DE4244357A1 - Satellite communication system with video signal compensation - Google Patents

Abstract

The satellite communication-receiver system has a signal converter (10) coupled to a demodulator (20), a circuit (30) to detect the noise level in the demodulator output, a circuit (40) to detect a signal and to identify video and audio signals. Further stages process the audio (50) and the video (70) components. A comparator (60) checks the signal level against a reference and also the noise level against a stored value. An output is generated to adjust the level of operation of the video processing stage.

Description

The present invention relates generally to a satellite litenrundfunk receiving system and in particular a Satelli broadcasting reception system to prevent loss of quality the image quality, which is reduced by reducing the ger / noise ratio and the reception sensitivity of the received satellite broadcast signal due to a Bad weather, such as precipitation, can be caused.

Fig. 3 shows a block diagram of a conventional satellite broadcast receiving system. According to this figure, the conventional satellite broadcast receiving system comprises a tuner 1 which is a it supplied first intermediate frequency signal quenzsignals converts into a second intermediate frequency signal ei nem lower band than that of the first Zwischenfre, a circuit 2 for automatic gain control (AGC) for automatically controlling the gain of the second intermediate frequency signal from the tuner 1 in response to a gain control signal, an amplifier 3 for amplifying the gain-controlled second th intermediate frequency signal from the circuit 2 for automatic gain control at a predetermined gain, a rectifier 4 for rectifying the output signal from the amplifier 3 , an amplifier 5 for amplifying the output signal from the rectifier 4 at a predetermined gain and for outputting the amplified signal as the gain control signal to the automatic V circuit 2 amplification control, a demodulator 6 for demodulating the output signal from the amplifier 3 in a frequency corresponding to the original baseband of a received satellite broadcast signal, a circuit 7 for detecting a signal for detecting an image signal and a sound signal from the output signal of the demodulator 6 , a sound signal processing circuit 8 for processing the detected audio signal from the circuit 7 for detecting a signal to make the audio signal audible, an image signal processing circuit 9 for processing the detected audio signal from the circuit 7 for detecting a signal to make the image signal representable, a telop signal generating circuit 10 for generating a predetermined telop signal and a switch 11 for selectively outputting the output signal from the telop signal generating circuit 10 or from the image signal processing circuit 9 in response to the output signal of the amplifier kers 5

The operation of the conventional Sa Tellite broadcast receiving system with the above mentioned described structure.

The received via a parabolic antenna (not shown) satellite broadcast signal is first converted in a down converter (not shown) into the first intermediate frequency signal from 1,035 to 1,336 GHz. The first intermediate frequency signal from the down converter is converted in tuner 1 into the second intermediate frequency signal of 402.78 MHz. The circuit 2 for automatic gain control automatically controls the gain of the second intermediate frequency signal from the tuner 1 in response to the output signal from the amplifier 5th The gain-controlled second intermediate frequency signal from the circuit 2 for automatic gain control is amplified at a predetermined gain in the amplifier 3 and then demodulated in the demodulator 6 into the frequency signal of the original baseband of 27 MHz.

On the other hand, the output signal from the amplifier 3 in the rectifier 4 is converted into a direct current (DC) signal and then amplified at a predetermined gain in the amplifier 5 . The output signal from Ver more 5 is used as the gain control signal of the circuit 2 supplied to the automatic gain control which automatically controls the gain of the second Zwischenfrequenzsi gnals from the tuner 1 in response to the gain control signal from the amplifier. 5

The circuit 7 for detecting a signal detects the image signal and the sound signal from the output signal of the de modulator 6 . The sound signal processing circuit 8 performs a digital demodulation on the detected sound signal from the circuit device 7 for detecting a signal to process the detected sound signal so that it becomes audible. The image signal processing circuit 9 removes from the detected image signal from the circuit 7 for detecting a signal a low frequency signal or an energy diffusion signal which is mixed at a bandwidth compression to obtain the displayable image signal. The Telop signal generating circuit 10 generates a character signal such as "poor reception condition".

At this time, provided that the level of the gain control signal from the amplifier 5 becomes lower than a predetermined reference voltage, the switch 11 gives the one due to the change in the electric field due to a bad weather such as rain, as shown in FIG plotting a change in the gain control signal shows the output signal from the telop signal generating circuit 10 as the final image signal. In contrast, when the level of the gain control signal is higher than the predetermined reference voltage, the switch 11 outputs the output signal from the image signal processing circuit 9 as the final image signal.

That is, the image signal of the received satellite broadcast radio signal is displayed when the reception condition of the received satellite broadcast signal is good while on place the received image signal the telop signal, as in for example "bad reception condition" is shown, if the reception condition of the received satellite broadcast radio signals due to bad weather conditions, as with for example when it is raining, is bad.

The conventional satellite broadcast mentioned above However, the radio reception system has the following disadvantages:

First, when the receiving condition of the receive NEN satellite broadcast signal due to bad weather location, such as in precipitation, is bad, no device provided that the satellite round radio signal compensates for the bad reception condition, au ß that a string such as "bad Reception condition "is shown.

Second, because of the receiving condition of the receive NEN broadcasting signal based on the signal of the automatic gain control (AGC) is differentiated, the reception condition cannot be differentiated exactly. This results from the slight change in the gain control signal during precipitation. In fact it will Carrier / Noise (C / N) ratio due to precipitation tiny.

It is therefore an object of the present invention to provide a satellite broadcast receiving system which an image signal of a received satellite broadcast signal can compensate if the receiving condition of the received Satellite broadcast signal due to bad weather, such as when there is precipitation.

This task is carried out by a satellite broadcasting emp Catch system solved according to claim 1.

The above task and other tasks, features and advantages of the present invention will become apparent from the  following detailed description in connection with clarified in the attached pictures, it shows:

Fig. 1 is a schematic block diagram of an inventive satellite broadcast receiving system;

Fig. 2 is a graph showing the change in a gain control signal;

Fig. 3 is a block diagram of a conventional satellite broadcast receiving system;

Fig. 4 is a detailed block diagram of an embodiment of the satellite broadcast receiving system of the present invention shown in Fig. 1;

Fig. 5 is a flow chart for explaining the inventive method of operation of a comparator unit;

Fig. 6 is a graph showing the manifestations of a carrier and the noise contained in a received satellite broadcast signal;

Fig. 7 is a detailed block diagram of an alternative embodiment of the inventive satellite broadcast receiving system of Fig. 1;

Fig. 8 is a detailed block diagram of a filter circuit of the image signal processing circuit in the system of Fig. 7; and

Fig. 9 is a circuit diagram of a Luminanzsignalpro zessors and the filter circuit of the image signal process ing circuit in the system of Fig. 7.

Fig. 1 shows a schematic block diagram of a satellite broadcast receiving system according to the invention. As shown in this figure, the satellite broadcast receiving system according to the invention comprises: a signal converter circuit 10 , which receives a gain control signal, for converting a first intermediate frequency signal supplied to the circuit into a second intermediate frequency signal, the band of which is lower than that of the first intermediate frequency signal, and for automatically controlling the gain of the second intermediate frequency signal in response to the gain control signal, a demodulator 20 for demodulating the second intermediate frequency signal from the signal converter circuit 10 into a frequency signal corresponding to the original baseband of a received satellite broadcast signal, the signal converter circuit 10 receiving the gain control signal from Output signal of the demodulator 20 receives, a circuit 30 for detecting a noise level from the output signal of the demodulator 20 , a circuit 40 for detecting a signal Detecting an image signal and a sound signal from the output signal of the demodulator 20 , a sound signal processing circuit 50 for processing the detected sound signal from the circuit 40 for detecting a signal to make the sound signal audible, a comparator unit 60 for comparing the gain control signal from the signal converter circuit 10 with a predetermined reference gain control signal stored in the comparator unit or for comparing the determined noise level by the circuit 30 for detecting a noise level with a predetermined reference noise level stored in the comparator unit and for generating a control signal for processing the determined image signal from the Circuit 40 for detecting a signal according to the comparison results, and an image signal processing circuit 70 for equalizing the image signal from the circuit 40 for detecting a signal or for normal ver operate the image signal in response to the control signal from the comparing unit 60 and then process the image signal to make the signal representable.

Fig. 4 shows a detailed block diagram of an embodiment of the inventive satellite broadcast receiving system of Fig. 1. As shown in this figure, the signal converter circuit 10 in Fig. 1 comprises: a tuner 10 a for converting the tuner supplied to it most Intermediate frequency signal in the second intermediate frequency signal, the band is lower than that of the first intermediate frequency signal, a circuit 10 c for automatic gain control for automatically controlling the gain of the second intermediate frequency signal from the tuner 10 a in response to the gain control signal, an amplifier 10 d for amplifying the Output signal from the circuit 10 c for automatic gain control at a predetermined gain and a rectifier 10 b for rectifying the output signal from the demodulator 20 and for outputting the rectified signal as the gain control signal to the circuit 10 c for automatic gain control.

The circuit 30 shown in FIG. 1 for detecting a noise level has a filter 30 a for filtering the output signal from the demodulator 20 in order to determine a desired frequency band of a signal corresponding to a noise, an amplifier 30 b for amplifying the output signal from the filter 30 a at a predetermined gain, and a peak detector 30 c for detecting an envelope curve corresponding to the peak value of the output signal from the amplifier 30 b. The peak value detector 30 c can have an integrator and the filter 30 a can be a bandpass filter with an upper limit value that is higher than that of the original baseband of the received satellite broadcast signal.

The circuit 40 shown in FIG. 1 for detecting a signal has a sound signal detector 40 a for determining only the sound signal from the output signal of the demodulator 20 and an image signal detector 40 b for detecting only the image signal from the output signal of the demodulator 20 . Here, the tone signal detector 40 a have a 5.73 MHz band pass filter BPF and the image signal detector 40 b have a low-pass filter TPF.

The image signal processing circuit 70 in Fig. 1 has a first amplifier 70 a for amplifying the determined image signal from the circuit 40 for detecting a signal at a predetermined gain, a second amplifier 70 b for amplifying the output signal from the first amplifier 70 a predetermined gain, a filter 70 c for filtering the output signal from the second amplifier 70 b in order to remove a noise corresponding to the high-frequency band of the signal, and a switch 70 d to which the output signals from the first amplifier 70 a and from the filter 70 c are supplied and selectively outputs one of the supplied signals in response to the control signal from the comparator unit 60 .

As also shown in FIG. 4, the satellite broadcast receiving system according to the invention further comprises: a first amplifier circuit 80 for amplifying the gain control signal from the rectifier 10 b at a predetermined gain, a first analog / digital (A / D) converter 90 for Converting the output signal from the first amplifier circuit 80 into a digital signal and for outputting the digital signal to the comparator unit 60 , a second amplifier circuit 100 for amplifying the output signal from the circuit 30 for detecting a noise level at a predetermined gain and a second A / D converter 110 for converting the output signal from the second amplifier circuit 100 into a digital signal and for outputting the digital signal to the comparison unit 60 .

Although not shown in detail in FIGS. 1 and 4, the comparator unit 60 has a microcomputer. In the microcomputer, the reference gain control signal with respect to the gain control signal from the signal converter circuit 10 and the reference noise level with respect to the noise level are pre-stored by the circuit 30 for detecting a noise level and are compared in each case on the basis of the preset system program. According to the comparison results, the microcomputer outputs a control signal, whereby either processing in which the noise is removed from the image signal or normal processing of the image signal is carried out, as will be described in detail later with reference to FIG. 9.

The filter 30 a in the circuit 30 for detecting a noise level is, as mentioned above, a bandpass filter BPF, which detects the noise component of a frequency band with an upper limit which is approximately 1-2 MHz higher than that of the original baseband of the received satellite broadcast signal. The upper limit of the baseband is, for example, 8 MHz for a high picture or 6.5 MHz for a normal picture. In this case, the filter 30 a has an upper limit of 9-10 MHz.

The operation of the satellite broadcast receiving system according to the invention with the above-mentioned structure will be described in detail with reference to FIG. 4.

The received via a parabolic antenna (not shown) satellite broadcast signal is first in a down converter (not shown), which typically reduces the frequency, converted into the first intermediate frequency signal from 1,035 to 1,336 GHz. In the signal converter circuit 10 , the first intermediate frequency signal output by the down converter in the tuner 10 a is converted into the second intermediate frequency signal of 402.78 MHz. The circuit 10 c for automatic gain control automatically controls the gain of the second intermediate frequency signal from the tuner 10 a in response to the gain control signal from the rectifier 10 b. The gain-controlled second inter mediate frequency signal from the circuit 10 c for automatic gain control is amplified in the amplifier 10 d at a pre-given gain and then supplied to the de modulator 20 . On the other hand, the output signal is rectified b from the demodulator 20 through the rectifier 10, which outputs the rectified signal as said control signal Verstär kung c to the circuit 10 for automatic gain control.

The demodulator 20 demodulates the output signal from the amplifier 10 d in the signal converter circuit 10 in the Fre-frequency signal of 27 MHz, which corresponds to the original base band of the received satellite broadcasting signal.

In the circuit 30 for detecting a noise level of the filter 30 filters a, the output signal from the demodulator 20 to derive determine the desired, corresponding to the noise frequency band of the signal, the amplifier 30 b, the output a amplified at a predetermined gain by the filter 30th The peak value detector 30 c determines the envelope value corresponding to the peak value of the output signal from the amplifier 30 b. The envelope curve is a direct current (DC) component representing the noise level. That is, the carrier-to-noise (C / N) ratio is small when the envelope value is large and large when the envelope value is small.

In the circuit 40 for detecting a signal, the sound signal detector 40 a detects only the sound signal from the output signal of the demodulator 20 and the image signal detector 40 b only the image signal from the output signal of the demodulator 20 . The sound signal processing circuit 50 processes the detected sound signal from the sound signal detector 40 a in the circuit 40 for detecting a signal to make the sound signal audible. The detected image signal from the image signal detector 40 b in the circuit 40 for detecting a signal is supplied to the image signal processing circuit 70 .

On the other hand, the gain control signal from the rectifier 10 b in the signal converter circuit 10 and the first amplifier circuit 80 supplied to the ciency amplifies the supplied gain control signal at a predetermined Verstär and outputs the amplified signal to the first A / D converter 90th As a result, the digitally converted gain control signal from the first A / D converter 90 is received by the comparator unit 60 .

The noise level from the circuit 30 for detecting a noise level is amplified in the second amplifier circuit 100 at a predetermined amplification level and then converted into a digital signal in the second A / D converter 110 . As a result, the digitally converted noise level is received by the second A / D converter 110 through the comparator unit 60 .

The satellite broadcast receiving system can also operate in an analog fashion, with the gain control signal and the noise level being fed directly to the comparator unit 60 without being converted into digital signals. In order to compensate for the loss of quality of the image quality even with subtle changes in the gain control signal and the noise level, the present invention provides a digitally operating satellite broadcasting reception system.

Fig. 5 shows a flow chart for explaining the inventive operation of the comparator unit 60th As shown, the comparator circuit 60 (e.g., a microcomputer) first compares the applied gain control signal with the predetermined reference gain control signal. Then, when the supplied gain control signal is higher than the predetermined reference gain control signal due to the comparison, the comparator unit 60 compares the supplied noise level with the predetermined reference noise level. If, due to the comparison, the supplied noise level is higher than the predetermined reference noise level, the comparator unit 60 determines that the image signal contains a high noise component, and then outputs a first logic level signal (for example a signal with a high level) as the control signal. to remove the noise from the image signal. In contrast, when the supplied noise level is less than or equal to the predetermined reference noise level, the comparator unit 60 determines that the picture quality of the received satellite broadcast signal is good, and then outputs a second logic level signal (e.g., a low level signal) as a control signal ) to process the image signal normally. On the other hand, when the gain control signal to be supplied is not higher than the predetermined reference gain control signal, the comparator unit 60 outputs the first logic level signal (e.g., a high level signal) as a control signal to remove the noise from the image signal regardless of the noise level.

According to FIG. 4, the first amplifier 70 amplifies a signal in the image processing circuit 70 the detected image signal by the circuit 40 for detecting a signal at a predetermined amplification degree. In order to compensate for the amplification of the received satellite broadcast radio signal reduced due to bad weather, such as during precipitation, the output signal from the most amplifier 70 a is amplified again in the second amplifier 70 b. The filter 70 filters the output signal c from the second amplifier 70 b to the corresponding to the noise high frequency band of the signal to remove therefrom. For such a filter function, the filter 70 c can be a band pass filter BPF, the upper limit of which is lower than that of the original baseband of the received satellite broadcasting signal. Then, in response to the control signal from the comparator unit 60 , the switch 70 d outputs either the output signal from the amplifier 70 a or from the filter 70 c as the final image signal.

That is, when the control signal of the first logic level is received from the comparator unit 60 , that is, when the reception sensitivity or the C / N ratio of the received satellite broadcast signal is poor, the switch 70 d outputs the output signal from the filter 70 c at its on gangsanschluß b as a final image signal. In contrast, the switch 70 d when receiving the control signal of the second logic level, which indicates that the reception sensitivity and the C / N ratio of the received satellite broadcast signal are good, the output signal from the amplifier 70 a at its input terminal a as a final Image signal off.

Fig. 6 shows the manifestations of a carrier and the noise contained in a satellite broadcast signal received through the parabolic antenna. In this figure, reference numeral A denotes a main carrier of 402.78 MHz, B a DC level of noise in the case of a bad C / N ratio and C a DC level of noise in the case of a good C / N ratio. Referring to FIG. 6 is a great difference between the DC levels in good or in bad C / N ratio.

Fig. 7 shows a detailed block diagram of an alternative embodiment of the satellite broadcast receiving system of Fig. 1 according to the present invention . The structure in Fig. 7 is substantially the same as that in Fig. 4, except that the image signal processing circuit 70 is constructed differently from that in FIG. 4. Therefore, only the structure and operation of the image signal processing circuit 70 in the system of FIG. 7 will be described below, with the description of the structure and operation of the other components being omitted.

In Fig. 7, the image signal processing circuit 70 includes: a luminance / chrominance (Y / C) separator 70 e for separating the luminance and chrominance signals Y and C from the image signal from the circuit 40 for detecting a Si gnals, a luminance signal processor 70 f for processing the separated luminance signal Y from the Y / C separator 70 e to make the signal representable, a chrominance signal processor 70 g for processing the separate chominance signal C from the Y / C separator 70 e to make the signal representable , a filter circuit 70 h for filtering the output signal from the luminance signal processor 70 f in response to the control signal from the comparator circuit 60 to remove the high frequency band of the signal corresponding to the black noise therefrom, and an adder 70 i for adding the output signal from the filter circuit 70 h and the chrominance signal processor 70 g and for outputting the added signal as the final image signal.

Fig. 8 shows a detailed block diagram of the filter circuit 70 h of the image signal processing circuit 70 in the system of Fig. 7. As shown, the filter circuit 70 h comprises: a first band pass filter 70 h1 for filtering the output signal from the luminance signal processor 70 f to pass the frequency signal corresponding to the original baseband of the received satellite broadcast signal, a second bandpass filter 70 h2 for filtering the output signal from the luminance signal processor 70 f in order to remove therefrom the high frequency band of the signal corresponding to the black noise and thereby only to pass one signal of a frequency band with an upper limit value, which is lower than that of the original baseband of the received satellite broadcast signal, and a switch 70 h3 for selectively outputting the output signal from the first or second band pass filter 70 h1 or 70 h2 in response to the control signal from the comparator unit 60 .

In operation, the switch 70 h3 on receipt of the control signal of the first logic level from the comparator unit 60 outputs the output signal from the second bandpass filter 70 h2 as a final luminance signal, in which the high-frequency band of the signal corresponding to the black noise has been removed. In contrast to this, when the control signal of the second logic level is received by the comparator unit 60 as the final luminance signal, the switch 70 h3 outputs the output signal from the first bandpass filter 70 h1 or the frequency signal corresponding to the original baseband of the received satellite broadcasting signal.

Fig. 9 shows a circuit diagram of the luminance signal processor 70 f and the filter circuit 70 h of the image signal processing circuit 70 in the system of FIG. 7. As is known, the first and the second bandpass filter 70 h1 and 70 h2 coils L1 and L2 or Capacitors C2 and C3. The luminance signal processor 70 f also has a DC voltage source Vcc, a capacitor C1 to which the luminance signal Y is supplied from the Y / C separator 70 e, a first and a second resistor R1 and R2, which are connected between the DC voltage source Vcc and the earth in Series connected and connected to an output of the capacitor C1, an NPN transistor Q1, the collector of which is connected to the DC voltage source Vcc, the emitter of which is connected to earth and the base of which is connected to the common connection point of the first and second resistors R1 and R2 , and a third resistor R3, which is connected between the emitter of the NPN transistor Q1 and the ground.

A difference between the image signal processing circuits 70 in FIG. 4 and FIG. 7 will be described below.

When the reception sensitivity or the C / N ratio of the received satellite broadcast signal is poor due to bad weather such as precipitation, the image signal processing circuit 70 in Fig. 4 amplifies the image signal based on the carrier center frequency by the decreased Increase reception sensitivity, and then removes the noise from the amplified image signal to improve the quality of the image signal. That is, the image signal processing circuit 70 in Fig. 4 processes the luminance and chrominance signals Y and C at the same time, which gives rise to the following problem. When the C / N ratio of the received satellite broadcast signal is poor, the black noise is generally located on the high frequency band of the received satellite broadcast signal. The black noise only leads to a loss in quality of the luminance signal Y. Therefore, when the luminance and chrominance signals Y and C are processed simultaneously, an image signal with poor color results because the chrominance signal C of the high-frequency band is unnecessarily removed. The improved image signal processing circuit in Fig. 7 over the image signal processing circuit 70 in Fig. 4 separates the luminance and chrominance signals Y and C from the image signal when the reception sensitivity and the C / N ratio of the received satellite broadcast signal are poor and then removes only the high frequency band of the signal corresponding to the black noise from the separated luminance signal. Therefore, according to the image signal processing circuit 70 in FIG. 7, a pure color image signal can be obtained with the black noise removed without a color defect.

As described above, the present Er Find the following benefits:  

First, the conditions of reception become sensitive speed and the image quality of the received satellite broadcast signal based on the gain control signals and the noise level, which correspond to the corresponding according to the original baseband of the received Satellite broadcast signal demodulated frequency signal will hold. In bad conditions, the min The reception sensitivity increases and the noise ent distant. Therefore, from the satellite broadcast received signal good image quality regardless of the weather be preserved.

Second, the gain control signal and the Noise level converted into digital signals, which subsequently with a reference gain control signal or with ei be compared to the reference noise level. According to ver the control signal is generated, which the Processing of the image signal. Hence the picture signal even with subtle changes in the gain Control signal and the noise level can be compensated.

Third, the conditions of reception sensitivity and the image quality of the received Satellite broadcast signal based on both the ampl control signal, as well as the noise level checked. This enables a precise compensation of the image signal light.

Claims (18)

1. Satellite broadcast reception system with
a signal converter device ( 10 ) which receives a gain control signal for converting a first intermediate frequency signal supplied to the circuit into a second intermediate frequency signal whose band is lower than that of the first intermediate frequency signal, and for automatically controlling the gain of the second intermediate frequency signal in response to that Gain control signal;
demodulating means ( 20 ) for demodulating the second intermediate frequency signal from the signal converting means ( 10 ) into a frequency signal corresponding to the original baseband of a received satellite broadcast signal;
wherein the signal converter means ( 10 ) receives the gain control signal from an output signal of the demodulation means ( 20 );
means ( 30 ) for detecting a noise level from the output of said demodulation means ( 20 );
means ( 40 ) for detecting a signal to detect an image signal and a sound signal from the output signal of the demodulation means ( 20 );
sound signal processing means ( 50 ) for processing the detected sound signal from the means ( 40 ) for detecting a signal to make the signal audible;
a comparator means ( 60 ) for comparing the gain control signal from the signal converter means ( 10 ) with a predetermined reference gain control signal or for comparing the determined noise level from the means ( 30 ) for detecting a noise level with a predetermined reference noise level and for generating one Control signals to process the detected image signal from the device ( 40 ) for detecting a signal according to the comparison results; and
image signal processing means ( 70 ) for equalizing the image signal from the means ( 40 ) for detecting a signal or for normally processing the image signal in response to the control signal from the comparator means ( 60 ) and then processing the image signal to obtain the signal to make representable. 2. Satellite broadcast receiving system according to claim 1, where the signal converter device ( 10 ) comprises:
a tuner ( 10 a) for converting the first intermediate frequency signal fed to the tuner into the second intermediate frequency signal, the band of which is lower than that of the first intermediate frequency signal;
a circuit ( 10 c) for automatically controlling the gain of the second intermediate frequency signal from the tuner ( 10 a) in response to the gain control signal;
an amplifier ( 10 d) for amplifying the output signal from the circuit ( 10 c) for automatic gain control at a predetermined gain; and
a rectifier ( 10 b) for rectifying the output signal from the demodulation device ( 20 ) and for outputting the rectified signal as the gain control signal to the circuit ( 10 c) for automatic gain control. 3. Satellite broadcast receiving system according to claim 2 with:
a first amplifier circuit ( 80 ) for amplifying the gain control signal from the rectifier ( 10 c) at a predetermined gain; and
a first analog / digital (A / D) converter ( 90 ) for converting the output signal from the first amplifier circuit ( 80 ) into a digital signal and for outputting the digital signal to the comparator device ( 60 ). 4. The satellite broadcast receiving system according to claim 1, 2, or 3, wherein the means ( 30 ) for detecting a noise level comprises:
a filter ( 30 a) for filtering the output signal from the demodulation device ( 20 ) in order to determine therefrom a desired frequency band of a signal corresponding to the noise;
an amplifier ( 30 b) for amplifying the output signal from the filter ( 30 a) at a predetermined gain; and
a peak value detector ( 30 c) for determining an envelope curve corresponding to the peak value of the output signal from the amplifier ( 30 b). To obtain 5. satellite broadcast receiving system according to claim 4, where in the peak detector (30 c) an integrator for integrating the output signal from the amplifier comprises the envelope curve of the noise level depicting lumbar DC level. 6. Satellite broadcast receiving system according to claim 4 or 5, wherein the filter ( 30 a) is a bandpass filter. 7. A satellite broadcast receiving system according to claim 6, where where the bandpass filter has an upper limit, which is 1-2 MHz higher than that of the original baseband of the received satellite broadcasting gnals. 8. Satellite broadcast reception system according to one of claims 4 to 7, with:
a second amplifier circuit for amplifying the output signal from the peak value detector ( 30 c) at a predetermined degree of amplification; and
a second analog / digital converter for converting the output signal from the second amplifier circuit into a digital signal and for outputting the digital signal to the comparator device. 9. Satellite broadcast receiving system according to one of claims 1 to 8, wherein the image signal processing device ( 70 ) comprises:
a first amplifier for amplifying the detected image signal from the means for detecting a signal at a predetermined degree of amplification;
a second amplifier for amplifying the output signal from the first amplifier at a predetermined gain;
a filter for filtering the output signal from the second amplifier to remove a high frequency band of the signal corresponding to the black noise therefrom; and
a switch to which the output signals from the first amplifier and the filter are fed and which outputs one of the supplied signals in response to the control signal from the comparator device. 10. A satellite broadcast receiving system according to claim 9, where the filter has a bandpass filter with an upper one Limit is less than that of the original baseband of the received satellite broadcasting gnals is. 11. Satellite broadcast receiving system according to one of claims 1 to 10, wherein the image signal processing device comprises:
a luminance / chrominance separator for separating the luminance and chrominance signals from the image signal from the means for detecting a signal;
a luminance signal processor for processing the separated luminance signal from the luminance / chrominance separator to make the signal representable;
a chrominance signal processor for processing the separated chrominance signal from the luminance / chrominance separator to make the signal representable;
a filter circuit for filtering the output signal from the luminance signal processor in response to the control signal from the comparator means to remove a high frequency band of the signal corresponding to the black noise from the output signal; and
an adder for adding the output signals from the filter circuit and the chrominance signal processor and for outputting the added signal as a final image signal. 12. The satellite broadcast receiving system according to claim 11, wherein the filter circuit comprises:
a first bandpass filter for filtering the output signal from the luminance signal processor to allow the frequency signal corresponding to the original baseband of the received satellite broadcast signal;
a second bandpass filter for filtering the output signal from the luminance signal processor in order to remove the high-frequency band of the signal corresponding to the black noise from the output signal and only to pass a signal of a frequency band with an upper limit value which is lower than that of the original baseband of the received Sa. tellite broadcast signal; and
a switch for selectively outputting the output signal from the first or second bandpass filter in response to the control signal from the comparator unit. 13. A satellite broadcast receiving system according to claim 12, where with the first and the second bandpass filter each have a capacitor and a coil. 14. The satellite broadcast receiving system according to claim 11, 12 or 13, wherein the luminance signal processor comprises:
a DC voltage source;
a capacitor to which the luminance signal is supplied from the luminescence / chrominance separator;
a first and a second resistor connected in series between the DC voltage source and the earth and connected in common to an output of the capacitor;
an NPN transistor whose collector is connected to the DC voltage source, whose emitter is connected to earth and whose base is connected to the common connection point of the first and second resistors; and
a third resistor connected between the emitter of the NPN transistor and the ground. 15. Satellite broadcast receiving system according to one of claims 1 to 14, wherein the device for detecting a signal comprises:
a sound signal detector for detecting only the sound signal from the output signal of the Demodulationseinrich device; and
an image signal detector for detecting only the image signal from the output signal of the Demodulationsein direction. 16. A satellite broadcast receiving system according to claim 15, where at the tone signal detector a bandpass filter and the Image signal detector has a low-pass filter. 17. Satellite broadcast receiving system according to one of the An claims 1 to 16, the demodulation device has a bandpass filter.   18. Satellite broadcast receiving system according to one of the An Proverbs 1 to 17, the comparator Control signal of a first logic level for compensation Chen of the image signal outputs when the supplied Gain control signal is lower than that before given reference gain control signal, or when the supplied noise level is higher than that before given noise level, even though the ampl control signal is higher than the predetermined Re reference gain control signal, and the control signal signal of a second logic level for normal Processing of the image signal outputs when the led gain control signal is higher than that predetermined reference gain control signal and when the supplied noise level is lower than that predetermined reference noise level.