JPH0786856A - Fm receiver - Google Patents

Abstract

PURPOSE:To prevent distortion and the decline of AM removal ratio from being generated in frequency modulated output by detecting the output level of a prefilter of an IF filter and controlling the level of IF signals supplied to the prefilter. CONSTITUTION:A level detector 50 is connected to the output terminal of the prefilter 21, detects the level of the output signals of the prefilter 21 and supplies level signals indicating the detected level to a gain control circuit 60. The gain control circuit 60 controls the level of gain control signals to be supplied to a mixer 10 so as to lower the gain of the mixer 10 when the level of the output signals of the prefilter 21 exceeds a prescribed value. In such a manner, a negative feedback control loop for reducing the gain of the mixer 10 so as to suppress the output when the output of the prefilter 21 increases exceeding a certain value and preventing the distortion of the output signals is formed. Also, when setting is performed so as to prevent a main filter 22 from amplifying passing signals, the generation of signal distortion can be prevented in the main filter 22 as well.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an FM receiver, and more particularly to improvement of an FM receiver having an IF (intermediate frequency) filter formed by an active filter.

[0002]

2. Description of the Related Art An example of the configuration of a conventional FM receiver is shown in FIG.
Will be described with reference to. In the figure, the FM signal arriving at the receiving antenna (not shown) is high-frequency amplified and supplied to the mixer 10. The mixer 10 multiplies the received high frequency by a local signal having a frequency corresponding to the tuning frequency to obtain an IF signal which is the frequency of the difference between the received high frequency signal and the local signal. Only the desired signal is separated from this IF signal by the IF filter 20 which is a bandpass filter. I
The IF signal that has passed through the F filter 20 has a limiter amplifier 3
When the amplitude is 0, the signal is amplified to have a constant amplitude, and is applied to the FM detector 40. The FM detector 40 generates a level output according to the frequency fraction deviation of the IF signal and obtains a demodulation output.

In the above structure, when the IF filter is composed of an active filter, the active filter is S / S compared with a passive filter such as a ceramic filter.
Since N is poor, it is common to form the IF filter by the pre-filter and the main filter, amplify the IF signal with the pre-filter having the BPF characteristic, and then connect the IF signal to the main filter having the narrower band characteristic.

[0004]

In the conventional configuration in which such an active filter is used for the IF filter, the IF signal is amplified by the pre-filter and supplied to the main filter. Therefore, when the level of the received signal increases, the level of the IF signal increases. Saturation occurs and the IF signal is distorted in the pre-filter or main-main filter.

The pre-filter and the main filter form a negative feedback loop because of the structure of the active filter. When the IF signal is distorted, the negative feedback is not correctly performed, and the phase of the filter output signal is shifted to cause phase distortion. Then, it causes distortion of the demodulation output and also causes a decrease in the AM removal ratio of the demodulation output.

For example, the band pass filter shown in FIG. 7 will be described as an example. In the figure, OP1 to OP3 are operational amplifiers, R1 to R7 are resistors, and C1 to C2 are capacitors. This filter is a so-called state variable type filter or biquad type filter, and operates as a first-order pair bandpass filter.

The central angular frequency ω of this bandpass filter
₀ is ω ₀ ² = R ₂ / (R ₃ R 6 R 7 C 1 C 2), and if this formula is modified, (R ₂ / R 3) × (1 / ω ₀ C 1 R 6) × (1 / ω ₀ C 2 R 7). = 1 (1) Here, considering the case where the negative feedback loop composed of three operational amplifiers is opened to make it an open loop,
In the equation (1), (R ₂ / R 3) is the gain of the operational amplifier 1, (1 /
Since the gain of ω ₀ C1 R6) and (1 / ω ₀ C2 R7) are the gain of the operational amplifier 3, the central angular frequency ω ₀ is the angular frequency at which the total gain of the operational amplifiers 1 to 3 in the open loop is 1. is there.

Next, consider the case where the output is saturated and distortion occurs. The occurrence of distortion is considered to be a decrease in gain. In this state, the central angular frequency ω ₀ is lowered and the phase of the output signal is delayed. Therefore, when the filter output is used with distortion, the phase of the output signal is delayed compared to when there is no distortion.
Such a phenomenon occurs as long as it is an active filter, and is particularly remarkable when a negative feedback is applied by using a plurality of amplifiers.

Therefore, an object of the present invention is to prevent distortion or reduction in the AM rejection ratio in the FM demodulation output due to distortion of the passing signal in the IF filter.

[0010]

In order to achieve the above object, an FM receiver according to the present invention comprises a frequency converter for mixing a received high frequency signal with a local oscillation signal and converting it into an intermediate frequency signal, and an intermediate frequency signal for converting the intermediate frequency signal. An IF filter including a pre-filter for band amplification and a main filter having a narrow band pass characteristic for separating a desired wave signal from the output of the pre-filter;
A limiter amplifier that equalizes the amplitude of the output signal of the filter,
An FM detector that generates a level signal according to the frequency deviation of the output signal of the limiter amplifier, a level detection circuit that detects the output signal level of the prefilter, and the frequency converter according to the output of the level detection circuit. A control circuit for controlling the gain of the IF filter and suppressing the level saturation of the desired wave signal in the IF filter.

[0011]

The desired wave signal is distorted in the pre-filter and the main filter by detecting the output level of the pre-filter of the IF filter for separating the desired wave signal from the IF signal and controlling the level of the IF signal supplied to the pre-filter. Prevent.

As a result, it is possible to prevent the distortion of the FM demodulation output and the reduction of the AM rejection ratio due to the distortion of the desired wave signal in the IF stage.

[0013]

Embodiments of the present invention will be described below with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 3 are designated by the same reference numerals, and description of such parts will be omitted.

In the configuration of this embodiment, the level detector 50
Also, a gain control circuit 60 is added. The level detector 50 is connected to the output terminal of the pre-filter 21, detects the level of the output signal of the pre-filter 21, and supplies a level signal indicating the detected level to the gain control circuit 60. The gain control circuit 60 controls the level of the gain control signal supplied to the mixer 10 so as to reduce the gain of the mixer 10 when this detection level, that is, the level of the output signal of the pre-filter 21 exceeds a predetermined value. In this way, when the output of the pre-filter 21 increases beyond a certain value, the gain of the mixer 10 is reduced so as to suppress this output,
A negative feedback control loop is formed that prevents distortion of the output signal. Since the output signal of the pre-filter 21 is adjusted so as not to exceed a predetermined level, if the main filter 22 is set so as not to amplify the passing signal, the main filter 2
Even with 2, it is possible to prevent signal distortion.

FIG. 3 shows an example of the structure of the level detector 50. The level detector 50 includes a level comparator 51, a detector 52, a reference voltage source E ₀ , and a capacitor C, and an input signal is input to the level comparator 51. When the amplitude of the input signal exceeds the reference voltage E ₀ , the “H” level output of the level comparator 51 is generated during that period. This output is smoothed by the detector 52 and the capacitor C ₀ , and is converted into a DC voltage output signal corresponding to the amplitude of the input signal. Level detector 50 by such arrangement, the level of the input signal and outputs the "H" level in advance exceeds the reference voltage E _0, and outputs the "L" level when not exceed the reference voltage E _0.

FIG. 4 shows a configuration example of the gain control circuit 60. A generally used Gilbert multiplier (double balanced differential amplifier) is used for the mixer 10. The gain control voltage is supplied to the variable current source 61 of the multiplier to increase or decrease the bias current of the multiplier. Further, the variable attenuator 62 is connected to the input signal end of the multiplier, and the level of the input signal passing through the variable attenuator 62 is adjusted according to the gain control voltage. Here, the variable current source 61 and the variable attenuator 62 correspond to the gain control circuit 60. Even if both the bias current level of the multiplier and the level of the input signal are not adjusted,
For example, the gain control circuit 60 can be configured with only one variable current source 61.

In the above embodiment, the output signal level is detected at the output terminal of the pre-filter 21. This is for the following reason. First, the main filter 2
When the signal level is detected at the output terminal of No. 2, the pass frequency band characteristic of the main filter 22 does not pass the distorted frequency component of high frequency, and therefore it is not possible to know whether or not the output of the pre-filter 21 is distorted. It is convenient to detect the output signal level of the pre-filter 21. On the other hand, when the signal level is detected before the pre-filter 21, it is before the filter is applied, and the output signal also includes the interfering wave signal other than the desired wave. Therefore, it is difficult to expect an accurate control operation due to the influence of the level of the interfering wave signal. Further, before amplification by the pre-filter, the signal level is low, so it is difficult to detect the level.

With this structure, the output signal of the pre-filter 21 is prevented from being distorted due to an excessive level.

FIG. 2 shows another embodiment of the present invention. In the figure, parts corresponding to those in FIG. 1 are designated by the same reference numerals, and description of such parts will be omitted. In this embodiment, the output signal of the pre-filter 21 is level-detected by the level detector 50, and the detected level is supplied to the controller 70 via an A / D converter of an interface (not shown). The controller 70 is configured by using a microprocessor or the like, and the data of the gain control signal to be output corresponding to the level of the output signal of the pre-filter 21 is not shown in the figure.
Read from OM. In this ROM, a control characteristic curve of the level of the output signal versus the gain control signal level is programmed in advance and is stored in, for example, a tabular form. The read data is given to a D / A converter (not shown) to become a gain control signal, which is supplied to the gain control circuit 60.
By using such a controller 70, the gain of the mixer can be controlled with a desired control characteristic.

Furthermore, by setting the frequency of the IF signal to a low frequency, it becomes easy to configure the IF filter with an active filter. In this case, since the frequency difference between the desired wave signal and the image frequency signal is twice the frequency of the IF signal, the difference between the two frequencies is small,
It becomes difficult to remove the image signal. Therefore, it is convenient to use an image cancellation type mixer.

FIG. 5 shows an example of an image cancellation type mixer. In the figure, mixers 11 and 12
An RF (high frequency) signal is supplied as an input signal to the one input terminal. The other input terminals of the mixers 11 and 12 are supplied with a local signal whose (π / 2) radian phase is shifted and a local signal whose phase is not shifted by the phase shifter 13, respectively. In the output of the mixer 11, the phase of the desired wave signal is shifted by (π / 2) radian phase.
The output of the mixer 12 is not phase-shifted, but the phase of the desired wave signal is (π
/ 2) Radians are phase-shifted. The two desired wave signals are added in phase by the adder 14, and a signal obtained by adding the two desired wave signals is obtained at the output of the adder 14.

On the other hand, since the image signal in the RF signal undergoes a phase shift of-(π / 2) radian at the output of the mixer 11, they are added at the inputs of the adder 14 in opposite phases. Therefore, the image signals are canceled at the output of the adder 14, and the image signal to be removed by the filter does not appear in the IF output signal. Therefore, it is convenient when an active filter is used for the IF filter having a low IF frequency as described above.

[0023]

As described above, according to the FM receiver of the present invention, the level of the output signal of the prefilter is detected,
The mixer gain is controlled according to the detection level to prevent the IF signal passing through the pre-filter and the main filter from being distorted, so that the demodulation output may be distorted or the AM rejection ratio may be lowered. It becomes possible to suppress.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of an FM receiver according to the present invention.

FIG. 2 is a block diagram showing a second embodiment of the FM receiver of the present invention.

FIG. 3 is a block diagram showing a configuration example of a level detector.

FIG. 4 is a block diagram showing a configuration example of a gain control circuit.

FIG. 5 is a block diagram showing an example of an image cancellation type mixer.

FIG. 6 is a block diagram showing a configuration example of a conventional FM receiver.

FIG. 7 is a circuit diagram showing a configuration example of an active filter.

Claims (2)

[Claims] 1. A frequency converter for mixing a received high frequency signal with a local signal to convert it to an intermediate frequency signal, a prefilter for band-amplifying the intermediate frequency signal, and a desired wave signal separated from the output of the prefilter. An IF filter including a main filter having a narrow band pass characteristic, a limiter amplifier that equalizes the amplitudes of the output signals of the IF filter, and an FM detector that generates a level signal according to the frequency deviation of the output signal of the limiter amplifier. A level detection circuit for detecting the output signal level of the pre-filter, a gain control of the frequency converter according to the output of the level detection circuit, and a control for suppressing the level saturation of the desired wave signal in the IF filter. An FM receiver comprising: a circuit. 2. The FM receiver according to claim 1, wherein the frequency converter is an image cancellation mixer.