JP5251343B2 - Distortion compensation device, wireless communication device, distortion compensation method, and wireless communication method - Google Patents

Description

  The present invention relates to a distortion compensation device, a wireless communication device, a distortion compensation method, and a wireless communication method that perform signal distortion compensation.

  In recent wireless communication devices using microwaves, it is generally required to reduce power consumption and to reduce the size and cost of a heat dissipation unit. As one of the techniques, a distortion compensation type amplifier is used in order to increase the efficiency of a high-power amplifier in a transmission system. For example, a wireless communication apparatus that communicates with a mobile terminal transmits a signal amplified by a high-power amplifier from an antenna.

  In such a wireless communication apparatus, in order to improve the quality of the signal transmitted from the antenna, it is necessary to compensate for signal distortion such as frequency deviation (amplitude variation due to frequency difference) generated in the signal in the high-power amplifier. There is. For this reason, at the time of product manufacture, it is necessary to finely adjust the lumped constants and distribution constants of the individual parts constituting the nonlinear distortion circuit having nonlinear distortion, and to make the frequency deviation in the nonlinear distortion circuit as flat as possible.

  Further, since the frequency deviation in the nonlinear distortion circuit varies depending on a temperature change or the like, the frequency deviation may not be flattened only by fine adjustment of the lumped constant or the distribution constant. On the other hand, in order to automatically compensate for the signal distortion, the frequency deviation of the signal amplified by the high-power amplifier is monitored, and the DPD that gives the signal a frequency characteristic opposite to the frequency deviation in the previous stage of the high-power amplifier. (Digital Pre-Distortion) is used (see, for example, Patent Document 1 below).

JP 2003-298362 A

  However, in the above-described prior art, when the frequency of the signal amplified by the high-power amplifier changes, the frequency deviation generated in the signal changes greatly. Therefore, a frequency deviation exceeding the range of frequency characteristics that can be controlled by the DPD occurs in the signal. Sometimes. For this reason, there is a problem that the frequency deviation generated in the signal cannot be sufficiently compensated.

  This problem will be specifically described. In the DPD, the frequency characteristic control range is set so that the frequency deviation becomes flat when the frequency characteristic given to the signal is set to approximately the center value of the frequency characteristic control range in the DPD. As a result, the variable widths in the plus direction and the minus direction of the frequency characteristics given to the signal are ensured equally.

  In this state, when the frequency of the signal changes, the frequency deviation generated in the signal changes greatly. Therefore, the frequency characteristic given to the signal to flatten the frequency deviation deviates from the median value of the control range of the frequency characteristic in the DPD. For this reason, the variable width in the positive direction or the negative direction of the frequency characteristic given to the signal is reduced. For this reason, depending on the change direction of temperature, a frequency deviation exceeding the control range of the frequency characteristic in the DPD occurs in the signal.

  On the other hand, it is conceivable to widen the control range of frequency characteristics in DPD. However, since the control range of the frequency characteristics and the control resolution of the frequency characteristics are in a trade-off relationship, there is a problem that the control resolution of the frequency characteristics deteriorates when the control range of the frequency characteristics is expanded. In addition, in order to widen the control range of the frequency characteristic while ensuring the control resolution of the frequency characteristic, it is necessary to use a highly accurate circuit, and there is a problem that the cost of the apparatus increases.

  The disclosed distortion compensation apparatus, wireless communication apparatus, distortion compensation method, and wireless communication method are intended to solve the above-described problems and to sufficiently compensate for a frequency deviation of a signal.

  In order to solve the above-described problems and achieve the object, this distortion compensation apparatus is controlled for each of a plurality of frequencies in a distortion compensation apparatus that compensates for a frequency deviation of a variable frequency signal amplified by a nonlinear distortion circuit having nonlinear distortion. Storage means for associating and storing range information, detection means for detecting the frequency of the signal, and setting in the storage means a control range indicated by control range information associated with the frequency detected by the detection means And a deviation compensating means for controlling a frequency characteristic applied to a signal at the preceding stage of the nonlinear distortion circuit within a control range set by the setting means.

  According to the above configuration, the control range of the frequency characteristic can be switched to the optimum range according to the frequency of the signal amplified by the nonlinear distortion circuit. For this reason, even if the frequency of the signal is switched, it is possible to evenly secure the variable width in the plus direction or minus direction of the frequency characteristic given to the signal.

  According to the disclosed distortion compensation device, wireless communication device, distortion compensation method, and wireless communication method, there is an effect that the frequency deviation of the signal can be sufficiently compensated.

  Exemplary embodiments of a distortion compensation device, a wireless communication device, a distortion compensation method, and a wireless communication method will be described below in detail with reference to the accompanying drawings. In this distortion compensation device, wireless communication device, distortion compensation method, and wireless communication method, the control range of the frequency characteristic is switched to an optimal range according to the frequency of the signal amplified by the nonlinear distortion circuit. Thereby, even if the frequency of the signal is switched, a variable width of the frequency characteristic can be secured and the frequency deviation of the signal can be sufficiently compensated.

(Embodiment)
FIG. 1 is a block diagram of a functional configuration of the wireless communication apparatus according to the embodiment. As illustrated in FIG. 1, the wireless communication device 100 according to the embodiment includes a signal processing unit 110, a DPDC 120, an analog conversion unit 130, an RF circuit 140, a bandpass filter 150, an antenna 160, and digital conversion. Part 170. The wireless communication device 100 is a base station that performs wireless communication with a mobile terminal (not shown).

  The signal processing unit 110 outputs a signal for transmission to a mobile terminal (not shown) to the DPDC 120. The DPDC 120 (DPD Controller) is a distortion compensation device that compensates for the frequency deviation of the signal amplified by the RF circuit 140. Specifically, the DPDC 120 is an equalizer that gives a frequency characteristic to the signal output from the signal processing unit 110.

  The DPDC 120 applies a frequency characteristic opposite to the frequency deviation generated in the signal in the RF circuit 140 to the signal before the RF circuit 140 by digital signal processing. The DPDC 120 outputs a signal given frequency characteristics to the analog conversion unit 130. An analog conversion unit 130 (DAC: Digital Analog Converter) converts the signal output from the DPDC 120 into an analog signal and outputs the analog signal to the RF circuit 140.

  The RF circuit 140 is an RF (Radio Frequency: high frequency) circuit that processes (amplifies) the signal output from the analog conversion unit 130, and is a non-linear distortion circuit having non-linear distortion. For this reason, a frequency deviation occurs in the signal processed by the RF circuit 140. The RF circuit 140 outputs the processed signal to the band pass filter 150.

  The band pass filter 150 extracts a predetermined band component of the signal output from the RF circuit 140 and outputs it to the antenna 160. Antenna 160 transmits the signal output from bandpass filter 150 to a mobile terminal (not shown) by radio waves. A digital conversion unit 170 (ADC: Analog Digital Converter) acquires a signal output from the RF circuit 140 to the bandpass filter 150. The digital conversion unit 170 converts the acquired signal into a digital signal and outputs the digital signal to the monitoring unit 124 of the DPDC 120.

  Next, a specific configuration of the DPDC 120 will be described. The DPDC 120 includes a storage unit 121, a detection unit 122, a setting unit 123, a monitoring unit 124, and a deviation compensation unit 125. The storage unit 121 stores control range information in association with each other for a plurality of frequencies. The control range information is a control range of frequency characteristics in the deviation compensation unit 125.

  The detection unit 122 detects the frequency of the signal processed by the RF circuit 140. The signal processed by the RF circuit 140 and transmitted by the antenna 160 is a variable frequency signal. The detection unit 122 detects the signal frequency by acquiring a signal frequency switching signal (not shown) from the signal processing unit 110, for example. When the frequency of the signal is switched in the RF circuit 140, the signal frequency may be detected by obtaining a signal frequency switching signal (not shown) from the RF circuit 140.

  The setting unit 123 sets the control range indicated by the control range information associated with the frequency detected by the detection unit 122 in the deviation compensation unit 125 in the storage unit 121. The monitoring unit 124 monitors the frequency deviation of the signal processed by the RF circuit 140. The monitoring unit 124 outputs deviation information indicating the monitored frequency deviation to the deviation compensation unit 125.

  The deviation compensation unit 125 is an equalizer that gives frequency characteristics to the signal output from the signal processing unit 110, that is, the signal in the previous stage of the RF circuit 140. Further, the deviation compensation unit 125 compensates the frequency deviation of the signal at the subsequent stage of the RF circuit 140 by controlling the frequency characteristics given to the signal within the control range set by the setting unit 123.

  Specifically, the deviation compensation unit 125 controls the frequency characteristics given to the signal based on the deviation information output from the monitoring unit 124. For example, the deviation compensation unit 125 controls the frequency characteristics given to the signal so that the frequency deviation indicated by the deviation information output from the monitoring unit 124 is minimized. The detection unit 122, the setting unit 123, the monitoring unit 124, and the deviation compensation unit 125 can be realized by an LSI (Large Scale Integration) such as a CPU (Central Processing Unit).

  FIG. 2 is a block diagram showing a specific example of the RF circuit shown in FIG. As shown in FIG. 2, the RF circuit 140 includes a modulation circuit 211 (MOD), a mixer circuit 212, an amplifier 213, a mixer circuit 214, and an amplifier 215. The modulation circuit 211 modulates the signal output from the digital conversion unit 170 and outputs the modulated signal to the mixer circuit 212.

  The mixer circuit 212 performs frequency conversion of the signal output from the modulation circuit 211 using an input clock signal (not shown). The mixer circuit 212 outputs the frequency-converted signal to the amplifier 213. The amplifier 213 amplifies the signal output from the mixer circuit 212 and outputs the amplified signal to the mixer circuit 214.

  The mixer circuit 214 converts the frequency of the signal output from the amplifier 213 using an input clock signal (not shown). The mixer circuit 214 outputs the frequency-converted signal to the amplifier 215. The amplifier 215 amplifies the signal output from the mixer circuit 214 and outputs the amplified signal to the band pass filter 150.

  The specifics of the RF circuit 140 are not limited to the example shown in FIG. 2, and any nonlinear distortion circuit having nonlinear distortion may be used. The RF circuit 140 is configured by, for example, a field effect transistor (FET) LCR stripline.

  FIG. 3 is a diagram conceptually showing the control range information stored in the storage unit. As illustrated in FIG. 3, the storage unit 121 (see FIG. 1) stores EQL <b> 1 to EQLn as frequency characteristic control range information. In EQL1 to EQLn, the horizontal axis indicates the frequency. In EQL1 to EQLn, the vertical axis indicates the amplitude. That is, each of EQL1 to EQLn indicates a slope of the amplitude (frequency characteristic) with respect to the frequency.

  The storage unit 121 stores ± X dB as a variable width common to EQL1 to EQLn. The control range indicated by the control range information is determined by the reference value (median value) indicated by EQL1 to EQLn and the variable width ± X dB. For example, the control range indicated by EQL1 is a range in which the reference value indicated by EQL1 is the median, the upper limit is the reference value + XdB, and the lower limit is -XdB.

  FIG. 4 is a diagram illustrating a specific example of the control range information stored in the storage unit. Here, the control range information shown in FIG. 3 will be specifically described. The storage unit 121 (see FIG. 1) stores a table 400 as shown in FIG. 4 as frequency characteristic control range information. The EQL numbers 1 to n (n is a natural number) are identification numbers for identifying a plurality of pieces of control range information. In the table 400, a reference value and a variable width are associated with each of EQL1 to EQLn. However, the variable width is ± 2 dB common to all EQLs 1 to n.

  For example, the control range indicated by the control range information of EQL1 has a reference value of −0.3 and a variable width of ± 2 dB, so that the upper limit is 1.7 and the lower limit is −2.3. The control range indicated by the control range information of EQL4 has a reference value of 0 and a variable width of ± 2 dB, so that the upper limit is 2 and the lower limit is -2. Note that the control range (upper limit and lower limit) is information that is uniquely calculated from the reference value and the variable width, and thus may not be included in the table 400.

  FIG. 5 is a diagram illustrating a control range of frequency characteristics. A control range 510 shown in FIG. 5 is a control range indicated by EQL4 of the table 400 (see FIG. 4). As shown in FIG. 5, the median value of the control range 510 is a frequency characteristic 511 having an amplitude gradient with respect to frequency of zero. The upper limit of the control range 510 is the frequency characteristic 512 having an amplitude gradient of 2 with respect to the frequency. The lower limit of the control range 510 is the frequency characteristic 513 having an amplitude gradient of −2 with respect to the frequency.

  When the control range 510 is set, the deviation compensator 125 sets the initial state of the frequency characteristic given to the signal as the frequency characteristic 511. Further, the deviation compensation unit 125 controls the frequency characteristic given to the signal between the frequency characteristic 512 and the frequency characteristic 513 based on the deviation information output from the monitoring unit 124. Although the control range 510 indicated by EQL4 of the table 400 has been described here, the same applies to the control ranges indicated by other EQLs of the table 400.

  FIG. 6 is a flowchart showing an example of the frequency and control range information storage process. Here, a storage process for storing the control range information described with reference to FIGS. 3 to 5 in association with a plurality of frequencies will be described. First, the signal processing unit 110 sets a signal frequency (step S601). Here, the signal processing unit 110 sets the frequency of the signal to the frequency F1.

  Next, the detection unit 122 detects the frequency (frequency F1) of the signal set in step S601 (step S602). Next, the setting unit 123 performs initial setting of the control range of the frequency characteristic for the deviation compensating unit 125 (step S603). Here, the setting unit 123 sets the control range (control range 510 in FIG. 5) indicated by EQL4 (reference value inclination is 0) in the table 400 (see FIG. 4) as an initial value in the deviation compensation unit 125.

  Next, the deviation compensation unit 125 controls the frequency characteristics within the control range set in step S603 (step S604) so that the frequency deviation indicated by the deviation information output from the monitoring unit 124 is minimized. . Specifically, the deviation compensation unit 125 controls the frequency characteristics by adjusting the TAP coefficient.

  Next, the setting unit 123 calculates a deviation of the frequency characteristic controlled in step S604 from the reference value (slope 0) of the control range set in step S603 (step S605). Next, the setting unit 123 sets control range information (EQL6) in which the frequency characteristic indicated by the deviation calculated in step S605 becomes the reference value (median value) from the control range information (EQL1 to EQLn) in the table 400. Select (step S606).

  Next, the storage unit 121 stores the frequency (F1) detected in step S602 and the control range information selected in step S606 in association with each other (step S607), with respect to the frequency set in step S601. The control range information storing step is terminated. By repeating the above steps while changing the frequency set in step S601, the control range information can be stored in association with each other for a plurality of frequencies.

  The above steps are preferably performed as factory training when the wireless communication device 100 or the DPDC 120 is manufactured. As a result, the optimum table 400 can be generated for manufacturing variations such as the lumped constant and distributed constant of each component of the RF circuit 140.

  FIG. 7 is a diagram showing a specific example of step S603 shown in FIG. In FIG. 7, a graph 710 indicates a frequency deviation that occurs in the signal in the RF circuit 140. The frequency deviation shown in the graph 710 is a frequency deviation in which the amplitude with respect to the frequency falls to the right (a state where the amplitude is smaller as the frequency is larger). A graph 720 shows a control range 721 set in the deviation compensation unit 125 and a frequency characteristic 722 that the deviation compensation unit 125 gives to the signal.

  In step S603 shown in FIG. 6, a control range 721 indicated by EQL4 (reference value inclination is 0) of the table 400 (see FIG. 4) is set. At this time, the frequency characteristic 722 given to the signal by the deviation compensation unit 125 is set to the reference value of the control range 721. A graph 730 shows the frequency deviation of the signal monitored by the monitoring unit 124. Here, since the frequency characteristic 722 (see graph 720) given to the signal by the deviation compensating unit 125 has a slope of 0, the frequency deviation shown in the graph 710 remains as it is.

  FIG. 8 is a diagram showing a specific example of step S604 shown in FIG. In FIG. 8, the same parts as those shown in FIG. In step S604 shown in FIG. 6, the frequency characteristic 722 given to the signal is controlled so that the frequency deviation indicated by the deviation information output from the monitoring unit 124 is minimized.

  For this reason, as shown in the graph 720, the frequency characteristic 722 has an inverse characteristic with respect to the frequency deviation shown in the graph 710, centering on the flat frequency characteristic (slope is 1), and the amplitude with respect to the frequency increases to the right ( The larger the frequency, the larger the amplitude). As a result, the frequency deviation (graph 710) generated in the signal in the RF circuit 140 and the frequency characteristic 722 cancel each other. For this reason, the frequency deviation shown in the graph 730 is a frequency deviation whose amplitude is substantially constant with respect to the frequency.

  FIG. 9 is a diagram showing a specific example of step S606 shown in FIG. In FIG. 9, the same parts as those shown in FIG. In step S606 shown in FIG. 6, control range information in which the frequency characteristic 722 (graph 720 in FIG. 8) controlled in step S604 is a reference value is selected.

  At this time, the frequency characteristic 722 given to the signal by the deviation compensation unit 125 is set to the reference value of the control range 721 selected in step S606. For this reason, the frequency characteristic 722 is substantially the same as the frequency characteristic 722 shown in the graph 720 of FIG.

  Therefore, also in this case, the frequency deviation shown in the graph 730 is a frequency deviation whose amplitude is substantially constant with respect to the frequency. In step S606, only the control range information may be selected. Therefore, as shown in the graph 720, it is not necessary to actually set the frequency characteristic 722 according to the selected control range information.

  FIG. 10 is an example of information stored by the storage process shown in FIG. In FIG. 10, the same parts as those shown in FIG. By repeating each step shown in FIG. 6 while changing the frequency, the storage unit 121 (see FIG. 1) can display a table as shown in FIG. 10 as information in which control range information is associated with each of a plurality of frequencies. 400 can be stored.

  Here, the frequency F1 is stored in association with EQL6. Further, the frequency F2 is stored in association with EQL5. Further, the frequency F3 is stored in association with EQL4. The frequency F4 is stored in association with EQL2. Here, the case where only the frequencies F1 to F4 are stored in the table 400 has been described, but the number of stored frequencies may be two or more.

  FIG. 11 is a flowchart showing an example of the distortion compensation operation after the storing step shown in FIG. A distortion compensation operation in the case where the frequency of the signal processed by the RF circuit 140 is switched after each step shown in FIG. 6 will be described. First, the signal processing unit 110 switches the frequency of the signal (step S1101). Next, the detection unit 122 detects the frequency of the signal switched in step S1101 (step S1102).

  Next, in the table 400 stored in the storage unit 121, the setting unit 123 reads out control range information associated with the frequency detected in step S1102 from the table 400 in the storage unit 121. Then, the setting unit 123 sets the control range indicated by the control range information read from the table 400 in the deviation compensation unit 125 (step S1103).

  Next, the deviation compensation unit 125 starts control of the frequency characteristics given to the signal within the control range set in step S1103 (step S1104), and ends a series of operations at the time of switching the frequency of the signal. Thereafter, the deviation compensator 125 performs a distortion compensation operation (see FIG. 12). Each step shown in FIG. 11 is performed every time the frequency of the signal is switched.

  FIG. 12 is a diagram illustrating an example of a distortion compensation operation according to a temperature change. In FIG. 12, the same parts as those shown in FIG. Here, a case where the frequency of the signal is frequency F3 and the control range (inclination 0 of the reference value) indicated by EQL4 is set in deviation compensation unit 125 in step S1103 (see FIG. 11) will be described.

  Graphs 710, 720, and 730 denoted by reference numeral 1210 show an example of distortion compensation operation at normal temperature. As indicated by a graph 710 of reference numeral 1210, it is assumed that there is almost no frequency deviation generated in a signal in the RF circuit 140 at room temperature.

  For this reason, the frequency characteristic 722 given to the signal by the deviation compensation unit 125 is set to the reference value (slope 0) of the control range 721, as indicated by a graph 720 of reference numeral 1210. Thereby, as indicated by a graph 730 of reference numeral 1210, the frequency deviation indicated by the deviation information output from the monitoring unit 124 is a frequency deviation whose amplitude is substantially constant with respect to the frequency.

  Graphs 710, 720, and 730 denoted by reference numeral 1220 show an example of distortion compensation operation at a low temperature. As indicated by a graph 710 of reference numeral 1220, it is assumed that the frequency deviation generated in the signal in the RF circuit 140 is a downward-sloping frequency deviation at a low temperature.

  For this reason, as shown in a graph 720 of reference numeral 1220, the frequency characteristic 722 given to the signal by the deviation compensation unit 125 is set to a frequency deviation that rises to the right in the control range 721. As a result, as indicated by a graph 730 of reference numeral 1220, the frequency deviation indicated by the deviation information output from the monitoring unit 124 is a frequency deviation whose amplitude is substantially constant with respect to the frequency.

  Graphs 710, 720, and 730 denoted by reference numeral 1230 show an example of distortion compensation operation at a high temperature. As indicated by a graph 710 of reference numeral 1230, it is assumed that the frequency deviation generated in the signal in the RF circuit 140 is a frequency deviation that rises to the right at high temperatures.

  For this reason, the frequency characteristic 722 given to the signal by the deviation compensator 125 is set to a frequency deviation with a downward slope in the control range 721 as indicated by a graph 720 of reference numeral 1230. Thereby, as indicated by a graph 730 of reference numeral 1230, the frequency deviation indicated by the deviation information output from the monitoring unit 124 is a frequency deviation whose amplitude is substantially constant with respect to the frequency.

  In this way, the deviation compensation unit 125 controls the frequency characteristic 722 given to the signal based on the deviation information output from the monitoring unit 124, so that the frequency deviation of the signal can be achieved even when the temperature changes from normal temperature to low temperature or high temperature. Can be compensated. Here, three patterns of normal temperature, low temperature, and high temperature have been described, but the deviation compensation unit 125 constantly monitors the deviation information output from the monitoring unit 124 and continuously monitors the frequency characteristics with respect to temperature changes. 722 may be controlled.

  FIG. 13 is a diagram illustrating an example of a distortion compensation operation according to frequency switching. In FIG. 13, the same parts as those shown in FIG. Here, a case will be described in which the frequency of a signal processed by the RF circuit 140 is switched to the frequencies F1, F2, and F4 by the signal processing unit 110 at room temperature.

  Graphs 710, 720, and 730 denoted by reference numeral 1310 show an example of the distortion compensation operation when the signal frequency is switched to the frequency F1. As indicated by a graph 710 of reference numeral 1310, when the frequency of the signal is the frequency F1, the frequency deviation generated in the signal in the RF circuit 140 is a steeply descending frequency deviation.

  For this reason, as shown in a graph 720 of reference numeral 1310, a control range 721 (EQL6) having a frequency characteristic 722 that rises sharply as a reference value is set in the deviation compensation unit 125. Thereby, when the frequency characteristic 722 is the reference value of the control range 721, the frequency deviation indicated by the deviation information output from the monitoring unit 124 has an amplitude with respect to the frequency, as indicated by a graph 730 of reference numeral 1310. Becomes a substantially constant frequency deviation.

  Graphs 710, 720, and 730 denoted by reference numeral 1320 illustrate an example of the distortion compensation operation when the signal frequency is switched to the frequency F2. As indicated by a graph 710 of reference numeral 1320, when the frequency of the signal is the frequency F2, the frequency deviation generated in the signal in the RF circuit 140 is a gentle downward-sloping frequency deviation.

  For this reason, as shown in a graph 720 of reference numeral 1320, a control range 721 (EQL5) using a frequency characteristic 722 that gradually increases to the right as a reference value is set in the deviation compensation unit 125. Thereby, when the frequency characteristic 722 is the reference value of the control range 721, the frequency deviation indicated by the deviation information output from the monitoring unit 124 has an amplitude with respect to the frequency, as indicated by a graph 730 of reference numeral 1320. Becomes a substantially constant frequency deviation.

  Graphs 710, 720, and 730 denoted by reference numeral 1330 show an example of the distortion compensation operation when the signal frequency is switched to the frequency F4. As indicated by a graph 710 of reference numeral 1330, when the frequency of the signal is the frequency F4, the frequency deviation generated in the signal in the RF circuit 140 is a steeply rising frequency deviation.

  For this reason, as shown in a graph 720 of reference numeral 1330, a control range 721 (EQL2) using the frequency characteristic 722 of a steeply descending slope as a reference value is set in the deviation compensating unit 125. Thereby, when the frequency characteristic 722 is the reference value of the control range 721, the frequency deviation indicated by the deviation information output from the monitoring unit 124 has an amplitude with respect to the frequency, as indicated by a graph 730 of reference numeral 1330. Becomes a substantially constant frequency deviation.

  Thereby, even when the frequency of the signal processed by the RF circuit 140 is switched to the frequencies F1, F2, and F4, the frequency deviation when the frequency characteristic 722 is always the reference value of the control range 721 can be reduced. . Accordingly, since the variable range of the frequency characteristic 722 to be given to the signal is equally secured in the positive direction and the negative direction, even if the temperature changes from normal temperature to high temperature or low temperature, the frequency characteristic 722 is controlled to reduce the frequency deviation of the signal. Can be compensated.

  As described above, according to the wireless communication apparatus 100 (or DPDC 120) according to the embodiment, the control range of the frequency characteristic is switched to the optimum range according to the frequency of the signal amplified by the nonlinear distortion circuit (RF circuit 140). Therefore, even if the frequency of the signal is switched, the variable width in the positive direction or the negative direction of the frequency characteristic given to the signal can be ensured evenly. For this reason, the frequency deviation of the signal can be sufficiently compensated.

  Further, since the frequency deviation of the signal can be sufficiently compensated without expanding the frequency characteristic control range, the control resolution of the frequency characteristic can be improved as compared with the case where the frequency characteristic control range is expanded. For this reason, the control precision of a frequency deviation can be improved and the quality of a signal can be improved. Alternatively, the cost of the apparatus can be reduced as compared with the case where a highly accurate circuit is used to ensure the control range and control resolution of the frequency characteristics.

  Further, normally, the signal frequency is not switched while transmitting the signal, and the signal transmission is stopped when the signal frequency is switched. For this reason, the frequency characteristic control range can be switched without affecting the signal to be transmitted by switching the frequency characteristic control range when switching the signal frequency. For this reason, the frequency deviation of the signal can be sufficiently compensated without degrading the signal.

  In addition, since the frequency deviation of the signal can be sufficiently compensated, fine adjustment of the lumped constants and distribution constants of individual components at the time of product manufacture can be simplified. Since this fine adjustment is usually a manual operation, the manufacturing cost can be greatly reduced by simplifying this fine adjustment.

  As described above, according to the disclosed distortion compensation device, wireless communication device, distortion compensation method, and wireless communication method, the frequency deviation of the signal can be sufficiently compensated. In the above-described embodiment, the case where the wireless communication device 100 is a base station for wireless communication has been described, but the wireless communication device 100 may be a mobile terminal such as a mobile phone.

  Further, the above-described DPDC 120 (distortion compensation device) can be applied not only to the wireless communication device 100 but also to all devices that amplify a variable frequency signal using a nonlinear distortion circuit having nonlinear distortion.

It is a block diagram which shows the functional structure of the radio | wireless communication apparatus concerning embodiment. FIG. 2 is a block diagram illustrating a specific example of the RF circuit illustrated in FIG. 1. It is a figure which shows notionally the control range information memorize | stored in a memory | storage part. It is a figure which shows the specific example of the control range information memorize | stored in a memory | storage part. It is a figure which shows the control range of a frequency characteristic. It is a flowchart which shows an example of the memory | storage process of a frequency and control range information. It is a figure which shows the specific example of step S603 shown in FIG. It is a figure which shows the specific example of step S604 shown in FIG. It is a figure which shows the specific example of step S606 shown in FIG. It is an example of the information memorize | stored by the memory | storage process shown in FIG. It is a flowchart which shows an example of the distortion compensation operation | movement after the memory | storage process shown in FIG. It is a figure which shows an example of the distortion compensation operation | movement according to a temperature change. It is a figure which shows an example of the distortion compensation operation | movement according to frequency switching.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Wireless communication apparatus 130 Analog conversion part 150 Band pass filter 160 Antenna 170 Digital conversion part 211 Modulation circuit 212,214 Mixer circuit 213,215 Amplifier 400 Table 510,721 Control range 511-513,722 Frequency characteristic 710,720,730 Graph

Claims (6)

A distortion compensation device that compensates a frequency deviation of a variable frequency signal amplified by a nonlinear distortion circuit having nonlinear distortion in a base station device that transmits a radio signal to a mobile terminal ,
Storage means for storing control range information in association with each other for a plurality of frequencies;
Detecting means for detecting the frequency of the signal;
Setting means for setting a control range indicated by control range information associated with the frequency detected by the detection means in the storage means;
Deviation compensation means for compensating the frequency deviation of the signal by controlling the frequency characteristics given to the signal in the previous stage of the nonlinear distortion circuit within the control range set by the setting means;
A distortion compensation apparatus comprising:   The distortion compensation apparatus according to claim 1, wherein the storage unit stores a control range in which the frequency characteristic controlled by the deviation compensation unit becomes a median value for each of the plurality of frequencies in association with each other. Monitoring means for monitoring the frequency deviation of the signal amplified by the nonlinear distortion circuit;
The distortion compensation apparatus according to claim 1, wherein the deviation compensation unit controls the frequency characteristic based on a frequency deviation monitored by the monitoring unit. Signal processing means for outputting a signal to be transmitted to the mobile terminal ;
A nonlinear distortion circuit for amplifying the signal output by the signal processing means;
The distortion compensation apparatus according to any one of claims 1 to 3, which compensates for a frequency deviation of a variable frequency signal amplified by the nonlinear distortion circuit;
Transmitting means for wirelessly transmitting a signal whose frequency deviation has been compensated by the distortion compensation device to a mobile terminal ;
A wireless communication apparatus comprising: A distortion compensation method for compensating for a frequency deviation of a variable frequency signal amplified by a non-linear distortion circuit having non-linear distortion in a base station apparatus that transmits a radio signal to a mobile terminal ,
A storage step of storing control range information in association with each other for a plurality of frequencies;
A detecting step for detecting a frequency of the signal;
In the storing step, a setting step for setting a control range indicated by control range information associated with the frequency detected by the detection step;
A deviation compensation step for compensating a frequency deviation of the signal by controlling a frequency characteristic to be given to the signal in the previous stage of the nonlinear distortion circuit within the control range set by the setting step;
A distortion compensation method comprising: A signal processing step of outputting a signal to be transmitted to the mobile terminal ;
A nonlinear distortion step of amplifying the signal output by the signal processing step;
The distortion compensation method according to claim 5, wherein a frequency deviation of a variable frequency signal amplified by the nonlinear distortion step is compensated;
A transmission step of wirelessly transmitting a signal whose frequency deviation is compensated by the distortion compensation method to a mobile terminal ;
A wireless communication method comprising:

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