WO2009139442A1 - 通信装置、通信システム、受信方法及び通信方法 - Google Patents
通信装置、通信システム、受信方法及び通信方法 Download PDFInfo
- Publication number
- WO2009139442A1 WO2009139442A1 PCT/JP2009/058997 JP2009058997W WO2009139442A1 WO 2009139442 A1 WO2009139442 A1 WO 2009139442A1 JP 2009058997 W JP2009058997 W JP 2009058997W WO 2009139442 A1 WO2009139442 A1 WO 2009139442A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- signal
- unit
- retransmission
- initial transmission
- packet
- Prior art date
Links
Images
Classifications
-
- 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
- H04L1/1812—Hybrid protocols; Hybrid automatic repeat request [HARQ]
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J11/00—Orthogonal multiplex systems, e.g. using WALSH codes
- H04J11/0023—Interference mitigation or co-ordination
-
- 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
-
- 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
Definitions
- the present invention relates to a communication device, a communication system, a reception method and a communication method, and more particularly to a communication device, a communication system, a reception method and a communication method to which automatic retransmission control is applied.
- hybrid automatic retransmission HARQ ARQ: Automatic Repeat reQuest (ARQ) described in Non-Patent Document 1 and Non-Patent Document 2
- error correction coding such as turbo coding
- HARQ is a technique in which when a receiver detects an error in a received signal, it requests retransmission to the transmitter, and performs a decoding process on a combined signal of the signal received again and the signal already received.
- an incremental redundancy IR (Incremental Redundancy), which is one of the hybrid automatic retransmission HARQ, divides redundant bits and retransmits them little by little, so that the coding rate can be lowered as the number of retransmissions increases, and error correction is performed. I can strengthen my ability.
- MC-CDM Multi Carrier Coded Multiplexing: Code Division Multiplexing
- OFDM Orthogonal Frequency Division Multiplexing
- CDM Code Division Multiplexing
- methods such as multi-carrier code division multiplexing
- Spread-OFDM Orthogonal Frequency and Division Multiplexing
- the successive interference canceller SIC disclosed in Non-Patent Document 3 and Non-Patent Document 4 includes the received signal power of each code channel or the received signal power versus interference power and noise among the code-multiplexed received signals.
- the signal is detected by despreading, demodulating, and decoding in order from the channel signal with the largest power ratio (SINR: Signal to Interference plus Noise power Ratio, hereafter referred to as “SINR”) to obtain a determination signal of an information symbol.
- SINR Signal to Interference plus Noise power Ratio
- an interference signal replica (undesired signal) created using the determination result is subtracted from the received signal.
- the present invention has been made in view of such circumstances, and an object of the present invention is to provide a communication device, a communication system, a reception method, and a communication method that prevent repetition of retransmission and increase in delay.
- a communication device is a communication device that performs hybrid automatic retransmission that requests retransmission to a transmission source when an error is detected in a received signal, and includes a signal including an initial transmission signal and a retransmission signal for any one of the signals.
- a reception unit that receives a signal in which the initial transmission signal and the retransmission signal are multiplexed, and an initial transmission signal or a retransmission signal of the initial transmission signal and the retransmission signal included in the signal received by the reception unit.
- a detection order determining unit that determines the order in which the initial transmission signal and the retransmission signal are detected from the signal received by the receiving unit, and the order determined by the detection order determining unit
- a signal detection unit that detects an initial transmission signal and the retransmission signal by removing an interference component from a signal received by the reception unit using a signal detected by the apparatus.
- the communication apparatus of this invention is the above-mentioned communication apparatus, Comprising:
- the said detection order determination part determines the order detected so that the order of the said initial transmission signal may come before the said retransmission signal. It is characterized by.
- the communication apparatus of this invention is the above-mentioned communication apparatus, Comprising:
- the said detection order determination part uses a reception level further, when determining the order detected.
- the communication apparatus of the present invention is the communication apparatus described above, wherein the initial transmission signal and the retransmission signal are signals that have been subjected to error correction coding at a transmission source, and the signal detection unit includes: When detecting a signal, a signal in which the signal detected by the device is subjected to error correction decoding processing using the error correction code is used to generate a replica signal of an interference component for the signal to be detected and received by the receiving unit The replica signal is removed from the signal.
- the communication device of the present invention is the communication device described above, wherein the signal detection unit uses all signals detected by the signal detection unit when detecting the signal, An interference component is removed from the signal received by the receiving unit.
- the communication apparatus is the communication apparatus described above, wherein the signal detection unit detects the retransmission signal from the initial transmission among the signals detected by the signal detection unit. An interference component is removed from the signal received by the receiving unit using a signal.
- the communication apparatus of the present invention is the communication apparatus described above, and the signal received by the receiving unit is a code obtained by multiplying the initial transmission signal and the retransmission signal by a unique spreading code, respectively.
- the signal detection unit removes the interference component from the signal received by the reception unit, and then multiplies the signal from which the interference component has been removed by the spreading code specific to the signal to be detected. Then, the detection target signal is detected.
- the communication apparatus of the present invention is the communication apparatus described above, and the signal received by the reception unit is spatially multiplexed by transmitting the initial transmission signal and the retransmission signal from different antennas.
- the signal detection unit removes the interference component from the signal received by the reception unit and then sets the detection target from the signal from which the interference component has been removed based on the propagation path estimation value for each antenna. A signal is detected.
- the communication apparatus of the present invention is the communication apparatus described above, wherein the signal detection unit detects the initial transmission signal and the retransmission signal according to the order determined by the detection order determination unit. It is characterized in that it is performed once for each signal.
- the communication apparatus of the present invention is the communication apparatus described above, wherein the signal detection unit detects the initial transmission signal and the retransmission signal according to the order determined by the detection order determination unit. Repeated multiple times.
- the communication device of the present invention is the communication device described above, wherein the signal detection unit outputs a soft decision value of the detected signal and stores the soft decision value output by the signal detection unit.
- a synthesis unit that synthesizes the soft decision value of the retransmission signal of the initial transmission signal.
- the communication apparatus of the present invention is the communication apparatus described above, wherein the soft decision value output by the signal detection unit is a demodulation result.
- the communication device of the present invention is the communication device described above, wherein the soft decision value output by the signal detection unit is a decoding result.
- the communication device of the present invention is the communication device described above, wherein the information that can determine whether the signal is the initial transmission signal or the retransmission signal is information indicating the number of retransmissions.
- the communication device of the present invention is the communication device described above, wherein the reception unit receives a reception signal including a retransmission control signal, and information that can determine whether the signal is the initial transmission signal or the retransmission signal is It is described in the retransmission control signal.
- the communication system of the present invention includes a first communication device and a second communication device, and when an error is detected in a signal received from the first communication device, the second communication device.
- the second communication device is a signal including an initial transmission signal and a retransmission signal for any one of the signals,
- a receiving unit that receives a signal in which a transmission signal and the retransmission signal are multiplexed, and whether the initial transmission signal and the retransmission signal are included in the signal received by the reception unit can be determined.
- the detection order determining unit that determines the order in which the initial transmission signal and the retransmission signal are detected, and according to the order determined by the detection order determining unit, by the device Using the detected signal, Removing the interference component from the signal whose serial receiving unit receives, characterized by comprising a said signal detector for detecting the initial transmission signal and the retransmission signal.
- the communication system of the present invention is the communication system described above, wherein the initial transmission signal and the retransmission signal are information signals that have been subjected to error correction coding, and the signal detection unit includes the signal A signal that has been detected by the apparatus is subjected to error correction decoding processing using the error correction code, and a replica signal of an interference component for the signal to be detected is generated, and the signal received by the receiving unit The replica signal is removed from the signal.
- the communication apparatus in the reception method in the communication apparatus that performs hybrid automatic retransmission that requests retransmission to the transmission source when an error is detected in the received signal, is any of the initial transmission signal and the A first process of receiving a signal in which the initial transmission signal and the retransmission signal are multiplexed, and the communication apparatus has received in the first process.
- the initial transmission signal and the retransmission signal are obtained from the signal received in the first process according to information capable of determining whether the initial transmission signal and the retransmission signal of the initial transmission signal and the retransmission signal included in the signal.
- Interference components from the filtered signal Te it characterized in that it comprises a third step of the detecting initial transmission signal and the retransmission signal.
- the communication method of the present invention includes a first communication device and a second communication device.
- the second communication device When an error is detected in a signal received from the first communication device, the second communication device.
- the first communication device transmits a first transmission signal and a retransmission signal for one of the signals.
- the second communication device receives a signal transmitted in the first process and in which the initial transmission signal and the retransmission signal are multiplexed, and The second communication apparatus determines whether the second transmission apparatus includes the first transmission signal and the retransmission signal included in the signal received in the second process, and determines whether the second transmission apparatus is an initial transmission signal or a retransmission signal. From the signal received in the process, the initial transmission signal and the retransmission In accordance with the third process for determining the order of detecting the number and the order determined by the second communication apparatus in the third process, using the signal detected by the second communication apparatus, A fourth step of detecting the initial transmission signal and the retransmission signal by removing an interference component from the signal received in the second step.
- the detection order determining unit determines the order of detecting signals that interfere with each other according to the number of retransmissions, and the signal detecting unit uses the detected signal in accordance with the order to receive the receiving unit. Removes the interference component from the received signal and detects the initial transmission signal and the retransmission signal. For this reason, the earlier the order of detection, the smaller the number of retransmissions, the faster the signal detection is performed for a retransmission signal with a large number of retransmissions, so that signal detection is performed on a signal from which more interference components have been removed. Signal detection can be performed with high accuracy. Therefore, it is possible to prevent the number of retransmissions of a specific signal from increasing and delay from increasing.
- FIG. 3 is a schematic block diagram showing a configuration of a code channel replica generation unit 605-1 in the same embodiment. It is a flowchart explaining operation
- FIG. 3 is a schematic block diagram showing a configuration of a symbol replica generation unit 1204-1 according to the same embodiment. It is a flowchart explaining the reception operation
- the packet transmission device 100 transmits a signal obtained by code-multiplexing an initial transmission packet and a retransmission packet related to any initial transmission packet before the initial transmission packet, and a successive interference canceller (SIC) using repetitive processing.
- the packet receiving device 200 having a Successive Interference Cellnel receives the signal transmitted by the packet transmitting device 100 and gives priority to the signal of the initial transmission packet among the code-multiplexed signals.
- the retransmission packet is a packet that is retransmitted with respect to the same data as the data transmitted in the initial transmission packet.
- the interference signal is an interference signal due to inter-code interference, and means another signal that is code-multiplexed. That is, for example, if signals P 1 and P 2 are code-multiplexed, is a signal P 2 is an interference signal to the signal P 1, the signal P 1 is an interference signal for the signal P 2, i.e. the signal P 1 It has a signal interfering with each other by being encoded multiplexed signal P 2 and. Signal detection is to obtain an information bit for propagation path distortion correction, despreading, and demodulation after reproducing an interference signal for the signal to be detected and performing interference cancellation processing for removing the reproduced signal (replica) from the received signal.
- FIG. 1 is a schematic block diagram showing a configuration of a packet transmission device 100 according to an embodiment of the present invention.
- the packet transmission device 100 is included in a downlink base station device and an uplink mobile station in a mobile radio communication system.
- the relay station apparatus is provided in the downlink between the relay station and the mobile station.
- the packet transmission apparatus 100 includes code channel signal generation units 101-1 to 101-N (N is the number of code multiplexing), a code multiplexing unit 102, an IFFT unit 103, a multiplexing unit 104, a GI insertion unit 105, a transmission unit 106, a pilot signal.
- a generation unit 107, a retransmission control signal generation unit 108, a restoration unit 109, and an antenna unit 120 are included.
- the code channel signal generation units 101-1 to 101-N generate a signal to be code-multiplexed from the information bit sequence constituting the input packet of each code channel, and an encoding unit 111, an interleaving unit 112, and a modulation unit 113
- the diffusion unit 114 is included.
- FIG. 2 is a schematic block diagram showing the configuration of the encoding unit 111.
- the encoding unit 111 has a function of adding redundant bits to the information bit sequence constituting the input packet so that the packet receiving apparatus 200 can detect and correct errors, and the error detecting encoding unit 121, A correction encoding unit 122, an encoded bit storage unit 123, and a puncturing unit 124 are provided.
- the error detection encoding unit 121 performs error detection encoding such as CRC (Cyclic Redundancy Check) so that the packet receiving apparatus 200 that receives the packet can detect whether or not there is an error.
- CRC Cyclic Redundancy Check
- the error correction coding unit 122 performs error correction coding such as a turbo code, a convolutional code, and an LDPC (Low Density Parity Check) code on the output bit sequence from the error detection coding unit 121.
- error correction coding such as a turbo code, a convolutional code, and an LDPC (Low Density Parity Check) code on the output bit sequence from the error detection coding unit 121.
- all bits constituting the packet are transmitted on the same code channel, and the error detection encoding unit 121 and the error correction encoding unit 122 perform processing for each packet.
- the error correction encoding unit 122 includes inner encoders 3001 and 3002 and an inner interleaving unit 3003. When the error detection encoded information bit sequence from the error detection encoding unit 121 is input, error correction encoding is performed.
- the unit 122 outputs three types of information bit sequences of systematic bits x, parity bits z, and parity bits z ′.
- the systematic bit x is the bit sequence itself input from the error detection encoding unit 121.
- the parity bit z is an output result of the internal encoder 3001 encoding the bit sequence from the error detection encoding unit 121.
- the parity bit z ′ is an output result obtained by first interleaving the bit sequence from the error detection coding unit 121 by the internal interleaving unit 3003 and coding the result of the interleaving process by the internal encoder 3002. .
- the inner encoder 3001 and the inner encoder 3002 may be the same encoder that performs the encoding of the same encoding method, or may be different encoders.
- a recursive convolutional encoder is used for both the inner encoder 3001 and the inner encoder 3002.
- the error correction encoding unit 122 will be described using a turbo code with the configuration shown in FIG.
- the coded bit storage unit 123 stores the coded bit sequence generated by the error correction coding unit 122. In addition, when a retransmission packet is generated, the stored encoded bit sequence is output to puncturing section 124.
- the puncturing unit 124 performs error correction coding according to the puncture pattern determined based on the response signal (acknowledgment ACK / non-acknowledgment NACK) of the packet reception device 200 received by the restoration unit 109 or the number of packet retransmissions calculated from the response signal.
- the encoded bit sequence output from the unit 122 or the encoded bit sequence output from the encoded bit storage unit 123 is punctured.
- the puncturing unit 124 when generating the initial transmission packet (when receiving a reception notification ACK as a response signal to the previous packet), the puncturing unit 124 applies the new encoded bit sequence output from the error correction encoding unit 122.
- the puncture process is performed and a retransmission packet is generated (when a non-acknowledgment notification NACK is received as a response signal)
- the puncture process is performed on the encoded bit sequence stored in the encoded bit storage unit 123.
- the puncturing unit 124 may perform rate matching such as bit padding (bit insertion) or bit repetition (bit repetition) in addition to the puncturing process.
- the puncture unit 124 is “1” in the puncture pattern shown in FIG. 4 or 5 among x, z, and z ′ output from the error correction coding unit 122 or the coded bit storage unit 123. Output the bit at the bit position.
- FIG. 5 shows a puncture pattern in which systematic bits are transmitted using only the initial transmission packet.
- FIG. 5 shows transmission of systematic bits in both the initial transmission packet and the retransmission packet.
- the interleave unit 112 rearranges the bit arrangement of the encoded bit sequence that is the output from the encoding unit 111.
- the modulation unit 113 performs data modulation such as QPSK (Quadrature Phase Shift Keying: 4-level phase shift keying), 16QAM (16 Quadrature Amplitude Modulation: 16-level quadrature amplitude modulation) on the output from the interleave unit 112, and performs modulation. Generate a symbol.
- Spreading section 114 multiplies the modulation symbol generated by modulation section 113 by a spreading code sequence corresponding to each of code channel signal generation sections 101-1 to 101-N.
- the code channel signal generation units 101-1 to 101-N have the above-described functions, and in accordance with the retransmission request from the packet receiving apparatus 200, the code channel signal composed of the initial transmission packet or the retransmission packet. Generate.
- the code multiplexer 102 code-multiplexes the output signals from the code channel signal generators 101-1 to 101-N.
- the IFFT unit 103 performs frequency-time conversion on the signal code-multiplexed by the code multiplexing unit 102 by inverse fast Fourier transform IFFT (Inverse Fast Fourier Transform) or the like to generate a time-domain signal.
- IFFT Inverse Fast Fourier Transform
- N indicates the number of multiplexed codes in the code multiplexing unit 102
- SF indicates the spreading factor of the spreading code multiplied by the spreading unit 114.
- d u indicates a modulation symbol data-modulated by the modulation unit 113.
- K 0, 1, 2,... N sub ⁇ 1 of the k-th subcarrier.
- N sub represents the total number of subcarriers.
- Multiplexing section 104 multiplexes the time domain signal output from IFFT section 103, the retransmission control signal output from retransmission control signal generation section 108, and the pilot signal output from pilot signal generation section 107.
- the multiplexing method in the multiplexing unit 104 may be any of time multiplexing, frequency multiplexing, code multiplexing, and the like.
- Pilot signal generation section 107 generates a pilot signal used for propagation path estimation.
- the retransmission control signal generation unit 108 generates a signal (retransmission control signal) for notifying the packet reception device 200 of how many retransmissions the packet signal transmitted on each code channel is.
- retransmission control signal generation section 108 may generate a retransmission control signal including transmission parameters such as a data modulation scheme, spreading factor, code multiplexing number, and puncture pattern.
- the GI insertion unit 105 inserts a guard interval GI (Guard Interval) into the signal output from the multiplexing unit 104 and inputs the signal to the transmission unit 106.
- the transmission unit 106 converts the output signal from the GI insertion unit 105 into an analog signal (Digital / Analogue conversion), performs a filtering process for band limitation, further converts to a transmittable frequency band, and outputs the signal. .
- the antenna unit 120 transmits the output signal of the transmission unit 106 to the packet reception device 200. Alternatively, a signal including a response signal transmitted from the packet reception device 200 is received.
- the restoration unit 109 converts the signal from the packet reception device 200 received from the antenna unit 120 into a frequency band that can be restored, filtering processing that performs band limitation, and converts an analog signal into a digital signal (A / D conversion). Further, received signal restoration processing such as data demodulation and error correction decoding is performed on the digital signal, and a response signal included in the signal from the packet receiving apparatus 200 is extracted. The restoration unit 109 outputs the extracted response signal to the retransmission control signal generation unit 108 and the encoding unit 111.
- the restoration unit 109 has a function capable of restoring received signal processing based on the transmission method of the received signal.
- the response signal is a signal that confirms transmission and includes information on whether or not to request retransmission.
- reception side For example, if there is a reception notification ACK (ACKnowledge) / non-acknowledgement notification NACK (Negative ACKnowledge) signal, and the reception side cannot correctly receive a packet transmitted from the transmission side, the reception side will not accept the transmission side. If the notification NACK signal is sent back and the signal is successfully received, the receiving side sends back a reception notification ACK signal. Further, when the response signal cannot be received within a certain predetermined time, the receiving side may determine that the signal has not been received correctly.
- ACK reception notification ACK
- NACK Negative ACKnowledge
- FIG. 6 is a schematic block diagram showing the configuration of the packet reception device 200 according to the present embodiment.
- the packet reception device 200 is included in a mobile station device in the downlink and a base station device in the uplink by the mobile radio communication system. Further, it is provided in a relay station apparatus in the downlink between the base station and the relay station.
- the packet reception device 200 includes an antenna unit 201, a reception unit 202, a propagation path estimation unit 203, a GI removal unit 204, an FFT unit 205, a reception packet management unit 206, a detection order determination unit 207, an interference cancellation unit 208, and a reception signal storage unit. 209, a synthesis unit 210, a decoding unit 211, and a response signal generation unit 212.
- the receiving unit 202 converts the signal from the packet transmission device 100 received from the antenna unit 201 into a signal-processable frequency band such as a signal detection process and a filtering process that limits the band, and then converts the signal from an analog signal to a digital signal. (Analogue / Digital conversion).
- the propagation path estimation unit 203 estimates a propagation path (impulse response, transfer function, etc.) through which the reception signal has passed, using a pilot signal included in the reception signal converted into a digital signal by the reception unit 202. Instead of the pilot signal, other signals that can estimate the propagation path, such as a control channel and a preamble, may be used.
- the reception packet management unit 206 determines whether each code channel signal is an initial transmission packet signal or a retransmission packet signal based on the retransmission control signal included in the reception signal converted into a digital signal by the reception unit 202 (in detail, what Information that can be determined), that is, information indicating the number of retransmissions. Based on the information indicating the number of retransmissions, the detection order determination unit 207 determines the order of the code channels from which signals are detected by the interference cancellation unit 208 and notifies the interference cancellation unit 208 of the order. Details of the order determination by the detection order determination unit 207 will be described later.
- the GI removal unit 204 removes a guard interval GI (Guard Interval) from the data signal included in the reception signal converted by the reception unit 202 into a digital signal.
- the FFT unit 205 converts the output signal of the GI removing unit 204 into a frequency domain signal by performing a fast Fourier transform FFT process.
- the interference cancellation unit (signal detection unit) 208 is a signal output from the fast Fourier transform FFT while referring to the propagation path estimation value output from the propagation path estimation unit 203 based on the detection order determined by the detection order determination unit 207.
- the information bit sequence is detected from the encoded bit LLR (also referred to as a soft decision value) and an error detection result. Details of the operation of the interference canceling unit will be described later.
- the interference cancellation unit 208 of the packet reception apparatus 200 uses the detected signals in the order determined by the detection order determination unit 207 based on the information indicating the number of retransmissions, and uses the detected signals to generate interference components.
- the operation for removing each packet and detecting each packet will be described.
- each of code channel signal generation units 101-1 to 101-4 of packet transmitting apparatus 100 generates a signal of one packet among packets P1, P2, P3 ′, and P4 ′, and packet transmitting apparatus 100 Suppose that a signal obtained by code-multiplexing these signals is transmitted as shown in FIG.
- the packet transmitting apparatus 100 transmits a retransmission control signal indicating the number of retransmissions of the packets P1, P2, P3 ', and P4' together with the signals of these packets.
- the receiving unit 202 of the packet receiving device 200 receives the signal transmitted by the packet transmitting device 100 via the antenna unit 201.
- the received packet management unit 206 acquires information indicating the number of retransmissions of the code-multiplexed packet of each signal from the retransmission control signal included in the received signal.
- the received packet management unit 206 receives the packets P1 and P2 0 times (initial transmission packet).
- the packet P3 ′ obtains information indicating one time (retransmission packet)
- the packet P4 ′ obtains information indicating one time (retransmission packet).
- the detection order determination unit 207 determines the detection order so as to detect sequentially from the code channel including the initial transmission packet with a small number of retransmissions.
- the code channels CH1 and CH2 formed by the initial transmission packets P1 and P2 with the number of retransmissions of 0 are detected first, and then the code channels CH3 and CH4 formed by the retransmission packets P3 ′ and P4 ′ are detected. Determine the order to detect.
- the interference cancellation unit 208 signal detection processing is performed preferentially from the initial transmission packet, and the interference replica generated from the detection signal of the initial transmission packet as a result of this signal detection processing is removed from the reception signal, Perform signal detection processing of the retransmitted packet. Therefore, when detecting a retransmission packet, detection processing is performed on a signal from which an interference component due to an initial transmission packet having a smaller number of retransmissions than the detected retransmission packet is removed, thereby improving the detection accuracy of the retransmission signal. It becomes possible.
- the packet including a lot of systematic bits can be detected with higher accuracy.
- the signal of the initial transmission packet can be detected with high accuracy. Then, after removing the interference replica generated from the detected signal of the initial transmission packet from the received signal, the detection accuracy of the retransmission packet signal can be further improved by detecting the signal of the retransmission packet.
- the first transmission packet is punctured with pattern 1 in FIG. 5, and the retransmitted packet is punctured with pattern 2 in FIG.
- the initial transmission packet has a larger number of systematic bits than the retransmission packet, it is possible to detect the signal of the initial transmission packet with high accuracy and improve the signal detection accuracy of the retransmission packet.
- retransmission packets having the same number of retransmissions may be in any detection order. For example, they may be detected together and the detection order may be determined using other criteria such as a spread code sequence.
- the packet receiving apparatus 200 assigns an OVSF sequence with a small number of codes generated from the same parent code as a spreading code to a packet with a small number of retransmissions, whereby the packet receiving apparatus 200 accurately It can be detected well. Then, after removing the interference replica generated from the detected signal of the initial transmission packet from the received signal, the detection accuracy of the retransmission packet signal can be further improved by detecting the signal of the retransmission packet.
- OVSF code Orthogonal Variable Spreading Factor
- OVSF code C 1 ( 1, 1, 1, 1 ) in P2
- OVSF code C 4 (1, ⁇ 1, ⁇ 1,1) is assigned to P4 ′.
- C 1 is the OVSF code
- An OVSF code sequence with fewer codes generated from the same parent code can maintain orthogonality more, and a packet signal with a smaller number of retransmissions can be detected with higher accuracy.
- the detection order determining unit 207 determines the detection order so that detection is performed in order of P2, P3 ′, and P4 ′ in order from the code channel including the packets with the smallest number of retransmissions. Then, signal detection is performed from the retransmission packet signal with a small number of retransmissions among the retransmission packets, and the interference replica generated using all the detected signals is removed from the received signal. Therefore, when detecting a retransmission packet, detection processing is performed on a signal from which interference components due to retransmission packets and initial transmission packets having a smaller number of retransmissions than the detected retransmission packet are removed. It is possible to improve the detection accuracy.
- FIG. 8 is a schematic block diagram illustrating a configuration example of the interference canceling unit 208 that performs successive-type repetitive interference cancellation.
- the interference canceling unit 208 uses code channel parameters such as spreading codes to detect the code channel signals in the order determined by the detection order determining unit 207.
- the interference cancellation unit 208 includes N propagation path compensation units 601, code separation units 603-1 to 603-N, N MCI replica generation units 604, code channel replica generation units 605-1 to 605-N, and N pieces.
- N indicates the maximum value of the number of multiplexed codes that can be received.
- Each of code separation sections 603-1 to 603-N includes despreading section 607, demodulation section 608, deinterleave section 609, depuncture section 610, and decoding section 611.
- a series of processing in the interference cancellation unit 208 is repeatedly executed by a predetermined number of repetitions. That is, when receiving a signal with the number N of code multiplexes, the interference cancellation unit 208 cancels interference by the subtraction unit 606, channel compensation by the channel compensation unit 601, and code separation for the first to Nth code channels.
- a series of processes for performing code channel separation by any of the units 603-1 to 603-N is repeated for the number of repetitions.
- the interference canceling unit 208 sets parameters of each unit to be configured based on the order determined by the detection order determining unit 207.
- N 4
- the order of the code channels CH1, CH2, CH3, and CH4 determined by the detection order determination unit 207 based on the example shown in FIG. 7 packets P1, P2, P3 ′, P4 ′ In order
- the signal of the code channel (packet) is detected and interference is removed. Details of each part of the interference cancellation unit 208 will be described later.
- FIG. 10 is a schematic block diagram showing the configuration of the code channel replica generation unit 605-1.
- the code channel replica generation unit 605-1 includes a puncturing unit 621, an interleaving unit 622, a modulation replica generation unit 623, and a spreading unit 624. Based on the detection order determined by the detection order determining unit 207, the spread code C 1 ... C N Among these, a replica of the code channel corresponding to the spreading code input to the spreading unit 624 is generated.
- the code channel replica generation unit 605-1 uses the code channel signal corresponding to the spreading code input to the despreading unit 607 among the spreading codes C 1 to C N by the code separation unit 603-1 in FIG.
- a code channel replica is generated based on a coded bit LLR (Log Likelihood Ratio) that is output each time detection is performed.
- code channel replica generation units 605-2 to 605-N generate code channel replicas based on encoded bit LLRs output by code separation units 603-2 to 603-N, respectively.
- the encoded bit LLR is a log likelihood ratio LLR of each bit encoded by the error correction code of the encoding unit 111.
- the puncturing unit 621 performs the log likelihood ratio LLR of the encoded bit that is the output signal from the decoding unit 611 for each code channel (packet) by the puncturing unit 124 of the packet transmission device 100 that is the packet transmission source. Puncture processing is performed using the same pattern as the puncture pattern.
- the interleave unit 622 performs a bit arrangement rearrangement process on the output signal from the puncture unit 621 by using the same pattern as the interleave pattern that the interleave unit 112 of the packet transmission device 100 performs for each code channel (packet).
- Modulation symbol replica generation section 623 modulates the output signal from interleaving section 622 with the same modulation scheme as modulation section 113 such as QPSK modulation and 16QAM modulation, and generates a modulation symbol replica.
- the processing of the modulation symbol replica generation unit 623 will be described using QPSK modulation as an example. If the log likelihood ratio LLR of the bits constituting the QPSK modulation symbol is ⁇ (b 0 ) and ⁇ (b 1 ), a replica of the QPSK modulation symbol is given by equation (2). However, j represents an imaginary unit. In other modulations such as 16QAM, it is possible to generate a symbol replica based on the same principle.
- Spreading unit 624 modulates the output modulation symbol replica from the symbol replica generation unit 623 duplicates only the spreading factor of the spread codes C 1 ... C N, by multiplying the spread code C 1 ... C N in each code channel A code channel replica (data signal replica) is generated.
- MCI replica generation units 604-1 to 640-N and code separation unit 603 in the case of detecting and removing the interference in the order of code channels CH1, CH2, CH3, and CH4 The operations -1 to 603-N will be described in order.
- the MCI replica generation unit (interference replica generation unit) 604-1 detects the code channel CH1 detected first in the code separation unit 603-1 in the i-th repetition of the iterative processing in the interference cancellation unit 208.
- S ⁇ i-1,2 to S ⁇ i-1,4 which are replica signals of the code channels CH2 to CH4 generated by the code channel replica generation units 605-2 to 605-N in the i-1th iteration.
- the replica signals S a and b indicate that the detection order generated in the a-th iteration of the iterative process is the replica signal of the b-th code channel.
- subtracting unit 606-1 subtracts the MCI replica for code channel CH1 generated by MCI replica generating unit 604-1 from the output signal from FFT unit 205.
- propagation path compensation section 601-1 multiplies the subtraction result of subtraction section 606-1 by a weighting factor that compensates for propagation path distortion calculated using the propagation path estimation value calculated by propagation path estimation section 203.
- a weighting factor MMSE (Minimum Mean Square Error) weight, ORC (Orthogonal Restoration Combi) weight, MRC (Maximum Ratio Combining) weight, etc. are used. Can do.
- the despreading unit 607 of the code separation unit 603-1 multiplies the output signal from the propagation path compensation unit 601-1 by the spreading code C1 unique to the code channel CH1, and performs despreading processing. The CH1 signal is detected.
- the demodulation unit 608 performs demodulation processing on the output signal from the despreading unit 607 in the same modulation scheme as the transmission side such as QPSK, 16QAM, and the soft decision result of the coded bit, for example, the log likelihood ratio
- the encoded bit LLR is calculated.
- the demodulating process of the demodulating unit 608 will be described by taking an example in which the modulation method is QPSK and the coded bit LLR is calculated as a soft decision result.
- the QPSK symbol transmitted on the transmission side that is, the modulation result by the modulation unit 113 in FIG. 1 is X
- the symbol after despreading on the reception side that is, the despreading result by the despreading unit 607 is Xc.
- X can be expressed by Expression (3).
- j represents an imaginary unit.
- ⁇ (b 0 ) and ⁇ (b 1 ) which are log likelihood ratios LLR of the respective bits b 0 and b 1 , are obtained as in Expression (4).
- Re () represents the real part of a complex number.
- ⁇ is the equivalent amplitude after propagation path compensation. For example, if the propagation path estimation value in the k-th subcarrier is H (k) and the multiplied MMSE-based propagation path compensation weight W (k), ⁇ is W ( k) H (k).
- ⁇ (b 1 ) may be obtained by replacing the real part and the imaginary part of ⁇ (b 0 ). Note that, in the case of other modulation schemes such as 16QAM instead of QPSK, it is possible to calculate based on the same principle. Further, the demodulation unit 608 may calculate the hard decision result instead of the soft decision result.
- the deinterleaving unit 609 rearranges the bit arrangement so as to perform the reverse operation of the interleaving performed by the interleaving unit 112 of the transmission source packet transmitting apparatus 100.
- Depuncture section 610 uses the puncture pattern for the initial transmission packet to perform depuncture processing on the encoded bit LLRs whose bit arrangement has been rearranged by deinterleaving section 609, and outputs the result to decoding section 611.
- the depuncture unit 610 will be described in detail.
- the encoded bit sequence output from the error correction encoding unit 122 of the packet transmission device 100 is expressed as “x1, z1, z1 ′, x2, z2, z2 ′, x3, z3, z3 ′, x4, z4, z4 ′.
- X5, z5, z5 ′, x6, z6, z6 ′ the puncturing unit 124 performs puncturing processing to thin out bits in the pattern 1 of FIG. Assume that x4, z4 ′, x5, and x6 ”are output.
- the encoded bit LLR that is output from the deinterleave unit 609 corresponding to the encoded bit sequence output from the puncture unit 124 and transmitted from the packet transmitting apparatus 100 is expressed as “x r 1, z r 1, x r 2, x r 3, x r 4, z r 4 ', and x r 5, x r 6 ".
- depuncturing section 610 in this coded bit LLR "x r 1, z r 1, x r 2, x r 3, x r 4, z r 4 ', x r 5, x r 6 ", transmission Virtual values are inserted into bit positions corresponding to z1 ′, z2, z2 ′, z3, z3 ′, z4, z5, z5 ′, z6, and z6 ′ thinned out by the original puncture unit 124.
- the encoded bit LLR output from the depuncture unit 610 is “x r 1, z r 1,0, x r 2,0,0”. , X r 3,0,0, x r 4,0, z r 4 ′, x r 5,0,0, x r 6,0,0 ”.
- the decoding unit 611 performs error correction decoding processing corresponding to error correction coding such as turbo coding and convolutional coding performed by the error correction coding unit 122 of the source packet transmission apparatus 100, as a depuncture unit 610. Is performed on the encoded bit LLR output from the above, and the encoded bit LLR corrected in error is output.
- the code separation unit 603-1 separates the code channel CH1
- the code channel replica generation unit 605-1 performs coding bits of the code channel CH1 from the decoding unit 611 of the code separation unit 603-1.
- a replica signal of the code channel CH1 is generated using the LLR.
- the decoding unit 611 performs error detection processing on the packet by using an error detection code such as CRC (Cyclic Redundancy Check) performed by the error correction encoding unit 122 of the source packet transmission apparatus 100.
- the error detection processing result is input to the decoding unit 611 of the code separation unit 603-N that performs signal detection of the last code channel.
- the decoding unit 611 of the code separation unit 603-N repeats the iterative process that the decoding unit 611 counts whether all error detection processing results including the decoding unit 611 are error-free.
- each decoding unit 611 uses each decoding unit 611 to The encoded bit LLR of the error correction decoding result is output to the combining unit 210 and the received signal storage unit 209.
- the output signal of the depuncture unit 610 is used as the signal to be output to the combining unit 210 and the received signal storage unit 209. It can also be input to the storage unit 209.
- the interference cancellation unit 208 performs signal detection of the code channels CH2, CH3, and CH4 in the order of the code channels CH2, after detecting the signals of the code channels CH1 in the order determined by the detection order determination unit 207. This is performed using a code channel replica whose signal is detected.
- the code channel replica input to the MCI replica generation unit 604 is different from the MCI replica generation process for the code channel CH1.
- the MCI replica generation unit 604 When the code separation unit 603-2 detects a signal of the code channel CH2 in the i-th repetition of the iterative processing in the interference cancellation unit 208, the MCI replica generation unit 604 generates the code channel CH1 generated in the i-th repetition.
- the replica signals S ⁇ i, 1 and the replica signals S ⁇ i-1,3 , S ⁇ i-1,4 of the code channels CH3 to CH4 generated in the i-1th iteration are code-multiplexed and further propagated By multiplying the path estimation value, an MCI replica that causes interference with the code channel CH2 is generated.
- the MCI replica generation unit 604 when the code separation unit 603-3 detects the signal of the code channel CH3, the MCI replica generation unit 604 generates the replica signals S ⁇ i, 1 , S ⁇ of the code channels CH1 and CH2 generated in the i-th iteration.
- the code channel CH3 is obtained by code-multiplexing S ⁇ i-1,4 , which is a replica signal of the code channel CH4 generated in the i-th and i-1th iterations, and multiplying by the propagation channel estimation value.
- An MCI replica that causes interference is generated.
- the MCI replica generation unit 604 When the code separation unit 603-4 detects the signal of the code channel CH4, the MCI replica generation unit 604 generates the replica signals S ⁇ i, 1 to S ⁇ i, 3 of the code channels CH1 to CH3 generated in the i-th iteration. Is multiplexed and further multiplied by the propagation path estimation value to generate an MCI replica that causes interference with the code channel CH4.
- the code channel replica generation unit 604 generates (updates) the code channel replica using the generated (updated) code channel replica to be used for interference cancellation processing in the code channel to be detected next.
- the MCI replica generation unit 604 uses the MCI replica R ⁇ i, u used for the interference cancellation processing when detecting the u-th code channel detected by the detection order determination unit 207 as follows. (5) is calculated.
- H is a propagation path estimated value and N is the number of multiplexed code channels.
- the interference cancellation unit 208 generates a code channel replica using the encoded bit LLR output from the decoding unit 611, but generates a code channel replica using the encoded bit LLR output from the depuncture unit 610. May be.
- the deinterleaving unit 609 and the depuncturing unit 610 perform processing according to a pattern corresponding to each code channel.
- Despreading section 607 multiplies the spreading code sequence multiplied at the time of transmission specific to each code channel.
- interference cancellation is sequentially performed for each code channel based on the number of retransmissions of a packet constituting the code channel (code channel signal detection).
- the channels may be grouped and interference cancellation may be performed in order for each group.
- the code channel may be grouped according to the initial transmission packet or the retransmission packet.
- an interference replica is generated using the signal of the initial transmission packet among the detected signals, and the interference component is removed.
- the reception signal storage unit 209 in FIG. 6 includes a coded bit LLR (decoding result) output from each decoding unit 611 when the repetition processing in the interference cancellation unit 208 reaches a predetermined number of repetitions (for example, the maximum number), or The encoded bit LLR (demodulation result) output from the depuncture unit 610 is stored.
- the reception signal storage unit 209 receives the packet received before this retransmission packet, that is, the initial transmission packet of the retransmission packet or the initial transmission packet.
- At least one encoded bit LLR for the retransmission packet is output to combining section 210. For example, when the p-th retransmission packet is received, the encoded bit LLR of the first reception packet (initial transmission packet) may be output, or the first to p ⁇ 1 receptions The encoded bit LLR of the packet may be output.
- the combining unit 210 combines the encoded bit LLR output from the reception storage unit 209 and the encoded bit LLR of the retransmission packet output from the interference cancellation unit 208. That is, combining section 210 is a coded bit LLR output from interference cancellation section 208 and a coded bit LLR stored in reception storage section 209, which is a signal of coded bit LLR output from interference cancellation section 208. Of the initial transmission packet or the encoded bit LLR of the retransmission packet of the initial transmission packet. Among the outputs of the interference cancellation unit 208, the combining unit 210 outputs the encoded bit LLR of the initial transmission packet as it is.
- the output signal of the reception storage unit 209 for the code channel CH3 is expressed as g1 p (m) (where m is an index of encoded bits constituting the packet, and the maximum value is the number of bits constituting the packet), and the output signal for the code channel CH3 from the interference cancellation unit 208 is g2 p (m).
- the synthesis unit 210 calculates the output signal ⁇ p by the following equation (6).
- ⁇ p represents a weighting factor to be given to the output g1 p (m) from the reception storage unit 209
- ⁇ p represents a weighting factor to be given to the output g2 p (m) from the interference cancellation unit 208
- g1 p (m) g2 p multi-level number of data modulation has been performed (m)
- coding rate, spreading factor it is determined by the number of code multiplexes such. For example, if g1 p (m) is subjected to QPSK modulation and g2 p (m) is subjected to 16QAM modulation, weighting is performed such that ⁇ p > ⁇ p , thereby enabling synthesis that reflects demodulation accuracy. Become. However, you may synthesize
- the decoding unit 211 performs error correction decoding processing on error correction coding such as turbo coding and convolution coding performed by the transmission source packet transmission apparatus 100 on the output signal (coded bit LLR) from the combining unit 210. To generate an error detection coded bit sequence. Further, the decoding unit 211 performs error detection processing on the packet by error detection such as CRC (Cyclic Redundancy Check) performed by the transmission source device on the error detection coded bit sequence. In addition to outputting the result, if no error is detected in this error detection process, a packet composed of an information bit sequence obtained by removing redundant bits for error detection from the generated bit sequence is output.
- error detection processing such as turbo coding and convolution coding performed by the transmission source packet transmission apparatus 100 on the output signal (coded bit LLR) from the combining unit 210.
- CRC Cyclic Redundancy Check
- the response signal generation unit 212 generates a data sequence including control data indicating the presence / absence of a packet error from the error detection result received from the decoding unit 211, and performs a signal processing such as error correction coding and data modulation to generate a response signal Is generated. Further, the response signal generation unit 212 converts the response signal into an analog signal (D / A conversion), and further converts it into a transmittable frequency band (radio frequency band). The response signal generation unit 212 transmits a signal including this response signal from the antenna 201.
- the communication method of the response signal by the response signal generation unit 212 is not limited as long as the transmission signal of the transmission source of the reception signal such as OFDM or single carrier modulation method can be restored.
- a signal indicating “no packet error” is input from the decoding unit 211
- an ACK signal is generated as a response signal indicating that reception has been correctly completed to the transmission / reception apparatus that is the transmission source of the reception signal.
- a NACK signal is generated as a response signal for requesting retransmission of the packet to the transmission / reception device that is the transmission source of the received signal.
- the decoding unit 211 can be replaced by the decoding unit 611.
- FIG. 11 is a flowchart for explaining the operation of the packet receiving apparatus 200.
- the packet receiving apparatus 200 receives the code multiplexed signal (S101)
- the received packet management unit 206 of the packet receiving apparatus 200 acquires the number of retransmissions of the packets constituting each code channel from the retransmission control signal included in the received signal. (S102).
- the detection order determination unit 207 determines the signal detection order (interference signal removal order) of the packet (code channel) for canceling the interference and detecting the signal from the retransmission number information acquired by the received packet management unit 206 (S103). .
- the interference cancellation unit 208 detects a packet (code channel) according to the signal detection order determined in step S103 (S104). Each decoding unit 611 determines whether or not there is an error in the signal-detected packet (S105). If it is determined that there is no error in all the packets, the response signal generation unit 212 responds that there is no error. A signal is returned to the packet transmitting apparatus 100 (S110). If the decoding unit 611 determines in step S105 that there is an error in the packet, it determines whether or not the repetition processing of the interference cancellation unit 208 has been repeated up to the number of repetitions (S106), and has not been repeated up to the number of repetitions. When it is determined that the decoding unit 611 outputs the encoded bit LLR, the interference cancellation unit 208 returns to step S104 and repeats again.
- the response signal generation unit 212 determines the number of retransmissions of the packets constituting the code channel in which the error is detected in step S105 (S107).
- a response signal requesting retransmission is returned to the transmission source (S111).
- the combining unit 210 stores the encoded bit LLR of the retransmission packet output from the decoding unit 611 and the received signal storage unit 209.
- the received initial transmission packet is combined (S108), and the decoding unit 211 performs error detection processing on the combined result (S109). If there is no error as a result of the error detection process, a response signal indicating that there is no error is returned to the transmission source (S110). If there is an error, a response signal indicating that retransmission is requested is returned to the transmission source (S111). Returning to step S101, the next signal is received.
- the interference canceling unit 208 has been described as performing iterative processing that repeatedly performs signal detection of code-multiplexed code channels.
- the first processing in the above iterative processing is not performed repeatedly. Only, that is, the detection of the signal of each code channel may be performed once for each code channel.
- the detection order determination unit 207 of the packet reception device 200 determines the signal detection order so that detection is performed from a packet with a small number of retransmissions among code-multiplexed packets, and the interference cancellation unit 208 Performs signal detection from the initial transmission packet in accordance with the signal detection order, removes an interference component due to the signal of the detected packet from the received signal, and then performs signal detection of the retransmission packet. For this reason, when signal detection is performed on a retransmission packet, signal detection is performed on a signal from which more interference components have been removed, so that signal detection can be performed with high accuracy. Therefore, it is possible to prevent the number of retransmissions of a specific packet from increasing and delay from increasing.
- the puncturing unit 124 of the packet transmitting apparatus 100 performs puncturing processing using a puncture pattern in which the first transmission packet includes more systematic bits than the retransmission packet.
- the interference cancellation unit 208 of the packet reception device 200 can detect the signal of the initial transmission packet with high accuracy. The accuracy of removing interference components with respect to the retransmission packet signal based on the signal of the initial transmission packet is improved, and the signal detection of the retransmission packet can be improved with accuracy.
- the interference signal means another spatially multiplexed signal. That is, for example, if signals P 1 and P 2 are spatially multiplexed, a signal P 2 is an interference for the signal P 1, the signal P 1 is an interference for the signal P 2.
- the interference cancellation process is a process for removing a signal reproducing the interference signal from the received signal (replica), for example, when detecting the signal P 2 is used to remove a replica of the signal P 1 from the received signal the signal .
- FIG. 12 is a schematic block diagram illustrating the configuration of the packet transmission device 300 according to the present embodiment.
- the packet transmission device 300 is included in a downlink base station and an uplink mobile station in a wireless communication system. In addition, it is provided in a relay station on the downlink between the relay station and the mobile station.
- the packet transmission device 300 includes stream signal generation units 301-1 to 301-Ns (where Ns is the number of streams), antenna units 302-1 to 302-Ns, a retransmission control signal generation unit 311, and a restoration unit 312. N stream signals generated from different information bit sequences constituting each packet are transmitted one by one from each of the antenna units 302-1 to 302-Ns. Further, the packet transmission device 300 restores a signal including a response signal from the packet reception device 400.
- the restoration unit 312 converts the signal received from the packet reception device 400 via the antenna unit 302-1 into a frequency band that can be restored, performs band limitation by filtering, and converts the analog signal into a digital signal ( (Analogue / Digital conversion), and further, a received signal restoration process such as data demodulation and error correction decoding is performed on the digital signal, a response signal included in the signal from the packet reception device 400 is extracted, and each response signal indicates Packet reception success / failure information is notified to the encoding unit 303 and the retransmission control signal generation unit 311 in the stream generation units 301-1 to 301-Ns.
- the restoration unit 312 has a function capable of restoring the received signal processing based on the transmission method of the received signal.
- the restoration unit 312 is described as receiving via the antenna unit 302-1. However, the restoration unit 312 may be received via any one of the antenna units 302-2 to 302-Ns. You may make it receive from a dedicated antenna.
- Stream signal generation sections 301-1 to 301-Ns generate transmission data signals for each stream from information bits constituting each input packet, and encode section 303, interleave section 304, modulation section 305, and IFFT section 306.
- the encoding unit 303 has a function of adding redundant bits to the information bit sequence of the input packet so that the packet receiving apparatus 400 can perform error detection and error correction.
- the encoding unit 303 encodes or retransmits the encoded bit of the initial transmission packet or the retransmission according to the response signal from the packet receiving apparatus 400 to the signal (packet signal) of each stream output from each of the stream signal generation units 301-1 to 301-Ns. Output the encoded bits of the packet.
- a packet is generated for each stream, and error detection coding and error correction coding are performed for each packet (each stream).
- the puncture unit 124 may use the puncture pattern shown in FIG. 4 or the puncture pattern shown in FIG. 5 as in the first embodiment.
- the interleaving unit 304 rearranges the bit arrangement of the encoded bits output from the encoding unit 303 according to a predetermined pattern.
- Modulation section 305 performs data modulation on the coded bits whose bit arrangement is rearranged by interleaving section 304 using a modulation scheme such as QPSK or 16QAM, and generates modulation symbols. Note that the data modulation method may be different for each stream.
- the IFFT unit 306 assigns the modulation symbol from the modulation unit 305 to each subcarrier, and performs frequency-time conversion by IFFT (Inverse Fast Fourier Transform) or the like to generate a time-domain signal.
- IFFT Inverse Fast Fourier Transform
- the multiplexing unit 306 multiplexes the time-domain signal generated by the IFFT unit 305, the pilot signal generated by the pilot signal generation unit 310, and the retransmission control signal generated by the retransmission control signal generation unit 311.
- the retransmission control signal is multiplexed only by the multiplexing unit 306 included in the stream signal generation unit 301-1, and the multiplexing units 306 included in the other stream signal generation units 301-2 to 301-Ns are described above.
- the time domain signal and the pilot signal are multiplexed.
- the pilot signal generation unit 310 generates a pilot signal used for propagation path estimation of each stream signal on the reception side. Preferably, an orthogonal pilot signal is generated for each stream.
- the retransmission control signal generation unit 311 determines the number of retransmissions of packets to be transmitted in each stream based on the success / failure information of each packet reception from the restoration unit 312 and transmits the determined retransmission number to the receiving apparatus. Is generated. In other words, when receiving success / failure information indicating packet reception failure, retransmission control signal generating section 311 generates a retransmission control signal with the number of retransmissions of the packet increased by one, and receiving success / failure information indicating successful packet reception. A retransmission control signal indicating the initial transmission packet is generated by setting the number of retransmissions of the next packet to be transmitted using the same successful stream to “0”.
- retransmission control signal generation section 311 is connected to multiplexing section 307 included in stream signal generation section 301-1, and retransmission control signal generated by retransmission control signal generation section 311 is generated by stream signal generation section 302-1.
- the retransmission control signal generation unit 311 is connected to one of the multiplexing portions 307 of the other stream signal generation units 302-2 to 302-N so that the stream signal is multiplexed to other stream (s). You may make it the structure multiplexed with the stream which a production
- the retransmission control signal generation unit 311 may generate a retransmission control signal including transmission parameters such as a data modulation scheme, the number of streams, and a puncture pattern.
- the GI insertion unit 308 inserts a guard interval GI (Guard Interval) into the output signal of the multiplexing unit 307, and the transmission unit 309 converts the output signal from the GI insertion unit 308 into an analog signal (D / A Conversion), band limitation by filtering processing, and further conversion to a frequency band that can be transmitted.
- GI Guard Interval
- the same processing is performed in the stream signal generation units 301-2 to 301-Ns other than the stream signal generation unit 301-1, and the output signals from the respective stream signal generation units correspond to the corresponding antenna units 302-2 to 302-2.
- the transmitting apparatus 300 transmits a signal in which an initial transmission packet or a retransmission packet is spatially multiplexed.
- Signals transmitted from antenna units 302-1 to 302-Ns are referred to as stream 1 to stream Ns.
- the retransmission packet has been described as being transmitted from the same stream and the same antenna as the initial transmission packet, but may be transmitted from a different antenna for each number of retransmissions.
- the packet reception device 400 it is assumed that the retransmission packet is transmitted from the same stream and the same antenna as the initial transmission packet.
- FIG. 13 is a schematic block diagram showing the configuration of the packet reception device 400 according to the present embodiment.
- the packet receiver 400 is provided in a mobile station in the downlink and a base station in the uplink by the wireless communication system. Also, it is provided in a relay station on the downlink between the base station and the relay station.
- the packet receiver 400 includes antenna units 401-1 to 401-M (where M is the number of reception antennas), signal processing units 402-1 to 4-2M for each antenna, received packet management unit 403, detection order determination unit 404, an interference cancellation unit 405, a received signal storage unit 406, a synthesis unit 407, a decoding unit 408, and a response signal generation unit 409.
- the per-antenna reception processing units 402-1 to 402-M receive and process signals received via the corresponding antenna units 401-1 to 401-M, and receive the reception unit 411, GI removal unit 412, and FFT unit 413. , A propagation path estimation unit 414 is provided.
- the per-antenna reception processing unit 402-1 will be described, but the other per-antenna reception processing units 402-2 to 402-M also have corresponding antenna units 401-2 to 401-M, respectively.
- the configuration is the same as the reception processing unit for each antenna 402-1 except that no signal is output to the reception packet management unit 403.
- the reception unit 411 converts the signal from the packet transmission device 300 received via the antenna unit 401-1 into a frequency band that can be processed by a signal detection process or the like, limits the band by a filtering process, and converts the analog signal into a digital signal (Analogue / Digital conversion).
- the propagation path estimation unit 414 compares the pilot signal included in the digital signal converted by the reception unit 411 with the known pilot signal at the time of transmission in the unit, and compares each of the antenna units 301-1 to 301 of the packet transmission device 300. -Estimate the propagation path characteristic between Ns and the antenna unit 401-1 of the packet reception device 400, and output the propagation path estimation value. In addition, you may make it use the other signal which can estimate a propagation path, such as a control channel and a preamble.
- the GI removal unit 412 removes the guard interval GI included in the digital signal converted by the reception unit 411.
- the FFT unit 413 performs fast Fourier transform FFT processing on the signal from which the GI removal unit 412 has removed the guard interval GI, thereby converting the signal into a frequency domain signal. The same processing is performed in the other antenna-specific reception processing units 402-2 to 402-M.
- the signal R p (k) in the k-th subcarrier of the p-th received packet in HARQ can be expressed by Equation (7).
- H p (k) is a propagation path characteristic between the transmission antenna and the reception antenna
- S p (k) is a transmission signal for each transmission antenna
- N (k) is a noise for each reception antenna.
- T represents a transposed matrix.
- Received packet management section 403 transmits the initial transmission packet by each stream transmitted from antenna sections 301-1 to 301-Ns of transmitting apparatus 300 from the retransmission control signal included in the received signal, or transmits the retransmission packet.
- Information indicating the number of retransmissions that is, the number of retransmission packets being transmitted (specifically, the number of retransmission packets transmitted), data relating to transmission parameters such as a data modulation scheme and a puncture pattern are extracted.
- the detection order determination unit 404 determines the order in which signals are detected by the interference cancellation unit 405 based on information indicating the number of retransmissions extracted by the received packet management unit 403 and notifies the interference cancellation unit 405 of the order. Details of the order determination by the detection order determination unit 404 will be described later.
- the interference cancellation unit 405 is based on the propagation path estimation value output from the propagation path estimation unit 414 and the data regarding the transmission parameters of each packet output from the reception packet management unit 403.
- the reception signal storage unit 406, the synthesis unit 407, and the decoding unit 408 have the same functions as the reception signal storage unit 209, the synthesis unit 210, and the decoding unit 211 of the first embodiment illustrated in FIG. However, the processing of the number of streams Ns is performed in parallel, but the reception signal storage unit 209, the synthesis unit 210, and the decoding unit 211 in the first embodiment are different in that each process is performed for each code channel.
- the response signal generation unit 409 also has the same function as the response signal generation unit 212 in the first embodiment.
- the detection order determination unit 404 determines the order in which spatially multiplexed signals using MIMO are detected based on information indicating the number of retransmissions.
- the packet transmission device 300 transmits the stream 1 including the initial transmission packet P1 from the antenna unit 301-1 to the antennas 401-1 to 401-4 of the packet transmission device 400.
- Stream 2 composed of the initial transmission packet P2 from the antenna unit 301-3 to the antennas 401-1 to 401-4 of the packet transmission device 400 for the first time.
- Stream 3 consisting of packet P3 ′ is transmitted simultaneously from antenna section 301-4 to antennas 401-1 to 401-4 of packet transmitting apparatus 400, and stream 4 consisting of first retransmission packet P4 ′.
- the packet receiving apparatus 400 receives signals obtained by spatially multiplexing these streams 1 to 4 using the antenna units 401-1 to 401-4.
- the transmitting apparatus 300 transmits a retransmission control signal indicating the number of retransmissions of the packets P1, P2, P3 ', and P4' together with these packets.
- the packets P3 'and P4' are retransmission packets for the initial transmission packets P3 and P4, respectively. Further, the packet transmitting apparatus 300 performs puncture processing on the initial transmission packet with the pattern 1 in FIG. 4, and performs retransmission processing on the retransmission packet with the pattern 2 in FIG.
- Received packet management section 403 of packet receiving apparatus 400 obtains the number of retransmissions of packets transmitted by each stream from the retransmission control signal included in the signal received by antenna-specific signal processing section 402-1 via antenna section 401-1. To do.
- packets P 1, P 2, P 3 ′, and P 4 ′ are transmitted in streams 1 to 4, respectively, and the received packet management unit 403 receives the packets P 1 and P 2 0 times (initially Information indicating that the packet P3 ′ is once (retransmission packet) and the packet P4 ′ is once (retransmission packet) is obtained from the retransmission control signal.
- the detection order determination unit 404 determines the detection order based on the information indicating the number of retransmissions acquired by the received packet management unit 403 so that the first transmission packet is detected first. In the case of FIG. 16, the detection is performed so that the stream 1 and the stream 2 including the initial transmission packets P1 and P2 are detected first, and then the stream 3 and the stream 4 including the retransmission packets P3 ′ and P4 ′ are detected. Determine the order.
- the interference cancellation unit 405 detects signals preferentially from the stream transmitting the initial transmission packet according to the detection order determined by the detection order determination unit 404, and receives the interference replica generated from the detection signal of the initial transmission pilot.
- the signal is removed from the transmitted signal and the signal of the stream transmitting the retransmission packet is detected. Therefore, by performing detection processing in order from the initial transmission packet, when detecting the signal of the retransmission packet, signal detection of the retransmission packet is performed by detecting the signal of the retransmission packet from the signal from which the interference component due to the initial transmission packet is removed. The accuracy can be improved.
- the initial transmission packet is made to include all systematic bits like the puncture pattern shown in FIG. Since the packet can be detected with high accuracy, the accuracy of the interference replica generated from the detected signal of the initial transmission packet is improved, the interference component for the retransmission packet can be accurately removed, and the detection accuracy of the signal of the retransmission packet is improved. be able to.
- the packet transmitting apparatus 300 has been described as using the puncture pattern shown in FIG. 4, but FIG. 5 is used as the puncture pattern, and the first transmission packet is punctured with the pattern 1 in FIG. Even when puncturing is performed on the retransmitted packet with the pattern 2 in FIG. 5, by determining the stream detection order in the same manner as in the case of using FIG. 4, from the initial transmission packet having a large number of systematic bits. Signal detection is performed to improve the accuracy of interference replicas for retransmission packets, and the signal detection accuracy of retransmission packets can be further improved.
- the detection order determining unit 404 determines the detection order based on the number of retransmissions of the packets constituting the stream, and detects the reception level such as SINR, such as detecting the larger SINR first among packets having the same number of retransmissions.
- the detection order may be determined as a reference.
- the detection order determination unit 404 determines the order in which packets of each stream are detected one by one in sequence (separate stream interference cancellation and MIMO spatial multiplexing) based on the number of retransmissions of the packets constituting each stream.
- the streams may be grouped based on the number of packet retransmissions, and the order may be determined so that the packets of each stream are detected in order for each group.
- FIG. 14 is a schematic block diagram showing a configuration of an interference cancellation unit 405 that performs successive-type repeated interference cancellation on a spatially multiplexed signal.
- the interference cancellation unit 405 includes a stream 1 in which the packet transmission device 300 as illustrated in FIG. 16 transmits the packet P1 from the antenna unit 302-1; a stream 2 in which the packet P2 is transmitted from the antenna unit 302-2; From the stream 1 received by the detection order determination unit 404, the spatial multiplexing signal composed of the stream 3 transmitted P3 ′ from the antenna unit 302-3 and the stream 4 transmitted packet P4 ′ from the antenna unit 302-4 is received. Based on the detection order of the stream 4, these streams are sequentially detected. A series of processing (stream 1 to stream 4 detection processing) in the interference cancellation unit 405 is repeatedly executed a predetermined number of times, except when all information bits can be detected without error during the process.
- the interference cancellation unit 405 includes stream detection units 1201-1 to 1201-Ns, Ns reception replica generation units 1202, symbol replica generation units 1204-1 to 1204-Ns, and each antenna signal processing unit 402-1 to The replica of the interference signal is removed from the frequency domain data signal output by the 402-M FFT unit 413, and the spatially multiplexed stream is separated, and each stream is demodulated and decoded.
- the stream detection unit 1201-1 detects the signal of the stream 1 with the first detection order
- the stream detection unit 1201-2 detects the signal of the stream 2 with the second detection order
- the stream detection unit 1201 -3 detects the signal of the third stream 3 in the detection order
- the symbol replica generation unit 1204-1 generates a symbol replica of the signal constituting the stream 1
- the symbol replica generation unit 1204-2 generates a symbol replica of the signal constituting the stream 2
- the symbol replica generation unit 1204- 3 generates a symbol replica of a signal constituting the stream 3
- Each of the stream detection units 1201-1 to 1201-Ns includes a subtraction unit 1203, a MIMO separation unit 1205 (stream separation unit), a demodulation unit 1207, a deinterleave unit 1208, a depuncture unit 1209, and a decoding unit 1210.
- the subtraction unit 1203 subtracts the interference replica (stream replica) generated by the reception replica generation unit 1202 from the output signal of the FFT unit 413 of the per-antenna signal processing units 402-1 to 402-M.
- output signals R 1 to n, i, m (k) for the signal processing unit 402-m (1 ⁇ m ⁇ M) for each antenna of the subtraction unit 1203 of the stream detection unit 1201-n are as follows: Equation (8) is obtained.
- R m (k) is a frequency domain signal of the k-th subcarrier output from the FFT unit 413 of the per-antenna signal processing unit 402-m
- R ⁇ n, i, m (k) is the i-th iterative process.
- the symbol replica of stream 1 to stream (n ⁇ 1) generated in the i-th iteration and the stream (n + 1) generated in the i ⁇ 1-th iteration Using the symbol replica of the stream Ns and the propagation path estimation value, an interference signal replica that is an interference component of the received signal is generated.
- the replica R ⁇ n, i, m (k) of the interference signal output from the reception replica generation unit 1202 for the stream n received by the antenna 401-m during the i-th iterative process is expressed by the following equation (9).
- H u, m (k) is the propagation path estimation value of the stream u received by the antenna 401-m
- S u u, i (k) is generated by the symbol replica generation unit 1204-u in the i th iteration.
- the symbol replica of the stream u is shown.
- i 1 (first iteration process)
- a replica of the interference signal is generated from only the symbol replica of stream 1 to stream (n ⁇ 1) generated up to the detection process of stream n and the propagation path estimation value. To do.
- the above-described interference cancellation processing is performed on signals received by all the antennas 401-1 to 401-M.
- MIMO separation section 1205 performs stream separation and propagation path compensation of the spatially multiplexed (MIMO) signal on the output of subtraction section 1203 based on the propagation path estimation value that is the output of propagation path estimation section 414, and A stream modulation symbol sequence is generated. Specifically, the stream signal is reproduced by maximum likelihood estimation. Alternatively, a separation method such as calculating a ZF (Zero Factor) weight or an MMSE (Minimum Mean Square Error) weight for the output of the subtraction unit 1203 and multiplying the output of the subtraction unit 1303 by the calculated weight is used.
- ZF Zero Factor
- MMSE Minimum Mean Square Error
- the weighting factors W ZF, n (k), W MMSE, n (k) based on the ZF criterion and the MMSE criterion of the MIMO separation unit 1205 belonging to the stream detection unit 1201-n are expressed by the following equations (10), (11 ).
- H is a complex conjugate transpose of a matrix
- ⁇ 1 is an inverse matrix
- ⁇ 2 is noise power
- I N is an N ⁇ N unit matrix.
- H n (k) in the case of the repetitive processing (i> 1) in the repetitive SIC is the equation (13).
- Demodulation section 1207 performs demodulation processing on the modulation symbol sequence that is the output signal from MIMO separation section 1205, and extracts a signal for each encoded bit.
- the log likelihood ratio (LLR) for each coded bit is output, similarly to the demodulator 608 of the first embodiment shown in FIG.
- Deinterleaving section 1208 performs deinterleaving processing on the signal for each encoded bit output from demodulation section 1207. This deinterleaving process is rearrangement for returning the order rearranged by the interleaving unit 112 in the interleaver unit of the packet transmission device 300 to the original order.
- the depuncture unit 1209 performs a process opposite to the puncture (bit removal) process performed in the puncture unit 124 in the packet transmission device 300. That is, a depuncture process for inserting a predetermined virtual value is performed on the punctured bits.
- the depuncture unit 1209 uses the same puncture pattern as the puncture unit 124 in the packet transmission apparatus 300 as a puncture pattern. That is, for the first transmission packet, the depuncture unit 1209 performs depuncture processing based on the pattern 1 in FIG. Performs depuncture processing based on pattern 2 in FIG.
- the decoding unit 1210 performs softening on the output signal of the depuncturing unit 1209 by error correction decoding processing for error correction coding such as turbo coding and convolution coding performed by the error correction coding unit 122 of the packet transmission device 300.
- error correction decoding processing for error correction coding such as turbo coding and convolution coding performed by the error correction coding unit 122 of the packet transmission device 300.
- the log likelihood ratio LLR of the coded bit as the determination result is output.
- Symbol replica generation sections 1204-1 to 1204-Ns generate a symbol replica of each stream using the log likelihood ratio LLR of the encoded bits generated by decoding section 1210.
- decoding section 1210 performs error detection processing on the packet by error detection such as cyclic redundancy check CRC performed by error detection coding section 121 of packet transmitting apparatus 300, and outputs error detection information.
- the error detection processing result is input to the decoding unit 1210 of the stream demultiplexing unit 1201-Ns that detects the signal of the last code channel. Receiving these inputs, the decoding unit 1210 of the stream separation unit 1201 -Ns repeats the iterative process that the decoding unit 1210 counts whether all error detection processing results including the decoding unit 1210 have no errors. When the number of repetitions reaches a predetermined number of repetitions (maximum number of repetitions), the repetition process is terminated (output to the symbol replica generation unit 1204-Ns is stopped), and each decoding unit 1210 has an error caused by each decoding unit 1210.
- the encoded bit LLR of the corrected decoding result is output to the combining unit 407 and the received signal storage unit 406.
- the output signal of the depuncture unit 1209 is used as the signal to be output to the combining unit 407 and the received signal storage unit 406. It can also be input to the storage unit 406.
- FIG. 17 is a schematic block diagram showing the configuration of the symbol replica generation unit 1204-1.
- the other symbol replica generation units 1204-2 to 1204-Ns have the same configuration.
- the symbol replica generation unit 1204-1 generates a symbol replica based on the encoded bit LLR output every time signal detection of the signal corresponding to the stream 1 is completed by the puncture unit stream separation unit 1201-1, and the puncture unit 1211 And an interleaving unit 1212 and a modulation symbol replica generation unit 1213.
- the puncturing unit 1211 has the same pattern as the LLR of the coded bit that is the output signal of the decoding unit 1210 for each stream (packet) by the puncturing unit 124 of the packet transmission device 300. Puncture processing is performed using a pattern (puncture pattern in FIG. 4). Similar to the interleaving unit 622 shown in FIG. 10, the interleaving unit 1212 uses the same pattern as the pattern applied to the output signal from the puncturing unit 1211 for each stream (packet) by the interleaving unit 304 of the packet transmission device 300. Perform rearrangement processing.
- modulation symbol replica generation section 1213 modulates the output signal of interleaving section 1212, such as QPSK modulation and 16QAM modulation, to modulation section 305 of packet transmitting apparatus 300 shown in FIG. Modulation is performed by a method to generate a modulation symbol replica.
- Modulation symbol replica generation section 1213 that is, symbol replica generation section 1204-1 inputs the generated symbol replica to each of reception replica generation sections 1202 that generate replicas of interference signals for stream 2 to stream N.
- the symbol replica generation units 1204-1 to 1204-Ns generate symbol replicas using the encoded bit LLR output from the decoding unit 1210, but the depuncture unit 1209 A symbol replica may be generated using the encoded bit LLR output from the.
- FIG. 18 is a flowchart for explaining the reception operation of the packet reception device 400.
- the packet receiving device 400 receives the spatially multiplexed signal (S201)
- the received packet management unit 403 acquires the retransmission count information of the packets constituting each stream from the retransmission control signal included in the received signal (S202).
- the detection order determination unit 404 determines the order in which packets are detected (the order in which streams are detected) from the retransmission count information acquired in step S202 (S203).
- the interference cancellation unit 405 sequentially performs interference cancellation processing and signal detection of the stream of the corresponding packet in accordance with the order of detecting the packet determined in step S203 (S204).
- Decoding section 1210 determines whether or not there is an error in the signal-detected packet (S205), and when it is determined that there is no error for all packets, packet transmitting apparatus 300 sends a response signal (ACK) indicating that there is no error. (S210), and the process ends.
- NACK response signal
- step S207 If it is determined in step S207 that the packet is a retransmission packet (q ⁇ 1), the initial transmission packet or the retransmission packet received previously and stored in the reception signal storage unit 406 is combined with the retransmission packet. (S208) After this decoding result, the decoding unit 408 performs error correction decoding processing, and then performs error detection processing (S209). As a result of the error detection process, when it is determined that there is no error, a response signal (ACK) indicating that there is no error is returned to the transmission source (S210), and the reception process is terminated.
- ACK response signal
- a response signal (NACK) requesting retransmission is returned to the transmission source (S211), and the process returns to step S201 to receive the next reception signal. It becomes.
- the repeated successive interference canceller SIC is used to detect a signal spatially multiplexed by MIMO.
- MIMO multiplexed signal
- other separation methods for detecting a stream such as V-BLAST in order may be used. Good.
- a case where a spatially multiplexed signal is received by MIMO is shown, but the present invention can be similarly applied to a case where a code multiplexed and spatially multiplexed signal is received. It is also possible to apply a combination of the detection of the code-multiplexed signal of the embodiment and the detection of the spatially-multiplexed signal of the present embodiment.
- the detection order determination unit 404 of the packet reception apparatus 400 determines the signal detection order so that detection is performed from packets with a small number of retransmissions among the spatially multiplexed packets, and the interference cancellation unit 405. Performs signal detection from the initial transmission packet in accordance with the signal detection order, removes an interference component due to the signal of the detected packet from the received signal, and then performs signal detection of the retransmission packet. For this reason, when signal detection is performed on a retransmission packet, signal detection is performed on a signal from which more interference components have been removed, so that signal detection can be performed with high accuracy. Therefore, it is possible to prevent the number of retransmissions of a specific packet from increasing and delay from increasing.
- the puncturing unit 124 of the packet transmission device 300 performs puncturing processing using a puncture pattern in which the first transmission packet includes more systematic bits than the retransmission packet.
- the interference cancellation unit 405 of the packet reception device 400 can accurately detect the signal of the initial transmission packet, The accuracy of removing interference components from the retransmission packet signal based on the initial transmission packet signal is improved, and the signal detection of the retransmission packet can be improved.
- an interference cancellation unit of the packet reception device 400 can be obtained by assigning more transmission power as the number of packets with smaller number of retransmissions increases.
- 405 can accurately detect signals of a packet with a small number of retransmissions and a signal of an initial transmission packet. Accordingly, the accuracy of removing interference components from the retransmission packet signal based on the initial transmission packet signal is improved, and the signal detection of the retransmission packet can be improved.
- detection processing is performed on a signal from which an interference component due to a retransmission packet having a smaller number of retransmissions than the detected retransmission packet is removed, and detection accuracy of a signal having a large number of retransmissions is improved. It becomes possible to improve.
- the stream signal generation units 301-1 to 301-N of the packet transmission device 300 more packets are assigned by allocating such that signals are transmitted from antennas whose channel eigenvalues in MIMO transmission increase as the number of packets with a smaller number of retransmissions increases.
- the interference canceling unit 405 of the receiving apparatus 400 can accurately detect a packet with a small number of retransmissions and a signal of an initial transmission packet.
- the channel eigenvalue is one of the indices indicating the quality of each stream, obtained by performing singular value decomposition on a matrix whose element is the channel response of each stream transmitted from the transmission antenna. The larger the stream, the higher the quality of the stream that can be transmitted.
- the accuracy of removing interference components from the retransmission packet signal performed based on the signal of the initial transmission packet is improved, and the signal detection of the retransmission packet can be improved. Also, when detecting a retransmission packet, detection processing is performed on a signal from which an interference component due to a retransmission packet having a smaller number of retransmissions than the detected retransmission packet is removed, and detection accuracy of a signal having a large number of retransmissions is improved. It becomes possible to improve.
- each of these parts is constituted by a memory and a CPU (central processing unit), and the function is executed by executing a program for realizing the function of each part. May be realized.
- a program for realizing the above function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read into a computer system and executed to perform processing of each unit.
- the “computer system” includes an OS and hardware such as peripheral devices.
- the “computer-readable recording medium” means a storage device such as a flexible disk, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included.
- the program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.
- the present invention is suitable for use in a mobile communication system including a base station apparatus and a mobile station apparatus, but is not limited to this.
Landscapes
- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Detection And Prevention Of Errors In Transmission (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
Description
本願は、2008年5月15日に、日本に出願された特願2008-128582号に基づき優先権を主張し、その内容をここに援用する。
以下、図面を参照して、本発明の第1の実施形態について説明する。本実施形態では、MC-CDM(Multi Carrier-Code Division Multiplexing:マルチキャリア符号分割多重)方式、および、受信した信号に誤りを検出すると送信元に再送を要求するハイブリッド自動再送HARQを適用したパケット通信システムにおいて、パケット送信装置100が、初送パケットと該初送パケットより以前のいずれかの初送パケットに関する再送パケットとをコード多重した信号を送信し、繰り返し処理を用いた逐次型干渉キャンセラ(SIC:Successive Interference Canceller)を具備したパケット受信装置200が、パケット送信装置100が送信した信号を受信し、コード多重されている信号のうち、初送パケットの信号を優先して、順に信号検出する。なお、再送パケットとは、初送パケットで送信したデータと同一のデータに関して再送されるパケットである。
本実施形態では、パケットを構成する全てのビットは、同じコードチャネルにて送信され、誤り検出符号化部121および誤り訂正符号化部122は、パケット毎に処理を行う。
多重部104は、IFFT部103から出力された時間領域の信号と、再送制御信号生成部108から出力される再送制御信号と、パイロット信号生成部107から出力されたパイロット信号とを多重する。多重部104における多重方法は、時間多重、周波数多重、コード多重などのいずれであってもよい。パイロット信号生成部107は、伝搬路推定に用いるパイロット信号を生成する。再送制御信号生成部108は、各コードチャネルで送信するパケットの信号が何回目の再送であるかをパケット受信装置200に通知するための信号(再送制御信号)を生成する。なお、再送制御信号生成部108が、データ変調方式、拡散率、コード多重数、パンクチャパターンなどの送信パラメータを含む再送制御信号を生成するようにしてもよい。
ただし、jは虚数単位を表す。なお、16QAMなどの他の変調においても、同一の原理でシンボルレプリカを生成することが可能である。
次に、図8を参照して、コードチャネルCH1、CH2、CH3、CH4の順でのコードチャネルを検出、および干渉除去する場合のMCIレプリカ生成部604-1~640-Nおよびコード分離部603-1~603-Nの動作を順に説明する。
ここで、重み係数としては、MMSE(Minimum Mean Square Error: 最小2乗誤差)重み、ORC(Orthogonal Restoration Combi:直交性回復合成)重み、MRC(Maximum Ratio Combining:最大比合成)重みなどを用いることができる。次に、コード分離部603-1の逆拡散部607は、伝搬路補償部601-1からの出力信号に、コードチャネルCH1に固有の拡散符号C1を乗算して逆拡散処理を行い、コードチャネルCH1の信号を検出する。その後、復調部608は、逆拡散部607からの出力信号に対してQPSK、16QAMなどの送信側と同じ変調方式での復調処理を行い、符号化ビットの軟判定結果、例えば、対数尤度比である符号化ビットLLRを算出する。
ここで、図9に示すように、前記合成部210および前記受信信号記憶部209に出力する信号として、前記復号部611の代わりに、デパンクチャ部610の出力信号を前記合成部210および前記受信信号記憶部209に入力することもできる。
以下に説明する、コードチャネルCH2、CH3、CH4に対するMCIレプリカの生成処理では、コードチャネルCH1に対するMCIレプリカの生成処理とは、MCIレプリカ生成部604に入力されるコードチャネルレプリカが異なる。
なお、逐次型の繰り返し干渉キャンセラである上述の干渉キャンセル部208において、i=1の場合、第i-1回目コードチャネルレプリカS^i-1,n=S^0,nは生成できないため、生成可能なi=1のコードチャネルレプリカのみでMCIレプリカを生成する。
また、デインターリーブ部609、デパンクチャ部610は、各々のコードチャネルに対応したパターンに従って処理が行われる。逆拡散部607は、各々のコードチャネル固有の送信時に乗算された拡散符号系列を乗算する。
なお、前記復号部211は、復号部611で代用することも可能である。
第1の実施形態では、ハイブリッド自動再送HARQの初送パケットと再送パケットとが拡散符号によってコード多重され、コード間干渉MCIを繰り返し遂次型干渉キャンセラ(SIC)によって除去する場合について説明した。第2の実施形態では、パケット送信装置300とパケット受信装置400とを備える通信システムであって、パケット送信装置300が送信した初送パケットと再送パケットとがMIMO(Multi Input Multi Output:マルチ入力マルチ出力)を用いて空間多重され、パケット受信装置400は、他ストリームの信号を繰り返し逐次型干渉キャンセラ(SIC)によって除去する通信システムについて説明する。本実施形態では、パケットの伝送方式として、OFDM方式(Orthogonal Frequency Division Multiplexing:直交周波数分割多重)方式を適用した場合で説明する。
パケット送信装置300は、ストリーム信号生成部301-1~301-Ns(ただし、Nsはストリーム数)、アンテナ部302-1~302-Ns、再送制御信号生成部311、復元部312を有し、各パケットを構成する異なる情報ビット系列から生成したN個のストリーム信号を、各アンテナ部302-1~302-Nsから1つずつ送信する。
また、パケット送信装置300は、パケット受信装置400からの応答信号を含む信号を復元する。
なお、本実施形態では、再送パケットは初送パケットと同じストリーム、同じアンテナから送信する場合で説明したが、再送回数毎に異なるアンテナから送信してもよい。以下、パケット受信装置400の説明においても、再送パケットは初送パケットと同じストリーム、同じアンテナから送信されるとして説明する。
パケット受信装置400は、アンテナ部401-1~401-M(ただし、Mは受信アンテナ数)、アンテナ毎信号処理部402-1~4-2-M、受信パケット管理部403、検出順決定部404、干渉キャンセル部405、受信信号記憶部406、合成部407、復号部408、応答信号生成部409を有する。
受信信号記憶部406、合成部407、復号部408は、図6に示す第1の実施形態の受信信号記憶部209、合成部210、復号部211と同様の機能を各部がストリーム数Ns個有しており、ストリーム数Nsの処理を並行して行うが、第1の実施形態における受信信号記憶部209、合成部210、復号部211は、コードチャネル毎に各々の処理を行う点が異なる。また、応答信号生成部409も、第1の実施形態における応答信号生成部212と同様の機能を有す。
ここで、図15に示すように、前記合成部407および前記受信信号記憶部406に出力する信号として、前記復号部1210の代わりに、デパンクチャ部1209の出力信号を前記合成部407および前記受信信号記憶部406に入力することもできる。
なお、上述の逐次型の繰り返し干渉キャンセル処理では、シンボルレプリカ生成部1204-1~1204-Nsは、復号部1210から出力される符号化ビットLLRを用いてシンボルレプリカを生成したが、デパンクチャ部1209から出力される符号化ビットLLRを用いてシンボルレプリカを生成するようにしてもよい。
また、本実施形態では、MIMOで空間多重された信号を受信した場合を示しているが、コード多重および空間多重された信号を受信した場合においても、同様に適用可能で有り、さらに、第1の実施形態のコード多重された信号の検出と本実施形態の空間多重された信号の検出を組み合わせて適用することも可能である。
よって、該初送パケットの信号に基づき行う再送パケットの信号に対する干渉成分の除去の精度も良くなり、再送パケットの信号検出を精度良くすることができる。また、再送パケットを検出する際には、検出する再送パケットより再送回数の小さい再送パケットによる干渉成分が除去された信号に対して検出処理を行うことになり、再送回数が大きい信号の検出精度を良くすることが可能となる。
101-1~101-N…コードチャネル信号生成部
102…コード多重部
103、306…IFFT部
104、307…多重部
105、308…GI挿入部
106、309…送信部
107、310…パイロット信号生成部
108、311…再送制御信号生成部
109、312…復元部
111、303…符号化部
112、304…インターリーブ部
113、305…変調部
114…拡散部
120、302-1~302-Ns…アンテナ部
121…誤り検出符号化部
122…誤り訂正符号化部
123…符号化ビット記憶部
124…パンクチャ部
200、400…パケット受信装置
201、401-1~401-M…アンテナ部
202、411…受信部
203、414…伝搬路推定部
204、412…GI除去部
205、413…FFT部
206、403…受信パケット管理部
207、404…検出順決定部
208、405…干渉キャンセル部
209、406…受信信号記憶部
210、407…合成部
211、408…復号部
212、409…応答信号生成部
301-1~301-Ns…ストリーム信号生成部
402-1~402-M…アンテナ毎信号処理部
601…伝搬路補償部
603-1~603-N…コード分離部
604…MCIレプリカ生成部
605-1~605-N…コードチャネルレプリカ生成部
606、1203…減算部
607…逆拡散部
608、1207…復調部
609、1208…デインターリーブ部
610、1209…デパンクチャ部
611、1210…復号部
621、1211…パンクチャ部
622、1212…インターリーブ部
623、1213…変調シンボルレプリカ生成部
624…拡散部
1201-1~1201-Ns…ストリーム検出部
1202…受信レプリカ生成部
1204-1~1204-Ns…シンボルレプリカ生成部
1205…MIMO分離部
3001、3002…内部符号器
3003…内部インタリーバ
Claims (19)
- 受信した信号に誤りを検出すると送信元に再送を要求するハイブリッド自動再送を行う通信装置において、
初送信号といずれかの信号に対する再送信号とを含む信号であって、前記初送信号と前記再送信号とが多重された信号を受信する受信部と、
前記受信部が受信した信号に含まれる前記初送信号と前記再送信号との初送信号か再送信号かを判定可能な情報に応じて、前記受信部が受信した信号から、前記初送信号と前記再送信号とを検出する順番を決定する検出順決定部と、
前記検出順決定部が決定した順番に従い、当該装置により検出済の信号を用いて、前記受信部が受信した信号から干渉成分を除去して、前記初送信号および前記再送信号を検出する信号検出部と
を具備することを特徴とする通信装置。 - 前記検出順決定部は、前記初送信号の順番が前記再送信号より先になるように検出する順番を決定することを特徴とする請求項1に記載の通信装置。
- 前記検出順決定部は、検出する順番を決定する際に、さらに受信レベルを用いることを特徴とする請求項2に記載の通信装置。
- 前記初送信号および前記再送信号は、送信元において誤り訂正符号化された信号であり、
前記信号検出部は、前記信号を検出する際に、当該装置により検出済の信号を前記誤り訂正符号により誤り訂正復号処理した信号を用いて検出対象としている信号に対する干渉成分のレプリカ信号を生成し、前記受信部が受信した信号から該レプリカ信号を除去することを特徴とする請求項1に記載の通信装置。 - 前記信号検出部は、前記信号を検出する際に、当該信号検出部により検出済の全ての信号を用いて、前記受信部が受信した信号から干渉成分を除去することを特徴とする請求項1に記載の通信装置。
- 前記信号検出部は、前記再送信号を検出する際に、当該信号検出部により検出済の信号のうち、前記初送信号を用いて、前記受信部が受信した信号から干渉成分を除去することを特徴とする請求項1に記載の通信装置。
- 前記受信部が受信する信号は、前記初送信号と前記再送信号とに各々に固有の拡散符号が乗算されたコード多重された信号であり、
前記信号検出部は、前記受信部が受信した信号から干渉成分を除去した後、該干渉成分を除去した信号に、検出対象としている信号に固有の前記拡散符号を乗算して、前記検出対象としている信号を検出することを特徴とする請求項1に記載の通信装置。 - 前記受信部が受信する信号は、前記初送信号と前記再送信号とが各々異なるアンテナから送信されて空間多重された信号であり、
前記信号検出部は、前記受信部が受信した信号から干渉成分を除去した後、前記アンテナ毎の伝搬路推定値に基づいて、該干渉成分を除去した信号から前記検出対象としている信号を検出することを特徴とする請求項1に記載の通信装置。 - 前記信号検出部は、前記検出順決定部が決定した順番に従った前記初送信号および前記再送信号の検出を、各信号について1回ずつ行うことを特徴とする請求項1に記載の通信装置。
- 前記信号検出部は、前記検出順決定部が決定した順番に従った前記初送信号および前記再送信号の検出を、複数回繰り返すことを特徴とする請求項1に記載の通信装置。
- 前記信号検出部は、検出した信号の軟判定値を出力し、
前記信号検出部が出力する軟判定値を記憶する受信信号記憶部と、
前記信号検出部が出力する軟判定値と、前記受信信号記憶部が記憶している軟判定値であって、前記信号検出部が出力する軟判定値の信号の初送信号、または、該初送信号の再送信号の軟判定値とを合成する合成部と
を具備することを特徴とする請求項1に記載の通信装置。 - 前記信号検出部が出力する軟判定値は、復調結果であること
を特徴とする請求項11に記載の通信装置。 - 前記信号検出部が出力する軟判定値は、復号結果であること
を特徴とする請求項11に記載の通信装置。 - 前記初送信号か再送信号かを判定可能な情報は、再送回数を示す情報であることを特徴とする請求項1に記載の通信装置。
- 前記受信部は、再送制御信号を含む受信信号を受信し、
前記初送信号か再送信号かを判定可能な情報は、前記再送制御信号に記載されていることを特徴とする請求項1に記載の通信装置。 - 第1の通信装置と第2の通信装置とを具備し、前記第1の通信装置から受信した信号に誤りを検出すると、前記第2の通信装置が前記第1の通信装置に再送を要求するハイブリッド自動再送を行う通信システムにおいて、
前記第2の通信装置は、
初送信号といずれかの信号に対する再送信号とを含む信号であって、前記初送信号と前記再送信号とが多重された信号を受信する受信部と、
前記受信部が受信した信号に含まれる前記初送信号と前記再送信号との初送信号か再送信号かを判定可能な情報に応じて、前記受信部が受信した信号から、前記初送信号と前記再送信号とを検出する順番を決定する検出順決定部と、
前記検出順決定部が決定した順番に従い、当該装置により検出済の信号を用いて、前記受信部が受信した信号から干渉成分を除去して、前記初送信号および前記再送信号を検出する信号検出部と
を具備することを特徴とする通信システム。 - 前記初送信号および前記再送信号は、誤り訂正符号化された情報の信号であり、
前記信号検出部は、前記信号を検出する際に、当該装置により検出済の信号を前記誤り訂正符号により誤り訂正復号処理した信号を用いて検出対象としている信号に対する干渉成分のレプリカ信号を生成し、前記受信部が受信した信号から該レプリカ信号を除去すること
を特徴とする請求項16に記載の通信システム。 - 受信した信号に誤りを検出すると送信元に再送を要求するハイブリッド自動再送を行う通信装置における受信方法において、
前記通信装置が、初送信号といずれかの信号に対する再送信号とを含む信号であって、前記初送信号と前記再送信号とが多重された信号を受信する第1の過程と、
前記通信装置が、前記第1の過程にて受信した信号に含まれる前記初送信号と前記再送信号との初送信号か再送信号かを判定可能な情報に応じて、前記第1の過程にて受信した信号から、前記初送信号と前記再送信号とを検出する順番を決定する第2の過程と
前記通信装置が、前記第2の過程にて決定した順番に従い、当該通信装置により検出済の信号を用いて、前記第1に過程にて受信した信号から干渉成分を除去して、前記初送信号および前記再送信号を検出する第3の過程と
を具備することを特徴とする受信方法。 - 第1の通信装置と第2の通信装置とを具備し、前記第1の通信装置から受信した信号に誤りを検出すると、前記第2の通信装置が前記第1の通信装置に再送を要求するハイブリッド自動再送を行う通信システムにおける通信方法において、
前記第1の通信装置が、初送信号といずれかの信号に対する再送信号とを送信する第1の過程と、
前記第2の通信装置が、前記第1の過程にて送信された信号であって、前記初送信号と前記再送信号とが多重された信号を受信する第2の過程と、
前記第2の通信装置が、前記第2の過程にて受信した信号に含まれる前記初送信号と前記再送信号との初送信号か再送信号かを判定可能な情報に応じて、前記第2の過程にて受信した信号から、前記初送信号と前記再送信号とを検出する順番を決定する第3の過程と、
前記第2の通信装置が、前記第3の過程にて決定した順番に従い、当該第2の通信装置により検出済の信号を用いて、前記第2の過程にて受信した信号から干渉成分を除去して、前記初送信号および前記再送信号を検出する第4の過程と
を備えることを特徴とする通信方法。
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP09746648A EP2278739A1 (en) | 2008-05-15 | 2009-05-14 | Communication device, communication system, reception method, and communication method |
US12/991,935 US8381060B2 (en) | 2008-05-15 | 2009-05-14 | Communication device, communication system, reception method, and communication method |
JP2010512016A JPWO2009139442A1 (ja) | 2008-05-15 | 2009-05-14 | 通信装置、通信システム、受信方法及び通信方法 |
CN2009801170469A CN102027703A (zh) | 2008-05-15 | 2009-05-14 | 通信装置、通信系统、接收方法和通信方法 |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2008128582 | 2008-05-15 | ||
JP2008-128582 | 2008-05-15 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2009139442A1 true WO2009139442A1 (ja) | 2009-11-19 |
Family
ID=41318805
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/JP2009/058997 WO2009139442A1 (ja) | 2008-05-15 | 2009-05-14 | 通信装置、通信システム、受信方法及び通信方法 |
Country Status (5)
Country | Link |
---|---|
US (1) | US8381060B2 (ja) |
EP (1) | EP2278739A1 (ja) |
JP (1) | JPWO2009139442A1 (ja) |
CN (1) | CN102027703A (ja) |
WO (1) | WO2009139442A1 (ja) |
Families Citing this family (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20080316004A1 (en) * | 2007-06-19 | 2008-12-25 | Kiko Frederick J | Powerline communication apparatus and methods |
US8423863B2 (en) * | 2009-11-06 | 2013-04-16 | Electronics And Telecommunications Research Institute | Terminal transmission apparatus for providing multimedia service via satellite communication link and method for providing multimedia service using the same |
US8230310B2 (en) * | 2010-01-15 | 2012-07-24 | Telefonaktiebolaget Lm Ericsson | Method and apparatus for received signal processing in a wireless communication receiver |
US9066249B2 (en) * | 2012-03-07 | 2015-06-23 | Apple Inc. | Methods and apparatus for interference coordinated transmission and reception in wireless networks |
GB2503418A (en) * | 2012-04-27 | 2014-01-01 | Imp Innovations Ltd | Spreading data symbols using a number of signature sequences selected in accordance with system values indicative of signal-to-noise ratios |
US9258215B2 (en) * | 2013-01-02 | 2016-02-09 | Infinera Corporation | Optical layer protection switching applications |
CN103246261A (zh) * | 2013-04-22 | 2013-08-14 | 深圳华中数控有限公司 | 一种使用Android终端控制机械设备的系统及方法 |
US8837515B1 (en) | 2013-06-06 | 2014-09-16 | Futurewei Technologies, Inc. | System and method for collision resolution |
US9215017B2 (en) * | 2013-06-18 | 2015-12-15 | Samsung Electronics Co., Ltd. | Computing system with decoding sequence mechanism and method of operation thereof |
CN104426641B (zh) * | 2013-09-11 | 2019-01-11 | 松下知识产权经营株式会社 | 通信控制装置及通信控制方法 |
JP2016025649A (ja) * | 2014-07-24 | 2016-02-08 | 富士通株式会社 | 電子装置及び機器検知方法 |
JP2016046618A (ja) | 2014-08-21 | 2016-04-04 | ソニー株式会社 | 信号処理装置および方法、並びに、プログラム |
US11108894B2 (en) * | 2019-08-09 | 2021-08-31 | Microsoft Technology Licensing, Llc | Masked packet checksums for more efficient digital communication |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2000151504A (ja) * | 1998-11-18 | 2000-05-30 | Nec Saitama Ltd | 基地局無線装置及びその制御方法 |
JP2001189671A (ja) * | 1999-12-28 | 2001-07-10 | Matsushita Electric Ind Co Ltd | 干渉信号除去装置および干渉信号除去方法 |
JP2003008549A (ja) * | 2001-06-20 | 2003-01-10 | Mitsubishi Electric Corp | Cdma受信機 |
JP2007028054A (ja) * | 2005-07-14 | 2007-02-01 | Matsushita Electric Ind Co Ltd | 干渉キャンセル装置および干渉キャンセル方法 |
JP2007184926A (ja) * | 2005-12-29 | 2007-07-19 | Ntt Docomo Inc | Arq機能を有する部分並列干渉キャンセル方法及び受信機 |
JP2008128582A (ja) | 2006-11-22 | 2008-06-05 | Fujitsu General Ltd | 空気調和機 |
WO2008099919A1 (ja) * | 2007-02-16 | 2008-08-21 | Sharp Kabushiki Kaisha | 無線受信装置、無線通信システム、無線通信方法およびプログラム |
Family Cites Families (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CA2395190C (en) * | 2000-10-21 | 2007-09-25 | Samsung Electronics Co., Ltd. | Harq device and method for mobile communication system |
KR100464325B1 (ko) * | 2001-10-15 | 2005-01-03 | 삼성전자주식회사 | 이동통신시스템에서 패킷 재전송을 위한 송수신 장치 및 방법 |
US7447968B2 (en) * | 2002-04-24 | 2008-11-04 | Samsung Electronics, Co., Ltd. | Apparatus and method for supporting automatic repeat request in a high-speed wireless packet data communication system |
JP3679089B2 (ja) * | 2002-11-20 | 2005-08-03 | 松下電器産業株式会社 | 基地局装置および再送パケットの送信電力制御方法 |
CN1790976A (zh) * | 2004-12-17 | 2006-06-21 | 松下电器产业株式会社 | 用于多天线传输中的重传方法 |
CN1972176A (zh) | 2005-11-24 | 2007-05-30 | 松下电器产业株式会社 | 多天线通信系统中重传数据的检测方法 |
US7730382B2 (en) * | 2005-12-02 | 2010-06-01 | Beceem Communications Inc. | Method and system for managing memory in a communication system using hybrid automatic repeat request (HARQ) |
JP5177892B2 (ja) | 2007-01-29 | 2013-04-10 | パナソニック株式会社 | 無線通信システム、無線通信装置及び再送制御方法 |
US20100238818A1 (en) | 2007-10-11 | 2010-09-23 | Panasonic Corporation | Wireless communication mobile station apparatus and communication quality information generating method |
-
2009
- 2009-05-14 US US12/991,935 patent/US8381060B2/en active Active
- 2009-05-14 WO PCT/JP2009/058997 patent/WO2009139442A1/ja active Application Filing
- 2009-05-14 EP EP09746648A patent/EP2278739A1/en not_active Withdrawn
- 2009-05-14 CN CN2009801170469A patent/CN102027703A/zh active Pending
- 2009-05-14 JP JP2010512016A patent/JPWO2009139442A1/ja active Pending
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2000151504A (ja) * | 1998-11-18 | 2000-05-30 | Nec Saitama Ltd | 基地局無線装置及びその制御方法 |
JP2001189671A (ja) * | 1999-12-28 | 2001-07-10 | Matsushita Electric Ind Co Ltd | 干渉信号除去装置および干渉信号除去方法 |
JP2003008549A (ja) * | 2001-06-20 | 2003-01-10 | Mitsubishi Electric Corp | Cdma受信機 |
JP2007028054A (ja) * | 2005-07-14 | 2007-02-01 | Matsushita Electric Ind Co Ltd | 干渉キャンセル装置および干渉キャンセル方法 |
JP2007184926A (ja) * | 2005-12-29 | 2007-07-19 | Ntt Docomo Inc | Arq機能を有する部分並列干渉キャンセル方法及び受信機 |
JP2008128582A (ja) | 2006-11-22 | 2008-06-05 | Fujitsu General Ltd | 空気調和機 |
WO2008099919A1 (ja) * | 2007-02-16 | 2008-08-21 | Sharp Kabushiki Kaisha | 無線受信装置、無線通信システム、無線通信方法およびプログラム |
Non-Patent Citations (4)
Title |
---|
AKITA; SUYAMA; FUKAWA; SUZUKI: "Interference Canceller in Downlink Using Transmission Power Control of MC-CDMA", THE INSTITUTE OF ELECTRONICS, INFORMATION AND COMMUNICATION ENGINEERS, April 2002 (2002-04-01) |
D. CHASE: "Code combining-A maximum likelihood decoding approach for combining and arbitrary number of noisy packets", IEEE TRANS. COMMUN., vol. COM-33, May 1985 (1985-05-01), pages 385 - 393 |
ISHIHARA; TAKEDA; ADACHI: "DS-CDMA Frequency Domain MAI Canceller", THE INSTITUTE OF ELECTRONICS, INFORMATION AND COMMUNICATION ENGINEERS, January 2005 (2005-01-01) |
J. HAGENAUER: "Rate-compatible punctured convolutional codes (RCPC codes) and their application", IEEE TRANS. COMMUN., vol. 36, April 1988 (1988-04-01), pages 389 - 400 |
Also Published As
Publication number | Publication date |
---|---|
US8381060B2 (en) | 2013-02-19 |
CN102027703A (zh) | 2011-04-20 |
US20110066911A1 (en) | 2011-03-17 |
JPWO2009139442A1 (ja) | 2011-09-22 |
EP2278739A1 (en) | 2011-01-26 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
WO2010005037A1 (ja) | 通信装置、通信システム、受信方法及び通信方法 | |
WO2009139442A1 (ja) | 通信装置、通信システム、受信方法及び通信方法 | |
JP5213271B2 (ja) | 通信装置、通信システム、受信方法およびプログラム | |
JP5376243B2 (ja) | 通信装置、通信システム、受信方法および通信方法 | |
WO2009131094A1 (ja) | 通信装置、通信システム、受信方法およびプログラム | |
WO2009104582A1 (ja) | 受信装置、送信装置、通信システム及び通信方法 | |
US20100325510A1 (en) | Transmission device, reception device, communication system, and communication method | |
JP5013617B2 (ja) | 通信装置、通信システムおよび受信方法 | |
Bai et al. | Hybrid-ARQ for layered space time MIMO systems with channel state information only at the receiver | |
JP5376244B2 (ja) | 通信装置、通信システム、受信方法及び通信方法 | |
JP4631053B2 (ja) | 再送装置及び再送方法 | |
JP5036062B2 (ja) | 通信装置、通信システムおよび通信方法 | |
JP2010050716A (ja) | 通信装置、通信システム及び通信方法 | |
RU2369021C2 (ru) | Передача с инкрементной избыточностью в системе связи mimo |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
WWE | Wipo information: entry into national phase |
Ref document number: 200980117046.9 Country of ref document: CN |
|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 09746648 Country of ref document: EP Kind code of ref document: A1 |
|
WWE | Wipo information: entry into national phase |
Ref document number: 2010512016 Country of ref document: JP |
|
WWE | Wipo information: entry into national phase |
Ref document number: 12991935 Country of ref document: US Ref document number: 2009746648 Country of ref document: EP |
|
NENP | Non-entry into the national phase |
Ref country code: DE |