TWI456936B - Method for performing hybrid automatic repeat request operation in a wireless mobile communication system - Google Patents

Claims (30)

A method for performing a hybrid automatic repeat request (HARQ) operation in a wireless mobile communication system, the wireless mobile communication system using a frame, each frame having a plurality of sub-frames for communication, the method comprising: According to #l in the #i frame The data transmitted in the downlink (DL) subframe transmits the assignment information to determine the HARQ timing, where the HARQ timing includes the transmission time of the DL data burst and the transmission time of the HARQ feedback for the DL HARQ; and according to the determined The HARQ timing to perform a HARQ operation, wherein And i determining at least one frame index indicating the HARQ timing and at least one subframe index. A method of performing a HARQ operation as described in claim 1, wherein when a frequency division duplex (FDD) mode is used, the HARQ timing is determined by a result value calculated as follows: for the finger in the downlink Equipped with advanced-MAP information element (A-MAP IE), the sub-frame index of the advanced-MAP information element is l , the index of the advanced-MAP information element is i For the HARQ sub-packet transmission in the downlink, the subframe index of the HARQ sub-packet transmission is m, and m=l , the frame index of the HARQ sub-packet transmission is i And for HARQ feedback in the uplink (UL), the subframe index of the HARQ feedback is n, and n =ceil (m +F /2) modF , the frame index of the HARQ feedback is j, and; wherein Means carrying the assignment containing the information on the distribution of the information The index of the sub-frame of the A-MAP IE, i indicates the index of the frame carrying the assigned A-MAP IE, and m indicates the index of the sub-frame corresponding to the transmission of the HARQ sub-packet of the data burst. n denotes the index of the subframe carrying the HARQ feedback, j denotes the index of the frame carrying the HARQ feedback, F denotes the number of subframes per frame, and N denotes the number of frames per superframe, and If each hyperframe has four frames, N is 4 and z represents the DL HARQ feedback offset. The method for performing a HARQ operation as described in claim 2, wherein the DL HARQ feedback offset z is determined according to a data burst processing time of the HARQ sub-packet burst by the following equation, Where ceil() represents the top function, NTTI Indicates the number of subframes that the HARQ sub-packet spans, and Rx_time represents the data burst processing time. A method of performing a HARQ operation as described in claim 2, wherein the retransmission of the data burst corresponding to the HARQ feedback is a pre-defined number of frames from the transmission of the data burst Then, start in the sub-frame with the same index m. The method for performing a HARQ operation as described in claim 2, wherein performing the HARQ operation comprises: transmitting, by a base station (BS) to a mobile station (MS), a #m DL subframe in a #i frame The starting HARQ sub-packet; and the #n uplink (UL) of the #j frame received by the BS from the MS The HARQ feedback for the HARQ sub-packet in the subframe. The method of performing a HARQ operation as described in claim 2, wherein performing the HARQ operation comprises: receiving, by the MS from the BS, the beginning of the #m DL subframe in the #i frame a HARQ sub-packet; and the HARQ feedback for the HARQ sub-packet in the #n UL subframe of the #j frame transmitted by the MS to the BS. A method of performing a HARQ operation as described in claim 1, wherein when the FDD mode is used and the data burst in the long transmission time interval (TTI) occupies two or more sub-frames, the following The equation or a table having a result value according to the following equation to determine the HARQ timing, n =ceil (l +F /2) modF Where l An index indicating a sub-frame carrying the assigned A-MAP IE containing the data bursting assignment information, i indicating an index of a frame carrying the assigned A-MAP IE, and m indicating a corresponding burst of the data HARQ sub-sealing The index of the subframe in which the transmission of the packet can start, n represents the index of the subframe carrying the HARQ feedback, j represents the index of the frame carrying the HARQ feedback, and F represents the number of subframes per frame, N Indicates the number of frames per superframe, and if each hyperframe has four frames, N is 4, z represents the DL HARQ feedback offset, and ###### Child frame. A method of performing a HARQ operation as described in claim 1, wherein when a time division duplex (TDD) mode is used, the HARQ timing is determined by a result value calculated as follows: for the finger in the downlink With advanced-MAP information element transmission, the sub-frame index of the advanced-MAP information element is l , the index of the advanced-MAP information element is i For the HARQ sub-packet transmission in the downlink, the subframe index of the HARQ sub-packet transmission is m and m=l , the frame index of the HARQ sub-packet transmission is i And for HARQ feedback in the uplink (UL), the subframe index of the HARQ feedback is n: For D>U, for DU,n =m -K And the frame index of the HARQ inverse product is j and j =(i +z )modN Where each frame has a D downlink (DL) subframe and a U uplink (UL) subframe, An index representing a sub-frame of the assigned A-MAP IE containing the information of the distribution information, ranging from 0 to D-1, i denotes an index of a frame carrying the assigned A-MAP IE, m denotes an index of a subframe corresponding to the start of transmission of the HARQ sub-packet of the data burst, and n denotes a sub-carrier carrying the HARQ feedback The index of the frame, j represents the index of the frame carrying the HARQ feedback, N represents the number of frames per hyperframe, z represents the DL HARQ feedback offset, and if D is equal to or less than U, then K is determined by -ceil{ (UD)/2} is calculated, and if D is greater than U, K is calculated by floor{(DU)/2}. A method for performing a HARQ operation as described in claim 8, wherein the DL HARQ feedback offset z is determined according to a data burst processing time of the HARQ sub-packet burst by the following equation, Among them NTTI Indicates the number of subframes that the HARQ sub-packet spans, and Rx_time represents the data burst processing time. A method of performing a HARQ operation as described in claim 8 wherein the retransmission of the data burst corresponding to the HARQ feedback is after a predetermined number of frames from the transmission of the data burst Start in the sub-frame with the sub-frame index m. A method for performing a HARQ operation as described in claim 8 wherein the subframe index is , m, n are used as DL sub-frame index, each sub-frame index l , m, n from 0 to D-1, D is the number of DL subframes defined in each frame except for the period supporting the legacy system, if the subframe index l , m, n are used as the UL sub-frame index, each sub-information Box index l , m, n from 0 to U-1, U is the number of UL subframes defined in each frame except for the period supporting the legacy system, the frame index corresponding to each frame The sub-frame index order for the entire period of the cycle supporting the legacy system is calculated. A method for performing a HARQ operation as described in claim 8 wherein the subframe index is , m, n is used as the DL sub-frame index, then the DL subframe index is a reordered index for use in the DL subframe of the communication from the relay station (RS) to the MS, if the subframe index l , m, n is used as the UL subframe index, then the UL subframe index is a reordered index for the UL subframe of the communication from the MS to the RS, the frame index is corresponding to each message The sub-frame index order of the entire period used to communicate with the RS is calculated. The method for performing a HARQ operation as described in claim 8 wherein the performing the HARQ operation comprises: transmitting, by the base station (BS) to the mobile station (MS), in the #m DL subframe of the #i frame. The starting HARQ sub-packet; and the HARQ feedback for the HARQ sub-packet in the #n uplink (UL) subframe of the #j frame received by the BS from the MS. The method of performing a HARQ operation as described in claim 8, wherein performing the HARQ operation comprises: receiving, by the MS, the BS from the BS starting in the #m DL subframe of the #i frame a HARQ sub-packet; and the HARQ feedback for the HARQ sub-packet in the #n UL subframe of the #j frame transmitted by the MS to the BS. A method for performing a HARQ operation as described in claim 1, wherein the assignment A-MAP IE including the information distribution information indicates a long transmission time interval (TTI) and If the value is not 0 in the TDD mode, the HARQ sub-packet is transmitted in the #0 DL subframe of the #(i+1) frame, and the HARQ feedback of the HARQ sub-packet is #n' in the #j' frame. The UL subframe is transmitted, and the long TTI transmission indicates that the HARQ sub-packet spans two or more subframes and the subframe index n' and the frame index j' are determined by the following equation or by a table having a result value according to the following equation, n '=l -K For DU j '=((i +1)+z )modN . A method for performing a hybrid automatic repeat request (HARQ) operation in a wireless mobile communication system, the wireless mobile communication system using a frame, each frame having a plurality of sub-frames for communication, the method comprising: According to #l in the #i frame The data transmitted in the downlink (DL) subframe transmits the assignment information to determine the HARQ timing, and the HARQ timing includes the transmission time of the uplink (UL) data burst, the transmission time of the HARQ feedback, and the UL HARQ Retransmitting time of the data burst; and performing HARQ operations according to the determined HARQ timing, Which uses l And i determining at least one frame index indicating the HARQ timing and at least one subframe index. A method of performing a HARQ operation as described in claim 16, wherein when a frequency division duplex (FDD) mode is used, the HARQ timing is determined by a result value calculated as follows: for the finger in the downlink Equipped with the Advanced-MAP Information Element (A-MAP IE), the sub-frame index of the Advanced-MAP Information Element is l. , the index of the advanced-MAP information element is i For the HARQ sub-packet transmission in the uplink (UL), the subframe index of the HARQ sub-packet is m, and m=n, where n =ceil (l +F /2) modF The frame index of the HARQ sub-packet is j and; and for the HARQ feedback in the downlink, the subframe index of the HARQ feedback is l , the frame index of the HARQ feedback is k and, where An index indicating a sub-frame carrying the assigned A-MAP IE containing the data bursting assignment information, i indicating an index of a frame carrying the assigned A-MAP IE, and m indicating a corresponding burst of the data The index of the subframe in which the transmission of the HARQ sub-packet can start, j represents the index of the frame carrying the HARQ feedback, F represents the number of subframes per frame, and N represents the number of frames of each hyperframe. And if each hyperframe has four frames, N is 4, k represents an index of the frame carrying the HARQ feedback, v represents a UL HARQ transmission offset, and w represents a UL HARQ feedback offset . A method for performing a HARQ operation as described in claim 17 wherein the processing time of the HARQ sub-package is based on a table of the following equations or a result value having an equation according to the following table Determining the UL HARQ transmission offset v and the UL HARQ feedback offset w, Where ceil() represents the top function, floor() represents the floor function, NTTI Indicates the number of subframes that the HARQ sub-packet spans, and Rx_time represents the data burst processing time. A method of performing a HARQ operation as described in claim 17, wherein the retransmission of the data burst corresponding to the HARQ feedback is started at a time determined by a result value calculated as follows: for the uplink The HARQ sub-packet in the path is retransmitted, the sub-frame index of the HARQ sub-packet re-transmit is m, and the frame index of the HARQ sub-packet re-transmit is p and; wherein p represents the case where the HARQ feedback is a negative acknowledgement (NACK) The index of the retransmission startable frame of the data burst, v represents the UL HARQ transmit offset, and w represents the UL HARQ feedback offset. The method for performing a HARQ operation according to claim 17, wherein the performing the HARQ operation comprises: receiving, by the base station (BS), the #m UL subframes of the #j frame from the mobile station (MS) The starting HARQ sub-packet; the #l transmitting the #k frame to the MS by the BS The HARQ feedback for the HARQ sub-packet in a downlink (DL) subframe; and the HARQ starting from the #m UL subframes of the p-th frame received by the BS from the MS Re-emission of the sub-packet. The method of performing a HARQ operation as described in claim 17, wherein performing the HARQ operation comprises: transmitting, by the MS to the BS, the beginning of the #m UL subframes of the #j frame a HARQ sub-packet; receiving, by the MS, the #l frame from the BS The HARQ feedback for the HARQ sub-packet in DL subframes; and the re-transmitting from the MS to the BS starting from the #m UL subframes of the #p frames Said HARQ packet. A method for performing a HARQ operation as described in claim 16, wherein when the FDD mode is used and the data burst in the long transmission time interval (TTI) occupies two or more sub-frames, the following The equation or a table having a result value according to the equations of the following table to determine the HARQ timing, n =ceil (l +F /2) modF Where l An index indicating a sub-frame carrying the assigned A-MAP IE containing the data bursting assignment information, i indicating an index of a frame carrying the assigned A-MAP IE, and m indicating a corresponding burst of the data The index of the subframe in which the HARQ sub-packet can be transmitted, n is the index of the subframe carrying the HARQ feedback, j is the index of the frame carrying the HARQ feedback, and F is the number of subframes per frame. , N indicates the number of frames per superframe, and if each hyperframe has four frames, N is 4, and p indicates that the data bursts when the HARQ feedback is NACK. The index of the frame in which the retransmission can start, v represents the UL HARQ transmission offset, w represents the UL HARQ feedback offset, and represents #yn of the #i frame Child frame. Performing HARQ operations as described in claim 16 a method, wherein when a time division duplex (TDD) mode is used, the HARQ timing is determined by a result value calculated below: for an assigned Advanced-MAP Information Element (A-MAP IE) transmission in the downlink, The sub-frame index of the advanced-MAP information element is l , the index of the advanced-MAP information element is i For the HARQ sub-packet transmission in the uplink, the subframe index of the HARQ sub-packet transmission is m, and for the DU, For l <D<U, for D=l , m=0,1,..., or U-1, for 1 =0, and the frame index of the HARQ sub-packet transmission is j, and j=(i+v) mod N; and for the HARQ feedback in the downlink, the subframe index of the HARQ feedback is 1 The frame index of the HARQ feedback is k, and k=(j+1+w) mod N: each frame has a D downlink (DL) subframe and a U uplink (UL) subframe. ,l An index indicating a sub-frame carrying the assigned A-MAP IE containing the data bursting assignment information, the range from 0 to D-1, i indicating the index of the frame carrying the assigned A-MAP IE, m Indicates an index of a subframe that can be started corresponding to the transmission of the HARQ sub-packet of the data burst, and n denotes an index of the subframe that carries the HARQ feedback, j Indicates the index of the frame carrying the HARQ feedback, where N is the number of frames per hyperframe, and if each hyperframe has four frames, N is 4, k is the signal carrying the HARQ feedback. The index of the frame, v represents the UL HARQ transmission offset, w represents the UL HARQ feedback offset, and if D is less than U, K is calculated by -ceil{(UD)/2}, and if D is equal to or greater than U, Then K is calculated by floor{(DU)/2}. The method for performing a HARQ operation according to claim 23, wherein the UL HARQ transmission offset v and the UL are determined according to a data burst processing time of the HARQ sub-packet by the following equation HARQ feedback offset w, The TTI indicates the number of subframes spanned by the HARQ sub-packets, and both Tx_Time and Rx_Time indicate the data burst processing time. A method of performing a HARQ operation as described in claim 23, wherein the retransmission of the data burst corresponding to the HARQ feedback is started at a time determined by the following calculation: for the uplink The HARQ sub-packet is retransmitted, the sub-frame index of the HARQ sub-packet re-transmit is m, and the frame index of the HARQ sub-packet is p, and p =(k +v ) mod 4; Where p denotes an index of the frame in which the retransmission of the data burst can begin if the HARQ feedback is a negative acknowledgement (NACK). A method for performing a HARQ operation as described in claim 23, wherein if the subframe index is , m, n are used as DL sub-frame index, each sub-frame index l , m, n from 0 to D-1, D is the number of DL subframes defined in each frame except for the period supporting the legacy system, if the subframe index l , m, n is used as the UL sub-frame index, and each sub-frame index l , m, n from 0 to U-1, U is the number of UL subframes defined in each frame except for the period supporting the legacy system, the frame index corresponding to each frame The sub-frame index order of the entire period of the cycle supporting the legacy system is calculated. A method for performing a HARQ operation as described in claim 23, wherein if the subframe index is , m, n is used as the DL sub-frame index, then the DL subframe index is a reordered index for use in the DL subframe of the communication from the relay station (RS) to the MS, if the subframe index l , m, n is used as the UL subframe index, then the UL subframe index is a reordered index for the UL subframe of the communication from the MS to the RS, the frame index is corresponding to each message The sub-frame index order of the entire period used to communicate with the RS is calculated. The method for performing a HARQ operation according to claim 23, wherein performing the HARQ operation comprises: receiving, by a base station (BS), a #m UL subframe from a mobile station (MS) The starting HARQ sub-packet; the #l transmitting the #k frame to the MS by the BS Downlink (DL) The HARQ feedback for the HARQ sub-packet in the subframe; and the re-transmitting of the HARQ sub-packet starting from the #m UL subframes of the p-th frame from the MS. The method of performing a HARQ operation as described in claim 23, wherein performing the HARQ operation comprises: transmitting, by the MS to the BS, the #m UL subframes of the #j frame a HARQ sub-packet; receiving, by the MS, the #l frame from the BS The HARQ feedback for the HARQ sub-packet in DL subframes; and the re-transmitting from the MS to the BS starting from the #m UL subframes of the #p frames Said HARQ sub-packet. The method for performing a HARQ operation as described in claim 16 of the patent application, wherein the assignment A-MAP IE including the data distribution assignment information indicates that the long transmission time interval (TTI) is transmitted in the TDD mode, The #0UL subframe in the #j frame starts to transmit the HARQ sub-packet corresponding to the data burst, and the HARQ feedback of the HARQ sub-packet is #l in the #p frame. The UL subframe is transmitted, and the long TTI transmission indicates that the HARQ sub-packet spans two or more subframes.