JP2012244475A - Receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption without deteriorating total EVM.SOLUTION: A receiver 100 comprises: a Mixer 106 performing frequency conversion of a reception signal; and a synthesizer 110 generating an oscillation signal used for the frequency conversion in the Mixer 106. The receiver 100 comprises: a LPF 108 attenuating a band higher than a cut-off frequency of the frequency-converted reception signal; and a BPF 132 extracting a reception signal of an adjacent channel from the frequency-converted reception signal. The receiver 100 comprises an RSSI detection part 134 measuring intensity of the reception signal of the adjacent channel. The receiver 100 comprises a control part 140 which sets the cut-off frequency of the LPF 108 depending on the intensity of the reception signal of the adjacent channel, and sets at least one of a current value flowing in the Mixer 106 and a current value flowing in the synthesizer 110 depending on the set cut-off frequency.

Description

  The present invention relates to a receiver.

  2. Description of the Related Art Conventionally, a receiver such as a mobile phone that receives a radio signal performs frequency conversion of a received signal by a mixer, attenuates a high-frequency component of the frequency-converted received signal by an LPF (Low Pass Filter), and then performs baseband processing. Etc. are known to perform. Note that an oscillation signal used for frequency conversion in the mixer is generated by a synthesizer.

  In such a receiver, conventionally, EVM (Error Vector Magnitude) is used as an index of the reception quality of a radio signal. The value of EVM is determined based on parameters such as a quadrature error generated by a mixer, a phase noise generated by a synthesizer, and a group delay generated by an LPF.

  Here, in the conventional receiver, by reducing the frequency of the oscillation signal while changing the local oscillation level of the oscillation signal based on the number of segments of the reception signal, the power consumption is reduced while suppressing the deterioration of the reception performance. It is known to measure.

  In the conventional receiver, when the quality of the received signal is good, the power consumption can be reduced by lowering the oversampling frequency of the delta-sigma ADC (Analog to Digital Converter) and the operating frequency of the digital filter. Are known.

JP 2007-142819 A JP 2007-243504 A

  However, the technique disclosed in the above prior art document does not consider reducing the power consumption of the receiver without degrading the total EVM.

  In other words, in the prior art, a cutoff frequency that can sufficiently attenuate an out-of-band signal is fixed and used regardless of the usage status of the adjacent channel so as not to be affected by the adjacent channel of the received signal. It was.

  For this reason, the EVM due to the filter group delay in the LPF has a constant value. In the prior art, since the current flowing to the synthesizer and the current flowing to the mixer are also fixed, the EVM due to the phase noise of the synthesizer and the EVM due to the orthogonal error of the mixer also have a constant value. Therefore, the total EVM is a constant value.

  In this case, the total EVM is maintained at a constant value, but the synthesizer and the Mixer are set on the assumption that the signal strength of the adjacent channel is high regardless of the actual usage status of the adjacent channel. A large current flows. For this reason, since the power consumption of the receiver is kept relatively large, it is difficult to reduce the power consumption.

  On the other hand, if the current that is simply passed through the synthesizer or the current that is passed through the mixer is reduced, the power consumption is reduced. May deteriorate.

  The disclosed technique has been made in view of the above, and an object thereof is to realize a receiver capable of reducing power consumption without degrading the total EVM.

  In one aspect, a receiver disclosed in the present application includes a conversion unit that performs frequency conversion of a received signal and an oscillation signal generation unit that generates an oscillation signal used for frequency conversion of the mixer. A receiver that attenuates a frequency band higher than a cutoff frequency of the reception signal frequency-converted by the mixer; an extraction unit that extracts a signal of an adjacent channel from the reception signal frequency-converted by the mixer; Is provided. In addition, the receiver includes a detection unit that measures the intensity of the signal of the adjacent channel extracted by the extraction unit. The receiver sets the cutoff frequency of the attenuation unit according to the intensity of the reception signal of the adjacent channel measured by the detection unit, and sends the cutoff frequency to the conversion unit according to the set cutoff frequency. A control unit configured to set at least one of a first current value and a second current value to be supplied to the oscillation signal generation unit;

  According to one aspect of the receiver disclosed in the present application, it is possible to reduce power consumption without degrading the total EVM.

FIG. 1 is a diagram illustrating an overall configuration of a receiver. FIG. 2 is a diagram illustrating an example of a truth table for current selection of the mixer and the synthesizer. FIG. 3 is a diagram illustrating an example of a truth table for LPF cutoff setting selection. FIG. 4 is a diagram showing an outline of the EVM parameter configuration of the receiver. FIG. 5 is a diagram illustrating an example of distribution of EVM parameters. FIG. 6 is a diagram illustrating a configuration of the control unit. FIG. 7 is a diagram illustrating an example of a truth table for control signal selection in the selection circuit. FIG. 8 is a diagram illustrating an example of a control table. FIG. 9 is a flowchart showing the control process of the receiver.

  Hereinafter, an embodiment of a receiver disclosed in the present application will be described in detail with reference to the drawings. The disclosed technology is not limited by this embodiment. For example, in the following embodiments, a mobile phone is assumed as an example of a receiver. However, the present invention is not limited to this, and any receiver that can receive a radio signal may be used.

  FIG. 1 is a diagram illustrating an overall configuration of a receiver. As illustrated in FIG. 1, the receiver 100 includes an antenna 102, an LNA (Low Noise Amplifier) 104, a mixer 106, an LPF 108, and a synthesizer 110. The receiver 100 includes a BGR (Band Gap Reference) 112, constant current circuits 114, 116, 118, and a current selection circuit 120. The receiver 100 also includes cutoff setting circuits 124, 126, and 128, a cutoff selection circuit 130, a BPF (Band Pass Filter) 132, an RSSI (Received Signal Strength Indicator) detection unit 134, and a control unit 140.

  The LNA 104 is a low noise amplifier that receives and amplifies a radio signal received via the antenna 102. The LNA 104 outputs the amplified received signal to the mixer 106.

  The Mixer 106 is a frequency converter that performs frequency conversion of the reception signal amplified by the LNA 104. The mixer 106 also receives an oscillation signal generated by the synthesizer 110. The mixer 106 applies an oscillation signal to the reception signal and mixes the reception signal and the oscillation signal, thereby converting the frequency of the reception signal to the frequency of the baseband signal. The current selected by the current selection circuit 120 is supplied to the Mixer 106, and the received signal is frequency-converted by the supplied current.

  The LPF 108 is an attenuator that attenuates a frequency band higher than the cut-off frequency of the received signal frequency-converted by the mixer 106. The LPF 108 attenuates the high frequency band based on the cutoff frequency selected by the cutoff selection circuit 130.

  The synthesizer 110 generates an oscillation signal that is used for frequency conversion in the mixer 106. The synthesizer 110 outputs an oscillation signal oscillated at a predetermined frequency to the mixer 106. The synthesizer 110 is supplied with the current selected by the current selection circuit 120, and generates an oscillation signal with the supplied current.

  The BGR 112 is a reference voltage generation circuit that generates a reference voltage for a power source used in the mixer 106 and the synthesizer 110. The reference voltage generated by the BGR 112 is supplied to the constant current circuits 114, 116, and 118.

  The constant current circuit 114 is a circuit that allows the constant current A to flow based on the reference voltage supplied from the BGR 112. The constant current circuit 116 is a circuit that supplies a constant current B smaller than the constant current A based on the reference voltage supplied from the BGR 112. The constant current circuit 118 is a circuit that allows a constant current C smaller than the constant current B to flow based on the reference voltage supplied from the BGR 112.

  The current selection circuit 120 supplies a current to be supplied to the mixer 106 based on the control signals S1 and S2 transmitted from the control unit 140 from among the constant currents A, B, and C that are flowed by the constant current circuits 114, 116, and 118. select. Further, the current selection circuit 120 supplies the synthesizer 110 with the control signals S3 and S4 transmitted from the control unit 140 from among the constant currents A, B, and C that are flowed by the constant current circuits 114, 116, and 118. Select the current to be used.

  The cutoff setting circuit 124 is a circuit that sets a cutoff frequency A used in the LPF 108. The cutoff setting circuit 126 is a circuit that is used in the LPF 108 and sets a cutoff frequency B that is higher than the cutoff frequency A. The cut-off setting circuit 128 is a circuit that is used in the LPF 108 and sets a cut-off frequency C that is higher than the cut-off frequency B.

  The cut-off selection circuit 130 uses the LPF 108 based on the control signals S5 and S6 transmitted from the control unit 140 among the cut-off frequencies A, B, and C set by the cut-off setting circuits 124, 126, and 128. Select the cutoff frequency to be used.

  The BPF 132 is a band-pass filter that passes only the signal in the frequency band of the adjacent channel from the reception signal frequency-converted by the mixer 106. The BPF 132 extracts the reception signal of the adjacent channel by passing only the signal of the frequency band of the adjacent channel. The BPF 132 outputs the extracted reception signal of the adjacent channel to the RSSI detection unit 134. Note that the adjacent channel is, for example, a channel in a frequency band adjacent to a channel in a frequency band to be received by the receiver 100 among channels obtained by dividing a frequency band assigned to a certain carrier into a plurality of channels.

  The RSSI detector 134 measures the strength of the reception signal of the adjacent channel extracted by the BPF 132. The RSSI detector 134 outputs the measured received signal strength of the adjacent channel to the controller 140.

  The control unit 140 sets a cutoff frequency used by the LPF 108 according to the intensity of the reception signal of the adjacent channel measured by the RSSI detection unit 134. In addition, the control unit 140 sets a first current value that flows to the mixer 106 and a second current value that flows to the synthesizer 110 according to the set cutoff frequency. For example, the control unit 140 sets the control signals S1, S2, S3, and S4 according to the intensity of the reception signal of the adjacent channel measured by the RSSI detection unit 134 and outputs the control signals S1, S2, S3, and S4 to the current selection circuit 120. Further, the control unit 140 sets control signals S5 and S6 according to the intensity of the reception signal of the adjacent channel measured by the RSSI detection unit 134, and outputs the control signals S5 and S6 to the cutoff selection circuit 130. Details of the control unit 140 will be described later.

  FIG. 2 is a diagram illustrating an example of a truth table for current selection of the mixer and the synthesizer. As shown in FIG. 2, in the current selection truth table 300, the truth values of the control signals S1 and S2 are set corresponding to the mixer current 302, and the control signals S3 and S4 are corresponded to the synthesizer current 304. The truth value of is set.

  As shown in the truth table 300, the control unit 140 sets the control signal S1 to “0” when the constant current A is supplied to the mixer 106. In this case, the control unit 140 can set the control signal S2 to either “0” or “1”. In addition, when the constant current B is supplied to the mixer 106, the control unit 140 sets the control signal S1 to “1” and the control signal S2 to “0”. When the constant current C is supplied to the mixer 106, the control unit 140 sets the control signal S1 to “1” and the control signal S2 to “1”.

  The control unit 140 sets the control signal S3 to “0” when the constant current A is supplied to the synthesizer 110. In this case, the control unit 140 can set the control signal S4 to “0” or “1”. In addition, when the constant current B is supplied to the synthesizer 110, the control unit 140 sets the control signal S3 to “1” and the control signal S4 to “0”. In addition, when the constant current C is supplied to the synthesizer 110, the control unit 140 sets the control signal S3 to “1” and the control signal S4 to “1”.

  FIG. 3 is a diagram illustrating an example of a truth table for LPF cutoff setting selection. As shown in FIG. 3, the truth value table 400 for selecting the cut-off frequency used in the LPF 108 is set with the truth values of the control signals S5 and S6 corresponding to the cut-off setting 402.

  As shown in truth table 400, control unit 140 sets control signal S5 to “0” when the cutoff frequency used in LPF 108 is set to frequency A. In this case, the control unit 140 can set the control signal S6 to “0” or “1”. In addition, when the cutoff frequency used in the LPF 108 is set to the frequency B, the control unit 140 sets the control signal S5 to “1” and the control signal S6 to “0”. Further, when the cutoff frequency used in the LPF 108 is set to the frequency C, the control unit 140 sets the control signal S5 to “1” and the control signal S6 to “1”.

  FIG. 4 is a diagram showing an outline of the EVM parameter configuration of the receiver. 4, EVM 200 represents the concept of EVM in a conventional general receiver, and EVM 250 represents the concept of EVM in the receiver 100 of the present embodiment.

  First, as shown in the EVM 200, in the conventional general receiver, the total square root of the synthesizer phase noise parameter 202, the mixer orthogonal error parameter 204, and the LPF filter group delay parameter 206 is calculated as a total sum. EVM is required. That is, the total EVM = SQRT ((synthesizer phase noise parameter 202) ^ 2 + (Mixer orthogonal error parameter 204) ^ 2 + (LPF filter group delay parameter 206) ^ 2).

  On the other hand, in the receiver 100 of this embodiment, the control unit 140 sets the cutoff frequency of the LPF to be high when, for example, the adjacent channel is not used and the received signal strength of the adjacent channel is low. As a result, the filter group delay parameter of the LPF is improved and becomes smaller, so the filter group delay parameter 206 ′ of the LPF becomes smaller than the filter group delay parameter 206 of the LPF.

  Therefore, even if the synthesizer phase noise parameter 202 ′ and the mixer orthogonal error parameter 204 ′ deteriorate by the improvement of the LPF filter group delay parameter 206 ′, the total EVM does not change. In other words, the total EVM does not change even if the synthesizer phase noise parameter 202 ′ and the mixer orthogonal error parameter 204 ′ deteriorate, for example, by reducing the current flowing through the synthesizer 110 and the mixer 106. Therefore, for example, as shown in FIG. 5 below, the receiver 100 receives the signal while maintaining (without deteriorating) the total EVM by reducing the current passed through the synthesizer 110 and the mixer 106 by the control unit 140. The power consumption of the machine 100 can be reduced.

  FIG. 5 is a diagram illustrating an example of distribution of EVM parameters. FIG. 5 shows a fixed example 452 in which the parameters of the current flowing through the mixer 106, the current flowing through the synthesizer 110, and the cutoff frequency of the LPF 108 are fixed, and modified examples 454, 456, and 458 in which the parameters are changed. ing. The modification example 454 is an example in which the cutoff frequency of the LPF 108 is changed when the signal strength of the adjacent channel is smaller than a preset threshold value and the adjacent channel is unused. The modification example 456 is an example in which, from the state of the modification example 454, the current flowing through the synthesizer 110 is reduced while allowing deterioration of the phase noise characteristics of the synthesizer 110. The modification example 458 is an example in which, from the state of the modification example 454, the deterioration of the orthogonal error characteristic of the mixer 106 is allowed and the current flowing through the mixer 106 is reduced.

  First, in the fixed example 452, the EVM due to the Mixer quadrature error is 3.2 (% rms), the EVM due to the synthesizer phase noise is 2.2 (% rms), and the EVM due to the LPF group delay is 5.8 (% rms). Assume that the total EVM is 7.0 (% rms). On the other hand, in the modification example 454, as the cut-off frequency of the LPF 108 is increased, the group delay of the LPF 108 is reduced. As a result, the EVM due to the LPF group delay is 2.9 (% rms). That is, the modified example 454 improves the EVM due to the LPF group delay by 2.9 (% rms) compared to the fixed example 452. Therefore, the total EVM is also improved by 2.2 (% rms), resulting in 4.8 (% rms).

  On the other hand, in the modification example 456, the control current of the synthesizer 110 is reduced to the amount equivalent to the improvement of the EVM due to the LPF group delay. When the control current of the synthesizer 110 is reduced, the EVM parameters such as phase noise are deteriorated. However, when the EVM improvement in the LPF 108 is added, the total EVM value is controlled to be constant (no deterioration). That is, the current flowing through the synthesizer 110 is reduced until the EVM due to the synthesizer phase noise is deteriorated by 3.3 (% rms) to 5.5 (% rms). This allows the deterioration of characteristics up to 7.8 (dB) in terms of phase noise of the synthesizer 110. As a result, while the total EVM is maintained at the same value as in the fixed example 452, in other words, the current flowing through the synthesizer 110 can be reduced without degrading the total EVM as compared with the fixed example 452. .

  Further, in the modified example 458, the control current of the mixer 106 is reduced to the amount equivalent to the improvement of the EVM due to the LPF group delay. When the control current of the Mixer 106 is reduced, EVM parameters such as orthogonal error are deteriorated. However, when the EVM improvement in the LPF 108 is combined, control is performed so that the total EVM value becomes constant (no deterioration). That is, the current flowing through the Mixer 106 is reduced until the EVM due to the Mixer orthogonal error deteriorates by 2.8 (% rms) to 6.0 (% rms). This allows the deterioration of the characteristics up to 5.5 (dB) in terms of the orthogonal error SSB (Single Side Band) of the Mixer 106. As a result, while the total EVM is maintained at the same value as in the fixed example 452, in other words, the current flowing through the mixer 106 can be reduced without degrading the total EVM as compared with the fixed example 452.

  FIG. 6 is a diagram illustrating a configuration of the control unit. As illustrated in FIG. 6, the control unit 140 includes a processor 142, a reading unit 144, a writing unit 146, a control table 148, a memory 150, and a selection circuit 152.

  The processor 142 receives the power signal 141 indicating the signal strength of the adjacent channel output from the RSSI detector 134. Then, based on the signal strength of the adjacent channel indicated by the power signal 141, the processor 142 calculates a current value that flows through the mixer 106, a current value that flows through the synthesizer 110, and a cutoff frequency of the LPF 108. The processor 142 generates the control signals S1 to S6 according to the truth table shown in FIGS. 2 and 3 based on the calculated current value to be supplied to the mixer 106, the current value to be supplied to the synthesizer 110, and the cutoff frequency of the LPF 108. Output.

  The reading unit 144 receives the power signal 141 indicating the signal strength of the adjacent channel output from the RSSI detection unit 134. Then, the reading unit 144 reads out a Mixer control current value (a current value passed through the Mixer 106) corresponding to the signal strength of the adjacent channel indicated by the power signal 141 from the control table 148 stored in the memory 150 by the writing unit 146. Further, the reading unit 144 reads a synthesizer control current value (a current value passed through the synthesizer 110) corresponding to the signal strength of the adjacent channel indicated by the power signal 141 from the control table 148 stored in the memory 150 by the writing unit 146. . Further, the reading unit 144 reads the LPF cutoff frequency (the cutoff frequency of the LPF 108) corresponding to the signal strength of the adjacent channel indicated by the power signal 141 from the control table 148 stored in the memory 150 by the writing unit 146. Then, the reading unit 144 controls the control signals S1 to S1 according to the truth table shown in FIGS. 2 and 3 based on the read current value flowing to the Mixer 106, the current value flowing to the synthesizer 110, and the cutoff frequency of the LPF 108. S6 is generated and output.

  The writing unit 146 writes the control table 148 into the memory 150. In addition to the control table 148, the memory 150 stores data for executing various functions of the receiver 100 and various programs for executing various functions. Details of the control table 148 will be described later.

  The selection circuit 152 receives the selection signal 162. Based on the received selection signal 162, the selection circuit 152 selects and outputs one of the control signals S1 to S6 calculated by the processor 142 or the control signals S1 to S6 read by the reading unit 144.

  FIG. 7 is a diagram illustrating an example of a truth table for control signal selection in the selection circuit. As shown in FIG. 7, the truth value table 160 of the control signal selection is set with the truth value of the selection signal 162 corresponding to the selection method of the control signals S1 to S6. For example, when “0” is input as the selection signal 162, the selection circuit 152 outputs the control signals S1 to S6 calculated by the processor 142. On the other hand, when “1” is input as the selection signal 162, the selection circuit 152 outputs the control signals S1 to S6 read from the control table 148 by the reading unit 144.

  FIG. 8 is a diagram illustrating an example of a control table. As shown in FIG. 8, in the control table 148, an LPF cutoff frequency 166, a synthesizer control current 168, and a mixer control current 170 are associated with each of a plurality of adjacent channel power monitor values 164. For example, when the adjacent channel power monitor value 164 is greater than or equal to ΔΔdBm and less than OOdBm, the reading unit 144 reads the frequency B as the LPF cutoff frequency 166, reads the constant current A as the synthesizer control current 168, and performs Mixer control. The constant current B is read as the current 170.

  FIG. 9 is a flowchart showing the control process of the receiver. As shown in FIG. 9, the RSSI detector 134 first monitors the signal strength (power) of the adjacent channel output from the BPF 132 (step S101). Subsequently, the control unit 140 determines whether or not the adjacent channel is unused depending on whether or not the signal strength of the adjacent channel is equal to or higher than a preset threshold (step S102). For example, if the signal strength of the adjacent channel is equal to or higher than a preset threshold, the control unit 140 determines that the adjacent channel is used, and if the signal strength of the adjacent channel is less than the preset threshold, It is determined that the adjacent channel is not used.

  When it is determined that the adjacent channel is not unused (No at Step S102), the control unit 140 returns to Step S101 and repeats the process. On the other hand, when it is determined that the adjacent channel is not used (step S102, Yes), the control unit 140 selects an LPF cutoff frequency, a synthesizer control current, and a mixer control current according to the signal strength of the adjacent channel. (Step S103). For example, when the signal strength of the adjacent channel is less than □□ dBm, the control unit 140 selects the frequency C as the LPF cutoff frequency 166, selects the constant current C as the synthesizer control current 168, and sets the mixer control current 170 as the mixer control current 170. A constant current C is selected.

  Then, the control unit 140 outputs control signals S1 to S6 based on the selected LPF cutoff frequency, synthesizer control current, mixer control current, and the truth table of FIGS. 2 and 3 (step S104). . For example, when the signal strength of the adjacent channel is less than □□ dBm, the control unit 140 sets all the control signals S1 to S6 to “1” and outputs them.

  Subsequently, the cutoff selection circuit 130 sets the cutoff frequency of the LPF 108 based on the control signals S5 and S6 and the truth table 400 of FIG. 3 (step S105). Further, the current selection circuit 120 sets a current to be passed through the synthesizer 110 based on the control signals S3 and S4 and the truth table 300 in FIG. 2 (step S106). Further, the current selection circuit 120 sets a current to be passed through the mixer 106 based on the control signals S1 and S2 and the truth table 300 of FIG. 2 (step S107).

  The control unit 140 determines whether or not the reception process of the receiver 100 is continued (step S108). When it is determined that the reception process is continued (step S108, Yes), the control unit 140 returns to step S101 and repeats the process. On the other hand, when it is determined that the reception process is not continued (No in step S108), the control unit 140 ends the process.

  As described above, according to the receiver 100 of the present embodiment, power consumption can be reduced without degrading the total EVM. That is, receiver 100 does not fix the cutoff frequency of LPF 108, but variably sets the cutoff frequency of LPF 108 according to the strength of the reception signal of the adjacent channel. For example, the receiver 100 sets the cutoff frequency of the LPF 108 higher as the intensity of the reception signal of the adjacent channel becomes lower. As a result, the EVM due to the group delay of the LPF 108 is improved. Then, the receiver 100 reduces the current flowing through the synthesizer 110 or the mixer 106 until the EVM due to the phase noise of the synthesizer 110 or the EVM due to the quadrature error of the mixer deteriorates, corresponding to the improvement of the EVM. As a result, the receiver 100 can reduce power consumption without degrading the total EVM.

  In addition, although the present embodiment has been described mainly with respect to the receiver, the present invention is not limited to this, and a function similar to that of the above-described embodiment is realized by executing a reception control program prepared in advance by a computer. Can do. That is, the reception control program receives a radio signal in the receiver, performs frequency conversion of the received reception signal, extracts a reception signal of an adjacent channel from the frequency-converted reception signal, and extracts the extracted signal A process for measuring the intensity of the received signal of the adjacent channel is executed. Further, the reception control program sets, in the receiver, a cutoff frequency of an attenuation unit that attenuates a high frequency band of the frequency-converted reception signal according to the measured intensity of the reception signal of the adjacent channel, At least one of a current value passed through a conversion unit that performs frequency conversion of the received reception signal according to the set cutoff frequency and a current value passed through an oscillation signal generation unit that generates an oscillation signal used for the frequency conversion Execute the process to set. Note that the reception control program can be distributed to computers via a communication network such as the Internet. The reception control program can also be executed by being recorded on a memory, a hard disk, or other computer-readable recording medium provided in the receiver, and being read from the recording medium by the computer.

100 receiver 104 LNA
106 Mixer
108 LPF
110 Synthesizer 114, 116, 118 Constant current circuit 120 Current selection circuit 124, 126, 128 Cutoff setting circuit 134 RSSI detection unit 140 Control unit 141 Power signal 142 Processor 144 Reading unit 148 Control table 150 Memory 152 Selection circuit

Claims (4)

A conversion unit for performing frequency conversion of the received signal;
An oscillation signal generation unit that generates an oscillation signal used for frequency conversion in the conversion unit;
An attenuation unit for attenuating a frequency band higher than the cutoff frequency of the reception signal frequency-converted by the conversion unit;
An extraction unit that extracts a reception signal of an adjacent channel from the reception signal frequency-converted by the conversion unit;
A detector for measuring the intensity of the reception signal of the adjacent channel extracted by the extraction unit;
The cutoff frequency of the attenuation unit is set according to the intensity of the reception signal of the adjacent channel measured by the detection unit, and the first current value that flows to the conversion unit according to the set cutoff frequency and A control unit that sets at least one of the second current values that flow through the oscillation signal generation unit;
A receiver comprising: The control unit sets the cutoff frequency of the attenuation unit higher as the intensity of the reception signal of the adjacent channel measured by the detection unit decreases, and the first current value and the second current value The receiver according to claim 1, wherein at least one of the two is set low. The control unit sets the attenuation frequency of the attenuation unit higher as the intensity of the reception signal of the adjacent channel measured by the detection unit becomes lower, and corresponds to an improvement in EVM by setting the cutoff frequency. The first current is set low until EVM in the conversion unit deteriorates, or until the EVM in the oscillation signal generation unit deteriorates corresponding to the improvement of EVM due to the setting of the cutoff frequency. 2 is set low, or the first and second currents are reduced until EVM in the conversion unit and the oscillation signal generation unit deteriorates corresponding to an improvement in EVM by setting the cutoff frequency. The receiver according to claim 2, wherein the receiver is set. The control unit determines a cutoff frequency of the attenuation unit and at least one of the first current value and the second current value based on the intensity of the reception signal of the adjacent channel measured by the detection unit. A computing unit for computing,
Measured by the detection unit from a control table in which the cutoff frequency of the attenuation unit and at least one of the first current value and the second current value are associated with each other according to the intensity of the reception signal of the adjacent channel A reading unit that reads the cutoff frequency of the attenuation unit corresponding to the intensity of the received signal of the adjacent channel and at least one of the first current value and the second current value;
The receiver according to claim 1, further comprising: a selection unit that selects one of a result calculated by the calculation unit or a result read by the reading unit.

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