DE2404497C3 - Automatic tuner - Google Patents

Description

The present invention relates to an automatic tuner. Home reception of television broadcasts it is necessary to select a desired channel from several Select telecommunication channels. One of the typical channel selectors used for the purpose of d < A rotary selector is used to select TV channels. However, a rotary selector usually closes a circuit through mechanical contact a pair of contacts, which is done by manual rotation. For this (iruiulc suffers a rotary selector is always disadvantageous with poor electrical contact between the con-

clock pairs due to the destruction of the contact surfaces, furthermore there is manual handling tiresome, and eventually the rotating motion makes a sound. Another typical one Channel selector, which is suitable for selecting television channels, is a multi-circuit push button switch. A push button switch, however, has the same disadvantages of poor electrical conductivity for the same reason as a rotary selector.

Recently, a television channel selector for selecting VHF television channels has become known, which uses a voltage controlled variable capacitance and it is to be expected that this channel selector will find a wide range of applications in the future. Such a voltage controlled variable Capacitor uses a capacitance between the Boundary layer of a diode is formed, namely variable as a function of the barrier or boundary layer applied reverse voltage and is known as a variable capacitance diode. In such a channel selector it is necessary to provide a supply voltage with which a multitude of different To generate voltages in response to manual operation of the channel selector, each Voltage belongs to a value that causes a certain capacitance, with which in turn the channel selector selects the desired corresponding channel. Such a supply voltage for Generating a variety of different voltages has a reference voltage source and a plurality of voltage dividers for dividing the voltage of the voltage source, each of the partial voltages is selectively selectable in response to an individual manual setting. Another guy such a power supply for generating different voltages for a variable capacitance diode comprises a capacitor and a charging and discharging circuit of the same, via the Capacitor jine voltage is applied. which selects in response to an output of a channel selector and is applied to the variable capacitance diode. More precisely, the capacitor is being charged or discharged by the charging or discharging circuit. until one is placed over the capacitor Voltage causes a capacitance in the Diouc, with which the voter selects a television channel to view a Generate tuner output signal, whereby the charge / discharge circuit is forced to charge or Interrupt the discharge process of the capacitor, so that the voltage generated across the capacitor equal i / leibt. If another channel is desired, the charge-discharge circuit will turn again switched on by manual actuation and the above process is repeated until another Channel is selected. Even so, the voltage across the capacitor drops over due to leaks undesired creepage distances, whereby a detuning of the channel selector occurs, which is in a poor picture quality noticeable on the screen of the cathode ray tube of the television receiver power. In order to solve such a problem, it is necessary to provide a circuit that can control the voltage drop compensated across the capacitor due to leakage, causing the circuit complicated and the system becomes expensive. Another disadvantage of the Fernsehkar.fcl'wühlcr with a variable Capacitance diode with voltage applied to the capacitor consists in the fact that it is above the capacitor lying voltage rises or falls exponentially rather than linearly, making it difficult to get an accurate one to achieve automatic voting. However, it is desirable to have an improved power source which is suitable for use in automatic tuners. A voltage-storing component of interest here in connection with the present invention is contained in U.S. Patent 3,753,110; H.

in on August 14, 1973 for Hironosuke Ikeda et al., clerk by Sanyo Electric Co., Ltd., the same assignee as the present invention. As stated in the cited patent, Professors Takehiko Ta kash as h i and Assistant Professor Osamu Y am on ο to of the Technical Department of the University of Nagoya started their studies on an electrochemical voltage storage system Component that uses a solid electrolyte, on '? .-. R 22nd annual

.-υ Meeting of the Japanese Chemical Association, held between April 5 and 7, 1969. To be brief, this element contains a silver electrode as cathode, a silver telluric alloy electrode as an anode and a solid state elec-

: i trolytes with high ionic conductivity, e.g. B. RbAg ₄ I ₅ , wherein the solid electrolyte is sandwiched between the two electrodes. If a DC voltage is applied to the component, such that the silver electrode (cathode)

jci is negative, part of the migrates in the silver-tellurium alloy electrode contained silver over to the silver electrode, which results in a decreasing activity of the silver in the silver-tellurium alloy. creating a growing potential difference between

r. occurs on both electrodes. The inventor of this component called this process "loading". When the polarity of the applied DC voltage The opposite is the case compared to the case mentioned at the beginning, so the silver in the Ag-Te alloy is again

κι enriched, which is a decreasing potential difference and may return to its original value. The inventor of this Elements called this process "discharge". Studies conducted on this by the inventors

r. Component say that the electromotive force generated by the above charging or Entladcstrom, runs linearly within a certain range with respect to the charging or discharging time. the end for this reason, this component is in excellent

> () the way suitable, a non-registered and non-destructive Perform read operation, keeping between the charging or discharging voltage and the clamping voltage there is a relatively linear relationship, and in addition the memory function for a relatively

r> be maintained for a long time. These advantages mean that each component has opened a way for its possible use, namely, used as an analog safety element. Said patent beinhal et ^f further improved electro-

, o chemically tension-storing element. More accurate 6 of said patent shows an improved electrochemical voltage storage device Element with the elimination of the ohmic voltage drop across the resistance of the solid-state

electrolytes and the overvoltage caused by the dissolution or deposition of silver, the Component is basically characterized by the use of an auxiliary cable that provides an

has output terminal for the separate reception of the potential from the above-mentioned cathode, which as The input terminal is used for the power supply.

The invention is based on the object of creating an automatic tuner that does the tuning is able to perform automatically with precision, and in addition, if a Detuning the vote self-correcting i> a should.

The solution to the problem is characterized according to the invention by means of a solid electrochemical voltage-storing component with a cathode with an active metal, with an anode, consisting of an alloy of this metal and a solid electrolyte with high ionic conductivity that is sandwiched between the cathode and the anode is arranged, wherein the voltage-storing component has a clamping voltage between the The anode and the cathode, which is a linear function of the component to or from the same The amount of charge carried away is, depending on whether the anode is positive or negative,

a control device for controlling the cathode of the component to generate a current in a desired Direction by the same, whereby a selective loading or unloading of the voltage-storing component occurs, a tuning device with a voltage-controlled variable reactance to which the clamping voltage of the voltage-controlled element can be applied, wherein a tuning frequency of this tuning device depends on the clamping voltage of the voltage storing device Elements depends on

Coupling elements for the voting device to provide an indicator signal for the degree of voting of the voting device to generate and

Circuits for the tuning display signal of the tuning device to interrupt the flow of current through the voltage-storing component and thus to interrupt the charging or discharging

The automatic tuner according to the invention has the salient advantage that with it a vote can be carried out fully automatically with great precision, with the occurrence of a The tuning corrects itself automatically.

Further preferred refinements of the invention are presented in subclaims 2 to 12.

Further advantages of the automatic tuner according to the invention result from the following example description in conjunction with the drawings. It shows

1 shows a schematic cross section through an electrochemically voltage-storing element, as used in the present invention,

Figure 2 is a graph showing the relationship between charge or discharge time and therefore the Amount of electricity and the electromotive force of the component, the charging or discharging current serves as a parameter,

3 shows a schematic cross section through an improved electrochemically voltage-storing device Element for eliminating the ohmic voltage drop within the solid electrolyte and for Elimination of overvoltage caused by the dissolution or deposition of silver,

Fig. 4 is a block diagram of a television receiver embodying the present invention by using of the above-mentioned voltage-storing element includes,

Fig. 5 shows the relationship between time and ver "' different voltages which occur at different points in the block diagram of FIG. 5,

Figure 6 is a block diagram of a television receiver in a preferred embodiment Invention, in turn the above-mentioned spani " nungsstcicherndc element is used,

Fig. 7 is a more detailed circuit diagram of the manual

Actuating switch II of the charging / discharging control circuit 12, the voltage-storing element 13 and the DC voltage amplifier 14 from the left

ι> half of Fig. fi,

Fig. 8 is a more detailed circuit diagram of the lower one Threshold detector 15, the upper threshold detector 16 and the hip-hop 17.

9 also shows a more detailed circuit diagram of the - "> gate 18, the inverter 19, the gate 20, the channel selector 21 and the intermediate frequency amplifier 23,

Fig. Small detailed circuit diagram of the frequency de-

tcktors 42, a circuit 40 for generating a

:> Charge / discharge control signal of the bandpass filter 47 and 48th of the level detector 49 and the AND gate 41, uiut

Fig. 1 1 graphically shows the relationship between the value of the signal at different Tci in lcn of the circuit diagram in FIG. 10 as a function of the frequency.

In the drawings, the same reference parts are identified by the same reference numerals.

1 illustrates a schematic cross section of an electrochemically voltage-storing component 1 which is used in the device of the present invention. This component is a cell of the type. The contains a solid electrolyte 4 of high ionic conductivity, such as. B. ■ '<> RbAg ₄ I ₅ or Ag ₁ SI, covered like a sandwich by f »inp kT athr» Hp J A \ f> haiintcnrhlirh ^ ilhpr ί A a \ pnthUlt ·

the other side of the solid electrolyte is covered with an anode 3 mainly made of an alloy of silver and one element from the group

• 'consists of sulfur (S), selenium (Se) and tellurium (Te), preferably the alloy is an Ag-Te alloy. When on the two electrodes 2 and 3 of this component a DC voltage is applied, in each case via an input source 5 and common-

in the same terminal 7, so that the anode ^ des Component positive and cathode 2 is negative. thus becomes the silver in the Ag-Te alloy ionizes and dissolves within the anode 3 within the solid electrolyte 4 and is

a method 2 deposited. Such a working state is hereinafter referred to as "loading". If a DC voltage is applied to the above-mentioned component in the opposite direction as just described, the deposited on the cathode 2 migrates.

bo gered silver on the anode 3 and is on the same deposited. Such a working state is hereinafter referred to as "unloading".

Fig. 2 is a graph showing the relationship between charging and discharging times and accordingly the amount of electricity and the electromotive force of the component as these between the two electrodes 2 and 3 is displayed, measured at the output terminal 6 and the common

men terminal 7, where the lid or discharge current of the component is used as a parameter in the graphic representation. As shown in Fig. 2, the following operation is intended to clarify that the electromotive force of such a device as a cell indicates the value which depends on the activity of the silver in the Ag-Te alloy of the cathode 3 that the activity of silver varies over a wide measuring range by any slight charging or discharging when the atomic mixture ratio of silver and tellurium within the Ag-Te alloy approaches 2, and that the relationship between the above-mentioned electromotive force and the charging or Discharge electricity quantity / ■ /, where / is the flowing current and t is time, usually indicates a linear relationship during the charging or discharging period, in the case that the electromotive force changes only in a relatively low voltage range (from 0 up to 100 mV according to the embodiment in FIG. 2) and in the event that the current density is relatively low (less than 100 μΑ / cm ² also according to the embodiment in F Fig. 2). In this connection it should be emphasized that the application of a given voltage to the device for either charging or discharging actually causes a constant current to flow through the element and therefore the said linear relationship is between the clamping voltage of the element and the charging and discharging time usable.

It has also become known that this element has an additional characteristic because of the voltage applied before the The current was established directly, even after the current was switched off, with the being sent to the element applied voltage in the above voltage range (between 0 and 100 mV according to the design in Fig. 2) must be.

It is understood that the component described with reference to FIG. 1 has two connection chambers 5 and 6 jointly led to the cathode 2,

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a clamping voltage is applied to the element. It should be repeated that the element shown in Fig. 1 as a cell can be viewed as previously explained. In the case of such a component, which has a common cathode for power supply and for displaying the terminal voltage, therefore the displayed output voltage corresponds as a whole to the electromotive force of the element and an overvoltage of the element as a cell. This results from the fact that the beginning of the Current flow or the interruption of the same within the element has an influence of the overvoltage exerts on the displayed voltage and therefore the output voltages applied to the element directly in front and can be measured after the change in the electrical current state, are different. This means that the voltage holding characteristic of the element is lowered. It was found, that this reduction in the stress retention characteristic is exacerbated by the fact that an increasing current for charging and discharging the element causes a greater overvoltage, which results in an inaccurate vote. For this reason it is desirable to have an improved To produce a stress-storing element which eliminates the above problem.

The overvoltage as found in electrochemical

voltage-storing elements occurs, which a voltage drop after interruption of the current flow caused in the element can be classified as follows:

1. A voltage drop caused by the current flowing through the resistor due to of the solid electrolyte of the cell is present (or as an ohmic voltage drop via the resistance within the electrolyte).

2. An overvoltage caused by dissolution or Deposition of Ag in an interface between the electrolyte and the anode or the cathode.

3. An overvoltage caused by the diffusion of Ag ions into the anode.

3 shows a schematic cross section through an improved electrochemically voltage-storing component 30 for eliminating the ohmic voltage drop across the resistor within the electrolyte as described above under 1. and the overvoltage caused by the dissolution or deposition of silver, as described above under 2.. The component 30 according to FIG. 3 is basically characterized by the fact that the element has a secondary cathode 34 which has a connection terminal 6 for sampling the voltage, separately from the above-mentioned cathode 32 which has an input terminal 5 for the power supply. More precisely, the component according to FIG. 3 has in particular a solid electrolyte 31, which consists of Ag ₃ SI, an anode 33, consisting of an Ag-Te alloy, a cathode 32, consisting of Ag and a hip cathode 34, which is also made of Ag exists.

FIG. 4 shows a block diagram of a television receiver embodying the present invention in FIG which the above-mentioned voltage-storing element is used. A typical television receiver is in the right half of the diagram in FIG. 4

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£ \ * £ .vl £ l UIIU ^ IILIiaili / IIIC S ^- 111 tt * l 11 IC «7 A, Cl

Channel selector 21, an intermediate frequency amplifier 23, a video amplifier 25, a cathode ray tube 27 and a control circuit 26. The tuner

_i; or channel selector usually includes a high frequency amplifier, local oscillator and mixer. For the purpose of embodying the present invention, the television receiver channel selector further includes voltage controlled variable resistors connected together to form part of the tuning circuit for the high frequency amplifier and local oscillator, as will be described in more detail below. A typical and preferred voltage controlled variable resistor is now a commercial goal! available voltage-controlled variable capacitor. As described above, such a voltage controlled variable capacitor has a capacitance formed by an interface of a semiconductor diode, the capacitance being a function of the reverse voltage applied to the diode; such a diode is known as a capacitance diode. It should be understood, however, that any type of voltage controlled variable resistor can be used for the purpose of the present invention if available. The control loop 26 of a typical monochrome television receiver has

a sync pulse circuit, vertical and horizontal deflection circuits, a high voltage circuit or the like, which is necessary for the operation of the cathode ray tube 27. If the present Invention is applied in a color television receiver, the control circuit 26 can further additional, have circuitry necessary for receiving the color television signal.

Thus, in the left half, FIG. 4 shows an embodiment of an automatic tuner which is contained in the television receiver described above. To briefly mention, the auto tuner shown begins auto-tuning by manually turning on a switch, thereby charging or discharging the voltage storage element, and as a result, the variable voltage across the element is adjusted to the voltage controlled variable capacity at * nptpnt Hio with yl * "" Ahctimittlrpicpn in Hpm to charge-discharge circuit 12, causing circuit 12 to reverse the charge or discharge mode of operation.

The operation of the embodiment in Fig. 4 will be better understood from the following description with simultaneous reference to FIG. 5, which shows the relationship between the various parts in FIG Fig. 4 shows occurring voltages and the time course. To explain how the execution works

m in Fig. 4, it is first assumed that only the upward-scanning switch 11 U has been operated manually. Also assume that no television signal has been transmitted in any channel. Fig. 5 (a) shows the relationship between the

i) input clamping voltage of the voltage-storing element 13 and the time during the operation of the device according to the invention in such a situation Wpnn rlrr upwards ahtastrnrlp Srhaltt'r

Channel selector is connected until one of the broadcast channels is selected as a result of the voting within the channel selector when a tuning output is obtained in the form of an intermediate frequency signal from the intermediate frequency amplifier, which is used to charge and discharge the voltage-storing Elements, which automatically selects a TV channel. Another detailed description of what is shown automatic tuner is described below with particular reference to the right half of FIG. 4 given.

Looking again at Fig. 4, the automatic tuner contains a manually operated switch 11 for starting the scanning of the television channels, the switch having an upward-scanning switch 11 U and a downward-scanning switch HD, both switches having a positive voltage source + B are connected. A charge / discharge control circuit 12 is used to control the charging or discharging process of a voltage-storing element 13, namely as a function of an output signal originating from the switches HU or HD and a canceling signal originating from an output of the intermediate frequency amplifier, which is described below. An output of the voltage-storing element 13 leads to a DC voltage amplifier 14. An output of this amplifier 14 is led via a gate 18 to the channel selector 21 and at the same time via an inverter 19 and a gate 20 to the channel selector 21 as well. In the channel selector 21, the output signal, originating from either gate 18 or 20, is routed to the voltage-controlled, variable, reverse-biased capacitor, which is described in more detail below. Simultaneously, an output from amplifier 14 is fed to a lower threshold indicator 15 and an upper threshold indicator 16 so that the output, either from detector 15 or 16, flip-flop in response to a given lower or upper threshold of the output from amplifier 14 17 can set or reset, due to a diode connection. A reset pulse of the flip-flop 17 is passed to the gate 18, whereby the amplified voltage signal can pass the gate 18; a setting pulse of the Fl ^; P-flops 17 is directed to gate 20, whereby the amplified and reversed voltage signal can pass through gate 20 to channel selector 21. The reset pulse of the flip-flop 17 becomes simultaneous

HU has been manually operated, to put it more precisely, the charging / discharging circuit 12 is enabled to enter the charging mode, whereby the voltage-controlled element 13 is charged, as has been explained in detail in the present application. A change in the voltage at the starting point of the element 13 is shown in Fig. 5 a, from the point of origin α to point b. If the element 13 is kept in the charging process, the element 13 would be destroyed due to overcharging. However, in the present embodiment, an output signal from the DC voltage amplifier 14, which corresponds to the voltage of the element 13 at point b , but has been amplified by the amplifier 14 and reversed, is threshold-indicated by the lower threshold indicator 15, whereby the flip-flop 17 is set will. Therefore, no output reset pulse from the flip-flop 17 passes through the connection 104 on the charge / discharge control circuit 12, so that the control circuit 12 is switched to the discharge mode, which in turn discharges the voltage-storing element 13, as has also been explained in detail in the present application is. The change in the voltage at the starting point of the element 13 during this time is shown in FIG. 5 a, from point b to point c. In the embodiment shown, there is an output signal from the DC voltage amplifier 14 which corresponds to the voltage of the element 13 at point c , but has been amplified by the amplifier 14 and reversed. determined by the threshold by the upper threshold indicator 16, whereby the flip-flop 17 is reset. The reset pulse of the flip-flop 17 is passed through the connection 104 to the charging / discharging circuit 12, so that the latter is in turn controlled into the charging mode. The same process as described above is then repeated. FIG. 5 b shows a change in the voltage at the output of the DC voltage amplifier 14, the points a ', b' and c ' corresponding to the points a, b and c with respect to the diagram of FIG. 5a.

From the foregoing description it can be understood that within a period of time of the loading process a set pulse from flip-flop 17 serves to open gate 20; within a time period During the discharge process, a reset pulse from the flip-flop 17 serves to open the gate 18. Therefore, during the discharging process, an output signal from the DC voltage amplifier 14

Pass through the gate 18 to the channel selector 21. An output from gate 18 is shown in Fig. Sc. on the other hand, an output signal from amplifier 14 after it is during the charging process was reversed by the inverter 19, pass through the gate 20 to the channel selector 21. An output signal from gate 20 is shown in Fig. 5d. As a result, the channel selector 21 receives a combined output signal, originating from ports 18 and 20, the waveform thereof being shown in Figure 5e.

As just described, the combined output signal in the channel selector 21 is applied to a voltage controlled variable capacitance which is connected to the selection circuits of a high frequency amplifier and a local oscillator. It is now understandable that it is necessary to switch the voltage range (Kl to Vl) as in Pin ^ np7piot 711 u / bhtpn iinrl ύμι-άτ Hpropctalt HaR Hpr

Said range is sufficient to cover the voltage values, Or are required to obtain all television channels when using the channel selector 21, specifically when using the said voltage-controlled variable capacitance to which the voltage values are applied. It should be emphasized that the voltage values shown in FIG. 5 correspond to the frequencies of carrier waves from television channels CWl, C7 / 2, CHl ... CHn .

Now assume that some television stations broadcast using different channels in a certain area. It is also assumed that the voltage-storing element 13 has been discharged to the point α. If the upward-scanning switch HU is now operated manually, the automatic tuner according to the invention is placed in the loading mode or in an upward-scanning mode. If a voltage at the starting point of the voltage-storing element 13 coincides with a frequency of the carrier wave in which a television signal has been sent, the channel selector automatically selects the frequency and selects the channel, so that an intermediate frequency signal is generated at the intermediate frequency amplifier 23 and an output signal from Level display circuit 24. The output signal of this display circuit 24 is fed to the charge / discharge control circuit 12 in order to switch it off, so that the charging process is then interrupted. This state produced in this way is retained unchanged, which is why the voltage of the voltage-storing element 13 remains unchanged until another manual actuation of the switch HU takes place. After such a manual operation of the switch 11.1 / the charging / discharging circuit 12 is again forced to switch to the charging mode, so that the television stations are scanned in the manner described above from the lower frequency channel to the higher frequency channel until another, now transmitting channel through the channel selector 21 is selected. When the voltage applied to the channel selector reaches the value V2 , the state of the flip-flop 17 is changed, so that the charge / discharge circuit 12 is controlled in the discharge mode. In the embodiment shown here, however, a live path is routed from gate 18 to inverter 19 and to gate 21 within the discharge time as a function of the output signal from flip-flop 17. This causes the selection process to run again from the lower frequency channel to the higher frequency channel, even within the discharge process after manual actuation of the switch 11 U, which will be described in more detail below.

In the foregoing description it was assumed that only the up-scanning switch ⁵ ILL / had been operated. This switch 11 U should be designed in such a way that it enables the control circuit 12 to be in the charging mode during the charging time and in the discharging mode during the discharging time. It will be understood that the up-sampling switch 11t / is only used to set the circuit 12 in the loading process, ie in a process in which the sampling takes place from the lower frequency channel to the higher frequency channel. In the embodiment shown, a downward-scanning switch HD is also provided. The down-sampling switch HD should be designed so that the circuit 12 is in the discharge process during the

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Discharge period is in the discharge mode. It

- '"it is understandable that the down-scanning switch 11D is only used to switch the control circuit 12 into the set down-scan mode, d. H. in a mode in which the sampling of the higher frequency channel happens to the lower frequency channel.

- ^v > In a different embodiment, one of the switches HU or HD can be missing, so that the scanning can only be carried out in one direction. In a further embodiment, the output signal from the DC voltage amplifier 14 can be fed directly to the channel selector 21. It is easier to understand that in such an embodiment the manual actuation of the switch 11 U results in a sampling from the higher frequency channels to the lower frequency channels within the charging process

> ^r > and from the lower frequency channels to the higher frequency channels within the discharge process, while manual actuation of the switch HD causes scanning from the lower frequency channel to the higher frequency channel during the charging process and from the higher frequency channel to the lower frequency channel during the discharge Process.

In the previous description, provided that that the range of variable capacity

• * ^r > of the voltage controlled variable capacitance diode is sufficient to cover the corresponding frequency range of the VHF television channel No. 1 to No. 12 of the Japanese television standard. In reality, however, it is quite difficult

5 »the entire frequency range for all VHF television channels by using a channel selector to mask that is a typical voltage controlled has variable capacitance diodes that are now commercially available. Therefore the one shown contains Embodiment also has a circuit for automatically switching the channel selector 21 to on lower frequency channel band, d. H. on channels 1 to 3, or on a higher frequency channel band, d. H. to channels no. 4 to 12. Such a band

w) rich switching circuit includes an inverter 29, the is connected to the flip-flop 17 and to a supply line 200 which leads to the channel selector 21.

To describe the circuit it is assumed that the channel selector 21 is currently in the lower fre-

t> 5 frequency channel band from a lower frequency to a higher frequency samples. In this situation, the flip-flop 17 is reset, as described above became. Therefore a reset failure

output pulse from high level to inverter 29, creating a reverse output pulse with low level from the inverter 29 to the channel selector 21 via the line 200. Channel selector 21 is constructed so that this low level pulse on line 200 will channel selector 21 made to work in the lower frequency channel band. When the voltage-storing element 13 is loaded to a higher value, an inverted and amplified output signal from the amplifier 14 is indicated in terms of thresholds by the lower threshold detector 15, which sets the flip-flop 17, whereby the signal path via the gate 18 is changed in the signal path via the inverter 19 and the gate 20, at the same time a reversed output signal with a high level is fed from the inverter 29 to the channel selector 21 via the line 200. That from The high level output from inverter 29 forces the channel selector 21 to operate in the higher frequency channel band. The channel scan is thus carried out from a lower frequency to a higher frequency within the high frequency channel band due to the interposition of the inverter 19, although the voltage storage element 13 is discharged during this time period will. When the voltage-storing element 13 is discharged to a lower limit value, a inverted output signal amplified by amplifier 14 is thresholded by the upper one Threshold detector displayed to reset flip-flop 17, changing the signal path via inverter 19 and gate 20 to gate 18, and at the same time, there becomes an inverted low level output from the inverter 29 to the channel selector 21 via line 200. So there is a full cycle of channel selection in both Cases relating to the lower frequency channel band and the high frequency channel band completely.

Fig. 6 shows a block diagram of a television receiver equipped with a preferred embodiment of the present invention which uses the voltage storage element described above. The embodiment shown in FIG. 6 has an automatic frequency control in addition to that in FIG Fig. 4 shown embodiment. Therefore, the same parts, which correspond to the embodiment according to FIG. 4, denoted by the same reference numerals. Therefore, only one additional implementation will be described in the following, while a detailed description of the same parts according to the embodiment from Fig. 4 is omitted. With reference to the lower part of the block diagram in FIG. 6, the embodiment shown additionally has a frequency detector 42, such as B. a ratio detector which is connected to the intermediate frequency amplifier 23 to the To demodulate the frequency of the intermediate frequency output, the embodiment also has a Circuit 40 which generates a charge / discharge control signal and is connected to the frequency detector 42 is to generate a charge / discharge control signal for the circuit 12 in accordance with the output signal from the frequency detector 42, there are further bandpass filters 47 and 48 for selective Raising the sound and video components of the intermediate frequency output from amplifier 23, des further a level detector 49 for the simultaneous detection of the level of the sound and the selected video, and an AND gate 41, which is based on the output signals from the signal generator 40 and the level detector 49 responds to generate a clear signal to interrupt the control circuit 12.

It should first be assumed that during the

The selection circles within the channel selector 21 have selected exactly the frequency of a desired channel. The sound and the video components of the intermediate frequency output signal from the amplifier 23 can pass through the bandpass filters 47 and 48 they are sufficient to be detected by the level detector 49 according to their level, so that the simultaneous detection of both the sound and the video components is an output signal generated on line 102 of level detector 49.

On the other hand, the intermediate frequency output from the amplifier 23 is displayed in terms of frequency by the frequency detector 42 and, if the intermediate frequency output signal has exactly the frequency, then an output signal on a line 101

- ° of the output from the signal generator 40 received. Because of this, the AND gate 41 becomes conductive and generates an output signal on line 103 of gate 41, which is sent to control circuit 12 as a clear signal is performed so that within the control circuit 12 the charging or discharging process of the voltage-storing element 13 is interrupted. As a result, a DC voltage value corresponding to the voltage controlled variable capacitance is given within the channel selector 21, unchanged on one

-W held the desired fixed value. It is now assumed that a slight detuning occurs within the channel selector 21. Because of this mentioned Detuning within the channel selector 21 fluctuates the frequency of the intermediate frequency output signal from amplifier 23, whereby an off output signal from the frequency detector 42 is changed, in such a way that on the line 101 of the output of the signal generator 40 no output signal appears more, whereby on line 103 of the

^ o Output of the AND gate 41 no clear pulse is generated and therefore the control circuit 12 starts up. On the other hand, it causes fluctuation the frequency up or down that the signal generator 40 a discharge or charge control signal

«Of the line 100 generated, whereby the control circuit 12 is set in the discharge or charge mode, so that the voltage-storing element 13 is discharged or is loaded, 'which depends on whether the frequency of the intermediate frequency output is up or down

so fluctuates. When discharging the voltage-storing Element 13 decreases the voltage at the output thereof, whereby the frequency of the intermediate frequency output becomes lower, whereas a charging of the voltage storage element 13 the voltage can grow at the exit of the same, whereby the Frequency of the intermediate frequency output becomes higher. When the channel selector 21 is set exactly again and therefore the intermediate frequency output of the exact frequency is obtained from amplifier 23, so again appears from the AND gate 41, a clear pulse, so that the loading or unloading of the Element 13 within the control circuit 12 is interrupted. As a result, it becomes such an automatic Receive frequency control, and this precise

b ^r > select can be applied in an automatic manner within the automatic tuner according to the invention which has a voltage controlled resistor in connection with that described above

voltage-storing element used.

In the embodiment of Figure 6, both the audio and video components are within the intermediate frequency is raised by bandpass filters 47 and 48, and a level detection takes place at the same time the same instead of for the purpose of deleting the charge / discharge control circuit 12. Such simultaneous Level detection of two components within the intermediate frequency is preferred with regard to the fact that the intermediate frequency output contains these two components. If only the video component would be used for the purpose of deleting the control circuit 12, it could happen that the Sound component is erroneously used to interrupt the control circuit 12, whereby a detuning could occur. It will be understood that in the embodiment shown in FIG simultaneous detection of the audio and video components is preferably obtained within the level detector 24 to provide a clear signal on line 103. Alternatively, however, the simultaneous Detection of the sound component and a sync output pulse or simultaneous detection of the Video component and a synchronization output pulse to shutdown the control circuit 12 used will. Such a synchronization output pulse can either be a horizontal synchronization pulse or be a vertical sync pulse generated by a sync pulse circuit of a typical TV receiver is available.

7 shows a detailed schematic diagram of the manual switch 11, the charge / discharge control circuit 12 with the voltage-storing element 13 and the DC voltage amplifier 14 according to FIG. 6. As can be seen from the circuit diagram, the manual depression of the switch 11 causes U setting the flip-flop FFl and resetting the flip-flop FFl; Depression of the manual switch 11 U causes the flip-flop FFl to be reset and the flip-flop FFl to be set. The line 100 comprises two feeds 120 and 121, which originate from FIG. 10, which is described in more detail below. When the device scans the lower channel band, ie channels 1 to 3 in the case of the Japanese television standard, the output level on the line 104, originating from the flip-flop 17, is low. As will be described later, both outputs on lines 120 and 121 are high as long as the displayed frequency is outside the frequency range within which the automatic frequency control is operating. If, therefore, the switch 11 U is depressed in such a situation, the output signal, originating from the flip-flop FFl, has a lower level, and accordingly the output signal from the AND gate 1 has a low level. On the other hand, the output of the flip-flop FF2 also has a low level. so that all inputs of the OR gate ORl have a low level and therefore the output from the inverter INVl has a high level, whereby an output signal from the OR gate ORl also receives a high level, so that a transistor 77-71 is turned on. In this situation, a transistor TRIl is switched off, so that the collector of the same has a high voltage drop and therefore a transistor TRTi is switched on. As a result, a charging current flows through the voltage-storing element 13 from the anode 33 to the cathode 32 via a resistor RlX and the transistors ΓΛ73, TRIl, in the direction as shown in a dotted line in FIG. 7, however, the switch UD depressed, se the flip-flop FFl is reset, so that the touching output pulse has a high level, which is fed as an input to the AND gate ANDl . It is assumed, however, that one of the dei

• o inputs of the gate ANDl via the line 104 receives a low level. Therefore the output of the AND gate ANDl has a low level (the AND gate is blocked). A high-level output signal is obtained from the flip-flop FF2, whereby the output of the OR gate OR1 is also given a high level, so that an output signal with a low level through the OR gate ORT. is led to transistor ΓΑ71. Accordingly, the transistor 7V? 71 is switched off, whereby eir

-?.. "Discharge through the spannungsspeichernde element 13 from the cathode 32 to the anode 33 via a resistor Λ72 and the transistor 77 of the direction indicated in dei Figure 7 by a solid line 73 flows Depression of either switch 11 U or 11 D thus mixed the control circuit 12 ir the charge or discharge mode, whereby the channel selector is scanned accordingly.

It is now assumed that a receiving channel is selected by the channel selector 21 in such a situation. As a result, a clear signal with a high level is generated on line 103, as just described, which is applied to an AND gate AND1 . The output signals on lines 120 and 121 are high during the time

J5 in which the channel selector 21 approximately selects. Therefore, all inputs to the gate ANDl are high, so that the output pulse from the AND gate ANDl also has a high level, whereby the transistor TÄ72 is switched on. The pulling of current on transistor 77-72 causes a negative voltage - V to be applied to the gate electrode of transistor TRTh across the emitter of transistor 77-72, so that transistor 77-73 is turned off, which in turn causes another charging.

*> or the discharge process of the voltage-storing element 13 is interrupted. Depression of either switch 11 U or HD causes an output from OR gate OR3 to be high, which is shown on line 135 in the diagram

5 ″ of FIG. 10 in order to reset a flip-flcp within FIG. 10, which is described below. Similarly, depressing either switch gate 11 U or HD causes an output from the OR gate ORA with a high Pe-

">'. gel, the output signal being inverted by an inverter INVi to apply an inverted low level output to the transistor TRIl so that the transistor TRIl is switched off, which is why the transistor TRTh is switched on as long as either the switch HU or HD is depressed. In this way, an = enable application of the oR gate oR 4 and the inverter INVi that a user can select the channels sequentially as desired as long as he the

h> Holds the switch down.

8 shows a more detailed circuit diagram of the lower threshold detector 15, the upper threshold detector 16 and the flip-flop 17. The lower threshold

Value switch 15 contains a pair of transistors TRHl and 77-82, which are connected together to form a Schmidt circuit, and resistors Ä81 and Λ82 as inputs of the Schmidt circuit. The resistance ratio of these resistances is chosen to set the lower threshold. In the same way, the upper threshold switch 16 contains a pair of transistors 77-83 and 77784, which are also connected to form a Schmidt circuit, and resistors 7283 and /? 84 as the input circuit of the Schmidt circuit, the resistance ratio of these resistors being selected in this way to set the upper threshold. The inputs of the threshold value switches 15 and 16 are connected to the output of the DC voltage amplifier 14. The output of the threshold value discriminators 15 and 16 is led to the flip-flop 17, which is implemented by a pair of transistors TRS6 and 77-87, which are connected to one another in a known manner. The output of half a stage of the flip-flop including the transistor 77-86 is connected to the gate 18, and the output of the other half stage of the flip-flop 17 is connected to the gate 20, as well as to the control circuit 12. Das The circuit diagram in FIG. 8 also contains the inverter 29, which has been explained in connection with the circuit diagram in FIG. The inverter 29 consists of a transistor 77-89, the line 200 leads away from the collector of the transistor 77-89.

Fig. 9 is a detailed circuit diagram showing the gate 18, the inverter 29, the gate 20, the channel selector 21 and the intermediate frequency amplifier 23. The gates 18 and 20 will r realized by field-effect transistors 791 and T93, the inverter 19 is a typical bipolar transistor 19. The gate connections of the transistors 791 and 793 are connected to the output of the flip-flop 17. The outputs of these gates 18 and 20 are connected to the channel selector 21 via a DC voltage amplifier / 490. The channel selector 21 comprises a first tuning circuit TK 1 for a high-frequency amplifier and a second tuning circuit TK1 for the local or local oscillator. The tuning circuits TKl and TKI each contain a voltage-controlled variable capacitance diode VCl and VCl as part of a capacitive element of the tuning circuit and the output of the DC voltage amplifier / 490 is placed in the reverse direction on these capacitance diodes. A DC voltage switching signal is applied through the switching diodes D91 and D91 to the center taps of the coils in the tuning circuits TKl and TKl in order to reduce or increase the inductance of these coils in the tuning circuits TKl and TKl , i.e. by the frequency that is processed in the channel selector 21 to change from a higher value to a lower value, so that both the higher frequency channels and the lower frequency channels can be covered by a single set of coils, as has been explained in connection with the circuit diagram in FIG. A more precise knowledge and mode of operation of the channel selector 21 does not need to be given, but is known. In short, a higher output voltage from the amplifier / 490 biases the capacitance diodes KCl and VCl more in the reverse direction, as a result of which the capacitance at the junctions of these diodes decreases, with the result that a higher tuning frequency of the tuning circuits TKl and TKl and vice versa is achieved. When received in the low frequency channels, there will be a signal

with a low level (L signal) placed on line 200, which is why switching diodes D91 and D92 remain blocked. When receiving the higher frequency channels, however, a signal with a high level (H signal) is applied to line 200, whereby the diodes Ö91 and D92 are polarized in the flow direction and switch through, so that the lower half of each coil of the tuning circuits TKl and TKl through a Direct current are short-circuited, which flows through the diodes D91 and D92 and through the lower coil half, with the result that the inductance of the coils of the tuning circuits is reduced and the tuning frequency of the tuning circuits is raised in the direction of a higher frequency channel. The intermediate frequency amplifier 23 is also known as belonging to the prior art, for which reason it does not need to be described in more detail. It should be emphasized that the three lines 105, 106 and 107 lead away from this.

Fig. 10 shows a more detailed circuit diagram of the frequency detector 42, the circuit 40 for generating the charging ZEntladesieuersignais, the bandpass filters 47 and 48, the level detector 49 and the AND gate 41. A detailed description of the circuit diagram in Fig. 10 is made simultaneously with Description has been given of the diagrams in FIG. 11 which graphically represent the relationship between the magnitude of the signals in various parts of the circuit diagram of FIG. 10 and the frequency of the signals. The frequency detector 42 receives the intermediate frequency output signal from the intermediate frequency amplifier 23 via the line 105 and is used to deliver the same or symmetrical small output signals at both outputs 113 and 114 if the frequency of the intermediate frequency output signal has a certain value, and the frequency detector 42 is also used to detect asymmetrical To generate output signals at both outputs 113 and 114 if the frequency of the intermediate frequency output signal deviates from this predetermined value. More precisely, the frequency detector 42 generates a higher output voltage at the output 113 and a lower output voltage at the output 114 when the frequency of the intermediate frequency output signal deviates towards a frequency which is higher than the predetermined value and generates a lower output voltage at the output 113 and a higher one Output voltage at the output 114 _S when the frequency of the intermediate frequency output signal deviates towards a frequency which is less than the predetermined frequency value. A known ratio detector can be used as the frequency detector 42. Fig. 11c shows a characteristic curve of such a ratio detector. The outputs 113 and 114 are connected to points A and B of a bridge circuit 115 which contains a pair of diodes 111 and 112 and a pair of transistors 116 and 117. A connection between the cathode of diode 11.1 and the base of transistor 116 together form branch point A, and a connection between the cathode of diode 112 and the base of transistor 117 together form branch point B. A resistor is between the connection of the cathodes of diodes 111 and 112, whereby this connection point is grounded, furthermore the emitters and transistors 116 and 117 are connected to one another. The collectors of transistors 116 and 117 are across in

Reverse polarity diodes 118 and 119 are connected to leads 120 and 121, referred to collectively in FIG. 6 as line 100, so as to generate an automatic frequency control signal which is referred to as the charge / discharge control signal in the description in connection with FIG The collectors of transistors 116 and 117 are furthermore connected via lines 122 and 123, which have been combined as line 101 in the description with respect to FIG. 6, to diodes 124 and 12S, which together with a further diode 126 form the AND- Form gate 41. The audio bandpass filter 47 for selecting the audio component and the video bandpass filter 48 for selecting the video component, which receive the intermediate frequency signal supplied via the lines 106 and 107, are connected to a audio level detector 129 and a video level detector 130 of the level detector 49. The sound level detector 129 can be a Schmidt circuit consisting of the transistors 7101 and TL02 with an input circuit consisting of resistors for setting a detection level, and the video level detector 130 can also be a Schmidt circuit with the transistors 7103 and 7104 with an input circuit, Consists of resistors to determine the detection level with regard to the video signal. The output signals originating from the level detectors 129 and 130 are applied to the cathodes of the diodes 131 and 132, which together form an AND gate 133, the output signal of which is applied to the flip-flop 134, which is triggered by a signal via the line 135 from Gate ORZ in the circuit diagram in FIG. 7 is reset. The output of the flip-flop 134 is connected to the diode 126 of the AND gate 41. The characteristics of the band pass filters 47 and 48 are shown in Figs. 11a and 11b, respectively.

In operation, automatic channel selection begins in response to the manual actuation of manual switch 11 (in Fig. 6) as explained earlier so that the audio and video components of the intermediate frequency output are passed by band pass filters 47 and 48, respectively, when A certain transmission channel was selected by the channel selector 21 on the basis of the application of an associated voltage which is connected to the clamping voltage of the voltage- storing element to the voltage-controlled varactor diodes VCl and VCl (in FIG. 9). As can be seen from FIGS. 11 a and 11 b, the levels of the output signals from the bandpass filters 47 and 48 are higher, the more precisely the voltage hi applied to the diodes KCl and VC2 , which is why the intermediate frequency approaches the specified value closer. When the level of the output signals of the band-pass filters 47 and 48 exceeds the stages P and Q in FIGS. 11 a and 11 b, the transistors 7101 and 7103 of the first stage of the level detector 129 and 130 respectively turn on, which is why the transistors 7102 and 7104 of the second stage of the level detectors 129 and 130 are inhibited, respectively, so that the output signals of the level detectors 129 and 130 have a high level. As a result, the diodes 131 and 132 of the AND gate 133 block and the anodes of the diodes 131 and 132 become H, which means a high level output or an AND output signal at the AND gate 133. Due to this, the flip-flop 134 is set, which originated H. If the intermediate frequency exactly matches the predetermined value, then fluctuating or the same but very small output signals are obtained from the frequency detector 42, so that both transistors 116 and 117 block and thus generate an H output signal on lines 122 and 123, which together with the H output signal of the flip-flop 134 through the AND gate 41 and this output signal of the AND gate 41 is fed via the line 103 as a clear signal, as it has been explained in more detail in connection with the circuit diagram in FIG.

It is now assumed that for some reason the intermediate frequency has drifted to a lower or higher value. Then, corresponding to the higher level on the line 113 and the lower level on the line 114 in the first case and the lower level on the line 113 and the higher level on the line 114 in the latter case, an unbalanced output signal between the lines 113 and 114 get io that in the first case the transistor 116 and in the latter case ^p al! the transistor 117 turns on, with the result that the voltage at the collector of the conductive transistor largely drops to ground potential. In the first case, therefore, diode 118 turns on and a charge control signal is received on line 120; in the latter case, diode 119 turns on and a discharge control signal is received on line 121.

In any case, however, an unbalanced output signal is obtained between lines 122 and 123, so that line 122 becomes L in the first case and line 123 also becomes L in the latter case, with the result that there is no input condition at AND gate 41 and therefore no clear signal is received from this gate 41. As set out in more detail in the previous description with respect to FIG. 7, the charge control signal on line 120 forces control circuit 12 into the charge mode

^{4 (1} , which is why the voltage-storing element 13 is charged, whereas the Entladestei'crsignal on the line 121 forces the control circuit 12 to go into the discharge mode, which is why the voltage-storing element 13 is discharged.

^Vi When the voltage-storing element 13 is charged or discharged, the output signal, originating from the element 13, becomes higher or lower, which is why the intermediate frequency is raised or lowered. When the intermediate frequency approaches the predetermined value, the output signal from the frequency detector becomes symmetrical and small, which is why the bridge circuit 115 is balanced so that both transistors 116 and 117 block. As a result, no control output is sent to the

"Lines 120 and 121 received while a clear signal appears on line 103 so that another Loading of the voltage-storing element 13 of the control circuit 12 is interrupted.

The following is a more detailed description

^{b ()} the advantages of the need to be given by simultaneous level determination of two components, so z. B. the audio and video component of an intermediate frequency output signal, for the purpose of obtaining a cancellation signal. For example be that

^b '< fourth channel of the television channels of the Japanese television standard. The frequency of the video carrier wave (FV ") is 171.25 MHz and the frequency of the audio carrier wave (Fs) is 175.75 MHz for the

fourth channel. If therefore the frequency of the local oscillator (Fo) becomes 230 MHz, the intermediate frequency (video) of 58.75 MHz will be in agreement due to the difference between Fo and Fv obtained with the following equation.

Fo - Fv = 230 MHz - 171.25 MHz = 58.75 MHz.

On the other hand, when the frequency of the local oscillator (fo) becomes 234.50 MHz, so a pseudo-video intermediate frequency of 58.75 MHz is obtained by means of subtraction between Fo and Fs in accordance with the following equation.

Fo - Fs = 234.50 MHz - 175.75 MHz = 58.75 MHz.

selector next to the desired correct frequency of the channel is selected. However, if, as in the As shown in the present embodiment, an output signal of the same level of both the audio and video components the intermediate frequency is used, d. H. the logical output product of the audio and video intermediate frequencies, thus, a clear signal for the charge / discharge circuit is generated, and therefore the above disadvantage can thereby be eliminated will. As previously pointed out, a synchronization pulse can also be used instead of either the audio or video component of the intermediate frequency output signal the fact that a sync pulse is only obtained when the frequency is exactly from Channel selector has been selected.

In the preceding description, the explanations were only given with regard to a television receiver

system is designed in this way. that a cancel signal only in response to the video component of the intermediate frequency is obtained, it can happen that a unwanted frequency erroneously identified by the invention in connection with each Device that contains a tuner can be embodied, such as B. in amplitude or frequency modulated Radio receivers and the like.

On this ^l ) sheet of drawings

Claims (12)

Patent claims: 1. Automatic tuner, characterized by an electrochemically voltage-storing one solid component (1,13,30) with a cathode (2,32) with a solid metal, with a Anode (3.33), which contains an alloy of this metal and a foreign body electrolyte (4, 31) with high ion conductivity, which is sandwiched between the cathode and the anode is, wherein the voltage-storing component is a clamp between the anode and of the cathode, which has a linear function of the component supplied or removed from it The amount of charge is, depending on whether the anode is positive or negative, a control device (12) for controlling the cathode of the component to a Generate current in a desired direction through the same, thereby enabling selective charging or discharge of the voltage-storing component occurs, a tuning device (21) with a voltage-controlled variable reactance ( VC \, VCl) to which the clamping voltage of the voltage-controlled component can be applied, a tuning frequency of this tuning device depending on the clamping voltage of the voltage-storing component, Coupling elements (23) for the voting device to provide an indicator signal for the degree of voting to generate the tuning device and Circuits (24, 40, 41, 42, 49) for the tuning display signal of the tuning device Interruption of the current flow through the voltage-storing component and thus for the interruption the loading or unloading process of the same. 2. Automatic tuner according to claim 1, characterized in that the cathode of the voltage-storing Element (30) consists of a main cathode (32) consisting of active metal and an auxiliary cathode (34), the Auxiliary cathode also consists of active metal and with the voltage controlled variable reactance connected is. 3. Automatic tuner according to claim 1 or 2, characterized in that the cathode (2, 32, 34) of the voltage-storing component (1, 13, 30) consists of silver and the anode (3, 33) consists of an alloy of silver and a chalcogenide element. 4. Automatic tuner according to claim 1, characterized by a switching device (11) for starting the charging or discharging process of the voltage-storing element (1, 13, 30) consisting of two manual switches (lit /, HD), which have two flip-flops (FFl, FFl) and an OR gate (ORl, ORl) are connected to the voltage-storing element (13). 5. Automatic tuner according to claim 1, characterized by a threshold value detector (15,16) which when a certain value of the clamping voltage of the voltage-retaining device is reached Element emits a signal to control the power supply of the voltage-storing Elements to change how it is loaded or unloaded. 6. Automattscher tuner according to claim 5, characterized in that for changing the Direction of the charge or discharge current of the voltage-storing element in a discharge or charging current of the same the voltage of the element a lower and an upper Threshold detector (15, 16) is supplied, which are connected to a flip-flop (17), wherein an output of the same is connected to the control device (12) and the change in Clamping voltage of the element in turn is given up on the variable reactance. υ 7. Automatic tuner according to claim 1, characterized characterized in that the circuitry for generating an erase pulse for interruption the charging or discharging process of the voltage-storing element a frequency de- - have ⁿ tcktor (42), whose output signa! for controlling the control circuit (12, 13, 21, 23, 42, 40, 49, 41) containing the voltage-storing element, the charging or discharging process of the element being dependent on the direction of the swan - '"> depends on the frequency displayed. 8. Automatic tuner according to claim 7, characterized in that for generating the Erase pulse to interrupt the charging or discharging process of the voltage-storing i'i elements two components of the intermediate frequency output an intermediate frequency amplifier (23) can be used. 9. Automatic tuner according to claim 1, characterized in that the tuning device '' ■ lung (21) a channel selector for a television receiver is. 10. Automatic tuner according to claim H and 9, characterized as there! ' at least one of the two components is the video component ■ '"of the intermediate frequency output signal of the intermediate frequency amplifier (23) is. 1 I. Automatic tuner according to claim H and '), characterized in that at least one of the components mentioned is the sound component ■ '"■ of the intermediate frequency output signal of the intermediate frequency amplifier (23) is. 12. Automatic tuner according to claim S. thereby marked. claLi one of the two components is a synchronicity pulse. or that ilic '· "Two components, the sound and the video component are.