JP4394700B2 - Despreader - Google Patents

Description

  The present invention is mounted on a radio receiving apparatus that can improve transmission quality based on desired directivity or diversity scheme by performing predetermined processing on received waves that have arrived in parallel with a plurality of antennas. The present invention relates to a despreader that performs a despreading process on a received wave adapted to a system.

  The CDMA (Code Division Multiple Access) method is capable of suppressing co-channel interference and efficiently reusing radio frequencies under the inherent secrecy and interference resistance.

  In addition, since the CDMA system has recently been able to flexibly set the radio transmission characteristics for each sector zone due to the establishment of a technology that realizes transmission power control with high accuracy and responsiveness, it is also actively applied to mobile communication systems. Is being applied.

  FIG. 14 is a diagram illustrating a configuration example of a reception system in a mobile communication system using an array antenna under the CDMA scheme.

  In the figure, the feeding ends of the four antennas 141-1 to 141-4 are individually connected to four inputs of the A / D conversion board 142, and the four outputs of the A / D conversion board are respectively connected to the line 143-. 1 to 143-4 are connected to corresponding inputs on the receiver board 144.

  The A / D conversion board 142 includes a front end unit 145-1 and an A / D converter (A / D) 146-1 that are cascade-connected between the feeding end of the antenna 141-1 and one end of the line 143-1. A front end portion 145-2 and an A / D converter (A / D) 146-2 that are cascade-connected between the feeding end of the antenna 141-2 and one end of the line 143-2, and the antenna 141-3. A front end 145-3 and an A / D converter (A / D) 146-3 connected in cascade between the feed end of the antenna 141 and one end of the line 143-3, and a feed end of the antenna 141-4 and the line 143. -4, and a front end portion 145-4 and an A / D converter 146-4 (A / D) connected in cascade.

  The receiver board 144 is connected to all the other ends of the lines 143-1 to 143-4, and a control signal indicating the type of despread code to be applied is individually supplied from the outside (for example, a channel control device not shown). And a searcher 148 disposed between the other end of the line 143-4 and the control input of the receiving units 147-1 to 147-4.

  The receiving unit 147-1 is provided with multipliers 149-11 to 149-14 in which the other ends of the lines 143-1 to 143-4 are individually connected to one input, and the control signal described above is given to one input. And a corresponding output of the searcher 148 is connected to the other input, and a despreading code generator (CODE) 150-1 whose output is connected to the other input of the multipliers 149-11 to 149-14 These are arranged separately from the multipliers 149-11 to 149-14 and dump filters (DUMP) 151-11 to 151-14 that output demodulated signals.

  Note that the configurations of the receiving units 147-2 to 147-4 are the same as the configuration of the receiving unit 147-1. Therefore, in the following, the corresponding components are assigned the first serial numbers “2” to “4”, respectively. The same reference numerals are given, and the description and illustration thereof are omitted here.

  The searcher 148 includes cascaded matched filters 152, an averaging unit 153, and a RAM 154, and a despread code generation unit 150 that is arranged in a subsequent stage of the RAM 154 and is individually provided in the receiving units 147-1 to 147-4. And a path detection unit 155 connected to corresponding inputs -1 to 150-4.

  The matched filter 152 operates in synchronization with a clock having a frequency given by (8fc) with respect to the chip rate fc of the despread code, and the number of stages is the word length of the spread code. A shift register 156 that is (8L−1) with respect to L, and an input terminal of the shift register 156 and an output of all the stages are individually connected, and among the bits constituting the despread code, A multiplier 157 in which a weight corresponding to a logical value (either “1” or “−1”) is individually set in advance, and an adder 158 arranged as a final stage after the multiplier 157 Composed. In the following description, it is assumed that the number of stages of the shift register 156 is “31” for simplicity.

  In the conventional example having such a configuration, each of the front end units 145-1 to 145-4 receives received waves arriving in parallel with the antennas 141-1 to 141-4 in the baseband region (hereinafter, “ "Spread signal").

  Each of the A / D converters 146-1 to 146-4 outputs these spread signals at a period (hereinafter referred to as “oversampling period”) given by (1 / 8fc) with respect to the above-described chip rate fc. At the same time, discrete signals are generated by oversampling, and these discrete signals are sent to lines 143-1 to 143-4.

  In the searcher 148 provided in the receiver boat 144, the shift register 156 sequentially accumulates the discrete signals provided via the line 143-4, and the multiplier 157 and the adder 158 are connected to the accumulated discrete signals. Correlation with a despread code given in advance as the above-mentioned weight is taken.

  The averaging unit 153 takes the average of the above correlation results for each despread code period and in chronological order over a period of multiple times the despread code period. The delay profile shown is obtained, and the delay profile is stored in the RAM 154.

  The path detection unit 155 reads the delay profiles stored in the RAM 154 in this way in the order of time series and with the period of the despread code, thereby indicating the time point when the average value exceeding the predetermined threshold is detected. A “path detection signal” composed of a pulse train is cyclically output at the period of the despread code.

Among the reception units 147-1 to 147-4, for example, in the reception unit 147-1, the despread code generation unit 150-1 performs a predetermined channel setting procedure in the pulse train given as the path detection signal described above. A despreading code is generated starting from a time point indicating a channel allocated based on the received control signal and given in parallel.

  Multipliers 149-11 to 149-14 multiply these discrete signals by despreading processing by multiplying the despread codes and the discrete signals given via lines 143-1 to 143-4.

  Therefore, the outputs of these multipliers 149-11 to 149-14 indicate the components of the channels allocated under the channel setting among the components included in the received waves arriving at antennas 141-1 to 141-4. Four demodulated signals are obtained in the baseband region.

  These demodulated signals are subjected to predetermined filtering processes by the dump filters 151-11 to 151-14, respectively, and only the components that have arrived at the antennas 141-1 to 141-4 are extracted based on the adaptive algorithm. A synthesis process is performed.

  However, since such a synthesis process is not a feature of the present invention, as long as it is adapted to a desired sector zone, any method including an adaptive algorithm to be applied and any directivity or diversity method to be achieved There may be.

  By the way, in the above-described conventional example, the number of lines indicated by reference numeral “143” increases in proportion to the number of antennas indicated by reference numeral “141”. The number of lines can be reduced by multiplexing the discrete signals generated by the A / D converters 146-1 to 146-4, for example.

  However, such a configuration in which discrete signals are simply multiplexed has been difficult to apply in practice because of restrictions on the upper limit of speed and power consumption inherent in applicable semiconductor devices.

  Also, for the lines 143-1 to 143-4, since the bit rate of the signal transmitted through these lines 143-1 to 143-4 is several megabits / second to several tens of megabits / second, A structure in which electromagnetic noise radiation is suppressed must be applied.

  Further, since the number of antennas described above may increase in the future for the purpose of forming a highly accurate sector zone or a small sector zone, the function distribution between the A / D conversion board 142 and the receiver board 144 and a plurality of receptions may be increased. It was highly possible that the achievement of additional dispersion on the machine board would be hindered.

  An object of the present invention is to provide a despreader in which flexible modularization is achieved without greatly complicating the hardware configuration.

  FIG. 1 is a principle configuration diagram of a radio receiving apparatus related to the present invention.

  The first radio receiving apparatus shown in FIG. 1 receives received waves arriving in parallel with a plurality of N antennas 10-1 to 10-N in a baseband region with a plurality of N different phases and an occupied bandwidth of 2 A plurality of N thinning-out processing units 11-1 to 11-N that sample at a frequency more than twice and generate discrete signals individually corresponding to these received waves, and a plurality of N thinning-out processing units 11-1 to 11-N A multiplexing unit 12 that multiplexes the discrete signals generated by the output unit 10 and outputs a multiplexed signal; a demultiplexing unit 13 that demultiplexes the multiplexed signal output by the multiplexing unit 12 and restores a plurality of N discrete signals; A prediction process for individually predicting instantaneous values at a common time point that is given from the outside or set in advance for a plurality of N discrete signals restored by the demultiplexing unit 13 is performed in the baseband region. Anne Constructed and a predictive processing unit 14-1 to 14-N of the plurality N of generating a baseband signal representing Na 10-1 to 10-N received wave arriving in parallel, respectively.

  In the first radio receiving apparatus described above, the received wave is generated based on a direct spreading scheme to which a spreading code having a chip rate of fc is applied, and a plurality of N decimation processing means 11-1 to 11-N. Samples the received waves arriving in parallel with the plurality of N antennas 10-1 to 10-N in synchronization with a sampling clock having a period of (1 / 2fc) or less, and sets the second radio receiving apparatus It can also be configured.

  Further, in the second radio receiving apparatus described above, a plurality of N thinning-out processing units 11-1 to 11-N each have a plurality of different phases set at regular intervals of (1 / 2Nfc) or less on the time axis. It is also possible to configure the third radio receiving apparatus by sampling received waves that arrive in parallel with the N antennas 10-1 to 10-N.

  Further, in the second or third radio receiving apparatus described above, a despreading process is performed in parallel with the N discrete signals restored by the demultiplexing means 13, and the distribution of the despread power in the transmission band is obtained. The path monitoring means 21 obtained in the order of time series, and the time when the power exceeds a predetermined threshold under the power distribution obtained by the path monitoring means 21 and corresponding to the path designated from the outside, is obtained. A plurality of N prediction processing units 14-1 to 14-N are given as a common time point and are generated by a phase specifying unit 22 for specifying the sampling clock phase and a plurality of N prediction processing units 14-1 to 14-N. The N baseband signals are subjected to despreading processing based on the despread code having the phase specified by the phase specifying means 22, and received signals received by the N antennas 10-1 to 10 -N. And a despreading unit 23 to obtain a demodulated signal corresponding to, it is also possible to configure the fourth wireless reception apparatus.

  On the other hand, in the second or third radio receiving apparatus described above, the despreading power and the power despread in the transmission band according to the despreading process for the N discrete signals restored by the demultiplexing means 13 The path monitoring means 31 for obtaining the measured power distributions in the order of time series, and obtaining the distribution of these measured powers in the order of the time series in which sampling is performed by a plurality of N thinning-out processing means 11-1 to 11-N; Under the distribution of power obtained by the path monitoring means 31, a time when the power exceeds a predetermined threshold and corresponds to a path designated from the outside is obtained, and the time is determined by a plurality of prediction processing means 14-1 to 14-. N basebands generated by a phase identification unit 32 that identifies the sampling clock phase as a common time point and a plurality of N prediction processing units 14-1 to 14-N. Is subjected to despreading processing based on the despread code of the phase specified by the phase specifying means 32 to obtain demodulated signals individually corresponding to the received waves arriving at the N antennas 10-1 to 10-N It is also possible to provide a despreading processing means 33 and constitute a fifth wireless reception apparatus.

  Further, in the second or third radio receiving apparatus described above, a despreading process is performed in parallel with the N discrete signals restored by the demultiplexing means 13, and the distribution of the despread power in the transmission band is obtained. The path monitoring means 21 obtained in the order of time series, and the time when the power exceeds a predetermined threshold under the power distribution obtained by the path monitoring means 21 and corresponding to the path designated from the outside, is obtained. A phase identification unit 22 that is given as a common time to the plurality of N prediction processing units 14-1 to 14 -N and is specified as a phase of the sampling clock, a transfer function indicating a filtering characteristic to be subjected to the prediction processing, A plurality of N predictive processing units 14-1 to 14-N that obtain a product of the despread code of the phase specified by the specifying unit 22; By performing the filtering process based on the filtering characteristics given by the same transfer function, the N discrete signals restored by the demultiplexing means 13 are subjected to the despreading process in conjunction with the prediction process, and the N antennas 10- A sixth radio reception apparatus can also be configured by obtaining demodulated signals individually corresponding to received waves arriving at 1 to 10-N.

  Further, in the second or third radio receiving apparatus described above, the power despread in the transmission band according to the despreading process and the despreading process for the N discrete signals restored by the demultiplexing means 13 The path monitoring means 31 for obtaining the measured power distribution in series in the time series, and obtaining the distribution of these measured powers in the order of the time series in which the plural N thinning-out processing means 11-1 to 11-N perform sampling. Under the distribution of power obtained by the monitoring means 31, a time when the power exceeds a predetermined threshold and corresponds to a path designated from the outside is obtained, and that time is determined as a plurality of N prediction processing means 14-1 to 14-. N is given as a common time to N, and is specified by the phase specifying means 32 for specifying the phase of the sampling clock, the transfer function indicating the filtering characteristic to be subjected to the prediction process, and the phase specifying means 32 A plurality of N prediction processing means 14-1 to 14-N are given by a transfer function equal to the product obtained by the multiplication means 42. By performing the filtering process based on the filtering characteristics, a plurality of N discrete signals restored by the demultiplexing means 13 are subjected to a despreading process in conjunction with the prediction process, and the plurality of N antennas 10-1 to 10-N are applied. By obtaining a demodulated signal individually corresponding to the incoming received wave, the seventh radio receiving apparatus can be configured.

  Further, in the second or third radio receiving apparatus described above, a despreading process is performed in parallel with the N discrete signals restored by the demultiplexing means 13, and the distribution of the despread power in the transmission band is obtained. The path monitoring means 21 obtained in the order of time series, and the time when the power exceeds a predetermined threshold under the power distribution obtained by the path monitoring means 21 and corresponding to the path designated from the outside, is obtained. Provided as a common time point to the plurality of N prediction processing units 14-1 to 14-N, and a phase specifying unit 22 that specifies the phase of the sampling clock; a binary value that can be taken by the despreading code; Corresponding to the form of prediction processing that can be performed by -1 to 14-N, transmission of constants of different signs individually associated with these binary values and filtering characteristics to be subjected to these prediction processes With function A plurality of N prediction processing units 14-1 to 14 -N, which are despreads given in series among the products stored in the storage unit 51. A plurality of N restored by the demultiplexing means 13 is performed by performing the filtering process based on the filtering characteristic given by the transfer function equal to the product corresponding to the logical value of the code and the form of the prediction process given from the outside. 8th radio receiving apparatus by performing despreading processing on the discrete signals of the received signals and obtaining the demodulated signals individually corresponding to the received waves arriving at the N antennas 10-1 to 10-N. Can also be configured.

  Further, in the second or third radio receiving apparatus described above, the power despread in the transmission band according to the despreading process and the despreading process for the N discrete signals restored by the demultiplexing means 13 The path monitoring means 31 for obtaining the measured power distribution in series in the time series, and obtaining the distribution of these measured powers in the order of the time series in which the plural N thinning-out processing means 11-1 to 11-N perform sampling. Under the distribution of power obtained by the monitoring means 31, a time when the power exceeds a predetermined threshold and corresponds to a path designated from the outside is obtained, and that time is determined as a plurality of N prediction processing means 14-1 to 14-. Prediction processing that can be performed by the phase specifying means 32 that specifies the sampling clock phase as a common time point for N, and the binary that can be taken by the despread code and the plurality of N prediction processing means 14-1 to 14-N Corresponding to the form, a memory in which products of all combinations of constants of different signs individually associated with these two values and transfer characteristics indicating the filtering characteristics to be subjected to the prediction processing are stored in advance A plurality of N prediction processing units 14-1 to 14 -N, which are given from the logical value of the despread code given in series among the products stored in the storage unit 51 and given from the outside. By performing a filtering process based on a filtering characteristic given by a transfer function equal to the product corresponding to the form of the prediction process, a plurality of N discrete signals restored by the demultiplexing means 13 are inversely combined with the prediction process. The ninth radio receiving apparatus can also be configured by performing spreading processing and obtaining demodulated signals individually corresponding to the received waves arriving at the N antennas 10-1 to 10-N.

  FIG. 2 is a block diagram showing the principle of a first despreader according to the present invention.

  The first despreader according to the present invention performs prediction processing and despreading processing on a spread signal obtained by sampling a direct spread received wave in the baseband region at a frequency more than twice the chip rate of the spread code. The product of the filtering means 61 for generating the demodulated signal, the transfer function indicating the filtering characteristics to be applied to the prediction process, and the despreading code to be applied to the despreading process is taken, and the product is transmitted to the filtering means 61. And a control means 62 that supplies the filtering means 61 as a function.

  FIG. 3 is a principle block diagram of a second despreader according to the present invention.

  The second despreader according to the present invention performs a prediction process and a despread process on a spread signal obtained by sampling a direct spread received wave at a frequency more than twice the chip rate of the spread code in the baseband region. Corresponding to the filtering means 61 for generating the demodulated signal, the binary values that the spreading code can take and the form of prediction processing, constants of different codes individually associated with these binary values, and the prediction processing The product of all combinations with the transfer function indicating the filtering characteristics to be provided is stored in advance, and the product of the despread code to be applied to the despreading process among the products stored in the storage unit 71 Control means 72 is provided, which provides the filtering means 61 with a product corresponding to the logical value and the form of prediction processing given together with the logical value as a transfer function.

  In the first radio receiving apparatus described above, the thinning-out processing units 11-1 to 11-N receive received waves arriving in parallel with the antennas 10-1 to 10-N at a plurality of N different phases in the baseband region. By sampling at a frequency that is at least twice the occupied bandwidth, discrete signals individually corresponding to these received waves are generated. The multiplexing means 12 multiplexes these discrete signals and outputs a multiplexed signal.

  Further, the demultiplexing means 13 restores the above-described N discrete signals by demultiplexing the multiplexed signal. Further, the prediction processing means 14-1 to 14-N perform prediction processing for individually predicting instantaneous values at a common time point given from the outside or set in advance for these discrete signals, and the baseband region Thus, baseband signals respectively indicating the received waves arriving in parallel with the antennas 10-1 to 10-N are generated.

  That is, the discrete signals described above are interpolated in the course of the prediction process performed by the prediction processing means 14-1 to 14-N among the instantaneous values of the received waves arriving in parallel with the antennas 10-1 to 10-N, respectively. The instantaneous value to be generated is generated without being sampled, multiplexed by the multiplexing means 12 and supplied to the demultiplexing means 13.

  Therefore, in the present invention, even when the number N of the antennas 10-1 to 10-N is large or the occupied band of the received waves arriving at these antennas 10-1 to 10-N is wide, the multiplexing means The band of the multiplexed signal output by the signal 12 is kept small, and the number of lines connecting the multiplexing means 12 and the demultiplexing means 13 is highly accurate and less than the number N of the antennas 10-1 to 10-N. It can be suppressed.

  Further, in the second radio receiving apparatus described above, in the first radio receiving apparatus described above, the antennas 10-1 to 10-N are based on a direct spreading scheme in which a spreading code having a chip rate of fc is applied. The received waves generated in parallel arrive in parallel.

  The decimation processing means 11-1 to 11-N individually generate discrete signals by sampling these received waves in synchronization with a sampling clock having a period of (1 / 2fc) or less.

  Since these discrete signals are generated by sampling the received wave at a period in which the sampling theorem holds in the occupied band in the baseband region of the received wave described above, the multiplexing means 12, the demultiplexing means 13 and The prediction processing means 14-1 to 14-N can be linked in the same manner as the first wireless reception apparatus, and can be applied to a wireless transmission system to which the direct spreading method is applied.

  In the third wireless reception device, in the second wireless reception device described above, the thinning processing units 11-1 to 11-N have different phases set at regular intervals of (1 / 2Nfc) or less on the time axis. The received waves arriving in parallel with the antennas 10-1 to 10-N are sampled.

  That is, the N transfer functions indicating the filtering characteristics to be individually applied in the course of the prediction processing to be performed by the prediction processing means 14-1 to 14-N are positioned at regular intervals in the phase space. The calculation procedure required for the calculation can be simplified, or the hardware configuration used for the actual setting can be standardized.

  In the fourth radio receiving apparatus, in the second or third radio receiving apparatus, the path monitoring unit 21 performs despreading processing in parallel with the N discrete signals restored by the demultiplexing unit 13. The distribution of power despread in the transmission band is obtained in the order of time series. The phase specifying unit 22 obtains a time point at which the power exceeds a predetermined threshold under the power distribution thus obtained and corresponds to a path designated from the outside. Further, the phase specifying means 22 gives the time as a common time to the prediction processing means 14-1 to 14-N and specifies the phase of the sampling clock.

  Further, the prediction processing means 14-1 to 14-N perform prediction processing for individually predicting the instantaneous value at the common time point described above for a plurality of N discrete signals restored by the demultiplexing means 13, and A baseband signal individually indicating the received wave described above is generated in the baseband region.

  The despreading processing unit 23 performs despreading processing on these baseband signals based on the despreading code of the phase specified by the phase specifying unit 22, so that each of the baseband signals arriving at the antennas 10-1 to 10 -N is received. A demodulated signal corresponding to the received wave is obtained.

  That is, since a reception system adapted to the direct spreading method is realized and despreading processing is performed reliably, even if the number N of antennas 10-1 to 10-N is large, restrictions on hardware implementation. Is mitigated, and a desired combining process is performed on the demodulated signal obtained by the despreading process, whereby interference based on the sector zone configuration and the diversity reception method can be suppressed.

  In the fifth radio receiving apparatus, in the above-described second or third radio receiving apparatus, the path monitoring unit 31 performs despreading processing and despreading on the N discrete signals restored by the demultiplexing unit 13. Measurement of power despread in the transmission band according to processing is performed in series in the order of time series, and the distribution of these measured power is time series sampled by the thinning processing means 11-1 to 11-N. It asks in order of. The phase specifying means 32 obtains a time point when the power exceeds a predetermined threshold under the power distribution thus obtained and corresponds to a path designated from the outside, and the time point is determined by the prediction processing means 14-1. ~ 14-N as a common time point and specified as the phase of the sampling clock.

  Further, the prediction processing means 14-1 to 14-N perform prediction processing for individually predicting the instantaneous value at the common time point described above for a plurality of N discrete signals restored by the demultiplexing means 13, and A baseband signal individually indicating the received wave described above is generated in the baseband region.

  The despreading processing unit 33 performs despreading processing on these baseband signals based on the despreading code having the phase specified by the phase specifying unit 32, thereby individually arriving at the antennas 10-1 to 10-N. A demodulated signal corresponding to the received wave is obtained.

  Since the power distribution described above is obtained in series in time series by the path monitoring unit 31, the path monitoring unit 31 distributes the individual powers for the received waves that arrive in parallel with the antennas 10-1 to 10-N. It is configured without installing hardware and software that require

  Therefore, the scale of hardware is reduced as compared with the above-described fourth radio receiving apparatus, and the hardware can be obtained even when the number N of antennas 10-1 to 10-N is large as in the radio receiving apparatus. As well as the restrictions on the implementation of the above, the interference based on the sector zone configuration and the diversity reception method can be suppressed.

  In the sixth radio receiving apparatus, in the above-described second or third radio receiving apparatus, the path monitoring unit 21 performs despreading processing in parallel with the N discrete signals restored by the demultiplexing unit 13. Thus, the power distribution despread in the transmission band is obtained in the order of time series. The phase specifying unit 22 obtains a time point at which the power exceeds a predetermined threshold under the power distribution thus obtained and corresponds to a path designated from the outside. Further, the phase specifying means 22 gives the time as a common time to the prediction processing means 14-1 to 14-N and specifies the phase of the sampling clock.

  The multiplying unit 41 calculates the product of the transfer function indicating the filtering characteristic to be subjected to the prediction processing performed by the prediction processing units 14-1 to 14 -N and the despread code of the phase specified by the phase specifying unit 22. Ask.

  Further, the prediction processing means 14-1 to 14-N perform a filtering process based on a filtering characteristic given by a transfer function equal to the product of these to thereby obtain a plurality of N discrete signals restored by the demultiplexing means 13. In addition, a despreading process is performed together with the prediction process to obtain demodulated signals individually corresponding to the received waves arriving at the antennas 10-1 to 10-N.

  Since the prediction process and the despreading process are performed in this way, even when the number of antennas 10-1 to 10-N is large, the restrictions on the hardware implementation are alleviated, and the sector zone configuration and the diversity reception system are used. Interference suppression based on.

  In the seventh radio receiving apparatus, in the second or third radio receiving apparatus, the path monitoring unit 31 performs despreading processing and despreading processing on a plurality of N discrete signals restored by the demultiplexing unit 13. In response, the power despread in the transmission band is measured in series in the order of time series, and the distribution of these measured powers is in the order of time series in which sampling is performed by the thinning-out processing means 11-1 to 11-N. Ask. The phase specifying means 32 obtains a time point when the power exceeds a predetermined threshold under the power distribution thus obtained and corresponds to a path designated from the outside, and the time point is determined by the prediction processing means 14-1. ~ 14-N as a common time point and specified as the phase of the sampling clock.

  The multiplying means 42 obtains a product of the despread code having the phase thus specified and a transfer function indicating the filtering characteristic to be subjected to the prediction process.

  Further, the prediction processing means 14-1 to 14-N perform a filtering process based on a filtering characteristic given by a transfer function equal to the product of these to thereby obtain a plurality of N discrete signals restored by the demultiplexing means 13. In addition, a despreading process is performed together with the prediction process to obtain demodulated signals individually corresponding to the received waves arriving at the antennas 10-1 to 10-N.

  Since the above-described power distribution is directly obtained in time series by the path monitoring unit 31, the path monitoring unit 31 distributes the individual powers for the received waves arriving in parallel with the antennas 10-1 to 10-N. It is configured without installing hardware and software that require

  Therefore, the hardware scale is reduced, and the restrictions on the hardware implementation are eased even when the number of antennas 10-1 to 10-N is large in the same manner as the radio receiving apparatus. It is possible to suppress interference based on the zone configuration and diversity reception method.

  In the eighth radio receiving apparatus, in the second or third radio receiving apparatus described above, the path monitoring unit 21 performs despreading processing in parallel with the N discrete signals restored by the demultiplexing unit 13. Thus, the power distribution despread in the transmission band is obtained in the order of time series. The phase specifying unit 22 obtains a time point at which the power exceeds a predetermined threshold under the power distribution thus obtained and corresponds to a path designated from the outside. Further, the phase specifying means 22 gives this time point as a common time point to the prediction processing means 14-1 to 14-N and specifies it as the phase of the sampling clock.

  Further, the storage means 51 is individually associated with these binary values corresponding to the binary values that can be taken by the despreading code and the prediction processing modes that can be performed by the prediction processing means 14-1 to 14-N. The products of all combinations of constants with different signs and transfer functions indicating the filtering characteristics to be subjected to these prediction processes are stored in advance.

  The prediction processing means 14-1 to 14-N have a transfer function equal to the product corresponding to the logical value of the despread code given in series and the form of the prediction processing given from the outside among these products. By performing the filtering process based on the filtering characteristics to be given, a plurality of N discrete signals restored by the demultiplexing means 13 are subjected to a despreading process in conjunction with the prediction process, and are applied to the antennas 10-1 to 10-N. A demodulated signal individually corresponding to the incoming received wave is obtained.

  That is, since the despreading process is performed by the prediction processing units 14-1 to 14-N, the hardware configuration is simplified as compared with the fourth to seventh radio receiving apparatuses described above, and adaptation to a high chip rate is performed. Is possible.

  In the ninth radio receiving apparatus, in the above-described second or third radio receiving apparatus, the path monitoring unit 31 performs despreading processing and despreading on a plurality of N discrete signals restored by the demultiplexing unit 13. Measurement of power despread in the transmission band according to processing is performed in series in the order of time series, and the distribution of the measured power is sampled by the thinning-out processing means 11-1 to 11-N. It asks in order of. The phase specifying means 32 obtains a time point when the power exceeds a predetermined threshold under the power distribution thus obtained and corresponds to a path designated from the outside, and the time point is determined by the prediction processing means 14-1. ~ 14-N as a common time point and specified as the phase of the sampling clock.

  Further, the storage means 51 is individually associated with these binary values corresponding to the binary values that can be taken by the despreading code and the prediction processing modes that can be performed by the prediction processing means 14-1 to 14-N. The products of all combinations of the constants with different signs and the transfer characteristics indicating the filtering characteristics to be subjected to the prediction process are stored in advance.

  The prediction processing means 14-1 to 14-N have a transfer function equal to the product corresponding to the logical value of the despread code given in series and the form of the prediction processing given from the outside among these products. By performing the filtering process based on the filtering characteristics to be given, a plurality of N discrete signals restored by the demultiplexing means 13 are subjected to a despreading process in conjunction with the prediction process, and are applied to the antennas 10-1 to 10-N. A demodulated signal individually corresponding to the incoming received wave is obtained.

  Since the power distribution described above is obtained in series in time series by the path monitoring unit 31, the path monitoring unit 31 distributes the individual powers for the received waves that arrive in parallel with the antennas 10-1 to 10-N. It is configured without installing hardware and software that require

  Therefore, the scale of hardware is reduced, and adaptation to a high chip rate is possible in the same manner as the wireless receiver.

  In the first despreader according to the present invention, the control means 62 spreads the spread signal obtained by sampling the direct spread type received wave in the baseband region at a frequency more than twice the chip rate of the spread code. The product of the transfer function indicating the filtering characteristic to be applied to the prediction processing applied to the signal and the despreading code to be applied to the despreading processing applied in parallel is taken. Further, the control means 62 gives the product to the filtering means 61 as a transfer function indicating the filtering characteristics of the filtering means 61. The filtering unit 61 generates a demodulated signal by performing filtering processing based on the transfer function thus given to the spread signal.

  That is, the prediction process and the despreading process described above are achieved under the filtering characteristics indicated by a single transfer function obtained in advance based on the linearity of these processes.

  Therefore, with regard to hardware that performs such prediction processing and despreading processing, as long as rounding errors, truncation errors, and other errors that occur in the course of these processes are small enough to be allowed, the degree of freedom of arrangement and mounting is ensured. The

  In the second despreader according to the present invention, the storage means 71 has a binary value that can be taken by the spreading code to be applied to the despreading process of the received wave, and the received wave is twice the chip rate of the spread code. Corresponding to the form of prediction processing that can be performed on the spread signal sampled in the baseband region at the above frequency, constants of different signs individually associated with these binary values and the prediction processing are provided. The products of all combinations with the transfer function indicating the filtering characteristics to be performed are stored in advance.

  The control means 72 performs filtering using, as a transfer function, a product corresponding to the logical value of the despread code to be applied to the despreading process described above and the form of the prediction process given together with the logical value. This is given to means 61.

  The filtering unit 61 generates a demodulated signal by performing filtering processing based on the transfer function thus given to the spread signal.

  That is, since the despreading process is performed without using a means for exclusively performing the despreading process, it is possible to simplify the hardware configuration and adapt to a high chip rate.

  In the first despreader according to the present invention, the prediction process and the despreading process are achieved under the filtering characteristics indicated by a single transfer function determined in advance based on the linearity of these processes. In addition, the hardware arrangement for performing the prediction process and the despreading process and the degree of freedom of mounting are ensured.

  Further, in the second despreader according to the present invention, the despreading process is performed without using a means for exclusively performing the despreading process, so that the hardware configuration is simplified and adaptation to a high chip rate is possible. It becomes possible.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 4 is a diagram showing a configuration of first to fourth wireless reception apparatuses related to the present invention.

  In the figure, components having the same functions and configurations as those shown in FIG. 14 are denoted by the same reference numerals, and description thereof is omitted here.

  4 differs from the conventional example shown in FIG. 14 in that an A / D conversion board 80 is provided instead of the A / D conversion board 142, and reception is performed instead of the receiver board 144. And the A / D conversion board 81 is connected to the receiver board 81 via a single line 82 instead of the lines 143-1 to 143-4.

  The difference in configuration between the A / D conversion board 80 and the A / D conversion board 142 is that the A / D converter (A / D) 83-1 instead of the A / D converters 146-1 to 146-4 is used. 83-4 is provided, and a multiplexer 84 to which a synchronization signal is externally supplied to the control terminal is provided as a final stage after the A / D converters 83-1 to 83-4.

  The difference between the configuration of the receiver board 81 and the receiver board 144 is that a demultiplexer 85 in which a demultiplexing input is connected to the line 82 and the above-described synchronization signal is given to the control terminal, and the demultiplexer 85. Interpolating filters 86-1 to 86-4 individually disposed between the four outputs of the receivers 147-1 to 147-4, and a matched filter 152 disposed in the first stage of the searcher 148. Is directly connected to the output of the interpolation filter 86-4.

  The interpolation filter 86-1 is arranged at the first stage, and has 31 stages of shift registers 87-1 having a delay time of (1/8 fc) per stage, and the input terminal of the shift register 87-1 and the output of each stage. A multiplier 88-1 to which a discrete signal including a bit string obtained in parallel is given and 31 coefficients (not shown) indicating a transfer function to be described later are given, and 31 of the multipliers 88-1 And an adder 89-1 disposed as the final stage.

  The configuration of the interpolation filters 86-2 to 86-4 is the same as the configuration of the interpolation filter 86-1, and therefore, in the following, the same constituent numbers “2” to “4” are added to the corresponding components. Reference numerals are given, and the description and illustration thereof are omitted here.

  Further, regarding the correspondence relationship between the wireless reception device shown in FIG. 4 and the principle configuration diagram shown in FIG. 1, the antennas 141-1 to 141-4 correspond to the antennas 10-1 to 10-N, and the front end unit 145-1 to 145-4 and A / D converters 83-1 to 83-4 correspond to the thinning processing means 11-1 to 11-N, the multiplexer 84 corresponds to the multiplexing means 12, and the demultiplexer 85 Corresponding to the demultiplexing means 13, the interpolation filters 86-1 to 86-4 correspond to the prediction processing means 14-1 to 14-N, and the matched filter 152, the averaging unit 153 and the RAM 154 correspond to the path monitoring means 21. The path detection unit 155 corresponds to the phase specifying unit 22, and the reception units 147-1 to 147-4 correspond to the despreading processing unit 23.

  Hereinafter, the operation of the wireless reception apparatus shown in FIG. 4 will be described.

  In the A / D conversion board 80, the A / D converters 83-1 to 83-4 take in the spread signals obtained by the front end units 145-1 to 145-4, respectively, and as shown in FIG. These spread signals are recycled without overlapping on the time axis in a period (= 1 / 2fc) (hereinafter referred to as "decimation sampling period") that is four times the above oversampling period (= 1 / 8fc). To discretely generate discrete signals.

  The multiplexer 84 generates a multiplexed discrete signal by multiplexing the discrete signal generated by the A / D converters 83-1 to 83-4 on the time axis while synchronizing with the synchronization signal. Then, the multiplexed discrete signal is sent to the line 82.

  On the other hand, in the receiver board 81, the demultiplexer 85 performs the demultiplexing process opposite to the multiplexing process performed by the multiplexer 84 on the multiplexed discrete signal as described above, thereby performing the four discrete processes described above. The signals are restored, and these discrete signals are supplied to the interpolation filters 86-1 to 86-4, respectively.

Further, the multipliers 88-1 to 88-4 constituting the interpolation filters 86-1 to 86-4 have a bandwidth equal to four times the chip rate fc (the above-mentioned “decimation sampling frequency”) in the baseband region. For a time function C _n = f (n / 8fc) defined as a Fourier transform (FIG. 6 (b)) of a frequency function (FIG. 6 (a)) showing an ideal rectangular passband,
_{C -16, C -15, ...,} C -1, C 1, C 2, ..., C 16
A transfer function consisting of a sequence C of coefficients defined by

  The interpolation filters 86-1 to 86-4 are transversal filters having a transfer function given as a sequence of these coefficients C (for example, in the interpolation filter 86-1, a shift register 87-1 and a multiplier 88- 1 and an adder 89-1.

  That is, in the interpolation filters 86-1 to 86-4 (adders 89-1 to 89-4), four discrete signals generated in the oversampling process performed in the thinning sampling period in the A / D conversion board 80. Are instantaneously interpolated every (1/8 fc) on the time axis and given in parallel to the four inputs of the receiving units 147-1 to 147-4.

  Note that the operations of the receiving units 147-1 to 147-4 and the searcher 148 are the same as those in the conventional example, and therefore the description thereof is omitted here.

  As described above, according to the wireless receiver shown in FIG. 4, discrete signals generated at different phases and a common thinning sampling period in the A / D conversion board 80 are multiplexed and sent out to the transmission line 82 to be transmitted. In the receiver board 81 facing through the path 82, these discrete signals are demultiplexed by the demultiplexer 85, and interpolation processing (prediction processing) performed by the interpolation filters 86-1 to 86-2. It is restored below and given in parallel to the receiving units 147-1 to 147-4.

  Therefore, according to the wireless receiver shown in FIG. 4, the number of lines to be formed between the A / D conversion board 80 and the receiver board 81 is reduced to less than the number of antennas 144-1 to 144-4. As long as the deviation of accuracy of the interpolation processing (prediction processing) performed by the interpolation filters 86-1 to 86-4 is allowed, the transmission quality is maintained high.

  FIG. 7 is a diagram illustrating another configuration example of the first to fourth wireless reception apparatuses related to the present invention.

  7, components having the same functions and configurations as those shown in FIG. 4 are given the same reference numerals, and description thereof is omitted here.

  The difference between the configuration of the wireless reception device shown in FIG. 7 and the configuration of the wireless reception device shown in FIG. 4 is the configuration of the receiver board 90 provided in place of the receiver board 81.

  The difference between the configuration of the receiver board 90 and the receiver board 81 is that interpolation filters 91-1 to 91-4 are provided instead of the interpolation filters 86-1 to 86-4, and the four outputs of the demultiplexer 85 are The searcher 92 arranged between the coefficient input terminals of the interpolation filters 91-1 to 91-4 is provided in place of the searcher 148.

  The interpolation filter 91-1 is arranged at the first stage, and has a seven-stage shift register 93-1 having a delay time (1 / 2fc) per stage, and an input terminal of the shift register 93-1 and an output of each stage. A multiplier 94-1 to which a discrete signal composed of bit strings obtained in parallel is given, an adder 95-1 connected to eight outputs of the multiplier 94-1 and arranged as the final stage, and an input Is connected to the corresponding output of the searcher 92, and the output is connected to the ROM 96-1 connected to the coefficient input of the multiplier 94-1.

  The configuration of the interpolation filters 91-2 to 91-4 is the same as the configuration of the interpolation filter 91-1, and therefore, in the following, the same constituent numbers “2” to “4” are added to the corresponding components. Reference numerals are given, and the description and illustration thereof are omitted here.

  The difference between the configuration of the searcher 92 and the searcher 148 is that matched filters 97-1 to 97-4 directly connected to the four outputs of the demultiplexer 85 are provided in place of the matched filter 152. -1 to 97-4 are connected in cascade to the averaging units 98-1 to 98-4, which are connected directly to the outputs of the averaging units 98-1 to 98-4. The RAM 99 is provided in place of the RAM 154, the path detecting unit 100 is provided in place of the path detecting unit 155, the first to fourth outputs of the path detecting unit 100 are individually connected to the clock input, and the data Latches (L) 101-1 to 101-4 to which synchronization signals are given in parallel with the inputs are provided, and the outputs of these latches 101-1 to 101-4 and interpolation filters 91-1 to 91-4 are provided respectively. R The mapping ROM 102-1 is arranged between the OM 96-1 to 96-4 inputs.

  The difference between the configurations of the matched filter 97-1 and the matched filter 152 is that the delay time per stage is (1 / 2fc) and the number of stages is (2L-1) with respect to the word length L of the despread code. A shift register 103-1 is provided in place of the shift register 156, and a multiplier 104-1 is provided in place of the multiplier 157 for multiplying the input terminal of the shift register 103-1 and outputs of all stages by a weight described later. The adder 105-1 disposed as the final stage after the multiplier 104-3 is provided in place of the adder 158.

  Note that the configurations of the matched filters 97-2 to 97-4 are the same as the configurations of the matched filter 97-1, and therefore, the same reference numerals with “2” to “4” assigned to the corresponding constituent elements, respectively. Here, the description and illustration thereof are omitted.

  Further, regarding the correspondence relationship between the wireless reception device shown in FIG. 7 and the principle configuration diagram shown in FIG. 1, the interpolation filters 91-1 to 91-4 correspond to the prediction processing means 14-1 to 14-N, The matched filters 97-1 to 97-4, the averaging units 98-1 to 98-4, and the RAM 99 correspond to the path monitoring unit 21, and the path detection unit 100, the latches 101-1 to 101-4, and the mapping ROM 102 specify the phase. Except for the point corresponding to the means 22, it is the same as the correspondence relationship in the wireless receiver shown in FIG.

  Hereinafter, the operation of the wireless reception apparatus shown in FIG. 7 will be described.

In the receiver board 90, the ROMs 96-1 to 96-4 provided in the interpolation filters 91-1 to 91-4 are stored in the functions C _n = f (n / _n ) as shown in FIG. 8fc)
_{(1) C -16, C -12} , C -8, C -4, C 1, C 5, C 9, C 13
_{(2) C -15, C -11} , C -7, C -3, C 2, C 6, C 10, C 14
_{(3) C -14, C -10} , C -6, C -2, C 3, C 7, C 11, C 15
_{(4) C -13, C -9} , C -5, C -1, C 4, C 8, C 12, C 16
The four coefficient columns (1) to (4) defined as follows are stored in advance.

  Further, in the mapping ROM 102 provided in the searcher 92, as shown in FIG. 8 (b), among the above-described coefficient columns (1) to (4), values “0” to “3” given as synchronization signals are provided. ”Is stored in advance as identification information indicating unique coefficient columns corresponding to“ (for the sake of simplicity, it is assumed that any one of “(1)” to “(4)”).

  In the searcher 92 provided in the receiver boat 90, the shift registers 103-1 to 103-4 sequentially store the four discrete signals restored by the demultiplexer 85 in parallel, and the multipliers 104-1 to 104-104. -4 and adders 105-1 to 105-4 reciprocally take the correlation between the accumulated discrete signals and the despread codes given in advance as the weights described above.

  Averaging sections 98-1 to 98-4 average the correlation results described above for each despread code period and in chronological order over a period that is a multiple of the despread code period. Thus, as shown by a solid line, a dotted line, a broken line, and a one-dot chain line in FIG. 9, a delay profile composed of a set of power distributions given at intervals of (1 / 2fc) on the time axis is obtained. Store in the RAM 99.

  The path detection unit 100 reads out the delay profiles stored in the RAM 99 in this order in time series and in synchronism with the despreading code, thereby setting a predetermined threshold value in the above-described number sequence indicating the power. A “path detection signal” composed of a pulse train indicating a point in time when an average value exceeding the maximum value is detected is cyclically output at the period of the despread code.

  The receiving units 147-1 to 147-4 operate in response to these path detection signals basically in the same manner as in the conventional example, and here, the receiving units 147-1 to 147-4 The description of the operation is omitted.

  The latches 101-1 to 101-4 are synchronization signals indicating which of the discrete signals generated by the A / D converters 83-1 to 83-4 are being restored by the demultiplexer 85. Are held in parallel, and the value of the synchronization signal (any one of “0” to “3”) at the time when the path detection signal is output by the path detection unit 100 is held.

  When the value of the synchronization signal is held in any one of the latches 101-1 to 101-4 (hereinafter referred to as “effective latch” for simplicity), the mapping ROM 102 is stored in advance. Among the identification information (1) to (4), identification information corresponding to the value is acquired. Further, the mapping ROM 102 is an interpolation filter corresponding to the above-described effective latch among the interpolation filters 91-1 to 91-4 (hereinafter referred to as “effective interpolation filter” for simplicity, and “interpolation filter 91 for simplicity”. -1 ").) Is given its identification information.

  In the effective interpolation filter 91-1, the ROM 96-1 reads out the coefficient column corresponding to the identification information from the coefficient columns stored in advance, and gives it to the multiplier 94-1, so that it is given as the sequence column. It operates as a transversal filter having a transfer function.

  Therefore, according to the radio reception apparatus shown in FIG. 7, the interpolation filters 91-1 to 91-4 each have four discrete signals generated in the oversampling process performed by the A / D conversion board 80. By switching the coefficients of the multipliers 94-1 to 94-4, among the instantaneous values that are not actually included in these discrete signals, the instantaneous value when the “path detection signal” is given by the path detection unit 100. The value is interpolated on the phase space and given in parallel to the four inputs of the receiving units 147-1 to 147-4.

  Further, in the radio receiving apparatus shown in FIG. 7, the searcher 92 is provided with latches 101-1 to 101-4 and mapping ROM 102 which are not provided in the searcher 148 in comparison with the radio receiving apparatus shown in FIG. ROMs 96-1 to 96-4 that are not included in the interpolation filters 86-1 to 86-4 are included in the interpolation filters 91-1 to 91-4, respectively.

  However, the total number of stages of shift registers 93-1 to 93-4 provided in the interpolation filters 91-1 to 91-4, multipliers 94-1 to 94-4 and adders 95-1 to 95- The scale of the hardware 4 includes the total number of stages of shift registers 87-1 to 87-4 provided in the interpolation filters 86-1 to 86-4, multipliers 88-1 to 88-4, and an adder, respectively. This corresponds to approximately “1/4” (= ((1/8 fc) / (1/2 fc)) of the hardware scale of 89-1 to 89-4.

  Furthermore, the sum of the number of stages of the shift registers 103-1 to 103-4 provided in the matched filters 97-1 to 97-4, the multipliers 104-1 to 104-4, and the adders 105-1 to 105-4 The hardware scale is approximately equal to the number of stages of the shift register 156 provided in the matched filter 152 and the hardware scale of the multiplier 157 and the adder 158, respectively.

  Further, the hardware scale of the averaging units 98-1 to 98-4 is larger than the hardware scale of the averaging unit 153, but should be performed by the interpolation filters 91-1 to 91-4 and the searcher 92. The speed of the main calculation is “¼” (= ((1/8 fc) / (1/2 fc)) of the speed of the calculation to be performed in the same manner in the interpolation filters 86-1 to 86-4 and the searcher 148. It becomes.

  Therefore, in the radio receiving apparatus shown in FIG. 7, the hardware scale does not increase significantly and the operation speed becomes lower than that of the radio receiving apparatus shown in FIG. At the same time, restrictions on EMI radiation can be relaxed.

  In the wireless receiving apparatus shown in FIG. 7, the interpolation filters 91-1 to 91-4 are provided with ROMs 96-1 to 96-4, respectively. For example, as shown in FIG. ) Are given to the input terminal in different permutations, and selectors 105-1 to 105-4 whose selection inputs are connected to the outputs of the latches 101-1 to 101-4 are provided in the mapping ROM 102, respectively. Instead, the outputs of the selectors 105-1 to 105-4 may be directly connected to the multipliers 94-1 to 94-4 without going through the ROMs 96-1 to 96-4.

  The selectors 105-1 to 105-4 are arranged in the interpolation filters 91-1 to 91-4 in place of the ROMs 96-1 to 96-4, respectively, or the above-described four coefficient columns are arranged in parallel. It may be configured as an annular shift register that is loaded and circulates in synchronization with the synchronization signal.

  FIG. 11 is a diagram illustrating a configuration example of a fifth wireless reception apparatus related to the present invention.

  11, components having the same functions and configurations as the components shown in FIG. 7 are denoted by the same reference numerals, and description thereof is omitted here.

  The radio receiver shown in FIG. 11 differs from the radio receiver shown in FIG. 7 in that a searcher 110 is provided in place of the searcher 92, a synchronization signal is given to the selection input, and four inputs are provided. The selector 111 to which the outputs of the interpolation filters 91-1 to 91-4 are connected is provided in the preceding stage of the searcher 110.

  The difference between the configuration of the searcher 110 and the searcher 92 is that an averaging unit 112 is provided instead of the averaging unit 98-1, and the RAM 113 in which the control output of the selector 111 is connected to a specific address input is replaced with the RAM 99. The control output of the averaging unit 112 is connected to the control input of the selector 111, and matched filters 97-2 to 97-4 and averaging units 98-2 to 98-4 are provided in the preceding stage of the RAM 113. The output of the selector 111 is directly connected to the input of the matched filter 97-1.

  Note that the selector 111, the matched filter 97-1, the averaging unit 112-1, and the RAM 113 correspond to the path monitoring unit 31 with respect to the correspondence relationship between the wireless reception device illustrated in FIG. 11 and the principle configuration diagram illustrated in FIG. Then, except for the point that the path detection unit 100, the latches 101-1 to 101-4 and the mapping ROM 102 correspond to the phase specifying means 32, it is the same as the correspondence relationship in the radio reception apparatus shown in FIGS.

  Hereinafter, the operation of the wireless reception apparatus shown in FIG. 11 will be described.

  The selector 111 counts immediately after the synchronization signal is updated following the time when a control signal described later is given to the control input described above, and selects signals ("0" to "0" synchronized with the synchronization signal). 3 ”is generated cyclically.) And this selection signal is given to the RAM 113.

  Further, the selector 111 selects discrete signals associated in advance in the order of the value of the selection signal described above from among the discrete signals output by the interpolation filters 91-1 to 91-4.

  In the searcher 110, the matched filter 97-1 takes the correlation between the discrete signal thus selected and the despread signal in the same manner as the radio reception apparatus shown in FIG. 7, and the averaging unit 112 calculates the correlation. A delay profile is obtained by obtaining the resulting power distribution in a cyclic order in time series.

  The averaging unit 112 stores the delay profile in a storage area corresponding to the value of the selection signal given by the selector 111 in the storage area of the RAM.

  Further, when the power given as the delay profile in the order of the time series exceeds a predetermined threshold or power exceeding the threshold is not obtained for a predetermined period, the averaging unit 112 sends the selector 111 a selector 111. A control signal indicating this is given.

  When this control signal is given, the selector 111 updates the value of the selection signal by counting as described above, and gives the selection signal to the RAM 113.

  That is, by applying the searcher 110 in place of the searcher 92 and adding the selector 111, the interpolation filters 91-1 to 91-4 operate in the same manner as in the wireless reception device shown in FIG.

  Therefore, according to the wireless reception device shown in FIG. 11, the hardware configuration is simplified as long as the time required for obtaining the delay profile is short enough.

  FIG. 12 is a diagram showing the sixth and seventh radio reception apparatuses related to the present invention and the first despreader according to the present invention.

  In the figure, components having the same functions and configurations as those shown in FIG. 7 are given the same reference numerals, and the description thereof is omitted here.

  The difference between the configuration of the radio receiving apparatus shown in FIG. 12 and the radio receiving apparatus shown in FIG. 7 is that the interpolation filters 91-1 to 91-4 are not provided, and the receiving units 147-1 to 147-4 are provided. The alternative receiving units 121-1 to 121-4 are directly connected to the four outputs of the demultiplexer 85.

  The receiving unit 121-1 is shared by the interpolation / despreading filters 122-11 to 122-14 directly connected to the four outputs of the demultiplexer 85, and these interpolation / despreading filters 122-11 to 122-14. And a despreading code generator (CODE) 150-1.

  Among these interpolation / despreading filters 122-11 to 122-14, as shown in FIG. 12, the interpolation / despreading filter 122-11 includes the interpolation filters 91-1 to 91-4 shown in FIG. And 147-1 are merged as shown in the following (a) to (d).

The components of the interpolation / despreading filter 122-11 are shown in FIG. 7 as a general rule in order to enable distinction from the components of the other interpolation / diffusion filters 122-12 to 122-14. 14 is left as the second subscript number, and “1” is added as the first subscript number, and the interpolation filters 91-1 to 91-4 shown in FIG. 14 and the receiving unit 147-1 shown in FIG. I decided to.
(a) A multiplier 123-11 instead of the multiplier 149-11 is arranged between the ROM 96-11 and the multiplier 94-11.
(b) The output of the despread code generator 150-1 is connected to the (multiplier) multiplier input of the multiplier 123-11.
(c) The dump filter 151-1 is merged with a transversal filter comprising a shift register 93-11, a multiplier 94-11 and an adder 95-11.
(d) Multipliers 149-11 to 149-14 and dump filters 151-11 to 155-14 are not provided.

  The configuration of the interpolation / despreading filters 122-12 to 122-14 is the same as the configuration of the interpolation / diffusion filter 122-11. “2” to “4” are added and the description and illustration are omitted here.

  Further, regarding the correspondence relationship between the despreader shown in FIG. 12 and the block diagram shown in FIG. 2, the receiving units 121-1 to 121-4 correspond to the filtering means 61, and the searcher 92 corresponds to the control means 62. .

  Hereinafter, the operation of the radio receiving apparatus including the first despreader according to the present invention will be described.

  ROM 96-11 to 96-14,..., 96-41 to 96-44 are similar to the ROMs 96-1 to 96-4 provided in the wireless receiver shown in FIG. A column of coefficients shown is stored in advance.

  The despread code generation units 150-1 to 150-4 generate despread codes synchronized with the path detection signal output from the path detection unit 100 provided in the searcher 92, in the same manner as the radio reception apparatus shown in FIG. Generate.

  ROM 96-11 to 96-14,..., 96-41 to 96-44 output a coefficient sequence corresponding to the identification information given by the mapping ROM 102 provided in the searcher 92, among the above-described coefficient sequence, and Multipliers 123-11 to 123-14,..., 123-41 to 123-44 respectively obtain these coefficient sequences and the despread codes generated by the despread code generation units 150-1 to 150-4, respectively. While multiplying, the products of both are given to the multipliers 94-11 to 94-14,..., 94-41 to 94-44.

  That is, in the reception units 121-1 to 121-4, shift registers 93-11 to 93-14, ..., 93-41 to 93-44, multipliers 94-11 to 94-14, ..., 94-41 to 94 are used. , And adders 95-11 to 95-14,..., 95-41 to 95-44, transfer functions of transversal filters are ROM 96-11 to 96-14,. -44 is appropriately set as the product of the coefficient sequence given by -44 and the despread code given by the despread code generators 150-1, ..., 150-4.

  As described above, according to the despreader shown in FIG. 12, the interpolation process and the despreading process are performed collectively with a configuration different from that of the radio reception apparatus shown in FIG. Similar to the apparatus, even when the number of antennas indicated by reference numeral “141” is large, restrictions on hardware implementation are relaxed, and interference suppression based on the sector zone configuration and diversity reception method is possible. Become.

  In the despreader shown in FIG. 12, the interpolation / despread filters 122-11 to 122-14,..., 122-41 to 122-44 have ROMs 96-11 to 96-14,. 96-44 is provided, but if means for securely holding the coefficients to be given to the multipliers 123-11 to 123-14,... 123-41 to 123-44 is provided, these ROMs 96- 11 to 96-14,..., 96-41 to 96-44 may be provided as a common ROM in all or each of the receiving units 121-1 to 121-4.

  In the despreader shown in FIG. 12, the interpolation / despreading filters 122-11 to 122-14,..., 122-41 to 122-44 are shifted to the shift registers 93-11 to 93-14,. ... 93-44 are provided, and these shift registers 93-11 to 93-14,..., 93-41 to 93-44 are shared by the receiving units 121-1 to 121-4. It may be provided as a register.

  FIG. 13 is a diagram showing the eighth and ninth radio receiving apparatuses related to the present invention and the second despreader according to the present invention.

  In the figure, components having the same functions and configurations as those shown in FIG. 12 are given the same reference numerals, and description thereof is omitted here.

  The difference between the present embodiment and the embodiment shown in FIG. 12 is the configuration of receiving units 131-1 to 131-4 provided in place of the receiving units 121-1 to 121-4.

  The difference between the configuration of the receiving unit 131-1 and the receiving unit 121-1 is that interpolation / despreading filters 132-11 to 132-14 are provided instead of the interpolation / despreading filters 122-11 to 122-14. In the point.

  The difference between the configuration of the interpolation / despreading filter 132-11 and the interpolation / despreading filter 122-11 is that the ROM 133-11 is provided instead of the ROM 96-11, the multiplier 123-11 is not provided, and the ROM 133- 11 is directly connected to the multiplier 94-11, and a specific address input of the ROM 133-11 (here, for the sake of simplicity, it is assumed that only one bit of the MSB is generated) is generated as a despread code. The output of the unit 150-1 is connected.

  Note that the configuration of the interpolation / despreading filters 132-12 to 132-14 is the same as that of the interpolation / despreading filter 132-11. Suppose that the same code | symbol which each added 2 "-" 4 "is provided, The description and illustration are abbreviate | omitted here.

  Further, the configuration of the receiving units 131-2 to 131-4 is the same as the configuration of the receiving unit 131-1. Therefore, in the following description, "2" to "4" Are given the same reference numerals, and the description and illustration thereof are omitted here.

  Further, regarding the correspondence relationship between this embodiment and the block diagram shown in FIG. 3, shift registers 93-11 to 93-14,..., 93-41 to 93-44, multipliers 94-11 to 94-14,. , 94-41 to 94-44 and adders 95-11 to 95-14, ..., 95-41 to 95-44 correspond to the filtering means 61, and ROM 133-11 to 133-14, ..., 133-41 to 133-44 corresponds to the storage unit 71, and the searcher 92 and the despread code generation units 150-1 to 150-4 correspond to the control unit 72.

  Hereinafter, the operation of the radio receiving apparatus including the second despreader according to the present invention will be described.

  The despread code generation units 150-1 to 150-4 generate despread codes that are synchronized with the path detection signal output by the path detection unit 100, respectively.

  The mapping ROM 102 outputs identification information in the same manner as in the embodiment shown in FIG.

  On the other hand, the ROMs 131-11 to 133-14,..., 131-41 to 131-44 are associated with the four coefficient sequences shown in FIG. 8 (a) and the logical values of the despread codes described above. , The product of the binary values corresponding to the logical values (here, for the sake of simplicity, it is assumed that they are “−1” and “1”) and the columns of these coefficients is stored in advance.

  Furthermore, the ROMs 131-11 to 133-14,..., 131-41 to 131-44 multiply the products corresponding to the logical values of these despread codes and the identification information described above, among the products stored in advance. , 94-41 to 94-44.

  That is, shift registers 93-11 to 93-14, ..., 93-41 to 93-44, multipliers 94-11 to 94-14, ..., 94-41 to 94-44 and adders 95-11 to 95- , 95-41 to 95-44 has the same coefficient sequence as that of the coefficient sequence given in the embodiment shown in FIG. 41 to 123-44, and the despreading process is performed in parallel with the interpolation process according to the sequence of these coefficients.

  Therefore, according to this embodiment, the sizes of the storage areas of the ROMs 133-11 to 133-14,... 133-41 to 133-44 are the same as the ROMs 96-11 to 96-14 provided in the embodiment shown in FIG. ,... Doubles the storage area of 96-41 to 96-44, but the multipliers 123-11 to 123-14,..., 123-41 to 123-44 are not provided. Simplification can be achieved.

  Further, in the present embodiment, since multiplications to be performed in real time are omitted by these multipliers 123-11 to 123-14,..., 123-41 to 123-44, compared with the embodiment shown in FIG. Thus, high-speed despreading processing becomes possible.

  In each of the above-described embodiments, the despreader according to the present invention is applied to the receiving end of the wireless transmission system to which the CDMA system is applied. However, these inventions are not limited to such a CDMA wireless transmission system. However, the present invention can be applied to a wireless transmission system to which the FDMA scheme or the TDMA scheme is applied, and can be applied regardless of the modulation scheme applied together with these multiple access schemes.

  Further, in each of the above-described embodiments, the despreader according to the present invention is applied to the radio base station of the mobile communication system in which the radio zone is formed as a sector zone. The present invention is not limited to the mobile communication system to which is applied, and can be applied to other wireless transmission systems.

  Further, in each of the above-described embodiments, the channel configuration and the channel setting procedure applied as the mobile communication system are not shown. However, the present invention is independent of the channel configuration and the channel setting procedure. Applicable.

  Further, in each of the above-described embodiments, neither a multiplexing method to be performed by the multiplexer 84 nor a transmission format of a signal to be transmitted through the line 82 is shown. Any known technique may be applied to the transmission format.

  Further, in each of the above-described embodiments, the values of the oversampling frequency and the thinning sampling frequency are not specifically shown, but for these frequencies, the number of antennas and the occupied bandwidth of the received wave (CDMA system is applied). In this case, any value can be used as long as it is adapted to the chip rate and the modulation process to be performed prior to the spreading process) and the interpolation process and the despreading process are reliably performed in the digital domain based on the sampling theorem. There may be.

  In each of the above-described embodiments, the A / D converters 83-1 to 83-4 perform A / D conversion at a common thinning sampling frequency in different phases set at regular intervals on the time axis. The phase to be subjected to such A / D conversion may be set at any interval on the time axis as long as the interpolation process is performed with a desired accuracy.

  Further, in each of the above-described embodiments, the interpolation process is performed by the above-described transversal filter, or the filtering process including the interpolation process and the despreading process is performed. May be composed of a multiplier that multiplies the output of the multiplier 123-11 and the output of the multiplier 123-11 and a dump filter.

  In each of the above-described embodiments, the interpolation process or both the interpolation process and the despreading process are performed by the transversal filter, but a transient response according to switching of the coefficient indicating the transfer function is allowed. For example, an IIR (Infinite Impulse Response) filter may be applied if it is short enough.

  Further, in each of the above-described embodiments, a plurality of receiving units are provided, to which channels are individually assigned based on the channel setting procedure and to which any of the symbols “147”, “121”, and “131” is assigned. However, the number of the receiving units may be “1” when, for example, a single call is to be formed via the wireless transmission path at the same time.

  Further, in each of the above-described embodiments, the demodulated signal to be subjected to the synthesis process is generated in the course of the despreading process in order to enable extraction of the component of the received wave that has arrived from the desired sector zone. The present invention is not limited to such a synthesis process. For example, in order to form a desired scanning antenna by the antennas 141-1 to 141-4, a part of phase scanning, frequency scanning and feeding point switching scanning or Any synthesis process that achieves all may be performed.

  As described above, the despreader according to the present invention can be applied not only to the receiving end of the radio transmission system to which the CDMA system is applied, but also to the radio transmission system to which the FDMA system or the TDMA system is applied, In addition, the present invention can be applied regardless of the modulation scheme applied together with these multiple access schemes. And by applying the first despreader according to the present invention, at the receiving end having the various configurations described above, the degree of freedom of hardware arrangement and mounting for performing prediction processing and despreading processing is ensured, In addition, by applying the second despreader, the hardware configuration is simplified and adaptation to a high chip rate is possible.

  Applying the despreader according to the present invention as described above is extremely useful at the receiving end of a radio transmission system such as a CDMA system.

It is a figure which shows the principle structure of the radio | wireless receiving apparatus relevant to this invention. It is a principle block diagram of the 1st despreader concerning this invention. FIG. 3 is a principle block diagram of a second despreader according to the present invention. It is a figure which shows the structure of the radio | wireless receiving apparatus relevant to this invention. It is a figure which shows the time of A / D converter sampling. It is a figure which shows the coefficient which should be set to an interpolation filter. It is a figure which shows another structure of the radio | wireless receiving apparatus relevant to this invention. It is a figure which shows the information which should be stored in ROM and mapping ROM. It is a figure which shows an example of the delay profile detected by a searcher. It is a figure which shows the other structural example of a searcher. It is a figure which shows another structure of the radio | wireless receiving apparatus relevant to this invention. It is a figure which shows embodiment corresponding to a 1st de-spreader. FIG. 6 is a diagram showing an embodiment corresponding to a second despreader. It is a figure which shows the structural example of the receiving system in the mobile communication system using an array antenna under a CDMA system. It is a figure which shows an example of a delay profile.

Explanation of symbols

10 antenna 11 decimation processing means 12 multiplexing means 13 demultiplexing means 14 prediction processing means 21, 31 path monitoring means 22, 32 phase identification means 23, 33 despreading processing means 41, 42 multiplication means 51, 71 storage means 61 filtering Means 62, 72 Control means 80, 142 A / D conversion board 81, 90, 144 Receiver board 82, 143 Line 83, 146 A / D converter (A / D)
84 Multiplexer 85 Demultiplexer 86, 91 Interpolation filter 87, 93, 103, 156 Shift register 88, 94, 104, 123, 149, 157 Multiplier 89, 95, 105, 158 Adder 92, 110, 148 Searcher 96, 133 ROM
97,152 Matched filter 98, 112, 153 Averaging unit 99, 113, 154 RAM
100, 155 Path detection unit 101 Latch (L)
102 Mapping ROM
105, 111 Selectors 121, 131, 147 Receivers 122, 132 Interpolation / Despread Filter 141 Antenna 145 Front End 150 Despread Code Generator (CODE)
151 Dump filter (DUMP)

Claims (2)

Filtering means for generating a demodulated signal by performing a prediction process and a despreading process on a spread signal obtained by sampling a received signal of a direct spreading method in a baseband region at a frequency of twice or more the chip rate of a spreading code;
Control means for taking a product of a transfer function indicating a filtering characteristic to be applied to the prediction process and a despreading code to be applied to the despreading process, and giving the product to the filtering means as a transfer function of the filtering means A despreader comprising: and. Filtering means for generating a demodulated signal by performing a prediction process and a despreading process on a spread signal obtained by sampling a received signal of a direct spreading method in a baseband region at a frequency of twice or more the chip rate of a spreading code;
Corresponding to the binary values that can be taken by the spreading code and the form of the prediction process, the constants of the different codes individually associated with these binary values and the transmission characteristics indicating the filtering characteristics to be subjected to the prediction process Storage means in which products of all combinations with functions are stored in advance;
Of the products stored in the storage means, the filter corresponding to the logical value of the despreading code to be applied to the despreading process and the prediction processing form given together with the logical value as a transfer function. A despreader comprising: control means for supplying to the means.

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