JPH0134407B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention solves the problem of cross-modulation and
This paper relates to an automatic gain control method for reducing RF intermodulation interference, etc.

In a conventional AGC circuit, for example, as shown in Figure 1, the output of the IF amplification stage is amplified and detected by an AGC amplifier, and only the DC component corresponding to the electric field strength is fed back to the front end as an AGC control signal.

However, in this type of AGC circuit, as shown in Figure 2, the tuning bandwidth of the front end (the bandwidth surrounded by curve A, which is usually several M
Hz), even if there is a strong adjacent interference wave B, due to the tuning characteristics of the IF amplification stage,
If the bandwidth of the IF amplification stage is outside the bandwidth of the IF amplification stage (the bandwidth surrounded by curve B, which is usually several 100 KHz), no AGC control signal will be generated due to the proximity interference wave B.
Therefore, without front-end gain adjustment, excessive input of nearby interference wave B may cause cross-modulation or
It has the drawback of generating distortion due to RF intermodulation interference, etc., and significantly reducing reception quality.

For this reason, some devices extract the AGC control signal via the output side of the front end.
The tuning bandwidth of the front end is several MHz as mentioned above.
Since the AGC control signal is also generated by the proximity interference wave B, especially if the electric field strength of the proximity interference wave B is stronger than that of the target wave A, the AGC control signal generated by the proximity interference wave B is There is a problem in that so-called sensitivity blocking occurs in which the amplification degree of the front end is extremely suppressed by the signal, and the apparent electric field strength of the desired target wave A decreases, making it impossible to receive high-quality reception.

Although this invention extracts the AGC control signal via the output side of the front end, if the adjacent interference wave exists within the tuning bandwidth of the front end, the amplitude is modulated by the adjacent interference wave. Focusing on the fact that an envelope signal generated on the output side of the front end, we detected the envelope signal to extract the low frequency signal component, amplified and detected this low frequency signal component, and amplified and detected the output of the front end. This is superimposed on the signal, and the amplification level of the front end can be controlled according to the level of interference caused by nearby interference waves, so even if there is an excessive input of nearby interference waves, there will be no cross modulation or RF intermodulation interference. There is no risk of causing
An object of the present invention is to provide an automatic gain control method that is free from the risk of sensitivity blocking caused by AGC effects due to strong adjacent interference waves.

Hereinafter, the method of the present invention will be explained based on embodiments shown in the drawings.

In Figure 3, 1 is the front end and 2 is the front end.
In the IF amplification stage, 3 is an FM detection section.

Also, a part of the high frequency signal output from the front end 1 is supplied to the AGC amplifier 4.
After being amplified and detected by the AGC amplifier 4, the DC component corresponding to the electric field strength is fed back to the front end 1 via a superimposition circuit 5, which will be described later.

Furthermore, if the input signal is an envelope signal, the AGC amplifier 4 detects it and extracts only its low frequency signal component. This low frequency signal is supplied to an AC amplifier 6, and after being further amplified and detected by this AC amplifier 6, it is input to a superimposition circuit 5,
It is superimposed on the amplified and detected high frequency signal output from the AGC amplifier 4 and fed back to the front end 1.

Incidentally, both the AGC control signal output from the AGC amplifier 4 and the signal output from the AC amplifier 6 are transmitted through a time constant circuit (not shown) provided in each of the amplifiers 4 and 6, such as a CR or the like. After being converted into an averaged DC component, each signal is supplied to a superimposing circuit 5, and the superimposing circuit 5 combines the two signals as a DC sum to form a superimposed signal. This superimposed signal is then fed back to the front end 1 as an AGC control signal. Therefore, if the signal extracted from the front end 1 is not an envelope signal, the output of the AGC amplifier is directly fed back to the front end 1 as an AGC signal.

Next, the envelope signal from which the low frequency signal component is extracted in the AGC amplifier 4 will be explained. Now, as shown in Fig. 2, when the target wave A of FM broadcast is being received, if a nearby interference wave B of FM broadcast also exists within the tuning bandwidth of front end 1,
Front end 1 is on the output side of front end 1.
A spectrum surrounded by the tuning characteristic curve A is output.

Here, the target wave A is tuned to the center of the tuning bandwidth of the front end 1, so even if the frequency shifts due to modulation, the output side of the front end 1 has a signal as shown in Figure 4a. A high frequency signal having a constant amplitude should be output. However, the spectrum of the near-field interference wave B is close to the slope part of the tuning characteristic curve A of the front end 1, and the frequency is shifted by the modulation of this near-field interference wave B, and the spectrum crosses the slope part of the curve. In order to enter the tuning band of B, the high frequency signal output from the front end 1 is subjected to amplitude modulation by the frequency shift of the adjacent interference wave B, that is, it is slope detected in the above slope section, and as shown in Fig. 4b. An envelope signal as shown is output.

That is, the present invention extracts a part of the high frequency signal output from the front end 1, and extracts a part of the high frequency signal output from the front end 1, and extracts it from the above-mentioned envelope signal output from the front end 1 when it is interfered with by the nearby interference wave B. Detection is performed to extract only the low frequency signal component, and this low frequency signal component is further amplified and detected by an AC amplifier 6 etc. and converted to a DC component. , is amplified and detected by the AGC amplifier 4 and superimposed on the high frequency signal converted into a DC component, and this superimposed signal is fed back to the front end 1 as an AGC control signal.

Therefore, according to this method, even if a strong adjacent interference wave B exists in the same band of the front end 1, the low frequency signal component ( Figure 4c
) is extracted and amplified and detected to generate the normal AGC control signal (in this example, AGC amplifier 4).
Since the amplification degree of the front end 1 is reliably suppressed by the proximity interference wave B, the conventional AGC control signal is
Unlike the AGC circuit that takes out the output from the output side of the IF amplification stage, there is no possibility that the AGC effect due to the nearby interference wave B will not work and cause cross-modulation or RF intermodulation interference in the front end 1, and the above-mentioned interference can be avoided. The resulting distortion can be significantly reduced.

Moreover, the closer the proximity interference wave B approaches the target wave A, and the higher the signal level of the proximity interference wave B, the greater the pulsation rate of the envelope signal, and the greater the low-frequency signal component extracted from this envelope signal. Therefore, the AGC control signal fed back to the front end 1 becomes larger, and a deeper AGC effect comes into play. In other words, since the amplification degree of the front end 1 is controlled according to the level of interference caused by the nearby interference wave B, a more effective AGC effect can be expected within a range that does not interfere with the reception of the target wave A.

In addition, the voltage level of the AGC control signal output from the AGC amplifier 4 is set to a value slightly lower than that in the conventional AGC circuit, so that the output signal of the AGC amplifier 4 is
If the AGC effect is set so that when the voltage output through the AC amplifier 6 is superimposed and fed back to the front end 1, the reception quality of the target wave A is not impaired, the proximity interference wave B can be set. There is no risk of sensitivity blocking occurring due to

It should be noted that the present invention is not limited to the embodiments described above and can be modified as appropriate. Any means may be used to superimpose the signal amplified via the AC amplifier 6 or the like on the output signal of the amplifier 4.

[Brief explanation of drawings]

Figure 1 is a block diagram of a conventional AGC circuit, Figure 2 is a block diagram of a conventional AGC circuit.
The figure is a graph showing the bandwidth of the front-end and IF amplification stages and the spectra of the target wave and adjacent interference waves. Figure 3 is a block diagram showing one embodiment of the present invention. Figure 4a shows the existence of adjacent interference waves. Figure 4b is a waveform diagram of the envelope signal amplitude-modulated by the proximity interference wave, and Figure 4c is a waveform diagram of the low-frequency signal component extracted from the envelope signal. It is. 1...Front end, 2...IF amplification stage, 3
...FM detection section, 4...AGC amplifier, 5...superposition circuit, 6...AC amplifier.

Claims (1)

[Claims] 1. Extracting a part of the high frequency signal output from the front end, amplifying and detecting this extracted high frequency signal and converting it into a DC component, and detecting an envelope signal generated by a nearby interference wave from the extracted high frequency signal. The low-frequency signal component is extracted, and the low-frequency signal component that has been amplified and detected and converted to a DC component is superimposed on the high-frequency signal that has been converted to a DC component, and this superimposed signal is
An automatic gain control method characterized in that the AGC control signal is fed back to the front end.