JP2589203B2 - AGC circuit - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an AGC circuit used in, for example, an FM radio receiver, and more particularly to an AGC circuit capable of eliminating an influence of a local oscillation signal on an AGC operation. .

FIG. 5 is an equivalent circuit block diagram showing an example of a conventional AGC circuit. The AGC circuit detects the output signal level of the frequency converter and performs AGC. The AGC circuit was published on March 1, 1988 in "88 Sanyo Semiconductor Data Book, Bipolar Integrated Circuit for Car Audio (CQ Publisher) "No. 124
136 pages.

In FIG. 5, reference numeral 10 denotes an AGC circuit (AGC), for example, an IC 12
Integrated on top. 14 is an antenna circuit (ANT), R
First gate of F amplifier 16 and antenna input attenuator (AT
T) is connected to the pin diode 18. Reference numeral 20 denotes a frequency converter (MIX), which receives an antenna signal via an RF amplifier 16 and receives a local oscillation signal from a local oscillator (OSC) 22 via a buffer 24. 26 is a level detector which detects the level of the IF signal which is the output signal of the MIX20. The detected signal level is AGC1
Entered as 0.

The AGC 10 generates an AGC signal when the signal level has exceeded a predetermined level. The AGC signal is applied to a pin diode 18 and an RF amplifier 16 via a pin of the IC 12 and a pin, respectively.
And the levels of the antenna signal and the MIX input signal are attenuated. Thus, AGC 10
The AGC signal functions to keep the output level of the MIX 20 constant.

In this case, the relationship between the MIX input frequency and the AGC on level (AGC sensitivity) is as shown in FIG. As shown in FIG. 6, the AGC sensitivity becomes lower as the detuning degree Δf is larger than the center frequency (Δf = 0).

If there is no AGC, when the ANT input and MIX input levels increase, for example, the non-linearity of Tr or the like generates an IM (intermodulation) frequency, that is, a third-order distortion harmonic, and the interference characteristics deteriorate. Therefore, the AGC attenuates the ANT input and the MIX input, thereby suppressing the occurrence of distortion and improving the interference characteristics.

Further, in order to improve the interference characteristics when the degree of detuning Δf is large, the input to the AGC detection unit, that is, the level detector 26 may be a MIX input.

[Problem to be Solved by the Invention] In the above-described conventional technology, when an AGC signal is generated from a MIX output, if there is an adjacent station having a large electric field strength with respect to the center frequency, the characteristic shown in FIG. As a result, the AGC 10 generates an AGC signal for an adjacent station, and the originally desired tuning (center) frequency is attenuated, making it difficult to hear.

In addition, when the AGC signal is generated based on the MIX input, there is a problem that the AGC circuit makes a false difference due to the local oscillation signal. That is, the FM front end has a local oscillation circuit including a local oscillator 22 and a buffer 24,
The signal level is 300 mVrms to 1 Vrms, which is extremely large compared to the MIX input level. Also, the frequency of the local oscillation signal is 50
It is a high frequency of MHz to 120 MHz, and is a frequency in a band close to the MIX input signal. For this reason, there is a risk that a local oscillation signal is input to the AGC circuit due to GND, Vcc, air propagation, or the like, and an erroneous AGC signal is generated due to the local oscillation signal level.

Therefore, when applying the AGC by detecting the MIX input level,
It is necessary to lower the sensitivity of the AGC. However, lowering the sensitivity causes a new adverse effect that the interference (rejection) characteristic particularly at a frequency where the detuning degree Δf is small is reduced.

The present invention has been made in order to solve the above-described problems of the related art, and has an object to prevent a malfunction of an AGC circuit due to an influence of a local oscillation signal and to set an optimal AGC amount for a desired tuning signal. It is an object of the present invention to provide an AGC circuit.

Means for Solving the Problems In order to achieve the above object, an RF amplifier circuit of an FM radio receiver detects a signal level of a frequency converter according to the present invention and generates an AGC signal according to the signal level. An AGC circuit that controls the gain of the AGC circuit is a filter circuit that cuts off at least the frequency of the local oscillation signal with respect to the intermediate frequency signal that is the output signal of the frequency converter. A level detection circuit having a high detection sensitivity for the intermediate frequency signal, a first level detection circuit for detecting a level of the intermediate frequency signal band-limited by the filter circuit, and a detuning degree with respect to a center frequency. A level detection circuit having a constant detection sensitivity to the input signal to the frequency converter, regardless of the level of the input signal to the frequency converter. The comprises a second level detection circuit for detecting, and adding circuit for outputting a combined signal defining said AGC signal by adding the first and second level detection signal. Furthermore, the detection sensitivity of the second level detection circuit is set to be higher than the detection sensitivity of the first level detection circuit when the degree of detuning with respect to the center frequency is within a predetermined range.

[Operation] According to the AGC circuit of the present invention having the above configuration, the detection sensitivity can be set by the first AGC signal for the adjacent interfering station near the center frequency, and the electric field strength of the adjacent interfering station can be reduced. Image frequency signal (IM signal) generated when high
Can be effectively suppressed.

In addition, for the adjacent interfering station having a detuning degree equal to or greater than a predetermined value, a constant detection sensitivity can be set by the second level detection signal, thereby preventing excessive sensitivity suppression of the center frequency due to excessive AGC. be able to.

Furthermore, by filtering the output signal (intermediate frequency signal) from the frequency converter with a filter circuit,
From the output signal, a signal having a frequency equal to or higher than the frequency of the local oscillation signal is cut off and used as an input to a first level detection circuit.
Therefore, the malfunction of the AGC circuit due to the local oscillation signal is prevented not only by the detection sensitivity of the second level detection circuit but also by the filtering by the filter circuit.

On the other hand, the first level detection circuit performs level detection based on the intermediate frequency signal before IF detection, so that the intermediate frequency signal to be subjected to level detection includes some interference signals, and the detection output Since the level rises due to the disturbing signal, the disturbing signal can be suppressed by the AGC circuit.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a circuit block diagram showing one embodiment of an AGC circuit according to the present invention. The same or corresponding parts as those in FIG. 5 are denoted by the same reference numerals, and description thereof is omitted.

In Figure 1, 30 is a filter circuit which is a characteristic component of the present invention (low-pass filter), are constituted by resistors R ₁ and capacitor C ₁ determines the cutoff frequency.
The filter circuit 30 cuts off a signal of 50 MHz or more in the output signal line of the MIX 20 and outputs a local oscillation signal (50 MHz to 120 MHz).
MHz). When the AGC circuit of the present invention is formed into an IC, a stray capacitance (parasitic capacitance) C _S is generated.
The cutoff frequency is determined by the stray capacitance C _S.

Reference numeral 32 denotes a first level detection circuit, which is a second characteristic component of the present invention, as shown in FIG.
For example, it has a detection sensitivity that decreases in accordance with the detuning degree Δf with respect to the IF frequency f _I. The first level detection circuit 32 detects the output signal level of the MIX 20 band-limited by the filter circuit 30 according to the detection sensitivity.

Reference numeral 34 denotes a second level detection circuit, which is a third characteristic component of the present invention. As shown in FIG. 3, the second level detection circuit has a constant detection sensitivity irrespective of the center frequency, for example, the degree of detuning with respect to the tuning frequency. I have. The second level detection circuit 34 detects the input signal level of the MIX 20 according to the detection sensitivity. Second
Since a high frequency of about 60 MHz to 110 MHz is input to the level detection circuit 34, the frequency characteristics of the level detection circuit 34 need to extend at least to about 110 MHz. Since this frequency band is the same as the above-described local oscillation signal (50 MHz to 120 MHz), there is a risk that the second level detection signal becomes inappropriate due to the jump of the local oscillation signal and the AGC 10 malfunctions. Therefore, in this embodiment, thereby suppressing AGC sensitivity capacitance of the capacitor C ₂ to determine the AGC sensitivity (detection sensitivity) of the second level detection circuit 34 as C ₁ <C _2. This A
The GC sensitivity is set not only to a value that does not cause the above-mentioned malfunction but also to a value that can eliminate the IM signal described in the related art, including variations in elements, temperature characteristics, and the like.

Reference numeral 36 denotes an adder circuit, which is a fourth characteristic component of the present invention, which adds the first and second level detection signals and outputs a combined signal defining the AGC signal output from the AGC circuit 10. An offset circuit 38 determines the offset amount of the combined signal current value output from the addition circuit 36 and inputs the AGC current _IAGC to the AGC circuit 10.

FIG. 4 shows the relationship between the AGC signal center frequency defined by the AGC current I _AGC and the AGC on level. That is, as shown in FIG.
In the C circuit, first, a 50M
After removing the local oscillation signal of Hz (Hz120 MHz) or more, the first level detection circuit outputs the signal level, that is, the first level detection signal.

On the other hand, the second level detection circuit outputs the input signal level of the MIX 20, that is, the second level detection signal.

Then, the first and second level detection signals are added to an adding circuit.
The signal added at 36, that is, the synthesized signal, is
The AGC signal is applied to the AGC circuit 10 via 38 to control the gain of the RF amplifier circuit 16.

Here, since the detection sensitivity of the first level detection circuit 32 is set to be high for an adjacent interfering station close to the center frequency, it can be effectively attenuated, and the IM signal generated by the adjacent interfering station can be effectively attenuated. Can be effectively suppressed.

On the other hand, the detection sensitivity of the second level detection circuit 34 is set to be constant for an adjacent interfering station having a degree of detuning equal to or greater than a predetermined value, so that excessive suppression of the center frequency due to excessive AGC is prevented. can do.

As described above, the detuning degree (for example, in FIG. 4, Δf = ±
(Set at about 1 MHz), the detection sensitivity characteristic changes, so that an appropriate AGC amount can be set.

In this embodiment, the effect of the local oscillation signal is
By arranging a low-pass filter that cuts the signal of 50 MHz or more, and the constant detection sensitivity of the second level detection circuit,
This is eliminated by making the detection sensitivity higher than the detection sensitivity of the first level detection circuit at the time of detuning.

[Effects of the Invention] As described above, according to the AGC circuit of the present invention, the local oscillation signal is prevented from being mixed into the AGC circuit, and the detection sensitivity characteristic of the level detection is changed at a predetermined detuning degree. Therefore, it is possible to prevent the AGC circuit from malfunctioning due to the local oscillation signal and to set an optimal AGC amount for a desired reception signal. Further, since the first level detection signal is obtained by using the signal before demodulation, high adjacent interference rejection characteristics are obtained even in a range where the degree of detuning from the center frequency is relatively large.

[Brief description of the drawings]

FIG. 1 is a circuit block diagram showing an embodiment of an AGC circuit according to the present invention, FIG. 2 is an AGC sensitivity characteristic diagram in a first level detection circuit, and FIG. 3 is an AGC sensitivity characteristic in a second level detection circuit. FIG. 4, FIG. 4 is an AGC sensitivity characteristic diagram according to the present invention, FIG. 5 is an equivalent circuit block diagram showing an example of a conventional AGC circuit, and FIG. 6 is an AGC sensitivity characteristic diagram in a conventional example. 10 AGC circuit (16 RF amplifier) 20 Frequency converter 30 Filter circuit 32 First level detection circuit 34 Second level detection circuit 36 Addition circuit

Claims (1)

(57) [Claims] An AGC circuit for detecting a signal level of a frequency converter, generating an AGC signal corresponding to the signal level, and controlling a gain of an RF amplifier circuit of an FM radio receiver, wherein an output of the frequency converter is output. A filter circuit for intercepting a signal having a frequency equal to or higher than the frequency of the local oscillation signal with respect to the intermediate frequency signal, and a level detection having a higher detection sensitivity for the intermediate frequency signal as the degree of detuning with respect to a predetermined center frequency is smaller. A first level detection circuit for detecting a level of the intermediate frequency signal band-limited by the filter circuit; and a constant level for an input signal to the frequency converter regardless of a degree of detuning with respect to a center frequency. A second level detection circuit for detecting a level of an input signal to the frequency converter; And an adder circuit for adding a second level detection signal and outputting a synthesized signal defining the AGC signal, wherein the detuning degree with respect to a center frequency is within a predetermined range or more, and the second level detection circuit An AGC circuit, wherein the detection sensitivity is set to be higher than the detection sensitivity of the first level detection circuit.