DE2319232C3 - Device for switching off television signals - Google Patents

Description

, a lottery ticket *. ·! «.» «. * (230, 238), the one at the Emeangdie Receives video signals and in response to the beginning of each vertical blanking interval of the V, - ao deosignals trigger pulses at their output

'' '! ■ fine first monovibrator (240), whose oneE is connected to the output of the trigger circuit and VerukaltSensignale at its output delivers during its unstable state, which is caused by a trigger pulse triggers and after a set time Art. Which is equal to the length of a Vert.kal-Aus ^

^ta S "wSen monovibrator (260), the input of which is coupled to the output of the separator S 5nd at its output delivers first parts of hori- ■ mnt-il gap signals during its in-S η state, which is triggered by a flank of a separated horizontal synchronizing pulse and after a set time on S if S is equal to the not yet accrued Te of the horizontal blanking interval, in which the said separated Honzontalsynchronisier- * ° ii) a fourth monovibrator (230), the input of which is coupled to the output of the separator and on whose output normal pulses of the same width appear during its unstable state, which is triggered by the leading edge of a separated horizontal synchronization pulse or a separated compensation pulse and stops after a set time equal to the length of a horizontal synchronization

impulse is;

b) a second logic circuit (238), the first input of which is connected to the output of the separator and whose second input to the output of the fourth monovibrator? is coupled and their Output applied to the input of the first monovibrator (240), this second logic circuit is in a first logical state if neither a disconnected at its first input Horizontal synchronization pulse or trigger pulse is still applied to its second input Normal pulse, and is otherwise in a second logic state.

e) a poor. Monovibrator (270), the input of which is coupled to the output of the separator S and fn its exit second parts of Äori / ontal gap signals during semes Stable state is provided by an edge def separated horizontal synchronization pulse is pelleted out and stops after a set time which is equal to the not yet expired Te 'des; Horizontal blanking interval in which 5 « de said separated horizontal synchronizing pulse appears, plus the following B.ld-

Tetne first combination circuit (250) with dre inputs, each of which is connected to a separate d _r drdMonovibratoren (240, 260 270) and whose output has a first logic Signalzusuind when a vertical Lückens.gnal and / ode s first part of the horizontal -Lückens.gnals ud or a second part of the horizontal gap signal are present, and whose output has a specific logic signal state if all these signals are missing, so that the complete gap signals appear at this output

7 device according to claim 6, be. which the separator at its output as a response to A.KPleichsimoulse provides compensating pulses separated in the video signal, characterized by.

The invention relates to devices for processing video signals for the purpose of Switching of television signals in the studio or control room of a television station. The invention relates in particular to a device for switching off television signals, with which the image component of a Video signal can be controllably attenuated without affecting the parts that the synchronizing and Contain color sync information, are disturbed. In television studios or broadcasting systems are common Switching from one video signal source to the other is necessary in order to receive selected television information to broadcast. If the two video signal sources share the same pulse center (i.e. the same generator for the horizontal, vertical and color sync signals) are synchronized, then this switching can be done easily by using a Uniblender. It is coming suggest, however, that the two video signal sources are "out of sync"; H. from different pulse centers can be controlled, for example if the one video signal locally and the other video signal remotely is produced. In such cases, simply switching between the signals is not beneficial because in the entire synchronization information (synchronization pulses and color bursts) from one source can appear in the image information of the other source.

If the pulse center of the transmitting station over Phase-locking loops are synchronized with the remote pulse center, a switchover can occur between such "out of sync" video signals occurs whenever the remotely generated video signal is being sent. Switching from a locally generated to a remotely generated video signal then happens with intermediate switching to a black level source until the pulse center the transmitting station through the phase lock loop

fen has been brought into synchronization with the remote pulse center. A close phase lock between However, a local and distant impulse center can be noticeable for the television viewer taking time to complete, on the other hand there may be slight phase differences between the pulse centers cause the hue of the images provided by one or both signal sources is adulterated.

It is therefore desirable to switch between different video signal sources without changing the respective To synchronize pulse centers with one another so that the problems associated with the phase locking of such pulse centers do not arise. The object of the invention is thus to provide a device which the when Switching the video signals occurring transitional phenomena from the one broadcast to the television subscriber Keeps video signal away.

The invention solves this problem with a facility ao device for switching off television signals, with the characterizing from claim 1 Features.

The invention is explained below with reference to drawings:

Figures 1 and 2 show, in block form and in greater detail, respectively, an embodiment of the invention;

Fig. 3 is a more detailed circuit diagram of the separator shown schematically in Figs. 1 and 2 for Separation of the synchronous information and a Renegerierstufe also shown in FIGS. 1 and 2 to obtain the gap signals indicating the blanking interval:

Fig. 4 is a diagram showing the time relationship between signals in the regeneration stage;

Fig. 5 shows schematically one with the circuit according to Fig. 2 together usable device, which allows an automatic operation in the transmitting station.

Referring to FIG. 1 pass video signals from a television switchgear can come via the input terminals 1 and 3 to the input circuits of an amplifier 5 and a synchronous information-separating separator 7. The output of the amplifier 5 provides a video signal X, which is the first to the Input of an analog multiplier circuit 9 is given.

An analog multiplier circuit has two input circuits for receiving two input signals X and Y and one output circuit for emitting an output signal XY, which is the product of the two S ° input signals. In the present case, the multiplier circuit is an amplifier whose gain factor for X signals is independent of the amplitude of these signals, but can be controlled as a function of a continuous range of y signals.

At the output of the separator 7, separated pulses appear which correspond to the horizontal synchronization pulses and the compensation pulses of the input video signal. These separated synchronization pulses reach the input of a regeneration stage 11. Controlled by the separated synchronization pulses, this stage generates pulses which correspond to the horizontal and vertical blanking intervals of the input video signal. In the following, these impulses are simply referred to as “gap signals”. A switching arrangement 13 receives an adjustable direct current control signal from a source 15 and supplies an output signal Y to the second input of the analog multiplier circuit 9. The gap signals characteristic of the blanking intervals and supplied by the regeneration stage 11 act on the switching arrangement 13 in such a way that they during the horizontal and vertical Blanking intervals supplies a predetermined first output level which causes the analog multiplier circuit 9 to fully amplify the video signals sent through it. During the time between these blanking intervals, the switching arrangement supplies a second level which is dependent on the adjustable direct current control signal from the source 5 and which determines the gain factor of the analog multiplier circuit for the continuous video signals during those image intervals.

The ^} 'signal generated by the analog multiplier circuit 9 is transmitted via the buffer amplifier 17 coupled to output terminal 19. The video signals handled by the device shown in FIG appear between terminals 19 and 21.

The device shown in Fig. 1 for switching off television signals can be in cascade behind a television switchgear to be switched, which is to be broadcast from a large number of available video signals Selects video signal. If you operate the control signal source 15 so that before switching a weakening to black takes place and full attenuation in the analog multiplier circuit is set, while after switching there is a fade in again and full gain in of the analog multiplier circuit 9 is set, then by switching between the Video signal sources caused transient phenomena hidden from a television viewer.

FIG. 2 shows the arrangement shown in FIG. 1 as a block diagram in greater detail. The video signals fed to terminal 100 are amplified in amplifier transistors 106, 110 and by functional amplifier 112. From here antiphase amplified video signals {X) arrive at the input terminals 12 and 9, the analog multiplier circuit 121. This circuit outputs via its output terminals 14 and 2 in antiphase video signals XY to a buffer amplifier 129, which consists of the elements 130-138.

The amplification factor of the device for switching off television signals is determined by the setting of a manually operated potentiometer 139 during the picture intervals. The potentiometers 139, 140 and the resistors 141 and 142 form an adjustable ohmic voltage divider which can supply a control voltage between 0 and +10 volts. This control voltage is applied to terminal 8 of the analog multiplier circuit via the transistor 144 , which is connected as an emitter follower, and the series connection of the resistors 145 and 147 , in order to control its gain factor.

The separator 149 supplies separated synchronization pulses which coincide in time with the synchronization pulses of the video signals supplied to it via the input terminal 100. These separated synchronization pulses reach the regeneration stage 150, which, controlled by these pulses, delivers a positively directed pulse, the so-called "gap signals", during the horizontal and vertical blanking intervals. These gap signals are applied to the base of an emitter grounded transistor 146 . The positively directed gap signals make the otherwise non-conductive collector-emitter stretch "

of the transistor 146 has a very low resistance, as a result of which the terminal 8 of the analog multiplier circuit 121 is clamped to ground, so that the video signals from the multiplier circuit are fully amplified during the blanking intervals. The positively directed gap signals also reach terminal 4 of the analog multiplier circuit 121 via the capacitor 152 and the resistor 154 in order to support the transition of the multiplier circuit to the high-gain state.

The regeneration stage 150 also supplies pulses to the base of an NPN transistor 156 during the horizontal blanking interval. This transistor is located in a circuit 155 for restoring the black level of the input video signals to a steady level after these signals have passed through the coupling capacitor 101. The elements 156 to 164 form a delaying amplifier stage, which delays the pulses from the regeneration circuit 150 somewhat, and during the back porch ao of the horizontal blanking interval (ie that part of this interval which follows the trailing edge of each horizontal synchronizing pulse) sampling pulses to the gate electrode of a field effect transistor 165 supplies.

The video signals at the junction of resistors 104 and 105 pass via the emitter follower transistors 106 and 166, the temperature-compensating diode-connected transistors 168 and 169 and resistor 171 to the base of an emitter follower transistor 172. A series circuit of a coil 173 and a Capacitor 174 is tuned to the frequency of the color subcarrier and removes the color burst (color sync signal) from the rear black shoulders of the video signals appearing at the base and emitter of transistor 172. The field effect transistor 165, which is keyed to be transparent for the duration of the rear porch of the video signals, changes the voltage on the capacitor 180 to a value which corresponds to the black level of the video signals at the emitter of the transistor 172. This voltage is amplified in the functional amplifier 178 and then fed to the input circuit of a voltage comparator 123 , which sends an error signal current back to the connection point of the resistors 104 and 105 in order to correct the black level at this point.

The following table lists the elements that can be used in the circuit according to Fig. 2:

Resistances

102 11 000 Ω

103 9 090 Ω

104 221 Ω

105,147,154, 205 100 Ω

107,124,125, 45,177 1,000 Ω

108 3 160 Ω

ill, 117,118,119,122,133 3,320 Ω

114.115 3 010 Ω

120.123 1500 Ω

126,100,171,191 680 Ω

127 1 200 Ω

132 511 Ω

134 200 Ω

136 432 Ω

142 619 Ω

151,170,185 10,000 Ω

157.189 2,200 Ω

161.162 3,300 Ω

5 °

55

6ο

164 5 100 Ω

167, 188 2,000 Ω

176 2 870 Ω

179 20,000 Ω

184 510 000 Ω

190, 198 7 500 Ω

200 1 800 Ω

201.202 3,900 Ω

Potentiometer

113.140 1,000 Ω

139, 175 2,000 Ω

153 10,000 Ω

Capacitors

101 1 50 μί / 6 V

116 2.5 to 9 pf

128, 143,192, 203 3.3 µΩ / 15 V.

135, 137,182, 183 120 μί / 15 V.

138 120μί / 6ν

148 220 pf

152 120 μΓ / 10 V

159 5600 pf

163 4.7μί / 10ν

174 470 pf

180 1000 pf

181 2.2 μί / 15 V.

Transistors

106,144,146, 186 2Ν2222

109,110,131 2Ν3906

130,156,158 2Ν3904

165 2Ν4039

Integrated circuits

112 RCA Corporation CA3OO5

121 Motorola Semiconductor

Products Inc MC1595

(166,168,169,172,186,187)

RCA Corporation CA3045

178 Fairchild Instruments Ine μα. 741

(194,195,199, 204)

RCA Corporation CA3O18 A

FIG. 3 schematically shows the separator 149 and the regeneration stage 150, which are shown in block form in FIG. FIG. 4 shows the shape of stress waves as they occur at various points in the regeneration stage 150 .

The top waveform in Fig. 4 is the voltage at the output of the separator 149 during the last two horizontal deflections or portions of a television image and the beginning of a subsequent vertical blanking interval or retrace interval

The first two broader pulses of this wave form are horizontal synchronization pulses, and the last four narrower pulses are equalization pulses. The point in time f ₀ corresponds to the beginning of the horizontal blanking interval in which the first horizontal synchronization pulse shown lies. The time Z ₁ corresponds to the leading edge of the first horizontal synchronization pulse shown, the trailing edge of which coincides with the time f ₂ . At / ₃ lies the end of the horizontal blanking interval containing the first horizontal synchronization pulse shown: and the start of the horizon lies _{at time f 4}

valley blanking interval, which contains the second shown and thus last horizontal synchronization pulse of the image. The time / ₅ corresponds to the leading edge of the second horizontal synchronization pulse shown, the trailing edge of which occurs _{at the time / e.} At tj lies the end of the horizontal blanking interval containing the second shown and thus last horizontal synchronization pulse of the image. The leading edge of the first equalization pulse appears at time t _s and its trailing edge at time t _a, as well as the beginning of the regenerated vertical blanking interval. Time t ₁₀ corresponds to the end of the regenerated vertical blanking interval.

In response to the separated sync pulses provided by the separator 149 appear on the Terminals 2, 8 and 10 of the integrated circuit buffer amplifier 220 are negative-going separated synchronizing pulses, while at terminal 6 of this amplifier positive-going separated Synchronization pulses appear.

Each of the integrated circuits 230, 240, 260, 270, 280 and 440 (see Fig. 5) is operated so that that it functions as a monostable multivibrator (monovibrator) and is effective at its inputs 3, 4 negatively directed logical signal change is brought into its unstable state. After a certain Period of time, the monovibrator returns to its stable state.

This period of time is determined by the capacitance between terminals 10 and 11 and the resistance between terminal 9 and a bias potential. In the stable state, terminal 1 of the Monovibrators at a higher potential than terminal 6, and in the unstable state, terminal 6 is on higher potential than terminal 1.

The second waveform from the top in Fig. 4 is part of the output voltage at terminal 6 of the monovibrator 230. The leading edges of the negative-going separated sync pulses at the terminal 10 of the buffer amplifier 220 have at the terminals 3 and 4 of the monovibrator 230 as a result that this every time it is tilted into its unstable state. The duration of this unstable condition, i.e. H. the tipping back time, is set so that it corresponds to the duration of the horizontal sync pulses. At the At terminal 6 of the monovibrator 230, pulses appear which have the same width as the horizontal synchronization pulses whether they were triggered by the horizontal synchronization pulses themselves or the compensation pulses.

3 also shows an AND element 238 whose first input 1 receives negatively directed separated synchronization pulses and whose second input 2 receives positive pulses from terminal 6 of integrated circuit 230 that are equal in width to one another. These signals are then and only then both logically "high" for a certain duration if the pulses with the normalized width are wider than the separated synchronization pulses. This is the case immediately after each equalization pulse, as a result of which a negatively directed pulse appears at terminal 3, the inverted signal output of AND element 238. The capacitor 239, located between terminal 3 and ground, prevents the formation of narrow pulse peaks on the edges of the horizontal synchronization pulses or the leading edges of the compensation pulses. The third waveform from the top, shown in FIG. 4, shows the voltage profile at this terminal 3 of the AND gate: 238 during the time immediately before and at the beginning of the vertical blanking interval.

The leading edges of the negatively directed pulses appearing at terminal 3 of AND gate 238 get to terminals 3 and 4 of the monovibrator! 240 and tilt this in each case into its unstable state. The time for which this monovibrator 24C remains in its unstable state is set so

xo that it corresponds to the usual duration of a vertical blanking interval, which with the help of the potentiometer 2460 is reached. As can be seen in Figure 4, a negative appears during each vertical blanking interval Signal at terminal 1 of the monovibrator 240.

> 5 The monovibrator 270 is driven by the trailing edges positively directed synchronizing pulses, which are fed to its terminals 3, 4, in its unstable State tilted. The duration of this unstable state is set with the help of potentiometer 2766 so that

ao that they are the usual time between the trailing edge of a horizontal synchronization pulse and the Corresponds to the beginning of the next horizontal blanking interval. The voltage at terminal 6 of the Monovibrators 270 is a chain of positively directed

as impulses. However, this signal can also be used as a chain consider negative going pulses, each pulse from the beginning of a horizontal blanking interval lasts until the trailing edge of the horizontal synchronization pulse contained therein. This waveform is in Fig. 4 shown at the fifth position.

The monovibrator 260 is fed to its terminals 3, 4 by the leading edges of the negative-going, separated synchronizing pulses be tipped into its unstable state. The duration of this unstable state is with the help of the Potentiometer 2666 set to have the usual duration between the leading edge of the horizontal sync pulse and at the end of the horizontal blanking interval containing this sync pulse is equivalent to. The waveform shown in the sixth position in FIG. 4 indicates the signal voltage terminal 1 of monovibrator 260 between rewind intervals.

The waveform shown next below in Fig. 4 is part of the composite blanking interval pulses, that of the base of the transistor 146 shown in FIG. 2 from the output 6 of one in FIG. 3 NOR gate 250 shown are supplied. During a vertical or horizontal blanking interval (and really only then) is at least one of the inputs 5, 4, 3 of the NOR gate 250 in the logical Meaning "low". The NOR gate 250 therefore only supplies a "high" output signal during such blanking intervals and controls the analog multiplier circuit 121 (shown in Fig. 2) by means of the transistor 146 to full gain during these blanking intervals. The output of the NOR gate 250 thus corresponds the "gap signal" mentioned above.

The leading edges of the positively directed pulses appearing at terminal 6 of the monovibrator 270 generate negative edges at the output of amplifier 226 to turn monovibrator 280 into to bring its unstable state. The duration of this unstable state is set to be about

Length corresponds to a normal back porch. The lowest waveform shown in FIG shows the relative position between the voltage pulses at terminal 6 of the monovibrator 280 and the

11 ^u 12

Horizontal sync pulses during the 411 and 413 to analog multiplier circuit 221 tikalhinlaufs. The multiplication circuit 121 brings a guided voltage

As can now be seen again in FIG. 2, in a state in which the video these are fed to it positively directed impulses on the basis of the signal fully amplified. During the image intervals of the Transistors 156 are given and then serve to combine the 5 video signals, the voltage across the Detection of the black level in the circuit 155 by emitters of the transistors 405 and 406 control to restore the black value. the voltage at the capacitor 415 is specified in such a way that

Appropriate values and data of those shown in Fig. 3 for transmission to the analog multiplying circuit elements are in the following table circuit 121 a lower gain in this listed: 10 circuit effects.

The loading resistors' ^m capacitor 415 charge stored

the voltage on the capacitor is correct. Charged

²¹⁰ · ■ ,, i ™ η ^{is the} capacitor 415 across the collector of a

²¹¹ > ²⁸⁶ rv! ο NPN transistor 460 or the collector of a PNP

^2l3 '²¹⁹; ^ 15 transistor 417, both with one end of the condenser

²¹⁵ τ η O ^{sators 4l5 are connected}

²¹⁷ _ ■ ³ ^ ^ The transistor 416 is set to constant collector

234,244,264,274 1,000 Ll current biased. In the absence of electricity from the

²³⁶ η η collector of the transistor 417 has the current flow in the

² * ^6a , linn ^ao collector of transistor 416 a charge of the

^266a ™ capacitor 415 so that at the base of the

² J ^{6 a} ^ 000 Q transistor 406 a negative voltage appears and

^{28 <} * ^ ^^ the video signal output is attenuated to black.

Potentiometer The diode 430 prevents reverse charging

25 of capacitor 415 during the attenuation

2466, 2760 l ™ n procedure, so that an electrolytic capacitor is used

²⁸⁶⁶ »2 000U can be generated.

Capacitors If the collector-emitter junction of the transistor

424 by applying a positive voltage to the

²⁰ ^! . y ^r '^ ^ 30 base of this transistor is made conductive, then

nrin f ^w ' ^{rd the} transistor 417 is set so that it is at his

²³ J * ¹⁰⁰ ^ P ^ collector supplies a constant current. This con-

²³ _ rP P \ constant current is greater than the constant collector

Zyi , _, -v> nn f current of transistor 416, and the excess

²⁶ T- ²⁷⁵ "| *? Pj. 35 current discharges capacitor 415, causing the

5100 pf _Bas j _s J ₆₅ j _rans j _slors 406 a less negative span transistors voltage appears. This masks the video signal output

from black to maximally amplified image signals. Through

² J ² 7NJiMTJ ^the setting of potentiometer 431 will be the

² ** j οκηοπΛ ⁴ ° ^max ' ^rnale deflection downwards that of the base of the

²¹⁸ 2N3904 transistor 406 experiences voltage supplied, and

Integrated circuits thus determine the maximum image gain.

Two NOR elements 425 and 426 are connected together to form a bi-220 Motorola Semiconductor _{stable multivibrator} (vibrator).

; r ° ^du <* ^s 1 ™ · ■ · · · ■ ■ · ^MC536 45 tet. the activation of the trans-

230,240,260,270,280 _{sistors 41? ge} i _ibteri constant current controls. from

Texas Instruments Ine SN74 121 emer _automatic control system of the transmitter can

238 Motorola Semiconductor _{negatively directed pulses} either as remote control

Froducts inc. .... MC846 _{command to} fade out to NOR gate 426 or i

250 Motorola Semiconductor _{50 aU remote control} ( _e hl to attenuate the NOR-

Products Ine MC562 _{G] ied 425 can be given}

Fig. 5 shows schematically additional circuitry. Sometimes it is desirable to use snow in an emergency

Orders that allow elements 139 to 148 and 151 to be darkened. This is done by pressing

to 154 of the circuit shown in Fig. 2 replace ken a single-pole emergency switch 433 of the one

can to the video signals on impulse commands 55 normally open contact and a normally closed contact, dii

to be able to fade in or fade out automatically. can be grounded. The work contact

The PNP transistors 405 and 406 form one of the switch 433 is via an adjustable resistor

non-additive mixer connected to the combined stand 434 with the base of transistor 417

th emitter electrodes to the more negative of the two When the button for the switch 43 is depressed

Signal voltages applied to ^base electrodes rea- 6o the transistor 417 is biased, un

greed. During horizontal and vertical blanking, the attenuation controls as described above m

Intervals, the voltage at the combined is a speed, which is determined by the value de

switched emitters of transistors 405 and 406 is determined by variable resistor 434,

that signal determines which of the rain- When the switch 433 is pressed, the input

rierstufe 150 via the inverting amplifier 401 ⁶ 5 of the inverting amplifier 436 in the logical Sinr

and capacitor 402 to the base of transistor "low", making the output "high". D.

is coupled. These amplifiers 436 and 437, inverting via resistor 408, are so g

the phase splitter transistor 409 and the resistors switched so that these signal states are stored

i3 t 14

When the switch is released, the rest 408, 446 10 000 Ω

contact is put back to ground potential, then 410, 412 2 200 Ω

the output of the inverting amplifier becomes 436 411, 413,414 6 800 Ω

and the input of the inverting amplifier 437 418 6 200 Ω

put on ground. This makes the monovibrator 5 419, 423 8 200 Ω

440 tipped into its unstable state. This has 420, 422 2,000 Ω

a negative going pulse at the base of the 421 3,000 Ω

Transistor 447 so that the capacitor 415 432 5 100 Ω

is charged quickly via this transistor, where 444 1,000 Ω

through again the potential at the base of the tranio

sistor 406 becomes more negative. This brings the analog potentiometer

Multiplier circuit 121 quickly returns to its ...

State of full reinforcement. ⁴³ * in nnn π

A variable resistance 449 between 7 / j ^{4 l0} 99 ° "

the anode of a diode 448 and -10 V, can be 15 ⁴ ^ 25 υυυ Ω

be set by the operator to the

The fade-in speed can be controlled manually. The capacitors

Series connection of the diode 448 and the variable 402 180 μί / 10 V

Resistor 449 acts as a bypass path parallel to 415 68 μΐ / IO V

the 20 445 33Ο "f / g γ" drawn from the collector of transistor 416

Constant current. As the value of the variable resistance 449 becomes smaller, the speed “.... ,,
of fading in from black to light larger. Semiconductor components

Suitable values for the elements of the in Fig. 5 403, 429, 430 IN695

circuit shown are listed below: 25 405, 406, 417, 447 2N3906

"..,", 409,416,424,428 2N3904

^Forests 435 INLOO

404 160 000 Ω 440 SN74, 12

407 4 700 Ω 448 IN691

In addition 5 sheets of drawings

Claims (5)

Patent claims: 1. Device for switching off television signals, characterized by: a) Input terminals (1, 3) for receiving video signals with horizontal and vertical blanking intervals, intervening image intervals and with synchronizing pulses appearing during the blanking intervals; b) a gap generator (11) coupled to the input terminals and controlled by the Synchronization pulses Horizontal and vertical gap signals provides which coincide with the horizontal and vertical blanking intervals of the video signals; c) a control signal source (15) for outputting an adjustable DC control signal; d) a switching arrangement (13) connected to the control signal source and to the gap signal generator ao is coupled and provides a first predetermined output level for the duration of the gap signals and supplies a second output level which has a function for the duration between the gap signals of the adjustable DC control signal; e) an analog multiplier circuit (9) connected to the input terminals and the switching arrangement is coupled and on the output side supplies a video signal which is the product of the input side Video signal and the respective output level is, so this multiplier circuit for the duration the gap signals provides a predetermined gain and during the time between them Gap signals a gain determined by the adjustable direct current control signal supplies. 2. Device according to claim I, characterized in that the gap signal generator has the following contains: a) a separator (7) which is coupled on the input side to the video signal input terminals (1, 3) and separated at its output depending on the synchronization pulses of the video signal Provides synchronization pulses; b) a trigger circuit (230, 238) acted upon by the separator and controlled by its Input pulses generated trigger pulses whose duration is shorter than the horizontal synchronization pulses are in the video signal; c) a first monovibrator (240), the input of which is coupled to the output of the trigger circuit and vertical gap signals at its output during its unstable state supplies, which is triggered by a trigger pulse and stops after a set time, which is equal to the length of a vertical blanking interval; d) a second monovibrator (260), the input of which is coupled to the output of the separator is and at its output first parts of horizontal gap signals each during its unstable state, which is caused by an edge of a separated horizontal synchronizing pulse is triggered and stops after a set time, which is the same as that which has not yet expired Part of the horizontal load interval in which said separated horizontal synchronizer appears; e) a third monovibrator (270), the input of which is coupled to the output of the separator is and at. Its output second parts of horizontal gap signals each during its unstable state, which is caused by an edge of a separated horizontal synchronizing pulse is triggered and stops after a set time, which is the same as that which has not yet expired Part of the horizontal blanking interval during which said separated horizontal sync pulse appears, plus the subsequent frame interval; f) a first logic circuit (250) with three inputs, each with a separate one of the three monovibrators (240, 260, 270) is connected and their output has a first logic signal state hai, if a vertical gap signal and / or a first part of the horizontal gap signal and / or a second part of the horizontal gap signal are present, and the output of which is a second logic signal state when all these signals are missing, so that at this output the complete gap signals appear. 3. Device according to claim 2, characterized in that the separator (7) in response to the compensation pulses of the video signal at its output provides separated compensation pulses; and that the trigger circuit (230, 238) has a fourth monovibrator (230), the input of which is coupled to the output of the separator and normal pulses are the same at its output Width each appear during its unstable state, which is severed by the leading edge of a Horizontal synchronization pulse or a separated compensation pulse triggered and stops after a set time equal to the length of a horizontal synchronizing pulse is; and that the trigger circuit further comprises a second logic circuit (238), whose first input to the output of the separator and whose second input to the output of the fourth monovibrator is coupled and the output of which is the input of the first monovibrator (240) applied; and that this second logic circuit is in a first logic state is when neither a separated horizontal synchronization pulse or trigger pulse at its first input there is still a normal pulse at its second input, and is otherwise in its second logic state. 4. Device according to claim 1, characterized in that in the switching arrangement (13) a non-additive mixer is included, whose first input circuit (406) with the variable control signal source (15) and its second input circle (405) is coupled to the gap signal generator (11 or 150), and its output circuit (409) the Output level of the switching arrangement supplies depending on which of the two input circuits supplied signals deviates more from a fixed reference value. 5. Device according to claim 4, characterized in that the first input circuit (406) of the non-additive mixer a direct current source (417) and a direct current sink (416) is connected, of which at least one is controllable, and that furthermore an electrical charge storage device (415) with the first input circuit (406) of the non-additive mixer. ₆ Device according to one of the preceding claims for the generation of gap signals lasting for the time of the u Vontal and vertical blanking intervals of a video signal for a Pnrichtuni for blanking of television ■ "ηΐη - with horizontal and vertical shrinking pulses equipped video signal send of the horizontal and vertical display during the Honzunuu- u .. ~ ^ - imervalVe should be fully amplified, «• denotes by:. · ⁸ ^? a separator (7), which receives the video signal at its input and, at its output, horizontal synchronizing • -moulse separated from the horizontal synchromes.enmpulsen SJc video signals delivers the horizontal synchromic pulses of the video signal according to time and