KR100469708B1 - Apparatus and method for demodulating an f-pdcch and an f-pdch in a mobile station of a mobile communication system - Google Patents

Abstract

The present invention discloses a mobile station apparatus and method for demodulating a packet data control channel and a packet data channel in a mobile communication system. In accordance with another aspect of the present invention, a demodulation device for a mobile station includes: a packet data control channel information division control unit for dividing and outputting information strings received in a packet data control channel into respective packet transmission units; and packet data control channel information divided into each packet transmission unit. And a packet data channel demodulation control unit for controlling demodulation of the packet data information string received through the packet data channel based on the output of the packet data control channel demodulation unit. It is done.

Description

Apparatus and method for demodulating a packet data control channel and a packet data channel in a mobile station of a mobile communication system {APPARATUS AND METHOD FOR DEMODULATING AN F-PDCCH AND AN F-PDCH IN A MOBILE STATION OF A MOBILE COMMUNICATION SYSTEM}

The present invention relates to a receiver apparatus and method of a mobile station in a mobile communication system, and more particularly, to a receiver apparatus and method of a mobile station for receiving high-speed packet data transmitted from a base station in a multimedia mobile communication system.

The typical mobile communication system, the IS-2000 mobile communication system, only supports voice and low-speed circuit and packet data services. However, as the technology evolves with the needs of the user, the mobile communication system is developing in the form of supporting a high speed packet data service. In particular, a mobile communication system such as CDMA2000 1xEV-DV has recently received much attention as a system for supporting high-speed packet data service as well as voice. Therefore, there is a need for a mobile station receiver apparatus capable of efficiently processing high-speed packet data while supporting voice services.

An object of the present invention is to provide a receiver apparatus and method of a mobile station for efficiently receiving high speed packet data in a mobile communication system.

Another object of the present invention is to provide a mobile station receiver for efficiently demodulating an F-PDCH in a situation where a forward packet data control channel (F-PDCCH) exists in addition to the forward packet data channel (F-PDCH) in a high speed packet data communication system; In providing a method.

It is another object of the present invention to provide a mobile station receiver apparatus and method for efficiently demodulating an F-PDCH.

Another object of the present invention is to provide a receiver apparatus and method capable of controlling a demodulation operation of an F-PDCH according to a demodulation result of an F-PDCCH.

It is still another object of the present invention to provide a receiver device and a method capable of simultaneously demodulating a plurality of Walsh codes when one user uses several Walsh codes.

Still another object of the present invention is to transmit a plurality of IR / Chase Combining Blocks that can support parallel transmission used for efficient packet transmission when channel resources are sufficient. The present invention provides a receiver apparatus and method capable of independently performing an IR / Chase combining operation for each packet.

It is still another object of the present invention to generate a control signal for removing unnecessary demodulation operations by buffering or stopping the demodulation operation of the F-PDCH signal transmitted together with the control channel according to the demodulation result of the control channel. To provide a receiver device and method.

In order to achieve the above objects, the present invention includes information for distinguishing a user, retransmission channel classification information, encoded packet size, and packet classification information at retransmission, and the information is transmitted in any one packet transmission unit among predetermined packet transmission units. A packet data control channel for transmitting one or more Walsh codes to the packet data to be transmitted, and a packet data channel for transmitting the packet data in parallel when two or more Walsh codes are assigned, the packet data control channel and the packet data In a mobile communication system for transmitting information together in a channel, the mobile station apparatus demodulating the packet data control channel and the packet data channel, wherein the information strings received in the packet data control channel are divided and outputted in the respective packet transmission units. A packet data control channel information segmentation control section; A packet data control channel demodulator for demodulating and outputting packet data control channel information strings divided by a packet transmission unit, and information for identifying the user and retransmission channel classification information based on an output of the packet data control channel demodulator; And a packet data channel demodulation control unit for controlling demodulation of the packet data channel according to the information.

1 is a diagram illustrating a generation structure of an F-PDCH for a packet data service.

2 is a diagram illustrating an F-PDCCH generation structure for a packet data service.

3 is a diagram illustrating a forward link modulation structure for a packet data service;

4 is a timing diagram showing a timing relationship between a mobile station measuring a C / I value and a packet transmitted and received between base stations selected according to the measured C / I value.

5 is a diagram illustrating a structure of a mobile station apparatus according to an embodiment of the present invention for demodulation for each channel of a forward link.

6 is a diagram showing the structure of a mobile station apparatus according to an embodiment of the present invention for demodulating an F-PDCCH;

FIG. 7 is a flowchart illustrating an operation of the F-PDCH demodulation operation controller of FIG. 6.

8 illustrates a structure of a mobile station apparatus according to an embodiment of the present invention for symbol buffering and symbol demapping of an F-PDCH.

9 illustrates a structure of a mobile station apparatus from selection to decoding of encoded symbols of an F-PDCH according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same elements among the drawings are denoted by the same reference numerals and symbols as much as possible even though they are shown in different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First of all, the present invention relates to a structure of a mobile station receiver for demodulating a forward channel of a mobile communication system capable of supporting a voice service and a multimedia service including a low speed circuit and a high speed packet data service using 1x bandwidth. The structure of the transmitter, channel and receiver for supporting the voice service is the same as that of the transmitter, channel and receiver of the existing 1x system, respectively. Here, 1x bandwidth refers to a frequency bandwidth of 1.25MHz used in the existing IS-95 series North American synchronous system, and 1x system refers to a system supporting 1x bandwidth. Data services can be broadly divided into circuit mode (circuit mode operation) and packet mode (packet mode operation) data services according to the type of circuit connection for the service. The data service includes various video services such as a video conference, an Internet service, and the like. The dedicated line data service uses the structure of the transmitter, channel, and receiver of the existing 1x system. Therefore, in the present invention, only the structure of a transmitter, a channel, and a receiver for a high speed packet data service will be described.

First, in the mobile communication system according to an embodiment of the present invention summarized the forward link channels required for high-speed packet data service as shown in Table 1 below.

Forward Channels for Packet Data Services channel Usage Remarks Forward-Pilot Channel (F-PICH) It is used for mobile station synchronous demodulation and can also be used as a means for measuring carrier-to-interference ratio (CIR) for rate control. Common Channel Forward-Packet Data Control Channel (F-PDCCH) Simultaneously transmitted with F-PICH, F-PDCH, etc., which user is assigned to the data packet transmitted by the base station (MAC_ID), whether the transmitted packet is a new packet or a retransmitted packet (SP_ID), and four transmitted packets Among the ARQ channels, information such as the number of ARQ channels (ARQ_ID) and the packet size of the transmitted packet (Encoder Packet Size) is included. Control Channel Forward-Packet Data Channel (F-PDCH) Simultaneous transmission of F-PICH, F-PDCCH, etc. Traffic Channel

Referring to Table 1, channels for a forward link packet data service according to an embodiment of the present invention are largely divided into a common channel, a control channel, and a traffic channel. The common channel, which represents the F-PICH, provides a reference amplitude and a phase change amount for synchronous demodulation in a mobile station. In the traffic channel, there is actually an F-PDCH through which packet data is transmitted. The control channel transmits information related to the traffic channel. The control channel is an F-PDCCH, which is assigned to which user a forwarded packet is assigned (Medium Access Control Identification (MAC_ID)), and whether the forwarded packet is a new or retransmitted packet (Sub-Packet Identification: SP_ID). ), Which number of ARQ channels is transmitted among the four ARQ (Automatic Repeat Request) channels (ARQ channel identification: ARQ_ID), and the packet size of the transmitted packet (Encoder Packet Size). Doing. Packets transmitted from the base station to the F-PDCH are simultaneously received by all users, but the mobile station cannot know which packet corresponds to itself. Therefore, the demodulation is first performed on a control channel having a relatively small amount of data for transmitting user information and packet information on a packet transmitted through the F-PDCH. Therefore, the packet information transmitted on the F-PDCH cannot be determined until the demodulation on the control channel is finished. In addition, it is necessary to temporarily store a packet transmitted on the F-PDCH until the demodulation on the F-PDCCH is completed. The present invention proposes a configuration of a mobile station receiver including a demodulation device for an F-PDCCH which is a control channel related to the F-PDCH demodulation and an algorithm for demodulating the F-PDCH according to the F-PDCCH demodulation result.

1 shows an F-PDCH generation structure in a forward link transmitter for packet data service. Referring to FIG. 1, the packet data is added by a CRC bit adder (Add 16 Bit Packet Cyclic Redundancy Check) block (2), followed by a turbo encoder tail bit adder (Add 6 Bit Turbo Encoder Tail). Turbo encoder tail bits are added in the allowance block (4) and then turbo encoded in the turbo encoder (Turbo Encoder R = 1/5 Block) 6. The coded output from the turbo encoder 6 is interleaved by a QCTC channel interleaver (QCTC) channel interleaver (8) and then the symbol selection in the QCTC symbol selection block (QCTC) is selected. do. The output of the QCTC symbol selector 10 is XORed at the adder 13 with the output of the scrambler 12 to perform data scrambling. The output of the adder 13 is modulated into I, Q symbols in a quadrature phase shift keying (QPSK), 8-PSK, and 16 quadrature amplitude modulation (QAM) modulator 14, and symbol DEMUX I / Q pairs 1 To N (N = 1 to 28)) 16, the base station is demultiplexed into I and Q channels by the number of 32 Walsh code channels currently available for the F-PDCH. The output of the symbol DEMUX 16 is Walsh diffused from the 32 Chip Walsh Subchannel Cover 1 18 and the 32 Chip Walsh Subchannel Cover 28 28, respectively. 32 Chip Walsh Sub Channel Cover 1 (18) ......... The outputs of the 32 Chip Walsh Sub Channel Cover 28 (20) are each channel of I and Q in Walsh Chip Level Summer (22). Will merge. Each of the I and Q outputs of the Walsh chip level adding unit 22 is input to the A and B terminals of FIG. 3, and then converted into RF (Radio Frequency) bands through PN spreading and baseband filtering, and then transmitted through an antenna.

2 shows a structure of generating an F-PDCCH in a forward link transmitter for packet data service. The forward link transmitter is characterized by transmitting code division multiplexing (CDM) with an F-PDCH signal and an F-PICH signal. Referring to FIG. 2, the F-PDCCH input sequence includes a 6-bit MAC_ID representing a user ID, a 2-bit SP_ID representing a Subpacket ID for retransmission, a 2-bit ARQ_ID representing an ID of an ARQ channel of each packet in parallel transmission, 3-bit Encoder Packet Size ID 13 bits of Encoder Packet Size ID. Therefore, when demodulating the F-PDCCH, it is possible to know whether the user ID and the currently transmitted packet are new packets or whether the previous packet has been retransmitted due to an error and also the size of the transmitted packet. In addition, when parallel transmission is used because channel resources are sufficient, ARQ processing for each transmission can be performed independently through the ARQ_ID bit. 13 bits of the F-PDCCH are determined for each N slot, and the value of N varies depending on the slot length of the transmitted F-PDCH. N = 1 when SUBPACKET_LENGTH = 1, N = 2 when SUBPACKET_LENGTH = 2, and N = 4 when SUBPACKET_LENGTH = 4, 8. The 13-bit F-PDCCH information is added to the CRC by the Add 8 Error Detection Encoder Bits Block 24 and then added by the Add 8 Encoder Tail Bits Block 26 to 8. After the bit tail bit is added, it is input to K = 9 Convolutional Encoder Block, R = 1/2 for N = 1, R = 1/4 for N = 2,4 . The output of the K = 9 convolutional encoder 28 becomes a 58N symbol after the symbol is repeated in the Symbol Repetition for N = 4 (Factor = 2) Block 30, and the 58N symbol is a symbol puncturing unit ( Symbol puncturing is performed in Puncture 10N Symbols Block) (32). The output of the symbol puncturing unit 32 is interleaved in the block interleaver 34 and then modulated into I, Q symbols in the QPSK modulator 36, and the output of the QPSK modulator 36 is multiplied by the multipliers 38 and 40. The multiplier is multiplied by a 64 Walsh code indicating an F-PDCCH channel, and the outputs of the multipliers 38 and 40 are input to the A and B terminals of FIG. 3 and then undergo the same process as the F-PDCH.

3 illustrates a structure of a forward link channel modulation in a forward link transmitter for packet data service. This figure shows an operation of orthogonally spreading various channel signals of the forward link as shown in FIGS. 1 and 2 and transmitting them as a signal suitable for transmission to a terminal by frequency shifting a signal of an RF band. Referring to FIG. 3, a channel gain block 42 corresponds to each channel to I and Q signals coming from respective channels (eg, F-PDCH, F-PDCCH, etc.). It multiplies the gain, and is combined by I and Q channels in Walsh Chip Summer 44. The I and Q outputs of the Walsh chip adder 44 are multiplied by PN_I and PN_Q codes in a quadrature spreading block 46 to spread the PN and then input to the baseband filters 48 and 50. And filtered. The outputs of the baseband filters 48 and 50 are multiplied by cos (2pif _c t) and sin (2pif _c t) in the multipliers 52 and 54 respectively, then summed in the adder 56 and finally transmitted to the antenna stage. do.

4 shows a timing relationship between a mobile station measuring a C / I value and packets transmitted and received between base stations selected according to the measured C / I value. As shown in FIG. 5, it can be seen that there is a delay of 3 slots until the C / I measurement result of the mobile station for the slot transmitted from the base station is actually reflected in the base station. Therefore, the Applied Channel Quality Indication (CQI Index) used in the Finger I MUX 112 of FIG. 5 becomes a CQI Index value of 3 slots before. In this case, the CQI Index value indicates a base serving sector having the largest C / I value for every 1.25 msec slot among a maximum of eight active sets.

5 shows a structure of a mobile station apparatus according to an embodiment of the present invention for demodulation for each channel of a forward link. Referring to FIG. 5, a signal received through an antenna is converted to baseband and then subjected to analog-to-digital (A / D) conversion. The Analog-to-Digital Converter (ADC) 100 outputs an 8x oversampled signal and the chip rate in the Finger i Decimator 102 for chip rate processing. After the decimation (1.2288Mcps) is input to the finger i PN despreader 1 ~ 8 (Finger i PN Despread 1 ~ 8) (110). The PN code, which is another input to the finger i PN despreader 1 to 8 (110), simultaneously generates up to eight active sets of PN codes generated by the finger i PN GEN 104. In order to demodulate the signals, the finger i PN offset masks 1 to 8 (108) generate a PN code using a mask corresponding to the pilot PN offset of each active set. In this case, the finger i PN offset control 106 may change the pilot PN offset of the base station corresponding to the case where the active set is changed, so even in this case, the pilot PN of the active set whose PN offset mask is changed is used. The finger i PN despreaders 1-8 (110) are each configured to satisfy an offset, and then the outputs are muxed at the finger i MUX (112) after PN despreading is performed. The role of Finger i MUX 112 is currently in the Active Set. In this case, the signal of the finger i MUX 112 which selects a signal having the best C / I is selected by an Applied CQI Index. The outputs of the finger i PN despreaders 1 to 8 110 are set to an active set m Finger IC / I measure (m = 0 to 7) 114. The input C / I value is measured and the output of the active set m finger i C / I measuring unit 114 is an active set m C / I combiner m = 0-7 (116) C / I values of the assigned fingers are added to each active set in step C. The output of the active set m C / I combiner 116 is input to the Best Serving Sector Select Block 118. As a result, the sector having the largest C / I is selected, and the output of the best sector selecting unit 118 is input to the CQI Index Buffer 120 and buffered. In the CQI Index buffer 120, a 3-slot delayed value is output as an Applied CQI Index input to the finger i MUX 112, which is a point in time when the C / I is measured at the mobile station and the base station is R-CQICH (Reverse). This is because a delay of 3 slots occurs as shown in FIG. 4 between time points transmitted using the CQI Index sent to the channel. The signal selected by the finger i MUX 112 is divided into three paths and processed respectively. The first path of the output of the finger i MUX 112 is input to the Finger i Channel Estimation unit 122 to extract the amplitude and phase change of the signal by the channel, which is the value of the F-PDCCH. The finger i lock multiplier 130 is input to the F-PDCCH Finger i Complex Multiply 130 to be used for demodulation of the F-PDCCH symbol and to determine the lock state of the finger. And a finger i lock detection signal (Finger i Lock Detection (i = 0 to n-1)). The second path of the finger i MUX 112 output is input to the F-PDCCH Finger i Walsh Despreader 128 to demodulate the F-PDCCH, thereby performing Walsh despreading. At this time, the Walsh code input to the F-PDCCH finger i Walsh despreader 128 is input from the F-PDCCH Finger i 64 Walsh Generator 126. The output of the F-PDCCH finger i Walsh despreader 128 is the coherent symbol demodulation in the F-PDCCH finger i complex multiplier 130, and then the F-PDCCH finger i FIFO memory (F-PDCCH). Finger i FIFO) (132). An F-PDCCH Finger i Symbol (i = 0 to n-1), which is an output of the F-PDCCH Finger i FIFO memory 132, is output from another finger as shown in FIG. And F-PDCCH symbol combiner (F-PDCCH Symbol Combiner) (146). The third path of the finger i MUX 112 output is input to the F-PDCH 28 Walsh Finger i Despreader 136 to be Walsh despread, which is the F-PDCH 28 Walsh. The Walsh code input to the finger i despreader 136 is input from the F-PDCH Finger i 32 Walsh Generator 134. The number of Walsh codes used is the current packet data. It depends on the number of Walsh codes used by the base station for the F-PDCH when sending, and up to 28 if 32 Walsh codes are used. The 28 parallel outputs of the F-PDCH 28 Walsh Finger i Despreader 136 are the finger i channel weights in the F-PDCH 28 Walsh Finger i Complex Multiply 138. Coherent symbol demodulation is achieved using the output of the government 122. The F-PDCH 28 Walsh finger i complex multiplier 138 outputs 28 Walsh 1 finger i FIFO memories 140, Walsh 2 finger i FIFO memories 142, .. Walsh 28 finger i FIFO. Each is input to the memory 144. The outputs of the Walsh m-finger i FIFO memories (m = 0-28, i = 0-n-1) (140, 142,..., 144) are Walsh 1 finger i I, Q symbols, Walsh, respectively. 2 finger i I, Q symbol, ....., Walsh 28 The finger i I, Q symbol (i = 0 ~ n-1) is output to the F-PDCH Walsh 1 symbol combining portion (F-PDCH Walsh) of FIG. 1 Symbol Combiner (184), F-PDCH Walsh 2 Symbol Combiner (186) ........., F-PDCH Walsh 28 Symbol Combiner Combiner 188 is combined with the output from the other finger.

6 is a diagram illustrating a mobile station apparatus according to an embodiment of the present invention for demodulating F-PDCCH, and illustrates a mobile station configuration for F-PDCCH demodulation after the F-PDCCH finger i FIFO memory 132 described with reference to FIG. 5. It is shown. Referring to FIG. 6, the F-PDCCH finger i symbols (i = 0 to n-1) of FIG. 5 are combined in the F-PDCCH symbol combiner 146 and then the F-PDCCH circular symbol buffer. In the F-PDCCH cyclic symbol buffer 148, a slot boundary is updated every 1.25 msec. The F-PDCCH Buffer Segmentation Control Block 150 extracts symbols of 1, 2 and 4 slot lengths from the F-PDCCH cyclic symbol buffer 148. Until the demodulation of the PDCCH, it is not possible to know how many slots the F-PDCH is composed of. Also, since the F-PDCCH itself may be configured with 1, 2, and 4 slots, the F-PDCCH is performed at the end of each 1.25msec 1 slot. This is because demodulation of all possible cases (1, 2, 4 slots) requires information about the F-PDCH. The output of the F-PDCCH buffer division controller 150 is an F-PDCCH 1 slot deinterleaver 152, an F-PDCCH 2 slot deinterleaver 154, and an F-PDCCH 4 slot deinterleaver. Each is deinterleaved at 156. The outputs of the F-PDCCH 1 slot deinterleaver 152, the F-PDCCH 2 slot deinterleaver 154, and the F-PDCCH 4 slot deinterleaver 156 are the F-PDCCH 1 slot deletion symbol insertion unit (F-PDCCH 1). Slot Erased Symbol Insertion (158), the F-PDCCH 2-slot deletion symbol insertion unit 160, and the F-PDCCH 4-slot deletion symbol insertion unit 162, respectively, after each of the symbols that were deleted after the insertion of the slot deletion symbol insertion output (1 Slot Erased Symbol Insertion Output), 2 Slot Delete Symbol Insertion Output, and 4 Slot Delete Symbol Insertion Output. The 1-slot deletion symbol insertion output is input to the F-PDCCH 1 slot R = 1/2 decoding unit 166 and decoded, and then the F-PDCCH decoding result selection unit ( Select Correct F-PDCCH Decoding Block) 174. The 2-slot deletion symbol insertion output is input to the F-PDCCH 2 slot R = 1/4 decoding unit 168 to be decoded and then decoded by the F-PDCCH decoding result selector ( 174). The 4-slot deletion symbol insertion output is normalized to sequence repetition symbols in the F-PDCCH 4 Slot Symbol Normalization block 164 and the F-PDCCH 4 is performed. The outputs of the slot symbol normalization unit 164 are F-PDCCH 4 slot R = 1/4 decoding units 170 and F-PDCCH 4 slot R = 1/4, respectively. The decoder is input to the decoder (F-PDCCH 4 Slot R = 1/4 Decoding) 172, decoded, and then is input to the F-PDCCH decoding result selector 174. The F-PDCCH decoding result selection unit 174 checks whether there are any CRC good packets among the four F-PDCCH decoding results that are input, and the test result is input to the F-PDCH demodulation operation control unit 176. .

7 is a flowchart illustrating the operation of the F-PDCH demodulation operation control unit 176 of FIG. Referring to FIG. 7, the F-PDCH demodulation operation controller 176 checks whether there is a CRC good in packet among four F-PDCCH decoding results input from the F-PDCCH decoding result selecting unit 174 (step 702). . If none of the four F-PDCCH decoding results in the F-PDCCH being a CRC good, the F-PDCH demodulation operation control unit 176 generates a signal called F-PDCH Stop to stop subsequent F-PDCH processing (step 704). ). If there is a CRC good F-PDCCH, the F-PDCH demodulation operation controller 176 checks whether the F-PDCCH sequence which is the result of F-PDCCH decoding of the corresponding slot length is "000000XXXXX11" (step 706). If the F-PDCCH sequence is 000000XXXXX11, the transmitted message is Walsh space, and the F-PDCH demodulation operation control unit 176 stores the sequence value as Walsh space available for the next 20msec (step 708). The number of Walsh codes currently used is indicated by Walsh space, and this value is changed according to the number of users of a voice call and broadcasted to all terminals before the next 20msec frame transmission by the base station. If the F-PDCCH sequence is not 000000XXXXX11, it is a message indicating information on the F-PDCH, and the F-PDCH demodulation operation controller 176 proceeds to step 710. In step 710, the F-PDCH demodulation operation control unit 176 first checks whether the MAC_ID received by the mobile station is an ID assigned to the mobile station itself. If the MAC_ID is not its ID, the F-PDCH demodulation operation control unit 176 proceeds to step 712 and sets the F-PDCH Stop signal to "1" to stop further operation. If the MAC_ID is the same as its ID, the F-PDCH demodulation operation controller 176 proceeds to step 714 to check the received SP_ID value. If the received SP_ID = 0, the F-PDCH demodulation operation control unit 176 proceeds to step 716 and checks the standby SP_ID value to check whether the packet currently waiting for the mobile station is a new packet with SP_ID = 0. If the packet currently waiting for the mobile station is a new packet (waiting SP_ID = 0), the F-PDCH demodulation operation control unit 176 proceeds to step 718 to perform normal operation and if the packet currently waiting for the mobile station is not a new packet (waiting). SP_ID ≠ 0) In step 720, the F-PDCH demodulation operation controller 176 clears one of the F-PDCH Subpacket n QCTC Buffers of FIG. 9 corresponding to the received ARQ_ID and performs a normal operation. If the SP_ID = 0 is not received in step 714, the F-PDCH demodulation operation controller 176 proceeds to step 722 to check whether the packet currently awaited by the mobile station is a continuous packet instead of SP_ID = 0. If the packet currently waiting for the mobile station is a continuous packet (waiting SP_ID? 0), the F-PDCH demodulation operation control unit 176 proceeds to step 718 to perform normal operation, and if the packet currently waiting for the mobile station is not a continuous packet ( Standby SP_ID = 0), the F-PDCH demodulation operation control unit 176 sends an ACK (Acknowledgement) signal to the base station and sets the F-PDCH Stop signal to "1" to stop further operation. The standby SP_ID is a value determined according to the SP_ID of the immediately received user packet and the CRC check result, and the F-PDCH demodulation operation control unit 176 uses the currently received SP_ID value and the standby SP_ID value actually waiting for the mobile station. It is determined whether the received packet is a normal packet. The standby SP_ID value may change according to the following four cases. First, if the SP_ID (ie, the received SP_ID) of the received user packet is '00' and the received F-PDCH is CRC good, the next SP_ID is set to '0' because a new user packet should come next. Second, if the SP_ID of the received user packet is '00' and the F-PDCH is not CRC good, then the retransmitted user packet should come and the standby SP_ID is set to '1'. Third, if the SP_ID of the received user packet is not '00' and the F-PDCH is CRC good, then a new user packet should come next, so the standby SP_ID is set to '0'. Fourth, if the SP_ID of the received user packet is not '00' and the F-PDCH is not CRC good, the standby SP_ID is set to '1' since the retransmitted user packet should come next.

8 is a diagram illustrating a mobile station apparatus according to an embodiment of the present invention for symbol buffering and symbol demapping of an F-PDCH. FIG. 8 is a diagram illustrating buffering a coded symbol after F-PDCH Walsh despreading described in FIG. Mobile station configuration for F-PDCH demodulation up to buffering) is shown. Referring to FIG. 8, the output of the Walsh m Finger i I and Q symbols of FIG. 5 is an F-PDCH Walsh 1 symbol. F-PDCH Walsh 1 Symbol Combiner 184, F-PDCH Walsh 2 Symbol Combiner 186,..., F-PDCH Walsh 28 Symbol Combiner 188, respectively. In this case, the operating symbol combiner is determined by the Walsh space currently being used, and combines only the output of the locked finger. The output of the F-PDCH Walsh 1 symbol combiner 184, the F-PDCH Walsh 2 symbol combiner 186, ..., the F-PDCH Walsh 28 symbol combiner 188 is a Walsh 1 symbol buffer. (Walsh 1 Symbol Buffer) (190), Walsh 2 symbol buffer (192), ..., Walsh 28 symbol buffer (194), each of the role is 1 to perform symbol demapping by Walsh code This is to buffer symbols as long as the slot length. The operating symbol buffer is determined by the Walsh space currently being used, and the slot boundary in each buffer is updated every 1.25 msec. Walsh space is needed to select only those symbols corresponding to the Walsh channel currently in use from the 28 Walsh despread outputs and a 1.25msec input signal is needed to distinguish the slot boundaries. The output of the Walsh 1 symbol buffer 190 is an F-PDCH 1 Subpacket QPSK Symbol Buffer 214 and an F-PDCH 1 Slot 8-PSK symbol demapping unit (F-PDCH). 1 Slot 8-PSK Symbol Demapping Block (210), F-PDCH 1 Slot 16 QAM Symbol Demapping Unit (F-PDCH 1 Slot 16 QAM Symbol Demapping Block) 212, which is input to the F-PDCH 1 Slot 8- The PSK symbol demapping unit 210 and the F-PDCH 1 slot 16 QAM symbol demapping unit 212 demap the Walsh code 1 symbol buffer outputs of 1 slot by a corresponding modulation scheme. Similarly, the Walsh 2 symbol buffer 192 outputs the F-PDCH 1 subpacket QPSK symbol buffer 214, the F-PDCH 1 slot 8-PSK symbol demapping unit 210, and the F-PDCH 1 slot 16 QAM symbol demapping. The F-PDCH 1 slot 8-PSK symbol demapping unit 210 and the F-PDCH 1 slot 16 QAM symbol demapping unit 212 input Walsh code 2 symbol buffer outputs by 1 slot. Demapping to the corresponding modulation method. In addition, the output of the Walsh 28 symbol buffer 194 is F-PDCH 1 subpacket QPSK symbol buffer 214, F-PDCH 1 slot 8-PSK symbol demapping unit 210, F-PDCH 1 slot 16 QAM symbol The F-PDCH 1 slot 8-PSK symbol demapping unit 210 and the F-PDCH 1 slot 16 QAM symbol demapping unit 212 are inputted to the de-mapping unit 212. It demaps the outputs to the corresponding modulation scheme. The outputs of the F-PDCH Walsh 1 symbol combiner 184, the F-PDCH Walsh 2 symbol combiner 186,..., F-PDCH Walsh 28 symbol combiner 188 are also referred to as F-PDCH. F-PDCH Walsh 1 Symbol Absolute Value (196), F-PDCH Walsh 2 Symbol Absolute Value (198), ..., F-PDCH Walsh 28 Symbol Absolute Value After the absolute value is calculated in the calculation unit 200, the F-PDCH Walsh 1 ABS Symbol Buffer 202, the F-PDCH Walsh 2 Absolute Symbol Buffer 204,... ..., F-PDCH Walsh 28 is input to the absolute value symbol buffer 206. The F-PDCH Walsh n symbol absolute value calculation units calculate the absolute value of the symbols output from the symbol combiner for each Walsh channel. Is used to calculate The outputs of the F-PDCH Walsh 1 absolute value symbol buffer 202, the F-PDCH Walsh 2 absolute value symbol buffer 204, ..., the F-PDCH Walsh 28 absolute value symbol buffer 206 are received. If the modulation scheme of the received packet is 8-PSK or 16 QAM, the symbol de-signaling of the F-PDCH 1 slot 8-PSK symbol demapping unit 210 and the F-PDCH 1 slot 16 QAM symbol demapping unit 212 is performed. Obtain the demapping reference level of the 16 QAM signal from the F-PDCH 1 Slot 16 QAM Symbol Demapping Reference Level Calculation Block (208). Used for. Blind demapping requires a reference level that separates the decision region of each symbol. The reference level is easily determined by knowing the gain of the transmitter (G1) and the gain (G2) that occurs through the channel and the receiver. Can be done. Here, the transmitter gain G1 is a value that is determined such that the average power of each transmission symbol is normalized to 1, and the gain G2 generated at the channel and the receiver is obtained by adding an absolute value of the received symbols for one slot and averaging the appropriate value ( Scaling to Constant gives an approximate value. The F-PDCH 1 Slot 16 QAM Symbol Demapping Reference Level Calculation Block 208 multiplies the transmitter gain (G1) and the gain of the channel and the receiver (G2) by one slot symbol. Obtain the reference level required for demapping. The output of the F-PDCH 1 slot 16 QAM symbol demapping reference level calculator 208 is input to the F-PDCH 1 slot 16 QAM symbol demapping unit 212 and used as a symbol demapping reference level. Slot boundaries in the F-PDCH Walsh 1 absolute value symbol buffer 202, F-PDCH Walsh 2 absolute value symbol buffer 204, ..., F-PDCH Walsh 28 absolute value symbol buffer 206 Is updated every 1.25msec, and the operating absolute value symbol buffer is determined by Walsh space. The output of the F-PDCH 1 subpacket QPSK symbol buffer 214 outputs a QPSK coded symbol output, and the output of the F-PDCH 1 slot 8-PSK symbol demapping unit 210 is an F-PDCH. 1 subpacket 8-PSK symbol buffer 216, the output of the F-PDCH 1 slot 16 QAM symbol demapping unit 212 is F-PDCH 1 subpacket 16 QAM symbol buffer (F-PDCH 1 Subpacket 16 QAM Symbol Buffer (218). When the reception of one subpacket is completed, the F-PDCH 1 subpacket 8-PSK symbol buffer 216 outputs an 8-PSK coded symbol on the assumption that the modulation scheme of the received packet is 8-PSK. When the reception of one subpacket is completed, the subpacket 16 QAM symbol buffer 218 outputs 16 QAM coded symbols on the assumption that the modulation scheme of the received packet is 16 QAM. The reason for the above is that the modulation scheme of the packet transmitted on the F-PDCH is not known until the demodulation of the F-PDCCH is completed. Thus, in order to reduce the time required for symbol demapping in the state of not knowing the modulation scheme, This is because when the F-PDCCH demodulation is completed after all symbol demapping is performed for each modulation scheme, an appropriate symbol demapping output is selected and passed to the rear stage.

FIG. 9 is a diagram illustrating a mobile station apparatus according to an embodiment of the present invention for performing long code descrambling, QCTC combining, deinterleaving, and decoding of an F-PDCH. FIG. A configuration of a mobile station for F-PDCH demodulation from output of F-PDCH coded symbols for each scheme until finally turbo decoding is shown. Referring to FIG. 9, each of the QPSK coded symbol output, 8-PSK coded symbol output, and 16 QAM coded symbol output of FIG. 7 is an F-PDCH subpacket coded symbol output selector (F-PDCH Subpacket Coded). The fourth input of the F-PDCH subpacket coded symbol output selector 220 is actually input after the F-PDCH subpacket coded symbol output selector 220. Stop processing and indicate no further operation. One of four inputs of the F-PDCH subpacket coded symbol output selector 220 is selected by a symbol output selection and processing control block 224, and the F-PDCH Stop signal is " 1 " "", The fourth input of the F-PDCH subpacket coded symbol output selector 220, a processing stop and no operation signal, is selected. If the F-PDCH stop signal is not "1", Walsh is selected. Coded symbols of one subpacket are selected from a corresponding coded symbol buffer by using space, EP Size, and slot length information. The output of the F-PDCH subpacket coded symbol output selector 220 is input to a symbol buffer mux (226), and the F-PDCH subpacket 8-PSK and 16 QAM symbol buffer rearrangement unit (F). PDCH Subpacket 8-PSK, 16 QAM Symbol Buffer Reordering Block (222). The F-PDCH subpacket 8-PSK, 16 QAM symbol buffer relocator 222 performs symbol relocation to restore original coded symbols that have been shuffled at the transmitting end. This is because the transmitter sends mixed symbols at the time of symbol mapping in order to increase the reliability of the (systematic) bits. The output of the F-PDCH subpacket 8-PSK, 16 QAM symbol buffer relocator 222 outputs and muxes the output of the F-PDCH subpacket coded symbol output selector 220 in the symbol buffer MUX 226. The output of the symbol buffer MUX 226 is controlled by the SP_ID value. That is, when SP_ID = 0, the output of the F-PDCH subpacket 8-PSK and 16 QAM symbol buffer relocator 222 is selected, and when the SP_ID ≠ 0 or the modulation scheme is QPSK, the F-PDCH subpacket The output of the coded symbol output selector 220 is selected. The output of the symbol buffer MUX 226 is outputted to the descrambling output after the long code descrambling is performed in the long code descrambling block 228. At this time, the long code input to the long code descrambling unit 228 is generated as follows. That is, the long code generated by the long code generator 234 is buffered in the long code buffer 232 and the output of the long code buffer 232 is 32 chip long code decimation and hold unit 32. Chip Long Code Decimation & Hold Block) 230 is decimated and input as a long code used in the long code descrambling unit 228. This is because the long code descrambling is performed on the buffered F-PDCH coded symbol, so the decoded long code must also be buffered to match the F-PDCH symbol and descrambling timing. The output of the long code descrambling 228 is F-PDCH Subpacket 1 QCTC Buffer 236, F-PDCH Subpacket 2 QCTC Buffer 238 for QCTC combining according to ARQ_ID. One of the F-PDCH subpacket 3 QCTC buffer 240 and the F-PDCH subpacket 4 QCTC buffer 242 is input. One of the F-PDCH subpacket 1 QCTC buffer 236 and the F-PDCH subpacket 4 QCTC buffer 242 is selected according to ARQ_ID, and the selected F-PDCH subpacket n QCTC buffer has EP size, SP_ID, slot length ( IR / Chase Combining and QCTC Buffer Position Control are performed using information such as slot length. ARQ_ID is used for IR / Chase combining by distinguishing each packet independently when one user performs parallel transmission when channel resources are sufficient. That is, when ARQ_ID = 0, the F-PDCH subpacket 1 QCTC buffer is used. When ARQ_ID = 1, the F-PDCH subpacket 2 QCTC buffer is used. When ARQ_ID = 2, the F-PDCH subpacket 3 QCTC is used. If the buffer is used and ARQ_ID = 3, the F-PDCH subpacket 4 QCTC buffer is used. In this case, the F-PDCH subpacket n QCTC buffer is a block that IR / Chase-codes the encoded symbols in order to recover the packet error by retransmitting when an error occurs during F-PDCH packet transmission. Each F-PDCH IR / Chase combination has a different buffer size according to the payload size, and the retransmitted packet is indicated by the SP_ID. The output of the F-PDCH subpacket n QCTC buffer selected by ARQ_ID from the F-PDCH subpacket 1 QCTC buffer 236 to the F-PDCH subpacket 4 QCTC buffer 242 is an F-PDCH subpacket separator (F−). PDCH Subpacket Separationinto 3 Segment) 244 is divided into one systematic bit segment and two non-systematic bit segments. The deinterleaver (Deint) 1 246 performs deinterleaving on the regular bits and then inputs the output to the F-PDCH deinterleaver MUX 250. Non-Systematic Bit Segment 1 Symbols are alternately demuxed at P0 DEMUX 248 and deinterleaver 2 252 and deinterleaver 3 254 are demuxed irregular bit parts. Deinterleaving is performed on symbols corresponding to 1 (Non-Systematic Bit Segment 1). In addition, the non-systematic bit segment 2 symbols are alternately demuxed in the P1 DEMUX 250, and the deinterleaver 4 256 and the deinterleaver 5 258 are demuxed irregular bit portion 2 symbols. Each of the symbols corresponding to (Non-Systematic Bit Segment 2) is deinterleaved. The outputs of the deinterleaver 1 246 to the deinterleaver 5 258 are multiplexed in the F-PDCH deinterleaver MUX 260 and then the F-PDCH 1/5 turbo decoder F-PDCH 1/5 Turbo Decoder) 262 is inputted and decoded. The F-PDCH 1/5 turbo decoder 262 outputs an ACK / NACK signal according to the decoding result, and this output is input to the F-PDCH QCTC Buffer Control 264 to provide four signals. A control signal for clearing / holding the F-PDCH subpacket n QCTC buffers 236, 238, 240, and 242 corresponding to ARQ_ID is generated in the QCTC buffer. That is, when the decoding result of the F-PDCH 1/5 turbo decoder 262 is good, the F-PDCH subpacket n QCTC buffer having the ARQ_ID of the currently decoded packet is sent by sending an ACK signal to clear the next new one. When the decoding result is bad, the packet can be received and a NACK signal is sent to hold the F-PDCH subpacket n QCTC buffer having the ARQ_ID of the currently decoded packet to hold the next retransmitted packet. This allows the F-PDCH IR / Chase binding to continue. At this time, the control signal generated by the F-PDCH QCTC buffer control unit 264 is valid only for the F-PDCH subpacket n QCTC buffer corresponding to the ARQ_ID of the currently decoded packet.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention proposes a mobile station receiver structure using a retransmission and variable modulation scheme in a high speed packet data transmission system. When the proposed mobile station receiver structure is used, high speed wireless packet data can be efficiently received. In addition, the parallel transmission receiver structure proposed by the present invention can increase the throughput in a packet communication system by maximizing the use of system resources in a good channel condition.

Claims (22)

A packet data control channel including information for identifying a user, retransmission channel classification information, encoded packet size, and packet classification information in retransmission, wherein the information is transmitted in any one packet transmission unit among predetermined packet transmission units, and a packet to be transmitted In a mobile communication system for providing one or more Walsh codes to data and having a packet data channel for transmitting the packet data in parallel when two or more Walsh codes are provided, and transmitting the information together in the packet data control channel and the packet data channel. A mobile station apparatus for demodulating the packet data control channel and the packet data channel, A packet data control channel information division control unit for dividing and outputting the information strings received through the packet data control channel into the respective packet transmission units; A packet data control channel demodulator for demodulating and outputting the packet data control channel information strings divided by the packet transmission units; And a packet data channel demodulation control unit for controlling demodulation of the packet data channel according to the information including the user classification information and the retransmission channel classification information based on the output of the packet data control channel demodulation unit. Device. The method of claim 1, And buffers for temporarily storing the packet data information strings received on the packet data channel until the packet data control channel is completely demodulated. 3. The demodulation operation of claim 2, wherein the packet data channel demodulation control unit stops a demodulation operation of the packet data channel when a packet having a cyclic redundancy check (CRC) good is not present in the demodulation result of the packet data control channel information. And outputting a signal for causing the signal to be generated. The packet data channel demodulation control unit according to claim 3, wherein the packet data channel demodulation control unit has a CRC good-in-one packet present in the demodulation result of the packet data control channel information, and the packet data channel information sequence is a message indicating information on the packet data channel. And outputting a signal for stopping a demodulation operation of the packet data channel when the information identifying the user included in the information on the data channel does not indicate the mobile station itself. 5. The method of claim 4, wherein the packet data channel demodulation control unit retransmits the information included in the packet data channel when the information identifying the user included in the information on the packet data channel indicates the mobile station itself. And checking the value of channel discrimination information. 6. The method of claim 5, wherein the packet data channel demodulation control unit checks whether the packet waiting for the mobile station is a new packet when the value of the retransmission channel classification information indicates that a new packet is being transmitted. Device. The method of claim 6, wherein the packet data channel demodulation control unit outputs a signal for performing a normal data channel demodulation operation when the packet waiting for the mobile station is a new packet, and the packet waiting for the mobile station is not a new packet. And outputting a signal for clearing a corresponding buffer among the buffers and performing a normal data channel demodulation operation. 6. The method of claim 5, wherein the packet data channel demodulation control unit checks whether the packet waiting for the mobile station is a continuous packet when the value of the retransmission channel classification information indicates that a continuous packet is being transmitted. Said device. 10. The method of claim 8, wherein the packet data channel demodulation control unit outputs a signal for performing a normal data channel demodulation operation when the packet waiting for the mobile station is a continuous packet, and the packet waiting for the mobile station is a continuous packet. And if not, outputting a signal for stopping a demodulation operation of the packet data channel. The apparatus as claimed in claim 1, further comprising a demodulator for demodulating information strings of the packet data channel under control of the packet data channel demodulation control unit. The apparatus as claimed in claim 1, further comprising demodulators for demodulating the information strings transmitted in parallel when the information strings of the packet data channel are transmitted in parallel. A packet data control channel including information for identifying a user, retransmission channel classification information, encoded packet size, and packet classification information in retransmission, wherein the information is transmitted in any one packet transmission unit among predetermined packet transmission units, and a packet to be transmitted In a mobile communication system for providing one or more Walsh codes to data and having a packet data channel for transmitting the packet data in parallel when two or more Walsh codes are provided, and transmitting the information together in the packet data control channel and the packet data channel. A method for demodulating the packet data control channel and the packet data channel in a mobile station, Dividing and outputting information strings received through the packet data control channel into respective packet transmission units; Demodulating and outputting the packet data control channel information strings divided by the packet transmission units; And controlling demodulation of a packet data information string received through the packet data channel according to a demodulation result of the packet data control channel information including information for identifying the user and retransmission channel classification information. The method as claimed in claim 12, further comprising: temporarily storing, in buffers, packet data information strings received in the packet data channel until the packet data control channel is completely demodulated. 15. The method of claim 13, further comprising outputting a signal for stopping a demodulation operation of the packet data channel when a CRC good-in packet does not exist in the demodulation result of the packet data control channel information. Way. 15. The method of claim 14, wherein a CRC good in packet is present in the demodulation result of the packet data control channel information, wherein the packet data channel information sequence is a message indicating information on the packet data channel and is included in the information on the packet data channel. And if the information identifying the user does not indicate the mobile station itself, outputting a signal for stopping a demodulation operation of the packet data channel. 16. The method of claim 15, wherein when the information identifying the user included in the information on the packet data channel indicates the mobile station itself, the value of the retransmission channel classification information included in the information on the packet data channel is checked. And further comprising a process. The method as claimed in claim 16, further comprising the step of checking whether the packet waiting for the mobile station is a new packet when the value of the retransmission channel classification information indicates that a new packet is being transmitted. 18. The method of claim 17, wherein the mobile station outputs a signal for performing a normal data channel demodulation operation when a packet waiting for the mobile station is a new packet, and a corresponding buffer among the buffers when the packet waiting for the mobile station is not a new packet. And outputting a signal for clearing the signal and performing a normal data channel demodulation operation. The method as claimed in claim 16, further comprising the step of checking whether the packet waiting for the mobile station is a continuous packet when the value of the retransmission channel classification information indicates that a continuous packet is being transmitted. . 20. The method of claim 19, further comprising: outputting a signal for performing a normal data channel demodulation operation when the packet waiting for the mobile station is a continuous packet; and if the packet waiting for the mobile station is not a continuous packet, And outputting a signal for stopping the demodulation operation. The method as claimed in claim 12, further comprising demodulating information strings of the packet data channel under control of the packet data channel demodulation control unit. The method of claim 12, further comprising demodulating the information strings transmitted in parallel when the information strings of the packet data channel are transmitted in parallel.