DE1815437A1 - Television receiver - Google Patents

Description

Television Receiver The invention relates to a television receiver and in particular an automatic electronic tuning device for television receivers.

Conventional television receivers use rotatable inductive channel selectors, The channel selection is done by using tunable coils and capacitors switches to the relevant channel signals by placing a dial finger in a predetermined one Location.

Recently, in the course of the development of variable capacities propose a method for selecting a desired channel after which the Voltage is changed on a semiconductor element of variable capacitance, the serves as a voting element.

According to the invention, a television receiver that has a channel selector with such variable capacitance elements in the tuning and oscillation resonance circuit (hereinafter referred to as semiconductor channel selector), be designed so that automatic tuning to the desired channel takes place, even if there is a vote on a specific channel, the vote can be changed to another channel, instantaneously and only by pressing a detuning push-button switch.

A first object of the invention is to provide tuning only on the video carrier wave without tuning to the audio carrier wave.

It is a second object of the invention to establish a linear relationship between Ensure throughput time and tuning frequency on a television receiver that achieved the first goal.

A third object of the invention is to achieve the first object Television receiver in which the channel selector is divided into a large number of frequency band sections which can be put into action in sequence. It is a special indicator is provided for displaying the respective bands.

According to the invention, the television receiver is also intended to be a device have, which results in a detuning in a simple manner as soon as the user of the TV set the detuning pushbutton switch is operated.

According to the invention, the television receiver which satisfies the first objective should further be designed so that when an incoming signal is weakened by Fading od. The like. A vote on this signal is avoided. Finally supposed to a television receiver which satisfies the first object of the invention can be designed in such a way that that even if the received signal is briefly interrupted, it can control the receiving channel by holding a tension g holding onto a charging capacitor.

Further details, advantages and features of the invention result from the following description. In the drawing the invention is for example illustrates, namely Fig. 1 shows the circuit of a television receiver according to the invention, Fig. 2 shows the circuit of the main portion of the circuit of Fig. 1; Fig. 3 shows the circuit a main portion of a second embodiment of the television receiver according to the invention, Figs. 4 to 8 are graphs for explaining the operating characteristics of the invention Television receiver, Fig. 9 shows the block diagram of a third embodiment of the invention Television receiver, Fig. 10 shows a tristable circuit for the television receiver according to the invention, Fig. 11 shows various waveforms for explaining the function of the embodiment of Fig. 9, Fig. 12 and Fig. 13 are circuits of main parts of television receivers, respectively a fourth and fifth embodiment of the invention, and FIGS. 14 and 15 show circuits of the main parts of television receivers correspond to sixth and seventh embodiments the invention.

Fig. 1 shows an embodiment of the invention in which the immediately related to the invention parts are shown transistorized, while the remaining conventional circuit sections not directly related to the invention as with Vacuum tubes are drawn provided. One recognizes one VHF semiconductor channel selector A with a pair of input terminals 1 and 2. The channel selector For example, A works on a Z-low 1 "band when it has power over a Terminal 3 and on a "high" band when it is energized via a terminal 4 is. A voltage is applied to a semiconductor extension 5 of variable capacitance a terminal 6 applied. One can also see an intermediate frequency amplifier X, a Video detector C, a video amplifier D and a sync separator F.

A generator circuit G for a voltage to be applied consists of C1, h1 and TR3. A monostable multivibrator H is used for short-term storage. the The output voltage of a control circuit J is a function of the intermediate frequency changeable A Schmitt circuit K is used to form a signal in the following designated signal that enables the determination of whether a carrier wave is on which the channel selector is about to vote on, the video carrier wave or is the audio carrier wave. in the embodiment of FIG. 1, the horizontal synchronizing pulse signal, which occurs as the output of the sync separator P is used as the S signal.

A bistable multivibrator L is used to switch the reception band and an ammeter M for indicating the received channel.

To facilitate the description of the function of the circuit is only the main section of the arrangement of FIG. 1 is reproduced in the block diagram of FIG.

At the beginning of operation, the control transistor TR1 is not conductive because there is no input signal at its base. Neglected man the currents in the transistor TR2, which works as an emitter follower, in the silicon-controlled one Rectifier and in TR6, the capacitor C1 is charged by a current, which is supplied from an energy source E via a resistor R.

A potential v thus builds up at point P. Because the transistor As I said, TR2 works as an emitter follower, the base potential can be approximately equal to that Be emitter potential. The potential v at point P is therefore unchanged via terminal 6 to the semiconductor element 5 variable capacitance of the semiconductor channel selector A A placed. As a result, the tuned or received frequency increases due to the fact that the capacity of the semiconductor element 5 with variable Capacity generally decreases when a voltage is applied to it. In this way an automatic frequency scanning is thus effected. The transistor TR2 is provided a flow of the charging current flowing through the resistor R through the resistor R6 or the display device M to prevent. Can the through these two circuit elements If the current flowing are neglected, the transistor TR2 is also not required.

If there is an electromagnetic input wave at input terminal 1, so during the build-up of the applied voltage v there comes a point at which the frequency of the input electromagnetic wave and that received by the channel selector Frequency match. The input will then be in the ordinary intermediate frequency implemented and given to the intermediate frequency amplifier B. From the output stage of the intermediate frequency amplifier is part of the intermediate frequency signal to the Control circuit J given1 via the transistor TR7. With the intermediate frequency signal it can be the audio signal (in Japanese system 22, 25 MHz). In the following, however, in the explanation of a use of the video intermediate frequency signal assumed. The point at which the signal from Intermediate frequency amplifier is removed, need not necessarily in its output stage lie. It is even possible to use the signal from the output stage of the channel selector to decrease. The control circuit J and the transistor TR7 constitute a frequency discriminator whose center frequency is equal to the video intermediate frequency. Of course you can also be equal to the audio intermediate frequency; however, in the following explanation assume that the center frequency is equal to the video intermediate frequency. The frequency discriminator works in such a way that if a frequency is present that exceeds the center frequency Intermediate frequency signal is emitted to a reference output positive output. Conversely, if an input signal is present, the frequency is lower than the center frequency given a negative outcome. In the examples of Figures 1 and 2, the frequency discriminator is drawn as a Foster Seeley circuit. Of course, it can also be be a ratio detector or a slope detector.

In general, the local oscillator frequency is used in a channel selector chosen higher than that of the incoming input wave by an amount that corresponds to the intermediate frequency. Therefore, due to the above-mentioned approaches Sampling the frequency of the intermediate frequency signal gradually from a lower one Frequency off to the center frequency and eventually becomes greater than this. Remain the intermediate frequency is lower than the center frequency, otherwise the output of the control circuit negative compared to the reference output. The transistor TR1 stays then non-conductive. If the intermediate frequency is raised to the value of the middle frequency, so the output of control circuit J becomes equal to the reference output, thus making the transistor TR1 is made conductive. Continuing the scanning process has the consequence that the intermediate frequency becomes greater than the center frequency. The output of the control circuit thus becomes positive with respect to the reference output, whereby the transistor TR1 continues even further is driven into its conductive state. As a result, the through the charging current flowing through the resistor R becomes greater than that through the transistor TRa flowing stream. The potential at point P thus decreases. Such a decrease in potential At point P, the scanning process is reversed: the intermediate frequency and thus the output of the control circuit becomes smaller. That's kind of negative Feedback effect.

The state of equilibrium is reached when the resistance R flowing charging current and the discharging current flowing through the transistor TR1 each other become equal, so that the scanning is interrupted. This state is called synchronicity The frequency-output voltage characteristic of the control circuit is made J sufficiently sharp, you get a compressed receiver system with automatic Frequency control (AFC automatic frequency controlling), in which the state of equilibrium can be sustained at a point where the intermediate frequency coincides with the Center frequency matches.

Nevertheless, this is followed by frequency shifts caused by the channel selector possible regardless of the frequency and intensity of the incoming input wave.

TR6 is a cold element, for example a silicon TV rectifier or in the case of a vacuum tube Thyratron passed through a first Voltage is made non-conductive and made conductive by a second voltage. Builds up increases the potential at point P to the point at which the scanning is ended, the element becomes TR6 fully conductive and then reduces the potential at the starting point of the scan. If the potential at point P is reduced to zero, it becomes silicon-controlled Rectifier TR6 switched off and the next scanning process initiated. A semi-fixed resistor X7 is used for building a breakdown of the silicon-controlled rectifier Tfi6 causing voltage. In the semiconductor channel selector Q, the receiving frequency depends solely on the applied voltage v. It is therefore possible by making a voltmeter from the AmpAremeter M and the multiplication resistor R8 and by providing the voltmeter with a channel scale a channel display in Dependence on the applied voltage v and thus an indicator for the respective Receive channel. TR was previously used as a silicon controlled rectifier explained. But this can also be set by any other element e that brings the potential at point P back to the original value through a breakdown and then switched off. The element can, for example, consist of a combination a known Schmitt circuit with a switching transistor or the like.

exist, thereby also achieving satisfactory operation.

Should the adjustment to a certain incoming input shaft changed to another wave, this can be done by restarting the im Equilibrium state of interrupted scanning can be achieved. That will be in the the following are marked as detuning. That can be achieved with one procedure after which to increase the potential sharply on Point p a signal is supplied and with a method for the temporary interruption the conductivity of the transistor TR1. Figures 1 and 2 illustrate one after the other simple method working circuit that is related to the type of the second above Procedure heard. for this a forward diode D1 is in series with the ground side connected to a bias circuit R9, R10 for the transistor TR7. The drop in tension at the diode D1 can be neglected because of the forward polarity just mentioned. A capacitor C2 is connected to the connection point of the diode D1 with the resistor R10, which, on the other hand, lies at a point where one is divided by voltage voltage e obtained through resistors R11 and R12 is present. At rest the capacitor C2 is therefore charged via this voltage e. The transistor TR7 then works normally and maintains the state of attunement. If you press one now ° detuning ° pushbutton switch SW down, the potential at the connection point drops of resistors R11 and R12 with each other rapidly decrease to zero. The capacitor C2 becomes so prevented from quickly discharging. The potential at the connection point between resistor R10 and diode D1 is now made negative by the amount e and the transistor TR7 is thus switched off. As a result, the transistor TR1 non-conductive and then the scanning process is initiated. It is made through the resistances R9 and R10 cause a current to flow through the capacitor C2. After a certain period of time created by the resistors R9 and R10 as well as the capacitor C2 is determined, the potential at the connection point between the diode D1 and the resistor R10 is reduced to Wull volts, so that the Transistor TR7 becomes conductive again. In this way the prerequisites are for the next voting process. With such a circuit arrangement it is necessary to keep the "detuning" pushbutton switch SW on for a long time remains closed as the transistor TR7 remains non-conductive. Tests have shown that the values for the resistors R9 and R10 and the capacitor C2 are chosen so can that the transistor TR7 remains non-conductive for a maximum of 0.2 seconds. Of course the search speed must be chosen so that during the non-conductive State of transistor TR7 and therefore also of transistor TR1 is the tuning range completely abandoned for the previously set incoming input shaft and yet the tuning point for the following incoming input shaft has not yet been exceeded is. It is also possible to use a monostable multivibrator in the pulse generating section serving to make the transistor Tr7 conductive, the time span for the N @@@@@@ t @ ang @ from the closing time the @@@@ k @ @W @@@ @@ llen.

Above @ described by the function in general. it is now the the following facts: 1. television signal contain a video and a Audio carrier wave. With the described arrangement, both the video carrier wave as well as the audio carrier wave selected. It is now assumed that the normal is a conversion of the video carrier wave to an intermediate video frequency. It is then required the anomalous conversion of the audio carrier wave into the normal video intermediate frequency to prevent.

2. The distribution of the television wave bands is as follows: In the Japanese system channel 1 - 3 90 14 Hz - 108 MHz low band channel 4 -12 170 MHz - 222 MHz high band In the US system channel 2 - 6 54 MHz - 88 MHz low band channel 7-13 174 14Hz - 216 14Hz high band The UHF band is divided as follows: In the Japanese system channel 13 - 62 470 MHz - 770 MHz In the US system channel 14 - 83 470 MHz - 890 MHz An attempt is made to pass through all channels Bringing the use of an element with variable capacitance into the reception range of a device without switching the coils. the following ratios of the minimum tuning frequency to the maximum tuning frequency are obtained: In the Japanese system 90: 770 In the US system 54: 890, however, it is almost impossible to achieve such ratios solely with the aid of changes in the capacitance of the elements with variable capacitance. It is not convenient to perform the scanning or receiving operation on the frequency band between the "low" and "high" bands or between the "high" and UHF bands, since the intermediate bands are unrelated to television. It is therefore preferable to make a division for each of the reception bands described above. The following relationship 1 C ~ f² can thus be obtained from the following formula, which gives the parallel resonance frequency f through the inductance value L of a coil and the capacitance value C of a capacitor: This gives the following values for the ratio of the minimum to the maximum value of the tuning capacity for each band: In the Japanese system, low band 1/90: 1 / 108² = 1: 1 / 1.44 high band 1 / 170² = 1: 1 / 1.7 UHF band 1 / 470²: 1 / 770² = 1: 1 / 2.68 In the US system, low band 1/542: 1 / 88² = 1: 1 / 2.65 high band 1 / 174²: 1 / 216² = 1: 1 / 1.54 UHF band 1/4702 s 1 / 890² - 1 t 1 / 3.58 These ratio values can easily be achieved. The semiconductor channel selector A is to be designed in such a way that the Bandus circuit can be carried out purely electronically by applying a voltage ## - a specific terminal, as described above. After completion of the scanning process for the currently selected band, it is possible to automatically switch to the next door.

3. From the functional principle explained above, it follows that with Interruption or weakening of the incoming input wave due to fading, Noise or the like. What failure of the Synchronization signals result has, the state of equilibrium may be disturbed, so that the search restarted and the currently selected channel is changed. To prevent that, the tuning state is to be maintained for a short time, even if the above Circumstances arise. It is necessary to take additional precautions for this. This is to be explained in the following under the term of short-term storage, however, this is not necessary in all circumstances.

Of the three points explained here above, the work of the under Point 1 described discriminator can be made dependent on whether the The video signal demodulated by the video detector C is given to the video amplifier D. The circuit shown in Fig. 1 is constructed based on this fact, and the Explanations relating to FIG. 2 are directly applicable to FIG. 1 as well. if the demodulation output of the video detector C contains a synchronizing signal If a video signal is present, these synchronization signals occur in the sync separator F. as well pulses of a repetition rate appear on the horizontal synchronization signal output tube, which speaks of the horizontal frequency. If the tuning state is abnormal, none will be obtained Demodulation output when the envelope of the audio intermediate frequency signal is demodulating because this is frequency modulated. There is a distinction between that 90 normal and abnormal tuning state possible depending on the fact whether a horizontal synchronization signal output sync separator is present or not. One from the anode or grid of the horizontal sync signal output tube detachable signal is made with the help of a diode D2and a capacitor C3 converted into a DC signal. If the received direct current signal exceeds one predetermined value, so the cut circuit K is caused to a switching transistor Disconnect TR4, which is inserted between the output terminals of control circuit J. Since synchronization signals are not available in the abnormal tuning state, In this case, no output is supplied by the diode D2, so that the Sohnitt circuit K K not working. At this point the switching transistor TR4 is made conductive, so that the output of control circuit J does not reach transistor TR1. The scanning continues so, eliminating any possibility of tuning to the audio carrier wave is prevented. A resonance circuit N has the fundamental wave as the resonance frequency Horizontal repetition rate. This resonance circuit is used to switch off noise components. It is not necessary in all circumstances to connect the switching transistor, TR4 to the Provide output side of the control circuit. It can also be between the connection point between the decoupling resistor and the coil for the switching transistor TR4 and earth be switched. The Schmitt circuit K promotes operational safety, for what the output of diode D2 can be connected directly to transistor TR4.

The above has described the case where an S signal is from the output of the sync separator is removed. It is also possible to use part of the intermediate frequency signal from an intermediate stage of the intermediate frequency amplifier B and through it to demodulate a selector circuit that only allows the video carrier wave frequency to pass. The demodulation output can be connected directly to transistor TR4, like in the case of the output of the above-mentioned diode D2.

Alternatively, the S signal can also be examined to determine whether a the signal corresponding to the audio intermediate frequency in a certain tuning state in addition to the video component. In the normal tuning state, the audio intermediate frequency occurs always in a position 4.5 MHz below the video intermediate frequency. That applies to both the Japanese and US systems. It can therefore be one of the normal Audio intermediate frequency corresponding signal from intermediate frequency amplifier B im narrow band removed, rectified, and converted into a signal and then with a step after the! Diode D2 to be connected. This procedure can be used for a conventional television receivers can be easily performed. In the case of subcarrier television receivers is the audio intermediate frequency through an audio intermediate frequency trap in the stage considerably weakened after the intermediate frequency amplifier.

Therefore, it becomes the same as the normal audio intermediate frequency Signal after picking up from the audio intermediate frequency trap Q a narrowband amplifier fed. The signal can also be sent to the output stage of the channel selector or to the Step after the intermediate frequency amplifier can be removed.

This procedure is discriminatory compared to the procedure mentioned above, which is based on the presence or absence of the synchronization signals. Of the Advantage is that there is no possibility of incorrect work due of noise or crosstalk modulation. This advantage is given by the something complicated structure not bought too dearly.

The waveform of the scanning voltage will now be described in FIG. In the circuit arrangement of FIG. 2, the energy source E charges the capacitor C1 through the resistor R. The potential v at point P is represented by the well-known CR charging curve of FIG. The capacitance Cp of the variable capacitance semiconductor element is generally given by Cp = k vn ........................ (1) k, n = constant under the Assuming that the inductance L is connected in parallel with Cp, the tuning frequency f increases K, N = constant It follows that the tuning frequency is generally given by a curve according to FIG. FIG. 6 shows the relationship between frequency f and time t, which can be seen from FIGS. 4 and 5. It can be seen that variable frequency widths are obtained per unit of time. This means that the pulse width has to be changed depending on the frequency for the wmissingw. It also means that a very long time is required for the "detuning" in higher frequency ranges With receivers equipped with vacuum tubes, this charging current can be supplied by the energy source B. With transistorized receivers it can be obtained from the attenuator.

If one uses such a constant current circuit as shown in Fig. 3, it is possible to largely use the relationship shown in FIG to get straight without paying for it to a high power source to have to grab. However, it is still necessary that the width of the "Detune" pulse changes with frequency. The circuit shown in FIG is designed so that such a pulse width change is not required. The transistor TRf is used instead of the resistor R1, and the charging current i flowing through the transistor becomes proportional to the applied voltage v made. This method, the charging current i proportional to the applied voltage v v will be referred to as the proportional current sampling method in the following. In this way, between the time t and the voltage v, that in FIG. 7 is obtained relationship shown. The curve is opposite to that of Fig.

5 5 bent. The straight-line relationship shown in FIG. 8 is thus obtained between time and frequency. This is to be described in more detail below. The charging current i is proportional to the applied voltage v, i.e. given by i - A v. (3 AS proportionality constant This results in The frequency selected by the channel selector is given by equation (2). Thus log fz N log v + K '................ (6) K' = constant In reality, however, the frequency is changed at most twice, which is why the following equation is valid can be assumed: faa log v + b (7) a, b, constant The following equation is obtained from equations (5) and (7): A f = a log ext + b .......... .. (8) C1 The relationship between t and f is reduced to a linear function. This proves that the relationship of Fig. 8 actually becomes linear and means that the frequency change per unit time resulting from scanning remains constant. The “detuning” pulse width can thus advantageously remain constant.

The receiving band switching operation will now be described. It has already been mentioned that in VHF receivers a band switching between two bands, namely the "low" and the "high" band is to be carried out. With an all-channel receiver such a switching must be carried out between three bands, as to the two VHF bands, there is still a UHF band.

Fig. 1 shows the arrangement for a VHF receiver, in which the channel selector A, each having a pair of input and output terminals is that it works in the lower band when a voltage is applied to terminal 3 and in the "high" band when a voltage is applied to terminal 4.

With this arrangement, a voltage is alternately applied to the terminals 3 and 4, each time a scan is completed. Since switching he follows between the two bands, the bistable multivibrator in the in Fig. 1 switched. Can act as a trigger for the bistable multivibrator a voltage surge can be used, which occurs at resistor R2 when the Capacitor C1 through the silicon controlled Rectifier TR6 discharges. This happens when the return from the end point to the starting point during a scan I takes place.

With an all-channel receiver, three such channel selection levels can be used are provided. Fig. 9 shows an embodiment of such a receiver. Man recognizes a channel selector 91, an intermediate frequency amplifier 92, a tristable Circuit 93, a trigger pulse input terminal 94, a UHF band terminal 95 as well as a clamp 96 for the "high" and a clamp 97 for the low band. An example for a tristable circuit 93 is shown in FIG. As a trigger pulse Voltage surge pulses are used, which result from the current flowing after termination every scanning process flows through the silicon-controlled rectifier TRö. One The voltage appearing at each of the three terminals is applied to the terminal of the channel selector laid, whereby the band switching takes place. The output of the tristable circuit As FIG. 11 shows, 93 is shifted this time when it receives a trigger pulse is created. The receiving band can be in the order "lowest", "high" and "UHF" band can be switched. In Fig. 11, a outputs the to the trigger pulse input terminal 94 applied trigger pulses again, b is the voltage waveform applied to the UHF tape terminal and c is the voltage waveform appearing at terminal 96.

Short-term storage will now be described.

One of the basic problems of all automatic tuners with scanning device is that for them the uninterruptible running-in a stable wave is a prerequisite. From the description of the function above it can easily be seen that with such devices there is a risk of detuning exists if the incoming wave is only for a short time 1 interrupted will. This can be due to a fading or the like.

resulting attenuation, because of an equally high noise level, with decrease the degree of modulation of the video signal, very brief interruption of the synchronization signals etc. happen. This leads to the fact that the channel that has just been selected goes against changed the will of the TV user and selected the next channel will. Such disruptions can be avoided by short-term storage, which was described under point 3 above. In Fig. 1, the dashed line is shown Section H the circuit provided for this. Remains during scanning and dialing the switching transistor TR5 is conductive, so that it has no influence on these processes. The transistor TR5 is controlled by a monostable multivibrator H 'and is switched off as soon as the multivibrator H1 is activated by triggering. on the other hand it is switched on when the multivibrator after one by its own time constant returned to its original state for a certain period of time. The monostable multivibrator H1 is designed in such a way that it is triggered when the Discrimination signal is interrupted or weakened. In the circuit of Fig. 1 the Schmitt circuit K is supplied with the signal from the horizontal synchronization signals received at the sync separator and converted into a direct current in a narrow band circuit will. During the work of the Schmitt circuit K there is an influence on the monostable Multivibrator not available. As soon as the Schmitt circuit K stops working, will the monostable multivibrator H 'triggered by the resulting shock pulse, whereby the switching transistor TR5 is made non-conductive. Because this transistor TR5 is initially conductive, a search operation can be carried out without difficulty in spite of this arrangement initiated and the wave of a certain channel selected. Let us now assume that the exit the diode D2 decreases for some reason, if a certain channel has already been tuned into. This case would without the transistor TR5 and the monostable multivibrator H ', i.e. without short-term storage result in an upset. With the memory circuit, on the other hand, the Operation of the Schmitt circuit K interrupted because of the decrease in the output of the diode D2. The monostable multivibrator H ″ is thus by one of the Schmitt circuit generated shock pulse triggered. This turns off the transistor TR5 and a new scanning process is prevented. It is of course possible that the capacitor (J1 1 is discharged through the transistor TR1 even if the transistor TR5 Is blocked. This is a consequence of the fact that the equilibrium current is tuned in State had flowed through the transistor TR1. However, there is no discharge path for charging the capacitor C, since the Schmi.tt circuit K is already out of operation is set. The switching transistor TR4 in the control circuit J is therefore switched on and makes the transistor TR1 non-conductive. This becomes the original voting point held until the monostable multivibrator H 'has returned to its original state returns.

Is the weakening of the signal wave, during this time in which the the original tuning point is held, then the one that was created remains voltage is the same and there is no obstacle to generating the intermediate frequency signal. So the Schmitt circuit is in operation. The switching transistor TR4 is switched off and the duty cycle of the monostable multivibrator H 'is finished after the Control effect of the transistor TR5 initiated and then the transistor TR5 switched on is. This makes short-term storage secure maintain.

But if the weakening of the incoming wave is eliminated again the monostable multivibrator H has returned to its original state is, then disadvantageously the search process is started again, whereby causes a detuning and the next channel is selected. In practice it will however, the incoming input shaft is seldom interrupted for more than a few seconds. Therefore, the pulse width on the monostable multivibrator H 'or the storage time the short-term memory circuit from a practical point of view maxima a few Seconds. Such storage times are easy to achieve. During the Operation of the monostable gate H ', the transistor TR5 is non-conductive, and a "detuning" l by depressing the push button switch SW is not possible around this disadvantage to avoid is a diode D3 between the connection point of the resistors R11 and R12 with each other and the base of the post-stage transistor of the monostable multivibrator H 'switched. If the push button switch SW is operated, the cathode takes the Diode D3 to earth potential, whereby the monostail multivibrator H 'is independent of its operating time is interrupted in its operation. The transistor TR5 will immediately conductive, and the detuning is initiated. The diode D3 is for this one Purpose intended.

A method has been described above that causes a detuning enables transistor TR7 to be blanked for a predetermined period of time will. This method is simple and cheap and therefore advantageous. However, it has the disadvantage that operational errors occur when either the keying speed or the predetermined period of time, hereinafter referred to as the blanking time, of the intended value of any Reason, for example because of temporary changes.

This is a consequence of the fact that between the blanking time and there is a critical relationship with the blanking process. other great difficulty in the method described is that the blanking time must be changed, when the frequency band is switched. The blanking time could be for the same frequency band remains the same, the corresponding frequency band to be scanned but differs between the low ", the" high "and the" UHF "-i3and strong.

This makes the circuit complex and does not work properly Episode. It can be seen from this that the method explained with reference to FIG. 1 is simple, but is not very practical.

In order to solve the problems identified, the following is described Proposed method in which the blanking time corresponds to the scanning speed will be changed. The basic principle of this procedure is as follows: by pressing down of the detuning switch is an application of the input to the base of the control transistor TR1 prevents. This also prevents the tuning process and scanning continued, whereby the disgruntlement is achieved. If the received signal wave is out of tune, so the control signal and the discrimination signal disappear.

When the next incoming wave arrives, these are controlled and the discrimination signal is generated again. So can by palpation of the disappearance or the generation of these signals an input to the bis of the control transistor TR1 which brings it back into a state in which ao tuning is possible is. Since the detuning continues until the wave that has just been selected is completely off the capture area or until the next signal wave arrives, the scanning speed corresponding blanking time can be set automatically without that these must be given special consideration.

Fig. 12 shows an example of an arrangement in which creating of the discrimination signal is detected. Fig. 13 shows an arrangement that the Detects the disappearance of the control signal.

Fig. 12 shows a circuit in which the discrimination signal to a Terminal 21 is given. A terminal 22 is connected to the switching transistor TR4 of Fig. 1 connected. If the discrimination signal is fed to the terminal 21, it changes the potential of the collector of a transistor 23 from 0 to + E. Read potential change is differentiated so that a negative pulse is applied to a TranBistor 24 will. This creates a bistable multivibrator consisting of transistor ren 24 and 25 brought into the tSin "or the stable state. At this moment there is no voltage at the terminal 22, so that the switching transistor TR4 becomes non-conductive and the device so that it is in a state in which a voting process can be carried out. That is, after generating a discrimination signal, the apparatus performs a tuning process perform and select a video carrier wave. Then press a switch 26 generates a negative pulse which is applied to the transistor 25 will. As a result, the bistable multivibrator assumes another stable state. This has the consequence that a positive voltage occurs at the terminal 22, which the Lets transistor TR4 become conductive. The device is thus in a state in which voting is not possible. At the same time, the search will conduct some and leave the just received signal from voting. When the next one arrives incoming signal wave is generated again a discrimination signal, whereby the described function is repeated. In this way reception is possible.

Fig. 13 shows a control switch 27 which is a silicon-controlled Rectifier or the like. Can be. It is between the control circuit J and the base of the control transistor TX1 switched. The Sauerschalter is designed so that it once switched on remains switched on as long as there is a voltage between its Anode and its cathode is present. If this voltage disappears, it is switched off. In the receiving state, a positive voltage can be taken from the control circuit J and be applied to the base of the control transistor TR1. If you try to find a mood initiate, the switch 26 is depressed. This will be a positive Impulse given to the gate of the control switch 27 and made this conductive. In order to the input of the base of the transistor TR1 is interrupted. The scanning process will thus initiated again and as soon as the just received signal wave outside of the Voting is, the positive voltage of the control circuit J disappears, so that the control switch 27 is made non-conductive and allows reception.

Above the circuit according to the invention for automatic tuning described in detail. Finally, the voting display, i.e. the Display of the respective receiving channel. The tuning frequency is depends solely on the applied voltage v and therefore a display can thereby enable a voltage indicator to be used and it to be provided with a channel scale provides. However, if the frequency band is divided two or three times, then one double or triple channel scale required, which is easy for the user to read the scale difficult. For example, Fig. 1 shows the case in which the frequency band in divided into two sections is. A DC ammeter is used as the display device M used. The multiplication resistance H8 is chosen so that it is greatest at the point Voltage of the "lower" band a current flows through it which is half the scale deflection is equivalent to. Terminal 4 des, which is used for the power supply in the whohenz band to switch the frequency band serving bistable multivibrator L is with connected to the display device via a resistor in such a way that through the display device a current superimposed on the mentioned current flows. The resistance will be like this selected that the superimposed current is equal to that current that is at the point max -maler tension flows in the "lower" band. Such an arrangement results in a Display for the "lower" band in the first half of the full scale of the display device and a display for the high band in the second half on the device. In this way one advantageously obtains a single scale which is used to display the "lower" and the "high" band is suitable.

If the frequency band is divided into three sections, one single scale can be divided into three sections, each one-third occupies the full scale. This is done in the way described above. It is but in television technology so that the "lower" and the ZhoheZ band as common Bands belonging to the VHF band are considered that are not separated from one another are. The UHF band is differentiated from the VHF band. The total number of channels in the VHF band, which includes the "low" and "high Z" bands, is 12. The number of Channels in the UHF band is considerably coarser. It is therefore from a practical point of view better to summarize the display of the entire VHS tape on a scale and display the UHF band on a different scale. It is necessary to do this, the circuit to be interpreted in such a way that the sensitivity to tension; of the voltmeter (R8 and M) becomes twice as high in the UHF band as for the VHF band. It can either can be achieved by taking the resistance value of the multiplication resistor R8 makes only half the size during UHF reception than during VHS reception, or by the fact that the current sensitivity of the ammeter M during UHF reception doubled compared to VHF reception. The first case is shown in Fig. 14, the second in Fuig. 15th

Fig. 14 shows a circuit in which a voltage is applied to a terminal 36 is laid. A terminal 38 is connected to the energy supply source for the high " Band connected to the tristable circuit. A clamp 37 is on the power source of the UHF band. For the display of the lower "band is due to the Terminals 37 and 38 no voltage, and the voltage applied to terminal 38 becomes therefore given to an ammeter 35 via a resistor 31. So that the "lower" and the "high" band can be displayed on a single scale is the value of the resistor 31 selected so that at the point of maximum voltage in the "low" band the display device has performed half a scale deflection2. For the advertisment In the "high" band, a voltage + S is applied to terminal 36, which is transmitted via a resistor 33 reaches the ammeter 35, which is thus brought to half the scale deflection will. This closes the display for the whohe "band on the display for that lower "band. There is no voltage at terminal 38 for the UHF band display, however, the + E voltage at terminal 37 is maintained. This tension is on the base of a transistor 34 is placed across a resistor 5. The transistor will made so conductive. A current now flows through the ammeter 35 via the Parallel resistors 31 and 30. Will be the resistance values of the resistors 31 and 30 equalized beforehand, so is the voltage sensitivity of the ammeter 35 in the UHF Baxld twice as high as in the VHF band. The display device is in able to perform a full scale deflection at the point of maximum tension.

Fig. 15 shows a circuit in which the terminals 46, 47 and 48 the Terminals 36, 37 and 38 of FIG. 14 correspond.

If the "lower" band is to be displayed, a voltage is applied to the Terminal 46 placed. This causes a current to flow through a resistor 39 and then by two branches of a shunt that has a resistor on one side 43 and .. an ammeter 45 and on the other side a diode 40 and a resistor 42 has. The resistances are chosen so that the total resistances of the shunt paths be the same size and the ammeter at the point of maximum voltage half the scale deflection shows. If the "high" band is to be displayed, a voltage + E is applied to the terminal 48 placed what the flow of a current through a resistor 44 and the ammeter 45. By a suitable choice of the resistor 44 it is possible to achieve that on the ammeter 45 there is half a scale deflection, it is then possible to display the "high" band on the second half of the hmperimeter scale. If the UHF band is to be displayed, the voltage + E is applied to terminal 47. The diode 40 is thus reverse-biased via the resistor 41. Of the The current flowing through the resistor 39 must then be passed through the AmpAremeter 45 flow. Since the resistances in the paths of the shunt are equal to sin the current flowing through the ammeter 45 is twice that.

roughly like both VHF band displays, so the display device is on point shows a full scale deflection at maximum voltage.

The resistor 41 can also be omitted. The internal resistance of Ampèremeters 45 must then be so large that the voltage difference between his Terminals are sufficient to make the diode 40 sufficiently conductive.

Claims (12)

P'a t e n t a n 5 p r ü c h e: 1. Television receiver, characterized by a Kahalwähler, the has variable capacities as tuning and oscillating elements to which the Sweeping the tuning frequencies of the channel selector the voltage of one from a DC power source charged capacitor is placed by assuming the maximum value of the Capacitor voltage sensing and this thereupon instantly discharging switching device an active control element connected in parallel to the capacitor to keep it constant the voltage across the capacitor in accordance with g with a conductivity state by a frequency discriminator circuit, the output terminal of which is used to control the conductivity of the active element is connected to its control terminal by an input signal and a video or audio intermediate frequency signal is applied to its input terminal is, and by a switching device, which is conductive or non-conductive, depending on whether a signal is present or not that corresponds to the input signal of the frequency discriminator circuit not identical but derived from the same received wave, which makes automatic Tuning is achieved while avoiding tuning to the audio carrier wave. 2. Television receiver according to claim 1, characterized in that the signal for making the switching element conductive or non-conductive, the synchronization signal i8t. 3. Television receiver according to claim 1, characterized in that when using the video intermediate frequency signal as the input signal of the frequency discriminator the audio intermediate frequency signal as a signal for rendering conductive or non-conductive of the switching element is used and vice versa. 4. Television receiver according to claim 1, characterized in that that the charging voltage of the capacitor from the emitter one working as an emitter follower Transistor removed and attached to the variable capacitance elements in the channel selector given that a variable impedance element is in series with a resistor is connected between the capacitor and the direct current source - and that the Impedance of this element as a function of the collector potential of the transistor is controlled, whereby the charging current flowing to the capacitor becomes the charging voltage of the capacitor and thus the relationship between the sampling time and the tuning frequency is linear. 5. Television receiver according to claim 1, characterized in that the channel selector is divided into a large number of band levels, only one of which is operated with the help of impulses, which are caused by the momentary discharge of the capacitor are obtained when the maximum voltage value is reached on the capacitor. 6. Television receiver according to claim 5, characterized in that the channel selector in a section for a "low" and a section for a "high" Volume is divided and that each of these sections is provided with an energy source a bistable multivibrator is connected, which with the help of the mentioned pulse repeatedly operated it. 7. Television receiver according to claim 5, characterized in that the channel selector in a section for a "low" band, one for a "high" Band and one for a "UHF" band, each with a power source connected via zinc tristable circuit, which with the help of the mentioned pulses is operated repeatedly. 8. fern television receiver according to claim 1, characterized in that with the input terminal of the switching elements Schmitt circuit connected by a signal that differs from the input signal of the frequency discriminator, but the signal derived from the same empirical wave is controlled and its operation is interrupted when the Empiangswelle is weakened in a predetermined barrel, whereby the receiver is prevented from dialing a received wave that is too weak. 9. Telecommunication receiver according to claim characterized in that with the switching element is connected to a bistable multivibrator, which is controlled by a switch is reversible, namely with Hilie en generated by operating the switch In @@ l @ en creates the @@@@@ telement to start scanning the channel sequence is in @@@@ tet, and that the bistable multivitrater is activated by an @ going signal of the frequency discriminator different, but derived from the same Em- @ iangswelle Signal is controlled, whereby the bistable multivibrator for switching on the Switching element is reversed again. 10. Television receiver according to claim 1, characterized in that a three-pole switch is switched off in the presence of a voltage on two of its terminals and is connected between the control terminal of the active control element and earth, that a device for supplying the control terminal of the three-pole switch with a the signal resulting from the actuation of the detuning switch is provided, that the three-pole switch by this signal to initiate the scanning of the Channel frequency is switched on and that the three-way switch is completely detuned of the receiver is switched off. 11. Television receiver according to claim 6 or 7, characterized in that that with a channel selector divided into "low" and a "high" band section a display device intended for the voltage on the charging capacitor is that 'when reaching the maximum occurring during the scanning of the low "band Voltage half the scale deflection and that when the "high" band is displayed a superimposed voltage resulting from the reversal of the bistable multivibrator is fed, whereby the scale range from half the scale deflection to the full Full deflection is assigned to the "high" band. 12. Television receiver according to claim 1, characterized in that the capacity of the charging capacitor to increase i the time constant of the discharge is increased that between the capacitor and the energy source, a switching element is switched on that with the input terminal of the switching element a monostable Multivibrator is connected and that for storing the received channel of the switching element switched off with the help of a signal that can be removed from the mono stable multivibrator is as soon as the receiving wave is weakened or has failed completely. L e r s e i t e