WO2012142973A1 - 确认或不确认指示信息发送的方法和设备 - Google Patents
确认或不确认指示信息发送的方法和设备 Download PDFInfo
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- WO2012142973A1 WO2012142973A1 PCT/CN2012/074523 CN2012074523W WO2012142973A1 WO 2012142973 A1 WO2012142973 A1 WO 2012142973A1 CN 2012074523 W CN2012074523 W CN 2012074523W WO 2012142973 A1 WO2012142973 A1 WO 2012142973A1
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- ack
- nack
- subframe
- timing relationship
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0053—Allocation of signaling, i.e. of overhead other than pilot signals
- H04L5/0055—Physical resource allocation for ACK/NACK
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/12—Arrangements for detecting or preventing errors in the information received by using return channel
- H04L1/16—Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
- H04L1/18—Automatic repetition systems, e.g. Van Duuren systems
- H04L1/1825—Adaptation of specific ARQ protocol parameters according to transmission conditions
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/12—Arrangements for detecting or preventing errors in the information received by using return channel
- H04L1/16—Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
- H04L1/18—Automatic repetition systems, e.g. Van Duuren systems
- H04L1/1829—Arrangements specially adapted for the receiver end
- H04L1/1854—Scheduling and prioritising arrangements
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/12—Arrangements for detecting or preventing errors in the information received by using return channel
- H04L1/16—Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
- H04L1/18—Automatic repetition systems, e.g. Van Duuren systems
- H04L1/1867—Arrangements specially adapted for the transmitter end
- H04L1/1887—Scheduling and prioritising arrangements
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/12—Arrangements for detecting or preventing errors in the information received by using return channel
- H04L1/16—Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
- H04L1/18—Automatic repetition systems, e.g. Van Duuren systems
- H04L1/1867—Arrangements specially adapted for the transmitter end
- H04L1/1896—ARQ related signaling
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0091—Signaling for the administration of the divided path
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/04—TPC
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
- H04W72/0446—Resources in time domain, e.g. slots or frames
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/21—Control channels or signalling for resource management in the uplink direction of a wireless link, i.e. towards the network
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/23—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W76/00—Connection management
- H04W76/20—Manipulation of established connections
- H04W76/27—Transitions between radio resource control [RRC] states
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W88/00—Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
- H04W88/02—Terminal devices
Definitions
- the present invention relates to the field of communications, and in particular, to a method and apparatus for confirming or not confirming the transmission of indication information.
- the base station can give the UE ( User Equipment , User equipment) Configure at least two carriers to transmit data for the UE through at least two carriers. This configuration is called carrier aggregation.
- the base station sends a PDCCH (Physical Downlink Control Channel) information to the UE in a downlink subframe, where the PDCCH information indicates scheduling of a PDSCH (Physical Downlink Shared Channel) carried by the downlink subframe. information.
- PDCCH Physical Downlink Control Channel
- the UE determines an uplink subframe according to a timing relationship between a subframe in which the PDSCH is located and an ACK (acknowledgement)/NACK (non-acknowledgement) corresponding to the PDSCH, and feeds back the ACK/NACK corresponding to the PDSCH on the uplink subframe of the primary carrier. .
- the UE For the carrier aggregation, after the base station sends the downlink data to the UE, the UE needs to feed back the corresponding ACK/NACK to the base station. If the feedback is ACK, the data transmission is correct, and if the feedback is NACK, the base station initiates. The corresponding retransmission.
- the current ACK/NACK transmission method is only applicable to carrier aggregation of at least two TDD carriers and having the same uplink and downlink subframe configuration, or carrier aggregation of at least two FDD carriers.
- carrier aggregation of at least two TDD carriers configured in different uplink and downlink subframes, or carrier aggregation of at least one FDD carrier and at least one TDD carrier especially when the TDD carrier is used as a primary carrier, There may be cases where ACK/NACK cannot be fed back on the primary carrier, and there is currently no solution for ACK/NACK feedback.
- the present invention provides a method and apparatus for confirming or not confirming the transmission of indication information.
- a method of transmitting an acknowledgment or not confirming indication information comprising:
- the network side device configures at least two carriers for the user equipment UE, including one primary carrier and at least one secondary carrier;
- the network side device sends PDCCH information to the UE in a first downlink subframe, where the PDCCH information indicates scheduling information of a PDSCH carried in a second downlink subframe;
- the network side device selects one of the at least two timing relationships between the subframe where the PDSCH is located and the subframe where the ACK/NACK corresponding to the PDSCH is located as the first timing relationship, where the first timing relationship is satisfied.
- a first condition the first condition is that the subframe that is the same as the time of the second downlink subframe on the first carrier corresponding to the first timing relationship is a downlink subframe, and the first timing relationship is determined to be corresponding to the first timing relationship.
- the network side device indicates the determined information related to the third uplink subframe and the first carrier to the UE;
- the network side device determines, in the third uplink subframe of the first carrier, a first channel resource used by the UE to feed back an ACK/NACK corresponding to the PDSCH, and the first channel resource Indicating to the UE;
- the network side device receives an ACK/NACK fed back by the UE on the first channel resource in the third subframe on the first carrier.
- Another method of transmitting confirmation or not confirming indication information comprising:
- the timing relationship satisfies the first condition: the subframe corresponding to the second downlink subframe time on the first carrier corresponding to the timing relationship is a downlink subframe; the UE acquires the network side device allocated to the UE for the feedback a first channel resource of an ACK/NACK corresponding to the PDSCH;
- the UE sends an ACK/NACK corresponding to the PDSCH on the first channel resource of the third uplink subframe in the first carrier.
- the present invention also provides a network side device, where the network side device includes: a sending unit, a receiving unit, and a processing unit, where
- the sending unit is configured to notify the UE of the carrier configured by the processing unit, and send PDCCH information to the UE in the first subframe, where the PDCCH information is used to indicate the PDSCH carried in the second downlink subframe. Scheduling information; and the third uplink subframe and the related information corresponding to the first carrier determined by the processing unit, and the first channel resource determined by the processing unit are indicated to the UE;
- the processing unit is configured to configure, for the UE, at least two carriers, including one primary carrier and at least one secondary carrier; between the subframe where the PDSCH is located and the ACK/NACK corresponding to the PDSCH Selecting one of the at least two timing relationships as the first timing relationship, where the first timing relationship satisfies the first condition, where the first condition is: the first carrier corresponding to the timing relationship and the second downlink subframe And determining, by the UE, the ACK corresponding to the ACK/NACK corresponding to the PDSCH, and determining the ACK for the UE to send the PDSCH corresponding to the first timing relationship. a first carrier of the /NACK; and determining, in the determined third uplink subframe of the first carrier, a first channel resource for the UE to feed back an ACK/NACK corresponding to the PDSCH;
- the receiving unit is configured to receive an ACK/NACK fed back by the UE on the first channel resource of the third subframe in the first carrier.
- the present invention also provides a user equipment, including: a receiving unit, a processing unit, and a sending unit, where
- the processing unit is configured to determine, according to the indication information received by the receiving unit, a third uplink subframe and a first carrier that are used by the network side device to feed back the ACK/NACK, and according to the The information about the first channel resource received by the receiving unit determines that the ACK/NACK corresponding to the PDSCH is sent on the first channel resource of the third uplink subframe in the first carrier;
- the sending unit is configured to send, by using the ACK/NACK corresponding to the PDSCH, the first channel resource of the third uplink subframe in the first carrier.
- a system for carrier aggregation of at least two TDD carriers configured for different uplink and downlink subframes passes at least two timing relationships Selecting a first timing relationship, and the subframe corresponding to the second downlink subframe time on the corresponding first carrier is a downlink subframe, so that a subframe that can be used for ACK/NACK feedback can be configured for the UE,
- the carrier and the corresponding channel resources so that the UE not only ensures that the UE can perform ACK/NACK feedback, but also enables the UE to perform flexible ACK/NACK feedback.
- the solution of the present invention is equally applicable to a system for carrier aggregation having at least two TDD carriers and having the same uplink and downlink subframe configuration, or a system for carrier aggregation of at least two FDD carriers, and the like.
- the ACK/NACK may be selected to be fed back to different carriers or different subframes of the same carrier, so the scheme may also balance the load of ACK/NACK feedback on each carrier or each subframe.
- FIG. 1 is a flowchart of a method for confirming or not confirming the transmission of indication information in a TDD system provided in Embodiment 1 of the present invention
- FIG. 2 is a flowchart of a method for confirming or not confirming the transmission of indication information in the TDD system provided in Embodiment 1 of the present invention
- FIG. 3 is a schematic diagram of an uplink-downlink subframe configuration and a timing relationship in carrier aggregation provided in Embodiment 1 of the present invention
- FIG. 5 is a flowchart of a method for confirming or not confirming the transmission of indication information in the TDD system provided in Embodiment 2 of the present invention.
- FIG. 7 is a schematic diagram of the binding or acknowledgment of the time domain partial binding in the carrier aggregation of different uplink and downlink configurations of the TDD provided in Embodiment 3 of the present invention.
- FIG. 8 is a flowchart of a method for confirming or not confirming the transmission of indication information in the TDD system provided in Embodiment 3 of the present invention.
- FIG. 9 is a flowchart of a method for confirming or not confirming the transmission of indication information in the TDD system provided in Embodiment 3 of the present invention.
- FIG. 10 is a schematic structural diagram of a network side device provided in Embodiment 4 of the present invention.
- FIG. 12 is a schematic structural diagram of a network side device provided in Embodiment 6 of the present invention.
- FIG. 13 is a schematic structural diagram of a user equipment provided in Embodiment 7 of the present invention.
- FIG. 14 is a schematic structural diagram of a network side device provided in Embodiment 8 of the present invention.
- FIG. 15 is a schematic structural diagram of a user equipment provided in Embodiment 9 of the present invention.
- 17 is a flowchart of another method for sending acknowledgement or non-acknowledgement indication information provided in an embodiment of the present invention.
- FIG. 18 is a schematic structural diagram of another network side device according to Embodiment 6 of the present invention.
- FIG. 19 is a schematic structural diagram of another user equipment provided in Embodiment 7 of the present invention.
- This embodiment provides a method for confirming or not confirming the transmission of indication information in a TDD system.
- the method may be performed by a network side device, and specifically includes:
- the network side device configures the UE with at least two carriers, including one primary carrier and at least one secondary carrier.
- the network side device sends the PDCCH information to the UE in a downlink subframe, where the PDCCH information indicates the scheduling information of the PDSCH carried by the downlink subframe, and the PDCCH information indicates the ACK/NACK channel resource corresponding to the PDSCH, and the ACK/NACK channel resource bearer
- the first uplink subframe of the secondary carrier the first uplink subframe is determined according to a timing relationship between the ACK/NACK corresponding to the PDSCH and the PDSCH, and the time of the first uplink subframe is a downlink subframe on the primary carrier.
- the ACK/NACK resource is an ACK/NACK resource of PUCCH format 3, or the ACK/NACK resource is an ACK/NACK resource of a PUCCH format lb.
- the number of ACK/NACK resources of a group of PUCCH format lbs can be 2, 3 or 4.
- the network side device may specifically be a base station, and the same is true for the following embodiments.
- the method for confirming or not confirming the transmission of the indication information in the TDD system may also be performed by the UE, and specifically includes: S21: The UE receives the PDCCH information that the network side device sends to the UE in one downlink subframe. S22: The UE determines the PDSCH scheduled by the PDCCH information according to the scheduling information carried in the PDCCH information, determines the ACK/NACK channel resource corresponding to the PDSCH according to the indication of the PDCCH information, and determines the timing relationship between the ACK/NACK corresponding to the PDSCH and the PDSCH. In the first uplink subframe that feeds back the ACK/NACK, the time at which the first uplink subframe is located is a downlink subframe on the primary carrier, and the secondary carrier carried by the ACK/NACK channel resource is determined.
- S23 The UE feeds back an ACK/NACK corresponding to the PDSCH on the determined ACK/NACK channel resource, where the ACK/NACK channel resource is located in the first uplink subframe of the determined secondary carrier.
- the primary carrier may also be called a primary cell (Pcell), and the secondary carrier may also be called a secondary cell (Scell).
- Pcell primary cell
- Scell secondary cell
- the time of the first uplink subframe is an uplink subframe on the first secondary carrier, and if the first secondary carrier is one, the ACK/NACK channel resource is carried on the first uplink subframe of the first secondary carrier; and Or, if the first secondary carrier is two or more, the ACK/NACK channel resource is carried on the first uplink subframe of one of the first secondary carriers, where one of the first secondary carriers is used.
- the carrier is one of the following secondary carriers: the secondary carrier with the highest priority, the secondary carrier with the lowest load, the secondary carrier with the lowest frequency or the highest, and the secondary carrier with the smallest or largest index number.
- the network side device can be configured to one secondary carrier of the UE by signaling.
- the ACK/NACK feedback is the uplink subframe at the moment.
- the ACK/NACK feedback is uplink at the time
- One of the frequency bands of the subframe such as a standard pre-defined, such as a frequency band with a lower frequency point, etc., or the network side notifies one frequency band of the UE by signaling, or selects one frequency band with the highest priority according to the priority of each frequency band
- the ACK/NACK feedback is a specific secondary carrier (for example, one of the configured secondary carriers with the highest priority) in the configured secondary carrier of the uplink subframe, or ACK
- the /NACK feedback is at this time the configured secondary carrier on at least two frequency bands of the uplink subframe.
- the method further includes:
- Determining the priority of each secondary carrier in the first secondary carrier including: according to the first uplink subframe, the ACK/NACK load corresponding to the first uplink subframe on each secondary carrier of the uplink subframe, or the frequency of each secondary carrier , or the index number configuration of each secondary carrier;
- determining a priority for the secondary carrier configured to the UE, where the method includes: determining, for each time, the priority of the subframe corresponding to the same time frame as the priority subframe of the uplink subframe, and determining the auxiliary of the first secondary carrier
- the priority of the carrier includes: obtaining a priority of all the secondary carriers in the uplink subframe at the time when the first uplink subframe is located.
- the priority of the primary carrier configured for the UE is determined.
- the priority of the primary carrier may be set to be the highest.
- the priority may be pre-defined according to some information, such as setting a priority according to the carrier label.
- the network side device and the UE may each determine the priority of the carrier.
- the priority may also be set by the network side device, and then configured to the UE by using the signaling.
- the signaling may be RRC (Radio Resource Control) dedicated signaling or PDCCH information.
- the label of the control channel unit CCE that the PDCCH occupies corresponds to the ACK/NACK channel resource; the PDCCH information indicates the scheduling information of the physical downlink shared channel PDSCH carried by the downlink subframe, including: a label of a CCE in the CCE occupied by the PDCCH Indicates ACK/NACK channel resources.
- This method is called an implicit indication method and is applicable to the case where the network side device only schedules one secondary carrier for the UE and does not schedule the primary carrier.
- the method further includes: the network side device reserves, by using RRC dedicated signaling, one ACK/NACK resource set, and at least one ACK/NACK included in the ACK/NACK resource set, for the UE to use the subframe for feeding back ACK/NACK.
- the channel resource is on one or more secondary carriers, and each ACK/NACK channel resource in the ACK/NACK resource set is carried on a unique secondary carrier;
- the PDCCH information indicates the ACK/NACK channel resource corresponding to the PDSCH, including:
- the network side device uses TPC (Transmit Power Control) or DAI (Downlink Assignment Index) in the PDCCH information that is sent to the UE as an ARI (ACK/NACK Resource Indicator).
- the ARI is used to indicate an ACK/NACK channel resource for the UE to feed back ACK/NACK in the ACK/NACK resource set, and the carrier where the ACK/NACK channel resource is located is a carrier used by the UE to feed back ACK/NACK.
- This method is called ARI explicit indication method and is applicable to the case where multiple carriers are scheduled in one downlink subframe.
- the UE receives the RRC dedicated signaling sent by the network side device, and acquires, according to the RRC dedicated signaling, an ACK/NACK resource set reserved by the UE on the subframe used for feeding back the ACK/NACK, ACK.
- At least one ACK/NACK channel resource included in the /NACK resource set is on one or more secondary carriers, and each ACK/NACK channel resource in the ACK/NACK resource set is carried on a unique secondary carrier;
- step S22 determining, according to the PDCCH information, the ACK/NACK channel resource corresponding to the PDSCH, including:
- the UE acquires the TPC or DAI used as the ACK/NACK channel resource indication ARI in the PDCCH information sent by the network side device, and determines the ACK/NACK channel resource used for the UE to feed back the ACK/NACK in the ACK/NACK resource set according to the ARI, ACK/
- the carrier where the NACK channel resource is located is a carrier used by the UE to feed back ACK/NACK.
- the UE acquires a TPC or DAI used as an ACK/NACK channel resource indication ARI, including:
- the UE selects one of the secondary carriers corresponding to the uplink subframe in the first uplink subframe as the third secondary carrier, and uses the TPC command word in the PDCCH information corresponding to the PDSCH carried on the third secondary carrier as the TPC command word;
- the TPC command words in the PDCCH information corresponding to the other PDSCHs are used as ARIs, and the other PDSCHs are carried on one or more secondary carriers other than the third secondary carrier, and are carried in multiple secondary carriers on other PDSCHs.
- the ARI values are equal.
- the PDCCH implicitly indicates the corresponding ACK/NACK resource, and the secondary carrier needs to display the corresponding ACK/NACK resource by using the ARI.
- the secondary carrier may be invoked, and the corresponding ACK/NACK resource may be implicitly indicated by using the PDCCH, thereby saving signaling resource overhead.
- the network side device uses the TPC in the PDCCH information as the ARI, and the network side device selects one of the secondary carriers corresponding to the uplink subframe in the first uplink subframe, and selects one as the third secondary carrier, and the third secondary carrier is in the first
- the uplink subframe corresponds to the secondary carrier with the highest priority among the secondary carriers of the uplink subframe
- the TPC command word in the PDCCH information corresponding to the PDSCH carried on the third secondary carrier is used as the TPC command word
- scheduling the PDCCH corresponding to the other PDSCH The TPC command word in the information is used as the ARI, and the other PDSCH is carried on one or more secondary carriers other than the third secondary carrier, and the ARI value is used when the other PDSCH is carried on multiple secondary carriers. Equal.
- the PDCCH is a PDCCH that schedules at least two carriers other than the highest priority carrier
- at least two ARIs in the PDCCH may indicate ACK/ based on the same or different ACK/NACK resource set.
- the NACK resource is located on one of the at least two carriers.
- the ARI in the PDCCH may indicate an ACK/NACK resource based on the same ACK/NACK resource set, for example, scheduling ARI1 in the PDCCH of the secondary carrier 1, and scheduling ARI2 in the PDCCH of the secondary carrier 2, in one
- the ACK/NACK resource is indicated in the ACK/NACK resource set, and the overhead of the ACK/NACK resource reservation is saved.
- the ARIs in the PDCCH may also be indicated based on different sets of ACK/NACK resources.
- a priority may be set for each carrier, and the carrier with the highest priority is the first carrier, and the remaining carriers are the second carrier.
- subframe n is an uplink subframe for the three carriers
- the priority is set to Pcell higher than Scdll is higher than Scell2
- subframe n is used for feedback subframe.
- the ACK/NACK corresponding to the PDSCH scheduled on p, and the subframe p is a downlink subframe for the three carriers. If the three subframes are allocated to the UE in the downlink subframe p network side device, the UE will feed back three ACKs corresponding to the downlink subframe p of the three carriers on the resource indicated by ARI1 in the PDCCH1 of the scheduling Scell1.
- the UE if the UE misses PDCCH1, the UE will feed back two ACK/NACKs corresponding to the downlink subframe p of the Pcell and the Scdl2 on the resource indicated by the ARI2 in the PDCCH2 of the scheduling Scell2, and the network side device passes the pair of ARI1 and ARI2.
- the blind detection of the indicated ACK/NACK resource the UE is missed by the PDCCH1, and only two ACK/NACK information are detected on the ACK/NACK resource, because the network side device considers that the UE does not receive the PDCCH1, and considers that the UE does not
- the ACK/NACK corresponding to the PDCCH1 is fed back, and thus the detection performance of the ACK/NACK is improved due to the decrease in the number of detected ACK/NACK bits.
- the network side device only schedules the Pcell and the Scell2 to the UE in the downlink subframe p, the UE The two ACK/NACK resources corresponding to the downlink subframe p of the Pcell and the Scdl2 are fed back on the resource indicated by the ARI2 of the PDCCH2 of the Scell2, and the network side device directly detects only the corresponding Pcell and Scell2 on the ACK/NACK resource indicated by the ARI2.
- the network side device indicates that the ACK/NACK channel resource corresponding to the PDSCH is carried in the first uplink subframe on the secondary carrier by using the PDCCH information, and the time of the first uplink subframe is a downlink subframe on the primary carrier, so that The UE feeds back the ACK/NACK corresponding to the PDSCH on the ACK/NACK channel resource located in the first uplink subframe of the determined secondary carrier, so that the ACK/NACK can also be fed back during carrier aggregation of different uplink and downlink subframe configurations.
- the method for receiving the acknowledgement or non-confirmation indication information in the time division duplex TDD system may specifically include:
- the network side device sends physical downlink control channel PDCCH information to the UE in a downlink subframe, where the PDCCH information indicates scheduling information of a physical downlink shared channel PDSCH carried by the downlink subframe; the PDCCH information indication An acknowledgement ACK/non-acknowledgement NACK channel resource corresponding to the PDSCH, the ACK/NACK channel resource is carried on a first uplink subframe on the secondary carrier, and the first uplink subframe is according to the PDSCH and the The timing relationship between the ACK/NACK corresponding to the PDSCH determines that the time at which the first uplink subframe is located is a downlink subframe on the primary carrier;
- the network side device receives the ACK/NACK fed back by the UE on the first uplink subframe of the secondary carrier where the ACK/NACK channel resource is located.
- the time at which the first uplink subframe is located is an uplink subframe on the first secondary carrier.
- the ACK/NACK channel resource is carried on the first uplink subframe of the first secondary carrier
- the ACK/NACK channel resource is carried on a first uplink subframe of one of the first secondary carriers
- the one of the first secondary carriers is one of the following secondary carriers: the secondary carrier with the highest priority, the secondary carrier with the lowest load, the secondary carrier with the lowest frequency, and the secondary carrier with the smallest index number.
- the network side device configures a secondary carrier to the UE by using signaling.
- the ACK/NACK channel resource is carried in the first uplink subframe of the highest priority secondary carrier in the first secondary carrier
- Determining the priority of each secondary carrier in the first secondary carrier including: according to the first uplink subframe being an ACK/NACK load corresponding to the first uplink subframe on each secondary carrier of the uplink subframe, Or the frequency of each secondary carrier, or the index number of each secondary carrier;
- the method further comprises:
- Determining a priority for the secondary carrier to be configured for the UE specifically, determining, for each time, a priority for all the secondary carriers in the uplink subframe for the subframe corresponding to the same time;
- the ACK/NACK channel resource is carried on a first uplink subframe on the second secondary carrier.
- the label of the control channel unit CCE occupied by the PDCCH corresponds to the ACK/NACK channel resource
- the PDCCH information indicates the scheduling information of the physical downlink shared channel (PDSCH) carried by the downlink subframe, and includes:
- the ACK/NACK channel resource is indicated by a label of one CCE in the CCE occupied by the PDCCH.
- the method further includes: the network side device controlling the RRC dedicated signaling by using the radio resource to reserve one for the UE on the subframe for feeding back the ACK/NACK ACK/NACK resource set, at least one ACK/NACK channel resource included in the ACK/NACK resource set is on one or more secondary carriers, and each ACK/NACK channel resource bearer in the ACK/NACK resource set On a unique secondary carrier;
- the PDCCH information indicates an ACK/NACK channel resource corresponding to the PDSCH, and includes:
- the network side device uses a transmit power control TPC or a downlink allocation indication DAI in the PDCCH information that is sent to the UE as an ACK/NACK channel resource indication ARI, where the ARI is used to indicate the ACK/NACK resource set. And transmitting, by the UE, the ACK/NACK channel resource of the ACK/NACK, where the carrier where the ACK/NACK channel resource is located is a carrier used by the UE to feed back the ACK/NACK.
- the network side device uses the TPC in the PDCCH information as an ARI, and includes:
- the network side device selects one of the secondary carriers corresponding to the uplink subframe as the third secondary carrier
- the method further includes:
- Determining a priority of the secondary carrier configured to the UE includes: determining, for each time, a priority for all the secondary carriers of the uplink subframe for the subframe corresponding to the same time;
- the third secondary carrier is a secondary carrier with the highest priority among the secondary carriers corresponding to the uplink subframe in the first uplink subframe.
- determining that the subframe corresponding to the same time is the priority of all the secondary carriers of the uplink subframe includes:
- the subframe is a load condition of ACK/NACK on each secondary carrier of the uplink subframe, or a frequency of each secondary carrier, or an index number of each secondary carrier.
- the UE feeds back an ACK/NACK corresponding to the PDSCH on the determined ACK/NACK channel resource, where the ACK/NACK channel resource is located on the first uplink subframe of the determined secondary carrier.
- the method further includes: receiving, by the UE, the radio resource control RRC dedicated signaling sent by the network side device, and acquiring, by using the RRC dedicated signaling, the network side device as the UE in the feedback
- the determining the ACK/NACK channel resource corresponding to the PDSCH according to the PDCCH information includes:
- the UE acquires a transmit power control TPC or a downlink assignment indicator DAI used as an ACK/NACK channel resource indication ARI in the PDCCH information sent by the network side device, and determines, in the ACK/NACK resource set, according to the ARI.
- the UE feeds back the ACK/NACK channel resource of the ACK/NACK, and the carrier where the ACK/NACK channel resource is located is a carrier used by the UE to feed back the ACK/NACK.
- the UE acquiring the TPC or DAI used as the ACK/NACK channel resource indication ARI includes:
- the UE selects one of the secondary carriers corresponding to the uplink subframe in the first uplink subframe as the third secondary carrier;
- the other PDSCHs are carried on one or more secondary carriers other than the third secondary carrier, and when the other PDSCHs are carried on multiple secondary carriers, the ARIs are equal.
- the time at which the first uplink subframe is located is an uplink subframe on the first secondary carrier.
- the method further Includes:
- the method further comprises:
- the secondary carrier carried by the ACK/NACK channel resource.
- the label of the control channel unit CCE occupied by the PDCCH corresponds to the ACK/NACK channel resource; Determining the ACK/NACK channel resource corresponding to the PDSCH according to the indication of the PDCCH information, including:
- the ACK/NACK channel resource is determined by a label of one CCE in the CCE occupied by the PDCCH.
- This embodiment provides a method of confirming or not confirming the transmission of the indication information in a TDD system or the like.
- the method may be performed by a network side device, and specifically includes:
- S34 Determine a first channel resource from the at least two different ACK/NACK channel resources for the UE to feed back ACK/NACK.
- the method for confirming or not confirming the transmission of the indication information in the TDD system provided in this embodiment.
- the method may be performed by the UE, and specifically includes:
- the UE receives, by the network side device, the information about the first channel resource that is used by the UE to feed back the ACK/NACK, and the first channel resource is at least two between the ACK/NACK corresponding to the PDSCH and the PDSCH by the network side device. Timing relationships, determining at least two different
- ACK/NACK channel resources and determined from at least two different ACK/NACK channel resources
- S43 The UE feeds back, to the network side device, the ACK/NACK corresponding to the PDSCH on the first channel resource.
- At least two timing relationships include at least corresponding carriers, and/or corresponding to the same one Timing relationship of different uplink subframes on the carrier.
- the at least two different ACK/NACK channel resources include: ACK/NACK channel resources on uplink subframes carried on different carriers at the same time 7 and/or ACK/NACK channel resources on different uplink subframes .
- the ACK/NACK channel resources on different uplink subframes may be different uplink subframes on different carriers, or different uplink subframes on the same carrier.
- S34 determining a first channel resource from at least two different ACK/NACK channel resources, including:
- S35 Notify the UE by signaling the first channel resource, including one of the following:
- S42 the UE receives the information of the first channel resource used by the network side device to notify the UE to feed back the ACK/NACK, including one of the following:
- the UE receives the newly added bit of the PDCCH information, the TPC, the first scrambling code corresponding to the first channel resource of the DAL, or the first PDCCH time-frequency resource location corresponding to the first channel resource, and is notified by the UE for the UE to feed back the ACK/ The first channel resource of the NACK.
- the signaling may be physical layer signaling (such as PDCCH information), or RLC (Radio Link Control) layer signaling, or MAC (Media Access Control) layer signaling, or RRC. (Radio Resource Control) layer signaling.
- the ACK/NACK of the secondary carrier can be adjusted to the ACK/NACK resource of the primary carrier, and the ACK/NACK of the primary carrier can also be adjusted to the ACK/NACK resource of the secondary carrier. Description.
- the ACK/NACK for the secondary carrier can be adjusted to the feedback on the ACK/NACK resource of the primary carrier:
- the ACK/NACK corresponding to the downlink subframes 0 and 9 on the secondary carrier subframe 7 can be adjusted to the primary carrier feedback, and can be adjusted to the subframe 4 of the primary carrier for feedback according to the timing relationship of the primary carrier.
- the network side device may use the special value of the DAI in the PDCCH scheduled by the downlink subframes 0, 9 (such as DAI equal to 4) or a state of the TPC to indicate the downlink sub-subframe on the I-subcarrier sub-frame 7.
- the ACK/NACK corresponding to frames 0 and 9 is adjusted to be transmitted to subframe 4 of the primary carrier, and the ACK/NACK resource may be indicated by the TPC in the PDCCH or an additional ACK/NACK resource may be reserved for the handover separately.
- This additional resource refers to a resource other than the set of resources indicated by the ARI.
- the above adjustment method reduces the load and feedback delay of the ACK/NACK on the secondary carrier subframe 7. Specifically, if the ACK/NACK corresponding to the subframes 0 and 9 is fed back on the secondary carrier subframe 7, the feedback delay is 7 and 8, respectively, and the feedback delay is 4 and 5 respectively.
- the ACK/NACK for the primary carrier can be adjusted to the feedback on the ACK/NACK resource of the secondary carrier:
- the ACK/NACK corresponding to the downlink subframe 1 on the primary carrier subframe 2 can be adjusted to the secondary carrier feedback, and can be adjusted to the subframe 7 of the secondary carrier for feedback according to the timing relationship of the secondary carrier.
- the network side device may use the special value of the DAI in the PDCCH scheduled by the downlink subframe 1 (such as DAI equal to 4) or a state of the TPC, indicating that the downlink subframe 1 on the primary carrier subframe 2 corresponds to
- the ACK/NACK is adjusted to the subframe 7 of the secondary carrier for feedback, and the ACK/NACK resource may be indicated by the TPC (or DAI) in the PDCCH, or an additional ACK/NACK resource may be reserved for the handover separately.
- the additional resource refers to a resource other than the set of resources indicated by the ARI.
- the network side device configures at least two carriers for the UE, including one primary carrier and at least one secondary carrier, and sends PDCCH information to the UE in one downlink subframe, where the PDCCH information indicates scheduling information of the PDSCH carried by the downlink subframe.
- Determining at least two different ACK/NACK channel resources according to at least two timing relationships between the ACK/NACK corresponding to the PDSCH and the PDSCH, and determining a first channel resource from at least two different ACK/NACK channel resources The source is used for the UE to feed back the ACK/NACK, and the first channel resource is notified to the UE by signaling, and the ACK/NACK fed back by the UE on the first channel resource is received, so that the ACK can be fed back when the carrier aggregation of different uplink and downlink subframe configurations is performed. /NACK. In addition, it is also possible to balance the load of ACK/NACK on the carrier and reduce the ACK/NACK feedback delay.
- the embodiment of the invention further provides a method for confirming or not confirming the transmission of the indication information.
- the system to which this embodiment is applicable may be a TDD system, an FDD system, or a carrier aggregation system of TDD and FDD.
- the method may be performed by a network side device, and specifically includes:
- the network side device configures at least two carriers for the UE, including one primary carrier and at least one secondary carrier.
- the primary carrier can adopt one of two modes of FDD and TDD. Regardless of which duplex mode carrier the primary carrier is, the secondary carrier can adopt one of FDD and TDD duplex modes.
- the primary carrier and the secondary carrier may also be carriers of other modes, as long as the solution of the present invention can be implemented, which is not limited herein.
- the primary carrier in the present invention may be a carrier for the UE to independently access, or a carrier that can be camped in an idle state, or a carrier for the UE to perform radio link failure detection; the primary carrier of the present invention may also be unavailable for the UE.
- the network side device sends PDCCH information to the UE in a first downlink subframe, where the PDCCH information indicates scheduling information of the PDSCH carried in the second downlink subframe.
- the first downlink subframe and the second downlink subframe may be the same subframe, or may be different subframes.
- the first downlink subframe and the second downlink subframe may be on the same carrier or on different carriers, and the latter is also called cross-carrier scheduling.
- the PDCCH may be a PDCCH demodulated based on a cell-specific reference signal in an LTE system, or may be an enhanced PDCCH demodulated based on a UE-specific reference signal in an LTE system.
- the subframe in which the selected first timing relationship is the same as the second downlink subframe at the time of the second downlink subframe is a downlink subframe, and the condition may be referred to as a first condition.
- the at least two timing relationships may include a timing relationship corresponding to different carriers; and/or include a timing relationship corresponding to the same carrier.
- the downlink subframe is in the The uplink subframes corresponding to the ACK/NACK feedback corresponding to the carrier are different.
- the timing relationship between the subframe where the PDSCH is located on the FDD carrier and the subframe where the ACK/NACK is located may be (n, n+4), that is, if the UE is in the subframe.
- the ACK/NACK corresponding to the PDSCH is fed back in the subframe n+4; for the timing relationship on the TDD carrier, it may be expressed as (n, n+k), where k may be greater than or equal to 4,
- the fourth subframe spaced from the PDSCH is not necessarily an uplink subframe. In particular, the guarantee that k is greater than or equal to 4 is for the consideration of the processing delay of the PDSCH, and other values may be used in the future.
- the ACK/NACK corresponding to the PDSCH can be fed back in one uplink subframe on the carrier.
- Another uplink subframe may be fed back on the carrier, and the different uplink subframes correspond to different timing relationships.
- the carrier may be a TDD carrier, an FDD carrier, or another carrier.
- a timing relationship may be selected, for example, a random selection, or may be selected according to different carriers corresponding to the timing relationship or different uplink subframes used for ACK/NACK feedback.
- the selected first timing relationship first needs to satisfy the condition that the subframe corresponding to the second downlink subframe time on the corresponding first carrier is the downlink subframe.
- the timing relationship corresponding to the carrier with the smallest load may be selected according to the load condition of the ACK/NACK channel on the carriers; or according to the ACK/NACK feedback delay on the carriers, The timing relationship corresponding to the carrier with the smallest delay is fed back; or the timing relationship corresponding to the carrier with the smallest transmit power required by the UE is selected.
- the transmission power it is assumed that the UE is far away from the macro cell carrying the primary carrier, and is closer to the micro cell carrying the secondary carrier, and the network side device may select the timing relationship corresponding to the secondary carrier to the UE. Because the selection of the secondary carrier causes the UE to require a transmission power that is smaller than the transmission power required by the UE when the primary carrier is selected.
- the load, feedback delay and transmission power may be selected according to the load condition of the ACK/NACK channel on the carriers.
- the timing relationship corresponding to the uplink subframe with the smallest load may be selected according to the load condition of the ACK/NACK channel on different uplink subframes; or the feedback delay may be selected according to the ACK/NACK feedback delay on the uplink subframes. Delays the timing relationship corresponding to the smallest uplink subframe. Of course, it is also possible to comprehensively consider the load and feedback delay.
- the third uplink subframe in the foregoing step determining, according to the first timing relationship and the subframe in which the PDSCH is located, that is, the foregoing second downlink subframe, determining, by the UE, the ACK/NACK corresponding to the PDSCH.
- the third uplink subframe determining, according to the first timing relationship and the subframe in which the PDSCH is located, that is, the foregoing second downlink subframe.
- the first carrier may be determined according to the first timing relationship. Specifically, whether the different timing relationships correspond to different carriers or different timing relationships correspond to the same carrier, the first carrier corresponding to the first timing relationship may be determined according to the correspondence between the timing relationship and the carrier.
- the foregoing S163 and S164 may be further implemented by first determining the first carrier, and determining a corresponding first timing relationship according to the determined first carrier. details as follows:
- S163' Determine a first carrier used by the UE to send an ACK/NACK corresponding to the PDSCH. If different timing relationships correspond to different carriers, one carrier may be randomly selected as the first carrier. Alternatively, the carrier with the smallest load may be selected as the first carrier according to the load condition of the ACK/NACK channel on the carriers; or the carrier with the smallest feedback delay may be selected as the first carrier according to the ACK/NACK feedback delay on the carriers; Alternatively, the carrier with the smallest transmission power required by the UE is selected as the first carrier. Of course, the load, feedback delay, and transmit power can also be considered.
- the timing relationship corresponding to the selected carrier needs to be ensured, and the subframe that satisfies the same time on the first carrier corresponding to the second downlink subframe should be the downlink subframe.
- a condition, thereby ensuring that the determined third uplink subframe is a subframe that the UE can use for ACK/NACK feedback.
- S164' selecting one of at least two timing relationships between the subframe in which the PDSCH is located and the subframe in which the ACK/NACK corresponding to the PDSCH is located as the first timing relationship, and determining, corresponding to the first timing relationship, The UE sends a third uplink subframe of the ACK/NACK corresponding to the PDSCH.
- the first carrier determined in S163' may be used to determine the location.
- Corresponding timing relationship the third uplink subframe for the UE to send the ACK/NACK corresponding to the PDSCH is determined according to the first timing relationship and the subframe in which the PDSCH is located, that is, the second downlink subframe.
- the timing relationship corresponding to the least loaded uplink subframe may be selected according to the load condition of the ACK/NACK channel on different uplink subframes; or the feedback delay may be selected according to the ACK/NACK feedback delay on the carriers.
- the timing relationship corresponding to the uplink subframe may be also possible to comprehensively consider the load and feedback delay. For this case, since the first timing relationship is determined according to the uplink subframe, the uplink subframe used to determine the first timing relationship is the ACK/NACK for the UE to send the PDSCH. Three uplink subframes.
- the selected first timing relationship also needs to satisfy the subframe on which the corresponding first carrier and the second downlink subframe are the same as the downlink.
- the frame condition is such that the determined third uplink subframe is a subframe that the UE can use for ACK/NACK feedback.
- the selection needs to be performed again, so that the first timing relationship satisfies the condition, in other words
- the step of indicating the S165 may be: indicating the selected first timing relationship to the UE. That is, the related information corresponding to the third uplink subframe and the first carrier is the first timing relationship. Specifically, the first timing relationship may be indicated by layer 1 signaling and/or RRC signaling.
- the network side device may only indicate the selected first carrier to the UE, and correspondingly, the UE may determine the first timing relationship corresponding to the first carrier according to the first carrier, and further according to the first The certain time relationship determines a third uplink subframe for the UE to send the ACK/NACK corresponding to the PDSCH. Therefore, the step of indicating the S165 may specifically be:
- the selected first carrier is indicated to the UE. That is, the related information corresponding to the third uplink subframe and the first carrier is the first carrier.
- the first carrier may be indicated by layer 1 signaling and/or RRC signaling.
- the information about the third uplink subframe and the first carrier may be the third uplink subframe and the first carrier information itself.
- the network side device may use the third uplink subframe and the first carrier.
- the UE is indicated by layer 1 signaling and/or RRC signaling.
- S166 Determine, in a third uplink subframe of the first carrier, a first channel resource used by the UE to feed back an ACK/NACK corresponding to the PDSCH, and indicate the first channel resource to the UE.
- the first channel resource may be randomly selected, or may be selected by the network side device according to the channel resource load condition, etc., which is not specifically limited in the present invention.
- the ACK/NACK channel resource may be indicated to the UE in an implicit indication manner.
- the ACK/NACK channel resource may be implicitly associated with the CCE label occupied by the PDCCH, so that the network side device uses the CCE to schedule the PDCCH, and the network side device should go to the ACK/NACK channel resource corresponding to the CCE to receive the ACK sent by the UE.
- the UE may determine the channel resource corresponding to the ACK/NACK feedback for the local UE according to the CCE that schedules the PDCCH, and the CCE may also be the enhanced CCE corresponding to the enhanced PDCCH.
- the ACK/NACK channel resource may also use a signaling indication, such as one or a group of ACK/NACK channel resources reserved by RRC signaling. If one is reserved, the network side device goes to the channel resource to receive the UE. ACK/NACK, correspondingly, the UE can learn that the reserved channel resource is a channel resource used for ACK/NACK feedback of the UE; if a group is reserved, the network side device also needs to dynamically indicate this through the PDCCH.
- a signaling indication such as one or a group of ACK/NACK channel resources reserved by RRC signaling. If one is reserved, the network side device goes to the channel resource to receive the UE. ACK/NACK, correspondingly, the UE can learn that the reserved channel resource is a channel resource used for ACK/NACK feedback of the UE; if a group is reserved, the network side device also needs to dynamically indicate this through the PDCCH.
- the UE can know that the resource dynamically indicated by the PDCCH in the group of channel resources is the UE can be used for ACK/NACK
- the channel resource to be fed back, for the network side device needs to receive the ACK/NACK sent by the UE on the dynamically indicated channel resource.
- the PDCCH may be dynamically indicated by a bit or a scrambling code in the PDCCH.
- the network side device may indicate the same signaling to the UE, or may indicate by using different signaling.
- S167 Receive the first channel resource of the UE on the third subframe on the first carrier.
- the ACK/NACK fed back on the source.
- the UE determines two carriers to be configured, including one primary carrier and at least one secondary carrier.
- the primary carrier and the secondary carrier are the same as the foregoing step S161, and details are not described herein again.
- the UE receives PDCCH information that is sent by the network side device to the UE in a first downlink subframe, where the PDCCH information indicates scheduling information of the PDSCH carried in the second downlink subframe.
- 5173 Obtain the indication information that is sent by the network side device to the UE, and determine, according to the indication information, a third uplink subframe and a first carrier that are used by the network side device to feed back the ACK/NACK.
- the indication information is related to the third uplink subframe used by the network side device for the ACK/NACK and the related information corresponding to the first carrier, where the network side device may perform layer 1 signaling and/or RRC. Signaling is sent to the UE.
- the related information may be the first timing relationship selected by the network side device or the first carrier determined by the network side device, as described in the foregoing step S165.
- the subframe corresponding to the second downlink subframe at the time corresponding to the second downlink subframe should be a downlink subframe, so that the determined third uplink subframe is ensured.
- the UE can be used for subframes of ACK/NACK feedback.
- the third uplink subframe and the first carrier are determined according to the indication information, which may be: according to the first timing relationship and the subframe where the PDSCH is located, that is, the second downlink And determining, by the UE, a third uplink subframe that is used by the UE to send the ACK/NACK corresponding to the PDSCH, and determining a first carrier corresponding to the first timing relationship according to the correspondence between the timing relationship and the carrier and the first timing relationship.
- the UE may determine the first carrier according to the correspondence between the first carrier and the carrier and the timing relationship. Corresponding first timing relationship, and determining a corresponding third uplink subframe according to the first timing relationship and the subframe in which the PDSCH is located, that is, the second downlink subframe. 5174: Acquire a first channel resource that is sent by the network side device to the UE for the UE to feed back the ACK/NACK corresponding to the PDSCH.
- the UE may determine the first ACK/NACK channel resource by receiving layer 1 signaling and/or RRC signaling. Specifically, if the network side device adopts an implicit indication manner, for example, the ACK/NACK channel resource may implicitly correspond to the CCE label occupied by the PDCCH, so that the UE receives the PDCCH on which CCE or CCEs, correspondingly, the UE It is possible to determine which CCE or which CCE corresponding ACK/NACK channel resource is the ACK/NACK channel resource that the network side device configures to the UE, so that ACK/NACK can be sent on the channel resource.
- the network side device can use the signaling indication mode, for example, to reserve one or a group of ACK/NACK channel resources through RRC signaling, if one is reserved, the UE can determine that the channel resource is configured for the network side device. The ACK/NACK channel resource of the UE, so that the ACK/NACK can be sent to the channel resource. If a group is reserved, the UE also needs to dynamically acquire which one of the ACK/NACK channel resources is used as the current through the PDCCH. The channel resource of the ACK/NACK is fed back. Correspondingly, the UE sends an ACK/NACK to the dynamically acquired channel resource.
- the dynamic indication can be performed by using a bit or a scrambling code in the PDCCH.
- the information in the two steps S173 and S174 can be obtained by obtaining the same signaling or by using different signaling.
- S175 Send an ACK/NACK corresponding to the PDSCH on the first channel resource on the third uplink subframe on the first carrier.
- the carrier in the present invention corresponds to a serving cell.
- one serving cell includes one downlink carrier and one uplink carrier corresponding to the downlink carrier; for the TDD system, one serving cell corresponds to one TDD carrier.
- the above layer 1 signaling may correspond to the PDCCH.
- the UE receives the newly added bit of the PDCCH information, the TPC, the first scrambling code corresponding to the first channel resource of the DA, or the first PDCCH time-frequency resource location corresponding to the first channel resource, and the UE is used to feed back the ACK/ The first channel resource of the NACK.
- a system for carrier aggregation of at least two TDD carriers configured for different uplink and downlink subframes passes at least two timing relationships Selecting a first timing relationship, and the subframe corresponding to the second downlink subframe time on the corresponding first carrier is a downlink subframe, so that a subframe that can be used for ACK/NACK feedback can be configured for the UE,
- the carrier and the corresponding channel resources so that the UE not only ensures that the UE can perform ACK/NACK feedback, but also enables the UE to perform flexible ACK/NACK feedback.
- the ACK/NACK may be selected to be fed back to different carriers or different subframes of the same carrier, so the scheme may also balance the load of ACK/NACK feedback on each carrier or each subframe. Further, when the first certain time relationship or the first carrier is selected according to the ACK/NACK feedback delay, the delay of the ACK/NACK feedback can be further reduced.
- a different carrier transmits a network side device in a different geographical location
- a macro base station corresponds to one carrier and a micro base station corresponds to another carrier
- the network side device can select a carrier with a smaller transmit power required by the UE to perform ACK/NACK. Feedback, thereby saving the power consumption of the UE and improving the reception performance of the network side device for ACK/NACK.
- the ACK/NACK of the secondary carrier can be adjusted to the ACK/NACK resource of the primary carrier, and the ACK/NACK of the primary carrier can also be adjusted to the ACK/NACK resource feedback of the secondary carrier.
- the network side device includes:
- the network side device notifies the UE of the ACK/NACK feedback mode by signaling, so that the UE performs ACK/NACK feedback according to the one ACK/NACK feedback mode and the pre-configured ACK/NACK timing relationship.
- the ACK/NACK feedback mode may be that the ACK/NACK may be fed back on the Pcell or a Scdl, or the ACK/NACK feedback mode may be that the ACK/NACK can only be fed back on a certain carrier, the one.
- the carrier can be a primary carrier, or a carrier at a low frequency point.
- the pre-configured ACK/NACK timing relationship is a timing relationship that is known by the UE after receiving the signaling in the foregoing solution, and may be a timing relationship of an existing system, or a timing relationship modified according to an existing system. .
- the UE side includes:
- the foregoing embodiments of the present invention solve the technical problem that if the ACK/NACK is always fed back on the primary carrier, the ACK/NACK cannot be fed back in some scenarios, for example, when the timing relationship corresponds to the first.
- the subframe on the carrier that is the same as the subframe in which the downlink PDSCH is located is an uplink subframe, the first carrier corresponding to the timing relationship cannot be used to carry the ACK/NACK corresponding to the PDSCH.
- an uplink subframe on the legacy TDD carrier, or an uplink subframe on the dynamic subframe TDD carrier that can be used as uplink ACK/NACK feedback (the ACK/NACK feedback is determined by the second TDD configuration)
- scheduling With the downlink data PDSCH it is impossible to feed back ACK/NACK on the current TDD carrier according to the ACK/NACK timing relationship on the current TDD carrier or the ACK/NACK timing relationship in the second TDD configuration.
- the present invention provides yet another method of confirming or not confirming the transmission of indication information.
- the system to which the embodiments of the present invention are applicable may be a TDD system, an FDD system, or a carrier aggregation system of TDD and FDD.
- Step i2 The network side device sends PDCCH information to the UE in a fifth subframe on the one TDD carrier, where the PDCCH information indicates scheduling information of the PDSCH carried in a fourth uplink subframe.
- the fifth subframe may be an uplink subframe or a downlink subframe. And the fifth subframe is the same uplink subframe as the uplink subframe, and may be different uplink subframes.
- the fifth subframe may be on the TDD carrier or on other carriers.
- the fourth uplink subframe is a subframe temporarily used for transmitting downlink PDSCH data, and/or, the uplink subframe may carry an uplink ACK/NACK when the downlink PDSCH data is not transmitted.
- Step i3 Determine a second carrier that is sent by the UE to the ACK/NACK corresponding to the PDSCH, where the second carrier is a carrier other than the TDD carrier, and specifically may be an FDD carrier or a TDD carrier.
- Step i4 Determine a second timing relationship of the ACK/NACK feedback corresponding to the PDSCH, and determine a sixth subframe to feed back the ACK/NACK according to the second timing relationship.
- the sequence of the foregoing steps i3 and i4 can be exchanged, that is, the second timing relationship can be determined first, and then the second subframe and the sixth subframe in which the ACK/NACK feedback is located are determined according to the second timing relationship.
- Step i5 Determine a second channel resource for the UE to feed back ACK/NACK on the sixth subframe of the second carrier, and indicate the second channel resource to the UE.
- the fifth subframe may be an uplink subframe or a downlink subframe. And the fifth subframe is the same uplink subframe as the uplink subframe, and may be different uplink subframes.
- the fifth subframe may be on the TDD carrier or on other carriers.
- the fourth uplink subframe may be the third subframe in the foregoing configuration, that is, one uplink subframe in the second TDD configuration of the dynamic subframe TDD carrier.
- the fourth uplink subframe is an uplink subframe on the traditional TDD carrier (non-dynamic subframe TDD carrier) or an uplink subframe in the second TDD configuration of the dynamic subframe TDD carrier, so if the fourth uplink
- the downlink data transmission is scheduled on the subframe, that is, the PDSCH transmission, which is based on the ACK/NACK timing relationship on the legacy TDD carrier, or the ACK/NACK timing relationship on the dynamic subframe TDD carrier, that is, the ACK/NACK in the second TDD configuration.
- the timing relationship is that the ACK/NACK corresponding to the PDSCH cannot be fed back. Therefore, the ACK/NACK corresponding to the PDSCH needs to be sent on other carriers.
- the carrier that is ACK/NACK fed back is the carrier other than the current TDD carrier; if the number of carriers configured for the UE other than the current TDD carrier is greater than 1,
- the UE may determine, by using the layer 1 signaling or the RRC signaling sent by the network side device, the second carrier for the ACK/NACK feedback in the carrier other than the current TDD carrier.
- the UE may determine the second timing relationship by using the second carrier. Specifically, the timing relationship between the PDSCH and the ACK/NACK on the second carrier may be used as the second timing relationship.
- the sequence of the foregoing steps i3 and i4 can be exchanged, that is, the second timing relationship can be determined first, and then the second subframe and the sixth subframe in which the ACK/NACK feedback is located are determined according to the second timing relationship.
- the UE may determine the second timing relationship by receiving layer 1 signaling or RRC signaling sent by the network side device.
- Step j5 Determine a second channel resource on the sixth subframe of the second carrier for UE feedback ACK/NACKo
- the ACK/NACK channel resource may be in an implicit manner, for example, the ACK/NACK channel resource may be implicitly associated with the CCE label occupied by the PDCCH, so that the UE receives the CCE for the network side device to schedule the PDCCH, and correspondingly The UE sends an ACK/NACK to the ACK/NACK channel resource corresponding to the CCE.
- the CCE may also be an enhanced CCE corresponding to the enhanced PDCCH.
- the ACK/NACK channel resource may also use a signaling indication, such as through an RRC letter. Let one or a group of ACK/NACK channel resources be reserved. If one is reserved, the UE sends an ACK/NACK to the channel resource.
- the UE also needs to dynamically determine the group by receiving the PDCCH.
- ACK/NACK channel resources Which one is used as the channel resource for the current feedback ACK/NACK.
- the UE sends an ACK/NACK to the dynamically indicated channel resource. Specifically, it can be determined by receiving a bit or a scrambling code in the PDCCH.
- Step j6 The UE sends an ACK/NACK on the second channel resource on the sixth subframe on the second carrier.
- the network side device configures two carriers for the UE, where carrier 1 is an FDD carrier and carrier 2 is a TDD carrier, and the TDD carrier is a conventional TDD carrier, that is, a dynamic subframe configuration is not adopted, and the uplink and downlink configuration of the TDD carrier is assumed to be configured.
- carrier 1 is an FDD carrier and carrier 2 is a TDD carrier
- the TDD carrier is a conventional TDD carrier, that is, a dynamic subframe configuration is not adopted
- the uplink and downlink configuration of the TDD carrier is assumed to be configured.
- the configuration of 10 subframes of a radio frame is DSUDDDSUDD (down, down, down, down, down, and down)
- S represents a special subframe
- the subframe can transmit downlink data PDSCH but cannot transmit uplink PUSCH data. Therefore, it can be used as a downlink subframe.
- the network side device can schedule the PDSCHs on the 8 downlink subframes of the TDD carrier.
- the ACK/NACK corresponding to the PDSCHs can be sent on the uplink subframe of the TDD carrier or on the uplink subframe of the FDD carrier.
- the network side device may also schedule the downlink PDSCH data on the uplink subframe of the TDD carrier. Accordingly, if the uplink subframe of the TDD carrier is not used for feeding back the uplink ACK/NACK, the UE needs to monitor the PDCCH information on the uplink subframe.
- the network side device schedules the downlink PDSCH data on the uplink subframe, since the uplink subframe of the current TDD carrier has only the ACK/NACK feedback timing of the downlink subframe on the carrier, if the uplink is used as the downlink transmission, If the current TDD carrier does not have the ACK/NACK timing of the downlink transmission, the UE needs to determine the carrier where the ACK/NACK corresponding to the PDSCH is located, which may be determined by the UE itself, or may be allocated by the network side device, and the ACK/ The carrier of the NACK is a carrier other than the current TDD carrier.
- the UE needs to determine the channel resource used for ACK/NACK feedback, which may be configured by the network side device through layer 1 signaling or RRC signaling or a combination of layer 1 signaling and RRC signaling, such as by using bits in the PDCCH ( For example, ARI) displays the allocation, or implicitly allocates by CCE labeling, etc., or can also configure a set of ACK/NACK channel resources through RRC, and then use the bits in the PDCCH to determine one of the ACK/NACK channel resources.
- PDCCH For example, ARI
- ARI displays the allocation, or implicitly allocates by CCE labeling, etc., or can also configure a set of ACK/NACK channel resources through RRC, and then use the bits in the PDCCH to determine one of the ACK/NACK channel resources.
- the first TDD of the TDD carrier notified by the system message is configured to be 0, that is, the subframe is configured as "lower, upper, lower, upper, lower, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper, upper
- the timing relationship with the ACK/NACK operates in accordance with a second TDD configuration, which is configured by RRC proprietary signaling.
- the 4th, 5th subframes are configured as uplink subframes according to the first TDD, but can be used as downlink data transmission, and the corresponding uplink ACK/NACK feedback can be fed back according to the second TDD configuration, that is, feedback can be performed in the third Or two sub-frames, that is, 3, 8 are fixed uplink sub-frames, and four sub-frames 4, 5, 9 and 10 can be understood as dynamic sub-frames.
- the invention also provides a network side device.
- the network side device may be a device in a TDD system, an FDD system, or a carrier aggregation system of TDD and FDD.
- the network side device may include:
- a sending module configured to send PDCCH information to a UE on a fifth subframe on a TDD carrier, where the PDCCH information indicates scheduling information of a PDSCH carried on a fourth uplink subframe; and processing the module on the second carrier A second channel resource determined on the sixth subframe is indicated to the UE.
- the relationship between the fifth subframe and the fourth uplink subframe and the PDCCH information are as described in the corresponding method embodiments, and are not described here.
- the fourth uplink subframe may be an uplink subframe in a second TDD configuration of the dynamic subframe TDD carrier, where the second TDD is configured to determine a TDD configuration of a PDSCH and an ACK/NACK timing relationship on the TDD carrier, which may be configured by the RRC.
- Proprietary signaling configuration may be an uplink subframe in a second TDD configuration of the dynamic subframe TDD carrier, where the second TDD is configured to determine a TDD configuration of a PDSCH and an ACK/NACK timing relationship on the TDD carrier, which may be configured by the RRC.
- Proprietary signaling configuration Proprietary signaling configuration.
- a processing module configured to configure at least two carriers for the UE, including at least one TDD carrier, and determine a second carrier that is sent by the UE to the ACK/NACK corresponding to the PDSCH, where the second carrier is a carrier other than the TDD carrier, specifically a FDD carrier or a TDD carrier; determining a second timing relationship of the ACK/NACK feedback corresponding to the PDSCH, and determining a sixth subframe that feeds back the ACK/NACK according to the second timing relationship; and sixth in the second carrier A second channel resource is determined on the subframe for the UE to feed back ACK/NACK.
- the method for determining the second carrier, the second timing relationship, the sixth subframe, and the second channel resource is as described in the foregoing method embodiment, and details are not described herein again.
- a receiving module configured to receive an ACK/NACK sent by the UE on the second channel resource on the sixth subframe on the second carrier.
- the configuration may include: a configuration unit, a carrier determining unit, a timing relationship and a subframe determining unit, and a channel resource determining unit.
- the configuration unit is configured to configure at least two carriers for the UE, including at least one TDD carrier.
- a carrier determining unit configured to determine, by the UE, a second carrier that sends an ACK/NACK corresponding to the PDSCH.
- the timing relationship and subframe determining unit is configured to determine a second timing relationship of the ACK/NACK feedback corresponding to the PDSCH, and determine a sixth subframe that feeds back the ACK/NACK according to the second timing relationship.
- a channel resource determining unit configured to determine, on the sixth subframe determined by the timing relationship and the subframe determining unit, and on the second carrier determined by the carrier determining unit, a second channel resource for the UE Feedback ACK/NACK.
- the processing method in the foregoing processing module is as described in the foregoing corresponding method embodiment, and details are not described herein again.
- the invention also provides a user equipment.
- the user equipment can be a TDD system, an FDD system, or a device in a carrier aggregation system of TDD and FDD.
- the receiving module is configured to receive PDCCH information on a fifth subframe on the one TDD carrier, where the PDCCH information indicates scheduling of a PDSCH carried on a fourth uplink subframe
- a sending module configured to send, by the UE, an ACK/NACK on the second channel resource on the sixth subframe on the second carrier determined by the processing module.
- a channel resource determining unit configured to determine a second channel on the sixth subframe determined by the timing relationship and the subframe determining unit, and on the second carrier determined by the ACK/NACK feedback carrier determining unit
- the resource is used for UE feedback ACK/NACK.
- the UE will bind the ACK/NACK of this carrier to the state "1, 0, and feed back to the eNB, indicating that the number of ACKs is 1; but the eNB schedules 4
- the "1, 0" feedback from the UE will be considered to be 4, so the last 3 packets will be lost. This error occurs because the state of the UE feedback is "1, 0".
- the overlapping state represents two meanings.
- This embodiment provides a method for confirming or not confirming the transmission of indication information in a TDD system.
- the method may be performed by a network side device, where the method specifically includes:
- S53 Set DAI values in the PDCCH information corresponding to each downlink subframe in each group from 1 to 2 N -1 in sequence;
- S54 Send PDCCH information corresponding to the downlink subframe in each group to the UE.
- the downlink subframe corresponding to the ACK/NACK that needs to be fed back in the subframe n is divided into at least two groups, which may include,
- S63 Receive PDCCH information that is sent by the network side device on each downlink subframe in each group.
- S65 Send each group of corresponding generated ACK/NACKs to the network side device.
- the status indication of the DAI when the partial ACK/NACK is bound is as shown in Table 2.
- the ACK/NACK feedback information i.e., the ACK/NACK state
- the ACK/NACK feedback information has no overlapping state.
- the two carriers Pcell and Scell are configured for the UE, and the subframe 2 is an uplink subframe on both carriers and needs to feed back ACK/NACK; the uplink subframe 2 needs to feed back the ACK/NACK corresponding to the two carriers.
- the six downlink subframes are divided into two groups, each group includes a downlink subframe number of three, the first group is the downlink subframes 4, 5, and 6 of the Scell, and the second group is the downlink subframe 5, 6 and the Pcell.
- the downlink subframe 8 of the Scell, the second group is across different carriers; for the downlink subframes 4, 5 of the first group, 6, the DAI count is 1, 2, 3 respectively.
- the ACK/NACK feedback information is prevented from overlapping by changing the DAI counting manner, thereby avoiding ACK/NACK feedback information errors.
- this embodiment provides a network side device, where the network side device includes: a configuration module 101, configured to configure at least two carriers, including a primary carrier and at least one secondary carrier, for the user equipment UE;
- the processing module 102 is configured to generate physical downlink control channel PDCCH information for the UE, where the PDCCH information indicates scheduling information of the physical downlink shared channel PDSCH carried by the downlink subframe, and the PDCCH information indicates the acknowledged ACK/non-acknowledged NACK channel resource corresponding to the PDSCH.
- the ACK/NACK channel resource is carried in the first uplink subframe on the secondary carrier configured by the configuration module 101, and the first uplink subframe is determined according to the timing relationship between the ACK/NACK corresponding to the PDSCH and the PDSCH, and the first uplink subframe
- the primary carrier configured on the configuration module 101 is a downlink subframe;
- the receiving module 104 is configured to receive an ACK/NACK fed back by the UE on the first uplink subframe of the secondary carrier where the ACK/NACK channel resource indicated by the PDCCH information sent by the sending module 103 is located.
- the time at which the first uplink subframe is located is an uplink subframe on the first secondary carrier.
- the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module 102 is carried on the first uplink subframe of the first secondary carrier;
- the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module 102 is carried on the first uplink subframe of one secondary carrier in the first secondary carrier.
- the one secondary carrier in the first secondary carrier is one of the following secondary carriers: the secondary carrier with the highest priority, the secondary carrier with the lowest load, and the secondary carrier with the lowest frequency, and the index
- the secondary carrier with the smallest value is configured, and the network side device configures a secondary carrier to the UE through signaling. If the first secondary carrier is two or more, and the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module 102, the first uplink subframe of the secondary carrier with the highest priority carried in the first secondary carrier on,
- Processing module 102 further for
- Determining the priority of each secondary carrier in the first secondary carrier including: according to the first uplink subframe, the ACK/NACK load corresponding to the first uplink subframe on each secondary carrier of the uplink subframe, or the frequency of each secondary carrier Or the index number of each secondary carrier is configured, so that the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module 102 is carried on the first uplink subframe of the highest priority secondary carrier in the first secondary carrier;
- processing module 102 is further used to
- Determining the priority of the secondary carrier configured for the UE specifically, determining, for each time, the priority of all the secondary carriers in the uplink subframe for the subframe corresponding to the same time;
- Determining the priority of each secondary carrier in the first secondary carrier includes: obtaining a priority of all the secondary carriers in the uplink subframe at the time when the first uplink subframe is located, so that the PDCCH generated by the processing module 102 is obtained.
- the ACK/NACK channel resource indicated by the information is carried on the first uplink subframe of the highest priority secondary carrier in the first secondary carrier.
- the sending module 103 is further configured to: after determining that the ACK/NACK channel resource corresponding to the PDSCH is located in the secondary carrier, send the information of the determined one secondary carrier to the UE by using the PDCCH information.
- the network side device only schedules one secondary carrier for the UE and does not schedule the primary carrier, and the secondary carrier is the second secondary carrier.
- the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module 102 is carried on the first uplink subframe on the second secondary carrier.
- the label of the control channel element CCE occupied by the PDCCH corresponds to the ACK/NACK channel resource
- the PDCCH information generated by the processing module 102 indicates the scheduling information of the physical downlink shared channel PDSCH carried by the downlink subframe, and includes:
- the ACK/NACK channel resource is indicated by the label of one CCE in the CCE occupied by the PDCCH.
- the network side device also includes:
- a reservation module configured to reserve, by using a radio resource, RRC dedicated signaling, for the UE to reserve one ACK/NACK resource set, and at least one ACK included in the ACK/NACK resource set, on the subframe used for feeding back ACK/NACK
- the NACK channel resource is on one or more secondary carriers, and each ACK/NACK channel resource in the ACK/NACK resource set is carried on a unique secondary carrier;
- the PDCCH information generated by the processing module 102 indicates the ACK/NACK channel resource corresponding to the PDSCH, including:
- Transmit power control TPC or downlink allocation indication DAI in the PDCCH information that is sent to the UE is used as an ACK/NACK channel resource indication ARI, and the ARI is used to indicate that the ACK/NACK resource set reserved by the reservation module is used for UE feedback ACK/ The ACK/NACK channel resource of the NACK, and the carrier where the ACK/NACK channel resource is located is a carrier used by the UE to feed back ACK/NACK.
- the TPC in the PDCCH information generated by the processing module 102 is used as the ARI, and includes: selecting one of the secondary carriers corresponding to the uplink subframe in the first uplink subframe as the third secondary carrier wave;
- the TPC command words in the PDCCH information corresponding to the other PDSCHs are scheduled as ARIs, and the other PDSCHs are carried on one or more secondary carriers other than the third secondary carrier, and are carried in multiple PDSCHs on other PDSCHs.
- the ARI values are equal.
- the processing module 102 is also used to:
- the third secondary carrier is the secondary carrier with the highest priority among the secondary carriers corresponding to the uplink subframe in the first uplink subframe.
- the determining, by the processing module 102, that the subframe corresponding to the same time is the priority of all the secondary carriers of the uplink subframe includes:
- the subframe is a load condition of ACK/NACK on each secondary carrier of the uplink subframe, or a frequency of each secondary carrier, or an index number of each secondary carrier.
- the network side device provided in this embodiment may include:
- a configuration module configured to configure, by the user equipment UE, at least two carriers, including one primary carrier and at least one secondary carrier;
- a processing module configured to generate physical downlink control channel PDCCH information for the UE, where the PDCCH information indicates a scheduling channel resource of a physical downlink shared channel PDSCH carried by the downlink subframe, where the ACK/NACK channel resource is carried in the
- the first uplink subframe is determined according to a timing relationship between the PDSCH and an ACK/NACK corresponding to the PDSCH, where the first uplink sub-frame is determined according to a timing relationship between the ACK/NACK corresponding to the PDSCH and the PDSCH.
- the time at which the frame is located is a downlink subframe on the primary carrier configured by the configuration module;
- a sending module configured to send, to the UE, PDCCH information generated by the processing module on a downlink subframe
- a receiving module configured to receive the ACK/NACK 0 fed back by the UE on the first uplink subframe of the secondary carrier where the ACK/NACK channel resource indicated by the PDCCH information sent by the sending module is located
- the time at which the first uplink subframe is located is an uplink subframe on the first secondary carrier.
- the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module is carried on the first uplink subframe of the first secondary carrier;
- the first secondary carrier is two or more, the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module, and one secondary carrier carried in the first secondary carrier On the first uplink subframe,
- the one of the first secondary carriers is one of the following secondary carriers: the secondary carrier with the highest priority, the secondary carrier with the lowest load, the secondary carrier with the lowest frequency, and the secondary carrier with the smallest index number.
- the network side device configures a secondary carrier to the UE by using signaling.
- the processing module is The ACK/NACK channel resource indicated by the PDCCH information is carried on the first uplink subframe of the highest priority secondary carrier in the first secondary carrier,
- the processing module is further used,
- Determining the priority of each secondary carrier in the first secondary carrier including: according to the first uplink subframe being an ACK/NACK load corresponding to the first uplink subframe on each secondary carrier of the uplink subframe, Or the frequency of each secondary carrier, or the index number of each secondary carrier, such that the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module is preferentially carried in the first secondary carrier The first uplink subframe of the highest secondary carrier;
- Determining a priority for the secondary carrier to be configured for the UE specifically, determining, for each time, a priority for all the secondary carriers in the uplink subframe for the subframe corresponding to the same time;
- Determining the priority of each secondary carrier in the first secondary carrier specifically, acquiring the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module, and carrying the ACK/NACK channel resource The first uplink subframe of the highest priority secondary carrier in a secondary carrier.
- the sending module is further configured to: after determining that the ACK/NACK channel resource corresponding to the PDSCH is located in the secondary carrier, send the determined information of one secondary carrier to the UE by using the PDCCH information.
- the network side device only schedules one secondary carrier for the UE and does not schedule a primary carrier, where the secondary carrier is a second secondary carrier.
- the ACK/NACK channel resource indicated by the PDCCH information generated by the processing module is carried on a first uplink subframe on the second secondary carrier.
- the label of the control channel element CCE occupied by the PDCCH corresponds to the ACK/NACK channel resource
- the PDCCH information generated by the processing module indicates the scheduling information of the physical downlink shared channel PDSCH carried by the downlink subframe, and includes:
- the ACK/NACK channel resource is indicated by a label of one CCE in the CCE occupied by the PDCCH.
- the network side device further includes:
- a reservation module configured to reserve, by using a radio resource, RRC dedicated signaling, the UE to reserve an ACK/NACK resource set on the subframe for feeding back the ACK/NACK, where At least one ACK/NACK channel resource included in the ACK/NACK resource set is on one or more secondary carriers, and each ACK/NACK channel resource in the ACK/NACK resource set is carried on a unique secondary carrier;
- the PDCCH information generated by the processing module indicates the ACK/NACK channel resource corresponding to the PDSCH, and includes:
- An ACK/NACK channel resource used by the UE to feed back the ACK/NACK in the set, where the carrier where the ACK/NACK channel resource is located is a carrier used by the UE to feed back the ACK/NACK.
- the TPC in the PDCCH information generated by the processing module is used as an ARI, and includes:
- processing module is further configured to:
- Determining a priority of the secondary carrier configured to the UE includes: determining, for each time, a priority for all the secondary carriers of the uplink subframe for the subframe corresponding to the same time;
- the third secondary carrier is a secondary carrier with the highest priority among the secondary carriers corresponding to the uplink subframe in the first uplink subframe.
- the determining, by the processing module, that the subframe corresponding to the same time is the priority of all the secondary carriers of the uplink subframe includes:
- the subframe is a load condition of ACK/NACK on each secondary carrier of the uplink subframe, or a frequency of each secondary carrier, or an index number of each secondary carrier.
- the network side device provided in this embodiment indicates the PDSCH corresponding to the PDCCH information.
- the ACK/NACK channel resource is carried in the first uplink subframe on the secondary carrier, and the time of the first uplink subframe is a downlink subframe on the primary carrier, so that the UE is in the first uplink subframe located in the determined secondary carrier.
- the ACK/NACK corresponding to the PDSCH is fed back on the ACK/NACK channel resource, so that ACK/NACK can also be fed back during carrier aggregation of different uplink and downlink subframe configurations.
- the embodiment provides a user equipment UE, where the UE includes:
- the receiving module 201 is configured to receive physical downlink control channel PDCCH information that is sent by the network side device to the UE in a downlink subframe.
- the determining module 202 is configured to determine, according to scheduling information carried in the PDCCH information received by the receiving module 201, a physical downlink shared channel (PDSCH) scheduled by the PDCCH information, and determine, according to a timing relationship between the PDCCH and the ACK/NACK corresponding to the PDSCH, a feedback ACK/ a first uplink subframe of the NACK, where the first uplink subframe is a downlink subframe on the primary carrier, and determining a secondary carrier carried by the ACK/NACK channel resource;
- PDSCH physical downlink shared channel
- the sending module 203 is configured to feed back an ACK/NACK corresponding to the PDSCH on the ACK/NACK channel resource determined by the determining module 202, where the ACK/NACK channel resource is located on the first uplink subframe of the determined secondary carrier wave.
- the receiving module 201 is further configured to receive radio resource control RRC proprietary signaling sent by the network side device;
- the determining module 202 is further configured to acquire, according to the RRC dedicated signaling received by the receiving module 201, an ACK/NACK resource set reserved by the network side device, and an ACK/NACK resource set reserved by the UE on the subframe used for feeding back the ACK/NACK. At least one ACK/NACK channel resource included in the ACK/NACK channel resource is carried on one or more secondary carriers, and each ACK/NACK channel resource in the ACK/NACK resource set is carried on a unique secondary carrier;
- Determining, by the determining module 202, the ACK/NACK channel resource corresponding to the PDSCH according to the PDCCH information including:
- the determining module 202 acquires a transmit power control TPC or a downlink allocation indicator DAI used as an ACK/NACK channel resource indication ARI in the PDCCH information sent by the network side device, and determines, in the ACK/NACK resource set, the ACK/NACK for the UE to feed back the ACK/NACK according to the ARI.
- ACK/NACK channel resource the carrier where the ACK/NACK channel resource is located is the carrier used by the UE to feed back ACK/NACK.
- the determining module 202 acquires the TPC or DAI used as the ACK/NACK channel resource indication ARI, including:
- One of the secondary carriers corresponding to the uplink subframe in the first uplink subframe is selected as the third secondary carrier wave
- the TPC command word in the PDCCH information corresponding to the PDSCH carried on the third secondary carrier is used as a TPC command word;
- the TPC command words in the PDCCH information corresponding to the other PDSCHs are used as ARIs, and the other PDSCHs are carried on one or more secondary carriers other than the third secondary carrier, and are carried in multiple PDSCHs on other PDSCHs.
- the ARI values are equal.
- the time at which the first uplink subframe is located on the first secondary carrier is an uplink subframe.
- the secondary carrier carried in the determining ACK/NACK channel resource in the determining module 202 includes:
- determining the secondary carrier carried by the ACK/NACK channel resource includes: determining that the secondary carrier carried by the ACK/NACK channel resource is one of the first secondary carriers;
- the one of the first secondary carriers is one of the following secondary carriers: the secondary carrier with the highest priority, the secondary carrier with the lowest load, the secondary carrier with the lowest frequency, and the secondary carrier with the smallest index number.
- the side device is configured to one secondary carrier of the UE by signaling. If the first secondary carrier is two or more, and the secondary carrier carried by the ACK/NACK channel resource is the highest priority secondary carrier in the first secondary carrier,
- Determining module 202 also for
- Determining the priority of each secondary carrier in the first secondary carrier including: according to the first uplink subframe, the ACK/NACK load corresponding to the first uplink subframe on each secondary carrier of the uplink subframe, or the frequency of each secondary carrier , or the index number configuration of each secondary carrier; Or determining a priority for the secondary carrier configured to the UE, where the determining, by using the subframe corresponding to the same time, the priority of all the secondary carriers of the uplink subframe;
- Determining the priority of each secondary carrier in the first secondary carrier includes: obtaining a priority of all the secondary carriers in the uplink subframe at the time when the first uplink subframe is located.
- the determination of the secondary carrier carried by the ACK/NACK channel resource in the module 202 includes: if the network side device only schedules one secondary carrier for the UE and does not schedule the primary carrier, and the secondary carrier is the second secondary carrier, the determining module 202 determines The secondary carrier is a secondary carrier carried by the ACK/NACK channel resource.
- the label of the control channel element CCE occupied by the PDCCH corresponds to the ACK/NACK channel resource
- Determining, by the determining module 202, the ACK/NACK channel resource corresponding to the PDSCH according to the PDCCH information including:
- the ACK/NACK channel resource is determined by the label of one CCE in the CCE occupied by the PDCCH.
- the user equipment UE provided by this embodiment may specifically include:
- a receiving module configured to receive physical downlink control channel PDCCH information that is sent by the network side device to the UE in a downlink subframe;
- a determining module configured to determine, according to the scheduling information carried in the PDCCH information received by the receiving module, the physical downlink shared channel PDSCH scheduled by the PDCCH information, according to the
- a first uplink subframe for feeding back the ACK/NACK where the first uplink subframe is a downlink subframe on the primary carrier, and determining a secondary carrier carried by the ACK/NACK channel resource; And the ACK/NACK corresponding to the PDSCH is fed back on the ACK/NACK channel resource determined by the determining module, where the ACK/NACK channel resource is located on the first uplink subframe of the determined secondary carrier.
- the receiving module is further configured to receive radio resource control RRC proprietary signaling sent by the network side device;
- the determining module is further configured to acquire, according to the RRC dedicated signaling received by the receiving module, that the network side device reserves, for the UE, the subframe that is used for feeding back the ACK/NACK.
- An ACK/NACK resource set, at least one ACK/NACK channel resource included in the ACK/NACK resource set is on one or more secondary carriers, and each ACK/NACK channel resource in the ACK/NACK resource set Beared on a unique secondary carrier;
- Determining, according to the PDCCH information, the ACK/NACK channel resource corresponding to the PDSCH in the determining module includes:
- the determining module acquires a transmit power control TPC or a downlink allocation indicator DAI used as an ACK/NACK channel resource indication ARI in the PDCCH information sent by the network side device, and determines, in the ACK/NACK resource set, according to the ARI. And transmitting, by the UE, the ACK/NACK channel resource of the ACK/NACK, where the carrier where the ACK/NACK channel resource is located is a carrier used by the UE to feed back the ACK/NACK.
- the determining module acquires the TPC or DAI used as the ACK/NACK channel resource indication ARI, including:
- the TPC command word in the PDCCH information corresponding to the other PDSCH is used as an ARI, and the other PDSCH is carried on one or more secondary carriers other than the third secondary carrier, and in the other When the PDSCH is carried on multiple secondary carriers, the ARI values are equal.
- the time at which the first uplink subframe is located is an uplink subframe on the first secondary carrier.
- the determining the secondary carrier carried by the ACK/NACK channel resource in the determining module includes:
- the determining the secondary carrier carried by the ACK/NACK channel resource includes: determining that the secondary carrier carried by the ACK/NACK channel resource is the first One of the secondary carriers;
- the one secondary carrier in the first secondary carrier is one of the following secondary carriers: The secondary carrier with the highest priority, the secondary carrier with the lowest load, the secondary carrier with the lowest frequency, and the secondary carrier with the smallest index number, and the network side device is configured to a secondary carrier of the UE through signaling.
- the determining Module also used
- Determining the priority of each secondary carrier in the first secondary carrier including: according to the first uplink subframe being an ACK/NACK load corresponding to the first uplink subframe on each secondary carrier of the uplink subframe, Or the frequency of each secondary carrier, or the index number of each secondary carrier;
- determining a priority for the secondary carrier configured to be used by the UE, where the determining, by using the subframe corresponding to the same time, the priority of all the secondary carriers of the uplink subframe, and determining the first auxiliary
- the priority of each of the secondary carriers in the carrier including: obtaining the secondary carrier carried by the ACK/NACK channel resource in the determining module, including:
- the secondary carrier is the second secondary carrier, and the determining module determines that the second secondary carrier is the ACK/NACK channel.
- the secondary carrier carried by the resource.
- the label of the control channel unit CCE occupied by the PDCCH corresponds to the ACK/NACK channel resource
- the ACK/NACK channel resource is determined by a label of one CCE in the CCE occupied by the PDCCH.
- the UE provided in this embodiment determines the PDSCH scheduled by the PDCCH information according to the scheduling information carried in the PDCCH information by receiving the PDCCH information that the network side device sends to the UE in one downlink subframe, and determines the ACK corresponding to the PDSCH according to the indication of the PDCCH information.
- this embodiment provides a network side device, including:
- the configuration module 301 is configured to configure, for the UE, at least two carriers, including one primary carrier and at least one secondary carrier.
- the sending module 302 is configured to send PDCCH information to the UE in a downlink subframe, where the PDCCH information indicates scheduling information of the PDSCH carried by the downlink subframe.
- the determining module 303 is configured to determine at least two different ACK/NACK channel resources according to at least two timing relationships between the PDSCH indicated by the PDCCH information sent by the sending module 302 and the ACK/NACK corresponding to the PDSCH.
- the sending module 302 is further configured to notify the UE by signaling the first channel resource determined by the determining module 303.
- the receiving module 304 is configured to receive ACK/NACK 0 that is fed back by the UE on the first channel resource determined by the determining module 303, where at least two timing relationships include at least two different carriers, and/or different uplinks on the same carrier. The timing relationship of the subframe.
- the transmitting module 302 notifies the UE by signaling the first channel resource, and includes: sending the information of the first channel resource to the UE by using a newly added bit of the PDCCH information, a TPC, or a DAI;
- the network side device sends PDCCH information to the UE in one downlink subframe by configuring at least two carriers for the UE, including one primary carrier and at least one secondary carrier, where the PDCCH information indicates the PDSCH carried by the downlink subframe.
- Scheduling information determining at least two different ACK/NACK channel resources according to at least two timing relationships between the PDSCH and the ACK/NACK corresponding to the PDSCH, and determining a first one from at least two different ACK/NACK channel resources
- the channel resource is used for the UE to feed back the ACK/NACK, and the first channel resource is notified to the UE by signaling, and the ACK/NACK fed back by the UE on the first channel resource is received, so that the UE can also provide feedback when the carrier aggregation of different uplink and downlink subframe configurations is performed.
- ACK/NACK In addition, it is also possible to balance the load of ACK/NACK on the carrier and reduce the ACK/NACK feedback delay.
- the implementation of the network side device is similar to the solution shown in Figure 16 above.
- the network side device may be a TDD system, an FDD system, or a device in a carrier aggregation system of TDD and FDD.
- the network side device may include:
- the sending unit 181 is configured to notify the UE of the carrier configured by the processing unit, and send PDCCH information to the UE in the first subframe, where the PDCCH information indicates scheduling information of the PDSCH carried in the second downlink subframe;
- the third uplink subframe determined by the unit and the related information corresponding to the first carrier, and the first channel resource are indicated to the UE.
- the processing unit 182 is configured to configure, for the UE, at least two carriers, including one primary carrier and at least one secondary carrier, and at least two timing relationships between the subframe where the PDSCH is located and the ACK/NACK corresponding to the PDSCH. Selecting one of the first timing relationships, wherein the subframe corresponding to the second downlink subframe time on the first carrier corresponding to the first timing relationship is a downlink subframe; determining, corresponding to the first timing relationship, a third uplink subframe for the UE to send the ACK/NACK corresponding to the PDSCH; determining a first carrier used by the UE to send the ACK/NACK corresponding to the PDSCH; and in the third uplink subframe of the determined first carrier And determining, by the UE, the first channel resource that feeds back the ACK/NACK corresponding to the PDSCH.
- the primary carrier and the secondary carrier are specifically as described in the foregoing Embodiment 2, and details are not described herein again.
- the receiving unit 183 is configured to receive an ACK/NACK fed back by the UE on the first channel resource on the third subframe on the first carrier.
- the configuration unit may include: a configuration unit, a timing relationship and a subframe determining unit, a carrier determining unit, and a channel resource determining unit.
- the configuration unit is configured to configure at least two carriers for the UE, including one primary carrier and at least one secondary carrier, and output the configured carrier information to the sending unit.
- a timing relationship and a subframe determining unit configured to select one of the at least two timing relationships between the subframe in which the PDSCH is located and the subframe in which the ACK/NACK corresponding to the PDSCH is located as a first timing relationship, where the first timing The relationship satisfies the first condition mentioned above, that is, the subframe on the first carrier corresponding to the first timing relationship that is the same as the time of the second downlink subframe is a downlink subframe, and the first timing relationship is determined. And a third uplink subframe used by the UE to send the ACK/NACK corresponding to the PDSCH.
- a carrier determining unit configured to determine a first carrier used by the UE to send the ACK/NACK corresponding to the PDSCH.
- a channel resource determining unit configured to determine, in the third uplink subframe determined by the timing relationship and the subframe determining unit, and on the first carrier determined by the carrier determining unit, that the UE is used to feed back the PDSCH The first channel resource of the corresponding ACK/NACK.
- the timing relationship and the subframe determining unit may be specifically configured to: if the timing relationship corresponds to different carriers, in at least two timing relationships between the subframe where the PDSCH is located and the ACK/NACK subframe corresponding to the PDSCH. And selecting a condition that the subframe that is the same as the time of the second downlink subframe on the corresponding first carrier is a downlink subframe, and satisfies one of the following conditions:
- the timing relationship is used as the first timing relationship: the timing relationship corresponding to the carrier with the smallest load of the ACK/NACK channel in different carriers, the timing relationship corresponding to the carrier with the smallest ACK/NACK feedback delay in different carriers, and the UE in different carriers
- the carrier determining unit may be configured to determine, according to the timing relationship and the first timing relationship determined by the subframe determining unit, a first carrier used by the UE to send the ACK/NACK corresponding to the PDSCH.
- the carrier determining unit is configured to determine a first carrier used by the UE to send the ACK/NACK corresponding to the PDSCH. Specifically, the carrier determining unit may select, as the first carrier, a carrier that satisfies the first condition and meets the first condition, and meets the following conditions: The carrier of the ACK/NACK channel on the carrier selects the carrier with the smallest load as the first carrier; or selects the carrier with the smallest feedback delay as the first carrier according to the ACK/NACK feedback delay on these carriers; or, selects a different carrier The carrier with the smallest transmission power required by the UE is used as the first carrier.
- the timing relationship and the subframe determining unit may be specifically configured to: if different timing relationships correspond to different carriers, determine a corresponding first timing relationship according to the first carrier determined by the carrier determining unit, and according to the Determining a first timing relationship and a subframe in which the PDSCH is located, determining a third uplink subframe used by the UE to send an ACK/NACK corresponding to the PDSCH.
- the selected first timing relationship is used as the location.
- the related information is indicated to the UE; or, if the timing relationship corresponds to a different carrier, the information of the first carrier may be indicated to the UE as the related information.
- the embodiment provides a user equipment UE, where the UE includes: a receiving module 401, configured to receive PDCCH information that is sent by the network side device to the UE in one downlink subframe, where the PDCCH information indicates that the downlink subframe is carried.
- the scheduling information of the PDSCH is further configured to receive, by the network side device, the information of the first channel resource used by the UE to feed back the ACK/NACK, and the first channel resource is the network side device corresponding to the PDSCH according to the PDSCH. At least two timing relationships between ACK/NACKs, determining at least two different ACK/NACK channel resources, and determining from at least two different ACK/NACK channel resources;
- Sending module 402 for feedback to the network device corresponding to the PDSCH channel resources in a first receiving module 401 notifies the ACK / NACK 0 wherein at least two timing relationships, including at least corresponding to different carriers, and / or correspond to the same carrier Timing relationship of different uplink subframes.
- the at least two different ACK/NACK channel resources include: ACK/NACK channel resources on uplink subframes carried on different carriers at the same time 7 and/or ACK/NACK channel resources on different uplink subframes .
- the ACK/NACK channel resources on different uplink subframes may be different uplink subframes on different carriers, or different uplink subframes on the same carrier.
- the UE in the receiving module 401 receives, by the network side device, information about the first channel resource used by the UE to feed back the ACK/NACK, including one of the following:
- the UE receives the newly added bit of the PDCCH information, the TPC, the first scrambling code corresponding to the first channel resource of the DAL, or the first PDCCH time-frequency resource location corresponding to the first channel resource, and is notified by the UE for the UE to feed back the ACK/ The first channel resource of the NACK.
- the PDCCH information that the user equipment sends to the UE in the downlink subframe is received by the network device, and the PDCCH information indicates the scheduling information of the PDSCH that is carried by the downlink device.
- the information of the first channel resource of the ACK/NACK is fed back.
- the first channel resource is that the network side device determines at least two different ACK/NACKs according to at least two timing relationships between the ACK/NACK corresponding to the PDSCH and the PDSCH.
- Channel resources, and determined from the at least two different ACK/NACK channel resources, the ACK/NACK corresponding to the PDSCH is fed back to the network side device on the first channel resource, so that the carrier aggregation of different uplink and downlink subframe configurations is also performed.
- Ability to feed back ACK/NACK In addition, it is also possible to balance the load of ACK/NACK on the carrier and reduce the ACK/NACK feedback delay.
- This embodiment also provides another user equipment, and the implementation scheme of the user equipment is similar to the scheme shown in FIG. 17 described above. As shown in FIG. 19, the user equipment includes:
- the receiving unit 191 is configured to receive information about two carriers allocated by the network side device for the user equipment UE, including one primary carrier and at least one secondary carrier, and receive the network side device on the first downlink subframe.
- the PDCCH information sent by the UE, the PDCCH information indicates scheduling information of the PDSCH carried in the second downlink subframe, and the indication information sent by the network side device is received, and the first timing relationship corresponding to the indication information satisfies a condition that the subframe corresponding to the time of the second downlink subframe on the first carrier corresponding to the timing relationship is a downlink subframe, and the network side device is allocated to the user equipment, and is used to feed back the Information of the first channel resource of the ACK/NACK corresponding to the PDSCH;
- the processing unit 192 is configured to determine, according to the indication information received by the receiving unit, a third uplink subframe and a first carrier that are used by the network side device to feed back the ACK/NACK, and The information about the first channel resource received by the receiving unit determines that the ACK/NACK corresponding to the PDSCH is sent on the first channel resource of the third uplink subframe in the first carrier;
- the sending unit 193 is configured to send, by using the ACK/NACK corresponding to the PDSCH, the first channel resource of the third uplink subframe in the first carrier.
- the processing unit 192 is configured to: according to the first timing relationship and the second downlink where the PDSCH is located. And determining, by the frame, a third uplink subframe that is used by the UE to send the ACK/NACK corresponding to the PDSCH, and determining, according to a correspondence relationship between the timing relationship and the carrier, a first carrier corresponding to the first timing relationship; The information about the first channel resource received by the receiving unit determines to send the ACK/NACK corresponding to the PDSCH on the first channel resource of the third uplink subframe in the first carrier.
- the processing unit 192 is configured to determine the first carrier according to the correspondence between the carrier and the timing relationship. And corresponding to the first timing relationship, and determining, according to the first timing relationship and the second downlink subframe where the PDSCH is located, the corresponding third uplink subframe; and the first channel received according to the receiving unit
- the information of the resource determines that the ACK/NACK corresponding to the PDSCH is sent on the first channel resource of the third uplink subframe in the first carrier.
- this embodiment provides a network side device, including:
- the configuration module 501 is configured to configure at least two carriers to the UE, where the subframe n of the at least two carriers in the configured carrier is an uplink subframe and needs to feed back an ACK/NACK.
- a dividing module 502 configured to configure the submodule 501 of the configuration module 501 to require feedback
- the downlink subframes corresponding to the ACK/NACK are divided into at least two groups, and the number of downlink subframes in each group does not exceed 2 N -1, where N represents the number of bits of the DAI, where at least one of the downlink subframes belongs to different carriers. ;
- the setting module 503 is configured to sequentially set the DAI value in the PDCCH information corresponding to each downlink subframe in each group divided by the dividing module 502 from 1 to 2 N -1;
- the sending module 504 is configured to send, to the UE, PDCCH information corresponding to the downlink subframe in each group set by the setting module 503.
- the downlink subframes on the first carrier and the transmission time are located in the first 2 N -1 are divided into the first group, and the 2 N -1 downlink subframes are called a first group of subframes; in the downlink subframe corresponding to the ACK/NACK, other downlink subframes except the first group of subframes on the first carrier, and corresponding to the ACK/NACK The downlink subframes on the second carrier in the downlink subframe are divided into the second group, and the number of downlink subframes in the second group also does not exceed 2 N -1.
- Setting module 503 specifically for In each of the groups, the DAI values of the 1 to 2 N -1 are sequentially set according to the sequence of sending the PDCCH information, where the DAI value is for at least two downlink subframes with the same transmission time. Then set in carrier order.
- the setting of the DAI value may also take other manners, for example, a setting order that can be known by both the network side device and the UE.
- the network side device provided in this embodiment avoids the overlap of the ACK/NACK feedback information by changing the DAI counting manner, thereby avoiding the ACK/NACK feedback information error.
- this embodiment provides a user equipment UE, including
- the receiving module 601 is configured to receive at least two carriers configured by the network side device, where the subframe n of the at least two carriers in the configured carrier is an uplink subframe and needs to feed back ACK/NACK;
- a dividing module 602 configured to receive the subframe n received by the receiving module 601
- the downlink subframes corresponding to the ACK/NACK are divided into at least two groups, and the number of downlink subframes in each group does not exceed 2 N -1, where N represents the number of bits of the DAI, where at least one of the downlink subframes belongs to different carriers. ;
- the receiving module 601 is further configured to receive PDCCH information that is sent by the network side device on each downlink subframe in each group;
- the generating module 603 is configured to generate, for each group divided by the dividing module 602, an N-bit ACK/NACK according to a DAI value in each PDCCH information in the group and an ACK/NACK corresponding to the PDSCH indicated by the PDCCH information. ;
- the sending module 604 is configured to send, to the network side device, the generated ACK/NACK of each group generated by the generating module 603.
- the user equipment provided in this embodiment avoids the overlap of the ACK/NACK feedback information by changing the DAI counting manner, thereby avoiding the ACK/NACK feedback information error.
- All or part of the technical solutions provided by the above embodiments may be implemented by software programming, and the software program is stored in a readable storage medium such as a hard disk, an optical disk or a floppy disk in a computer.
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Abstract
本发明公开了一种ACK/NACK指示信息发送的方法和设备。网络侧设备给UE配置至少两个载波;向UE发送PDCCH信息;在至少两个定时关系中选择一个作为第一定时关系;确定对应的第三上行子帧及第一载波;将该第三上行子帧和第一载波所对应的相关信息指示给UE;在该第一载波的第三上行子帧中确定第一信道资源,将该第一信道资源指示给UE;并接收UE在分配的资源上反馈的ACK/NACK。
Description
确认或不确认指示信息发送的方法和设备
本申请要求于 2011 年 4 月 21 日提交中国专利局、 申请号为 201110100737.7、 发明名称为 "TDD 系统中确认或不确认指示信息发送的 方法和设备" 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 本发明涉及通信领域, 特别涉及一种确认或不确认指示信息发送的方 法和设备。
背景技术
LTE( Long Term Evolution ,长期演进 )TDD ( Time Division Duplexing , 时分双工)、 FDD ( Frequency Division Duplexing ,频分双工)系统或 TDD 与 FDD的载波聚合系统中 ,基站可以给 UE ( User Equipment ,用户设备) 配置至少两个载波,通过至少两个载波为 UE传输数据,这种配置称为载波 聚合。 基站会在一个下行子帧上向 UE发送 PDCCH ( Physical Downlink Control Channel ,物理下行控制信道)信息,该 PDCCH信息指示该下行子 帧所承载的 PDSCH( Physical Downlink Shared Channel,物理下行共享信道) 的调度信息。 UE根据 PDSCH所在子帧与该 PDSCH对应的 ACK (确认) /NACK (不确认)所在子帧的定时关系确定上行子帧,并在主载波的该上 行子帧上反馈该 PDSCH对应的 ACK/NACK。
对于载波聚合来说,基站向 UE发送下行数据后, UE需要向基站反馈 相应的 ACK/NACK ,其中 ,如果反馈的是 ACK ,则说明数据传输正确,而 如果反馈的是 NACK ,则基站会发起相应的重传。
然而目前的 ACK/NACK发送方法只适用于至少两个 TDD载波且具有 相同上下行子帧配置的载波聚合,或至少两个 FDD载波的载波聚合。 在不 同上下行子帧配置的至少两个 TDD载波的载波聚合,或至少一个 FDD载 波和至少一个 TDD载波的载波聚合时,尤其是 TDD载波作为主载波时,
则可能出现无法在主载波上反馈 ACK/NACK 的情况, 目前也没有现成的 ACK/NACK反馈的解决方案。
发明内容 为使不同上下行子帧配置的载波聚合时可以反馈 ACK/NACK, 本发明 提供了一种确认或不确认指示信息发送的方法和设备。
所述技术方案如下:
一种传输确认或不确认指示信息的方法,该方法包括:
网络侧设备为用户设备 UE配置至少两个载波,其中包括一个主载波和 至少一个辅载波;
所述网络侧设备在第一下行子帧上向所述 UE发送 PDCCH信息,所述 PDCCH信息指示在第二下行子帧上承载的 PDSCH的调度信息;
所述网络侧设备在所述 PDSCH 所在子帧与所述 PDSCH 对应的 ACK/NACK所在子帧之间的至少两个定时关系中选择一个作为第一定时关 系,其中 ,所述第一定时关系满足第一条件,所述第一条件为 :所述第一 定时关系所对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行 子帧;确定与该第一定时关系对应的、 用于所述 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧;以及确定用于所述 UE发送所述 PDSCH对 应的 ACK/NACK的第一载波;
所述网络侧设备将所确定的所述第三上行子帧和第一载波所对应的相 关信息指示给 UE;
所述网络侧设备在所述第一载波的所述第三上行子帧中 ,确定用于所 述 UE反馈所述 PDSCH对应的 ACK/NACK的第一信道资源,并将所述第 一信道资源指示给 UE;
所述网络侧设备接收所述 UE在所述第一载波上的所述第三子帧上的 所述第一信道资源上反馈的 ACK/NACK。
另一种传输确认或不确认指示信息的方法,该方法包括:
UE确定网络侧设备配置给所述 UE的两个载波,其中包括一个主载波 和至少一个辅载波;
所述 UE接收所述网络侧设备在第一下行子帧上向 UE发送的 PDCCH 信息,所述 PDCCH信息指示第二下行子帧上承载的 PDSCH的调度信息; 所述 UE获取所述网络侧设备发送的指示信息,根据所述指示信息确定 所述网络侧设备为所述 UE确定的、用于反馈 ACK/NACK的第三上行子帧 及第一载波;所述指示信息所对应的第一定时关系满足第一条件:定时关 系所对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧; 所述 UE获取网络侧设备分配给所述 UE用于反馈所述 PDSCH对应的 ACK/NACK的第一信道资源;
所述 UE在所述第一载波中所述第三上行子帧的所述第一信道资源上 发送所述 PDSCH对应的 ACK/NACK。
本发明还提供了一种网络侧设备,所述网络侧设备包括:发送单元、 接收单元和处理单元,其中 ,
所述发送单元,用于将所述处理单元配置的载波通知给 UE;在第一子 帧上向所述 UE发送 PDCCH信息,所述 PDCCH信息用于指示第二下行子 帧上承载的 PDSCH的调度信息;以及将所述处理单元确定的第三上行子帧 及第一载波所对应的相关信息,以及所述处理单元确定的第一信道资源指 示给所述 UE;
所述处理单元,用于为所述 UE配置至少两个载波,其中包括一个主载 波和至少一个辅载波;在所述 PDSCH 所在子帧与所述 PDSCH对应的 ACK/NACK所在子帧之间的至少两个定时关系中选择一个作为第一定时关 系,其中 ,所述第一定时关系满足第一条件,所述第一条件为 :定时关系 对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧;确定 与所述第一定时关系对应的、 用于 UE发送该 PDSCH对应的 ACK/NACK 的第三上行子帧;确定用于 UE发送所述 PDSCH对应的 ACK/NACK的第 一载波;以及在所确定的第一载波的第三上行子帧中 ,确定用于所述 UE 反馈所述 PDSCH对应的 ACK/NACK的第一信道资源;
所述接收单元,用于接收所述 UE在所述第一载波中所述第三子帧的所 述第一信道资源上反馈的 ACK/NACK。
本发明还提供了一种用户设备,包括:接收单元、 处理单元和发送单 元,其中 ,
所述接收单元,用于接收网络侧设备为用户设备 UE分配的两个载波的
信息,其中包括一个主载波和至少一个辅载波;接收所述网络侧设备在第 一下行子帧上向所述 UE发送的 PDCCH信息,所述 PDCCH信息指示第二 下行子帧上承载的 PDSCH的调度信息;接收所述网络侧设备发送的指示信 息,所述指示信息所对应的第一定时关系满足第一条件:定时关系所对应 的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧;以及接收 所述网络侧设备为所述用户设备分配的、 用于反馈所述 PDSCH对应的 ACK/NACK的第一信道资源的信息;
所述处理单元,用于根据所述接收单元接收的指示信息确定所述网络 侧设备为所述 UE确定的、用于反馈 ACK/NACK的第三上行子帧及第一载 波;以及根据所述接收单元接收的所述第一信道资源的信息确定在所述第 一载波中所述第三上行子帧的所述第一信道资源上发送所述 PDSCH对应 的 ACK/NACK;
所述发送单元,用于将所述 PDSCH对应的 ACK/NACK在所述第一载 波中所述第三上行子帧的所述第一信道资源上发送。
本发明提供的技术方案带来的有益效果是:
通过上述实现方案,针对不同上下行子帧配置的至少两个 TDD载波的 载波聚合的系统,或至少一个 FDD载波和至少一个 TDD载波的载波聚合 的系统, 网络侧设备通过在至少两个定时关系中选择一个第一定时关系, 且其所对应的第一载波上与上述第二下行子帧时刻相同的子帧是下行子 帧,从而可以为 UE配置能够用于 ACK/NACK反馈的子帧、 载波及相应的 信道资源,从而使得 UE不但保证 UE能够进行 ACK/NACK反馈,而且还 能使得 UE能够进行灵活的 ACK/NACK反馈。 并且,本发明方案同样适用 于至少有两个 TDD载波且具有相同上下行子帧配置的载波聚合的系统,或 至少有两个 FDD载波的载波聚合的系统,以及类似系统。
另外,上述实现方案中 , ACK/NACK可以被选择到不同的载波或同一 个载波的不同的子帧上反馈, 因此该方案还可以平衡各载波或各子帧上的 ACK/NACK反馈的负载。
附图说明 为了更清楚地说明本发明实施例的技术方案, 下面将对实施例或现有 技术描述中所需要使用的附图作筒单地介绍, 显而易见地, 下面描述中的 附图仅仅是本发明的一些实施例, 对于本领域普通技术人员来讲, 在不付 出创造性劳动性的前提下, 还可以根据这些附图获得其他的附图。
图 1是本发明实施例 1中提供的 TDD系统中确认或不确认指示信息发 送的方法流程图;
图 2是本发明实施例 1中提供的 TDD系统中确认或不确认指示信息发 送的方法流程图;
图 3是本发明实施例 1 中提供的载波聚合下的上下行子帧配置以及定 时关系示意图;
图 4是本发明实施例 2中提供的 TDD系统中确认或不确认指示信息发 送的方法流程图;
图 5是本发明实施例 2中提供的 TDD系统中确认或不确认指示信息发 送的方法流程图;
图 6是本发明实施例 2中提供的载波聚合下的上下行子帧配置以及定 时关系示意图。
图 7是本发明实施例 3中提供的 TDD不同上下行配置载波聚合下的确 认或不确认时域部分绑定示意图;
图 8是本发明实施例 3中提供的 TDD系统中确认或不确认指示信息发 送的方法流程图;
图 9是本发明实施例 3中提供的 TDD系统中确认或不确认指示信息发 送的方法流程图;
图 10是本发明实施例 4中提供的网络侧设备结构示意图;
图 11是本发明实施例 5中提供的用户设备结构示意图;
图 12是本发明实施例 6中提供的网络侧设备结构示意图;
图 13是本发明实施例 7中提供的用户设备结构示意图;
图 14是本发明实施例 8中提供的网络侧设备结构示意图;
图 15是本发明实施例 9中提供的用户设备结构示意图;
图 16是本发明实施例 2中提供的另一种确认或不确认指示信息发送的
方法流程图;
图 17是本发明实施例 中提供的另一种确认或不确认指示信息发送的 方法流程图;
图 18是本发明实施例 6中提供的另一种网络侧设备的结构示意图; 图 19是本发明实施例 7中提供的另一种用户设备的结构示意图。
具体实施方式 为使本发明的目的、 技术方案和优点更加清楚, 下面将结合附图对本 发明实施方式作进一步地详细描述。
实施例 1
本实施例提供了一种 TDD系统中确认或不确认指示信息发送的方法。 参见图 1 , 该方法可以由网络侧设备执行, 具体包括:
S11: 网络侧设备给 UE配置至少两个载波, 其中包括一个主载波和至 少一个辅载波。
S12: 网络侧设备在一个下行子帧上向 UE发送 PDCCH信息, PDCCH 信息指示下行子帧所承载的 PDSCH的调度信息; PDCCH信息指示 PDSCH 所对应的 ACK/NACK信道资源, ACK/NACK信道资源承载在辅载波上的 第一上行子帧上, 第一上行子帧是根据 PDSCH 与 PDSCH 对应的 ACK/NACK之间的定时关系确定, 第一上行子帧所在时刻在主载波上是下 行子帧。
其中, ACK/NACK资源是一个 PUCCH format (格式) 3的 ACK/NACK 资源,或者 ACK/NACK资源是一组 PUCCH format lb的 ACK/NACK资源。 一组 PUCCH format lb的 ACK/NACK资源的个数可以是 2、 3或 4个。
另外, 该网络侧设备具体可以是基站, 对于后面的实施例来说同样如 此。
S13: 网络侧设备在 ACK/NACK信道资源所位于的辅载波的第一上行 子帧上, 接 UE反馈的 ACK/NACK。
本实施例提供的 TDD系统中确认或不确认指示信息发送的方法。 参见 图 2, 该方法也可以由 UE执行, 具体包括:
S21: UE接收网络侧设备在一个下行子帧上向 UE发送的 PDCCH信息。 S22: UE根据 PDCCH信息中携带的调度信息确定 PDCCH信息调度的 PDSCH, 根据 PDCCH信息的指示确定 PDSCH所对应的 ACK/NACK信道 资源, 根据 PDSCH与 PDSCH对应的 ACK/NACK之间的定时关系确定用 于反馈 ACK/NACK的第一上行子帧,第一上行子帧所在时刻在主载波上是 下行子帧, 并确定 ACK/NACK信道资源所^ ^载的辅载波。
S23: UE 在所确定的 ACK/NACK信道资源上反馈 PDSCH对应的 ACK/NACK, ACK/NACK信道资源位于所确定的辅载波的第一上行子帧 上。
在本发明实施例中, 主载波也可以叫做主小区 (Primary cell, Pcell ), 辅载波也可以叫做辅小区 ( Secondary cell , Scell )。
以图 3为例说明上述方法, 假设配置 1的 CC ( Component Carrier, 成 员载波)为主载波, 配置 2的 CC为辅载波。 按照现有技术 ACK/NACK只 能在主载波反馈的规则, 辅载波的子帧 7是上行子帧, 主载波的子帧 7是 下行子帧, 因此, 子帧 7的 4个 ACK/NACK无法在主载波上反馈。 按照本 实施例的方法, 子帧 7上的 4个 ACK/NACK可以在辅载波上反馈。 子帧 3 和子帧 4上的 ACK/NACK在主载波上反馈。 子帧 2上的 ACK/NACK, 既 可以在主载波上反馈, 也可以在辅载波上反馈。
其中, 第一上行子帧所在时刻在第一辅载波上是上行子帧, 如果第一 辅载波为一个,则 ACK/NACK信道资源承载在第一辅载波的第一上行子帧 上; 和 /或, 如果第一辅载波为两个或两个以上, 则 ACK/NACK信道资源 承载在第一辅载波中的一个辅载波的第一上行子帧上, 其中, 第一辅载波 中的一个辅载波, 为以下辅载波中的一种: 优先级最高的辅载波, 负载最 低的辅载波, 频率最低或最高的辅载波, 索引号取值最小或最大的辅载波。 网络侧设备可以通过信令配置给 UE的一个辅载波。
对于由网络侧设备通过信令配置辅载波的情况来说, 具体的, 网络侧 设备可以根据不同载波上 ACK/NACK 资源的负载情况等确定一个辅载波 供 UE在该辅载波上反馈 ACK/NACK, 并把该确定的一个辅载波通过 RRC 信令或物理层信令(如 PDCCH ) 配置给 UE。 更一般的, 对于不同频带的 载波聚合, 网络侧设备可以在每一个频带为 UE配置一个辅载波供 UE反馈 ACK/NACK, 或者网络侧设备在除了 UE的主载波所在频带之外的每一个
频带为 UE分别配置一个辅载波供 UE反馈 ACK/NACK。在反馈 ACK/NACK 的时刻, 当只有一个频带的载波上的对应时刻是上行子帧, 而其余频带的 载波上对应时刻都是下行子帧,则 ACK/NACK就反馈在该时刻是上行子帧 的频带上的所配置的一个辅载波上; 在反馈 ACK/NACK的时刻, 当有两个 或两个以上频带的载波上的对应时刻是上行子帧,则 ACK/NACK反馈在该 时刻是上行子帧的其中一个频带 (如标准预先规定的, 比如频点较低的一 个频带等,或网络侧通过信令通知 UE的一个频带,或根据各频带的优先级 选择优先级最高的一个频带)上的所配置的一个辅载波上,或者 ACK/NACK 反馈在该时刻是上行子帧的所配置辅载波中一个特定的辅载波(如优先级 最高的所配置的一个辅载波)上, 或者 ACK/NACK反馈在该时刻是上行子 帧的至少两个频带上的所配置的辅载波上。
如果第一辅载波为两个或两个以上,且 ACK/NACK信道资源承载在第 一辅载波中的优先级最高的辅载波的第一上行子帧上, 则该方法进一步包 括:
确定第一辅载波中各辅载波的优先级, 包括: 根据第一上行子帧为上 行子帧的各个辅载波上第一上行子帧对应的 ACK/NACK的负载情况,或者 各辅载波的频率, 或者各辅载波的索引号配置;
或者, 为配置给 UE的辅载波确定优先级, 具体包括, 针对每个时刻, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级, 以及确定 第一辅载波中各辅载波的优先级, 具体包括, 获取在第一上行子帧所在时 刻所对应的子帧为上行子帧的所有辅载波的优先级。
其中, 为配置给 UE的辅载波确定优先级, 优选的, 如果该时刻对于主 载波是一个上行子帧, 则主载波的优先级可以设置为最高。 另外, 优先级 可以是根据一些信息预先定义的, 如根据载波标号设置优先级, 对于这种 情况, 网络侧设备和 UE均可以自己确定载波的优先级。优先级也可以是网 络侧设备设置好, 然后通过信令配置给 UE的, 该信令可以是 RRC ( Radio Resource Control, 无线资源控制)专有信令, 或者是 PDCCH信息。 如果网 络侧设备通过 PDCCH信息将优先级配置给 UE, 则网络侧设备可以通过 PDCCH中的比特、 扰码、 或者某些已有字域隐式的确定该优先级, 如可以 利用 PDCCH中下行调度的资源分配字段,根据资源分配字段指示的资源分 配数量确定优先级, 如将资源分配数量最多的那个载波设为最高优先级。
例如, 子帧 3对于主载波是下行子帧, 子帧 3对于两个辅载波是上行子帧, 因此可以在子帧 3对两个辅载波进行优先级设定, 如果子帧 3上辅载波 1 的资源分配数量高于辅载波 2, 则子帧 3的载波优先级可以设置为辅载波 1 高于辅载波 2。
网络侧设备在确定 PDSCH对应的 ACK/NACK信道资源位于辅载波之 后, 还可以将所确定的一个辅载波的信息通过 PDCCH信息发送给 UE。
在网络侧设备为 UE只调度了一个辅载波且没有调度主载波,辅载波为 第二辅载波, 相应地, 网络侧设备向 UE 发送一个 PDCCH 信息时, ACK/NACK信道资源承载在第二辅载波上的第一上行子帧上。
PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道资源对 应; PDCCH信息指示下行子帧所承载的物理下行共享信道 PDSCH的调度 信息,包括:通过 PDCCH所占的 CCE中的一个 CCE的标号指示 ACK/NACK 信道资源。此方法称为隐式指示方法,适用于网络侧设备为 UE只调度了一 个辅载波且没有调度主载波的情况。
该方法进一步包括: 网络侧设备通过 RRC专有信令为 UE在用于反馈 ACK/NACK的子帧上, 预留一个 ACK/NACK资源集合, ACK/NACK资源 集合中包含的至少一个 ACK/NACK信道资源在一个或多个辅载波上, 且 ACK/NACK资源集合中的每个 ACK/NACK信道资源承载在一个唯一的辅 载波上; PDCCH信息指示 PDSCH所对应的 ACK/NACK信道资源, 包括: 网络侧设备将发送给 UE的 PDCCH信息中的 TPC( Transmit Power Control, 发送功率控制 )或 DAI ( Downlink Assignment Index, 下行分配指示 )用作 ARI ( ACK/NACK Resource Indicator, ACK/NACK信道资源指示), ARI 用于指示 ACK/NACK资源集合中用于 UE反馈 ACK/NACK的 ACK/NACK 信道资源, ACK/NACK信道资源所在的载波为 UE用于反馈 ACK/NACK 的载波。 此方法称为 ARI显式指示方法, 适用于一个下行子帧调度了多个 载波的情况。
相应的, UE接收网络侧设备发送的 RRC专有信令, 根据 RRC专有信 令获取网络侧设备为 UE在用于反馈 ACK/NACK 的子帧上预留的一个 ACK/NACK 资源集合, ACK/NACK 资源集合中包含的至少一个 ACK/NACK信道资源在一个或多个辅载波上, 且 ACK/NACK资源集合中 的每个 ACK/NACK信道资源承载在一个唯一的辅载波上;
步骤 S22中, 根据 PDCCH信息确定 PDSCH所对应的 ACK/NACK信 道资源, 包括:
UE获取网络侧设备发送的 PDCCH信息中被用作 ACK/NACK信道资 源指示 ARI的 TPC或 DAI, 根据 ARI确定 ACK/NACK资源集合中用于 UE反馈 ACK/NACK的 ACK/NACK信道资源, ACK/NACK信道资源所在 的载波为 UE用于反馈 ACK/NACK的载波。
其中, UE获取被用作 ACK/NACK信道资源指示 ARI的 TPC或 DAI, 包括:
UE在第一上行子帧对应为上行子帧的辅载波中,选择一个作为第三辅 载波;将第三辅载波上承载的 PDSCH所对应的 PDCCH信息中的 TPC命令 字作为 TPC命令字; 将其他 PDSCH所对应的 PDCCH信息中的 TPC命令 字作为 ARI,其他 PDSCH承载在除了第三辅载波之外的其他辅载波中的一 个或多个辅载波上, 且在其他 PDSCH承载在多个辅载波上时, ARI取值相 等。
以图 3为例, 子帧 2上的 ACK/NACK是针对 2个 CC, 即主载波和辅 载波, 的下行调度, 因此可以通过 ARI动态的指示 ACK/NACK在该主载 波或辅载波上反馈, 这样可以动态地调整多个 CC上的 ACK/NACK负载, 使得 ACK/NACK负载平衡。 子帧 3、 4、 7上的 ACK/NACK只是针对一个 CC的下行调度,且每个 CC都可以反馈 ACK/NACK,那么网络侧设备可以 用 PDCCH隐式指示对应的 ACK/NACK资源。相对于现有机制调度主载波 采用 PDCCH隐式指示对应的 ACK/NACK资源, 调度辅载波就需要用 ARI 显示指示对应的 ACK/NACK资源。本实施例对于针对一个 CC的下行调度, 只调用辅载波也可以用 PDCCH隐式指示对应的 ACK/NACK资源, 从而有 利于节省信令资源开销。
网络侧设备将 PDCCH信息中的 TPC用作 ARI , 包括: 网络侧设备在 第一上行子帧对应为上行子帧的辅载波中, 选择一个作为第三辅载波, 第 三辅载波是在第一上行子帧对应为上行子帧的辅载波中优先级最高的辅载 波;调度第三辅载波上承载的 PDSCH所对应的 PDCCH信息中的 TPC命令 字作为 TPC命令字; 调度其他 PDSCH所对应的 PDCCH信息中的 TPC命 令字作为 ARI,其他 PDSCH承载在除了第三辅载波之外的其他辅载波中的 一个或多个辅载波上, 且在其他 PDSCH承载在多个辅载波上时, ARI取值
相等。
进一步的,如果该 PDCCH是调度除该最高优先级的载波之外的至少两 个载波的 PDCCH, 该 PDCCH中的至少两个 ARI, 可以基于同一个或不同 的 ACK/NACK资源集合来指示 ACK/NACK资源位于该至少两个载波中的 一个载波上。
具体来说,该 PDCCH中的 ARI可以基于同一个 ACK/NACK资源集合 来指示 ACK/NACK资源, 例如, 调度辅载波 1的 PDCCH中的 ARI1 , 以 及调度辅载波 2的 PDCCH中的 ARI2, 在一个 ACK/NACK资源集合中指 示 ACK/NACK资源, 节省 ACK/NACK资源预留的开销。
该 PDCCH中的 ARI还可以基于不同的 ACK/NACK资源集合来指示。 本实施例可以为每个载波设置一个优先级, 且设最高优先级的载波为第一 载波, 其余载波为第二载波。
例如, 假设配置给 UE三个载波 Pcell, Scdll和 Scdl2, 子帧 n对于这 个三个载波都是上行子帧, 优先级设定为 Pcell高于 Scdll高于 Scell2, 子 帧 n用于反馈子帧 p上调度的 PDSCH对应的 ACK/NACK, 且子帧 p对于 这三个载波都是下行子帧。 如果在下行子帧 p 网络侧设备调度了这三个载 波给 UE, 则 UE会在调度 Scelll的 PDCCH1中的 ARI1所指示的资源上反 馈这三个载波的下行子帧 p 对应的三份 ACK/NACK, 如果 UE 漏检了 PDCCH1 ,则 UE会在调度 Scell2的 PDCCH2中的 ARI2所指示的资源上反 馈 Pcell和 Scdl2的下行子帧 p对应的两份 ACK/NACK, 网络侧设备通过 对 ARI1 和 ARI2 指示的 ACK/NACK 资源的盲检测, 得知 UE 漏检了 PDCCH1 , 且在 ACK/NACK资源上只检测两份 ACK/NACK信息, 因为网 络侧设备认为 UE没有收到 PDCCH1 , 也就认为 UE不会反馈 PDCCH1对 应的 ACK/NACK, 因而由于检测的 ACK/NACK 比特数的减少而提高了 ACK/NACK的检测性能; 如果在下行子帧 p网络侧设备只调度了 Pcell和 Scell2给 UE, 则 UE会在调度 Scell2的 PDCCH2的 ARI2指示的资源上反 馈 Pcell和 Scdl2的下行子帧 p对应的两份 ACK/NACK资源, 网络侧设备 直接在 ARI2指示的 ACK/NACK资源上只检测 Pcell和 Scell2对应的这两 份 ACK/NACK信息, 提高了检测性能; 如果在下行子帧 p网络侧设备只调 度了 Pcell和 Scelll给 UE, 则 UE会在调度 Scelll的 PDCCH1的 ARI1指 示的资源上反馈 Pcell, Scelll和 Scdl2的下行子帧 p对应的三份 ACK/NACK
资源, 网络侧设备直接在 ARI1指示的 ACK/NACK资源上只检测 Pcell和 Scelll对应的这两份 ACK/NACK信息, 因此这种情况下, UE无从得知网 络侧设备调度了 Scell2而漏检了 PDCCH2还是根本就没有调度 Scdl2。
该方法还包括: 将配置给 UE的辅载波确定优先级, 确定包括, 针对每 个时刻, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级。
其中, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级 包括: 根据子帧为上行子帧的各个辅载波上 ACK/NACK的负载情况, 或者 各辅载波的频率, 或者各辅载波的索引号配置。
本实施例网络侧设备通过 PDCCH 信息指示 PDSCH 所对应的 ACK/NACK信道资源承载在辅载波上的第一上行子帧上, 并且第一上行子 帧所在时刻在主载波上是下行子帧,使得 UE在位于所确定的辅载波的第一 上行子帧上的 ACK/NACK信道资源上反馈 PDSCH对应的 ACK/NACK, 从而在不同上下行子帧配置的载波聚合时也能够反馈 ACK/NACK。
对于上述实施例 1而言, 筒而言之,
该时分双工 TDD系统中接收确认或不确认指示信息的方法, 在网络侧 设备的具体实现具体可以包括:
网络侧设备给用户设备 UE配置至少两个载波,其中包括一个主载波和 至少一个辅载波;
所述网络侧设备在一个下行子帧上向所述 UE发送物理下行控制信道 PDCCH信息, 所述 PDCCH信息指示所述下行子帧所承载的物理下行共享 信道 PDSCH的调度信息; 所述 PDCCH信息指示所述 PDSCH所对应的确 认 ACK/不确认 NACK信道资源,所述 ACK/NACK信道资源承载在辅载波 上的第一上行子帧上,所述第一上行子帧是根据所述 PDSCH与所述 PDSCH 对应的 ACK/NACK之间的定时关系确定,所述第一上行子帧所在时刻在所 述主载波上是下行子帧;
所述网络侧设备在所述 ACK/NACK信道资源所位于的辅载波的所述 第一上行子帧上, 接收所述 UE反馈的所述 ACK/NACK。
所述第一上行子帧所在时刻在第一辅载波上是上行子帧,
如果所述第一辅载波为一个,则所述 ACK/NACK信道资源承载在所述 第一辅载波的第一上行子帧上;
和 /或,
如果所述第一辅载波为两个或两个以上,则所述 ACK/NACK信道资源 承载在所述第一辅载波中的一个辅载波的第一上行子帧上,
其中, 所述第一辅载波中的一个辅载波, 为以下辅载波中的一种: 优先级最高的辅载波, 负载最低的辅载波, 频率最低的辅载波, 索引 号取值最小的辅载波, 网络侧设备通过信令配置给 UE的一个辅载波。
如果所述第一辅载波为两个或两个以上,且所述 ACK/NACK信道资源 承载在所述第一辅载波中的优先级最高的辅载波的第一上行子帧上,
该方法进一步包括:
确定所述第一辅载波中各辅载波的优先级, 包括: 根据所述第一上行 子帧为上行子帧的各个辅载波上所述第一上行子帧对应的 ACK/NACK 的 负载情况, 或者各辅载波的频率, 或者各辅载波的索引号配置;
或者, 该方法进一步包括:
为配置给所述 UE的辅载波确定优先级, 具体包括, 针对每个时刻, 为 同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级; 以及
确定所述第一辅载波中各辅载波的优先级, 具体包括, 获取在所述第 所述网络侧设备在确定所述 PDSCH对应的 ACK/NACK信道资源位于 辅载波之后, 还包括:
将所确定的一个辅载波的信息通过所述 PDCCH信息发送给所述 UE。 在所述网络侧设备为所述 UE只调度了一个辅载波且没有调度主载波, 所述辅载波为第二辅载波, 相应地, 所述网络侧设备向所述 UE发送一个
PDCCH信息时, 所述 ACK/NACK信道资源承载在所述第二辅载波上的第 一上行子帧上。
相应地, PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道 资源对应;
所述 PDCCH 信息指示所述下行子帧所承载的物理下行共享信道 PDSCH的调度信息, 包括:
通过 PDCCH所占的 CCE中的一个 CCE的标号指示所述 ACK/NACK 信道资源。
该方法进一步包括: 所述网络侧设备通过无线资源控制 RRC专有信令 为所述 UE 在所述用于反馈所述 ACK/NACK 的子帧上, 预留一个
ACK/NACK 资源集合, 所述 ACK/NACK 资源集合中包含的至少一个 ACK/NACK信道资源在一个或多个辅载波上, 且所述 ACK/NACK资源集 合中的每个 ACK/NACK信道资源承载在一个唯一的辅载波上;
所述 PDCCH信息指示所述 PDSCH所对应的 ACK/NACK信道资源, 包括:
所述网络侧设备将发送给所述 UE的 PDCCH信息中的发送功率控制 TPC或下行分配指示 DAI用作 ACK/NACK信道资源指示 ARI, 所述 ARI 用于指示所述 ACK/NACK资源集合中用于所述 UE反馈所述 ACK/NACK 的 ACK/NACK信道资源, 所述 ACK/NACK信道资源所在的载波为所述 UE用于反馈所述 ACK/NACK的载波。
相应地, 所述网络侧设备将所述 PDCCH信息中的 TPC用作 ARI , 包 括:
所述网络侧设备在所述第一上行子帧对应为上行子帧的辅载波中, 选 择一个作为第三辅载波;
调度所述第三辅载波上承载的 PDSCH所对应的 PDCCH信息中的 TPC 命令字作为 TPC命令字;
调度其他 PDSCH所对应的 PDCCH信息中的 TPC命令字作为 ARI,所 述其他 PDSCH 载在除了所述第三辅载波之外的其他辅载波中的一个或 多个辅载波上, 且在所述其他 PDSCH承载在多个辅载波上时, 所述 ARI 取值相等。
相应地, 所述方法还包括:
将配置给所述 UE的辅载波确定优先级,所述确定包括,针对每个时刻, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级;
所述第三辅载波是在所述第一上行子帧对应为上行子帧的辅载波中优 先级最高的辅载波。
相应地, 所述为同一时刻所对应的子帧为上行子帧的所有辅载波确定 优先级包括:
根据所述子帧为上行子帧的各个辅载波上 ACK/NACK的负载情况,或 者各辅载波的频率, 或者各辅载波的索引号配置。
该实施例的时分双工 TDD系统中发送确认或不确认指示信息的方法, 在 UE侧的具体实现, 具体可以包括:
用户设备 UE接收网络侧设备在一个下行子帧上向所述 UE发送的物理 下行控制信道 PDCCH信息;
所述 UE根据所述 PDCCH信息中携带的调度信息确定所述 PDCCH信 息调度的物理下行共享信道 PDSCH, 根据所述 PDCCH 信息确定所述 PDSCH所对应的确认 ACK/不确认 NACK信道资源, 根据所述 PDSCH与 所述 PDSCH 对应的 ACK/NACK 之间的定时关系确定用于反馈所述 ACK/NACK的第一上行子帧, 所述第一上行子帧所在时刻在主载波上是下 行子帧, 并确定所述 ACK/NACK信道资源所^ ^载的辅载波;
所述 UE在所确定的 ACK/NACK信道资源上反馈所述 PDSCH对应的 ACK/NACK, 所述 ACK/NACK信道资源位于所确定的辅载波的所述第一 上行子帧上。
该方法进一步包括:所述 UE接收所述网络侧设备发送的无线资源控制 RRC专有信令,根据所述 RRC专有信令获取所述网络侧设备为所述 UE在 所述用于反馈所述 ACK/NACK 的子帧上预留的一个 ACK/NACK 资源集 合, 所述 ACK/NACK资源集合中包含的至少一个 ACK/NACK信道资源在 一个或多个辅载波上, 且所述 ACK/NACK资源集合中的每个 ACK/NACK 信道资源承载在一个唯一的辅载波上;
所述根据所述 PDCCH信息确定所述 PDSCH所对应的 ACK/NACK信 道资源, 包括:
所述 UE 获取所述网络侧设备发送的 PDCCH 信息中被用作 ACK/NACK信道资源指示 ARI的发送功率控制 TPC或下行分配指示 DAI, 根据所述 ARI确定所述 ACK/NACK 资源集合中用于所述 UE反馈所述 ACK/NACK的 ACK/NACK信道资源, 所述 ACK/NACK信道资源所在的 载波为所述 UE用于反馈所述 ACK/NACK的载波。
相应地, 所述 UE获取被用作 ACK/NACK信道资源指示 ARI的所述 TPC或 DAI, 包括:
所述 UE在所述第一上行子帧对应为上行子帧的辅载波中,选择一个作 为第三辅载波;
将所述第三辅载波上 7|载的 PDSCH所对应的 PDCCH信息中的 TPC 命令字作为 TPC命令字;
将其他 PDSCH所对应的 PDCCH信息中的 TPC命令字作为 ARI,所述
其他 PDSCH承载在除了所述第三辅载波之外的其他辅载波中的一个或多 个辅载波上, 且在所述其他 PDSCH承载在多个辅载波上时, 所述 ARI取 值相等。
所述第一上行子帧所在时刻在第一辅载波上是上行子帧,
如果所述第一辅载波为一个,则所述确定所述 ACK/NACK信道资源所 承载的辅载波包括:确定所述 ACK/NACK信道资源所承载的辅载波为所述 第一辅载波;
和 /或,
如果所述第一辅载波为两个或两个以上, 则所述确定所述 ACK/NACK 信道资源所承载的辅载波包括:确定所述 ACK/NACK信道资源所承载的辅 载波为所述第一辅载波中的一个辅载波;
其中, 所述第一辅载波中的一个辅载波, 为以下辅载波中的一种: 优先级最高的辅载波, 负载最低的辅载波, 频率最低的辅载波, 索引 号取值最小的辅载波, 网络侧设备通过信令配置给 UE的一个辅载波。
相应地, 如果所述第一辅载波为两个或两个以上, 且所述 ACK/NACK 信道资源所承载的辅载波为所述第一辅载波中的优先级最高的辅载波, 该方法进一步包括:
确定所述第一辅载波中各辅载波的优先级, 包括: 根据所述第一上行 子帧为上行子帧的各个辅载波上所述第一上行子帧对应的 ACK/NACK 的 负载情况, 或者各辅载波的频率, 或者各辅载波的索引号配置;
或者, 该方法进一步包括:
为配置给所述 UE的辅载波确定优先级, 具体包括, 针对每个时刻, 为 同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级; 以及
确定所述第一辅载波中各辅载波的优先级, 具体包括, 获取在所述第 所述确定所述 ACK/NACK信道资源所^ ^载的辅载波, 包括: 如果所述网络侧设备为所述 UE只调度了一个辅载波且没有调度主载 波, 所述辅载波为第二辅载波, 所述 UE 确定所述第二辅载波为所述
ACK/NACK信道资源承载的辅载波。
相应地, PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道 资源对应;
所述根据所述 PDCCH 信息的指示确定所述 PDSCH 所对应的 ACK/NACK信道资源, 包括:
通过 PDCCH所占的 CCE中的一个 CCE的标号确定所述 ACK/NACK 信道资源。
实施例 2
本实施例提供了一种 TDD系统或类似系统中确认或不确认指示信息发 送的方法。 参见图 4, 该方法可以由网络侧设备执行, 具体包括:
S31: 网络侧设备为 UE配置至少两个载波, 其中包括一个主载波和至 少一个辅载波。
S32: 网络侧设备在一个下行子帧上向 UE发送 PDCCH信息, PDCCH 信息指示下行子帧承载的 PDSCH的调度信息。 关系, 确定至少两个不同的 ACK/NACK信道资源。
S34: 从至少两个不同的 ACK/NACK信道资源中确定一个第一信道资 源用于 UE反馈 ACK/NACK。
S35: 将第一信道资源通过信令通知 UE。
S36: 接收 UE在第一信道资源上反馈的 ACK/NACK。
本实施例提供的 TDD系统中确认或不确认指示信息发送的方法。 参见 图 5, 该方法可以由 UE执行, 具体包括:
S41: UE接收网络侧设备在一个下行子帧上向 UE发送的 PDCCH信息,
PDCCH信息指示下行子帧承载的 PDSCH的调度信息;
S42: UE接收网络侧设备通过信令通知的、 用于 UE反馈 ACK/ NACK 的第一信道资源的信息,第一信道资源是网络侧设备根据 PDSCH与 PDSCH 对应的 ACK/NACK 之间的至少两个定时关系, 确定至少两个不同的
ACK/NACK信道资源, 并从至少两个不同的 ACK/NACK信道资源中确定 的;
S43 : UE 在第一信道资源上向网络侧设备反馈 PDSCH 对应的 ACK/NACK。
其中, 至少两个定时关系, 至少包括对应不同载波, 和 /或对应同一个
载波上的不同上行子帧的定时关系。
其中, 至少两个不同的 ACK/NACK信道资源包括: 在相同时刻 7 载在 不同载波上的上行子帧上的 ACK/NACK信道资源, 和 /或, 不同上行子帧 上的 ACK/NACK信道资源。 具体的, 不同上行子帧上的 ACK/NACK信道 资源可以为, 不同载波上的不同的上行子帧, 或者, 相同载波上的不同的 上行子帧。
具体的, S34: 从至少两个不同的 ACK/NACK信道资源中确定一个第 一信道资源, 包括:
根据至少两个不同的 ACK/NACK信道资源的负载情况,选择负载最低 的 ACK/NACK信道资源作为第一信道资源;
或者, 根据至少两个不同的 ACK/NACK信道资源的时延, 选择时延最 低的 ACK/NACK信道资源作为第一信道资源;
或者, 根据至少两个不同的 ACK/NACK信道资源的负载情况和时延, 至少两个不同的 ACK/NACK信道资源中确定一个第一信道资源。
S35: 将第一信道资源通过信令通知 UE, 包括以下之一:
通过 PDCCH信息的新增比特、 TPC, 或 DAI, 将第一信道资源的信息 通知给 UE;
根据扰码与 ACK/NACK信道资源的对应关系确定第一信道资源对应 的第一扰码, 并通过 PDCCH信息将第一扰码通知给 UE;
根据 PDCCH时频资源位置与 ACK/NACK信道资源的对应关系, 确定 第一信道资源对应的第一 PDCCH时频资源位置,并通过 PDCCH信息将第 一 PDCCH时频资源位置通知给 UE。
相应的, S42: UE接收网络侧设备通过信令通知的、用于 UE反馈 ACK/ NACK的第一信道资源的信息, 包括以下之一:
UE接收网络侧设备通过 PDCCH信息的新增比特、 TPC、 DAL 第一 信道资源对应的第一扰码、或者第一信道资源对应的第一 PDCCH时频资源 位置, 通知的用于 UE反馈 ACK/NACK的第一信道资源。
其中, 该信令可以是物理层信令(如 PDCCH信息)、 或者 RLC ( Radio Link Control, 无线链路控制)层信令、 或者 MAC ( Media Access Control, 介质访问控制)层信令、 或者 RRC ( Radio Resource Control, 无线资源控 制)层信令。
根据本实施例提供的方法,辅载波的 ACK/NACK可以调整到主载波的 ACK/NACK 资源上反馈, 主载波的 ACK/NACK也可以调整到辅载波的 ACK/NACK资源上反馈, 下面分别举例说明。
对于辅载波的 ACK/NACK可以调整到主载波的 ACK/NACK资源上反 馈的情况:
参见图 6, 辅载波子帧 7上的下行子帧 0、 9对应的 ACK/NACK可以 调整到主载波反馈, 并且根据主载波的定时关系, 可以调整到主载波的子 帧 4来反馈。 以 PDCCH调整为例, 网络侧设备可以利用下行子帧 0、 9调 度的 PDCCH中 DAI的特殊取值 (如 DAI等于 4 )或者 TPC的一个状态, 表示 I巴辅载波子帧 7上的下行子帧 0、 9对应的 ACK/NACK调整到主载波 的子帧 4来反馈,同时 ACK/NACK资源可以由该 PDCCH中的 TPC来指示 或者单独为这个切换预留一份额外的 ACK/NACK资源,该额外的资源是指 ARI指示的资源集合之外的资源。
上述调整方法,减小了辅载波子帧 7上 ACK/NACK的负载和反馈时延。 具体的, 如果子帧 0、 9对应的 ACK/NACK在辅载波子帧 7上反馈, 则反 馈时延分别为 7、 8, 调整后, 反馈时延分别为 4、 5。
对于主载波的 ACK/NACK可以调整到辅载波的 ACK/NACK资源上反 馈的情况:
参见图 6, 主载波子帧 2上的下行子帧 1对应的 ACK/NACK可以调整 到辅载波反馈, 并且根据辅载波的定时关系, 可以调整到辅载波的子帧 7 来反馈。 以 PDCCH调整为例, 网络侧设备可以利用下行子帧 1 调度的 PDCCH中 DAI的特殊取值 (如 DAI等于 4 )或者 TPC的一个状态, 表示 巴主载波子帧 2上的下行子帧 1对应的 ACK/NACK调整到辅载波的子帧 7 来反馈, 同时, ACK/NACK资源可以由该 PDCCH中的 TPC (或 DAI )来 指示, 或者单独为这个切换预留一份额外的 ACK/NACK资源, 该额外的资 源是指 ARI指示的资源集合之外的资源。
本实施例网络侧设备为 UE配置至少两个载波,其中包括一个主载波和 至少一个辅载波, 在一个下行子帧上向 UE发送 PDCCH信息, PDCCH信 息指示下行子帧承载的 PDSCH的调度信息, 根据 PDSCH与 PDSCH对应 的 ACK/NACK之间的至少两个定时关系,确定至少两个不同的 ACK/NACK 信道资源,从至少两个不同的 ACK/NACK信道资源中确定一个第一信道资
源用于 UE反馈 ACK/NACK, 将第一信道资源通过信令通知 UE, 接收 UE 在第一信道资源上反馈的 ACK/NACK, 从而在不同上下行子帧配置的载波 聚合时也能够反馈 ACK/NACK。 另外, 还可以平衡载波上 ACK/NACK的 负载, 减小 ACK/NACK反馈时延。
本发明实施例还提供了一种确认或不确认指示信息发送的方法。 该实 施例适用的系统可以是 TDD系统、 FDD系统 ,也可以是 TDD与 FDD 的载波聚合系统。
参见图 16 ,该方法可以由网络侧设备执行,具体包括:
5161:网络侧设备为 UE配置至少两个载波,其中包括一个主载波和至 少一个辅载波。
主载波可以采用 FDD和 TDD两种双工模式中的一种,不管主载波是 哪种双工模式的载波,辅载波都可以采用 FDD和 TDD两种双工模式中的 一种。 当然,主载波和辅载波也可以是其他模式的载波,只要能够实现本 发明方案即可,在此不做限定。另外,本发明中的主载波可以是供 UE独立 接入的载波,或可以空闲态驻留的载波,或供 UE进行无线链路失败检测的 载波;本发明的主载波也可以是不能供 UE独立接入,而只能在 UE连接态 时使用的载波。
5162:网络侧设备在一个第一下行子帧上向 UE发送 PDCCH信息,该 PDCCH信息指示第二下行子帧上承载的 PDSCH的调度信息。
其中 ,该第一下行子帧与第二下行子帧可以是同一个子帧,也可以是 不同的子帧。 该第一下行子帧与第二下行子帧可以在相同的载波上,也可 以在不同的载波上,后者也称为跨载波调度。
该 PDCCH可以是 LTE系统中基于小区特定参考信号解调的 PDCCH , 也可以是 LTE系统中基于 UE特定参考信号解调的增强的 PDCCH。
5163:在该 PDSCH所在子帧与该 PDSCH对应的 ACK/NACK所在子 帧之间的至少两个定时关系中选择一个作为第一定时关系,确定与该第一 定时关系对应的、 用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行 子帧。
其中 ,所选择的第一定时关系其所对应的第一载波上与上述第二下行 子帧时刻相同的子帧是下行子帧,可以将该条件称为第一条件。 这样,即 可保证所确定的该第三上行子帧是 UE能够用于 ACK/NACK反馈的子帧。
具体的,上述至少两个定时关系,可以包括对应不同载波的定时关系; 和 /或,包括对应同一个载波的定时关系,对于这种情况来说,针对不同的 定时关系,下行子帧在该载波上所对应的、用于 ACK/NACK反馈的上行子 帧不同。
对于至少两个定时关系对应不同载波的情况来说,比如, FDD载波上 的 PDSCH所在子帧与 ACK/NACK所在子帧的定时关系可以为( n , n+4 ) , 即如果 UE在子帧 n收到 PDSCH ,则会在子帧 n+4反馈该 PDSCH对应的 ACK/NACK;对于 TDD载波上的定时关系,则可以可以表示为( n , n+k ) , 其中 k可以大于等于 4 , 因为对于 TDD系统,与 PDSCH间隔的第 4个子 帧不一定是上行子帧。特别的,保证 k大于等于 4是为了 PDSCH的处理时 延的考虑,将来也可以采用其他数值。
对于至少两个定时关系对应同一载波的情况来说,假设一个载波上的 一个下行子帧上承载了 PDSCH ,则该 PDSCH对应的 ACK/NACK既可以 在该载波上的一个上行子帧反馈,也可以在该载波上的另一个上行子帧反 馈,该不同上行子帧对应不同的定时关系。其中 ,该载波可以为 TDD载波, 也可以为 FDD载波,或者其他载波。
其中 ,选择一个定时关系,具体可以有多种实现方式,比如,随机选 择,还可以根据定时关系所对应的不同载波或者用于 ACK/NACK反馈的不 同上行子帧的情况进行选择。 当然,所选择的第一定时关系首先需要满足 该条件:其所对应的第一载波上与上述第二下行子帧时刻相同的子帧是下 行子帧。
具体来说, 如果定时关系对应不同载波 ,则可以根据这些载波上 ACK/NACK信道的负载情况,选择负载最小的载波所对应的定时关系;或 者根据这些载波上的 ACK/NACK反馈时延,选择反馈时延最小的载波所对 应的定时关系;或者,选择 UE所需发送功率最小的载波所对应的定时关系。 对于根据发送功率进行选择这种情况来说,假设 UE距离承载主载波的宏小 区较远,而距离承载辅载波的微小区较近, 网络侧设备可以选择该辅载波 所对应的定时关系给 UE ,因为选择该辅载波会使得 UE需要的发送功率比 选择主载波时 UE所需要的发送功率要小。 当然,也可以综合考虑负载、反 馈时延及发送功率这几种情况。
如果定时关系对应同一个载波,则需要考虑该载波上定时关系所对应
的不同上行子帧的情况。 具体来说,可以根据不同上行子帧上 ACK/NACK 信道的负载情况,选择负载最小的上行子帧所对应的定时关系;或者根据 这些上行子帧上的 ACK/NACK反馈时延,选择反馈时延最小的上行子帧所 对应的定时关系。 当然,也可以综合考虑负载、 反馈时延这几种情况。
对于上述步骤中的确定第三上行子帧来说,可以是根据该第一定时关 系以及该 PDSCH所在子帧,即上述第二下行子帧,确定用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧。
S164:确定用于 UE发送该 PDSCH对应的 ACK/NACK的第一载波。 在确定了第一定时关系后,即可根据该第一定时关系确定该第一载波。 具体来说,不管是不同定时关系对应不同载波,还是不同定时关系对应同 一载波,均可以根据定时关系与载波的对应关系,确定第一定时关系所对 应的第一载波。
上述 S163与 S164还可以换一种实现方式,即先确定上述第一载波, 再根据所确定的第一载波确定相应的第一定时关系。 具体如下:
S163' :确定用于 UE发送该 PDSCH对应的 ACK/NACK的第一载波。 如果不同定时关系对应不同载波,则可以随机选择一个载波作为第一 载波。 或者,可以根据这些载波上 ACK/NACK信道的负载情况,选择负载 最小的载波作为第一载波;或者根据这些载波上的 ACK/NACK反馈时延, 选择反馈时延最小的载波作为第一载波;或者,选择 UE所需发送功率最小 的载波作为第一载波。 当然,也可以综合考虑负载、 反馈时延及发送功率 这几种情况。
其中 ,在确定第一载波时,还需要保证所选择的载波所对应的定时关 系,满足满足其所对应的第一载波上与上述第二下行子帧时刻相同的子帧 应该是下行子帧这一条件,从而可以保证所确定的该第三上行子帧是 UE 能够用于 ACK/NACK反馈的子帧。
S164' :在该 PDSCH所在子帧与该 PDSCH对应的 ACK/NACK所在子 帧之间的至少两个定时关系中选择一个作为第一定时关系,并确定与该第 一定时关系对应的、 用于 UE发送该 PDSCH对应的 ACK/NACK的第三上 行子帧。
对于上述选择一个定时关系作为第一定时关系的处理来说,如果不同 定时关系对应不同载波,则可以通过 S163' 中所确定的第一载波确定其所
对应的定时关系。之后,即可根据该第一定时关系以及该 PDSCH所在子帧, 即上述第二下行子帧,确定用于 UE发送该 PDSCH对应的 ACK/NACK的 第三上行子帧。
如果不同定时关系对应的是同一个载波,那么还需要考虑该载波上定 时关系所对应的不同上行子帧的情况。 具体来说,可以根据不同上行子帧 上 ACK/NACK信道的负载情况,选择负载最小的上行子帧所对应的定时关 系;或者根据这些载波上的 ACK/NACK反馈时延,选择反馈时延最小的上 行子帧所对应的定时关系。 当然,也可以综合考虑负载、 反馈时延这几种 情况。 对于这种情况来说, 由于是根据上行子帧确定的第一定时关系, 因 此,用于确定该第一定时关系的上行子帧,即为用于 UE发送该 PDSCH对 应的 ACK/NACK的第三上行子帧。
如上述步骤 S163中所述,对于该 S164'来说,所选择的第一定时关系, 也需要满足其所对应的第一载波上与上述第二下行子帧时刻相同的子帧应 该是下行子帧这一条件,从而可以保证所确定的该第三上行子帧是 UE能够 用于 ACK/NACK反馈的子帧。
相应地,在选择第一载波或第三上行子帧时,如果其所对应的第一定 时关系不能满足上述条件,则需要重新进行选择,以使得该第一定时关系 满足该条件,换一句话说,在选择第一载波或第三上行子帧时,就需要同 时考虑第一定时关系满足该条件的问题。
S165:将所确定的第三上行子帧和第一载波所对应的相关信息指示给 对于 UE来说,得知了网络侧设备所选择的第一定时关系,即可相应地 确定该第一定时关系所对应的第一载波,比如,结合定时关系与载波的对 应关系确定,以及用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行 子帧。 因此,该 S165的指示步骤,具体可以为 :将所选择的第一定时关系 指示给 UE。 即,该第三上行子帧及第一载波所对应的相关信息为该第一定 时关系。 具体可以通过层 1信令和 /或 RRC信令来指示该第一定时关系。
如果定时关系对应不同的载波,则网络侧设备可以只将所选择的第一 载波指示给 UE ,相应地, UE可以根据该第一载波确定其所对应的第一定 时关系,并进一步根据该第一定时关系确定用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧。 因此,该 S165的指示步骤,具体可以为 :
将所选择的第一载波指示给 UE。 即,该第三上行子帧及第一载波所对应的 相关信息为该第一载波。具体可以通过层 1信令和 /或 RRC信令来指示该第 一载波。
当然,该第三上行子帧及第一载波的相关信息,还可以为该第三上行 子帧及第一载波信息本身,相应地, 网络侧设备可以将该第三上行子帧及 第一载波通过层 1信令和 /或 RRC信令来指示给 UE。
5166:在所确定的第一载波的第三上行子帧中 ,确定用于 UE反馈所述 PDSCH对应的 ACK/NACK的第一信道资源,并将所述第一信道资源指示 给 UE。
其中 ,该第一信道资源可以随机选择,也可以由网络侧设备根据信道 资源负载情况等进行选择,本发明不做具体限定。
对于将第一信道资源指示给 UE来说,具体的, ACK/NACK信道资源 可以采用隐式指示的方式指示给 UE。 比如 ACK/NACK信道资源可以跟 PDCCH所占的 CCE标号隐式对应,这样网络侧设备用哪个 CCE来调度 PDCCH ,网络侧设备就应该去该 CCE对应的 ACK/NACK信道资源上去接 收 UE发送的 ACK/NACK ,相应地, UE可以根据调度该 PDCCH的 CCE 来确定其所对应的、用于本 UE进行 ACK/NACK反馈的信道资源,CCE也 可以是增强的 PDCCH对应的增强的 CCE。
ACK/NACK信道资源也可以采用信令的显示指示,比如通过 RRC信 令预留一个或一组 ACK/NACK信道资源,如果预留一个,那么网络侧设备 就去这个信道资源上去接收 UE发送的 ACK/NACK,相应地,UE则可以获 知该预留的信道资源为用于本 UE进行 ACK/NACK反馈的信道资源;如果 预留一组 , 那么网络侧设备还需要通过 PDCCH 来动态指示这一组 ACK/NACK信道资源中的哪一个用作当前 UE反馈 ACK/NACK的信道资 源,相应地, UE则可以获知该组信道资源中该 PDCCH动态指示的那个资 源为本 UE可以用于 ACK/NACK反馈的信道资源,对于网络侧设备来说, 则需要去这个动态指示的信道资源上接收 UE发送的 ACK/NACK。具体的, PDCCH可以通过该 PDCCH中的比特或扰码来进行动态指示。
需要说明的是,上述 S165和 S166两个步骤中的信息,网络侧设备可 以通过获取同一个信令指示给 UE ,也可以通过不同信令进行指示。
5167:接收 UE在所述第一载波上的所述第三子帧上的所述第一信道资
源上反馈的 ACK/NACK。 本实施例提供的确认或不确认指示信息发送的方法。 参见图 17 ,该方 法可以由 UE执行,具体包括:
5171: UE确定被配置的两个载波,其中包括一个主载波和至少一个辅 载波。
该主载波和辅载波具体与前述步骤 S161相同,在此不再赘述。
5172: UE接收网络侧设备在一个第一下行子帧上向 UE发送的 PDCCH 信息,该 PDCCH信息指示第二下行子帧上承载的 PDSCH的调度信息。
该第一下行子帧与第二下行子帧的关系,以及该 PDCCH具体为什么样 的 PDCCH ,如前述步骤 S162所述,在此不再赘述。
5173:获取网络侧设备发送给本 UE的指示信息,并根据该指示信息确 定网络侧设备为该 UE确定的、用于反馈 ACK/NACK的第三上行子帧及第 一载波。
该指示信息为网络侧设备为该 UE确定的、用于反馈 ACK/NACK的第 三上行子帧及第一载波所对应的相关信息,具体可以是网络侧设备通过层 1 信令和 /或 RRC信令发送给该 UE的。
如前述步骤 S165所述,该相关信息可以为网络侧设备所选择的第一定 时关系,或者是网络侧设备所确定的第一载波。 对于所选择的第一定时关 系来说,其所对应的第一载波上与上述第二下行子帧时刻相同的子帧应该 是下行子帧 ,从而可以保证所确定的该第三上行子帧是 UE 能够用于 ACK/NACK反馈的子帧。
如果获取到的相关信息是第一定时关系,则根据指示信息确定第三上 行子帧及第一载波,具体可以为 :根据该第一定时关系以及该 PDSCH所在 子帧,即上述第二下行子帧 , 确定用于本 UE 发送该 PDSCH 对应的 ACK/NACK的第三上行子帧,以及根据定时关系与载波的对应关系以及该 第一定时关系确定该第一定时关系所对应的第一载波。
如果获取到的相关信息是第一载波,则根据指示信息确定第三上行子 帧及第一载波,具体可以为 : UE根据该第一载波以及载波与定时关系的对 应关系,确定该第一载波所对应的第一定时关系,再根据该第一定时关系 以及该 PDSCH所在子帧,即上述第二下行子帧,确定相应的第三上行子帧。
5174:获取网络侧设备指示给本 UE的、 用于本 UE反馈该 PDSCH对 应的 ACK/NACK的第一信道资源。
与上述步骤 S166相对应地, UE可以通过接收层 1信令和 /或 RRC信 令确定该第一 ACK/NACK信道资源。具体的,如果网络侧设备采用隐式指 示的方式,比如 ACK/NACK信道资源可以跟 PDCCH所占的 CCE标号隐 式对应,这样 UE在哪个或哪几个 CCE上接收到 PDCCH ,相应的, UE就 可以确定哪个 CCE或哪几个 CCE中的某个 CCE对应的 ACK/NACK信道 资源为网络侧设备配置给本 UE的 ACK/NACK信道资源,从而可以去该信 道资源上发送 ACK/NACK。如果网络侧设备可以采用信令的显示指示方式, 比如通过 RRC信令预留一个或一组 ACK/NACK信道资源,如果预留一个, 那么 UE就可以确定该信道资源为网络侧设备配置给本 UE的 ACK/NACK 信道资源,从而可以去这个信道资源上去发送 ACK/NACK,如果预留一组, 那么 UE还需要通过 PDCCH来动态获取这一组 ACK/NACK信道资源中的 哪一个用作当前反馈 ACK/NACK的信道资源,相应的, UE去这个动态获 取的信道资源上发送 ACK/NACK。 具体的,可以通过该 PDCCH中的比特 或扰码来进行动态指示。
需要说明的是,上述 S173和 S174两个步骤中的信息,UE可以通过获 取同一个信令获得,也可以通过不同信令获得。
5175:在所述第一载波上的第三上行子帧上的所述第一信道资源上发 送该 PDSCH对应的 ACK/NACK。
另外,本发明中的载波与服务小区对应。 具体来说,对于 FDD系统, 一个服务小区包括一个下行载波和该下行载波对应的一个上行载波;对于 TDD系统,一个服务小区就是对应一个 TDD载波。
上述层 1信令可以对应 PDCCH。
具体的,网络侧设备可以通过 PDCCH信息的新增比特、 TPC,或 DAI , 将第一信道资源的信息通知给 UE;
或者根据扰码与 ACK/NACK信道资源的对应关系确定第一信道资源 对应的第一扰码,并通过 PDCCH信息将第一扰码通知给 UE;
或者根据 PDCCH时频资源位置与 ACK/NACK信道资源的对应关系, 确定第一信道资源对应的第一 PDCCH时频资源位置,并通过 PDCCH信息 将第一 PDCCH时频资源位置通知给 UE。
相应的, UE 接收网络侧设备通过信令通知的、 用于 UE反馈 ACK/ NACK的第一信道资源的信息,可以包括以下之一:
UE接收网络侧设备通过 PDCCH信息的新增比特、 TPC、 DA 第一 信道资源对应的第一扰码、或者第一信道资源对应的第一 PDCCH时频资源 位置,通知的用于 UE反馈 ACK/NACK的第一信道资源。
其中 ,该信令可以是物理层信令(如 PDCCH信息 或者 RLC ( Radio Link Control ,无线链路控制)层信令、 或者 MAC ( Media Access Control , 介质访问控制)层信令、 或者 RRC ( Radio Resource Control ,无线资源控 制)层信令。
通过上述实现方案,针对不同上下行子帧配置的至少两个 TDD载波的 载波聚合的系统,或至少一个 FDD载波和至少一个 TDD载波的载波聚合 的系统, 网络侧设备通过在至少两个定时关系中选择一个第一定时关系, 且其所对应的第一载波上与上述第二下行子帧时刻相同的子帧是下行子 帧,从而可以为 UE配置能够用于 ACK/NACK反馈的子帧、 载波及相应的 信道资源,从而使得 UE不但保证 UE能够进行 ACK/NACK反馈,而且还 能使得 UE能够进行灵活的 ACK/NACK反馈。 并且,本发明方案同样适用 于至少有两个 TDD载波且具有相同上下行子帧配置的载波聚合的系统,或 至少有两个 FDD载波的载波聚合的系统,以及类似系统。
另外,上述实现方案中 , ACK/NACK可以被选择到不同的载波或同一 个载波的不同的子帧上反馈, 因此该方案还可以平衡各载波或各子帧上的 ACK/NACK反馈的负载。 进一步地,在根据 ACK/NACK反馈时延选择第 一定时关系或第一载波时,还可以进一步减小 ACK/NACK反馈的时延。此 外,对于不同载波发送在不同地理位置的网络侧设备的场景,比如宏基站 对应一个载波和微基站对应另一个载波,网络侧设备可以选择一个 UE所需 发送功率较小的载波进行 ACK/NACK反馈,从而节省了 UE的耗电量,并 且提高了网络侧设备对 ACK/NACK的接收性能。
根据本实施例提供的方法,辅载波的 ACK/NACK可以调整到主载波的 ACK/NACK 资源上反馈,主载波的 ACK/NACK 也可以调整到辅载波的 ACK/NACK资源上反馈。
对于辅载波的 ACK/NACK可以调整到主载波的 ACK/NACK资源上反 馈的情况,以及主载波的 ACK/NACK可以调整到辅载波的 ACK/NACK资
源上反馈的情况来说,具体调整情况可以参见图 6 ,具体描述如前所述。在 此不再赘述。 上述实施例 1 和 2 提供的方案中, Pcdl 或 Scdl 都是可以发送 ACK/NACK的。 考虑到邻频干扰抑制问题, 不同上下行配置的 TDD载波 聚合的载波应该是跨频段的, 即聚合的多个载波频点彼此相距较远。 假设 两个不同上下行配置的 TDD载波 CO和 C1聚合, 其中 CO是低频段而 C1 是高频段, 那么 CO上的小区覆盖要大于 C1上的小区覆盖, 因此对于位于 小区边缘的 UE, 网络侧设备可以把 UE的上行 ACK/NACK配置到小区覆 盖较好的低频载波 CO上, 特别的, 如果低频载波为 UE的主载波, 则网络 侧设备可以 UE的上行 ACK/NACK配置到主载波上。
根据上述分析, 本发明提出的又一方案, 网络侧设备包括:
网络侧设备在多个 ACK/NACK反馈模式中确定一种 ACK/NACK反馈 模式;
网络侧设备通过信令将 ACK/NACK反馈模式通知给 UE, 以使得 UE 根据所述一种 ACK/NACK反馈模式和预先配置好的 ACK/NACK定时关系 进行 ACK/NACK反馈。
基于上述方案, 其中所述 ACK/NACK反馈模式可以是 ACK/NACK可 以反馈在 Pcell 或一个 Scdl 上, 或者, ACK/NACK反馈模式可以是 ACK/NACK只可以反馈在某一个载波上, 该某一个载波可以是主载波, 或 者低频点的载波。
基于上述方案, 其中所述信令优选可以是无线资源控制 (RRC, Radio Resource Control )专有信令, 广播信令或者层 1/层 2信令(如 PDCCH等)。
基于上述方案, 该预先配置好的 ACK/NACK定时关系是 UE收到了上 述方案中的所述信令就知道的定时关系, 可以是现有系统的定时关系, 或 者根据现有系统修改的定时关系。
本发明提出的又一方案, UE侧包括:
获取网络侧设备通知的配置 ACK/NACK反馈模式的信令;
UE 根据所述信令和预先配置好的 ACK/NACK 定时关系进行 ACK/NACK反馈。
上述方案中的 ACK/NACK反馈模式, ACK/NACK定时关系的描述同
相应的网络侧设备方案, 在此不再赘述。
上述图 16和 17对应的实施例解决了如下技术问题,即如果总在主载 波上反馈 ACK/NACK ,会导致有些场景下, ACK/NACK上无法反馈的情 况,比如当定时关系对应的第一载波上与下行 PDSCH所在的子帧时刻相同 的子帧是上行子帧时 , 是无法用该定时关系对应的第一载波来承载该 PDSCH对应的 ACK/NACK的。进一步地,如果传统 TDD载波上的某个上 行子帧,或者动态子帧 TDD载波上的可以用作上行 ACK/NACK反馈的上 行子帧 (该 ACK/NACK 反馈决定于第二 TDD 配置)上调度了下行数据 PDSCH ,则根据当前 TDD载波上的 ACK/NACK定时关系或第二 TDD配 置下的 ACK/NACK定时关系,是无法在当前 TDD载波上反馈 ACK/NACK 的。
针对上述问题,本发明提供了又一种确认或不确认指示信息发送的方 法。本发明实施例适用的系统可以是 TDD系统、 FDD系统,也可以是 TDD 与 FDD的载波聚合系统。
该方法可以由网络侧设备执行,具体包括:
步骤 il:网络侧设备为 UE配置至少两个载波,其中包括至少一个 TDD 载波。
步骤 i2:网络侧设备在所述一个 TDD载波上的一个第五子帧上向 UE 发送 PDCCH信息,所述 PDCCH信息指示在一个第四上行子帧上承载的 PDSCH的调度信息。
该第五子帧可以是上行子帧,也可以是下行子帧。 且该第五子帧为上 行子帧时,可以与该第四上行子帧为同一个上行子帧, 当然也可以为不同 上行子帧。 该第五子帧可以在该 TDD载波上,也可以在其他的载波上。
该至少一个 TDD载波可以采用动态的子帧配置,即该 TDD载波上可以 存在至少一个子帧,该子帧可以动态的被用作上行或下行.具体为 ,系统消息 通知的上下行配置为第一 TDD配置,例如第一 TDD配置下的子帧配置为配 置 0 ,即" 下下上上上" ,而上行 ACK/NACK反馈定时可以按照第二 TDD 配置来进行,该第二 TDD配置可以由 RRC专有信令来配置,假设该第二 配置下的子帧配置为配置 2 ,即" 下下上下下" ,在上述配置下,如果第 4 或 5个子帧被调度了下行数据,则可以根据上述第二 TDD配置的定时关系 来反馈对应的 ACK/NACK。 上述第四上行子帧可以为上述配置下的第 3个
子帧,即动态子帧 TDD载波的第二 TDD配置下的一个上行子帧。
所述第四上行子帧是临时用作传输下行 PDSCH数据的子帧,和 /或, 所述上行子帧在不传输下行 PDSCH数据时可以承载上行 ACK/NACK。
步骤 i3:确定 UE发送该 PDSCH对应的 ACK/NACK的第二载波,该 第二载波为该 TDD载波之外的载波,具体可以为 FDD载波或 TDD载波。
由于第四上行子帧为传统 TDD载波 (非动态子帧 TDD载波)上的一个上 行子帧,或者为动态子帧 TDD载波的第二 TDD配置下的一个上行子帧, 因此如果该第四上行子帧上调度了下行数据传输,即 PDSCH传输,那么根 据传统 TDD载波上的 ACK/NACK定时关系,或者动态子帧 TDD载波上的 ACK/NACK定时关系,即第二 TDD配置下的 ACK/NACK定时关系,是无 法反馈该 PDSCH对应的 ACK/NACK 的, 因此需要在其他载波上发送该 PDSCH对应的 ACK/NACKo
如果配置给 UE的除了当前 TDD载波的载波数量为 1,则 ACK/NACK 反馈的载波为该除当前 TDD载波之外的载波;如果配置给 UE的除了当前 TDD载波之外的载波数量大于 1 ,则可以根据 ACK/NACK负载情况和 /或 反馈时延来在该除当前 TDD 载波之外的载波中确定该第二载波用于 ACK/NACK反馈,子后可以通过层 1信令或 RRC信令将第二载波信息通 知给 UE。
步骤 i4:确定该 PDSCH对应的 ACK/NACK反馈的第二定时关系,并 根据该第二定时关系确定反馈该 ACK/NACK的第六子帧。
网络侧设备可以通过第二载波来确定第二定时关系,具体的,可以采 用第二载波上的 PDSCH与 ACK/NACK的定时关系为第二定时关系。
上述步骤 i3和 i4的顺序可以交换,即可以先确定第二定时关系,再根 据第二定时关系确定第二载波和 ACK/NACK反馈所在的第六子帧。
步骤 i5:在所述第二载波的第六子帧上确定一个第二信道资源用于 UE 反馈 ACK/NACK ,并将所述第二信道资源指示给 UE。
具体的 , ACK/NACK 信道资源可以采用隐式指示的方式 , 比如 ACK/NACK信道资源可以跟 PDCCH所占的 CCE标号隐式对应,这样网络 侧设备用哪个 CCE来调度 PDCCH ,相应的,网络侧设备就去哪个 CCE对 应的 ACK/NACK信道资源上去接收 UE发送的 ACK/NACK , CCE也可以 是增强的 PDCCH对应的增强的 CCE; ACK/NACK信道资源也可以采用信
令的显示指示,比如通过 RRC信令预留一个或一组 ACK/NACK信道资源, 如果预留一个,那么网络侧设备就去这个信道资源上去接收 UE 发送的 ACK/NACK ,如果预留一组,那么网络侧设备还需要通过 PDCCH来动态 指示这一组 ACK/NACK 信道资源中的哪一个用作当前 UE 反馈 ACK/NACK的信道资源,相应的,网络侧设备去这个动态指示的信道资源 上接收 UE发送的 ACK/NACK ,具体的,可以通过该 PDCCH中的比特或 扰码来指示。
步骤 i6:接收 UE在该第二载波上的第六子帧上的第二信道资源上发送 的 ACK/NACKo 相应的 UE侧方法如下:
步骤 jl: UE确定被配置的至少两个载波,其中包括至少一个 TDD载 波。
步骤 j2在所述一个 TDD载波上的一个第五子帧上接收 PDCCH信息, 所述 PDCCH信息指示在一个第四上行子帧上承载的 PDSCH的调度信息。
该第五子帧可以是上行子帧,也可以是下行子帧。 且该第五子帧为上 行子帧时,可以与该第四上行子帧为同一个上行子帧, 当然也可以为不同 上行子帧。 该第五子帧可以在该 TDD载波上,也可以在其他的载波上。
该至少一个 TDD载波可以采用动态的子帧配置,即该 TDD载波上可以 存在至少一个子帧,该子帧可以动态的被用作上行或下行.具体为 ,系统消息 通知的上下行配置为第一 TDD配置,例如第一 TDD配置下的子帧配置为配 置 0 ,即" 下下上上上" ,而上行 ACK/NACK反馈定时可以按照第二 TDD 配置来进行,该第二 TDD配置可以由 RRC专有信令来配置,假设该第二 配置下的子帧配置为配置 2 ,即" 下下上下下" ,在上述配置下,如果第 4 或 5个子帧被调度了下行数据,如果根据上述第二 TDD配置的定时关系来 反馈对应的 ACK/NACK。
而上述第四上行子帧可以为上述配置下的第 3 个子帧,即动态子帧 TDD载波的第二 TDD配置下的一个上行子帧。
所述第四上行子帧是临时用作传输下行 PDSCH数据的子帧,和 /或, 所述上行子帧在不传输下行 PDSCH数据时可以承载上行 ACK/NACK。
步骤 j3:确定发送该 PDSCH对应的 ACK/NACK的第二载波,该第二
载波为该 TDD载波之外的载波,具体可以为 FDD载波或 TDD载波。
由于第四上行子帧为传统 TDD载波 (非动态子帧 TDD载波)上的一个上 行子帧,或者为动态子帧 TDD载波的第二 TDD配置下的一个上行子帧, 因此如果该第四上行子帧上调度了下行数据传输,即 PDSCH传输,那个根 据传统 TDD载波上的 ACK/NACK定时关系,或者动态子帧 TDD载波上的 ACK/NACK定时关系,即第二 TDD配置下的 ACK/NACK定时关系,是无 法反馈该 PDSCH对应的 ACK/NACK 的, 因此需要在其他载波上发送该 PDSCH对应的 ACK/NACKo
如果配置给 UE的除了当前 TDD载波的载波数量为 1,则 ACK/NACK 反馈的载波为该除当前 TDD载波之外的载波;如果配置给 UE的除了当前 TDD载波之外的载波数量大于 1则 UE可以通过接收网络侧设备发送的层 1信令或 RRC信令来在该除当前 TDD载波之外的载波中确定该第二载波用 于 ACK/NACK反馈。
步骤 j4:确定该 PDSCH对应的 ACK/NACK反馈的第二定时关系,并 根据该第二定时关系确定反馈该 ACK/NACK的第六子帧。
UE可以通过第二载波来确定第二定时关系,具体的,可以采用第二载 波上的 PDSCH与 ACK/NACK的定时关系为第二定时关系。
上述步骤 i3和 i4的顺序可以交换,即可以先确定第二定时关系,再根 据第二定时关系确定第二载波和 ACK/NACK反馈所在的第六子帧。 具体 的, UE可以通过接收网络侧设备发送的层 1信令或 RRC信令来确定第二 定时关系。
步骤 j5:在所述第二载波的第六子帧上确定一个第二信道资源用于 UE 反馈 ACK/NACKo
具体的 , ACK/NACK 信道资源可以采用隐式指示的方式 , 比如 ACK/NACK信道资源可以跟 PDCCH所占的 CCE标号隐式对应,这样 UE 接收到网络侧设备用哪个 CCE来调度 PDCCH,相应的,UE就去哪个 CCE 对应的 ACK/NACK信道资源上去发送 ACK/NACK , CCE也可以是增强的 PDCCH对应的增强的 CCE; ACK/NACK信道资源也可以采用信令的显示 指示,比如通过 RRC信令预留一个或一组 ACK/NACK信道资源,如果预 留一个,那么 UE就去这个信道资源上去发送 ACK/NACK ,如果预留一组, 那么 UE还需要通过接收 PDCCH来动态确定这一组 ACK/NACK信道资源
中的哪一个用作当前反馈 ACK/NACK的信道资源,相应的, UE去这个动 态指示的信道资源上发送 ACK/NACK ,具体的,可以通过接收该 PDCCH 中的比特或扰码来确定。
步骤 j6: UE 在该第二载波上的第六子帧上的第二信道资源上发送 ACK/NACK。
举例说明:
假设网络侧设备为 UE配置两个载波,其中载波 1是 FDD载波,载波 2是 TDD载波,该 TDD载波是传统 TDD载波,即不采用动态子帧的配置, 假设 TDD载波的上下行配置为配置 2 ,即一个无线帧的 10个子帧的配置分 别为 DSUDDDSUDD (下下上下下下下上下下),其中 , S表示特殊子帧,该 子帧可以传输下行数据 PDSCH但不可以传输上行 PUSCH数据,因此可以 作为下行子帧。 网络侧设备可以调度 TDD 载波的 8 个下行子帧上的 PDSCH ,这些 PDSCH对应的 ACK/NACK可以发送在该 TDD载波的上行 子帧上,也可以发送在 FDD载波的上行子帧上。 此外,网络侧设备也可以 在 TDD载波的上行子帧上调度下行 PDSCH数据,相应地,如果 TDD载波 的上行子帧不用于反馈上行 ACK/NACK ,则 UE需要在该上行子帧上监测 PDCCH信息;如果网络侧设备在该上行子帧上调度了下行 PDSCH数据, 由于当前 TDD载波的上行子帧上只有该载波上的下行子帧的 ACK/NACK 反馈定时,因此如果该上行被用作下行传输,当前 TDD载波上是没有该下 行传输的 ACK/NACK定时的则 UE需要确定该 PDSCH对应的 ACK/NACK 所在的载波,具体可以由 UE自行确定,也可以由网络侧设备分配,反馈该 ACK/NACK的载波是当前 TDD载波之外的载波。
具体来说,对于由 UE自行确定的情况来说,如果 UE被配置了两个载 波,则 UE可以将该 ACK/NACK反馈在当前 PDSCH所在载波之外的另一 个载波上,该另一个载波可以使 FDD载波或 TDD载波,如果是 TDD载波, 则其在与当前 TDD载波的第四上行子帧时刻相同的子帧是下行子帧,这样 才可以保证该第四上行子帧上的下行数据传输的上行 ACK/NACK定时在 该另一个 TDD载波上是存在的。 如果是 FDD载波,则一定可以保证该第 四上行子帧上的下行数据传输的上行 ACK/NACK 定时的存在,例如该 ACK/NACK可以反馈在该 FDD载波的与该第四上行子帧间隔 4个子帧的 子帧上。
对于由网络侧设备配置的情况来说,假设 UE被配置了多于两个载波, UE可以根据网络侧设备的指示将该 ACK/NACK在其他载波上进行反馈。 具体可以通过层 1信令或 RRC信令或层 1信令与 RRC信令的组合来确定。
该 ACK/NACK反馈的定时关系可以就是选定的载波上的定时关系,即 选定载波上时刻与第四上行子帧的时刻相同的下行子帧对应的 ACK/NACK 反馈的定时关系。该定时关系也可以在确定反馈 ACK/NACK的载波之前确 定,具体可以通过选择反馈时延最小的定时关系来确定,然后再选择该定 时关系的载波作为反馈 ACK/NACK的载波。 即本发明确定 ACK/NACK的 反馈子帧和确定 ACK/NACK所在的载波的确定顺序不作限定。
然后 UE需要确定用于 ACK/NACK反馈的信道资源,具体可以由网络 侧设备通过层 1信令或 RRC信令或层 1信令与 RRC信令的组合来配置, 比如通过 PDCCH中的比特 (比如 ARI)等方式显示分配,或通过 CCE标号 等方式隐式分配,或也可以通过 RRC配置一组 ACK/NACK信道资源,然 后用 PDCCH中的比特来确定其中的一个 ACK/NACK信道资源。 对于当前 TDD 载波采用动态子帧配置的情况,假设系统消息通知的 TDD载波的第一 TDD配置为配置 0 ,即子帧配置为" 下下上上上下下上上 上" ,而该载波的 PDSCH与 ACK/NACK定时关系按照第二 TDD配置来操 作,该第二 TDD配置通过 RRC专有信令来配置。具体的,第 4,5子帧根据 第一 TDD 配置为上行子帧,但可以用作下行数据传输,其对应的上行 ACK/NACK反馈可以按照第二 TDD配置来反馈,即可以反馈在第 3或 8 个子帧上,即 3,8这两个子帧是固定的上行子帧,而第 4,5,9和 10这四个子 帧可以理解为动态子帧。
本发明中 ,假设配置了一个动态子帧的 TDD载波,和一个其他载波, 该其他载波可以是 FDD或 TDD。 对于当前 TDD载波的固定的上行子帧, 比如上述子帧 3,8 ,用作下行数据传输时,其对应的 ACK/NACK反馈是无 法按照第一 TDD配置和第二 TDD配置的定时关系来操作的, 因此可以将 该 ACK/NACK反馈到另一个 FDD或 TDD载波上,定时关系可以采用另一 个载波上的定时关系。 第二信道资源的配置与上述实施例一致,这里不在 赘述。
本发明还提供了一种网络侧设备。该网络侧设备可以是 TDD系统、 FDD 系统或者 TDD与 FDD的载波聚合系统中的设备。
具体来说,该网络侧设备可以包括:
发送模块,用于在一个 TDD 载波上的一个第五子帧上向 UE 发送 PDCCH信息所述 PDCCH信息指示在一个第四上行子帧上承载的 PDSCH 的调度信息;将处理模块在第二载波的第六子帧上所确定一个第二信道资 源指示给所述 UE。
第五子帧与第四上行子帧的关系以及 PDCCH信息,具体如上述对应的 方法实施例中所述,在此不再赘述。
第四上行子帧具体可以为动态子帧 TDD载波的第二 TDD配置下的一 个上行子帧 , 其中第二 TDD 配置为决定该 TDD 载波上 PDSCH 与 ACK/NACK定时关系的 TDD配置,可以由 RRC专有信令配置。
处理模块,用于为 UE配置至少两个载波,其中包括至少一个 TDD载 波;确定 UE发送该 PDSCH对应的 ACK/NACK的第二载波,该第二载波 为该 TDD载波之外的载波,具体可以为 FDD载波或 TDD载波;确定该 PDSCH对应的 ACK/NACK反馈的第二定时关系,并根据该第二定时关系 确定反馈该 ACK/NACK的第六子帧;在所述第二载波的第六子帧上确定一 个第二信道资源用于 UE反馈 ACK/NACK。
所述第二载波、 第二定时关系、 第六子帧以及第二信道资源的确定方 法如上述对应的方法实施例所述,在此不再赘述。
接收模块,用于接收 UE在所述第二载波上的所述第六子帧上的所述第 二信道资源上发送的 ACK/NACK。
对于上述处理模块来说,具体可以包括:配置单元、 载波确定单元、 定时关系及子帧确定单元,以及信道资源确定单元。
其中 ,配置单元,用于为 UE 配置至少两个载波,其中包括至少一个 TDD载波。
载波确定单元,用于确定 UE发送该 PDSCH对应的 ACK/NACK的第 二载波。
定时关系及子帧确定单元,用于确定该 PDSCH对应的 ACK/NACK反 馈的第二定时关系,并根据该第二定时关系确定反馈该 ACK/NACK的第六 子帧。
信道资源确定单元,用于在所述定时关系及子帧确定单元所确定的第 六子帧上,以及在所述载波确定单元所确定的第二载波上,确定一个第二 信道资源用于 UE反馈 ACK/NACK。
上述处理模块中的处理方法如上述对应的方法实施例所述,在此不再 赘述。 本发明还提供了一种用户设备。该用户设备可以是 TDD系统、 FDD系 统或者 TDD与 FDD的载波聚合系统中的设备。
具体来说,该用户设备可以包括:
接收模块用于在所述一个 TDD载波上的一个第五子帧上接收 PDCCH 信息,所述 PDCCH信息指示在一个第四上行子帧上承载的 PDSCH的调度
4曰碧、
第五子帧与第四上行子帧的关系以及 PDCCH信息,具体如上述对应的 方法实施例中所述,在此不再赘述。
第四上行子帧具体可以为动态子帧 TDD载波的第二 TDD配置下的一 个上行子帧 , 其中第二 TDD 配置为决定该 TDD 载波上 PDSCH 与 ACK/NACK定时关系的 TDD配置,可以由 RRC专有信令配置。
处理模块,用于 UE确定网络侧设备配置的至少两个载波,其中包括至 少一个 TDD载波;确定发送该 PDSCH对应的 ACK/NACK的第二载波, 该第二载波为该 TDD载波之外的载波,具体可以为 FDD载波或 TDD载波; 确定该 PDSCH对应的 ACK/NACK反馈的第二定时关系,并根据该第二定 时关系确定反馈该 ACK/NACK的第六子帧;在所述第二载波的第六子帧上 确定一个第二信道资源用于 UE反馈 ACK/NACK。
所述第二载波、 第二定时关系、 第六子帧以及第二信道资源的确定方 法如上述对应的方法实施例所述,在此不再赘述。
发送模块,用于 UE在所述处理模块所确定的所述第二载波上的所述第 六子帧上的所述第二信道资源上发送 ACK/NACK。
对于上述处理模块来说 , 具体可以包括 : 配置载波确定单元、 ACK/NACK反馈载波确定单元、 定时关系及子帧确定单元,以及信道资源 确定单元。
其中 ,配置载波确定单元,用于 UE确定网络侧设备配置的至少两个载
波,其中包括至少一个 TDD载波。
ACK/NACK 反馈载波确定单元, 用于确定发送该 PDSCH 对应的 ACK/NACK的第二载波,该第二载波为该 TDD载波之外的载波,具体可 以为 FDD载波或 TDD载波。
定时关系及子帧确定单元,用于确定该 PDSCH对应的 ACK/NACK反 馈的第二定时关系,并根据该第二定时关系确定反馈该 ACK/NACK的第六 子帧。
信道资源确定单元,用于在所述定时关系及子帧确定单元所确定的第 六子帧上,以及在所述 ACK/NACK反馈载波确定单元所确定的第二载波 上,确定一个第二信道资源用于 UE反馈 ACK/NACK。
上述处理模块中的处理方法如上述对应的方法实施例所述,在此不再 赘述。 实施例 3
现有技术中, 当采用 PUCCH format lb结合信道选择的 ACK/NACK反 馈模式时,如果 ACK/NACK原始比特数或者码字绑定后的原始比特数大于 4时, 可以采用 ACK/NACK时域部分绑定来压缩 ACK/NACK的比特数以 使其不大于 4。 如图 7 所示, 假设单码字传输, 子帧 2和子帧 7反馈的 ACK/NACK比特总数为 6, 以子帧 2为例, 此时可以把 Pcell的上行子帧 2 对应下行子帧 5和 6反馈的 ACK/NACK绑定为 2个比特, 把 Scdl的上行 子帧 2对应下行子帧 4、 5、 6和 8反馈的 ACK/NACK绑定为 2个比特, 即 每个载波绑定为 2个比特, 总共在子帧 2就是 4个 ACK/NACK比特, 因此 可以使用 PUCCH format lb结合信道选择的反馈方式。 其中, 最后每个载 波绑定的 2个比特可以根据表 1 , 即每个载波绑定后 ACK的总数来获得, 具体的对应关系是, 这 2个比特表示的 4种状态分别为 00 (表示绑定的几 个 ACK/NACK中至少存在一个 NACK )、 10 (表示没有 NACK且 ACK数 目为 1或 4 )、 01 (表示没有 NACK且 ACK数目为 2 )、 11 (表示没有 NACK 且 ACK数目为 3 )。 还有一个状态就是如果 UE发现漏检了 PDCCH或者没 有收到 PDCCH,则 UE什么都不会发送。 UE判断是否漏检了 PDCCH是根 据绑定的几个下行子帧中调度的 PDCCH中的 2比特的 DAI字段来确定, DAI是每个子帧累加计数的。 以 Scdl的 4、 5、 6、 8绑定为例说明, 如果
网络侧设备调度了这四个下行子帧, 那么相应的 4个 PDCCH中的 DAI取 值依次为 1、 2、 3和 4, 如果 UE只收到了 DAI为 1、 3和 4的 PDCCH, 则 UE判断 eNB (基站 )调度了下行子帧 5但自己漏检了这个 PDCCH, 因 此 UE什么都不会发送。 此外, 表 1只是给出了一种对应关系, 不排除其它 类似对应关系。
表 1
从表 1中 UE反馈的状态 "1 , 0" 可以看出, 其代表了没有 NACK且 ACK数目为 1或 4, 则会有一个错误的情况发生。 具体的, 如果 eNB调度 了 4、 5、 6、 8给 UE, 而 UE只收到了子帧 4的 PDCCH, 其中的 DAI取值 是 1 ,且这个数据调度 UE得到的是 ACK,此时 UE不会发现后面 3个 PDCCH 漏检,也没有 NACK出现, 因此 UE会将这个载波的 ACK/NACK绑定为状 态" 1 , 0,,来反馈给 eNB,表示 ACK数目为 1;但是 eNB调度了 4个 PDCCH, 得到 UE反馈的 "1 , 0" 会认为 UE反馈的 ACK数目为 4, 因此后面 3个 数据包就丢失了。 这个错误的情况发生就是由于 UE反馈的状态 "1 , 0"是
个交叠状态, 即代表了两个意思。
为了解决现有的 DAI计数方式导致的 ACK/NACK反馈信息错误的问 题, 可以改变 DAI计数方式, 以上述情况为例, 可以不让 DAI的取值大于 等于 4, 本发明提供的解决方案如下:
本实施例提供了一种 TDD系统中确认或不确认指示信息发送的方法。 参见图 8, 该方法可以由网络侧设备执行, 该方法具体包括:
S51: 配置至少两个载波给 UE,配置的载波中有至少两个载波的子帧 n 是上行子帧且需要反馈 ACK/NACK;
S52: 将该子帧 n需要反馈的 ACK/NACK所对应的下行子帧分成至少 两组,每一组的下行子帧数量不超过 2N-1个, N表示 DAI的比特数,其中, 至少有一组中的下行子帧属于不同载波;
S53:将每一组中的各个下行子帧所对应的 PDCCH信息中的 DAI值从 1到 2N-1依次进行设置;
S54: 将每一组中的下行子帧所对应的 PDCCH信息发送给该 UE。 具体的, 对于有两个载波, 且分两组的情况, 将该子帧 n需要反馈的 ACK/NACK所对应的下行子帧分成至少两组, 可以包括,
将所述 ACK/NACK所对应的下行子帧中,在第一载波上且发送时刻位 于前 2N-1个的下行子帧分为第一组,将这 2N-1个下行子帧称为第一组子帧; 将所述 ACK/NACK所对应的下行子帧中,在第一载波上除了该第一组 子帧之外的其它下行子帧, 以及所述 ACK/NACK所对应的下行子帧中在第 二载波上的下行子帧分为第二组, 所述第二组中的下行子帧数目同样不超 过 2N-1。
上述是针对两个载波的情况, 对于三个或以上载波, 和 /或分三个或以 上组来说, 其处理原理类似。 因此不再赘述。
具体的, 将每一组中的各个下行子帧所对应的 PDCCH信息中的 DAI 值从 1到 2N-1依次进行设置, 可以包括,
在所述每一组中, 所述 1到 2N-1的 DAI值按照所述 PDCCH信息的发 送时刻的先后顺序进行依次设置, 其中, 对于发送时刻相同的至少两个下 行子帧, DAI值再按照载波顺序进行设置。 当然, 该 DAI值的设置也可以 采取其他方式, 比如, 可以采取网络侧设备和 UE均能获知的设置顺序。
参见图 9, 该方法可以由用户设备执行, 该方法具体包括:
S61: 接收网络侧设备配置的至少两个载波, 配置的载波中有至少两个 载波的子帧 n是上行子帧且需要反馈 ACK/NACK;
S62: 将该子帧 n需要反馈的 ACK/NACK所对应的下行子帧分成至少 两组,每一组的下行子帧数量不超过 2N-1个, N表示 DAI的比特数,其中, 至少有一组中的下行子帧属于不同载波;
S63: 接收该网络侧设备在每一组中的各个下行子帧上发送的 PDCCH 信息;
S64: 针对每一组, 根据该组中各个 PDCCH信息中的 DAI值, 以及 PDCCH 信息指示的 PDSCH 所对应的 ACK/NACK, 生成 N 个比特的 ACK/NACK;
S65: 将每一组对应生成的 ACK/NACK发送给该网络侧设备。 根据本实施例提供的方法, 当 DAI的比特数 N为 2时, DAI在部分 ACK/NACK绑定时的状态指示如表 2所示。 通过表 2可以看出, 由于改变 了 DAI计数方式, 所以 ACK/NACK反馈信息(即 ACK/NACK状态)没有 交叠状态。
表 2
下面以图 7的子帧 2为例, 结合表 2说明本实施例的方案。
首先配置给 UE两个载波 Pcell和 Scell,且子帧 2在这两个载波上都是 上行子帧且需要反馈 ACK/NACK; 将上行子帧 2需要反馈的 ACK/NACK 对应的两个载波的 6个下行子帧分为两组, 每组包括的下行子帧数均为 3, 第一组为 Scell的下行子帧 4, 5和 6, 第二组为 Pcell的下行子帧 5, 6和 Scell的下行子帧 8, 第二组是跨不同载波的; 对于第一组的下行子帧 4, 5,
6, DAI计数分别为 1 , 2, 3, 对于第二组的下行子帧 5, 6, 8, DAI计数 分别为 1 , 2, 3,这样就不会出现 DAI为 4的情况, 即 UE就不会反馈 ACK 的数目为 4, 因此就避免了上述由于交叠状态而产生错误的情况。
本实施例通过改变 DAI计数方式避免 ACK/NACK反馈信息产生交叠, 从而避免了 ACK/NACK反馈信息错误。 实施例 4
参见图 10, 本实施例提供了一种网络侧设备, 网络侧设备包括: 配置模块 101 , 用于给用户设备 UE配置至少两个载波, 其中包括一个 主载波和至少一个辅载波;
处理模块 102,用于为 UE生成物理下行控制信道 PDCCH信息, PDCCH 信息指示下行子帧所承载的物理下行共享信道 PDSCH的调度信息; PDCCH 信息指示 PDSCH所对应的确认 ACK/不确认 NACK信道资源, ACK/NACK 信道资源承载在配置模块 101 配置的辅载波上的第一上行子帧上, 第一上 行子帧是根据 PDSCH与 PDSCH对应的 ACK/NACK之间的定时关系确定, 第一上行子帧所在时刻在配置模块 101配置的主载波上是下行子帧;
发送模块 103, 用于在一个下行子帧上向 UE发送处理模块 102生成的 PDCCH信息;
接收模块 104 , 用于在发送模块 103 发送的 PDCCH 信息指示的 ACK/NACK信道资源所位于的辅载波的第一上行子帧上, 接收 UE反馈的 ACK/NACK。 其中, 第一上行子帧所在时刻在第一辅载波上是上行子帧,
如果第一辅载波为一个,则处理模块 102生成的 PDCCH信息所指示的 ACK/NACK信道资源, 承载在第一辅载波的第一上行子帧上;
和 /或,
如果第一辅载波为两个或两个以上,则处理模块 102生成的 PDCCH信 息所指示的 ACK/NACK信道资源,承载在第一辅载波中的一个辅载波的第 一上行子帧上,
其中, 第一辅载波中的一个辅载波, 为以下辅载波中的一种: 优先级最高的辅载波, 负载最低的辅载波, 频率最低的辅载波, 索引
号取值最小的辅载波, 网络侧设备通过信令配置给 UE的一个辅载波。 如果第一辅载波为两个或两个以上,且处理模块 102生成的 PDCCH信 息所指示的 ACK/NACK信道资源,承载在第一辅载波中的优先级最高的辅 载波的第一上行子帧上,
处理模块 102, 进一步用于
确定第一辅载波中各辅载波的优先级, 包括: 根据第一上行子帧为上 行子帧的各个辅载波上第一上行子帧对应的 ACK/NACK的负载情况,或者 各辅载波的频率, 或者各辅载波的索引号配置, 以使得处理模块 102生成 的 PDCCH信息所指示的 ACK/NACK信道资源, 载在第一辅载波中的优 先级最高的辅载波的第一上行子帧上;
或者, 处理模块 102进一步用于
为配置给 UE的辅载波确定优先级, 具体包括, 针对每个时刻, 为同一 时刻所对应的子帧为上行子帧的所有辅载波确定优先级; 以及
确定第一辅载波中各辅载波的优先级, 具体包括, 获取在第一上行子 帧所在时刻所对应的子帧为上行子帧的所有辅载波的优先级, 以使得处理 模块 102生成的 PDCCH信息所指示的 ACK/NACK信道资源, 承载在第一 辅载波中的优先级最高的辅载波的第一上行子帧上。 发送模块 103, 还用于在确定 PDSCH对应的 ACK/NACK信道资源位 于辅载波之后,将所确定的一个辅载波的信息通过 PDCCH信息发送给 UE。 在网络侧设备为 UE只调度了一个辅载波且没有调度主载波,辅载波为 第二辅载波,
处理模块 102生成的 PDCCH信息所指示的 ACK/NACK信道资源,承 载在第二辅载波上的第一上行子帧上。
PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道资源对 应;
处理模块 102所生成的 PDCCH信息指示下行子帧所承载的物理下行共 享信道 PDSCH的调度信息, 包括:
通过 PDCCH所占的 CCE中的一个 CCE的标号指示 ACK/NACK信道 资源。 网络侧设备还包括:
预留模块, 用于通过无线资源控制 RRC 专有信令为 UE在用于反馈 ACK/NACK的子帧上, 预留一个 ACK/NACK资源集合, ACK/NACK资源 集合中包含的至少一个 ACK/NACK信道资源在一个或多个辅载波上, 且 ACK/NACK资源集合中的每个 ACK/NACK信道资源承载在一个唯一的辅 载波上;
处理模块 102所生成的 PDCCH信息指示 PDSCH所对应的 ACK/NACK 信道资源, 包括:
将发送给 UE的 PDCCH信息中的发送功率控制 TPC或下行分配指示 DAI用作 ACK/NACK信道资源指示 ARI, ARI用于指示预留模块预留的 ACK/NACK资源集合中用于 UE反馈 ACK/NACK的 ACK/NACK信道资源, ACK/NACK信道资源所在的载波为 UE用于反馈 ACK/NACK的载波。 处理模块 102所生成的 PDCCH信息中的 TPC用作 ARI, 包括: 在第一上行子帧对应为上行子帧的辅载波中, 选择一个作为第三辅载 波;
调度第三辅载波上承载的 PDSCH所对应的 PDCCH信息中的 TPC命令 字作为 TPC命令字;
调度其他 PDSCH所对应的 PDCCH信息中的 TPC命令字作为 ARI,其 他 PDSCH承载在除了第三辅载波之外的其他辅载波中的一个或多个辅载 波上, 且在其他 PDSCH承载在多个辅载波上时, ARI取值相等。 处理模块 102还用于:
将配置给 UE的辅载波确定优先级, 确定包括, 针对每个时刻, 为同一 时刻所对应的子帧为上行子帧的所有辅载波确定优先级;
第三辅载波是在第一上行子帧对应为上行子帧的辅载波中优先级最高 的辅载波。
处理模块 102为同一时刻所对应的子帧为上行子帧的所有辅载波确定 优先级包括:
根据子帧为上行子帧的各个辅载波上 ACK/NACK的负载情况,或者各 辅载波的频率, 或者各辅载波的索引号配置。
筒而言之, 该实施例所提供的网络侧设备, 可以包括:
配置模块,用于给用户设备 UE配置至少两个载波,其中包括一个主载 波和至少一个辅载波;
处理模块, 用于为所述 UE生成物理下行控制信道 PDCCH信息, 所述 PDCCH信息指示所述下行子帧所承载的物理下行共享信道 PDSCH的调度 信道资源,所述 ACK/NACK信道资源承载在所述配置模块配置的辅载波上 的第一上行子帧上, 所述第一上行子帧是根据所述 PDSCH与所述 PDSCH 对应的 ACK/NACK之间的定时关系确定,所述第一上行子帧所在时刻在所 述配置模块配置的主载波上是下行子帧;
发送模块,用于在一个下行子帧上向所述 UE发送所述处理模块生成的 PDCCH信息;
接收模块, 用于在所述发送模块发送的 PDCCH 信息指示的 ACK/NACK信道资源所位于的辅载波的所述第一上行子帧上, 接收所述 UE反馈的所述 ACK/NACK0
所述第一上行子帧所在时刻在第一辅载波上是上行子帧,
如果所述第一辅载波为一个,则所述处理模块生成的所述 PDCCH信息 所指示的所述 ACK/NACK信道资源,承载在所述第一辅载波的第一上行子 帧上;
和 /或,
如果所述第一辅载波为两个或两个以上, 则所述处理模块生成的所述 PDCCH信息所指示的所述 ACK/NACK信道资源, 承载在所述第一辅载波 中的一个辅载波的第一上行子帧上,
其中, 所述第一辅载波中的一个辅载波, 为以下辅载波中的一种: 优先级最高的辅载波, 负载最低的辅载波, 频率最低的辅载波, 索引 号取值最小的辅载波, 网络侧设备通过信令配置给 UE的一个辅载波。
相应地, 如果所述第一辅载波为两个或两个以上, 且所述处理模块生
成的所述 PDCCH信息所指示的所述 ACK/NACK信道资源, 承载在所述第 一辅载波中的优先级最高的辅载波的第一上行子帧上,
所述处理模块, 进一步用于,
确定所述第一辅载波中各辅载波的优先级, 包括: 根据所述第一上行 子帧为上行子帧的各个辅载波上所述第一上行子帧对应的 ACK/NACK 的 负载情况, 或者各辅载波的频率, 或者各辅载波的索引号配置, 以使得所 述处理模块生成的所述 PDCCH信息所指示的所述 ACK/NACK信道资源, 承载在所述第一辅载波中的优先级最高的辅载波的第一上行子帧上;
或者, 用于
为配置给所述 UE的辅载波确定优先级, 具体包括, 针对每个时刻, 为 同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级; 以及
确定所述第一辅载波中各辅载波的优先级, 具体包括, 获取在所述第 使得所述处理模块生成的所述 PDCCH信息所指示的所述 ACK/NACK信道 资源, 承载在所述第一辅载波中的优先级最高的辅载波的第一上行子帧上。
所述发送模块, 还用于在确定所述 PDSCH对应的 ACK/NACK信道资 源位于辅载波之后,将所确定的一个辅载波的信息通过所述 PDCCH信息发 送给所述 UE。
在所述网络侧设备为所述 UE只调度了一个辅载波且没有调度主载波, 所述辅载波为第二辅载波,
所述处理模块生成的所述 PDCCH信息所指示的所述 ACK/NACK信道 资源, 承载在所述第二辅载波上的第一上行子帧上。
PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道资源对 应;
所述处理模块所生成的所述 PDCCH信息指示所述下行子帧所承载的 物理下行共享信道 PDSCH的调度信息, 包括:
通过 PDCCH所占的 CCE中的一个 CCE的标号指示所述 ACK/NACK 信道资源。
所述网络侧设备还包括:
预留模块, 用于通过无线资源控制 RRC专有信令为所述 UE在所述用 于反馈所述 ACK/NACK的子帧上, 预留一个 ACK/NACK资源集合, 所述
ACK/NACK资源集合中包含的至少一个 ACK/NACK信道资源在一个或多 个辅载波上, 且所述 ACK/NACK资源集合中的每个 ACK/NACK信道资源 承载在一个唯一的辅载波上;
所述处理模块所生成的所述 PDCCH信息指示所述 PDSCH所对应的 ACK/NACK信道资源, 包括:
将发送给所述 UE的 PDCCH信息中的发送功率控制 TPC或下行分配 指示 DAI用作 ACK/NACK信道资源指示 ARI, 所述 ARI用于指示所述预 留模块预留的所述 ACK/NACK 资源集合中用于所述 UE 反馈所述 ACK/NACK的 ACK/NACK信道资源, 所述 ACK/NACK信道资源所在的 载波为所述 UE用于反馈所述 ACK/NACK的载波。
相应地,所述处理模块所生成的所述 PDCCH信息中的 TPC用作 ARI, 包括:
在所述第一上行子帧对应为上行子帧的辅载波中, 选择一个作为第三 辅载波;
调度所述第三辅载波上承载的 PDSCH所对应的 PDCCH信息中的 TPC 命令字作为 TPC命令字;
调度其他 PDSCH所对应的 PDCCH信息中的 TPC命令字作为 ARI,所 述其他 PDSCH 载在除了所述第三辅载波之外的其他辅载波中的一个或 多个辅载波上, 且在所述其他 PDSCH承载在多个辅载波上时, 所述 ARI 取值相等。
相应地, 所述处理模块还用于:
将配置给所述 UE的辅载波确定优先级,所述确定包括,针对每个时刻, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级;
所述第三辅载波是在所述第一上行子帧对应为上行子帧的辅载波中优 先级最高的辅载波。
相应地, 所述处理模块为同一时刻所对应的子帧为上行子帧的所有辅 载波确定优先级包括:
根据所述子帧为上行子帧的各个辅载波上 ACK/NACK的负载情况,或 者各辅载波的频率, 或者各辅载波的索引号配置。 本实施例提供的网络侧设备通过 PDCCH信息指示 PDSCH所对应的
ACK/NACK信道资源承载在辅载波上的第一上行子帧上, 并且第一上行子 帧所在时刻在主载波上是下行子帧,使得 UE在位于所确定的辅载波的第一 上行子帧上的 ACK/NACK信道资源上反馈 PDSCH对应的 ACK/NACK, 从而在不同上下行子帧配置的载波聚合时也能够反馈 ACK/NACK。 实施例 5
参见图 11 , 本实施例提供了一种用户设备 UE, UE包括:
接收模块 201 , 用于接收网络侧设备在一个下行子帧上向 UE发送的物 理下行控制信道 PDCCH信息;
确定模块 202, 用于根据接收模块 201接收的 PDCCH信息中携带的调 度信息确定 PDCCH信息调度的物理下行共享信道 PDSCH, 根据 PDCCH 与 PDSCH对应的 ACK/NACK之间的定时关系确定用于反馈 ACK/NACK 的第一上行子帧, 第一上行子帧所在时刻在主载波上是下行子帧, 并确定 ACK/NACK信道资源所承载的辅载波;
发送模块 203, 用于在确定模块 202所确定的 ACK/NACK信道资源上 反馈 PDSCH对应的 ACK/NACK, ACK/NACK信道资源位于所确定的辅载 波的第一上行子帧上。 接收模块 201 , 还用于接收网络侧设备发送的无线资源控制 RRC专有 信令;
确定模块 202, 还用于根据接收模块 201接收的 RRC专有信令获取网 络侧设备为 UE在用于反馈 ACK/NACK的子帧上预留的一个 ACK/NACK 资源集合, ACK/NACK资源集合中包含的至少一个 ACK/ NACK信道资源 在一个或多个辅载波上, 且 ACK/NACK资源集合中的每个 ACK/NACK信 道资源承载在一个唯一的辅载波上;
确定模块 202中的根据 PDCCH信息确定 PDSCH所对应的 ACK/NACK 信道资源, 包括:
确定模块 202 获取网络侧设备发送的 PDCCH 信息中被用作 ACK/NACK信道资源指示 ARI的发送功率控制 TPC或下行分配指示 DAI, 根据 ARI 确定 ACK/NACK 资源集合中用于 UE反馈 ACK/NACK 的
ACK/NACK信道资源, ACK/NACK信道资源所在的载波为 UE用于反馈 ACK/NACK的载波。 确定模块 202获取被用作 ACK/NACK信道资源指示 ARI的 TPC或 DAI, 包括:
在第一上行子帧对应为上行子帧的辅载波中, 选择一个作为第三辅载 波;
将第三辅载波上承载的 PDSCH所对应的 PDCCH信息中的 TPC命令字 作为 TPC命令字;
将其他 PDSCH所对应的 PDCCH信息中的 TPC命令字作为 ARI,其他 PDSCH承载在除了第三辅载波之外的其他辅载波中的一个或多个辅载波 上, 且在其他 PDSCH承载在多个辅载波上时, ARI取值相等。 第一上行子帧所在时刻在第一辅载波上是上行子帧,
如果第一辅载波为一个,则确定模块 202中的确定 ACK/NACK信道资 源所承载的辅载波包括:
确定 ACK/NACK信道资源所^ ^载的辅载波为第一辅载波;
和 /或,
如果第一辅载波为两个或两个以上,则确定 ACK/NACK信道资源所承 载的辅载波包括:确定 ACK/NACK信道资源所^载的辅载波为第一辅载波 中的一个辅载波;
其中, 第一辅载波中的一个辅载波, 为以下辅载波中的一种: 优先级最高的辅载波, 负载最低的辅载波, 频率最低的辅载波, 索引 号取值最小的辅载波, 网络侧设备通过信令配置给 UE的一个辅载波。 如果第一辅载波为两个或两个以上,且 ACK/NACK信道资源所承载的 辅载波为第一辅载波中的优先级最高的辅载波,
确定模块 202, 还用于
确定第一辅载波中各辅载波的优先级, 包括: 根据第一上行子帧为上 行子帧的各个辅载波上第一上行子帧对应的 ACK/NACK的负载情况,或者 各辅载波的频率, 或者各辅载波的索引号配置;
或者, 为配置给 UE的辅载波确定优先级, 具体包括, 针对每个时刻, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级; 以及
确定第一辅载波中各辅载波的优先级, 具体包括, 获取在第一上行子 帧所在时刻所对应的子帧为上行子帧的所有辅载波的优先级。 确定模块 202中的确定 ACK/NACK信道资源所承载的辅载波, 包括: 如果网络侧设备为 UE只调度了一个辅载波且没有调度主载波,辅载波 为第二辅载波,确定模块 202确定第二辅载波为 ACK/NACK信道资源承载 的辅载波。
PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道资源对 应;
确定模块 202中的根据 PDCCH信息确定 PDSCH所对应的 ACK/NACK 信道资源, 包括:
通过 PDCCH所占的 CCE中的一个 CCE的标号确定 ACK/NACK信道 资源。 筒而言之, 该实施例提供的用户设备 UE, 具体可以包括:
接收模块,用于接收网络侧设备在一个下行子帧上向所述 UE发送的物 理下行控制信道 PDCCH信息;
确定模块,用于根据所述接收模块接收的 PDCCH信息中携带的调度信 息确定所述 PDCCH 信息调度的物理下行共享信道 PDSCH, 根据所述
用于反馈所述 ACK/NACK的第一上行子帧,所述第一上行子帧所在时刻在 主载波上是下行子帧, 并确定所述 ACK/NACK信道资源所承载的辅载波; 发送模块,用于在所述确定模块所确定的 ACK/NACK信道资源上反馈 所述 PDSCH对应的 ACK/NACK, 所述 ACK/NACK信道资源位于所确定 的辅载波的所述第一上行子帧上。
所述接收模块, 还用于接收所述网络侧设备发送的无线资源控制 RRC 专有信令;
所述确定模块, 还用于根据所述接收模块接收的所述 RRC专有信令获 取所述网络侧设备为所述 UE在所述用于反馈所述 ACK/NACK的子帧上预 留的一个 ACK/NACK资源集合, 所述 ACK/NACK资源集合中包含的至少 一个 ACK/ NACK信道资源在一个或多个辅载波上,且所述 ACK/NACK资 源集合中的每个 ACK/NACK信道资源承载在一个唯一的辅载波上;
所述确定模块中的所述根据所述 PDCCH信息确定所述 PDSCH所对应 的 ACK/NACK信道资源, 包括:
所述确定模块获取所述网络侧设备发送的 PDCCH 信息中被用作 ACK/NACK信道资源指示 ARI的发送功率控制 TPC或下行分配指示 DAI, 根据所述 ARI确定所述 ACK/NACK 资源集合中用于所述 UE反馈所述 ACK/NACK的 ACK/NACK信道资源, 所述 ACK/NACK信道资源所在的 载波为所述 UE用于反馈所述 ACK/NACK的载波。
相应地, 所述确定模块获取被用作 ACK/NACK信道资源指示 ARI的 所述 TPC或 DAI, 包括:
在所述第一上行子帧对应为上行子帧的辅载波中, 选择一个作为第三 辅载波;
将所述第三辅载波上 7|载的 PDSCH所对应的 PDCCH信息中的 TPC 命令字作为 TPC命令字;
将其他 PDSCH所对应的 PDCCH信息中的 TPC命令字作为 ARI,所述 其他 PDSCH承载在除了所述第三辅载波之外的其他辅载波中的一个或多 个辅载波上, 且在所述其他 PDSCH承载在多个辅载波上时, 所述 ARI取 值相等。
所述第一上行子帧所在时刻在第一辅载波上是上行子帧,
如果所述第一辅载波为一个, 则所述确定模块中的确定所述 ACK/NACK信道资源所承载的辅载波包括:
确定所述 ACK/NACK信道资源所^载的辅载波为所述第一辅载波; 和 /或,
如果所述第一辅载波为两个或两个以上, 则所述确定所述 ACK/NACK 信道资源所承载的辅载波包括:确定所述 ACK/NACK信道资源所承载的辅 载波为所述第一辅载波中的一个辅载波;
其中, 所述第一辅载波中的一个辅载波, 为以下辅载波中的一种:
优先级最高的辅载波, 负载最低的辅载波, 频率最低的辅载波, 索引 号取值最小的辅载波, 网络侧设备通过信令配置给 UE的一个辅载波。
相应地, 如果所述第一辅载波为两个或两个以上, 且所述 ACK/NACK 信道资源所承载的辅载波为所述第一辅载波中的优先级最高的辅载波, 所述确定模块, 还用于
确定所述第一辅载波中各辅载波的优先级, 包括: 根据所述第一上行 子帧为上行子帧的各个辅载波上所述第一上行子帧对应的 ACK/NACK 的 负载情况, 或者各辅载波的频率, 或者各辅载波的索引号配置;
或者, 为配置给所述 UE的辅载波确定优先级, 具体包括, 针对每个时 刻, 为同一时刻所对应的子帧为上行子帧的所有辅载波确定优先级; 以及 确定所述第一辅载波中各辅载波的优先级, 具体包括, 获取在所述第 所述确定模块中的确定所述 ACK/NACK信道资源所承载的辅载波,包 括:
如果所述网络侧设备为所述 UE只调度了一个辅载波且没有调度主载 波, 所述辅载波为第二辅载波, 所述确定模块确定所述第二辅载波为所述 ACK/NACK信道资源承载的辅载波。
相应地, PDCCH所占的控制信道单元 CCE的标号与 ACK/NACK信道 资源对应;
所述确定模块中的根据所述 PDCCH信息确定所述 PDSCH所对应的 ACK/NACK信道资源, 包括:
通过 PDCCH所占的 CCE中的一个 CCE的标号确定所述 ACK/NACK 信道资源。
本实施例提供的 UE通过接收网络侧设备在一个下行子帧上向 UE发送 的 PDCCH信息, 根据 PDCCH信息中携带的调度信息确定 PDCCH信息调 度的 PDSCH, 根据 PDCCH信息的指示确定 PDSCH所对应的 ACK/NACK 信道资源, 根据 PDSCH与 PDSCH对应的 ACK/NACK之间的定时关系确 定用于反馈 ACK/NACK的第一上行子帧,第一上行子帧所在时刻在主载波 上是下行子帧, 并确定 ACK/NACK信道资源所承载的辅载波, 在所确定的 ACK/NACK信道资源上反馈 PDSCH对应的 ACK/NACK, ACK/NACK信 道资源位于所确定的辅载波的第一上行子帧上, 从而在不同上下行子帧配
置的载波聚合时也能够反馈 ACK/NACK。 实施例 6
参见图 12, 本实施例提供了一种网络侧设备, 包括:
配置模块 301 , 用于为 UE配置至少两个载波, 其中包括一个主载波和 至少一个辅载波。
发送模块 302,用于在一个下行子帧上向 UE发送 PDCCH信息, PDCCH 信息指示下行子帧承载的 PDSCH的调度信息。
确定模块 303, 用于根据发送模块 302发送的 PDCCH信息所指示的 PDSCH与该 PDSCH对应的 ACK/NACK之间的至少两个定时关系, 确定 至少两个不同的 ACK/NACK信道资源,
并从至少两个不同的 ACK/NACK信道资源中确定一个第一信道资源 用于 UE反馈 ACK/NACK。
发送模块 302,还用于将确定模块 303确定的第一信道资源通过信令通 知 UE。
接收模块 304, 用于接收 UE在确定模块 303确定的第一信道资源上反 馈的 ACK/NACK0 其中, 至少两个定时关系, 至少包括对应不同载波, 和 /或对应同一个 载波上的不同上行子帧的定时关系。
其中, 至少两个不同的 ACK/NACK信道资源包括: 在相同时刻 7 载在 不同载波上的上行子帧上的 ACK/NACK信道资源, 和 /或, 不同上行子帧 上的 ACK/NACK信道资源。 具体的, 不同上行子帧上的 ACK/NACK信道 资源可以为, 不同载波上的不同的上行子帧, 或者, 相同载波上的不同的 上行子帧。 确定模块 303中的从至少两个不同的 ACK/NACK信道资源中确定一个 第一信道资源, 包括:
根据至少两个不同的 ACK/NACK信道资源的负载情况,选择负载最低 的 ACK/NACK信道资源作为第一信道资源;
或者, 根据至少两个不同的 ACK/NACK信道资源的时延, 选择时延最
低的 ACK/NACK信道资源作为第一信道资源;
或者, 根据至少两个不同的 ACK/NACK信道资源的负载情况和时延, 至少两个不同的 ACK/NACK信道资源中确定一个第一信道资源。 发送模块 302中的将第一信道资源通过信令通知 UE, 包括以下之一: 通过 PDCCH信息的新增比特、 TPC, 或 DAI, 将第一信道资源的信息 通知给 UE;
根据扰码与 ACK/NACK信道资源的对应关系确定第一信道资源对应 的第一扰码, 并通过 PDCCH信息将第一扰码通知给 UE;
根据 PDCCH时频资源位置与 ACK/NACK信道资源的对应关系, 确定 第一信道资源对应的第一 PDCCH时频资源位置,并通过 PDCCH信息将第 一 PDCCH时频资源位置通知给 UE。 本实施例提供的网络侧设备通过为 UE配置至少两个载波,其中包括一 个主载波和至少一个辅载波, 在一个下行子帧上向 UE发送 PDCCH信息, PDCCH信息指示下行子帧承载的 PDSCH 的调度信息, 根据 PDSCH 与 PDSCH对应的 ACK/NACK之间的至少两个定时关系, 确定至少两个不同 的 ACK/NACK信道资源, 并从至少两个不同的 ACK/NACK信道资源中确 定一个第一信道资源用于 UE反馈 ACK/NACK, 将第一信道资源通过信令 通知 UE,接收 UE在第一信道资源上反馈的 ACK/NACK,从而在不同上下 行子帧配置的载波聚合时也能够反馈 ACK/NACK。 另外, 还可以平衡载波 上 ACK/NACK的负载, 减小 ACK/NACK反馈时延。
本发明实施例还提供了另一种网络侧设备。 该网络侧设备的实现方案 与上述图 16所示方案类似,该网络侧设备可以是 TDD系统、 FDD系统或 者 TDD与 FDD的载波聚合系统中的设备。
具体来说,如图 18所示,该网络侧设备可以包括:
发送单元 181 ,用于将所述处理单元配置的载波通知给 UE;在第一子 帧上向该 UE发送 PDCCH信息,该 PDCCH信息指示第二下行子帧上承载 的 PDSCH的调度信息;将处理单元所确定的第三上行子帧及第一载波所对 应的相关信息,以及第一信道资源指示给所述 UE。
该第一下行子帧与第二下行子帧的关系以及 PDCCH信息,具体如上述
实施例 2中所述,在此不再赘述。
处理单元 182,用于为 UE配置至少两个载波,其中包括一个主载波和 至少一个辅载波;在该 PDSCH所在子帧与该 PDSCH对应的 ACK/NACK 所在子帧之间的至少两个定时关系中选择一个作为第一定时关系,其中 , 所述第一定时关系对应的第一载波上与上述第二下行子帧时刻相同的子帧 是下行子帧;确定与该第一定时关系对应的、 用于 UE发送该 PDSCH对应 的 ACK/NACK 的第三上行子帧;确定用于 UE发送该 PDSCH对应的 ACK/NACK的第一载波;以及在所确定的第一载波的第三上行子帧中 ,确 定用于 UE反馈所述 PDSCH对应的 ACK/NACK的第一信道资源。
该主载波和辅载波具体如上述实施例 2中所述,在此不再赘述。
接收单元 183 ,用于接收 UE在所述第一载波上的所述第三子帧上的所 述第一信道资源上反馈的 ACK/NACK。
对于上述处理单元来说,具体可以包括:配置单元、 定时关系及子帧 确定单元、 载波确定单元、 以及信道资源确定单元。
其中 ,配置单元,用于为 UE配置至少两个载波,其中包括一个主载波 和至少一个辅载波,并将所配置的载波信息输出给所述发送单元。
定时关系及子帧确定单元,用于在该 PDSCH所在子帧与该 PDSCH对 应的 ACK/NACK所在子帧之间的至少两个定时关系中选择一个作为第一 定时关系,其中 ,该第一定时关系满足上述提到的第一条件,即所述第一 定时关系对应的第一载波上与上述第二下行子帧时刻相同的子帧是下行子 帧,以及确定与该第一定时关系对应的、 用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧。
载波确定单元,用于确定用于 UE发送该 PDSCH对应的 ACK/NACK 的第一载波。
信道资源确定单元,用于在所述定时关系及子帧确定单元所确定的第 三上行子帧中 ,以及在所述载波确定单元所确定的第一载波上,确定用于 UE反馈所述 PDSCH对应的 ACK/NACK的第一信道资源。
对于上述定时关系及子帧确定单元来说,具体可以用于,如果定时关 系对应不同载波则在该 PDSCH所在子帧与该 PDSCH对应的 ACK/NACK 所在子帧之间的至少两个定时关系中 ,选择满足对应的第一载波上与上述 第二下行子帧时刻相同的子帧是下行子帧这一条件,且满足如下条件之一
的定时关系作为第一定时关系:不同载波中 ACK/NACK信道的负载最小的 载波所对应的定时关系,不同载波中 ACK/NACK反馈时延最小的载波所对 应的定时关系,以及不同载波中 UE所需发送功率最小的载波所对应的定时 关系;和 /或,如果定时关系对应同一个载波,则在该 PDSCH所在子帧与 该 PDSCH对应的 ACK/NACK所在子帧之间的至少两个定时关系中 ,选择 满足对应的第一载波上与上述第二下行子帧时刻相同的子帧是下行子帧这 一条件,且满足如下条件之一的定时关系作为第一定时关系: 同一载波中 负载最小的上行子帧所对应的定时关系,和同一载波中 ACK/NACK反馈时 延最小的上行子帧所对应的定时关系;以及,确定与该第一定时关系对应 的、 用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧。
相应地,该载波确定单元,则可以用于根据定时关系及子帧确定单元 所确定的第一定时关系,确定用于 UE发送该 PDSCH对应的 ACK/NACK 的第一载波。
或者 , 载波确定单元 , 用于确定用于 UE 发送该 PDSCH 对应的 ACK/NACK的第一载波。 且具体地,该载波确定单元具体可以在不同定时 关系对应不同载波时,选择满足其所对应的定时关系满足上述第一条件, 且满足如下条件之一的载波作为第一载波 : 根据所述不同载波上 ACK/NACK信道的负载情况,选择负载最小的载波作为第一载波;或者根 据这些载波上的 ACK/NACK反馈时延,选择反馈时延最小的载波作为第一 载波;或者,选择不同载波中 UE所需发送功率最小的载波作为第一载波。
相应地,上述定时关系及子帧确定单元,则可以具体用于,如果不同 定时关系对应不同载波,则根据所述载波确定单元所确定的第一载波确定 相应的第一定时关系,以及根据所述第一定时关系以及所述 PDSCH所在子 帧,确定用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧。
对于上述发送单元来说,在其将处理单元所确定的第三上行子帧及第 一载波所对应的相关信息指示给所述 UE时,具体可以为 :将所选择的第一 定时关系作为所述相关信息指示给所述 UE;或者,如果定时关系对应不同 载波,则具体可以为 :将所述第一载波的信息作为所述相关信息指示给所 述 UE。
该实施例方案的效果与前述图 16对应的方法实施例的效果类似,在此 不再赘述。
实施例 7
参见图 13 , 本实施例提供了一种用户设备 UE , 该 UE包括: 接收模块 401 , 用于接收网络侧设备在一个下行子帧上向 UE发送的 PDCCH信息, PDCCH信息指示下行子帧承载的 PDSCH的调度信息; 接收模块 401 , 还用于接收网络侧设备通过信令通知的、 用于 UE反馈 ACK/ NACK 的第一信道资源的信息, 第一信道资源是网络侧设备根据 PDSCH与 PDSCH对应的 ACK/NACK之间的至少两个定时关系, 确定至 少两个不同的 ACK/NACK信道资源, 并从至少两个不同的 ACK/NACK信 道资源中确定的;
发送模块 402,用于在接收模块 401通知的第一信道资源上向网络侧设 备反馈 PDSCH对应的 ACK/NACK0 其中, 至少两个定时关系, 至少包括对应不同载波, 和 /或对应同一个 载波上的不同上行子帧的定时关系。
其中, 至少两个不同的 ACK/NACK信道资源包括: 在相同时刻 7 载在 不同载波上的上行子帧上的 ACK/NACK信道资源, 和 /或, 不同上行子帧 上的 ACK/NACK信道资源。 具体的, 不同上行子帧上的 ACK/NACK信道 资源可以为, 不同载波上的不同的上行子帧, 或者, 相同载波上的不同的 上行子帧。 接收模块 401 中的 UE接收网络侧设备通过信令通知的、 用于 UE反馈 ACK/ NACK的第一信道资源的信息, 包括以下之一:
UE接收网络侧设备通过 PDCCH信息的新增比特、 TPC、 DAL 第一 信道资源对应的第一扰码、或者第一信道资源对应的第一 PDCCH时频资源 位置, 通知的用于 UE反馈 ACK/NACK的第一信道资源。
本实施例提供用户设备通过收网络侧设备在一个下行子帧上向 UE发 送的 PDCCH信息, PDCCH信息指示下行子帧承载的 PDSCH的调度信息, 接收网络侧设备通过信令通知的、用于 UE反馈 ACK/ NACK的第一信道资 源的信息, 第一信道资源是网络侧设备根据 PDSCH 与 PDSCH对应的 ACK/NACK之间的至少两个定时关系, 确定至少两个不同的 ACK/NACK
信道资源, 并从至少两个不同的 ACK/NACK信道资源中确定的, 在第一信 道资源上向网络侧设备反馈 PDSCH对应的 ACK/NACK , 从而在不同上下 行子帧配置的载波聚合时也能够反馈 ACK/NACK。 另外, 还可以平衡载波 上 ACK/NACK的负载, 减小 ACK/NACK反馈时延。
该实施例还提供了另一种用户设备,该用户设备的实现方案与上述图 17所示方案类似。 如图 19所示,该用户设备包括:
接收单元 191、 处理单元 192和发送单元 193 ,其中 ,
所述接收单元 191,用于接收网络侧设备为用户设备 UE分配的两个载 波的信息,其中包括一个主载波和至少一个辅载波;接收所述网络侧设备 在第一下行子帧上向所述 UE发送的 PDCCH信息,所述 PDCCH信息指示 第二下行子帧上承载的 PDSCH的调度信息;接收所述网络侧设备发送的指 示信息,所述指示信息所对应的第一定时关系满足第一条件:定时关系所 对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧;以及 接收所述网络侧设备为所述用户设备分配的、用于反馈所述 PDSCH对应的 ACK/NACK的第一信道资源的信息;
所述处理单元 192,用于根据所述接收单元接收的指示信息确定所述网 络侧设备为所述 UE确定的、用于反馈 ACK/NACK的第三上行子帧及第一 载波;以及根据所述接收单元接收的所述第一信道资源的信息确定在所述 第一载波中所述第三上行子帧的所述第一信道资源上发送所述 PDSCH对 应的 ACK/NACK;
所述发送单元 193 ,用于将所述 PDSCH对应的 ACK/NACK在所述第 一载波中所述第三上行子帧的所述第一信道资源上发送。
如果上述接收单元 191 接收的指示信息为所述网络侧设备选择的第一 定时关系,则相应地,该处理单元 192用于,根据所述第一定时关系以及 所述 PDSCH所在的第二下行子帧,确定用于所述 UE发送该 PDSCH对应 的 ACK/NACK的第三上行子帧,以及根据定时关系与载波的对应关系确定 所述第一定时关系所对应的第一载波;以及根据所述接收单元接收的所述 第一信道资源的信息确定在所述第一载波中所述第三上行子帧的所述第一 信道资源上发送所述 PDSCH对应的 ACK/NACK。
如果上述接收单元 191接收的指示信息为第一载波的信息,则相应地, 处理单元 192用于,根据载波与定时关系的对应关系确定所述第一载波所
对应的第一定时关系,并根据所述第一定时关系以及所述 PDSCH所在的第 二下行子帧确定相应的所述第三上行子帧;以及根据所述接收单元接收的 所述第一信道资源的信息确定在所述第一载波中所述第三上行子帧的所述 第一信道资源上发送所述 PDSCH对应的 ACK/NACK。
该实施例方案的效果与前述图 17对应的方法实施例的效果类似,在此 不再赘述。 实施例 8
参见图 14, 本实施例提供了一种网络侧设备, 包括:
配置模块 501 , 用于配置至少两个载波给 UE, 配置的载波中有至少两 个载波的子帧 n是上行子帧且需要反馈 ACK/NACK;
划分模块 502 , 用于将该配置模块 501 配置的子帧 n 需要反馈的
ACK/NACK所对应的下行子帧分成至少两组, 每一组的下行子帧数量不超 过 2N-1个, N表示 DAI的比特数, 其中, 至少有一组中的下行子帧属于不 同载波;
设置模块 503,用于将划分模块 502划分的每一组中的各个下行子帧所 对应的 PDCCH信息中的 DAI值从 1到 2N-1依次进行设置;
发送模块 504,用于将设置模块 503设置的每一组中的下行子帧所对应 的 PDCCH信息发送给该 UE。 划分模块 502, 具体用于
将所述 ACK/NACK所对应的下行子帧中,在第一载波上且发送时刻位 于前 2N-1个的下行子帧分为第一组,将这 2N-1个下行子帧称为第一组子帧; 将所述 ACK/NACK所对应的下行子帧中,在第一载波上除了该第一组 子帧之外的其它下行子帧,以及所述 ACK/NACK所对应的下行子帧中在第 二载波上的下行子帧分为第二组, 所述第二组中的下行子帧数目同样不超 过 2N-1。
上述是针对两个载波的情况, 对于三个或以上载波, 和 /或分三个或以 上组来说, 其处理原理类似。 因此不再赘述。 设置模块 503, 具体用于
在所述每一组中, 所述 1到 2N-1的 DAI值按照所述 PDCCH信息的发 送时刻的先后顺序进行依次设置, 其中, 对于发送时刻相同的至少两个下 行子帧, DAI值再按照载波顺序进行设置。 当然, 该 DAI值的设置也可以 采取其他方式, 比如, 可以采取网络侧设备和 UE均能获知的设置顺序。 本实施例提供的网络侧设备通过改变 DAI计数方式避免 ACK/NACK 反馈信息产生交叠, 从而避免了 ACK/NACK反馈信息错误。 实施例 9
参见图 15, 本实施例提供了一种用户设备 UE, 包括
接收模块 601 , 用于接收网络侧设备配置的至少两个载波, 配置的载波 中有至少两个载波的子帧 n是上行子帧且需要反馈 ACK/NACK;
划分模块 602 , 用于将接收模块 601 接收的该子帧 n 需要反馈的
ACK/NACK所对应的下行子帧分成至少两组, 每一组的下行子帧数量不超 过 2N-1个, N表示 DAI的比特数, 其中, 至少有一组中的下行子帧属于不 同载波;
接收模块 601 ,还用于接收该网络侧设备在每一组中的各个下行子帧上 发送的 PDCCH信息;
生成模块 603, 用于针对划分模块 602划分得到的每一组,根据该组中 各个 PDCCH信息中的 DAI值,以及 PDCCH信息指示的 PDSCH所对应的 ACK/NACK, 生成 N个比特的 ACK/NACK;
发送模块 604 , 用于将生成模块 603 生成的每一组对应生成的 ACK/NACK发送给该网络侧设备。 本实施例提供的用户设备通过改变 DAI计数方式避免 ACK/NACK反 馈信息产生交叠, 从而避免了 ACK/NACK反馈信息错误。 以上实施例提供的技术方案中的全部或部分内容可以通过软件编程实 现, 其软件程序存储在可读取的存储介质中, 存储介质例如: 计算机中的 硬盘、 光盘或软盘。
以上所述仅为本发明的较佳实施例, 并不用以限制本发明, 凡在本发
明的精神和原则之内, 所作的任何修改、 等同替换、 改进等, 均应包含在 本发明的保护范围之内。
Claims
1、 一种传输确认或不确认指示信息的方法,其特征在于,所述方法包 括:
网络侧设备为用户设备 UE配置至少两个载波,其中包括一个主载波和 至少一个辅载波;
所述网络侧设备在第一下行子帧上向所述 UE发送 PDCCH信息,所述 PDCCH信息指示在第二下行子帧上承载的 PDSCH的调度信息;
所述网络侧设备在所述 PDSCH 所在子帧与所述 PDSCH 对应的 ACK/NACK所在子帧之间的至少两个定时关系中选择一个作为第一定时关 系,其中 ,所述第一定时关系满足第一条件,所述第一条件为 :所述第一 定时关系所对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行 子帧;确定与该第一定时关系对应的、 用于所述 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧;以及确定用于所述 UE发送所述 PDSCH对 应的 ACK/NACK的第一载波;
所述网络侧设备将所确定的所述第三上行子帧和第一载波所对应的相 关信息指示给 UE;
所述网络侧设备在所述第一载波的所述第三上行子帧中 ,确定用于所 述 UE反馈所述 PDSCH对应的 ACK/NACK的第一信道资源,并将所述第 一信道资源指示给 UE;
所述网络侧设备接收所述 UE在所述第一载波上的所述第三子帧上的 所述第一信道资源上反馈的 ACK/NACK。
2、根据权利要求 1所述的方法,其特征在于,所述至少两个定时关系, 包括对应不同载波的定时关系;和 /或,包括对应同一载波的不同定时关系, 其中 ,所述不同定时关系所对应的下行子帧在所述载波上所对应的、 用于 ACK/NACK反馈的上行子帧不同。
3、 根据权利要求 1或 2所述的方法,其特征在于,
所述网络侧设备从至少两个定时关系中选择一个作为第一定时关系, 包括:
如果所述至少两个定时关系对应不同载波,则选择满足所述第一条件, 且满足如下条件之一的定时关系:所述不同载波中 ACK/NACK信道的负载 最小的载波所对应的定时关系;所述不同载波中 ACK/NACK反馈时延最小 的载波所对应的定时关系;以及不同载波中 UE所需发送功率最小的载波所 对应的定时关系;
和 /或,
如果所述至少两个定时关系对应同一载波中的不同上行子帧,则选择 满足所述第一条件,且满足如下条件之一的的定时关系:所述同一载波中 负载最小的上行子帧所对应的定时关系,以及所述同一载波中 ACK/NACK 反馈时延最小的上行子帧所对应的定时关系。
4、 根据权利要求 1至 3任意一项所述的方法,其特征在于,所述确定 用于所述 UE发送所述 PDSCH对应的 ACK/NACK的第一载波,包括: 根据定时关系与载波的对应关系,确定所述第一定时关系所对应的第 一载波。
5、 根据权利要求 1或 2所述的方法,其特征在于,
所述确定用于所述 UE发送所述 PDSCH对应的 ACK/NACK的第一载 波,包括:
如果所述至少两个定时关系对应不同载波,则选择满足其所对应的定 时关系满足所述第一条件,且满足如下条件之一的载波作为所述第一载波: 所述不同载波中 ACK/NACK 信道的负载最小的载波;所述不同载波中 ACK/NACK反馈时延最小的载波;以及不同载波中 UE所需发送功率最小 的载波。
6、 根据权利要求 1、 2或 5所述的方法,其特征在于,
所述网络侧设备从至少两个定时关系中选择一个作为第一定时关系, 包括:
如果所述至少两个定时关系对应不同载波,则根据定时关系与载波的 对应关系,确定所述第一载波所对应的定时关系为所述第一定时关系。
7、 根据权利要求 1至 6任意一项所述的方法,其特征在于,
所述将所确定的第三上行子帧和第一载波所对应的相关信息指示给所 述 UE ,包括:将所选择的第一定时关系作为所述相关信息指示给所述 UE; 或者包括:如果定时关系对应不同载波,则将所选择的第一载波作为 所述相关信息指示给所述 UE。
8、 一种传输确认或不确认指示信息的方法,其特征在于,所述方法包 括:
UE确定网络侧设备配置给所述 UE的两个载波,其中包括一个主载波 和至少一个辅载波;
所述 UE接收所述网络侧设备在第一下行子帧上向 UE发送的 PDCCH 信息,所述 PDCCH信息指示第二下行子帧上承载的 PDSCH的调度信息; 所述 UE获取所述网络侧设备发送的指示信息,根据所述指示信息确定 所述网络侧设备为所述 UE确定的、用于反馈 ACK/NACK的第三上行子帧 及第一载波;所述指示信息所对应的第一定时关系满足第一条件:定时关 系所对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧; 所述 UE获取网络侧设备分配给所述 UE用于反馈所述 PDSCH对应的 ACK/NACK的第一信道资源;
所述 UE在所述第一载波中所述第三上行子帧的所述第一信道资源上 发送所述 PDSCH对应的 ACK/NACK。
9、 根据权利要求 8所述的方法,其特征在于,
所述 UE获取的指示信息为所述网络侧设备选择的第一定时关系, 则所述根据所述指示信息确定所述第三上行子帧及第一载波,包括: 根据所述第一定时关系以及所述 PDSCH所在的第二下行子帧,确定用 于所述 UE发送该 PDSCH对应的 ACK/NACK的第三上行子帧,以及根据 定时关系与载波的对应关系确定所述第一定时关系所对应的第一载波; 和 /或,所述 UE获取的指示信息为第一载波的信息,
则所述根据所述指示信息确定所述第三上行子帧及第一载波,包括: 根据所述载波与定时关系的对应关系确定所述第一载波所对应的第一 定时关系,并根据所述第一定时关系以及所述 PDSCH所在的第二下行子帧 确定相应的所述第三上行子帧。
10、 一种网络侧设备,其特征在于,所述网络侧设备包括:发送单元、 接收单元和处理单元,其中 ,
所述发送单元,用于将所述处理单元配置的载波通知给 UE;在第一子 帧上向所述 UE发送 PDCCH信息,所述 PDCCH信息用于指示第二下行子 帧上承载的 PDSCH的调度信息;以及将所述处理单元确定的第三上行子帧 及第一载波所对应的相关信息,以及所述处理单元确定的第一信道资源指 示给所述 UE;
所述处理单元,用于为所述 UE配置至少两个载波,其中包括一个主载 波和至少一个辅载波;在所述 PDSCH 所在子帧与所述 PDSCH对应的 ACK/NACK所在子帧之间的至少两个定时关系中选择一个作为第一定时关 系,其中 ,所述第一定时关系满足第一条件,所述第一条件为 :定时关系 对应的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧;确定 与所述第一定时关系对应的、 用于 UE发送该 PDSCH对应的 ACK/NACK 的第三上行子帧;确定用于 UE发送所述 PDSCH对应的 ACK/NACK的第 一载波;以及在所确定的第一载波的第三上行子帧中 ,确定用于所述 UE 反馈所述 PDSCH对应的 ACK/NACK的第一信道资源;
所述接收单元,用于接收所述 UE在所述第一载波中所述第三子帧的所 述第一信道资源上反馈的 ACK/NACK。
11、 根据权利要求 10所述的网络侧设备,其特征在于,
所述处理单元包括:配置单元、 定时关系及子帧确定单元、 载波确定 单元、 以及信道资源确定单元;其中 ,
所述配置单元,用于为所述 UE配置至少两个载波,其中包括一个主载 波和至少一个辅载波,并将所配置的载波信息输出给所述发送单元;
所述定时关系及子帧确定单元,用于在所述 PDSCH所在子帧与所述 PDSCH对应的 ACK/NACK所在子帧之间的至少两个定时关系中选择一个 作为第一定时关系,其中 ,所述第一定时关系满足第一条件,所述第一条 件为 :定时关系对应的第一载波上与上述第二下行子帧时刻相同的子帧为 下行子帧,以及确定与该第一定时关系对应的、 用于 UE发送该 PDSCH对 应的 ACK/NACK的第三上行子帧;
所述载波确定单元,用于确定用于所述 UE发送所述 PDSCH对应的 ACK/NACK的第一载波;
所述信道资源确定单元,用于在所述定时关系及子帧确定单元所确定 的第三上行子帧中 ,以及在所述载波确定单元所确定的第一载波上,确定 用于 UE反馈所述 PDSCH对应的 ACK/NACK的第一信道资源。
12、 根据权利要求 11所述的网络侧设备,其特征在于,
所述定时关系及子帧确定单元用于,
在所述至少两个定时关系对应不同载波时,选择满足所述第一条件, 且满足如下条件之一的定时关系作为所述第一定时关系:所述不同载波中
ACK/NACK信道的负载最小的载波所对应的定时关系;所述不同载波中 ACK/NACK反馈时延最小的载波所对应的定时关系;以及不同载波中 UE 所需发送功率最小的载波所对应的定时关系;和 /或,
在所述至少两个定时关系对应同一载波中的不同上行子帧时,选择满 足所述第一条件,且满足如下条件之一的定时关系作为所述第一定时关系: 所述同一载波中负载最小的上行子帧所对应的定时关系,以及所述同一载 波中 ACK/NACK反馈时延最小的上行子帧所对应的定时关系;
以及,确定与所述第一定时关系对应的、 用于 UE发送该 PDSCH对应 的 ACK/NACK的第三上行子帧。
13、 根据权利要求 11或 12所述的网络侧设备,其特征在于, 所述载波确定单元,用于根据定时关系及子帧确定单元所确定的第一 定时关系,确定用于 UE发送该 PDSCH对应的 ACK/NACK的第一载波。
14、 根据权利要求 11所述的网络侧设备,其特征在于,
所述载波确定单元,在所述至少两个定时关系对应不同载波时,选择 满足其所对应的定时关系满足所述第一条件,且满足如下条件之一的载波 作为所述第一载波:所述不同载波中 ACK/NACK信道的负载最小的载波; 所述不同载波中 ACK/NACK反馈时延最小的载波;以及不同载波中 UE所 需发送功率最小的载波。
15、 根据权利要求 11或 14所述的网络侧设备,其特征在于, 所述定时关系及子帧确定单元,用于在所述至少两个定时关系对应不 同载波时,根据定时关系与载波的对应关系,确定所述第一载波所对应的、 满足所述第一条件的定时关系为所述第一定时关系,以及确定与该第一定 时关系对应的、 用于 UE发送该 PDSCH对应的 ACK/NACK的第三上行子 帧。
16、 根据权利要求 10至 15任意一项所述的网络侧设备,其特征在于, 所述发送单元中的将所述处理单元确定的第三上行子帧及第一载波所 对应的相关信息,包括:将所选择的第一定时关系作为所述相关信息指示 给所述 UE;或者,在定时关系对应不同载波时,将所述第一载波的信息作 为所述相关信息指示给所述 UE。
17、 一种用户设备,其特征在于,包括:接收单元、 处理单元和发送 单元,其中 ,
所述接收单元,用于接收网络侧设备为用户设备 UE分配的两个载波的 信息,其中包括一个主载波和至少一个辅载波;接收所述网络侧设备在第 一下行子帧上向所述 UE发送的 PDCCH信息,所述 PDCCH信息指示第二 下行子帧上承载的 PDSCH的调度信息;接收所述网络侧设备发送的指示信 息,所述指示信息所对应的第一定时关系满足第一条件:定时关系所对应 的第一载波上与所述第二下行子帧时刻相同的子帧为下行子帧;以及接收 所述网络侧设备为所述用户设备分配的、 用于反馈所述 PDSCH对应的 ACK/NACK的第一信道资源的信息;
所述处理单元,用于根据所述接收单元接收的指示信息确定所述网络 侧设备为所述 UE确定的、用于反馈 ACK/NACK的第三上行子帧及第一载 波;以及根据所述接收单元接收的所述第一信道资源的信息确定在所述第 一载波中所述第三上行子帧的所述第一信道资源上发送所述 PDSCH对应 的 ACK/NACK;
所述发送单元,用于将所述 PDSCH对应的 ACK/NACK在所述第一载 波中所述第三上行子帧的所述第一信道资源上发送。
18、 根据权利要求 17所述的用户设备,其特征在于,
所述接收单元接收的指示信息为所述网络侧设备选择的第一定时关 系,
所述处理单元用于,根据所述第一定时关系以及所述 PDSCH所在的第 二下行子帧,确定用于所述 UE发送该 PDSCH对应的 ACK/NACK的第三 上行子帧,以及根据定时关系与载波的对应关系确定所述第一定时关系所 对应的第一载波;以及根据所述接收单元接收的所述第一信道资源的信息 确定在所述第一载波中所述第三上行子帧的所述第一信道资源上发送所述 PDSCH对应的 ACK/NACK;
或者,所述接收单元接收的指示信息为第一载波的信息,
所述处理单元用于,根据载波与定时关系的对应关系确定所述第一载 波所对应的第一定时关系,并根据所述第一定时关系以及所述 PDSCH所在 的第二下行子帧确定相应的所述第三上行子帧;以及根据所述接收单元接 收的所述第一信道资源的信息确定在所述第一载波中所述第三上行子帧的 所述第一信道资源上发送所述 PDSCH对应的 ACK/NACK。
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EP2693675A1 (en) | 2014-02-05 |
CN102752085A (zh) | 2012-10-24 |
EP3761545A1 (en) | 2021-01-06 |
EP3761545B1 (en) | 2022-12-07 |
EP2693675A4 (en) | 2014-04-09 |
CN102752085B (zh) | 2014-09-17 |
US20160050059A1 (en) | 2016-02-18 |
US9571253B2 (en) | 2017-02-14 |
US9203587B2 (en) | 2015-12-01 |
US20170111156A1 (en) | 2017-04-20 |
US20140044092A1 (en) | 2014-02-13 |
EP2693675B1 (en) | 2020-06-24 |
US10225062B2 (en) | 2019-03-05 |
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