DE3123426A1 - "MUTE FOR TELEVISION RECEIVER" - Google Patents

Description

Dipl.-Ing. Dipl.-Chem. O * Dipl.-Ing.

E. Prince - Dr. G. Hauser - G. Leiser

Ernsbergerstrasse 19

8 Munich 60

THOMSON-BRANDT June 12, 1981

173 / Bl. Haussmann

75008 Paris / France
Our reference: T 3431

Mute for television receivers

The invention relates to a muting arrangement for television receivers, which makes it possible to automatically suppress the sound on a television receiver when there is no television broadcast receives.

It is not desirable that audio signals other than those from television broadcasts can be received via the audio component of a television receiver. Furthermore, certain legislations, in particular German legislation, prescribe the existence of an arrangement for muting the television receiver when it is not receiving a television broadcast _f .

Due to the manufacturing and calibration tolerances as well as due to the aging of circuits, it is not possible to produce tuning circuits for television receivers, their

r.

Passband within the limits of the transmission band of TV channels lies and remains.

Even if the sound of the TV channel is frequency modulated, and if it is demodulated according to the differential carrier principle, interference modulations are encountered which affect the television make it possible, under certain circumstances, to receive pure sound stations that are in frequency ranges other than the television range or also lie within this range, which is also due to unauthorized interference or unusual propagation conditions can happen.

It is already known the presence during the return line the synchronization pulses of the received video signal capture. If these pulses are not present, an arrangement switches the sound of the television to somebody Turn off the audio channel.

The line deflection circuit of a television receiver, however, operates with high energy and steep edges. So she sends Interfering signals, which are very difficult to suppress when receiving in the most sensitive stages of the television receiver. These levels are usually more sensitive than the level of the received signal is low due to the effect the automatic gain control. If there is no transmission at all, the sensitivity is at its maximum. The one from the Line deflection emitted interference signals can then by the radio frequency or intermediate frequency stages of the television receiver are received and as synchronization pulses of a Video signal can be interpreted. The muting arrangement is then disabled, and it can in this way Are received that should not be heard.

The object of the invention is to create a muting arrangement Juer television receiver that does not have this defect. The muting arrangement for

Television receiver contains a device for detecting the Line sync pulses in that received by the receiver Signal and means for blocking the audio channel when these pulses disappear, and it is according to the invention characterized in that it further comprises identification means which allow the Amplitude and width of the synchronization pulses as well their phase with respect to the signals from the line deflection circuit the television receiver to measure these pulses of interfering signals to distinguish which are supplied by the line deflection circuit.

Further advantages and disadvantages of the invention emerge from the following description of exemplary embodiments the drawing. In the drawing show:

1 shows a circuit for identifying the synchronization pulses;

Fig. 2 waveforms in the circuit of Fig. 1;

3 shows another embodiment of an identification circuit, which is provided with a control circuit; and

FIG. 4 is controlled by the circuit according to FIG. 3 Sound output level.

In the circuit shown in Fig. 1, the video signal VI with negative polarity to the base of an NPN transistor Tl applied, its emitter to ground and its collector to a positive supply voltage via a resistor R1 connected is. This level, which is common to all television receivers is used enables the separation of both the line and the frame synchronization signals. At the collector this

■ t.

From the transistor, a signal V1 is obtained, which is generated on the one hand by the line oscillator circuit and the image separation circuit is used and on the other hand is applied to an identification circuit that controls the audio channel serves. This signal V1 is shown in FIG. It takes the form of a train of negative impulses the duration of about 5 ys, which are separated by level steps that start at Have a steep edge at the beginning of the pulse and a slightly rounded edge at the end of the pulse.

In order to identify the line synchronization pulses, this signal is applied to a differentiating circuit which is formed from a capacitor C1 in series with a resistor R2 connected to ground. The signal V2 present at the connection between the capacitor C1 and the resistor R2 is formed from alternating negative and positive saw teeth, the leading edges of which correspond to the edges of the pulses of the signal V1. From Fig. 2 it can be seen that in the presence of actual pulses of width 5 ^- ys, the sawtooth corresponding to the leading edge of the pulse has essentially sufficient time to return to 0 before the beginning of the sawtooth corresponding to the trailing edge of the pulse. Under these conditions, the amplitude of the positive sawtooth is essentially equal to the amplitude of the negative sawtooth, since the DC voltage component of the signal V2 is necessarily zero. This amplitude of the positive sawtooth then has a value U1.

If the synchronization pulses are "pseudo pulses" acts that go back to the reception of interfering signals that are sent out by a deflection stage, so these pseudo pulses are much narrower than the normal line deflection pulses, because the interference signals that are in the Receiving stage get into it, essentially on very rapid transition phenomena decline, e.g. B. on the

circuit of diodes. If the time constant c of the differential network C1, R2 is taken into account, the negative sawtooth corresponding to the leading edge of this pseudo pulse does not have the time required to return to 0 before the positive sawtooth corresponding to the trailing edge of the pseudo pulse begins. This positive sawtooth is then significantly less high and only reaches level U2, which is significantly lower than the level of UI _0. By comparing the two levels, it is thus possible to distinguish between real pulses and pseudo pulses.

This level differentiation is further facilitated by that the level UO of the pseudo impulses is much lower than that of real impulses, despite the effect of the automatic ones Gain control, as a result of which the level U2 is reduced even further.

Since the width of the normal pulses is about 5 \ is , an optimal value of the time constant of the differentiating network is about 2 ys.

In order to be able to make a distinction depending on the value of the voltage V2, this voltage is applied to the base of an NPN transistor T2 is applied via a potentiometer voltage divider, which consists of two resistors connected in series to ground R3, R4 is formed. The emitter of transistor T2 is also connected to ground, while its collector to is connected to a positive source of supply. Otherwise the base of the transistor T2 does not receive any polarization, and there the signal V2 has no DC voltage component, the transistor is permanently blocked, if not that at its base applied signal exceeds its threshold voltage. The ratio of the values of the resistors R3 and R4 determines the Level of the signal V2 at which the transistor stops conduct. If for this level a value between 70 and 80%

of the level U1 is assumed, corresponding to an undisturbed Reception in which the automatic gain control works, whereby a relatively constant level U1 is established a good discrimination between real synchronization pulses and pseudo pulses is obtained.

In the embodiment shown in FIG. 3, the information is or the signal V1 is applied to a 100 picofarad capacitor C1. The potentiometer voltage divider also forms the integrating resistor and is made up of a resistor R3 of 18 kilo ohms in series with a resistor R4 of 3.9 kilo ohms formed, which is connected to ground. The transistor T2 is of the type 2400.

Furthermore, in order to achieve a sufficient gain for switching the audio channel blocking elements, a transistor T3 of type 2401, which is connected as a current amplifier.

The emitter of this PNP transistor is connected to its base via a resistor R6 of 22 kiloohms. The basis is also connected to the collector of transistor T2 through a resistor R5 of 10 kiloohms.

The collector of the transistor T3 is connected in series via two Resistors R8 and R9 with the value 18 kilo ohms and 12 kilo ohms respectively are connected to ground. These resistances are through bridged a capacitor C3 of 1 microfarad.

To control the emitter of the transistor T3, a positive 200-volt pulse is assumed, which is the Corresponds to the line return pulse and can be picked up directly at the collector of the line offset transformer. This impulse VL is applied to the emitter of transistor T3 through a resistor R12 of 47 kiloohms. The emitter is over one Resistor R7 of 4.7 kiloohms, which is replaced by a capacitor C2

-U.

is bridged by 1 nanofarad, decoupled from the ground potential.

Those from the resistors R12, R7 and from the capacitor C2 The circuit arrangement formed enables the pulse shaping of the line pulse VL in such a way that a more pointed vertex is obtained, the position of which corresponds to the point in time at which the transistor T2 becomes conductive.

The voltage fluctuations on the Collector of transistor T3 can be integrated in order to suppress fluctuations that are due to the regular blocking of the Transistor T2 by the synchronization pulses and can also be attributed to the fact that this voltage is two different Has values depending on whether a television broadcast is being received or not.

When a normal picture is received, transistor T2 saturates during the second half of the line pulse. Of the Transistor T3 is thus saturated at the point in time when the capacitor C2 has a maximum charge due to the pulse VL having. The transistor T3 then lets a charging current from the capacitor C2 to the capacitor C3 through »

When the transistor T2 conducts too early with respect to the signal VL because the pseudo pulse is narrower than a real one Line pulse, the charge on capacitor C2 is lower at the point in time when transistor T3 becomes conductive, so that the charge of the capacitor C3 or the voltage at its terminals is lower. Part of the charging current of the capacitor C3 also comes from the voltage divider R6, R7, which itself delivers a lower current when the transistor T2 is saturated too early.

So if the image is correctly synchronized, the span is

voltage at the connections of the capacitor C3 maximum.

As the level of the receiver's antenna signal decreases, the picture is disturbed and there is some Variation of the line oscillator with respect to the synchronization pulses available. This results in a significant reduction in the voltage at the terminals of the capacitor C3 causes.

The connection point between resistors R8 and R9 is connected to the base of a type 2400 NPN transistor T4, whose emitter is in turn connected to ground. Otherwise this base does not receive any polarization, so that the Transistor T4 is only conductive when the voltage divider R8, R9 applied voltage reaches a minimum value. By the ratio -between the resistors R8 and R9, the switching of the transistor T4 can be set so that it takes place in the event of an interference signal level of the image, " which is perceived as unacceptable.

The control of the triggering of the muting can therefore be triggered by one of the following three phenomena: Insufficient width of the synchronization pulse, insufficient Amplitude of the synchronization pulse, too high a phase deviation of the synchronization pulse with respect to the Line return pulse of the local time base.

Dor dos transistor T4 is from a voltage source with the positive voltage of 10 volts over a Resistor R11 fed by 4.7 kiloohms. The switching signal S of the audio channel is tapped at the collector of transistor T4 via a diode D1 of type IN914, whose anode is connected to this Collector is connected.

It should be emphasized that the saturation characteristic of the transistors T2 and T3 is used, which makes it possible will minimize the influence of the scatter of components used in this circuit.

This switching signal S can be used to block the audio channel at any point in the same, for example both on the modulators as well as on the output circuit or on the circuit for the remote control of the volume "

The embodiment shown in Fig. 4 corresponds to blocking by muting the audio signal output point.

In this embodiment, the sound channel comprises an integrated one Circuit of the type TBA 120S, used for demodulating the intermediate frequency amplifier signals is suitable and outputs a low level audio signal to a power circuit whose Circuit diagram is common and which controls a loudspeaker HP. The integrated circuit IC 'contains an isolated transistor, whose electrodes are connected to different connections of the integrated circuit. It is common to do this Use transistor to perform the functions of transistor T4. In this case the cathode of the diode is D2 connected to a suitable point in the power circuit, so that when the transistor T4 is saturated, the diode D2 is blocked is and. the amplifier works, while when the transistor T4 is blocked, the diode D2 is saturated and blocks the amplifier »

German / sch

Claims (7)

Dipl.-Ing. Dipl.-Chem. Dipl.-Ing. E. Prince - Dr. G. Hauser - G. Leiser Ernsbergerstrasse 19 8 Munich 60 THOMSON-BRANDT June 12, 1981 173, Bl. Haussmann 75 008 Paris / France
Our reference: T 3431 PATENT CLAIMS Muting arrangement for television receivers, with a device (T1, R1) for detecting the line synchronization pulses in the signal received from the television receiver, a device (T4, D1, R11) for blocking the audio channel when these pulses disappear, and with a device (T3, C2, R7, R12) to determine the phase position of the synchronization pulses with respect to the signals of the line deflection circuit of the television receiver s ,, characterized by an identification device (C1 , R3, R4, T1), which measures the amplitude and the width of the synchronization pulses and a Differentiation of these pulses from interference signals from the line deflection circuit 'enables. 2. Arrangement according to claim 1 _f, characterized in that the Identifikxerungsexnrxchtung comprises a differentiating circuit (C1, R3, R4) which receives the synchronization pulses and to a threshold circuit (T2) emits a signal that is made up of differentiated pairs of opposite pulses Polarity is formed in each pulse pair, with the height of the second pulse of each pulse pair depends on the width of the synchronization pulses, and that the threshold value circuit responds only to the second differentiated impulses, the height of which indicates that they originate from synchronization pulses. 3. Arrangement according to claim 2, characterized in that the threshold value circuit from the line return pulses the line deflection circuit is fed and further responds only to the second differentiated pulses which are in phase with these retrace pulses are. 4. Arrangement according to claim 3, characterized in that it further comprises a current amplifier stage (T3) which of the threshold value circuit is controlled and an integrating circuit (C3, R8, R9) is controlled so that a DC voltage signal is obtained for controlling the audio channel. 5. Arrangement according to claim 4, characterized in that it further includes means (C2, R7, R12) which the Amplifier stage supplied with power from the flyback pulses, so that the DC voltage control signal is maximum when the second differentiated pulses are in phase with the second half of the retrace pulse. 6. Arrangement according to one of claims 1-5, characterized in that that the blocking device (T4) of the audio channel enables the audio output amplifier to be blocked. 7. Arrangement according to claim 6, characterized in that the device for blocking the sound channel is an isolated one Transistor (T4) comprises, the component of an integrated demodulation and preamplification circuit of this audio channel is. German / sch