JP5724565B2 - Reception method and receiver - Google Patents

Description

  The present invention relates to a reception method and a receiver, and more particularly, to a reception method and a receiver that perform interference cancellation processing of a radio signal.

  In recent years, MIMO (Multiple Input Multiple Output) technology has attracted attention in wireless communication systems, and SIC (Successive Interference Cancellation) is known as a countermeasure against such system interference. A receiver using the SIC method is described in Patent Document 1.

  FIG. 8 shows a configuration of a receiver using the SIC method in a related wireless communication system. Although FIG. 8 shows a case where one transmitter 700 and one receiver 701 exist as an example, a plurality of transmitters 700 actually exist.

  The transmitter 700 transmits a time-domain transmission signal obtained by multiplexing the reference signal and the user data signal to the receiver 701.

  The receiver 701 includes an A / D conversion unit 702, an FFT unit 703, a subcarrier extraction unit 704, an interference removal unit 705, a demodulation unit 706, a decoding unit 707, and an interference replica generation unit 708.

  The A / D converter 702 receives a time domain transmission signal in which a reference signal and a user data signal are multiplexed from the transmitter 700 as a received signal in a time domain affected by a propagation path or the like. The input reception signal in the time domain is converted into a digital signal. The converted reception signal in the time domain is output to FFT section 703.

  The FFT unit 703 receives the time domain received signal from the A / D conversion unit 702. The input time domain received signal is subjected to FFT processing and converted to a frequency domain received signal. The frequency domain received signal is output to subcarrier extraction section 704.

  The subcarrier extraction unit 704 receives the frequency domain received signal from the FFT unit 703. A subcarrier in which a reference signal and a user data signal are multiplexed is extracted from the received frequency domain received signal. The extracted user data signal is output to the interference removal unit 705, and the extracted reference signal is output to the demodulation unit 706.

  The interference removal unit 705 receives the user data signal from the subcarrier extraction unit 704 and receives the interference replica signal from the interference replica generation unit 708. The interference removal unit 705 is executed only “number of interference removals + 1” times, and the number of interference removals is fixedly given as a parameter. The interference is removed by subtracting the input interference replica signal from the user data signal, and the user data signal after interference removal is generated. However, in the first case, since there is no interference replica signal and interference cannot be removed, the input user data signal is treated as user data after interference removal. The user data signal after interference removal is output to demodulation section 706.

  Demodulation section 706 receives a reference signal from subcarrier extraction section 704 and receives a user data signal after interference removal from interference removal section 705. The demodulator 706 is executed only “interference removal count + 1” times. The user data signal after interference removal is equalized using the input reference signal, so that distortion caused by the propagation path and the like is removed from the user data signal after interference removal and a user data signal after equalization is generated. The The generated equalized user data signal is output to the decoding unit 707.

  The decoding unit 707 receives the equalized user data signal from the demodulation unit 706. The decoding unit 707 is executed only “interference removal count + 1” times. By decoding the input equalized user data signal, a decoded user data signal is generated. The generated decoded user data signal is output to interference replica generation section 708.

  The interference replica generation unit 708 receives the decoded user data signal from the decoding unit 707. The interference replica generation unit 708 is executed for “interference removal count”. Using the input decoded user data signal, an interference replica signal corresponding to an interference component included in the frequency domain received signal is generated. The generated interference replica signal is output to the interference removal unit 705.

  Patent Documents 2 and 3 are known as receivers of related wireless communication systems. In Patent Document 2, the number of repetitions of interference cancellation is controlled according to the propagation path state before error correction coding. In Patent Document 3, one interference cancellation process is performed based on a checksum determination result such as CRC. Controls the execution of interference cancellation.

JP 2010-130205 A JP 2009-302766 A JP 2008-537436 A

  In the related receiver as shown in FIG. 8, since the number of interference cancellations is set to be fixed, when interference cancellation becomes unnecessary before the fixed number of interference cancellations is reached, processing for extra interference cancellation occurs. As a result, there is a problem in that processing delay occurs and power consumption of the apparatus is required.

  In addition, in the related receiver as in Patent Document 2, although the number of repetitions of interference cancellation is controlled according to the propagation path state before error correction coding, the processing after error correction is not considered, Depending on the error correction capability, the number of interference cancellations may not be optimized and the processing speed may not be improved. Also, in a related receiver such as Patent Document 3, a checksum such as CRC is used for one interference cancellation process. Although the execution of interference cancellation is controlled based on the determination result, the user data signal confidence after error correction is not taken into consideration, and the repetition of interference cancellation processing is not supported, so the number of interference cancellation cannot be optimized. There was a problem that the speed could not be improved.

(Object of the present invention)
The objective of this invention is providing the receiving method and receiver which solve the subject mentioned above.

  The reception method of the present invention is a reception method in a receiver that receives a radio signal from a transmitter, and performs interference removal processing to remove interference on an input signal based on the received radio signal, and the interference A decision decoding process for decoding the removed signal and generating decision decoding information is performed, and the interference decision process and the decision decoding process are repeated by further inputting the generated decision decoding information to the interference removal process, The number of executions of the interference removal process is controlled based on a plurality of pieces of determination decoding information generated by the repetition.

  The receiver of the present invention is a receiver that receives a radio signal from a transmitter, and performs an interference removal processing unit that performs interference removal processing to remove interference on an input signal based on the received radio signal. A determination decoding processing unit that performs a determination decoding process that decodes the interference-removed signal and generates determination decoding information, and further inputs the generated determination decoding information to the interference cancellation process. And a repetition control unit that controls the number of times the interference removal processing is executed based on a plurality of pieces of determination decoding information generated by the repetition while repeating the determination decoding processing.

  According to the present invention, it is possible to provide a receiving method and a receiver that optimize the number of times of interference cancellation and reduce processing time and power consumption.

It is a block diagram which shows an example of a structure of the receiver in the radio | wireless communications system by this invention. It is a block diagram which shows the structure of the receiver in the radio | wireless communications system by the 1st Embodiment of this invention. 3 is a flowchart illustrating an operation of a receiver in the wireless communication system according to the first embodiment of the present invention. It is a block diagram which shows the structure of the receiver in the radio | wireless communications system by the 2nd Embodiment of this invention. 6 is a flowchart illustrating an operation of a receiver in the wireless communication system according to the second embodiment of the present invention. It is a block diagram which shows the structure of the receiver in the radio | wireless communications system by the 3rd Embodiment of this invention. 7 is a flowchart illustrating an operation of a receiver in a wireless communication system according to a third embodiment of the present invention. It is a block diagram which shows the structure of the receiver in a related radio | wireless communications system.

(Features of the present invention)
Prior to the description of the embodiments of the present invention, an outline of the features of the present invention will be described first.

  As shown in FIG. 1, the receiver 11 of the present invention includes an interference removal processing unit 12, a determination decoding processing unit 13, and an iterative control unit 14. Then, the interference removal processing unit 12 removes interference with respect to the input signal based on the radio signal received from the transmitter 10, and the determination decoding processing unit 13 decodes the interference-removed signal and generates determination decoding information. Then, the iterative control unit 14 further inputs the generated determination decoding information to the interference cancellation processing unit 12 to repeat the interference removal processing and the determination decoding processing, and performs interference based on the plurality of repeatedly generated determination decoding information. Controlling the number of times the removal process is executed is a main feature of the present invention.

  For example, the determination decoding information is a post-demodulation user data signal generated by the demodulation processing by the determination decoding processing unit 13 or a decoded data signal generated by the decoding processing. Further, for example, in the control of the number of executions of the interference removal process, the execution number is controlled by stopping the execution of the interference removal process when it is determined that the interference removal process is unnecessary based on the determination decoding information.

  In other words, in the present invention, the number of repetitions of interference removal processing is controlled according to determination decoding information such as a plurality of decoded user data signals and demodulated user data signals repeatedly generated by the determination decoding processing unit 13. Therefore, the number of execution times of the interference removal process is optimized, the processing time is shortened, and the power consumption of the apparatus is reduced.

(First embodiment of the present invention)
Next, a first embodiment of the present invention will be described in detail with reference to FIGS.

  FIG. 2 is a block diagram showing a configuration of a receiver using the SIC method in the wireless communication system according to the first embodiment of the present invention. The wireless communication system has one transmitter 100 and one receiver 101.

  The transmitter 100 transmits a transmission signal in a time domain obtained by multiplexing the reference signal and the user data signal to the receiver 101.

  The receiver 101 includes an A / D conversion unit 102, an FFT unit 103, a subcarrier extraction unit 104, an interference removal unit 105, a demodulation unit 106, a decoding unit 107, a soft decision bit check unit 108, and an interference replica generation unit 109. The correspondence relationship with FIG. 1 will be described. The interference replica generation unit 109 and the interference removal unit 105 correspond to the interference removal processing unit 12, and the demodulation unit 106 and the decoding unit 107 correspond to the determination decoding processing unit 13. The determination bit inspection unit 108 corresponds to the repetition control unit 14. Further, in the following description, execution of interference removal and the like is controlled by setting and notification of interference removal execution information, but for example, interference removal execution information is stored in a storage unit (not shown), and the interference removal execution information is stored. By acquiring from the storage unit, it is possible to set and notify the interference removal execution information.

  The A / D converter 102 receives a time domain transmission signal in which a reference signal and a user data signal are multiplexed from the transmitter 100 as a received signal in the time domain affected by a propagation path or the like. The input reception signal in the time domain is converted into a digital signal. The converted time domain received signal is output to FFT section 103.

  The FFT unit 103 receives the time domain received signal from the A / D conversion unit 102. The input time domain received signal is subjected to FFT processing and converted to a frequency domain received signal. The frequency domain received signal is output to subcarrier extraction section 104.

  The subcarrier extraction unit 104 receives the frequency domain received signal from the FFT unit 103. A subcarrier in which a reference signal and a user data signal are multiplexed is extracted from the received frequency domain received signal. The extracted user data signal is output to the interference removal unit 105, and the extracted reference signal is output to the demodulation unit 106.

  The interference removal unit 105 receives the user data signal from the subcarrier extraction unit 104, receives the interference replica signal from the interference replica generation unit 109, and receives interference removal execution information from the soft decision bit inspection unit 108. When the notified interference removal execution information indicates cancellation, the interference removal unit 105 does not operate. On the other hand, when the notified interference removal execution information indicates execution, interference removal is performed by subtracting the input interference replica signal from the user data signal, and a user data signal after interference removal is generated. However, it is always executed in the case of the first operation, and the input user data signal is handled as user data after interference removal. The generated interference-removed user data signal is output to demodulation section 106.

  Demodulation section 106 receives a reference signal from subcarrier extraction section 104, receives a user data signal after interference removal from interference cancellation section 105, and receives interference cancellation execution information from soft decision bit inspection section 108. When the notified interference removal execution information indicates cancellation, the demodulation unit 106 does not operate. On the other hand, when the notified interference removal execution information indicates execution, the user data signal after interference removal is equalized using the input reference signal, resulting in the propagation path from the user data signal after interference removal. And the equalized user data signal is generated. However, it is always executed in the first operation. The generated equalized user data signal is output to the decoding unit 107.

  Decoding section 107 receives the equalized user data signal from demodulation section 106 and receives interference removal execution information from soft decision bit inspection section 108. When the notified interference removal execution information indicates cancellation, the decoding unit 107 does not operate. On the other hand, when the notified interference removal execution information indicates execution, a decoded user data signal is generated by decoding the input post-equalization user data signal. However, it is always executed in the first operation. The generated decoded user data signal is output to soft decision bit inspection section 108 and interference replica generation section 109.

  Soft-decision bit inspection unit 108 receives the decoded user data signal from decoding unit 107. The input decrypted user data is stored. If the input decoded user data signal includes a parity bit such as CRC and the parity bit check result is OK, it is determined that the next interference cancellation processing is to be stopped, and interference cancellation execution information is obtained. Is set to cancel. On the other hand, when the input decoded user data signal includes a parity bit and the parity bit check result is NG, or when the input decoded user data signal does not include a parity bit, the following processing is performed. Execute.

That is, in the case of the first interference removal process, the interference removal execution information is set to execute. In the second and subsequent interference removal processing, the old decoded user data signal held is compared with the input new decoded user data signal bit pattern, the number of different bit patterns is counted, and the soft decision bit difference N _SOFT (s) is obtained. Here, the variable s indicates the interference removal number (positive integer). For example, the soft-decision bit check unit 108 sequentially stores the decoded user data signal repeatedly generated by the decoding unit 107 and the demodulated user data signal repeatedly generated by the demodulation unit 106 in a storage unit (not shown). Then, the current signal newly generated by the iterative process of the decoding unit 107 is compared with the previous signal generated previously. Further, when N _SOFT (s) ≧ Thr _SOFT (s) is not satisfied with respect to the soft decision interference removal judgment threshold Thr _SOFT (s) given as a parameter, it is determined that the next interference removal processing is to be stopped, and interference removal is performed. Set execution information to cancel. On the other hand, when N _SOFT (s) ≧ Thr _SOFT (s), it is determined that the next interference removal processing is executed, and the interference removal execution information is set to be executed. The interference judgment threshold value Thr _SOFT (s) for soft judgment can be corrected by the following equation 1.

Here, Coef _SOFT (s) is a real number that can be set according to the error correction coding rate of the user data signal. In other words, the threshold is weighted by the error correction coding rate. The interference removal execution information is notified to the interference removal unit 105, the demodulation unit 106, the decoding unit 107, and the interference replica generation unit 109.

  The interference replica generation unit 109 receives the decoded user data signal from the decoding unit 107 and receives interference removal execution information from the soft decision bit inspection unit 108. When the notified interference removal execution information indicates cancellation, the interference replica unit 109 does not operate. On the other hand, when the notified interference removal execution information indicates execution, an interference replica signal corresponding to an interference component included in the frequency domain user data signal is generated using the input decoded user data signal. However, it is always executed in the first operation. The generated interference replica signal is output to the interference removal unit 105.

  Next, the operation of the first embodiment of the present invention will be described. In the following description, processing for the receiver 101 in the wireless communication system will be described when there is one transmitter 100 and one receiver 101 as an example.

  FIG. 3 is a flowchart showing the operation of the receiver 101 in the present invention. Hereinafter, reception processing in the receiver 101 will be described with reference to FIG.

  First, the receiver 101 receives a time-domain transmission signal in which a reference signal and a user data signal transmitted from the transmitter 100 are multiplexed (step 200).

  Next, the A / D conversion unit 102 converts the received signal in the time domain into a digital signal by A / D conversion (step 201), and the FFT unit 103 performs FFT processing on the received signal in the time domain and converts it into the frequency domain. Then (step 202), the subcarrier extraction unit 104 extracts a reference signal and a user data signal from the frequency domain received signal (step 203).

  Next, in the case of the initial processing, the interference removal unit 105 outputs the input user data signal as it is (step 204). If it is not the first process, the interference component is removed from the user data signal using the interference replica signal (step 205).

  Next, the demodulation unit 106 equalizes the user data signal after interference removal using the reference signal (Step 206), and the decoding unit 107 decodes the user data signal after equalization (Step 207).

  Next, the soft decision bit check unit 108 stores the decoded user data signal (step 208). If the decoded user data signal includes a parity bit and the parity bit check result is OK, the interference removal execution information is set to stop and the process ends (steps 209 and 213). If the decoded user data signal includes a parity bit and the parity bit check result is NG, or if the input decoded user data signal does not include a parity bit, the process of the next step 210 Is executed (step 209).

That is, in the case of the initial process, the interference removal execution information is set to execute (step 210, step 214). If it is not the initial process, the number of different bit patterns of the stored old decoded user data signal and the new decoded user data signal is counted to obtain the soft decision bit difference N _SOFT (s) (step 211). . Then, the soft decision bit difference N _SOFT (s) is compared with the soft decision interference removal decision threshold Thr _SOFT (s) (step 212). If N _SOFT (s) ≧ Thr _SOFT (s) is not satisfied, interference removal is performed. The information is set to stop, and the process is terminated (step 213). If N _SOFT (s) ≧ Thr _SOFT (s), the interference removal execution information is set to execution (step 214).

  Next, the interference replica generation unit 109 generates an interference replica signal from the decoded user data signal (step 215), and repeats the processing of the interference removal unit 105 (step 204) and subsequent steps.

  As described above, in the first embodiment of the present invention, based on the decoded user data signal, in particular, the decoded user data signal in the old interference cancellation process and the decoded user data signal in the new interference cancellation process, or By controlling the execution of the interference cancellation process based on the check result of the parity bit included in the decoded user data signal, the number of interference cancellations can be determined adaptively. Therefore, the number of interference removals required by the receiver can be grasped, and the number of interference removal processes can be optimized, thereby shortening the processing time and power consumption.

  In addition, it effectively eliminates interference by comparing the number of different bit patterns of the decoded user data signal newly generated by repetition and the previously generated decoded user data signal with the interference removal determination threshold. The number of executions of processing can be controlled. Furthermore, since the threshold value dynamically fluctuates by weighting the interference removal determination threshold value with the error correction coding rate, the number of times of performing the interference removal process can be controlled with higher accuracy.

(Second embodiment of the present invention)
Next, a second embodiment of the present invention will be described in detail with reference to FIGS.

  FIG. 4 is a block diagram showing a configuration of a receiver using the SIC method in the wireless communication system according to the second embodiment of the present invention. The wireless communication system has one transmitter 300 and one receiver 301.

  The transmitter 300 transmits to the receiver 301 a time domain transmission signal obtained by multiplexing the reference signal and the user data signal.

  The receiver 301 includes an A / D conversion unit 302, an FFT unit 303, a subcarrier extraction unit 304, an interference removal unit 305, a demodulation unit 306, a decoding unit 307, a hard decision bit inspection unit 308, and an interference replica generation unit 309. The correspondence relationship with FIG. 1 will be described. The interference replica generation unit 309 and the interference removal unit 305 correspond to the interference removal processing unit 12, the demodulation unit 306 and the decoding unit 307 correspond to the determination decoding processing unit 13, and the hard The determination bit inspection unit 308 corresponds to the repetition control unit 14.

  The A / D converter 302 receives a time domain transmission signal in which a reference signal and a user data signal are multiplexed from the transmitter 300 as a received signal in the time domain affected by a propagation path or the like. The input reception signal in the time domain is converted into a digital signal. The converted reception signal in the time domain is output to FFT section 303.

  The FFT unit 303 receives the time domain received signal from the A / D conversion unit 302. The input time domain received signal is subjected to FFT processing and converted to a frequency domain received signal. The frequency domain received signal is output to subcarrier extraction section 304.

  The subcarrier extraction unit 304 receives the frequency domain received signal from the FFT unit 303. A subcarrier in which a reference signal and a user data signal are multiplexed is extracted from the received frequency domain received signal. The extracted user data signal is output to the interference removal unit 305, and the extracted reference signal is output to the demodulation unit 306.

  The interference removal unit 305 receives the user data signal from the subcarrier extraction unit 304, receives the interference replica signal from the interference replica generation unit 309, and receives interference removal execution information from the hard decision bit inspection unit 308. When the notified interference removal execution information indicates cancellation, the interference removal unit 305 does not operate. On the other hand, when the notified interference removal execution information indicates execution, interference removal is performed by subtracting the input interference replica signal from the user data signal, and a user data signal after interference removal is generated. However, it is always executed in the case of the first operation, and the input user data signal is handled as user data after interference removal. The generated user data signal after interference cancellation is output to demodulation section 306.

  Demodulation section 306 receives a reference signal from subcarrier extraction section 304, receives a user data signal after interference removal from interference cancellation section 305, and receives interference cancellation execution information from hard decision bit inspection section 308. When the notified interference removal execution information indicates cancellation, the demodulation unit 306 does not operate. On the other hand, when the notified interference removal execution information indicates execution, the user data signal after interference removal is equalized using the input reference signal, resulting in the propagation path from the user data signal after interference removal. And the equalized user data signal is generated. However, it is always executed in the first operation. The generated equalized user data signal is output to the decoding unit 307 and the hard decision bit inspection unit 308.

  The decoding unit 307 receives the equalized user data signal from the demodulation unit 306 and is notified of interference removal execution information from the hard decision bit inspection unit 308. When the notified interference removal execution information indicates cancellation, the decoding unit 307 does not operate. On the other hand, when the notified interference removal execution information indicates execution, a decoded user data signal is generated by decoding the input post-equalization user data signal. However, it is always executed in the first operation. The generated decoded user data signal is output to hard decision bit inspection section 308 and interference replica generation section 309.

  The hard decision bit inspection unit 308 receives the equalized user data signal from the demodulation unit 306 and the decoded user data signal from the decoding unit 307. The input equalized user data and the decoded user data signal are stored. If the input decoded user data signal includes a parity bit such as CRC and the parity bit check result is OK, it is determined that the next interference cancellation processing is to be stopped, and interference cancellation execution information is obtained. Is set to cancel. On the other hand, when the input decoded user data signal includes a parity bit and the parity bit check result is NG, or when the input decoded user data signal does not include a parity bit, the following processing is performed. Execute.

That is, in the case of the first interference removal process, the interference removal execution information is set to execute. In the case of the second and subsequent interference removal processing, the hard decision difference average is obtained by averaging the dispersion value (difference) for each bit of the held old post-equalization user data signal and the input new post-equalization user data signal. The value Avg _HARD (s) is obtained. Here, when it is not Avg _HARD (s) ≧ Thr _HARD (s) with respect to the interference determination threshold value Thr _HARD (s) for hard decision given as a parameter, it is determined that the next interference removal process is stopped, and interference Set removal execution information to abort. On the other hand, when Avg _HARD (s) ≧ Thr _HARD (s), it is determined that the next interference removal process is executed, and the interference removal execution information is set to be executed. The hard decision interference removal decision threshold Thr _HARD (s) can be corrected by the following equation 2.

Here, Coef _HARD (s) is a real number that can be set according to the reception state estimated from the reference signal. That is, the threshold is weighted according to the reception state estimated from the reference signal. The interference removal execution information is notified to the interference removal unit 305, the demodulation unit 306, the decoding unit 307, and the interference replica generation unit 309.

  The interference replica generation unit 309 receives the decoded user data signal from the decoding unit 307 and receives interference removal execution information from the hard decision bit inspection unit 308. When the notified interference removal execution information indicates cancellation, the interference replica unit 309 does not operate. On the other hand, when the notified interference removal execution information indicates execution, an interference replica signal corresponding to an interference component included in the frequency domain user data signal is generated using the input decoded user data signal. However, it is always executed in the first operation. The generated interference replica signal is output to the interference removal unit 305.

  Next, the operation of the second exemplary embodiment of the present invention will be described. In the following description, a process for the receiver 301 in the wireless communication system will be described when there is one transmitter 300 and one receiver 301 as an example.

  FIG. 5 is a flowchart showing the operation of the receiver 301 in the present invention. Hereinafter, the reception process in the receiver 301 will be described with reference to FIG.

  First, the receiver 301 receives a time-domain transmission signal in which a reference signal and a user data signal transmitted from the transmitter 300 are multiplexed (step 400).

  Next, the A / D conversion unit 302 converts the received signal in the time domain into a digital signal by A / D conversion (step 401), and the FFT unit 303 performs FFT processing on the received signal in the time domain and converts it into the frequency domain. (Step 402), the subcarrier extraction unit 304 extracts the reference signal and the user data signal from the frequency domain received signal (Step 403).

  Next, in the case of the initial processing, the interference removal unit 305 outputs the input user data signal as it is (step 404). If it is not the first process, the interference component is removed from the user data signal using the interference replica signal (step 405).

  Next, the demodulator 306 equalizes the user data signal after interference removal using the reference signal (step 406), and the decoder 307 decodes the user data signal after equalization (step 407).

  Next, the hard decision bit inspection unit 308 stores the equalized user data signal and the decoded user data signal (step 408). If the decoded user data signal includes a parity bit and the parity bit check result is OK, the interference removal execution information is set to stop and the process ends (steps 409 and 413). If the decoded user data signal includes a parity bit and the parity bit check result is NG, or if the input decoded user data signal does not include a parity bit, the process of the next step 410 Is executed (step 409).

That is, in the case of the initial process, the interference removal execution information is set to be executed (Step 410, Step 414). In addition, when it is not the first processing, the hard-decision bit difference value Avg _HARD (s) is obtained by averaging the dispersion values (differences) of the stored old equalized user data signal and new equalized user data signal for each bit. ) Is obtained (step 411). Then, the hard decision bit difference value Avg _HARD (s) is compared with the hard decision interference removal decision threshold Thr _HARD (s) (step 412). If Avg _HARD (s) ≧ Thr _HARD (s) is not satisfied, the interference removal is performed. The execution information is set to stop, the process is terminated (step 413), and when Avg _HARD (s) ≧ Thr _HARD (s), the interference removal execution information is set to execution (step 414).

  Next, the interference replica generation unit 309 generates an interference replica signal from the decoded user data signal (step 415), and repeats the processing of the interference removal unit 305 (step 404) and subsequent steps.

  As described above, in the second embodiment of the present invention, based on the demodulated user data signal, in particular, the demodulated user data signal in the old interference cancellation process and the demodulated user data signal in the new interference cancellation process, or By controlling the execution of the interference cancellation process based on the check result of the parity bit included in the decoded user data signal, the number of interference cancellations can be determined adaptively. Therefore, similarly to the first embodiment, the processing time can be shortened and the power consumption can be reduced.

  Further, by comparing the average value of the variance values for each bit of the demodulated user data signal newly generated by repetition and the previously generated demodulated user data signal with the interference cancellation determination threshold, It is possible to control the number of times of performing interference removal processing. Furthermore, since the threshold value dynamically fluctuates by weighting the interference cancellation determination threshold value according to the reception state of the reference signal, the number of times of performing the interference cancellation process can be controlled with higher accuracy.

(Third embodiment of the present invention)
Next, a third embodiment of the present invention will be described in detail with reference to FIGS.

  FIG. 6 is a block diagram showing a configuration of a receiver using the SIC method in the wireless communication system according to the third embodiment of the present invention. The wireless communication system has one transmitter 500 and one receiver 501.

  The transmitter 500 transmits a time-domain transmission signal obtained by multiplexing the reference signal and the user data signal to the receiver 501.

  The receiver 501 includes an A / D conversion unit 502, an FFT unit 503, a subcarrier extraction unit 504, an interference removal unit 505, a demodulation unit 506, a decoding unit 507, a hard / soft decision bit inspection unit 508, and an interference replica generation unit 509. The correspondence relationship with FIG. 1 will be described. The interference replica generation unit 509 and the interference removal unit 505 correspond to the interference removal processing unit 12, the demodulation unit 506 and the decoding unit 507 correspond to the determination decoding processing unit 13, and the hard and soft The determination bit inspection unit 508 corresponds to the repetition control unit 14.

  The A / D converter 502 receives a time domain transmission signal in which a reference signal and a user data signal are multiplexed from the transmitter 500 as a received signal in the time domain affected by a propagation path or the like. The input reception signal in the time domain is converted into a digital signal. The converted reception signal in the time domain is output to FFT section 503.

  The FFT unit 503 receives the time domain received signal from the A / D converter 502. The input time domain received signal is subjected to FFT processing and converted to a frequency domain received signal. The frequency domain received signal is output to subcarrier extraction section 504.

  The subcarrier extraction unit 504 receives the frequency domain received signal from the FFT unit 503. A subcarrier in which a reference signal and a user data signal are multiplexed is extracted from the received frequency domain received signal. The extracted user data signal is output to the interference removal unit 505, and the extracted reference signal is output to the demodulation unit 506.

  The interference removal unit 505 receives the user data signal from the subcarrier extraction unit 504, receives the interference replica signal from the interference replica generation unit 509, and notifies the interference removal execution information from the hard / soft decision bit inspection unit 508. When the notified interference removal execution information indicates cancellation, the interference removal unit 505 does not operate. On the other hand, when the notified interference removal execution information indicates execution, interference removal is performed by subtracting the input interference replica signal from the user data signal, and a user data signal after interference removal is generated. However, it is always executed in the case of the first operation, and the input user data signal is handled as user data after interference removal. The generated user data signal after interference cancellation is output to demodulation section 506.

  Demodulation section 506 receives the reference signal from subcarrier extraction section 504, receives the user data signal after interference removal from interference removal section 505, and receives interference removal execution information from hard / soft decision bit inspection section 508. When the notified interference removal execution information indicates cancellation, the demodulation unit 506 does not operate. On the other hand, when the notified interference removal execution information indicates execution, the user data signal after interference removal is equalized using the input reference signal, resulting in the propagation path from the user data signal after interference removal. And the equalized user data signal is generated. However, it is always executed in the first operation. The generated equalized user data signal is output to the decoding unit 507 and the hard / soft decision bit inspection unit 508.

  The decoding unit 507 receives the equalized user data signal from the demodulation unit 506 and receives interference removal execution information from the hard / soft decision bit inspection unit 508. When the notified interference removal execution information indicates cancellation, the decoding unit 507 does not operate. On the other hand, when the notified interference removal execution information indicates execution, a decoded user data signal is generated by decoding the input post-equalization user data signal. However, it is always executed in the first operation. The generated decoded user data signal is output to the hard / soft decision bit inspection unit 508 and the interference replica generation unit 509.

  The hard / soft decision bit inspection unit 508 receives the equalized user data signal from the demodulation unit 506 and the decoded user data signal from the decoding unit 507. The input equalized user data and the decoded user data signal are stored. If the input decoded user data signal includes a parity bit such as CRC and the parity bit check result is OK, it is determined that the next interference cancellation processing is to be stopped, and interference cancellation execution information is obtained. Is set to cancel. On the other hand, when the input decoded user data signal includes a parity bit and the parity bit check result is NG, or when the input decoded user data signal does not include a parity bit, the following processing is performed. Execute.

That is, in the case of the first interference removal process, the interference removal execution information is set to execute. In the case of the second and subsequent interference removal processing, the hard decision difference average is obtained by averaging the dispersion value (difference) for each bit of the held old post-equalization user data signal and the input new post-equalization user data signal. The value Avg _HARD (s) is obtained. The stored old decoded user data signal is compared with the input new decoded user data signal bit pattern, and the number of different bit patterns is counted to obtain the soft decision bit difference N _SOFT (s). Here, Avg _HARD (s) <Thr _HARD (s) and N with respect to the hard decision interference removal decision threshold Thr _HARD (s) and the soft decision interference removal decision threshold Thr _SOFT (s) given as parameters. _{When SOFT} (s) <Thr _SOFT (s), it is determined that the next interference removal processing is to be stopped, and the interference removal execution information is set to be stopped. On the other hand, if Avg _HARD (s) ≧ Thr _HARD (s) or N _SOFT (s) ≧ Thr _SOFT (s), it is determined that the next interference removal process is to be executed, and the interference removal execution information is executed. Set. The hard decision interference removal determination threshold value Thr _HARD (s) and the soft decision interference removal decision threshold value Thr _SOFT (s) can be corrected by the above Equations 1 and 2, respectively. The interference removal execution information is notified to the interference removal unit 505, the demodulation unit 506, the decoding unit 507, and the interference replica generation unit 509.

  The interference replica generation unit 509 receives the decoded user data signal from the decoding unit 507 and receives interference removal execution information from the hard / soft decision bit inspection unit 508. When the notified interference removal execution information indicates cancellation, the interference replica unit 509 does not operate. On the other hand, when the notified interference removal execution information indicates execution, an interference replica signal corresponding to an interference component included in the frequency domain user data signal is generated using the input decoded user data signal. However, it is always executed in the first operation. The generated interference replica signal is output to the interference removal unit 505.

  Next, the operation of the third embodiment of the present invention will be described. In the following description, a process for the receiver 501 in the wireless communication system will be described when one transmitter 500 and one receiver 501 exist as an example.

  FIG. 7 is a flowchart showing the operation of the receiver 501 in the present invention. Hereinafter, the reception processing in the receiver 501 will be described with reference to FIG.

  First, the receiver 501 receives a time-domain transmission signal in which a reference signal and a user data signal transmitted from the transmitter 500 are multiplexed (step 600).

  Next, the A / D converter 502 converts the time domain received signal into a digital signal by A / D conversion (step 601), and the FFT unit 503 performs FFT processing on the time domain received signal to convert it to the frequency domain. (Step 602), the subcarrier extraction unit 504 extracts the reference signal and the user data signal from the received signal in the frequency domain (Step 603).

  Next, in the case of initial processing, the interference removal unit 505 outputs the input user data signal as it is (step 604). If it is not the first process, the interference component is removed from the user data signal using the interference replica signal (step 605).

  Next, the demodulator 506 equalizes the user data signal after interference removal using the reference signal (step 606), and the decoder 507 decodes the user data signal after equalization (step 607).

  Next, the hard / soft decision bit inspection unit 508 stores the equalized user data signal and the decoded user data signal (step 608). If the decoded user data signal includes a parity bit and the parity bit check result is OK, the interference removal execution information is set to stop and the process ends (steps 609 and 615). If the decoded user data signal includes a parity bit and the parity bit check result is NG, or if the input decoded user data signal does not include a parity bit, the processing in the next step 610 is performed. Is executed (step 609).

That is, in the case of the initial process, the interference removal execution information is set to execute (steps 610 and 616). In addition, when it is not the first processing, the hard-decision bit difference value Avg _HARD (s) is obtained by averaging the dispersion values (differences) of the stored old equalized user data signal and new equalized user data signal for each bit. ) Is obtained (step 611). Then, the hard decision bit difference value Avg _HARD (s) is compared with the hard decision interference removal decision threshold value Thr _HARD (S) (step 612). If Avg _HARD (s) ≧ Thr _HARD (s), interference removal is performed. If execution information is set to execution (step 616) and Avg _HARD (s) ≧ Thr _HARD (s) does not hold, the number of different bit patterns of the stored old decoded user data signal and the new decoded user data signal To obtain the soft decision bit difference N _SOFT (s) (step 613).

Further, the soft decision bit difference N _SOFT (s) is compared with the soft decision interference removal decision threshold Thr _SOFT (s) (step 614). If N _SOFT (s) ≧ Thr _SOFT (s) is not satisfied, interference removal is performed. The information is set to stop, the process is terminated (step 615), and if N _SOFT (s) ≧ Thr _SOFT (s), the interference removal execution information is set to execution (step 616).

  Next, the interference replica generation unit 509 generates an interference replica signal from the decoded user data signal (step 617), and repeats the processing of the interference removal unit 505 (step 404) and subsequent steps.

  As described above, in the third embodiment of the present invention, based on the decoded user data signal and the demodulated user data signal, in particular, the decoded user data signal in the old interference cancellation process and the decoded in the new interference cancellation process. In addition to the user data signal, based on the demodulated user data signal in the old interference cancellation process and the demodulated user data signal in the new interference cancellation process, and further on the basis of the check result of the parity bit included in the decoded user data signal By controlling the execution of the interference cancellation process, the number of interference cancellations can be determined adaptively. Therefore, it is possible to further reduce the processing time and power consumption by optimizing the number of interference removals than in the first and second embodiments.

  Also, the number of different bit patterns between the plurality of decoded user data signals and the soft decision interference cancellation determination threshold value are compared, and a value obtained by averaging the variance value for each bit between the plurality of demodulated user data signals, By comparing the interference determination threshold value for hard determination, the number of executions of the interference cancellation process can be controlled effectively. Furthermore, the threshold value is dynamically changed by weighting the soft decision interference removal decision threshold according to the error correction coding rate and weighting the hard decision interference removal decision threshold according to the reception state of the reference signal. The number of executions of the removal process can be controlled.

  The configuration of the preferred embodiment of the present invention has been described above. However, it should be noted that such embodiments are merely examples of the present invention and do not limit the present invention in any way. Those skilled in the art will readily understand that various modifications and changes can be made according to a specific application without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 Transmitter 11 Receiver 12 Interference removal process part 13 Judgment decoding process part 14 Repetition control part 100 Transmitter 101 Receiver 102 A / D conversion part 103 FFT part 104 Subcarrier extraction part 105 Interference removal part 106 Demodulation part 107 Decoding part 108 Soft decision bit inspection unit 109 Interference replica generation unit 300 Transmitter 301 Receiver 302 A / D conversion unit 303 FFT unit 304 Subcarrier extraction unit 305 Interference removal unit 306 Demodulation unit 307 Decoding unit 308 Hard decision bit inspection unit 309 Interference replica Generation unit 500 Transmitter 501 Receiver 502 A / D conversion unit 503 FFT unit 504 Subcarrier extraction unit 505 Interference removal unit 506 Demodulation unit 507 Decoding unit 508 Hard / soft decision bit check unit 509 Interference replica generation unit 700 Transmitter 701 Receiver 702 A / D converter 703 FFT unit 70 Subcarrier extracting section 705 interference removal unit 706 demodulation unit 707 decoding unit 708 interference replica generation unit

Claims (7)

A receiving method in a receiver for receiving a radio signal from a transmitter, comprising:
Performing interference removal processing to remove interference on the input signal based on the received radio signal;
Performing a decoding process for decoding the signal from which interference has been removed and generating determination decoding information;
The interference cancellation process and the determination decoding process are repeated by further inputting the generated determination decoding information to the interference cancellation process, and the interference cancellation process is performed based on the plurality of determination decoding information generated by the repetition. Control the number of executions ,
The determination decoding process includes a demodulation process for demodulating the input signal, and a decoding process for decoding the demodulated signal,
The number of executions is controlled based on the demodulated signal generated by the demodulation process or the decoded signal generated by the decoding process.
The control of the number of executions controls the number of executions based on a result of comparing a bit pattern of a decoded signal newly generated by the repetition and a previously generated decoded signal,
The number of executions is controlled based on the comparison result and a value weighted by an error correction coding rate of the decoded signal.
Reception method. The number of executions is controlled by comparing the number of different bit patterns between the decoded signal newly generated by the repetition and the previously generated decoded signal with the weighted value, and calculating the number of executions. controlling method of the receiving claim 1. A receiving method in a receiver for receiving a radio signal from a transmitter, comprising:
Performing interference removal processing to remove interference on the input signal based on the received radio signal;
Performing a decoding process for decoding the signal from which interference has been removed and generating determination decoding information;
The interference cancellation process and the determination decoding process are repeated by further inputting the generated determination decoding information to the interference cancellation process, and the interference cancellation process is performed based on the plurality of determination decoding information generated by the repetition. Control the number of executions ,
The determination decoding process includes a demodulation process for demodulating the input signal, and a decoding process for decoding the demodulated signal,
The number of executions is controlled based on the demodulated signal generated by the demodulation process or the decoded signal generated by the decoding process.
The control of the number of executions controls the number of executions based on a dispersion value obtained from a demodulated signal newly generated by the repetition and a demodulated signal generated previously,
The control of the number of executions controls the number of executions based on the variance value and a value weighted by a reception state of a reference signal included in the wireless signal.
Reception method. The control of the number of executions compares the weighted value with a value obtained by averaging a variance value for each bit of the demodulated signal newly generated by the repetition and the demodulated signal generated previously, The receiving method according to claim 3 , wherein the number of executions is controlled. The control of the execution number of times, based on the inspection result of the parity bits included in the decoded signal, for controlling the execution number of times, receiving method according to any one of claims 1 to 4. A receiver for receiving a radio signal from a transmitter,
An interference removal processing unit for performing interference removal processing to remove interference on an input signal based on the received radio signal;
A determination decoding processing unit that performs a determination decoding process that decodes the interference-removed signal and generates determination decoding information;
The interference cancellation process and the determination decoding process are repeated by further inputting the generated determination decoding information to the interference cancellation process, and the interference cancellation process is performed based on the plurality of determination decoding information generated by the repetition. and the repetitive control unit for controlling the number of times to run, the Bei example,
The determination decoding processing unit includes a demodulation processing unit that demodulates the input signal, and a decoding processing unit that decodes the demodulated signal,
The repetition control unit controls the number of executions based on the demodulated signal generated by the demodulation processing unit or the decoded signal generated by the decoding processing unit,
The repetition control unit controls the number of executions based on a result of comparing a bit pattern between a decoded signal newly generated by the repetition and a previously generated decoded signal,
The repetition control unit controls the number of executions based on the comparison result and a value weighted by an error correction coding rate of the decoded signal.
Receiver. A receiver for receiving a radio signal from a transmitter,
An interference removal processing unit for performing interference removal processing to remove interference on an input signal based on the received radio signal;
A determination decoding processing unit that performs a determination decoding process that decodes the interference-removed signal and generates determination decoding information;
The interference cancellation process and the determination decoding process are repeated by further inputting the generated determination decoding information to the interference cancellation process, and the interference cancellation process is performed based on the plurality of determination decoding information generated by the repetition. and the repetitive control unit for controlling the number of times to run, the Bei example,
The determination decoding processing unit includes a demodulation processing unit that demodulates the input signal, and a decoding processing unit that decodes the demodulated signal,
The repetition control unit controls the number of executions based on the demodulated signal generated by the demodulation processing unit or the decoded signal generated by the decoding processing unit,
The repetition control unit controls the number of executions based on a dispersion value obtained from a demodulated signal newly generated by the repetition and a demodulated signal generated previously,
The repetitive control unit controls the number of executions based on the variance value and a value weighted by a reception state of a reference signal included in the radio signal.
Receiver.

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