH to be determined as the first SPS PDSCH respectively The target TCI state and the second target TCI state; the target SPS PDSCH is received based on the first target TCI state and the second target TCI state.
  • the second receiving process includes: determining the first SPS PDSCH to be determined as the first target SPS PDSCH, determining the TCI state corresponding to the first SPS PDSCH to be determined as the first target TCI state, The second to-be-determined SPS PDSCH is determined as the second target SPS PDSCH, and one of the multiple TCI states corresponding to the second to-be-determined SPS PDSCH is determined as the second target TCI state; the first target SPS is received based on the first target TCI state PDSCH, the second target SPS PDSCH is received based on the second target TCI state.
  • the receiving module 3 is further configured to, if the first SPS PDSCH to be determined corresponds to multiple TCI states, determine the first SPS PDSCH to be determined as the target SPS PDSCH, and determine the first SPS PDSCH to be determined as the target SPS PDSCH, and determine the first SPS PDSCH to be determined as the target SPS PDSCH Two of the multiple TCI states corresponding to the PDSCH are respectively determined as the first TCI state and the second TCI state; the target SPS PDSCH is received based on the first TCI state and the second TCI state.
  • the receiving module 3 is specifically configured to determine the one with the smallest or largest SPS configuration index value in the first SPS PDSCH set as the first target SPS PDSCH, and configure the SPS configuration in the second SPS PDSCH set
  • the one with the smallest or largest index value is determined as the second target SPS PDSCH
  • the second SPS PDSCH set is the SPS PDSCH set corresponding to multiple TCI states
  • the last TCI state corresponding to the second target SPS PDSCH is determined as the second target TCI state
  • the first target SPS PDSCH corresponds to one TCI state
  • the TCI state corresponding to the first target SPS PDSCH is determined as the first target TCI state
  • the first target SPS PDSCH corresponds to multiple TCI states
  • the first target SPS The first TCI state corresponding to the PDSCH is determined as the first target TCI state
  • the first target SPS PDSCH is received based on the first target TCI state
  • the second target SPS PDSCH is received
  • one of the multiple TCI states is the first TCI state, the last TCI state, the one with the smallest TCI state index value, or the one with the largest TCI state index value.
  • the combination of two of the plurality of TCI states is any of the following: a combination of a first TCI state and a second TCI state, a penultimate TCI state and The combination of the penultimate TCI state, the combination of the first TCI state and the penultimate TCI state, the combination of the one with the smallest TCI state index value and the one with the second smallest TCI state index value, the largest TCI state index value A combination of the one with the second largest TCI state index value, the one with the smallest TCI state index value, and the one with the largest TCI state index value.
  • the embodiment of the present application also provides a semi-persistent scheduling physical downlink shared channel SPS PDSCH receiving device, including: a processor and a memory, the memory is used to store at least one instruction, and the instruction is loaded and executed by the processor to implement any of the above embodiments.
  • SPS PDSCH reception method The specific process and principle of the SPS PDSCH receiving method are the same as the above-mentioned embodiments, and are not repeated here.
  • the number of processors may be one or more, and the processors and the memory may be connected by a bus or in other ways.
  • the memory can be used to store non-transitory software programs, non-transitory computer-executable programs and modules, such as program instructions/modules corresponding to the SPS PDSCH receiving apparatus in the embodiments of the present application.
  • the processor executes various functional applications and data processing by running the non-transitory software programs, instructions and modules stored in the memory, that is, to implement the method in any of the above method embodiments.
  • the memory may include a stored program area and a stored data area, wherein the stored program area may store an operating system, an application program required for at least one function; and necessary data and the like. Additionally, the memory may include high-speed random access memory, and may also include non-transitory memory, such as at least one magnetic disk storage device, flash memory device, or other non-transitory solid state storage device.
  • An embodiment of the present application further provides a terminal, including the SPS PDSCH receiving apparatus in any of the foregoing embodiments.
  • the terminals involved in this application may be mobile phones, tablet computers, personal computers (PCs), personal digital assistants (PDAs), smart watches, netbooks, wearable electronic devices, augmented reality technology (augmented reality, AR) devices, virtual reality (VR) devices, in-vehicle devices, drone devices, smart cars, smart audio, robots, smart glasses, and any other product with wireless communication capabilities.
  • Embodiments of the present application also provide a computer-readable storage medium, where a computer program is stored in the computer-readable storage medium, and when it runs on a computer, the computer can execute the SPS PDSCH receiving method in any of the foregoing embodiments.
  • the above-mentioned embodiments it may be implemented in whole or in part by software, hardware, firmware or any combination thereof.
  • software it can be implemented in whole or in part in the form of a computer program product.
  • the computer program product includes one or more computer instructions.
  • the computer program instructions when loaded and executed on a computer, result in whole or in part of the processes or functions described herein.
  • the computer may be a general purpose computer, special purpose computer, computer network, or other programmable device.
  • the computer instructions may be stored in or transmitted from one computer readable storage medium to another computer readable storage medium, for example, the computer instructions may be downloaded from a website site, computer, server or data center Transmission to another website site, computer, server, or data center by wire (eg, coaxial cable, optical fiber, digital subscriber line) or wireless (eg, infrared, wireless, microwave, etc.).
  • the computer-readable storage medium may be any available medium that can be accessed by a computer or a data storage device such as a server, data center, etc. that includes an integration of one or more available media.
  • the usable media may be magnetic media (eg, floppy disks, hard disks, magnetic tapes), optical media (eg, DVD), or semiconductor media (eg, Solid State Disk), and the like.
  • “at least one” refers to one or more, and “multiple” refers to two or more.
  • “And/or”, which describes the association relationship of the associated objects means that there can be three kinds of relationships, for example, A and/or B, which can indicate the existence of A alone, the existence of A and B at the same time, and the existence of B alone. where A and B can be singular or plural.
  • the character “/” generally indicates that the associated objects are an “or” relationship.
  • “At least one of the following” and similar expressions refer to any combination of these items, including any combination of single or plural items.
  • At least one of a, b, and c may represent: a, b, c, a-b, a-c, b-c, or a-b-c, where a, b, c may be single or multiple.

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Abstract

本申请涉及通信技术领域,特别涉及一种SPS PDSCH接收方法、装置、终端和存储介质,可以在待接收的至少部分SPS PDSCH对应两个TCI state时,解决SPS PDSCH发生冲突时如何接收的问题。该SPS PDSCH接收方法,包括:根据高层参数,确定第一SPS PDSCH集合,所述第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,所述第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH。

Description

SPS PDSCH接收方法、装置、终端和存储介质
本申请要求于2021年4月2日提交中国专利局、申请号为202110363713.4、申请名称为“SPSPDSCH接收方法、装置、终端和存储介质”的中国专利申请的优先权,其全部内容通过引用结合在本申请中。
技术领域
本申请涉及通信技术领域,特别涉及一种SPS PDSCH接收方法、装置、终端和存储介质。
背景技术
目前,对于半静态调度(Semi-Persistent Scheduling,SPS)物理下行共享信道(Physical Downlink Shared Channel,PDSCH)的接收,仅支持每个SPS PDSCH对应一个传输配置指示状态(Transmission Configuration Indicator state,TCI state)时的接收规则,当SPS PDSCH发生冲突(时域有重叠)时,如果某些SPS PDSCH对应两个TCI state,如何接收SPS PDSCH是一个待解决的问题。
发明内容
本申请实施例提供一种SPS PDSCH接收方法、装置、终端和存储介质,可以在待接收的至少部分SPS PDSCH对应两个TCI state时,解决SPS PDSCH发生冲突时如何接收的问题。
第一方面,本申请实施例提供一种半静态调度物理下行共享信道SPS PDSCH接收方法,包括:
根据高层参数,确定第一SPS PDSCH集合,所述第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;
根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,所述第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;
在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述目标TCI state为一个TCI state。
在一种可能的实施方式中,所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
在所述第一SPS PDSCH集合中将SPS配置索引值最小或最大的一者确定为目标SPS  PDSCH,若所述目标SPS PDSCH对应多个TCI state,则将所述多个TCI state中的一者确定为目标TCI state,并基于所述目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
将所述第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,将所述目标SPS PDSCH对应的TCI state确定为目标TCI state,并基于所述目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述目标TCI state包括第一目标TCI state和第二目标TCI state。
在一种可能的实施方式中,所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
将所述第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将所述第一目标SPS PDSCH对应的TCI state确定为所述第一目标TCI state;
将所述第一SPS PDSCH集合中除所述第一目标SPS PDSCH之外且对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,将所述第二目标SPS PDSCH对应的TCI state确定为所述第二目标TCI state;
基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
在一种可能的实施方式中,所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
将所述第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH;
将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和第二目标TCI state;
基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
将所述第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一待确定SPS PDSCH;
判断所述第一待确定SPS PDSCH对应一个TCI state还是多个TCI state;
若所述第一待确定SPS PDSCH对应一个TCI state,在第一SPS PDSCH集合中确定第二SPS PDSCH集合和第二TCI state集合;第二SPS PDSCH集合为第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH;第二TCI state集合为第二SPS PDSCH集合中SPS PDSCH对应的TCI state;
判断所述第二TCI state集合中是否包含所述第一待确定SPS PDSCH对应的TCI state;
若所述第二TCI state集合中包含所述第一待确定SPS PDSCH对应的TCI state,则将第一SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH,将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state,所述第二SPS PDSCH集合包括所述第一SPS PDSCH子集合,所述第一SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含所述第一待确定SPS PDSCH对应的TCI state,所述第二SPS PDSCH集合中除所述第一SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含所述第一待确定SPS PDSCH对应的TCI state;
基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,在所述若所述第一待确定SPS PDSCH对应一个TCI state,则判断第二SPS PDSCH集合中是否包含所述第一待确定SPS PDSCH对应的TCI state的过程之后,还包括:
若所述第二TCI state集合中不包含所述第一待确定SPS PDSCH对应的TCI state,则将第三SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二待确定SPS PDSCH,所述第三SPS PDSCH集合为所述第一SPS PDSCH集合中除所述第一待确定SPS PDSCH之外的SPS PDSCH集合;
判断所述第二待确定SPS PDSCH对应一个TCI state还是多个TCI state;
若所述第二待确定SPS PDSCH对应一个TCI state,则执行第一接收流程;
若所述第二待确定SPS PDSCH对应多个TCI state,则执行第二接收流程。
在一种可能的实施方式中,所述第一接收流程包括:
将所述第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将所述第一待确定SPS PDSCH的TCI state确定为第一目标TCI state,将所述第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将所述第二待确定SPS PDSCH的TCI state确定为第二目标TCI state;
基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
在一种可能的实施方式中,所述第一接收流程包括:
若所述第二TCI state集合中包含所述第二待确定SPS PDSCH对应的TCI state,则将第二SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH,将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state,所述第二SPS PDSCH集合包括所述第二SPS PDSCH子集合,所述第二SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含所述第二待确定SPS PDSCH对应的TCI state,所述第二SPS PDSCH集合中除所述第二SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含所述第二待确定SPS PDSCH对应的TCI state;
基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述第二接收流程包括:
将所述第二待确定SPS PDSCH确定为所述目标SPS PDSCH,将所述第二待确定SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state;
基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述第二接收流程包括:
将所述第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将所述第一待确定SPS PDSCH对应的TCI state确定为所述第一目标TCI state,将所述第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将所述第二待确定SPS PDSCH对应的多个TCI state中的一者确定为所述第二目标TCI state;
基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
在一种可能的实施方式中,在所述判断所述第一待确定SPS PDSCH对应一个TCI state还是多个TCI state的过程之后,还包括:
若所述第一待确定SPS PDSCH对应多个TCI state,则将所述第一待确定SPS PDSCH确定为所述目标SPS PDSCH,将所述第一待确定SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一TCI state和所述第二TCI state;
基于所述第一TCI state和所述第二TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
将所述第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将第二SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,所述第二SPS PDSCH集合为对应多个TCI state的SPS PDSCH集合;
将所述第二目标SPS PDSCH对应的最后一个TCI state确定为所述第二目标TCI state;
若所述第一目标SPS PDSCH对应一个TCI state,则将所述第一目标SPS PDSCH对应的TCI state确定为所述第一目标TCI state;
若所述第一目标SPS PDSCH对应多个TCI state,则将所述第一目标SPS PDSCH对应的第一个TCI state确定为所述第一目标TCI state;
基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
在一种可能的实施方式中,所述多个TCI state中的一者为第一个TCI state、最后一个TCI state、TCI state索引值最小的一者或TCI state索引值最大的一者。
在一种可能的实施方式中,所述多个TCI state中的两者的组合为以下各项中的任意一者:
第一个TCI state和第二个TCI state的组合、倒数第一个TCI state和倒数第二个TCI state的组合、第一个TCI state和倒数第一个TCI state的组合、TCI state索引值最小的一者和TCI state索引值次小的一者的组合、TCI state索引值最大的一者和TCI state索引值次大的一者的组合、TCI state索引值最小的一者和TCI state索引值最大的一者的组合。
第二方面,本申请实施例提供一种半静态调度物理下行共享信道SPS PDSCH接收装置,包括:
第一确定模块,用于根据高层参数,确定第一SPS PDSCH集合,所述第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;
第二确定模块,用于根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,所述第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;
接收模块,用于在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH。
第三方面,本申请实施例提供一种半静态调度物理下行共享信道SPS PDSCH接收装置,包括:
处理器和存储器,所述存储器用于存储至少一条指令,所述指令由所述处理器加载并执行时以实现上述的SPS PDSCH接收方法。
第四方面,本申请实施例提供一种终端,包括第二方面或第三方面的SPS PDSCH接收装置。
第五方面,本申请实施例提供一种计算机可读存储介质,所述计算机可读存储介质中存储有计算机程序,当其在计算机上运行时,使得计算机执行上述的SPS PDSCH接收方法。
本申请实施例中的SPS PDSCH接收方法、装置、终端和存储介质,通过在相互冲突的待接收SPS PDSCH中确定目标TCI state和目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH,可以解决SPS PDSCH发生冲突时如何接收的问题。
附图说明
图1为本申请实施例中一种SPS PDSCH接收方法的流程图;
图2为本申请实施例中一种第一SPS PDSCH集合的示意图;
图3为本申请实施例中一种第一时隙内待接收的SPS PDSCH的示意图;
图4为图1中步骤103的一种具体流程图;
图5为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图6为图1中步骤103的另一种具体流程图;
图7为图1中步骤103的另一种具体流程图;
图8为图1中步骤103的另一种具体流程图;
图9为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图10为图8中第一接收流程的一种具体示意图;
图11为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图12为图8中第一接收流程的另一种具体示意图;
图13为图8中第一接收流程的另一种具体示意图;
图14为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图15为图8中第二接收流程的一种具体示意图;
图16为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图17为图8中第二接收流程的另一种具体示意图;
图18为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图19为图1中步骤103的另一种具体流程图;
图20为本申请实施例中另一种第一SPS PDSCH集合的示意图;
图21为本申请实施例中一种SPS PDSCH接收装置的结构框图。
具体实施方式
本申请的实施方式部分使用的术语仅用于对本申请的具体实施例进行解释,而非旨在限定本申请。
如图1、图2和图3所示,本申请实施例提供一种半静态调度物理下行共享信道SPS PDSCH接收方法,包括:
步骤101、根据高层参数,确定第一SPS PDSCH集合,第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;其中,高层参数可以通过例如无线资源控制(Radio Resource Control,RRC)配置、或者介质访问控制(Medium Access Control,MAC)-控制元素(Control Element,CE)配置、或者下行链路控制信息(Downlink Control Information,DCI)指示,具体不作限定。
步骤102、根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;
例如,在图2中示意了一种第一SPS PDSCH集合的例子,其中,“#”后面的数字表示SPS配置索引值(Config Index),括号内表示SPS PDSCH对应的TCI state,TCI后面的数字表示TCI state的索引值,其中,无填充的SPS PDSCH对应一个TCI state,有填充的SPS PDSCH对应两个TCI state。
步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH。
具体地,例如,在步骤101中,首先在如图3所示的一个时隙内待接收的SPS PDSCH中确定一个SPS PDSCH,例如将SPS配置索引值最小的一个SPS PDSCH#0作为所确定的SPS PDSCH,将该SPS PDSCH#0以及该时隙内与该SPS PDSCH#0相冲突的其他SPS PDSCH的集合确定为如图2所示的第一SPS PDSCH集合。然后针对该第一SPS PDSCH集合,基于步骤102和步骤103确定所要接收的目标SPS PDSCH。例如,如果在步骤103中确定SPS PDSCH#0为目标SPS PDSCH,TCI1为目标TCI state,则可以基于TCI1接收SPS PDSCH#0,其中,TCI state用于确定接收SPS PDSCH的波束方向。对于第一SPS PDSCH集合,其中的SPS PDSCH之间发生冲突(时域有重叠),通过本申请实施例的接收方法,可以选择目标SPS PDSCH进行接收,以解决SPS PDSCH冲突的问题。在例如将图3中SPS PDSCH#0、SPS PDSCH#1、SPS PDSCH#3、SPS PDSCH#5和SPS PDSCH#7组成的第一SPS PDSCH集合根据上述流程确定出目标TCI state和目标SPS PDSCH之后,或者基于目标TCI state接收目标SPS PDSCH之后,可以在该时隙除 SPS PDSCH#0、SPS PDSCH#1、SPS PDSCH#3、SPS PDSCH#5和SPS PDSCH#7之外的SPS PDSCH中确定另一个SPS PDSCH,即在SPS PDSCH#8、SPS PDSCH#9和SPS PDSCH#10这些剩余的SPS PDSCH中将SPS配置索引值最小的一个SPS PDSCH#8作为所确定的SPS PDSCH,将SPS PDSCH#8以及与SPS PDSCH#8相冲突的SPS PDSCH确定为新的第一SPS PDSCH集合,根据相同的方式确定目标TCI state以及目标SPS PDSCH并接收,依次类推。
本申请实施例中的SPS PDSCH接收方法,通过在相互冲突的待接收SPS PDSCH中确定目标TCI state和目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH,可以解决SPS PDSCH发生冲突时如何接收SPS PDSCH的问题。
在一种可能的实施方式中,目标TCI state为一个TCI state。如果终端仅支持同时接收一个方向的波束,则可以基于一个TCI state来接收目标SPS PDSCH。
在一种可能的实施方式中,如图2、图4和图5所示,上述步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH的过程包括:
步骤201、在第一SPS PDSCH集合中将SPS配置索引值最小或最大的一者确定为目标SPS PDSCH;
步骤202、判断目标SPS PDSCH对应一个TCI state还是多个TCI state,若目标SPS PDSCH对应一个TCI state,则进入步骤203,若目标SPS PDSCH对应多个TCI state,则进入步骤204;
步骤203、将目标SPS PDSCH对应的TCI确定为目标TCI state,并基于目标TCI state接收目标SPS PDSCH;
步骤204、将多个TCI state中的一者确定为目标TCI state,并基于目标TCI state接收目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图2所示,在步骤201中,假设根据预设的规则将SPS配置索引值最小的一者确定为目标SPS PDSCH,即将SPS PDSCH#0确定为目标SPS PDSCH,则在步骤202中判断SPS PDSCH#0对应TCI1,即仅对应一个TCI state,因此进入步骤203,基于SPS PDSCH#0对应的TCI1接收SPS PDSCH#0。又例如,如果当前的第一SPS PDSCH集合如图5所示,在步骤201中,假设根据预设的规则将SPS配置索引值最小的一者确定为目标SPS PDSCH,即将SPS PDSCH#0确定为目标SPS PDSCH,则在步骤202中判断SPS PDSCH#0对应TCI2和TCI3,即对应两个TCI state,因此进入步骤204,在TCI2和TCI3中根据预设规则确定一个为目标TCI state,例如,根据预设规则将TCI state索引值最小的一者确定为目标TCI state,例如将TCI2确定为目标TCI state,则基于TCI2接收SPS PDSCH#0,可以理解地,在其他可能的实施方式中,预设规则也可以为其他规则,例如,将多个TCI state中TCI state索引值最大的一者、第一个TCI state或最后一个TCI state确定为目标TCI state。
在一种可能的实施方式中,如图5所示,假设终端仅支持同时接收一个方向的波束,上述步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目 标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH的过程包括:将第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,将目标SPS PDSCH对应的TCI state确定为目标TCI state,并基于目标TCI state接收目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图5所示,第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH为SPS PDSCH#1、SPS PDSCH#3和SPS PDSCH#5,假设将其中SPS配置索引值最小的一者确定为目标SPS PDSCH,即将SPS PDSCH#1确定为目标SPS PDSCH,将SPS PDSCH#1对应的TCI4确定为目标TCI state,基于TCI4接收SPS PDSCH#1。也就是说,在本实施例中,会排除掉对应多个TCI state的SPS PDSCH,在剩余SPS PDSCH中确定一个目标SPS PDSCH和对应的一个目标TCI state来接收。
在一种可能的实施方式中,目标TCI state包括第一目标TCI state和第二目标TCI state。如果终端支持同时接收两个方向的波束,则可以基于两个TCI state来接收目标SPS PDSCH。
在一种可能的实施方式中,如图5和图6所示,上述步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH的过程包括:
步骤301、将第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将第一目标SPS PDSCH对应的TCI state确定为第一目标TCI state;
步骤302、将第一SPS PDSCH集合中除第一目标SPS PDSCH之外且对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,将第二目标SPS PDSCH对应的TCI state确定为第二目标TCI state;
步骤303、基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图5所示,将图5中无填充的SPS PDSCH中SPS配置索引值最小的SPS PDSCH#1确定为第一目标SPS PDSCH,将其对应的TCI4确定为第一目标TCI state,将剩余无填充的SPS PDSCH中SPS配置索引值最小的SPS PDSCH#3确定为第二目标SPS PDSCH,将其对应的TCI1确定为第二目标TCI state,基于TCI4接收SPS PDSCH#1,基于TCI1接收SPS PDSCH#3。也就是说,在本实施例中,会排除掉对应多个TCI state的SPS PDSCH,在剩余SPS PDSCH中确定两个目标SPS PDSCH和对应的两个目标TCI state来接收。
在一种可能的实施方式中,如图2和图7所示,上述步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH的过程包括:
步骤401、将第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH;
步骤402、将目标SPS PDSCH对应的多个TCI state中的两者分别确定为第一目标 TCI state和第二目标TCI state;
步骤403、基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图2所示,将图2中有填充的SPS PDSCH中SPS配置索引值最小的SPS PDSCH#3确定为目标SPS PDSCH,将SPS PDSCH#3对应的TCI2和TCI3分别确定为第一目标TCI state和第二目标TCI state,其中,多个TCI state中两个目标TCI state的确定方式例如可以为将第一个TCI state和最后一个TCI state分别确定为两个目标TCI state,可以理解地,在其他可能的实施方式中,可以根据其他预设规则来从多个TCI state中确定两个目标TCI state,基于TCI2和TCI3接收SPS PDSCH#3。也就是说,在本实施例中,会在对应多个TCI state的SPS PDSCH中确定一个目标SPS PDSCH以及对应的两个目标TCI state来接收。
在一种可能的实施方式中,如图8和图9所示,上述步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH的过程包括:
步骤501、将第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一待确定SPS PDSCH;
步骤502、判断第一待确定SPS PDSCH对应一个TCI state还是多个TCI state;若第一待确定SPS PDSCH对应一个TCI state,则进入步骤503;
步骤503、在第一SPS PDSCH集合中确定第二SPS PDSCH集合和第二TCI state集合;第二SPS PDSCH集合为第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH;第二TCI state集合为第二SPS PDSCH集合中SPS PDSCH对应的TCI state,然后进入步骤504;
步骤504、判断第二TCI state集合中是否包含第一待确定SPS PDSCH对应的TCI state;若是,即若第二TCI state集合中包含第一待确定SPS PDSCH对应的TCI state,则进入步骤505;
步骤505、将第一SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,将目标SPS PDSCH对应的多个TCI state中的两者分别确定为第一目标TCI state和第二目标TCI state,第二SPS PDSCH集合包括第一SPS PDSCH子集合,第一SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含第一待确定SPS PDSCH对应的TCI state,第二SPS PDSCH集合中除第一SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含第一待确定SPS PDSCH对应的TCI state,然后进入步骤506;
步骤506、基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图9所示,在步骤501中将图2中SPS配置索引值最小的SPS PDSCH#0确定为第一待确定SPS PDSCH,然后在步骤502中判断SPS PDSCH#0仅对应TCI1,即对应一个TCI state,根据该判断结果进入步骤503,在步骤503中确定第二SPS PDSCH集合和第二TCI state集合,第二SPS PDSCH集合由有填充的SPS PDSCH组成,即SPS PDSCH#7和SPS PDSCH#3,第二TCI state集合由有填充的SPS PDSCH对应的TCI state组成,即TCI1、TCI3和TCI4,然后进入步骤504,在步骤504中判断第二TCI state集合中包含TCI1,在步骤505中,第一SPS  PDSCH子集合由SPS PDSCH#7和SPS PDSCH#3组成,SPS PDSCH#7对应的TCI4和TCI1包含SPS PDSCH#0对应的TCI1,SPS PDSCH#3对应的TCI1和TCI3包含SPS PDSCH#0对应的TCI1,需要说明的是,本实施例中,恰好第一SPS PDSCH子集合与第二SPS PDSCH集合相同,在其他可能的实施方式中,如果两者不同,那么第二SPS PDSCH集合中除第一SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含TCI1,将SPS PDSCH#7和SPS PDSCH#3(第一SPS PDSCH子集合)中SPS配置索引值最小的SPS PDSCH#3确定为目标SPS PDSCH,将SPS PDSCH#3对应的TCI1和TCI3分别确定为第一目标TCI state和第二目标TCI state,在步骤506中基于TCI1和TCI3接收SPS PDSCH#3。也就是说,在本实施例中,会结合对应一个TCI state的SPS PDSCH和对应多个TCI state的SPS PDSCH来确定目标SPS PDSCH和目标TCI state。
在一种可能的实施方式中,如图5和图8所示,在步骤502、判断第一待确定SPS PDSCH对应一个TCI state还是多个TCI state的过程之后,还包括:若第一待确定SPS PDSCH对应多个TCI state,则进入步骤506;
步骤507、将第一待确定SPS PDSCH确定为目标SPS PDSCH,将第一待确定SPS PDSCH对应的多个TCI state中的两者分别确定为第一TCI state和第二TCI state;
步骤508、基于第一TCI state和第二TCI state接收目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图5所示,在步骤501中将SPS配置索引值最小的SPS PDSCH#0确定为目标SPS PDSCH,在步骤502中判断SPS PDSCH#0对应TCI2和TCI3,即对应多个TCI state,将TCI2和TCI3分别确定为第一目标TCI state和第二目标TCI state,基于TCI2和TCI3接收SPS PDSCH#0。
在一种可能的实施方式中,如图8所示,在上述若第一待确定SPS PDSCH对应一个TCI state,则进入步骤504、判断第二TCI state集合中是否包含第一待确定SPS PDSCH对应的TCI state的过程之后,还包括:若否,即若第二TCI state集合中不包含第一待确定SPS PDSCH对应的TCI state,则进入步骤509;
步骤509、将第三SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二待确定SPS PDSCH,第三SPS PDSCH集合为第一SPS PDSCH集合中除第一待确定SPS PDSCH之外的SPS PDSCH集合;
步骤510、判断第二待确定SPS PDSCH对应一个TCI state还是多个TCI state;若第二待确定SPS PDSCH对应一个TCI state,则执行第一接收流程;若第二待确定SPS PDSCH对应多个TCI state,则执行第二接收流程。
在一种可能的实施方式中,如图8、图10和图11所示,第一接收流程包括:
步骤601、将第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将第一待确定SPS PDSCH的TCI state确定为第一目标TCI state,将第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将第二待确定SPS PDSCH的TCI state确定为第二目标TCI state;
步骤602、基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图11所示,在步骤501中将图11中SPS配置索引值最小的SPS PDSCH#0确定为第一待确定SPS PDSCH,然后在步骤502中判断SPS PDSCH#0仅对应TCI1,即对应一个TCI state,根据该判断结果进入步骤 503,确定第二SPS PDSCH集合和第二TCI state集合,第二SPS PDSCH集合由有填充的SPS PDSCH组成,即SPS PDSCH#7和SPS PDSCH#3,第二TCI state集合由有填充的SPS PDSCH对应的TCI state组成,即TCI2、TCI3和TCI4,然后进入步骤504,在步骤504中判断第二TCI state集合中不包含TCI1,进入步骤509,将除SPS PDSCH#0之外的SPS PDSCH中SPS配置索引值最小的一者SPS PDSCH#1确定为第二待确定SPS PDSCH,然后在步骤510中判断SPS PDSCH#1对应TCI4,即仅对应一个TCI state,执行第一接收流程,在步骤601中,将SPS PDSCH#0确定为第一目标SPS PDSCH,将TCI1确定为第一目标TCI state,将SPS PDSCH#1确定为第二目标SPS PDSCH,将TCI4确定为第二目标TCI state,在步骤602中基于TCI1接收SPS PDSCH#0,基于TCI4接收SPS PDSCH#1。
在一种可能的实施方式中,如图8、图12、图13和图14所示,第一接收流程包括:若第二TCI state集合中包含第二待确定SPS PDSCH对应的TCI state,则进入步骤701;
步骤701、将第二SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,将目标SPS PDSCH对应的多个TCI state中的两者分别确定为第一目标TCI state和第二目标TCI state,第二SPS PDSCH集合包括第二SPS PDSCH子集合,第二SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含第二待确定SPS PDSCH对应的TCI state,第二SPS PDSCH集合中除第二SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含第二待确定SPS PDSCH对应的TCI state;
步骤702、基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
具体地,在一种可能的实施方式中,如图12所示,可以通过网络侧配置使第二TCI state集合中包含第二待确定SPS PDSCH对应的TCI state,在另外可能的实施方式中,如图14所示,第一接收流程可以包括:
步骤703、判断第二TCI state集合中包是否含第二待确定SPS PDSCH对应的TCI state,若是,即若第二TCI state集合中包含第二待确定SPS PDSCH对应的TCI state,则进入步骤701,若否,即若第二TCI state集合中不包含第二待确定SPS PDSCH对应的TCI state,则进入步骤601和步骤602,步骤601和步骤602的具体过程与上述实施例相同,在此不再赘述。例如,如果当前的第一SPS PDSCH集合如图14所示,在步骤501中将图14中SPS配置索引值最小的SPS PDSCH#0确定为第一待确定SPS PDSCH,然后在步骤502中判断SPS PDSCH#0仅对应TCI1,即对应一个TCI state,根据该判断结果进入步骤503,在步骤503中确定第二SPS PDSCH集合和第二TCI state集合,第二SPS PDSCH集合由有填充的SPS PDSCH组成,即SPS PDSCH#7和SPS PDSCH#4,第二TCI state集合由有填充的SPS PDSCH对应的TCI state组成,即TCI2和TCI4,然后进入步骤504,在步骤504中判断第二TCI state集合中不包含TCI1,进入步骤509,将除SPS PDSCH#0之外的SPS PDSCH中SPS配置索引值最小的一者SPS PDSCH#1确定为第二待确定SPS PDSCH,然后在步骤510中判断SPS PDSCH#1对应TCI4,即仅对应一个TCI state,执行第一接收流程,在步骤701中,将SPS PDSCH#0确定为第一目标SPS
PDSCH,将TCI1确定为第一目标TCI state,第二SPS PDSCH子集合由SPS PDSCH#4和SPS PDSCH#7组成,SPS PDSCH#4对应的TCI2和TCI4包括TCI4,SPS PDSCH#7 对应的TCI4和TCI2包括TCI4,需要说明的是,本实施例中,恰好第二SPS PDSCH子集合与第二SPS PDSCH集合相同,在其他可能的实施方式中,如果两者不同,那么第二SPS PDSCH集合中除第二SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含TCI4,将SPS PDSCH#7和SPS PDSCH#4(第二SPS PDSCH子集合)中SPS配置索引值最小的SPS PDSCH#4确定为目标SPS PDSCH,将其对应的TCI4和TCI2分别确定为第一目标TCI state和第二目标TCI state,在步骤702中基于TCI4和TCI2接收SPS PDSCH#4。
在一种可能的实施方式中,如图8、图15和图16所示,第二接收流程包括:
步骤801、将第二待确定SPS PDSCH确定为目标SPS PDSCH,将第二待确定SPS PDSCH对应的多个TCI state中的两者分别确定为第一目标TCI state和第二目标TCI state;
步骤802、基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图16所示,在步骤501中将图16中SPS配置索引值最小的SPS PDSCH#0确定为第一待确定SPS PDSCH,然后在步骤502中判断SPS PDSCH#0仅对应TCI1,即对应一个TCI state,根据该判断结果进入步骤503,确定第二SPS PDSCH集合和第二TCI state集合,第二SPS PDSCH集合由有填充的SPS PDSCH组成,即SPS PDSCH#7和SPS PDSCH#1,第二TCI state集合由有填充的
SPS PDSCH对应的TCI state组成,即TCI3和TCI4,然后进入步骤504,在步骤504中判断第二TCI state集合中不包含TCI1,进入步骤509,将除SPS PDSCH#0之外的SPS PDSCH中SPS配置索引值最小的一者SPS PDSCH#1确定为第二待确定SPS PDSCH,然后在步骤510中判断SPS PDSCH#1对应TCI3和TCI4,即对应多个TCI state,执行第二接收流程,在步骤801中,将SPS PDSCH#1确定为目标SPS PDSCH,将对应的TCI3和TCI4分别确定为第一目标TCI state和第二目标TCI state,在步骤802中基于TCI3和TCI4接收SPS PDSCH#1。
在一种可能的实施方式中,如图8、图17和图18所示,第二接收流程包括:
步骤901、将第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将第一待确定SPS PDSCH对应的TCI state确定为第一目标TCI state,将第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将第二待确定SPS PDSCH对应的多个TCI state中的一者确定为第二目标TCI state;
步骤902、基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图18所示,在步骤501中将图18中SPS配置索引值最小的SPS PDSCH#0确定为第一待确定SPS PDSCH,然后在步骤502中判断SPS PDSCH#0仅对应TCI1,即对应一个TCI state,根据该判断结果进入步骤503,确定第二SPS PDSCH集合和第二TCI state集合,第二SPS PDSCH集合由有填充的SPS PDSCH组成,即SPS PDSCH#7和SPS PDSCH#1,第二TCI state集合由有填充的SPS PDSCH对应的TCI state组成,即TCI2和TCI3,然后进入步骤504,在步骤504中判断第二TCI state集合中不包含TCI1,进入步骤509,将除SPS PDSCH#0之外的SPS PDSCH中SPS配置索引值最小的一者SPS PDSCH#1确定为第二待确定SPS PDSCH,然 后在步骤510中判断SPS PDSCH#1对应TCI2和TCI3,即对应多个TCI state,执行第二接收流程,在步骤901中,将SPS PDSCH#0确定为第一目标SPS PDSCH,将其对应的TCI1确定为第一目标TCI state,将SPS PDSCH#1确定为第二目标SPS PDSCH,将其对应的多个TCI state中的一者例如TCI2确定为第二目标TCI state,在步骤902中,基于TCI1接收SPS PDSCH#0,基于TCI2接收SPS PDSCH#1。
可以理解地,上述图10、图11或图12所示的流程组合均可以与图8所示的流程组合,上述图15或图17所示的流程均可以与图8所示的流程组合,并且任意第一接收流程和任意第二接收流程均可以组合在一起并与图8形成为一个完整的流程。
在一种可能的实施方式中,如图19和图20所示,上述步骤103、在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH的过程包括:
步骤1011、将第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将第二SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,第二SPS PDSCH集合为对应多个TCI state的SPS PDSCH集合;
步骤1012、将第二目标SPS PDSCH对应的最后一个TCI state确定为第二目标TCI state;
步骤1013、判断第一目标SPS PDSCH对应一个TCI state还是多个TCI state,若第一目标SPS PDSCH对应一个TCI state,则进入步骤1014,若第一目标SPS PDSCH对应多个TCI state,则进入步骤1015;
步骤1014、将第一目标SPS PDSCH对应的TCI state确定为第一目标TCI state,然后进入步骤1016;
步骤1015、将第一目标SPS PDSCH对应的第一个TCI state确定为第一目标TCI state,然后进入步骤1016;
步骤1016、基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
具体地,例如,如果当前的第一SPS PDSCH集合如图20所示,在步骤1011中将SPS配置索引值最小的SPS PDSCH#0确定为第一目标SPS PDSCH,将有填充的SPS PDSCH中SPS配置索引值最小的SPS PDSCH#1确定为第二目标SPS PDSCH,在步骤1012中将SPS PDSCH#1对应的最后一个TCI state确定为第二目标TCI state,即将TCI3确定为第二目标TCI state,在步骤1013中判断SPS PDSCH#0对应TCI1,即对应一个TCI state,进入步骤1014,将其对应的TCI1确定为第一目标TCI state,然后进入步骤1016,基于TCI1接收SPS PDSCH#0,基于TCI3接收SPS PDSCH#1。
在一种可能的实施方式中,上述步骤204或步骤901中多个TCI state中的一者为第一个TCI state、最后一个TCI state、TCI state索引值最小的一者或TCI state索引值最大的一者。例如步骤204中,可以根据这四种规则中的一种来确定目标TCI state,步骤901中可以根据这四种规则中的一种来确定第二目标TCI state。
在一种可能的实施方式中,上述步骤402、步骤504、步骤506、步骤701或步骤 801中,多个TCI state中的两者的组合为以下各项中的任意一者:第一个TCI state和第二个TCI state的组合、倒数第一个TCI state和倒数第二个TCI state的组合、第一个TCI state和倒数第一个TCI state的组合、TCI state索引值最小的一者和TCI state索引值次小的一者的组合、TCI state索引值最大的一者和TCI state索引值次大的一者的组合、TCI state索引值最小的一者和TCI state索引值最大的一者的组合。在上述各步骤中,可以根据上述一种组合确定的两个TCI state分别作为第一目标TCI state和第二目标TCI state。
如图21所示,本申请实施例还提供一种半静态调度物理下行共享信道SPS PDSCH接收装置,包括:第一确定模块1,用于根据高层参数,确定第一SPS PDSCH集合,第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;第二确定模块2,用于根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;接收模块3,用于在第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在第一SPS PDSCH集合中确定目标SPS PDSCH,并基于目标TCI state接收目标SPS PDSCH。
该SPS PDSCH接收装置可以应用上述实施例中的SPS PDSCH接收方法,具体过程和原理与上述实施例相同,在此不再赘述。
应理解以上图21所示SPS PDSCH接收装置的划分仅仅是一种逻辑功能的划分,实际实现时可以全部或部分集成到一个物理实体上,也可以物理上分开。且这些模块可以全部以软件通过处理元件调用的形式实现;也可以全部以硬件的形式实现;还可以部分模块以软件通过处理元件调用的形式实现,部分模块通过硬件的形式实现。例如,第一确定模块1、第二确定模块2和接收模块3中的任意一者可以为单独设立的处理元件,也可以集成在SPS PDSCH接收装置中,例如集成在SPS PDSCH接收装置的某一个芯片中实现,此外,也可以以程序的形式存储于SPS PDSCH接收装置的存储器中,由SPS PDSCH接收装置的某一个处理元件调用并执行以上各个模块的功能。其它模块的实现与之类似。此外这些模块全部或部分可以集成在一起,也可以独立实现。这里所述的处理元件可以是一种集成电路,具有信号的处理能力。在实现过程中,上述方法的各步骤或以上各个模块可以通过处理器元件中的硬件的集成逻辑电路或者软件形式的指令完成。
例如,第一确定模块1、第二确定模块2和接收模块3这些模块可以是被配置成实施以上方法的一个或多个集成电路,例如:一个或多个特定集成电路(Application Specific Integrated Circuit,ASIC),或,一个或多个微处理器(digital singnal processor,DSP),或,一个或者多个现场可编程门阵列(Field Programmable Gate Array,FPGA)等。再如,当以上某个模块通过处理元件调度程序的形式实现时,该处理元件可以是通用处理器,例如中央处理器(Central Processing Unit,CPU)或其它可以调用程序的处理器。再如,这些模块可以集成在一起,以片上系统(system-on-a-chip,SOC)的形式实现。
在一种可能的实施方式中,目标TCI state为一个TCI state。
在一种可能的实施方式中,接收模块3具体用于,在第一SPS PDSCH集合中将SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,若目标SPS PDSCH对应多个TCI state,则将多个TCI state中的一者确定为目标TCI state,并基于目标TCI state接收目标SPS PDSCH。
在一种可能的实施方式中,接收模块3具体用于,将第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,将目标SPS PDSCH对应的TCI state确定为目标TCI state,并基于目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,目标TCI state包括第一目标TCI state和第二目标TCI state。
在一种可能的实施方式中,接收模块3具体用于,将第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将第一目标SPS PDSCH对应的TCI state确定为第一目标TCI state;将第一SPS PDSCH集合中除第一目标SPS PDSCH之外且对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,将第二目标SPS PDSCH对应的TCI state确定为第二目标TCI state;基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
在一种可能的实施方式中,接收模块3具体用于,将第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH;将目标SPS PDSCH对应的多个TCI state中的两者分别确定为第一目标TCI state和第二目标TCI state;基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
在一种可能的实施方式中,接收模块3具体用于,将第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一待确定SPS PDSCH;判断第一待确定SPS PDSCH对应一个TCI state还是多个TCI state;若第一待确定SPS PDSCH对应一个TCI state,在第一SPS PDSCH集合中确定第二SPS PDSCH集合和第二TCI state集合;第二SPS PDSCH集合为第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH;第二TCI state集合为第二SPS PDSCH集合中SPS PDSCH对应的TCI state;判断所述第二TCI state集合中是否包含所述第一待确定SPS PDSCH对应的TCI state;若所述第二TCI state集合中包含所述第一待确定SPS PDSCH对应的TCI state,则将第一SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH,将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state,所述第二SPS PDSCH集合包括所述第一SPS PDSCH子集合,所述第一SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含所述第一待确定SPS PDSCH对应的TCI state,所述第二SPS PDSCH集合中除所述第一SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含所述第一待确定SPS PDSCH对应的TCI state;基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
在一种可能的实施方式中,接收模块3具体还用于,若第二TCI state集合中不包含第一待确定SPS PDSCH对应的TCI state,则将第三SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二待确定SPS PDSCH,第三SPS PDSCH集合为第一SPS PDSCH集合中除第一待确定SPS PDSCH之外的SPS PDSCH集合;判断第二待确定SPS PDSCH对应一个TCI state还是多个TCI state;若第二待确定SPS PDSCH对应一个TCI state,则执行第一接收流程;若第二待确定SPS PDSCH对应多个TCI state,则执行第二 接收流程。
在一种可能的实施方式中,第一接收流程包括:将第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将第一待确定SPS PDSCH的TCI state确定为第一目标TCI state,将所述第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将第二待确定SPS PDSCH的TCI state确定为第二目标TCI state;基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
在一种可能的实施方式中,第一接收流程包括:若所述第二TCI state集合中包含所述第二待确定SPS PDSCH对应的TCI state,则将第二SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH,将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state,所述第二SPS PDSCH集合包括所述第二SPS PDSCH子集合,所述第二SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含所述第二待确定SPS PDSCH对应的TCI state,所述第二SPS PDSCH集合中除所述第二SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含所述第二待确定SPS PDSCH对应的TCI state;基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
在一种可能的实施方式中,第二接收流程包括:将第二待确定SPS PDSCH确定为目标SPS PDSCH,将第二待确定SPS PDSCH对应的多个TCI state中的两者分别确定为第一目标TCI state和第二目标TCI state;基于第一目标TCI state和第二目标TCI state接收目标SPS PDSCH。
在一种可能的实施方式中,第二接收流程包括:将第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将第一待确定SPS PDSCH对应的TCI state确定为第一目标TCI state,将第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将第二待确定SPS PDSCH对应的多个TCI state中的一者确定为第二目标TCI state;基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
在一种可能的实施方式中,接收模块3具体还用于,若第一待确定SPS PDSCH对应多个TCI state,则将第一待确定SPS PDSCH确定为目标SPS PDSCH,将第一待确定SPS PDSCH对应的多个TCI state中的两者分别确定为第一TCI state和第二TCI state;基于第一TCI state和第二TCI state接收目标SPS PDSCH。
在一种可能的实施方式中,接收模块3具体用于,将第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将第二SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,第二SPS PDSCH集合为对应多个TCI state的SPS PDSCH集合;将第二目标SPS PDSCH对应的最后一个TCI state确定为第二目标TCI state;若第一目标SPS PDSCH对应一个TCI state,则将第一目标SPS PDSCH对应的TCI state确定为第一目标TCI state;若第一目标SPS PDSCH对应多个TCI state,则将第一目标SPS PDSCH对应的第一个TCI state确定为第一目标TCI state;基于第一目标TCI state接收第一目标SPS PDSCH,基于第二目标TCI state接收第二目标SPS PDSCH。
在一种可能的实施方式中,多个TCI state中的一者为第一个TCI state、最后一个TCI state、TCI state索引值最小的一者或TCI state索引值最大的一者。
在一种可能的实施方式中,多个TCI state中的两者的组合为以下各项中的任意一者:第一个TCI state和第二个TCI state的组合、倒数第一个TCI state和倒数第二个TCI state的组合、第一个TCI state和倒数第一个TCI state的组合、TCI state索引值最小的一者和TCI state索引值次小的一者的组合、TCI state索引值最大的一者和TCI state索引值次大的一者的组合、TCI state索引值最小的一者和TCI state索引值最大的一者的组合。
本申请实施例还提供一种半静态调度物理下行共享信道SPS PDSCH接收装置,包括:处理器和存储器,存储器用于存储至少一条指令,指令由处理器加载并执行时以实现上述任意实施例中的SPS PDSCH接收方法。SPS PDSCH接收方法的具体过程和原理与上述实施例相同,在此不再赘述。
处理器的数量可以为一个或多个,处理器和存储器可以通过总线或者其他方式连接。存储器作为一种非暂态计算机可读存储介质,可用于存储非暂态软件程序、非暂态计算机可执行程序以及模块,如本申请实施例中的SPS PDSCH接收装置对应的程序指令/模块。处理器通过运行存储在存储器中的非暂态软件程序、指令以及模块,从而执行各种功能应用以及数据处理,即实现上述任意方法实施例中的方法。存储器可以包括存储程序区和存储数据区,其中,存储程序区可存储操作系统、至少一个功能所需要的应用程序;以及必要数据等。此外,存储器可以包括高速随机存取存储器,还可以包括非暂态存储器,例如至少一个磁盘存储器件、闪存器件、或其他非暂态固态存储器件。
本申请实施例还提供一种终端,包括上述任意实施例中的SPS PDSCH接收装置。本申请所涉及的终端可能为手机、平板电脑、个人计算机(personal computer,PC)、个人数字助理(personal digital assistant,PDA)、智能手表、上网本、可穿戴电子设备、增强现实技术(augmented reality,AR)设备、虚拟现实(virtual reality,VR)设备、车载设备、无人机设备、智能汽车、智能音响、机器人、智能眼镜等等任意具有无线通信功能的产品。
本申请实施例还提供一种计算机可读存储介质,计算机可读存储介质中存储有计算机程序,当其在计算机上运行时,使得计算机执行上述任意实施例中的SPS PDSCH接收方法。
在上述实施例中,可以全部或部分地通过软件、硬件、固件或者其任意组合来实现。当使用软件实现时,可以全部或部分地以计算机程序产品的形式实现。所述计算机程序产品包括一个或多个计算机指令。在计算机上加载和执行所述计算机程序指令时,全部或部分地产生按照本申请所述的流程或功能。所述计算机可以是通用计算机、专用计算机、计算机网络、或者其他可编程装置。所述计算机指令可以存储在计算机可读存储介质中,或者从一个计算机可读存储介质向另一个计算机可读存储介质传输,例如,所述计算机指令可以从一个网站站点、计算机、服务器或数据中心通过有线(例如同轴电缆、光纤、数字用户线)或无线(例如红外、无线、微波等)方式向另一个网站站点、计算机、服务器或数据中心进行传输。所述计算机可读存储介质可以是计算机能够存取的任何可用介质或者是包含一个或多个可用介质集成的服务器、数据中心等数据存储设备。所述可用介质可以是磁性介质,(例如,软盘、硬盘、磁带)、光介质(例如,DVD)、或者半导体介质(例如固态硬盘Solid State Disk)等。
本申请实施例中,“至少一个”是指一个或者多个,“多个”是指两个或两个以上。“和/或”,描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示单独存在A、同时存在A和B、单独存在B的情况。其中A,B可以是单数或者复数。字符“/”一般表示前后关联对象是一种“或”的关系。“以下至少一项”及其类似表达,是指的这些项中的任意组合,包括单项或复数项的任意组合。例如,a,b和c中的至少一项可以表示:a,b,c,a-b,a-c,b-c,或a-b-c,其中a,b,c可以是单个,也可以是多个。
以上仅为本申请的优选实施例而已,并不用于限制本申请,对于本领域的技术人员来说,本申请可以有各种更改和变化。凡在本申请的精神和原则之内,所作的任何修改、等同替换、改进等,均应包含在本申请的保护范围之内。

Claims (21)

  1. 一种半静态调度物理下行共享信道SPS PDSCH接收方法,其特征在于,包括:
    根据高层参数,确定第一SPS PDSCH集合,所述第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;
    根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,所述第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;
    在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH。
  2. 根据权利要求1所述的方法,其特征在于,
    所述目标TCI state为一个TCI state。
  3. 根据权利要求2所述的方法,其特征在于,
    所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
    在所述第一SPS PDSCH集合中将SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,若所述目标SPS PDSCH对应多个TCI state,则将所述多个TCI state中的一者确定为目标TCI state,并基于所述目标TCI state接收所述目标SPS PDSCH。
  4. 根据权利要求2所述的方法,其特征在于,
    所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
    将所述第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为目标SPS PDSCH,将所述目标SPS PDSCH对应的TCI state确定为目标TCI state,并基于所述目标TCI state接收所述目标SPS PDSCH。
  5. 根据权利要求1所述的方法,其特征在于,
    所述目标TCI state包括第一目标TCI state和第二目标TCI state。
  6. 根据权利要求5所述的方法,其特征在于,
    所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
    将所述第一SPS PDSCH集合中对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将所述第一目标SPS PDSCH对应的TCI state确定为所述第一目标TCI state;
    将所述第一SPS PDSCH集合中除所述第一目标SPS PDSCH之外且对应一个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,将所述第二目标SPS PDSCH对应的TCI state确定为所述第二目标TCI state;
    基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI  state接收所述第二目标SPS PDSCH。
  7. 根据权利要求5所述的方法,其特征在于,
    所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
    将所述第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH;
    将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和第二目标TCI state;
    基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
  8. 根据权利要求5所述的方法,其特征在于,
    所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
    将所述第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一待确定SPS PDSCH;
    判断所述第一待确定SPS PDSCH对应一个TCI state还是多个TCI state;
    若所述第一待确定SPS PDSCH对应一个TCI state,在第一SPS PDSCH集合中确定第二SPS PDSCH集合和第二TCI state集合;第二SPS PDSCH集合为第一SPS PDSCH集合中对应多个TCI state的SPS PDSCH;第二TCI state集合为第二SPS PDSCH集合中SPS PDSCH对应的TCI state;
    判断所述第二TCI state集合中是否包含所述第一待确定SPS PDSCH对应的TCI state;
    若所述第二TCI state集合中包含所述第一待确定SPS PDSCH对应的TCI state,则将第一SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH,将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state,所述第二SPS PDSCH集合包括所述第一SPS PDSCH子集合,所述第一SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含所述第一待确定SPS PDSCH对应的TCI state,所述第二SPS PDSCH集合中除所述第一SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含所述第一待确定SPS PDSCH对应的TCI state;
    基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
  9. 根据权利要求8所述的方法,其特征在于,
    在所述若所述第一待确定SPS PDSCH对应一个TCI state,则判断第二SPS PDSCH集合中是否包含所述第一待确定SPS PDSCH对应的TCI state的过程之后,还包括:
    若所述第二TCI state集合中不包含所述第一待确定SPS PDSCH对应的TCI state,则将第三SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二待确定SPS PDSCH,所述第三SPS PDSCH集合为所述第一SPS PDSCH集合中除所述第一待确定SPS PDSCH之外的SPS PDSCH集合;
    判断所述第二待确定SPS PDSCH对应一个TCI state还是多个TCI state;
    若所述第二待确定SPS PDSCH对应一个TCI state,则执行第一接收流程;
    若所述第二待确定SPS PDSCH对应多个TCI state,则执行第二接收流程。
  10. 根据权利要求9所述的方法,其特征在于,
    所述第一接收流程包括:
    将所述第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将所述第一待确定SPS PDSCH的TCI state确定为第一目标TCI state,将所述第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将所述第二待确定SPS PDSCH的TCI state确定为第二目标TCI state;
    基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
  11. 根据权利要求9所述的方法,其特征在于,
    所述第一接收流程包括:
    若所述第二TCI state集合中包含所述第二待确定SPS PDSCH对应的TCI state,则将第二SPS PDSCH子集合中SPS配置索引值最小或最大的一者确定为所述目标SPS PDSCH,将所述目标SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state,所述第二SPS PDSCH集合包括所述第二SPS PDSCH子集合,所述第二SPS PDSCH子集合中的每个SPS PDSCH对应的多个TCI state中包含所述第二待确定SPS PDSCH对应的TCI state,所述第二SPS PDSCH集合中除所述第二SPS PDSCH子集合的每个SPS PDSCH对应的多个TCI state均不包含所述第二待确定SPS PDSCH对应的TCI state;
    基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
  12. 根据权利要求9所述的方法,其特征在于,
    所述第二接收流程包括:
    将所述第二待确定SPS PDSCH确定为所述目标SPS PDSCH,将所述第二待确定SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一目标TCI state和所述第二目标TCI state;
    基于所述第一目标TCI state和所述第二目标TCI state接收所述目标SPS PDSCH。
  13. 根据权利要求9所述的方法,其特征在于,
    所述第二接收流程包括:
    将所述第一待确定SPS PDSCH确定为第一目标SPS PDSCH,将所述第一待确定SPS PDSCH对应的TCI state确定为所述第一目标TCI state,将所述第二待确定SPS PDSCH确定为第二目标SPS PDSCH,将所述第二待确定SPS PDSCH对应的多个TCI state中的一者确定为所述第二目标TCI state;
    基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
  14. 根据权利要求8所述的方法,其特征在于,
    在所述判断所述第一待确定SPS PDSCH对应一个TCI state还是多个TCI state的过程之后,还包括:
    若所述第一待确定SPS PDSCH对应多个TCI state,则将所述第一待确定SPS PDSCH确定为所述目标SPS PDSCH,将所述第一待确定SPS PDSCH对应的多个TCI state中的两者分别确定为所述第一TCI state和所述第二TCI state;
    基于所述第一TCI state和所述第二TCI state接收所述目标SPS PDSCH。
  15. 根据权利要求5所述的方法,其特征在于,
    所述在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH的过程包括:
    将所述第一SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第一目标SPS PDSCH,将第二SPS PDSCH集合中SPS配置索引值最小或最大的一者确定为第二目标SPS PDSCH,所述第二SPS PDSCH集合为对应多个TCI state的SPS PDSCH集合;
    将所述第二目标SPS PDSCH对应的最后一个TCI state确定为所述第二目标TCI state;
    若所述第一目标SPS PDSCH对应一个TCI state,则将所述第一目标SPS PDSCH对应的TCI state确定为所述第一目标TCI state;
    若所述第一目标SPS PDSCH对应多个TCI state,则将所述第一目标SPS PDSCH对应的第一个TCI state确定为所述第一目标TCI state;
    基于所述第一目标TCI state接收所述第一目标SPS PDSCH,基于所述第二目标TCI state接收所述第二目标SPS PDSCH。
  16. 根据权利要求3或13所述的方法,其特征在于,
    所述多个TCI state中的一者为第一个TCI state、最后一个TCI state、TCI state索引值最小的一者或TCI state索引值最大的一者。
  17. 根据权利要求7、8、11、12或14所述的方法,其特征在于,
    所述多个TCI state中的两者的组合为以下各项中的任意一者:
    第一个TCI state和第二个TCI state的组合、倒数第一个TCI state和倒数第二个TCI state的组合、第一个TCI state和倒数第一个TCI state的组合、TCI state索引值最小的一者和TCI state索引值次小的一者的组合、TCI state索引值最大的一者和TCI state索引值次大的一者的组合、TCI state索引值最小的一者和TCI state索引值最大的一者的组合。
  18. 一种半静态调度物理下行共享信道SPS PDSCH接收装置,其特征在于,包括:
    第一确定模块,用于根据高层参数,确定第一SPS PDSCH集合,所述第一SPS PDSCH集合为相互冲突的待接收SPS PDSCH的集合;
    第二确定模块,用于根据高层参数,确定每一个SPS PDSCH对应的SPS配置索引值、传输配置指示状态TCI state以及TCI state索引值,所述第一SPS PDSCH集合中的至少一个SPS PDSCH对应多个TCI state;
    接收模块,用于在所述第一SPS PDSCH集合中的SPS PDSCH对应的TCI state中确定目标TCI state,以及在所述第一SPS PDSCH集合中确定目标SPS PDSCH,并基于所述目标TCI state接收所述目标SPS PDSCH。
  19. 一种半静态调度物理下行共享信道SPS PDSCH接收装置,其特征在于,包括:
    处理器和存储器,所述存储器用于存储至少一条指令,所述指令由所述处理器加载 并执行时以实现如权利要求1至17中任意一项所述的SPS PDSCH接收方法。
  20. 一种终端,其特征在于,包括如权利要求18或19所述的SPS PDSCH接收装置。
  21. 一种计算机可读存储介质,其特征在于,所述计算机可读存储介质中存储有计算机程序,当其在计算机上运行时,使得计算机执行如权利要求1至17中任意一项所述的SPS PDSCH接收方法。
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