JPS6214977B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a mode switching control device for an AM stereo receiver, and in particular is capable of detecting the presence or absence of a pilot signal, which is a stereo identification signal, quickly and reliably.

In the Magnabox AM stereo system, AM modulation is performed using the sum signal L+R of the left signal L and right signal R.
It is a stereo system in which PM modulation is performed using a difference signal L-R, and an FM modulated signal with a deviation of 15 to 18 Hz at 5 Hz is used as a pilot signal for identifying stereo broadcasts. Therefore, it is necessary to extract and separate this pilot signal for stereo display and reception mode switching.

Figure 1 shows an example of a circuit for automatically switching the stereo display and reception mode.The intermediate frequency signal obtained at terminal 1 is supplied to AM detection circuit 2, and the sum signal L+R is detected. At the same time, the difference signal L-R and pilot signal P are supplied to the PM detection circuit 3 and detected, and these are sent to the high-pass filter 4.
is supplied to the matrix circuit 5 to obtain only the difference signal L-R, which is further supplied to the matrix circuit 5 and separated into left and right signals L and R.

Reference numeral 10 denotes a mode switching control device, in which the pilot signal P is separated by a band pass filter or low pass filter 11, and then supplied to a detection circuit 12 where the pilot signal P is detected.This detection output is sent to an integrator circuit and a level comparison circuit. The mode switching pulse S _M is supplied to the mode discrimination circuit 13 consisting of
is formed, and the matrix circuit 5 is controlled by this. That is, when the pilot signal P is not detected, the difference signal _L is
-R signal path is cut off.

This mode switching pulse S _M is then supplied to the stereo display circuit 15 to display the AM stereo broadcast.

In this conventional mode switching control device 10, the presence or absence of the pilot signal P is determined based on its level, so it has the following drawbacks.

That is, unlike the pilot signal (19KHz) used for FM stereo broadcasting, the pilot signal P for AM stereo broadcasting has an extremely low frequency, so the rising edge and rising edge of the integrating operation of the integrating circuit provided in the mode discrimination circuit 13 Both descents will be very slow. Even if the rise of the integrating circuit is slow, the problem shown on the left does not occur. However, if the fall is slow, the stereo mode will remain for a short period of time even though AM stereo broadcasting has been switched to monaural broadcasting, so the signal system of the difference signal L-R will remain in the stereo mode. noise is generated and is extremely harsh.

Regardless of the level discrimination method, for example, a method may be considered in which the peak level of the pilot signal P is detected and the mode is switched, but this method cannot accurately discriminate between noise and the pilot signal and often malfunctions. If the pilot signal itself is used, the repetition period is very long at 200 msec, so the mode is switched every half cycle of 100 msec, and the stereo display also flashes at the same time, making it impractical.

Therefore, the present invention proposes a mode switching control device that can eliminate the above-mentioned drawbacks by making it possible to detect the presence or absence of a pilot signal reliably in a short period of time. An example of this invention will be explained in detail with reference to FIG.

Band pass filter or low pass filter 11
The pilot signal P separated by is supplied to the limiter amplifier 12 and converted into a rectangular wave as shown in FIG.
After adjusting the level appropriately at B, counter 21
is supplied to the first control pulse S _P1 (Figure 3B)
is formed. In this example, the first control pulse S _P1 is output at the rising edge of the fourth cycle after the pilot signal P is input. The reason why the counter output is obtained in the fourth cycle is to avoid malfunctions caused by noise, etc. However, if the number of detection cycles is too long, it will take time to switch from monaural to stereo. Undesirable. Therefore, the number of detection cycles is 3~
About 5 cycles is good.

Mode switching pulse S _M with the first control pulse S _P1
formation circuit 22 is controlled. In this example, a JK flip-flop circuit is used, and the first control pulse S _P1 is used as the clock pulse. The set terminal S is grounded, the J terminal is fixed at high level H, and the K terminal is fixed at low level L. Therefore, when the first control pulse S _P1 is input, the mode switching pulse S _M (FIG. 3C) is obtained.

The waveform-shaped pilot signal P is further
is supplied to the control pulse forming circuit 30 of. This forming circuit 30 is composed of an inverter 31, a reverse current blocking diode 32 provided on the input side thereof, and a time constant circuit 33.
A parallel circuit of 3A and resistor 33B is connected in parallel to the signal path. Its time constant is the inverter 31
threshold level L and pilot signal P
It is selected to be about 0.5 seconds in relation to the period of .

If the time constant is selected in this way, the cathode side of the diode 32 is at a high level while the pilot signal P is obtained, and from the time the pilot signal P disappears, that level becomes the threshold level L of the inverter 31. (approximately 1/2 of the peak level of the pilot signal P, see Figure 3D) T _b
(1.0Ta<Tb<1.5Ta), the inverter 3
1 and thus the second control pulse S _P2 is inverted.

As a result of this second control pulse S _P2 resetting the counter 21 and flip-flop circuit 22, the mode switching pulse S _M is also inverted and the mode is switched from stereo to monaural. The stereo display also disappears.

Note that the stereo display circuit 14 includes a light emitting diode 16 and a switching transistor 17 as shown in the figure.
It is of the type controlled by

As explained above, according to the present invention, the level of the pilot signal P is not determined to discriminate between monaural and stereo, but the pilot signal P is counted and the discrimination is made. - Stereo identification can be performed reliably. Moreover, as in this embodiment, since the mode switching pulse S _M is configured to be obtained several cycles after the pilot signal P is input, it is resistant to noise and can be used even if the pilot signal P has an extremely low frequency. It has the feature of shortening the detection time. Conventionally, discrimination has been made based on the level after a period of at least several cycles has elapsed, which has the disadvantage of requiring a long detection time.

Further, in the present invention, since the flip-flop circuit 22 is controlled by the second control pulse _SP2 , the mode can be quickly switched from stereo to monaural, and the generation of burst noise can be eliminated. This is because the time constant circuit 33 determines whether the signal is a periodic signal or not, including a certain period Tb. Therefore, in the case of the embodiment, switching to monaural is performed approximately 250 msec after the pilot signal P disappears.
Conventionally, switching required approximately 1 to 2 seconds.

[Brief explanation of the drawing]

Figure 1 is a system diagram of a conventional mode switching control device.
FIG. 2 is a system diagram of essential parts showing an example of a mode switching control device according to the present invention, and FIG. 3 is a waveform diagram for explaining its operation. 11 is a band pass filter (low pass filter), 12 is a limiter, 21 is a counter, 22 is a mode switching pulse forming circuit, 30 is a generating circuit for the second control pulse S _P2 , S _P1 is the first control pulse, S _M is a mode switching pulse.

Claims (1)

[Claims] 1 Extract and separate an ultra-low frequency pilot signal from the AM stereo signal, and supply this separated pilot signal to a counter to obtain a first control pulse after counting a predetermined number of pulses. A stereo-monaural mode switching pulse forming circuit is controlled to form a mode switching pulse, and the pilot signal is supplied to a second control pulse generating circuit to generate a second control pulse in response to the termination of the pilot signal. form a control pulse of
A mode switching control device for an AM stereo receiver, wherein the second control pulse controls the mode switching pulse forming circuit.