DE2320242C3 - Circuitry in a narrow band television image transmission system - Google Patents

Description

In U.S. Patent Application No. 2,57,412, there is a system with the help of which television images of three-dimensional objects were uncompensated for a long time Let telephone lines be transmitted. Ks becomes a TV camera used which continuously delivers a video signal to a storage tube in which the information of any television picture can be stored. The single saved image - which is to be transmitted - is converted into a lonlrequentes Signal converted to over telephone transmission lines transmitted to a remote receiving ori / u will be where a second storage tube zui Storage of the tone frequency information is used. After the transfer is complete, the 1111 Recipient restored audio frequency information converted back to a video signal for viewing on a display device. The transmitted signal is frequency modulated, with its momentary frequency corresponds directly proportionally to the brightness value of the stored picture element which is transmitted.

Such a transmission system is called a "simplex system" because the transmission is always in a Direction takes place along the telephone line. In a "half-duplex system", on the other hand, transmissions take place in both directions, but not at the same time, such a system is particularly useful, when the image to be transmitted is a stored image of a moving object. In this momentary picture mode (Snapshot images) the television camera is operated with its usual vertical scanning frequency, the moving object being visible on a monitor and the signal information representing the image is written into the memory with the usual horizontal and vertical frequencies. The image will then read out from the memory and transmitted via the transmission line to the receiving location, wc a second storage tube is used to recover the information signals, which are then stored on a second monitor is in turn displayed with the usual horizontal and vertical deflection frequencies. With this one In operation, the tube works normally with bO Hz image deflection frequency - if for the purpose of transmission the information is written in or when it is read out for the purpose of reproduction.

It is also mentioned that the transmission ratios can be improved if the stored image is entered into the telephone line at approximately a quarter of the vertical scanning frequency. So is a second one. 15 Hz vertical scan frequency also desirable. In addition, it has been determined that when transmitting images of stationary objects, increased resolution can be achieved by bypassing the storage tube and entering the information on the telephone line directly in front of the television camera. The vertical deflection of the camera is at the scm operation from 60 Hz to 7 ¹ /: lowered Hz, and there · F.inschreiben in the storage tube on the receiver should also take place with the vertical frequency of 7 ^1/2 Hz. Therefore, a third vertical scanning frequency is Fuei the storage tube, namely from 7 ^1/2 FIz, in addition he wishes, but only in the recovery de. ' transmitted image.

The invention consists in the use of a changeable resistance-capacitance-time constant network for deriving a sawtooth voltage, de ren duration with the scanning time of the vertical deflection signal Ie matches the control of the Speicherröhri be used. In one mode of operation of the circuit according to the invention, the capacitor mi discharged at a speed which depends on the desired vertical frequency /. The impedance

Who! The contradicting part is influenced at the same time / ur adjustment of the slope of the generated saw / iihnc and / ur securing the continuous scanning of the target elements of the storage tube regardless of the selected frequency. The circuit according to the invention can in this way cause a first slope of the signal at a deflection frequency / of 60 H / and provide an increased slope when the frequency is reduced, first to 15 and second to 7 ¹ /: Hz.

The 60 H / deflection frequencies / is used to rewrite of the information signals in the storage tube before transmission over the Teiefonleitung and / to read out the information signals from the storage tube to the receiving location for display on a monitor device used.

On the other hand, the 15 Hz sampling frequency is used both for reading out the information signals of a stored image from the memory; röhre am Sending location. the signals read out are fed into a telephone line, as well as for writing down these signals into the storage tube at the receiving point. When the TV camera receives the information signals of a stationary object fed directly into the telephone line, the 7 '/ j Hz sampling frequency is used for writing these signals into the storage tube at the receiving location. The need for three such sampling frequencies for the complete control of the storage tube follows from the knowledge, that it is used to convey images and to display them on different lines, namely in a "half-duplex" operation.

The invention is explained in more detail below with reference to the representations of an exemplary embodiment. It indicates

I "i g. 1 the block diagram of a television picture transmission system, as in the aforementioned US patent application 2 57 412 is described,

F i g. 2 shows the block diagram of an arrangement for generating control pulses for the operation of the invention Arrangement and

F i g. 3 the circuit diagram of a circuit controlled by the control pulses for determining the appropriate one Frequency for the vertical deflection signals. which of the storage tubes for transmitting or receiving the in F i g. 1 are supplied to the circuit shown.

A telephone image system of the type described in US patent application 2,57,412 includes a television camera 110, a storage tube 112 connected to the output of the camera 110 , a first converter 114 for converting the video signals supplied by the storage tube 112 into audio-frequency signals that are to be transmitted over a telephone line, for example. Further, a monitor 116 is provided, whose input terminal is connected to the output of the camera 1 10 and the mil a second input terminal is connected to the output of the storage tube 112, with which can be considered to be transmitted scene with the aid of the monitor.

At the end of the telephone line, a second converter 120 is connected, to which the audio frequency signals are fed and which converts them into pulse-modulated information, which represents both the audio frequency and the brightness of the picture elements that were input-converted into this information form with the aid of the first converter 114 .

The pulse information is then fed to a two-liter storage tube 122 until the entire transmitted gene image has been received. and connect a / further monitor 124 for displaying the ii

^ the tubes 122 stored image in operation genome men. so that the image transfer is carried out in full in this way.

/ besides, I i g. 1 a .control switch 126 er know which in single image storage mode the be

kj away object images from the television camera 110 / in Storage tube 112 couples before it connects to converter I! ' / ugled, and in freeze mode the ob jekibilder directly from the television camera 110 / un Converter 114 can get, the storage room 112 then from the television image transmission system is separated.

In this memory image drive, the image signals are written into the storage tube 112 using the usual vertical scanning frequency of 60 Hz. In order to match the bandwidth ratios of the telephone line, the signals read out from the tube W1 are fed into the line with a sampling frequency of 15 Mz. In stationary operation, where the storage tube 112 is bypassed, the vertical scanning frequency for the camera 110 is reduced to 7 '/ Drawings. Schematics etc .. to be improved.

When viewing the storage tube 122, on the other hand, it can be seen that a vertical scanning frequency of 60 Hz is required to read out the information from its target for display on the monitor 124. Both the sampling frequency of 15 Hz and that of ΤΊ2 Hz are also used to write the image signals received via the telephone line into their memory. Since a single storage tube can be used for transmission at one point in time and for reception at a different point in time, complete control of the image transmission system requires that these three vertical scanning frequencies are available for the reception mode of the storage tube, while the scanning frequencies of 60 for transmission and \ 1 Hz are required.

The in F i g. The arrangement shown in FIG. 2 contains three inverter stages 10, 11 and 12, six NAND gates 18 bi:

23 with two inputs each, a pulse shaping circuit

24 and a converter and driver stage 26. The output of the inverter 10 is first with an input de; NAND gate 18 and secondly with the input de; Inverter 11 connected.

The output of the inverter 11 is in turn connected to an input of the NAND gate 19, dcsser other input is connected to the output of the pulse shaper circuit 24, which is shown as a monosiabilei multivibrator and pulses a Fre quency of either 7 '/ 2 or 15 Hz supplies. Such a pulse train can also be generated, for example, by a synchronizing generator, not shown, which supplies 60 Hz pulses to the second input of the NAND gate 18. The output connections of the gates 18 and 19 are connected to the inputs of the NAND gate 20, the converters - and driver stage 2 (amplifies the output signals of the NAND gate 20 and then feeds them to terminal 28.

Control signals in the form of a logical "0" or an i logical "1" are the input of the inverter K

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supplied, with the logical "0" in the l ^; nlk · a W) H / -Vertikiil-Ablenkfrequen / how they / to rewrite image signals representing a moving object in the memory, for the subsequent transmission or / to read out image signals from the memory at the Hmpfangsort / um / wake the Representation is necessary. On the other hand, a logic "I" is fed to the inverter 10 if the storage tube at the receiving location is written with a deflection frequency of 7 '/ j or 15 H /, or if the storage tube at the sending location is read out at the 15 H / sampling frequency.

The drawing can also be seen. that the output connection of the inverter 12 is connected to an input of the N AN D gate 21, the / further input of which is connected to an input of a counter 30. which is controlled by the synchronization generator and delivers a 15 Hz pulse train; The counter also ran i.iipulse with a frequency of 7 ¹ /: H / to an input of the NAND gate 22, the output of which is led together with the output connection of the gate 21 to the two input connections of the NAND gate 23. This output connection is connected to the input of the monostable multivibrator 24, so that a pulse train of TU: or a repetition frequency of 15 Hz is fed to the NAND gate 19.

The two input connections of the inverter 12 and the remaining input connection of the NAND gate 22 are fed control signals in the form of a logic "0" or a logic "I", the logic "0" being fed when a 15 Hz vertical deflection signal is required, either to read out information from the storage tube at the transmission location. this information is then to be sent into the telephone line, or for writing image signals into the storage tube at the receiving location. On the other hand, a logic "1" is applied to inverter 12 and port 22 when the vertical deflection frequencies /. should be reduced to 7 U 2 Hz, so that an increased resolution is to be achieved when reproducing stationary images at the receiver, if a greater richness of detail is desired.

If the inverter 10 is supplied with a logic "0", then the NAND gate 18 vertical deflection pulses of 60 Hz run to one input of the NAND gate 20, the other input of which is supplied by the NAND gate 19 with a logic "1". The output signal of the gate 20 are then Yertical driver pulses of 60 Hz, which are amplified by the driver stage 26 and fed to the output connection 28. If a logical "1" is fed to the inverter IO, the NAND gate 18 supplies a logical "1" at its output. while the NAND gate 19 provides the vertical drive pulses from the multivibrator 24 at its output. The output signal of the NAND gate 20 has a pulse frequency of 7> / 2 or 15 Hz in this mode and is fed to the terminal 28 via the driver stage 26

If a logic »0« is fed to the inverter 12, then the NAND gate 21 delivers a verticalfrequen th drive pulse of 15 Hz to one of the inputs of the NAND gate 23, while the other input is fed with a logical "1" from NAND gate 22. The The output of gate 23 is therefore a 15 Hz vertical drive pulse which is shaped by multivibrator 24 and as an input to the NAND gate 19 is fed. Will the inverter 12 on the other hand a logical "1" is supplied, then that delivers

NAND gate 21 also has a logical "I". while the NAND gate 22 supplies a Vcrtikal driving pulse with a pulse repetition frequency of 7U: Hz from the counter 30 as an output signal. The output signal of the NAND gate 23 in this I all has a pulse repetition frequency of TU2 Hz and is flown by the multivibrator 24. before it is fed to the input of the NAND gate 19.

In summary it can be said that at Zuü! ' ^r ung a logic signal "0" to the inverter 10 at the output terminal 28 a pulse train of a repetition frequency of 60 Hz is available. If a logic signal "!" Is fed to the inverter IO and a logic signal "0" is fed to the inverter 12, a pulse train with a repetition frequency of 15 Hz is produced at the output terminal 28 A logic signal "1" is supplied, then a pulse train with a repetition frequency of 7 ¹ /: Hz is produced at the output connection 28.

According to FIG. 3 is an operational amplifier 50, a set of vertical deflection coils 52, a current sensing resistor 54, an integration capacitor 56 and an adjustment resistor 58 provided for the charging time constant. This circuit uses a pair of transistors 60 and 62 interconnected in the manner shown. then a sawtooth generator is created.

In detail, the capacitor 56 is connected between the collector and emitter of the transistor 60, which is shown as an npn transistor and whose base is connected to the collector of the transistor 62 via a resistor 64 . The current sensing resistor 54 connects the emitter of the transistor 60 to a reference potential point (ground), while the setting resistor 58 leads the collector of this transistor via a normally closed switch 66 to a point of relatively fixed potential 65. A capacitor 68 and a resistor 70 are connected in series in the base line of the transistor 62 and through them the pulses of 60, 15 or 7 '/ 2 Hz from the terminal 28 of FIG. 2 supplied. The connection point of the capacitor with the resistor is connected via a further resistor 72 to an operating voltage source + Vi, to which the collector of the transistor 62 is also connected via a resistor 74. The transistor 62 is an npn transistor in the manner shown. then its emitter is connected to a second operating voltage source - V2 .

The switch 66 can be a single-pole changeover switch with connections A and C, with connection A being connected to the collector of transistor 60 and connection B being connected to that end of resistor 58 which faces away from point 65. A second identical switch 76 has its connection B connected to the collector of the transistor 60 , but its connection A is connected to the opposite end of the resistor 58 via the series connection of a fixed resistor 80 with a variable resistor 82. The connection C of this second single-pole changeover switch is connected in the same way to the opposite end of the resistor 58, in this case via the series connection of a fixed resistor 84 with an adjustable resistor 86.

The circuit according to FIG. 3 also illustrates a pair of control circuits 200 and 300 for operating the single pole changeover switch 66 and 76. Each control circuit contains a transistor 202 and 302, which are shown as npn transistors and have their emitters on

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Ground while their collectors are connected to an operating voltage source + Vi via relay coils 204 and 304. Semiconductor rectifiers 206 and 306 are parallel to the coils 204 b / w. 304 with such a polarity that they bypass the coils when the associated transistors are blocked. In such a blocking state of the transistors, the two single-pole changeover switches 66 and 76 are held in their closed normal position, in which the connections ß and Λ are connected to one another.

The transistors 202 and 302 are controlled in their first conduction state via a pair of rectifiers which are connected in series with one another, namely the rectifiers 208 and 210 for controlling the circuit 200 and the rectifiers 308 and 310 for controlling the circuit 300. Are the bases of transistors 202 and 302 via resistors 212 b / w. 312 is connected to ground and the connection points between the rectifiers are also connected to the operating voltage source + Vi via resistors 214 and 314 , and control signals in the form of a logic "0" or a logic "I" are fed to the cathodes of the rectifiers 208 and 308, respectively , with the polarity of the transistors shown, collector currents flow through coils 204 and 304 when a logic signal "I" is applied to the control input terminal, and the switching states of switches 66 and 76 are changed. It is also assumed that the signal applied to the cathode of rectifier 208 is the same control signal. which corresponds to the inverter 10 in FIG. 2 while the signal applied to the cathode of rectifier 308 is the same signal. which is also fed to the inverter 12 .

One of the two inputs of the operational amplifier 50 is connected to the collector of the transistor 60, while its output is connected to the input of an amplifier 53. The amplifier 53 is in turn connected to one terminal of the vertical deflection coil 52, the other terminal of which is connected to the current sensing resistor 54 as shown in the drawing. The other input of the operational amplifier 50 is connected via a resistor 57 to the tap of a centering poientiometer 55, which is connected between a point of fixed operating voltage 65 and ground. A further potentiometer 59 is connected between an operating voltage source + Va and ground, the tap of which applies a fixed voltage to the point 65 to which the adjustment resistor 58 is connected. A capacitor 61 serves as a shunt for this point to ground.

Before the various modes of operation of this circuit are explained in more detail, it should be pointed out that the operational amplifier 50 ensures a relatively fixed potential at the collector of the transistor 60. If the transistor 60 is blocked, then a relatively constant current flows through the resistor 58, and also through one of the three possible coupling paths which connect it to the collector of this transistor, as a result of the fixed voltage drop, and this current charges the capacitor 56 , whereby a linearly increasing voltage arises at the deflection coils 52. The amplitude of this sawtooth voltage is determined by the setting of the potentiometer 59, which effects a size setting with the aid of which the extent of the target area scanned by the electron beam in the storage tube can be determined. This amplitude remains unaffected if the

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Storage tube is switched from one operating state to the other. Setting ties potentiometers 55 also serves as a saw / ahnansiieg Imprint Vc'-shift DC voltage, with the help this can adjust the centering for the storage tube.

When the circuit is in operation, the two bowlers 55 and 59 are normally permanently set and remain unchanged. The operational amplifier 50 represents a fixed impedance at the collector of the transistor 60 and controls the output amplifier 53 for the deflection coils. Is the sawtooth voltage by a constant Generates current, which through the resistor 58 and one of the three aforementioned 1st charging paths for the capacitor 56 flows, then both the slope and the duration of the deflection voltage change accordingly, when changing the mode of operation of the storage tube.

If the cathode of diode 208 in FIG. 3 and the inverter 10 in F "i g. A logical" 0 "supplied 2, then 66 remains the Schaller in its normal closed position in which he / \ and B connects the terminals, so that the base of the transistor 62 positive- vertical frequency pulses of 60 W / are supplied. These signals serve to switch the transistor 60 at a frequency of b () Hz, and in this way the vertical sampling interval is determined. The charge stored in the integration capacitor 56 is at the end of this Intervals are brought back to the initial value, so that the deflection is ended and the degree of the linear drop in the sawtooth current through the deflection coil is determined as a function of the value of the direct voltage at point 65. The capacitor 56 discharges during the duration of the trigger Pulses through the current sensing resistor 54 and then charges up again via the resistor 58 with a slope that is dependent on the current flowing through it and the closed switch 66 flows.

Although no control signal is fed to the cathode of rectifier 308 , switch 76 remains in its normally closed position and connects terminals Λ and B. However, any current that tries to flow through resistors 80 and 82 during this period is passed through the Switch 66 bridged. The potentiometer 59 and the fixed resistor 58 together with the capacitor 56 then determine the amplitude and inclination of the sawtooth scanning current. which flows through the vertical deflection coils in this mode of operation. The inverter 10 is supplied with a logic signal "0" to generate a b0 Hz read out.

If, on the other hand, a logic signal "1" is fed to the inverter 10 and the rectifier 208, the transistor 202 becomes conductive and excites the relay coil 204, so that the contacts B and C of the switch 6f are connected to one another. At the same time by supplying logic signals "0" or "1" to the inverter 12 pulses to the base of transistor 62 either with 15 Hz or with 772 Hz repetition frequency gelie continued, so that transistor 60 at the end of the then abbreviated vertical The charge stored in the integration capacitor 56 is then returned to its initial value at an earlier point in time, so that the termination

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the Abienkintervalls and the linear AbIaII of the deflection coils flowing Sägezahnstromcs \ om Weri of resistance 58 and any / u this point in series with it connected resistor depends, to a logic signal "0" to the cathode of the rectifier J08 to, remains the Transistor? 02 not conducting, and contacts A and / i of switch 76 remain closed. In this mode of operation, the customer sator 56 is again discharged through the Stroml'ühlerwiderstand 54 and then charged again via the resistor 58. but with an inclination which is now dependent on the current flowing through this resistor and the resistors 80 and 82 lying in series with it. The resistance 82 allows in this respect clic change the pitch of the saw / ahnstromes occurs through the deflection coils, wherein the saw / ahnstrom with a sampling frequency of lö Hz., When the inverter 12 is also a logic signal "is fed 0". Such an arrangement is wake-up when the image information about a moving object is to be read out of the storage tube at the transmission location and fed to an audio frequency transmission channel and when information signals are to be written into the memory at the receiving location.

If, however, a logic signal "1" is fed to the cathode of the rectifier 308 , the transistor 302 becomes conductive, so that the excitation current flowing through the relay coil 304 for a connection of the contacts B and C of the switch 76 instead of the previous connection of the contacts A and B cares. The resistor, which determines the speed at which the capacitor 56 is charged, comprises a resistor 58 and the resistors 84 and 86, the resistor 86 being adjustable for setting the gradient of the current flowing through the deflection coils. If a logic signal “I” is fed to the inverter 12 at the same time, then in this mode of operation the capacitor 56 is discharged at a sampling frequency of 7 '/.> Hz. In this way, the circuit can be used when image information about stationary objects is to be fed directly from the television camera into an audio frequency line and the writing in a storage tube at the receiving location is reduced with this

'' ■ ' I frequency to improve the resolution with strong details.

The above is a preferred method of changing the duration and slope of vertical deflection signals for a storage tube has been described, each

But these changes can also be made in others Way to achieve within the scope of the invention. As long as the slope of the deflection signal is reduced and his Duration is increased. when thinking of operating the storage tube with high resolution (where do sampling

- ° when writing on the line at T / 2 Hz) switches to an operating state of low resolution (the reading and writing sampling frequency is 15 Hz) or switches to the more usual operating mode, where the images are written into the memory at the sending location or from the memory at the receiving location are read out, namely at 60 Hz, a complete control of the scanning of the storage tube can be achieved for their different modes of operation. In this way, a single storage tube can be used in a telephone image transmission system for both a transmission function and a reception function. but not at the same time, so that the number of components required to operate the telephone · video transmission system is reduced.

For this purpose 3 sheets of drawings

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Claims (1)

Patent claims: 1. Circuit arrangement in a narrow-band television transmission system with a fixed Honzontitl sampling frequency, in which a television camera operating with the fixed horizontal sampling frequency, a storage tube having an output and an input and an audio frequency transmission line for the transmission of television image information representing object images to a remote The receiving location can be interconnected, characterized in that a first circuit device is provided. which in a first mode of operation the television camera [I f 0). the storage tubes (112) and the audio frequency transmission line together in this order, the output of the storage tube (112) being connected to the audio frequency transmission line when the system is to transmit television picture information that the first circuit device continues to be in a temporary mode separates the output of the storage tube (112) from the audio frequency transmission line in that a second circuit means is provided. the vertical scanning signals are generated at a first scanning frequency when the first circuit device is operating in the first mode, and that a third sounding device is provided. the vertical scanning signals with a / wide scanning frequency / generated when the first Schaltiingseinriehtung operates in the second mode. 2. Circuit arrangement according to claim I. characterized in that the first circuit device works in the second mode, where the television camera (110) without interposition the storage tube (112) directly to the audio frequency / transmission line when the system is to transmit television image information representing stationary object images. and that the television camera (110) is connected to the third circuit means. when the first Circuit device works in the / wide mode of operation and the television camera (110) with the second Sampling frequency operates. J. Circuit arrangement according to claim I and / or 2. characterized in that the television camera (110) is connected to the second circuit device when the first circuit device operates in the first operating mode and the television camera (110) operates at the first sampling frequency operates, wherein the second sampling frequency is less than the first sampling frequency. 4. Circuit arrangement according to at least one of claims I to 3, characterized in that the / wide circuit device is a resistance-capacitance-cell constant network contains, which supplies a sawtooth voltage, the slope and duration of the sampling frequency of the vertical deflection signals corresponds, and that the third circuit means by the resistance of the network flowing current decreases and the time of the capacitor discharge to reduce the slope and increase the saw voltage period. ). Circuit arrangement according to at least one of claims 1 to 4, characterized in that iliis resistance capacity network Resistor (58) and a capacitor (56) has that a first transistor (60) is also provided is. between its collector and limit the capacitor (56) is sounded. and that the Iksis a pulse train is fed to the transistor (60), as a result of which he is controlled in the conduction state and its repetition rate / corresponds to the first base frequency if the system is telegraph information should be transmitted, the moving object images correspond, while the impulses with a different repetition frequency according to the / wide Abtasil'requen / if the system is to transmit television image information corresponding to stationary object images. b. Circuit arrangement according to Claim 1, characterized in that there are output terminals Connection of a playback device, and a fourth circuit device is provided. the so is operated that the audio frequency transmission, the storage tube (112) and the display device (116) are poured together in this order when the system is to reproduce television picture information signals representing object pictures, which are received from a remote transmission location, that the third sighting device a fifth Schaltiingseinrichtung containing the Storage tube (112) supplies vertical deflection signals of a third sampling frequency, if the fourth Sounding device is operated so that the received over the audio frequency transmission line Image information signals are written into the memory (112) that the second viewing means means including the vertical deflection signals of the storage tube (112) fourth sampling frequency supplies when the fourth sounding device is operated so that the Image information signals from the memory (112) for Feed to the connections of the playback device (116) are read out that the second circuit device is switched to the storage tube (112) when the first switching means is operated so that the image information signals are written in the memory, and that the third formwork means is connected to the storage tube (112) for supplying vertical deflection signals deliver when the first circuit device is operated so that the Bildinformai'onssignale from read out from the memory and fed to the tone frequency transmission line, the first and / wide sampling frequency are practically the same. 7. Circuit arrangement according to claim 6, characterized in that the / wide and third Sampling frequency are also practically the same. 8. Circuit arrangement according to claim 7, characterized in that the / wide and third Sampling frequency compared to the first and fourth sampling frequency are lower. 9. .Circuit arrangement according to claim 8, characterized characterized in that the second and third scanning frequencies are a quarter of the first and fourth Sampling frequency. K). Execution according to at least one of claims I to 9, characterized in that the first circuit means is operated so that the storage tube (112) with the television camera (110) and the audio frequency transmission line connected when this system TV picture in- information signals should be transmitted, the assess whether represent project images, and that the first Scrulumgs device is operated so that the spoke tube »E (112) from the connection / wipe the television camera (MO) and the audio frequency overtraining-> line is cut out when the system lerm screen informaion signals. represent the stationary object images, is to transmit, wherein the fifth circuit device of the storage tube (112) Vertik.al-Ablenksign.iie of the third Abtasiire- «Yue / feed when the first formwork installation is operated so that the storage tube (112) is cut out is. 11. .Circuit arrangement according to claim 10 characterized that the third Antastire- is qtien / practically half the size w n. the second <\ btastfrequen / is. 12. Circuit arrangement according to claim 4, characterized in that the / wide sounding device a resistance-capacity-time constant network / ur delivery of a sawtooth voltage, the slope and duration of which the Correspond to the scanning frequency of the vertical scanning signals, which are fed to the storage tube, and that the third Schalteinriehtung operates as follows: s Ben will be that the current flowing through the resistor is reduced and the time of the capacitor disengagement is extended when the deflection signals for reading from the storage tube with the second frequency - compared to the delivery of the deflection signals at the first sampling frequency when writing into the storage tube. 13. Circuit arrangement according to claim 12, characterized characterized in that the Walerstards capacity network a resistor (58). one capacitor (56) and one connected in series therewith Coupling path umiaüi, with a first transistor (60) is connected with its collector and its emitter via the capacitor (56) and via its base with the help of an impulse train in the line / ustand is biased, the repetition rate of which corresponds to the first sampling frequency when television picture information should be written into the storage tube, which represent moving object images, during the pulse repetition rate corresponds to the second sampling frequency when television picture information signals from the storage tube which object images are to be read out and the audio frequency transmission channel should be supplied. 14. Circuit arrangement according to claim 2, characterized in that the storage tube (112) is connected to the second circuit device when the first circuit device is in the first mode operates to operate the storage tube (112) at a first sampling frequency when the system is television picture information representing moving object pictures, is to be transmitted, the first sampling frequency being greater than the second sampling frequency.