JP2017228835A - Transmitter, receiver, transceiver, transmitting method, and receiving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmitter, receiver, transceiver, transmitting method, and receiving method that can appropriately perform distortion compensation processing when the transmitter and receiver share an antenna.SOLUTION: A transmission time distortion compensation unit 11 applies distortion compensation processing to an input signal. An output unit 12 applies transmission processing to output of the transmission time distortion compensation unit 11 and outputs a transmission signal to be input into an antenna shared with a receiver. A transmission side storage unit 13 has stored a transmission path parameter to compensate distortion occurring on a transmission path between the output unit 12 and the antenna. A transmission side setting unit 14 sets the transmission time distortion compensation unit 11 on the basis of the transmission path parameter.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a transmitter, a receiver, a transceiver, a transmission method, and a reception method used for communication.

  There is a communication system in which an antenna is shared by a plurality of transceivers. FIG. 8A is a block diagram illustrating a configuration example of a system in which one antenna is shared by a plurality of transceivers. In the example illustrated in FIG. 8A, a communication system in which the antenna 600 is shared by the four transceivers 400-a to 400-d and the four transceivers 500-a to 500-d via the input / output unit 800. Information is transmitted and received by a communication system in which the antenna 700 is shared.

  FIG. 8B is a block diagram illustrating a configuration example of the input / output unit 800. As shown in FIG. 8B, the input / output unit 800 between each of the transceivers 400-a to 400-d and the antenna 600 has a power divider that demultiplexes or combines a transmission signal and a reception signal, and each of the transceivers. For each of 400-a to 400-d, a band-pass filter group having a transmission signal or reception signal frequency band as a pass band and a frequency band other than that as a stop band is arranged.

  FIG. 8C is a block diagram illustrating a configuration example of the transceiver 400-a illustrated in FIG. 8A. In a wireless communication system used for data communication at a high transmission rate, a distortion compensation technique is used for a transceiver in order to suppress signal deterioration.

  Therefore, with high transmission rate, high multilevel, and wideband digital modulation signals, it improves demodulation quality degradation due to amplitude distortion and group delay distortion caused by power amplifiers and filters, and spectrum degradation during wireless output. As a method, a method called DPD (Digital Pre-distortion) is used.

  Patent Document 1 describes an apparatus that performs distortion compensation processing by feeding back an output signal. The apparatus described in Patent Document 1 is based on a digital signal obtained by converting a signal output from an RF (Radio Frequency) power amplifier, which is a main cause of signal distortion in an output signal, through a feedback path. A coefficient (also called an equivalent parameter) is determined. The device described in Patent Document 1 can realize distortion compensation that follows the use situation so that the distortion compensation coefficient changes according to the fluctuation of the output level by providing the feedback path.

  Patent Literature 2 describes a system that performs distortion compensation processing based on preset parameters. In the system described in Patent Document 2, when a signal is received, after the frequency conversion and digital signal conversion in ADC (Analog to Digital Converter), the transmission station and the reception station, or the transmission station and the relay and reception Distortion compensation processing is performed using a distortion compensation coefficient for correcting distortion generated in the signal with the station.

  Patent Document 3 describes a system that adjusts distortion compensation processing on the transmission side based on a received signal subjected to distortion compensation processing on the reception side.

JP 2005-203925 A JP 2007-228057 A JP 2010-193266 A

  As shown in FIG. 8B, in the configuration in which the antenna 600 is shared by the plurality of transceivers 400-a to 400-d, the band-pass filters 800f-1 to 800f-8 disposed in the input / output unit 800 are used. These characteristics are steeply set in order to remove the influence of each transmission / reception signal from other than the signal band. As a result, the frequency characteristics of the group delay in the passband deteriorate. Therefore, even when distortion compensation processing is performed on the transmission signal and reception signal in the transceiver, the transmission path from the input / output end of the transceiver to the antenna coupling section and the reception from the antenna coupling section to the input / output end of the transceiver The signal is distorted in the path. Such distortion particularly has a large influence on the modulation signal that has been subjected to high-multilevel modulation, and it becomes difficult to appropriately transmit and receive the modulation signal that has been subjected to high-multilevel modulation.

  In the configuration as shown in FIGS. 8A to 8C, when distortion compensation processing is performed as in the apparatus described in Patent Document 1, it is compensated that the transmitter / receiver 400- in which feedback is performed. It is only distortion within a to 400-d, and cannot cope with signal degradation that occurs in the transmission path and reception path.

  In addition, as described in Patent Document 2, when compensation processing for distortion generated in the transmission signal path and distortion generated in the reception signal path is performed using common parameters, the transmission signal transmitted from the antenna is Includes inverse characteristic distortion corresponding to the compensation processing for distortion in the received signal. Therefore, the transmission signal is in an overcompensated state and the distortion characteristic is deteriorated. Therefore, the spectrum of the transmission signal is distorted, and there may occur a case where a predetermined standard such as a spectrum mask or an ALCR (Adjacent Channel Leakage Ratio) cannot be satisfied.

  Even in the apparatus described in Patent Document 3, the same problem as the system described in Patent Document 2 may occur.

  Accordingly, an object of the present invention is to provide a transmitter, a receiver, a transceiver, a transmission method, and a reception method that can appropriately perform distortion compensation processing when a plurality of transceivers share an antenna. To do.

  The transmitter according to the present invention includes a transmission distortion compensation unit that performs distortion compensation processing on an input signal, and a transmission unit that performs transmission processing on the output of the transmission distortion compensation unit and inputs the signal to an antenna shared with the receiver. Output means for outputting a signal, transmission-side storage means for storing transmission path parameters for compensating distortion generated in the transmission path between the output means and the antenna, and transmission based on the transmission path parameters. And a transmission-side setting means for setting the distortion compensation means.

  The receiver according to the present invention receives an input signal via an antenna shared with the transmitter, inputs means for performing reception processing on the received signal, distortion-time distortion compensation means for performing distortion compensation processing on the output of the input means, Reception side storage means for storing reception path parameters for compensating for distortion occurring in the reception path between the input means and the antenna, and reception side for setting reception time distortion compensation means based on the reception path parameters And setting means.

  The transceiver according to the present invention includes any one of the transmitters and any one of the receivers.

  The transmission method according to the present invention performs distortion compensation processing on an input signal, performs transmission processing on the signal subjected to distortion compensation processing, and outputs a transmission signal for input to an antenna shared with the receiver, The content of the distortion compensation processing is set based on a transmission path parameter for compensating for distortion generated in the transmission path between the output means for outputting the transmission signal and the antenna.

  The receiving method according to the present invention is an input means for receiving a received signal through an antenna shared with a transmitter, performing a receiving process on the received signal, applying a distortion compensation process to the signal subjected to the receiving process, and performing a receiving process. The content of the distortion compensation processing is set based on a reception path parameter for compensating for distortion generated in the reception path between the antenna and the antenna.

  According to the present invention, when a plurality of transceivers share an antenna, it is possible to appropriately perform distortion compensation processing.

It is a block diagram which shows the example of a connection of the transmitter / receiver of 1st Embodiment. It is a flowchart which shows the operation | movement at the time of transmission in the transmitter / receiver of 1st Embodiment. It is a flowchart which shows the example of the predetermined distortion compensation process in this embodiment. It is a flowchart which shows the operation | movement at the time of reception in the transmitter / receiver of 1st Embodiment. It is a flowchart which shows the example of the predetermined distortion compensation process in this embodiment. It is a block diagram which shows the structural example of the transmitting apparatus of 2nd Embodiment. It is a block diagram which shows the structural example of the receiver of 3rd Embodiment. It is a block diagram which shows the structural example of the system by which the one antenna is shared by several transmitter / receiver. It is a block diagram which shows the structural example of an input / output part. It is a block diagram which shows the structural example of the transmitter / receiver shown by FIG. 8A.

Embodiment 1. FIG.
A transceiver 300 according to the first embodiment will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a connection example of the transceiver 300 according to the first embodiment. As shown in FIG. 1, the transceiver 300 of the first embodiment is connected to an antenna 600 via an input / output unit 500. When the transmission / reception device 300 inputs the transmission signal to the input / output unit 500, the transmission signal corresponding to the transmission signal is input to the antenna 600 and transmitted. Also, the received signal received by the antenna 600 is subjected to filter processing in the input / output unit 500 and input to the transceiver 300.

  The input / output unit 500 is connected to the transmission / reception terminal 300a to which the transmission signal is output and the reception signal is input in the transceiver 300. The antenna 600 is connected to the antenna connection end 500 a of the input / output unit 500.

  A transceiver 400 is also connected to the input / output unit 500. Therefore, the transceiver 300 shares the input / output unit 500 and the antenna 600 with the transceiver 400. The input / output unit 500 is connected to a transmission / reception terminal 400a to which a transmission signal of the transceiver 400 is output and a reception signal is input. Therefore, as described above, the antenna connection terminal 500 a to which the antenna 600 shared by the transceiver 300 and the transceiver 400 is connected to the input / output unit 500, the transmission / reception terminal 300 a of the transceiver 300, and the transmission / reception terminal of the transceiver 400 Between 400a, a band pass filter having a steep frequency characteristic is arranged. That is, the frequency characteristics of the band pass filters 510-a to 510-d in the input / output unit 500 are steep. Note that the input / output unit 500 may be configured so that the antenna 600 is shared by more transceivers.

  As shown in FIG. 1, the input / output unit 500 includes bandpass filters 510-a to 510-d and circulators 520-a to 520c.

  Each of the bandpass filters 510-a to 510-d performs a predetermined filter process on the input signal.

  The circulator 520-a is connected to the transmission / reception end 300a of the transceiver 300 and the bandpass filters 510-a and 510-c. Then, the circulator 520-a inputs the transmission signal input from the transmission / reception end 300a of the transceiver 300 to the band pass filter 510-a. Further, the circulator 520-a inputs the reception signal that has been subjected to the filter processing by the band pass filter 510-c to the transmission / reception end 300a of the transceiver 300.

  The circulator 520-b is connected to the transmission / reception end 400a of the transceiver 400 and the bandpass filters 510-b and 510-d. Then, the circulator 520-b inputs the transmission signal input from the transmission / reception end 400a of the transceiver 400 to the band pass filter 510-b. Further, the circulator 520-b inputs the reception signal that has been subjected to the filter processing by the band pass filter 510-d to the transmission / reception end 400a of the transceiver 400.

  The circulator 520-c is connected to the bandpass filters 510-a to 510-d and the antenna connection end 500a. Circulator 520-b inputs the received signal received by the antenna via antenna connection end 500a to bandpass filters 510-c and 510-d. In addition, circulator 520-b inputs a transmission signal obtained by filtering the transmission signal by bandpass filters 510-a and 510-b to antenna 600 through antenna connection end 500a. The transmission signal input to the antenna 600 is transmitted.

  As shown in FIG. 1, the transceiver 300 includes a transmission unit 100 and a reception unit 200. The transmission unit 100 is a module for transmitting a transmission signal via the antenna 600, for example. The receiving unit 200 is a module for receiving a received signal via the antenna 600, for example. Therefore, the antenna 600 is shared by the transmission unit 100 and the reception unit 200.

  The transmission unit 100 includes a transmission signal processing unit 110, a feedback signal processing unit 130, and an oscillation signal supply unit 140 that supplies a transmission signal corresponding to the carrier frequency to the transmission signal processing unit 110 and the feedback signal processing unit 130. including.

  As illustrated in FIG. 1, the transmission signal processing unit 110 of the transmission unit 100 includes a band-pass filter 111, an analog-to-digital (A-D) converter 112, a transmission equalizer 113, a storage unit 114, and transmission equalization. A parameter calculation unit 115, a modulator 116, a digital-to-analog (DA) converter 117, a frequency converter 118, a power amplifier 119, and a bandpass filter 120 are included.

  The band pass filter 111 performs a filtering process on an input signal that is an input analog signal.

  The A-D converter 112 converts an input signal, which is an analog signal subjected to filter processing, into a digital signal.

  The transmission equalizer 113 performs a predetermined distortion compensation process on the input signal converted into the digital signal. Note that the transmission equalizer 113 is realized by a plurality of electronic circuits such as a processor having a function of performing distortion compensation, for example.

  The storage unit 114 stores parameters for the transmission equalizer 113 to perform a predetermined distortion compensation process on the input signal.

  The transmission equalization parameter calculation unit 115 calculates parameters used for a predetermined distortion compensation process performed by the transmission equalizer 113 based on the parameters stored in the storage unit 114 and a feedback signal described later. Do.

  The modulator 116 performs predetermined modulation processing on the input signal that has been subjected to predetermined distortion compensation processing.

  The DA converter 117 converts the modulated input signal into an analog signal. Note that, on the output side of the DA converter 117, for example, a high-pass filter that passes a signal having a frequency equal to or higher than a predetermined frequency is disposed.

  Based on the oscillation signal supplied from the oscillation signal supply unit 140, the frequency converter 118 converts the input signal converted into an analog signal into a transmission signal having a predetermined carrier frequency. Specifically, the frequency converter 118 converts, for example, the frequency band of the input signal from the baseband to the carrier frequency band. The frequency converter 118 may include a power amplifier for obtaining a voltage conversion gain.

  The power amplifier 119 amplifies the transmission signal. The power amplifier 119 is, for example, a power amplifier.

  The band pass filter 120 performs a filtering process on the transmission signal. Note that the band-pass filter 120 performs, for example, a filtering process against unwanted radiation.

  Then, the transmission signal subjected to the filter processing by the band pass filter 120 is input to the input / output unit 500 via the transmission / reception end 400a.

  The feedback signal processing unit 130 of the transmission unit 100 includes a frequency converter 131, an AD converter 132, and a demodulator 133. The feedback signal processing unit 130 receives the transmission signal amplified by the power amplifier 119 in the transmission signal processing unit 110 and attenuates the transmission signal according to the amplification degree in the power amplifier 119. A vessel may be arranged.

  Based on the oscillation signal supplied from the oscillation signal supply unit 140, the frequency converter 131 converts the transmission signal amplified by the power amplifier 119 into a feedback signal in a predetermined baseband frequency band. The frequency converter 131 may include a power amplifier for obtaining a voltage conversion gain.

  The AD converter 132 converts a feedback signal that is an analog signal into a digital signal. Note that, on the input side of the A-D converter 132, for example, a high-pass filter that passes a signal having a frequency equal to or higher than a predetermined frequency is disposed.

  The demodulator 133 performs a demodulation process corresponding to a predetermined modulation process performed by the modulator 116 on the feedback signal that is a digital signal. The feedback signal demodulated by the demodulator 133 is input to the transmission equalization parameter calculation unit 115.

  As shown in FIG. 1, the receiving unit 200 includes a band pass filter 201, a power amplifier 202, an oscillation signal supply unit 203, a frequency converter 204, an A / D converter 205, a demodulator 206, a reception equalizer 207, a storage Unit 208, reception equalization parameter calculation unit 209, DA converter 210, and bandpass filter 211.

  The band pass filter 201 performs a filtering process on the received signal input from the input / output unit 500 via the transmission / reception end 300a.

  The power amplifier 202 amplifies the received signal that has been subjected to the filter processing. The power amplifier 202 is, for example, a low noise amplifier.

  The oscillation signal supply unit 203 supplies a transmission signal corresponding to a predetermined carrier frequency. Instead of providing the oscillation signal supply unit 203, the oscillation signal supply unit 140 described above may be configured to supply an oscillation signal.

  Based on the oscillation signal supplied from the oscillation signal supply unit 203, the frequency converter 204 converts the reception signal amplified by the power amplifier 202 into a baseband signal in a predetermined baseband frequency band. The frequency converter 204 may include a power amplifier for obtaining a voltage conversion gain.

  The AD converter 205 converts a baseband signal, which is an analog signal based on the received signal, into a digital signal. Note that, on the input side of the AD converter 205, for example, a high-pass filter that passes a signal having a frequency equal to or higher than a predetermined frequency is disposed.

  The demodulator 206 performs a demodulation process corresponding to the modulation process performed on the transmission side of the received signal on the baseband signal that is a digital signal.

  The reception equalizer 207 performs a predetermined distortion compensation process on the baseband signal converted into the digital signal.

  The storage unit 208 stores parameters for the reception equalizer 207 to perform a predetermined distortion compensation process on the baseband signal.

  The reception equalization parameter calculation unit 209 calculates a parameter used for a predetermined distortion compensation process performed by the reception equalizer 207 based on the parameters stored in the storage unit 208.

  The DA converter 210 converts a baseband signal that is a digital signal subjected to distortion compensation processing into an analog signal.

  The band pass filter 211 performs a filtering process on the baseband signal converted into the analog signal.

  Note that the transmission distortion compensation means corresponds to, for example, the transmission equalizer 113. The output means corresponds to the modulator 116, the DA converter 117, the frequency converter 118, the power amplifier 119, and the band pass filter 120. The transmission side storage means corresponds to the storage unit 114, for example. The transmission side setting means corresponds to the transmission equalization parameter calculation unit 115, for example. The transmission path parameter corresponds to, for example, an output unit static parameter. The feedback path parameter corresponds to, for example, a transmission unit static parameter.

  The input means corresponds to the band-pass filter 201, the power amplifier 202, the frequency converter 204, the A-D converter 205, and the demodulator 206. The reception distortion compensation means corresponds to the reception equalizer 207, for example. The receiving side storage means corresponds to the storage unit 208, for example. The reception side setting unit 24 corresponds to the reception equalization parameter calculation unit 209, for example. The reception path parameter corresponds to, for example, an input unit static parameter. The input means parameter corresponds to, for example, a receiving unit static parameter.

  Next, the operation of the transceiver 300 of the first embodiment will be described. FIG. 2 is a flowchart illustrating an operation during transmission in the transceiver 300 according to the first embodiment.

  First, when an input signal is input, the input signal is filtered by the band pass filter 111 (step S101).

  Then, the A-D converter 112 converts the input signal, which is an analog signal filtered by the band pass filter 111, into a digital signal (step S102).

  The transmission equalizer 113 performs a predetermined distortion compensation process on the input signal converted into the digital signal (step S103).

  The predetermined distortion compensation process performed on the input signal in the process of step S103 will be described. In the present embodiment, the predetermined distortion compensation processing refers to transmission according to the distortion that occurs until an input signal is input to the transceiver 300 and is input to the antenna 600 via the antenna connection end 500a as a transmission signal. The credit equalizer 113 is a process for giving an inverse characteristic of the distortion to the input signal. By performing such distortion compensation processing, the transmission equalizer 113 compensates for distortion generated in a signal from being input to the transceiver 300 to being input to the antenna 600 via the antenna connection end 500a. . The distortion includes, for example, amplitude distortion and group delay distortion.

  FIG. 3 is a flowchart showing an example of a predetermined distortion compensation process in the present embodiment.

  For example, the transmission equalizer 113 inputs the input signal of the previous distortion compensation processing result to the transmission equalization parameter calculation unit 115 and instructs the calculation of the transmission equalization parameter. The transmission equalization parameter calculation unit 115 reads parameters from the storage unit 114 in response to an instruction from the transmission equalizer 113 (step S201).

  The parameters stored in the storage unit 114 will be described. The storage unit 114 stores transmission unit static parameters according to the distortion generated in the input signal and the transmission signal in the transmission signal processing unit 110. Specifically, the transmission unit static parameters include, for example, a band-pass filter 111, an A-D converter 112, a modulator 116, a D-A converter 117, a frequency converter 118, a power amplifier 119, and a band-pass filter 120. , A parameter corresponding to the distortion generated in the input signal or the distortion generated in the transmission signal. The parameter is, for example, a coefficient.

  The storage unit 114 stores dynamic parameters corresponding to the feedback signal. Specifically, for example, a parameter corresponding to the difference between the input signal input by the transmission equalizer 113 in the process of step S201 and the feedback signal is stored. As for the feedback signal, the input signal input to the modulator 116 together with the transmission equalization parameter calculation unit 115 by the transmission equalizer 113 includes the modulator 116, the DA converter 117, the frequency converter 118, and the power amplifier. 119, a signal input to the transmission equalization parameter calculation unit 115 via the frequency converter 131, the AD converter 132, and the demodulator 133. Therefore, the feedback signal is distorted in each part of the transmission path as compared with the input signal. Therefore, the distortion produced in the transmission path of the feedback signal is shown by the difference between the input signal and the feedback signal. Therefore, the dynamic parameter stored in the storage unit 114 is a parameter corresponding to the distortion caused by the transmission of the input signal, the transmission signal, and the feedback signal in the transceiver 300. The parameter is, for example, a coefficient.

  Further, the storage unit 114 stores a transmission signal in the input / output unit 500 and a static parameter for output unit corresponding to distortion generated in the transmission signal. Specifically, the static parameter for the output unit is a parameter according to, for example, distortion generated in the transmission signal or the transmission signal in the circulator 520-a, the band pass filter 510a, and the circulator 520-c. The parameter is, for example, a coefficient.

  The transmission equalization parameter calculation unit 115 reads the transmission unit static parameter, the dynamic parameter, and the output unit static parameter from the storage unit 114 in the process of step S201. Note that the dynamic parameter read by the transmission equalization parameter calculation unit 115 in the process of step S201 is, for example, a parameter corresponding to the feedback signal, and specifically, for example, the previous time input by the transmission equalizer 113 This parameter is a parameter corresponding to the difference between the input signal resulting from the distortion compensation processing and the feedback signal. The parameter is, for example, a coefficient. In addition, the transmission equalization parameter calculation unit 115 obtains at least one of the transmission unit static parameter, the dynamic parameter, and the output unit static parameter from the storage unit 114 in the process of step S201. It may be configured to read.

  Then, the transmission equalizer parameter calculation unit 115 inputs the transmission equalizer 113 this time based on the transmission unit static parameter, the dynamic parameter, and the output unit static parameter read out in the process of step S201. A transmission equalization parameter, which is a parameter used for distortion compensation processing applied to the input signal, is calculated (step S202). Note that the transmission equalization parameter calculation unit 115 may be further configured to calculate the transmission equalization parameter based on the input signal input by the transmission equalizer 113 this time.

  The transmission equalization parameter calculation unit 115 inputs the transmission equalization parameter calculated in the process of step S202 to the transmission equalizer 113. Then, the transmission equalizer 113 performs a predetermined distortion compensation process on the input signal based on the transmission equalization parameter calculated and input by the transmission equalization parameter calculation unit 115 (step S203). . Note that the predetermined distortion compensation process performed in the process of step S203 is performed by a known processing method.

  The transmission equalizer 113 inputs an input signal that has been subjected to predetermined distortion compensation processing in steps S103 and S203 to the modulator 116. The modulator 116 performs predetermined modulation processing on the input signal that has been subjected to predetermined distortion compensation processing in steps S103 and S203 (step S204).

  The DA converter 117 converts the input signal modulated in the process of step S204 into an analog signal (step S205).

  The frequency converter 118 converts the input signal converted into the analog signal in the process of step S205 from the baseband to the transmission signal in the carrier frequency band (step S206).

  The power amplifier 119 amplifies the transmission signal (step S207). The transmission signal amplified by the power amplifier 119 in the process of step S207 is subjected to filter processing by the band pass filter 120 and input to the input / output unit 500 via the transmission / reception end 400a.

  Here, the transmission signal input to the input / output unit 500 is distorted in the transmission path in the transceiver 300. However, the transmission equalizer 113 has already given and compensated the transmission signal with an inverse characteristic corresponding to the distortion.

  Then, the transmission signal input to the input / output unit 500 after the distortion in the transmission path in the transceiver 300 is compensated by the transmission equalizer 113 is input to the antenna 600 as the transmission signal via the antenna connection terminal 500a. Distortion has occurred in the transmission path in the input / output unit 500 until this time. However, the transmission equalizer 113 has already given and compensated the transmission signal with an inverse characteristic corresponding to the distortion.

  Next, the operation at the time of reception in the transceiver 300 will be described. FIG. 4 is a flowchart illustrating an operation at the time of reception in the transceiver 300 according to the first embodiment.

  First, when a reception signal is input from the input / output unit 500 via the transmission / reception end 400 a, the reception signal is subjected to filter processing by the band pass filter 201. Then, the power amplifier 202 amplifies the received signal that has been subjected to the filter processing (step S301).

  The frequency converter 204 converts the received signal amplified by the power amplifier 202 into a baseband signal in a predetermined baseband frequency band (step S302).

  The AD converter 205 converts a baseband signal, which is an analog signal based on the received signal, into a digital signal (step S303).

  The demodulator 206 performs a demodulation process on the baseband signal, which is a digital signal, according to the modulation process performed on the transmission side of the received signal (step S304).

  The reception equalizer 207 performs a predetermined distortion compensation process on the baseband signal converted into the digital signal (step S305).

  A predetermined distortion compensation process performed on the baseband signal in the process of step S305 will be described. The predetermined distortion compensation processing in the present embodiment is input from the antenna 600 to the input / output unit 500 via the antenna connection end 500a until it is input to the reception equalizer 207 as a baseband signal. This is a process in which the reception equalizer 207 imparts the inverse characteristic of the distortion to the baseband signal in accordance with the distortion generated in. The reception equalizer 207 performs such distortion compensation processing so that the signal is input from the antenna 600 to the input / output unit 500 via the antenna connection end 500a until it is input to the reception equalizer 207. Distortions that occur in the signal are compensated. The distortion includes, for example, amplitude distortion and group delay distortion.

  FIG. 5 is a flowchart showing an example of a predetermined distortion compensation process in the present embodiment.

  For example, the reception equalizer 207 instructs the reception equalization parameter calculation unit 209 to calculate reception equalization parameters. The reception equalization parameter calculation unit 209 reads parameters from the storage unit 208 in response to an instruction from the reception equalizer 207 (step S401).

  The parameters stored in the storage unit 208 will be described. The storage unit 208 stores static parameters for the reception unit corresponding to the distortion generated in the reception signal or the distortion generated in the baseband signal in the reception unit 200. Specifically, the static parameter for the reception unit is, for example, distortion generated in the reception signal or the baseband signal in the band pass filter 201, the power amplifier 202, the frequency converter 204, the AD converter 205, and the demodulator 206. It is a parameter according to. The parameter is, for example, a coefficient.

  In addition, the storage unit 208 stores input unit static parameters corresponding to the distortion generated in the received signal in the input / output unit 500. Specifically, the static parameter for the input unit is a parameter according to distortion generated in the received signal in the circulator 520-c, the band pass filter 510d, and the circulator 520-b, for example. The parameter is, for example, a coefficient.

  The reception equalization parameter calculation unit 209 reads the reception unit static parameter and the input unit static parameter from the storage unit 208 in the process of step S401.

  Then, the reception equalization parameter calculation unit 209 performs distortion compensation performed on the baseband signal by the reception equalizer 207 based on the reception unit static parameter and the input unit static parameter read out in step S401. A reception equalization parameter, which is a parameter used for processing, is calculated (step S402).

  The reception equalization parameter calculation unit 209 inputs the reception equalization parameter calculated in the process of step S <b> 402 to the reception equalizer 207. The reception equalizer 207 performs a predetermined distortion compensation process on the input baseband signal based on the reception equalization parameter calculated and input by the reception equalization parameter calculation unit 209 ( Step S403). Note that the predetermined distortion compensation process performed in the process of step S403 is performed by a known processing method.

  According to the present embodiment, the transmission equalizer 113 of the transmission unit 100 performs compensation processing on the input signal according to the distortion generated in the transmission path in the transceiver 300 and the input / output unit 500. In addition, the reception equalizer 207 of the reception unit 200 performs compensation processing on the baseband signal according to the distortion generated in the reception path in the transceiver 300 and the input / output unit 500. Specifically, the transmission equalizer 113 performs compensation processing using a parameter corresponding to the distortion generated in the transmission path, and the transmission equalizer 113 sets the parameter corresponding to the distortion generated in the transmission path. To perform compensation processing. The reception equalizer 207 performs compensation processing using a parameter corresponding to distortion generated in the reception path. Therefore, in the transmitter / receiver 300, the signal transmitted from the antenna 600 and the signal received by the antenna 600 are subjected to compensation processing according to the respective paths. Therefore, even when the antenna 600 is shared by the transceiver 300 and the transceiver 400 including the transmission unit 100 and the reception unit 200, respectively, and a bandpass filter having a steep frequency characteristic is used and distortion occurs in the signal, Distortion compensation processing can be performed appropriately. Then, it is possible to satisfactorily prevent adverse effects on the compensation processing at the time of transmission due to the parameters used for the compensation processing at the time of reception.

  In particular, according to the present embodiment, the transmission equalizer 113 and the reception equalizer 207 are distorted in the input / output unit 500, that is, the transmission / reception end 300a in the transceiver 300 and the antenna connection end in the input / output unit 500. Compensate for distortion that occurs in the path between 500a. Therefore, even if the antenna 600 is shared and a band pass filter having a steep characteristic is used in the input / output unit 500 as in this example, the transceiver 300 can appropriately perform distortion compensation processing.

  Furthermore, according to the present embodiment, the transmission equalizer 113 performs compensation processing based on the transmission unit static parameter and the dynamic parameter. Therefore, compared to a case where distortion compensation processing is performed based only on static parameters, the transmission equalizer 113 can perform distortion compensation processing more appropriately.

  In this example, the storage unit 114 and the storage unit 208 each store in advance parameters corresponding to the path between the transceiver 300 and the antenna 600 (the input / output unit 500 in this example). However, the storage contents of the storage unit 114 and the storage unit 208 may be configured to be changed according to the path between the transceiver 300 and the antenna 600. Specifically, for example, each parameter corresponding to a plurality of types of input / output units is stored in advance in the storage unit 114 and the storage unit 208, and the transmission equalizer 113 is set according to the setting by the administrator of the transceiver 300. Alternatively, the reception equalizer 207 may be configured to read parameters used for compensation processing. Further, the storage unit 114 and the storage unit 208 may be configured to be able to newly store parameters according to the path between the transceiver 300 and the antenna 600.

  According to such a configuration, the transmission equalizer 113 and the reception equalizer 207 can appropriately perform distortion compensation processing according to various input / output units.

  Each equalization parameter may include a parameter based on a group delay characteristic outside the compensation range in order to perform distortion compensation processing outside the compensation range, and may further approximate or specify the parameter. A parameter simplified and corrected by a variable may be included. Then, it may be configured to always perform distortion compensation processing outside the compensation range, or may be configured to perform distortion compensation processing when a predetermined condition is met. The predetermined condition is, for example, whether or not the antenna is connected in a predetermined connection state.

Embodiment 2. FIG.
Next, the transmitter 10 according to the second embodiment will be described with reference to the drawings. FIG. 6 is a block diagram illustrating a configuration example of the transmitter 10 according to the second embodiment.

  As illustrated in FIG. 6, the transmitter 10 of the second embodiment includes a transmission time distortion compensation unit 11, an output unit 12, a transmission side storage unit 13, and a transmission side setting unit 14.

  The transmission distortion compensator 11 corresponds to, for example, the transmission equalizer 113 in the first embodiment.

  The output unit 12 corresponds to the modulator 116, the DA converter 117, the frequency converter 118, the power amplifier 119, and the band-pass filter 120 in the first embodiment.

  The transmission side storage unit 13 corresponds to, for example, the storage unit 114 in the first embodiment.

  The transmission side setting unit 14 corresponds to, for example, the transmission equalization parameter calculation unit 115 in the first embodiment.

  The transmission distortion compensator 11 performs distortion compensation processing on the input signal.

  The output unit 12 performs a transmission process on the output of the transmission distortion compensation unit 11 and outputs a transmission signal to be input to an antenna sharing the receiver. The receiver corresponds to, for example, the receiving unit 200 in the first embodiment and the receiving unit in the transceiver 400. The antenna corresponds to, for example, the antenna 600 in the first embodiment.

  The transmission side storage unit 13 stores transmission path parameters for compensating for distortion that occurs in the transmission path between the output unit 12 and the antenna. Note that the transmission path parameter corresponds to, for example, the output unit static parameter in the first embodiment.

  The transmission side setting unit 14 sets the transmission time distortion compensation unit 11 based on the transmission path parameter.

  According to this embodiment, when a plurality of transceivers share an antenna, it is possible to appropriately perform distortion compensation processing.

Embodiment 3. FIG.
Next, a receiver 20 according to a third embodiment will be described with reference to the drawings. FIG. 7 is a block diagram illustrating a configuration example of the receiver 20 according to the third embodiment.

  As illustrated in FIG. 7, the receiver 20 of the third embodiment includes an input unit 21, a reception distortion compensation unit 22, a reception-side storage unit 23, and a reception-side setting unit 24.

  The input unit 21 corresponds to the band pass filter 201, the power amplifier 202, the frequency converter 204, the A / D converter 205, and the demodulator 206 in the first embodiment.

  The reception distortion compensator 22 corresponds to, for example, the reception equalizer 207 in the first embodiment.

  The reception-side storage unit 23 corresponds to, for example, the storage unit 208 in the first embodiment.

  The reception-side setting unit 24 corresponds to, for example, the reception equalization parameter calculation unit 209 in the first embodiment.

  The input unit 21 receives a reception signal through an antenna shared with the transmitter, and performs reception processing on the reception signal. The transmitter corresponds to, for example, the transmission unit 100 in the first embodiment or the transmission unit in the transceiver 400. The antenna corresponds to, for example, the antenna 600 in the first embodiment.

  The reception distortion compensation unit 22 performs distortion compensation processing on the output of the input unit 21.

  The reception-side storage unit 23 stores reception path parameters for compensating for distortion generated in the reception path between the input unit 21 and the antenna. The reception path parameter corresponds to, for example, the input unit static parameter in the first embodiment.

  The reception side setting unit 24 sets the reception distortion compensation unit 22 based on the reception path parameter.

  According to this embodiment, when a plurality of transceivers share an antenna, it is possible to appropriately perform distortion compensation processing.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

  (Supplementary note 1) Transmission distortion compensation means for performing distortion compensation processing on an input signal, and transmission signal for performing transmission processing on the output of the transmission distortion compensation means to be input to an antenna shared with a receiver An output means for outputting, a transmission side storage means for storing a transmission path parameter for compensating for distortion generated in a transmission path between the output means and the antenna, and based on the transmission path parameter, A transmitter comprising: transmission-side setting means for setting distortion compensation means during transmission.

  (Additional remark 2) The said transmission side memory | storage means is a transmitter of Additional remark 1 which can memorize | store the parameter according to the other transmission path | route as said transmission path | route parameter.

  (Supplementary note 3) The transmitter further includes feedback means for feeding back the output signal of the output means to the distortion compensation means upon transmission, and the transmission side storage means further includes the feedback signal. Accordingly, a dynamic parameter used in the distortion compensation processing is stored, and the transmission side setting unit sets the transmission time distortion compensation unit based on the transmission path parameter and the dynamic parameter. The transmitter according to appendix 2.

  (Supplementary Note 4) The transmission side storage means further stores a feedback path parameter corresponding to a path until the output signal of the output means is fed back by the feedback means, and the transmission side setting means further includes: The transmitter according to any one of appendix 1 to appendix 3, wherein the transmission distortion compensation unit is set based on the feedback path parameter.

  (Supplementary Note 5) An input unit that receives a received signal through an antenna shared with a transmitter and performs a reception process on the received signal, a distortion compensation unit at the time of reception that performs a distortion compensation process on the output of the input unit, A reception-side storage unit storing reception path parameters for compensating for distortion generated in the reception path between the input unit and the antenna, and the reception distortion compensation unit are set based on the reception path parameter And a receiving side setting means.

  (Supplementary note 6) The receiver according to supplementary note 5, wherein the reception-side storage unit can further store a parameter according to another reception path as the reception path parameter.

  (Supplementary Note 7) The reception-side storage means stores input means parameters used in the distortion compensation processing according to the distortion generated in the input means, and the reception-side setting means includes the reception path parameters and the reception path parameters. The receiver according to appendix 5 or appendix 6, wherein the reception distortion compensation unit is set based on the input unit parameter.

  (Supplementary note 8) A transmitter / receiver comprising the transmitter according to any one of supplementary notes 1 to 4 and the receiver according to any one of supplementary notes 5 to 7.

(Supplementary Note 9) Distortion compensation processing is performed on an input signal, transmission processing is performed on the signal subjected to the distortion compensation processing, and a transmission signal to be input to an antenna shared with a receiver is output.
Based on the transmission path parameter stored in the transmission-side storage means in which the transmission path parameter for compensating for distortion generated in the transmission path between the output means for outputting the transmission signal and the antenna is stored. A transmission method comprising setting contents of the distortion compensation processing.

  (Supplementary Note 10) Input means for receiving a reception signal through an antenna shared with a transmitter, performing a reception process on the reception signal, performing a distortion compensation process on the signal subjected to the reception process, and performing the reception process The content of the distortion compensation processing is set based on a reception path parameter for compensating for distortion generated in the reception path between the antenna and the antenna.

  (Supplementary Note 11) A transmission-time distortion compensation process that performs distortion compensation processing on an input signal and a transmission process that is performed on the signal that has been subjected to the distortion-compensation process by the transmission-time distortion compensation process are performed on a computer and shared with a receiver. Output processing for outputting a transmission signal for input to an antenna to be transmitted, and a transmission path parameter for compensating distortion generated in a transmission path between the output end of the transmission signal and the antenna, A transmission program for executing a transmission side setting process for setting contents of a distortion compensation process during transmission.

  (Supplementary Note 12) At the time of reception in which a reception signal is input to a computer via an antenna shared with a transmitter, the reception signal is subjected to reception processing, and the signal subjected to the reception processing is subjected to distortion compensation processing Based on a distortion compensation process and a reception path parameter for compensating for distortion generated in the reception path between the input unit to which the reception signal is input and the antenna, the contents of the reception distortion compensation process are set. A receiving program for executing the receiving side setting process.

DESCRIPTION OF SYMBOLS 10 Transmitter 11 Transmission time distortion compensation part 13 Transmission side memory | storage part 14 Transmission side setting part 20 Receiver 21 Input part 22 Reception time distortion compensation part 23 Reception side memory | storage part 24 Reception side setting part 100 Transmission part 110 Signal processing part for transmission 111, 120, 201, 211, 510-a, 510-b, 510-c, 510-d Band pass filter 112, 132, 205 A-D converter 113 Transmission equalizer 114, 208 Storage unit 115 For transmission, etc. Parameter calculation unit 116 Modulator 117, 210 DA converter 118, 204 Frequency converter 119, 202 Power amplifier 130 Feedback signal processing unit 131, 204 Frequency converter 133, 206 Demodulator 140, 203 Oscillation signal supply unit 200 Reception unit 207 Reception equalizer 209 Reception equalization parameter calculation unit 30 , 400 transceiver 300a, 400a receiving end 500 output unit 500a antenna connection terminal 520-a, 520-b, 520-c circulator 600 antennas

Claims (10)

A distortion compensation means for transmission that performs distortion compensation processing on the input signal;
Output means for performing transmission processing on the output of the distortion compensation means at the time of transmission and outputting a transmission signal for input to an antenna shared with the receiver;
Transmission side storage means in which transmission path parameters for compensating for distortion generated in the transmission path between the output means and the antenna are stored;
A transmitter comprising: transmission side setting means for setting the transmission time distortion compensating means based on the transmission path parameter. The transmitter according to claim 1, wherein the transmission side storage unit is capable of storing a parameter corresponding to another transmission path as the transmission path parameter. The transmitter further includes feedback means for feeding back the output signal of the output means to the distortion compensation means upon transmission,
The transmission side storage means further stores dynamic parameters used in the distortion compensation processing according to the fed back signal,
The transmitter according to claim 1, wherein the transmission side setting unit sets the transmission time distortion compensation unit based on the transmission path parameter and the dynamic parameter. The transmission side storage means further stores a feedback path parameter corresponding to a path until the output of the output means is fed back by the feedback means,
The transmitter according to any one of claims 1 to 3, wherein the transmission side setting unit further sets the transmission time distortion compensation unit based on the feedback path parameter. An input means for receiving a received signal through an antenna shared with a transmitter and performing a receiving process on the received signal;
Receiving distortion compensation means for performing distortion compensation processing on the output of the input means;
Receiving-side storage means storing reception path parameters for compensating for distortion generated in the receiving path between the input means and the antenna;
A receiver comprising: a receiving side setting unit that sets the reception distortion compensation unit based on the reception path parameter. The receiver according to claim 5, wherein the reception-side storage unit can further store a parameter according to another reception path as the reception path parameter. The receiving side storage means stores input means parameters used in the distortion compensation processing according to the distortion generated in the input means,
The receiver according to claim 5 or 6, wherein the reception side setting unit sets the reception distortion compensation unit based on the reception path parameter and the input unit parameter. A transmitter according to any one of claims 1 to 4,
A transceiver comprising: the receiver according to any one of claims 5 to 7. Apply distortion compensation to the input signal,
Apply the processing for transmission to the signal subjected to the distortion compensation processing, and output a transmission signal for input to the antenna shared with the receiver,
The content of the distortion compensation processing is set based on a transmission path parameter for compensating distortion generated in a transmission path between the output means for outputting the transmission signal and the antenna. . A received signal is input via an antenna shared with the transmitter, and the received signal is subjected to reception processing.
Perform distortion compensation processing on the signal subjected to the reception processing,
The content of the said distortion compensation process is set based on the parameter for receiving paths for compensating the distortion which arises in the receiving path between the input means which performs the said receiving process, and the said antenna. The receiving method characterized by the above-mentioned.

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