JP2005348289A - Receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a receiver to conduct an appropriate AGC control even to a big interference wave. <P>SOLUTION: The receiver is provided with an AGC loop having an AGC circuit 30 to control a gain of a LNA 13 on the basis of a strength of a receiving signal and a level setting loop to set an AGC level of the AGC circuit 30. The level setting loop compares a strength (RSSI) of an objected signal obtained from the receiving signal with a reference value and is provided with a comparator 21 to output the compared result signal. The AGC circuit 30 controls the AGC level variably based on the compared result signal of the comparator 21. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a receiver, and more particularly, to an AGC control method for a receiver.

AGC (Automatic Gain Control) control is performed to set the intensity of a received signal to an appropriate value from a predetermined viewpoint such as reception sensitivity.
FIG. 5 is a block diagram showing a configuration of a conventional receiver.
As shown in FIG. 5, conventionally, when such AGC control is performed, the AGC level is set to a fixed value in the AGC circuit 90. The operation of the receiver shown in FIG. 5 will be described below.

First, a signal is received via the antenna unit 81, and the received signal is filtered in a band pass filter (BPF) 82.
The filtered signal is input to a low noise amplifier (LNA) 83 controlled by AGC control, where it is amplified. The amplified signal and the local oscillation signal from the local oscillator 84 are input to the mixer 85 where they are mixed to perform frequency conversion. Then, an extra frequency component is cut from the frequency-converted signal by filter processing in an intermediate frequency bandpass filter (IF-BPF) 86.

The output signal of the IF-BPF 86 is input to the detection unit 88 via the limiter 87, where a predetermined detection process is performed, and then input to the stereo demodulation unit 89, where the predetermined stereo demodulation process is performed. The stereo demodulator 89 outputs the stereo demodulated L and R signals.
As a technique for performing feedback based on received signal strength and controlling on / off of an amplifier, for example, there is a receiver disclosed in Patent Document 1. This receiver includes a comparator that compares a received signal strength (received electric field strength) detected by a level detector with a reference level output from a reference level device in a loop for turning on / off the amplifier. And a control circuit for sending a control signal to a high-frequency amplifier (amplifier) and a reference level device based on the comparison result.

  The reference level device switches which of the first level LH and the second level LL (LH> LL) is output to the comparator as a threshold based on a signal from the control circuit. That is, when the input from the level detector to the comparator exceeds the first level LH, the control circuit instructs the reference level device to output the level LL as the reference level to the comparator and turns off the high-frequency amplifier. To. The high frequency amplifier operates as an attenuator when turned off. When the input from the level detector to the comparator becomes equal to or lower than the second level LL, the control circuit instructs the reference level device to output the level LH as the reference level to the comparator and turns on the high-frequency amplifier. To do.

And by setting it as such a structure, it is trying not to reduce the sensitivity at the time of reception standby. However, this prior art relates to a technique for reducing power consumption by, for example, suspending a part of the apparatus during reception standby, and the interference wave included in the received signal is originally considered. Absent.
“Practical analog electronic circuit design method” by Kazuo Watanabe, General Electronic Publishing Company, 1996, PP 151-155 Japanese Patent Laid-Open No. 5-167465 “Receiver”

In such a receiver, the gain of the LNA 83 is controlled based on the AGC level of the AGC circuit 20. And since this AGC level is a fixed value, the following problems have arisen.
First, when the AGC level is set to a high level and the reception level of the desired wave is smaller than a practical sensitivity level indicating a level of reception level that can be audibly identified, for example, less than 30 dBμV, the noise is intermodulated. The effect becomes noticeable.

Here, the intermodulation is noise generated by the modulation product of the frequencies f2 and f3 different from the frequency f1 of the desired wave as shown in FIG. The intermodulation is described in more detail in Non-Patent Document 1.
Further, the signal received via the antenna unit 81 includes an interference wave component other than the desired wave. Since the AGC control is performed according to the strength of the dominant component included in the received signal, for example, as shown in FIG. 5, when the level of the disturbing wave is larger than the level of the desired wave However, there is a problem that the AGC control is operated according to the level of the jamming wave, and the level of the desired wave is also suppressed by the AGC control for the large jamming wave, so that the reception sensitivity is lowered. In particular, when the AGC level is set to a low value and therefore the AGC control is tight, if the level of the desired wave is greater than the practical sensitivity level, such a decrease in reception sensitivity is more noticeable. Become.

  An object of the present invention is to provide a receiver capable of performing appropriate AGC control even for a large interference wave.

  The receiver of the present invention comprises an AGC loop having AGC means for controlling the gain of an amplifier based on the strength of the received signal, and a level setting loop for setting the AGC level of the AGC means, the level setting loop comprising: Comparing means for comparing the intensity of the target signal obtained from the received signal with a reference value and outputting a signal of the comparison result, the AGC means variably changing the AGC level based on the comparison result signal It is a receiver characterized by controlling.

  Here, in the comparison means, the strength of the target signal obtained from the received signal is compared with a reference value, and the AGC level of the AGC level means is variably controlled based on the comparison result signal. For this reason, when a received signal including a desired wave and an interfering wave is handled in the AGC loop, for example, an AGC level based on the intensity of the desired wave (target signal) is also applied to an interfering wave larger than the desired wave. Setting is possible, and appropriate AGC control can be performed.

  According to the receiver of the present invention, the AGC level is switched by comparing the level of the target signal extracted from the received signal with the reference value corresponding to the practical sensitivity level. When the target signal level is lower than the reference value, the AGC level is lowered to prevent circuit saturation due to the interference wave included in the received signal and to reduce output noise. . If the target signal level is higher than the reference value, the AGC level is raised (or returned to the normal level), so that the desired signal, circuit saturation due to jamming waves, and reception sensitivity decline due to jamming waves Can be prevented.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram illustrating a configuration of a receiver according to an embodiment of the present invention.
In FIG. 1, the receiver of this embodiment includes an antenna 11, a band pass filter (BPF) 12, a low noise amplifier (LNA) 13, a local oscillator 14, a mixer 15, an intermediate frequency band pass. A filter (IF-BPF) 16, a limiter 17, a detector 18, a stereo demodulator 19, an AGC circuit 20, and a comparator 21 are provided.

Hereinafter, the operation of the receiver will be described.
First, a signal including various components such as a desired wave and an interference wave is received via the antenna unit 11, and the received signal is filtered by a band pass filter (BPF) 12.
The filtered signal is input to a low noise amplifier (LNA) 13 that is AGC-controlled and amplified there. The amplified signal and the local oscillation signal from the local oscillator 14 are input to the mixer 15 where they are mixed to perform frequency conversion. Then, an extra frequency component is cut by the filter processing in the intermediate frequency band pass filter (IF-BPF) 16 with respect to the frequency-converted signal, and a target signal is obtained from the received signal.

The output signal of the IF-BPF 16 is input to the detection unit 18 via the limiter 17, and after predetermined detection processing is performed there, it is input to the stereo demodulation unit 19 and subjected to predetermined stereo demodulation processing. Then, stereo demodulated L and R signals are output from the stereo demodulator 19.
Further, the limiter 17 obtains the received signal strength (RSSI) of the target signal obtained from the received signal, and inputs the RSSI to one input terminal of the comparator 21. A predetermined voltage (reference voltage) corresponding to the practical sensitivity level is applied to the other input terminal of the comparator 21, and the comparator 21 compares this reference voltage with the RSSI of the target signal, and the comparison result signal Is output to the AGC circuit 20.

  The AGC circuit 20 that has received the comparison result signal switches the AGC level for controlling the gain of the LNA 13 based on the comparison result signal. Preferably, when the RSSI is smaller than the reference voltage, the AGC circuit 20 sets the AGC level to be lower than a predetermined level, and when the RSSI is equal to or higher than the reference voltage, the AGC circuit 20 sets the AGC level to a predetermined level. Switch to set the level. In this way, in the loop from the limiter 17 to the LNA 13 via the comparator 21 and the AGC circuit 20, and further to the limiter 17 again via the mixer 15 and IF-BPF 16 between the LNA 13 The AGC level of the loop is set.

  As described above, in the present embodiment, the comparator 21 compares the RSSI obtained through the limiter 17 with the reference voltage, and the AGC circuit 20 determines the AGC level of the AGC loop according to the comparison result. Is controlled. As a result, an AGC level can be set based on the intensity of the desired wave (target signal) even for an interference wave larger than the desired wave, and appropriate AGC control can be performed.

FIG. 2 is a diagram illustrating a configuration of a main part of the receiver of FIG. 1, and is a diagram illustrating a more detailed configuration of an AGC circuit, a comparator, and related parts thereof.
In FIG. 2, the intensity (RSSI) of the signal detected from the limiter 17 is supplied to the analog comparator 21, where the magnitude relationship between the RSSI signal of the analog value and the reference value of the analog value is compared. The comparator 21 outputs the comparison result signal to the AGC level switching unit 31 in the AGC circuit 30.

  The AGC circuit 30 includes two constant current sources 32 and 33, a switch 34, and an operational amplifier 35. The constant current source 32 always supplies current to one input terminal of the operational amplifier 35. A switch 34 is connected in series to the constant current source 33, and the switch 34 is turned on / off according to the value of the comparison result signal, and the current from the constant current source 33 is supplied to one input terminal of the operational amplifier 35. Whether or not to be supplied is switched. The constant current source 33 and the switch 34 constitute an AGC level switching circuit 31.

An output signal of a mixer (not shown) is input to the other input terminal of the operational amplifier 35. In the operational amplifier 35, the output signal of the mixer is compared with a threshold value that determines an AGC level input to one input terminal. .
In FIG. 2, when the RSSI signal is equal to or higher than the reference value, a control signal for turning on (conductive) the switch 34 is output from the comparator 21. Thereby, the threshold value input to one input terminal of the operational amplifier 35 in the AGC circuit 30 is determined based on the current value obtained by adding the current from the constant current source 33 to the current from the constant current source 32. Therefore, the threshold value is set higher. This indicates that the AGC control is not easily triggered, that is, the AGC level is set to a higher level, for example, 100 dBμV.

  On the other hand, when the RSSI signal is smaller than the reference value, a control signal for turning off (non-conducting) the switch 34 is output from the comparator 21. As a result, the threshold value input to one input terminal of the operational amplifier 35 in the AGC circuit 30 is determined based only on the current from the constant current source 32, and the threshold value is set lower. This indicates that the AGC control is easily triggered, that is, the AGC level is set to a lower level, for example, 80 dBμV.

In the above description, the comparator 21 that outputs the comparison result signal to the AGC circuit 30 is an analog comparator, but may be configured as a digital comparator.
FIG. 3 is a diagram illustrating a case where a comparator that outputs a comparison result signal to the AGC circuit is configured as a digital comparator.

In FIG. 3, the signal strength (RSSI) detected from the limiter 17 is converted from an analog value to a digital value via the A / D converter 51 and supplied to the digital comparator 52.
The digital comparator 52 receives an RSSI signal expressed as a digital value and a reference value expressed as a digital value, and compares the magnitude relationship between them. Then, the comparison result signal is output from the digital comparator 52 to the AGC level switching unit 41 in the AGC circuit 40.

  The AGC level switching unit 41 controls the AGC level in two stages by turning on / off the switch 42 based on the comparison result signal. In FIG. 3, when the RSSI signal is smaller than the reference value, a control signal that turns on (conductive) the switch 42 is output from the digital comparator 52. In this case, since the switch 42 is turned on, a resistor having a resistance value R between the constant current source 43 and the operational amplifier 44 in the AGC circuit 40 is connected to the ground at the branch point P. Therefore, the voltage at the branch point P is the voltage across the resistor having the resistance value R. If the output current of the constant current source 43 is I, the voltage at the branch point P is R × I.

Therefore, a lower AGC level determined by R × I is set to one input terminal of the operational amplifier 44 in the AGC circuit 40 and is input to the other input terminal of the operational amplifier 44 in the AGC circuit 40. AGC control is performed on the output signal of the mixer (not shown) from a low signal level.
On the other hand, when the RSSI signal is equal to or higher than the reference value, a control signal for turning off (non-conducting) the switch 42 is output from the digital comparator 52. In this case, since the switch 42 is turned off, a resistor having a resistance value 2R is connected between the branch point P provided between the constant current source 43 and the operational amplifier 44 in the AGC circuit 40 and the ground. Therefore, the voltage at the branch point P becomes the voltage across the resistance value 2R, 2R × I.

Therefore, a higher AGC level determined by 2R × I is set to one input terminal of the operational amplifier 44 in the AGC circuit 40 and is input to the other input terminal of the operational amplifier 44 in the AGC circuit 40. AGC control is not applied until the output signal of the mixer (not shown) reaches its AGC level.
In FIG. 3, the AGC level switching unit switches the AGC level to two stages, but it is also possible to switch the AGC level to a plurality of stages according to the RSSI signal. For example, FIG. 4 shows a case where the AGC level is switched in four stages.

4, a selector 53 that generates a control signal to the AGC level switching unit 61 in the AGC circuit 60 based on the comparison result (output) signal from the comparator is added as compared with FIG. The selector 53 generates a control signal for switching the AGC level in stages. That is, in the order from the lowest AGC level to the lower AGC level, and therefore in the order in which the AGC trigger is hard to be triggered, “turn all switches U ₀ , U ₁ , U ₂ off” “turn switch U ₀ on” “switch U A control signal such as “turn ON ₀ and U ₁ ” and “turn ON switches U ₀ , U ₁ , U ₂ ” is generated in the selector 53 based on the comparison result signal from the digital comparator 52, and switches the AGC level. Each is supplied to the unit 61. Thereby, finer stepwise control of the AGC level based on the RSSI signal becomes possible.

  As described above, according to the present invention, the AGC level is switched by comparing the level of the target signal extracted from the received signal with the reference value corresponding to the practical sensitivity level. When the target signal level is lower than the reference value, the AGC level is lowered to prevent circuit saturation due to the interference wave included in the received signal and to reduce output noise. . In this case, the desired wave is also suppressed, but considering that the desired wave level is lower than the practical sensitivity level, the suppression of the desired wave is not a big problem. If the target signal level is higher than the reference value, the AGC level is raised (or returned to the normal level), so that the desired signal, circuit saturation due to jamming waves, and reception sensitivity decline due to jamming waves Can be prevented.

It is a block diagram which shows the structure of the receiver of one Embodiment of this invention. It is a figure which shows the structure of the principal part of the receiver of FIG. 1, and is a figure which shows the more detailed structure of an AGC circuit, a comparator, and its related part. It is a block diagram which shows the case where the comparator which outputs a comparison result signal with respect to an AGC circuit is comprised as a digital comparator. It is a block diagram which shows the case where an AGC level is switched in four steps in the case of a digital comparator. It is a block diagram which shows the structure of the conventional receiver. The influence of intermodulation will be described.

Explanation of symbols

11 Antenna 12 Band pass filter (BPF)
13 Low noise amplifier (LNA)
14 Local oscillator 15 Mixer 16 Intermediate frequency bandpass filter (IF-BPF)
17 limiter 18 detector 19 stereo demodulator 20, 30, 40, 60 AGC circuit 21 (analog) comparator 31, 41, 61 AGC level switching circuit 32, 33, 43 constant current source 34, 42 switch 35, 44 (AGC circuit) Operational amplifier 51 A / D converter 52 Digital comparator 53 Selector

Claims (3)

An AGC loop having AGC means for controlling the gain of the amplifier based on the intensity of the received signal, and a level setting loop for setting the AGC level of the AGC means,
The level setting loop includes a comparison unit that compares the intensity of a target signal obtained from a received signal with a reference value and outputs a signal of the comparison result.
The receiver, wherein the AGC means variably controls the AGC level based on the comparison result signal. When the strength of the target signal obtained from the received signal is smaller than the reference value, the AGC means sets the AGC level to be lower than a predetermined level,
2. The receiver according to claim 1, wherein the AGC means sets the AGC level to a predetermined level when the intensity of the target signal obtained from the received signal is equal to or higher than the reference value. The receiver according to claim 1, wherein the reference value is set based on a practical sensitivity level indicating an audible level.

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