DE737985C - Process for the production of a control image for the surveillance of television broadcasts - Google Patents

Description

Method for producing a control image for surveillance of television broadcasts For outgoing television broadcasts there is usually a check the image quality desired. This monitoring is of particular importance in the case of the takeover from TV programs recorded elsewhere (e.g. international Program exchange).

According to the invention, the control image used for monitoring made visible under the action of an impulse, which in turn is made visible by a at any point in time given signal comes into effect and its beginning with coincides with the beginning of the picture following the signal, during its duration is the same as the duration of the transmission of the control image, which is either a complete, image of the respectively transmitted scene containing all image elements only once or a single partial image of a color or stereo image or a single line of lines of an interlaced picture. The control image is reproduced. B. with Using a cathode ray tube, which is usually locked and only during the Duration of z. B. photographically to be recorded control image for image writing is released.

The invention is illustrated below with reference to an exemplary embodiment descriptive figures. It is assumed that the television broadcast is transmitted according to the currently valid German television standard.

In Fig. I there is schematically an arrangement for reproducing a photographic Retention of certain complete, transmitted according to the jump line procedure Shown in the picture. The writing of the picture must start with the first line and should stop after the two complete rows have elapsed. This is done the cathode ray tube K providing the control image, which usually is blocked, released for the duration of '12;, sec. by a positive pulse c.

The two relay arrangements R and R are fed from a high-frequency alternating current source T via lines h and h. A switching element S, which normally interrupts the circuit TR, is located between T and the relay R_. As soon as now from the Atislöseeinrichtung _-I, z. B. by a signal button, a brief pulse (indicated schematically by a) acts on the relay R, a positive control voltage via 1 is output at the output 1s of this relay until this relay R, through a blocking pulse arriving via 14 opposite polarity, which is discussed below, is locked again. The positive control voltage output at the output v = on R acts on the switching device S via the line 1s in such a way that the high frequency can now pass from T to the relay R-. As a result, this second relay also opens the current path from it, ie it can be controlled by the positive or negative pulses (shown schematically by b) of the multivibrator M, which oscillates at 12.5 periods and runs synchronously with the image. The positive pulse of the multivibrator generates a control voltage c in R; which releases the blocked cathode ray tube k which is to write the control image to be photographed. The duration of c is determined by the negative multivibrator pulse. For the purpose of releasing the tube 1i, c can e.g. B.

. as the unlocking voltage of the negatively biased control electrode are fed. This control voltage c is also generated via a differentiation arrangement D, which z. B. consists of an RC element, with its leading edge a positive one and with its trailing edge a negative pulse (see curve d). These impulses «-ground via line 1, fed to the first relay R1. The positive impulse of this curve shape d does not change the equilibrium position of the relay R, the negative impulse on the other hand controls this relay back into the equilibrium position that it had before the action of the Had a pulse, back. The one generated at the output of R, via 1;, of the switching device The control voltage supplied to S breaks down, and it becomes the initial one again Condition established: the cathode ray tube h remains dark as long as over the switch A is given a new impulse to trigger a control recording.

Fig. 2 shows the practical circuit arrangement for carrying out the method according to the invention based on the scheme of FIG. With i is the high frequency generator corresponding to T in Fig. i, whose voltage across the coupling capacitor 2 is fed to the control grid of the multi-grid tube. 4. This tube-1 forms in Connection with the two-pole tubes io and i-. and the associated switching elements the pulse relay R1 according to FIG. Once across the resistor 5 by closing the Switch 6 (corresponding to A in Fig. I) from the voltage source 7 of the multigrid tube.I a positive pulse a is supplied and thereby an opening of this previously blocked Tube takes place, the high-frequency voltage going out from i is transmitted via the transformer b the tube 14 is supplied. As soon as the counter voltage of the battery 13 is overcome, This two-pole tube is used to rectify the high-frequency voltage. The bias of the distribution grid of the tube 4 is by a battery 16 so set so that the tube 1I does not supply a rectified voltage as long as when the short positive voltage pulse is not given by closing the switch 6 will. Then temporarily the gain of the tube 4 is so large that the tube 14 with the resistor 12 and the capacitor 15 generates a positive voltage which turn the tube further upwards, so that it is now also after disappearing of the positive pulse a sets a stable value.

To control the second pulse relay (R. in Fig. I) from R1, a second tube io is used, which is connected in such a way that, just like the two-pole tube 14, it emits a positive control voltage. This voltage opens the previously blocked electron tube i, - serving as a switching element (S in FIG. I). By opening 17, the high frequency 7 ' fed to the input of the tube 17 from i via the coupling capacitor ig is now fed to the second pulse relay R = and this enables this relay to work. This second relay comprises the tubes 23, 26 and 30 with the connecting switching elements and works like the first pulse relay described above, in such a way that after the arrival of a positive pulse a positive control voltage is emitted which disappears again after the arrival of a negative blocking pulse. These positive opening and negative blocking pulses are derived via the coupling capacitor 24 from the multivibrator (not shown in FIG. 2) (11 in FIG iti is suitably synchronized with the frame rate. The time interval between the signal peaks derived from the multi-vibrator is 1/2. Sec., Is therefore equal to the time required for a complete picture to run.

The second pulse relay R-. is designed similarly to the first pulse relay. The two two-pole tubes 26 and 30 are coupled to the output of the multi-grid tube 23 via the high-frequency transformer 25. Time constant elements are provided in their anode circuit, which consist of resistors 28 and 32 and parallel capacitors 29 and 33, respectively. A corresponding bias of the two-pole sections is achieved by voltage sources 27 and 31, respectively. The positive voltage (c in FIG. I) picked up at the output of the second pulse relay at resistor 32 opens the cathode ray tube (not shown) connected to terminal 37. After 1/2 "second, as a result of the effect of the negative pulse supplied by the multivibrator, the positive control voltage taken from the output of the second pulse relay (c in FIG. I) will disappear and the cathode ray tube will be blocked again.

The control voltage taken from the output of the second pulse relay c is also the differential device consisting of the capacitor 3.4 and the resistor 35 (D in Fig. I) supplied. When the positive control voltage c arises, with With the help of this differentiation device, a positive impulse when disappearing of the positive control voltage, a negative pulse via line 36 to the first Pulse relay supplied. During the first (positive) impulse on the equilibrium position (Switching state) of the first relay R1 has no effect, the one at the end of the The negative impulse distorting the control image causes a switchover of the first relay. As a result, after an image is written, both the first and the second pulse relay is returned to its original state of equilibrium will. The cathode ray tube then remains dark again until manually A new positive trigger pulse is given via switch 6.

The derivation of the negative blocking pulse from the trailing edge of the control voltage c of the second relay to block the first has the purpose that not the first The pulse relay is blocked again immediately before the recording is made. will if After the trigger pulse given by hand, a negative pulse from the 12.5 Hz multivibrator is initially applied follows. Immediate use of the multivibrator pulse to block the first one. Relay would require a special interlocking of the relay, which is only eliminated may be used if a positive multivibrator impulse has already raised the second relay Has.

The second pulse relay R2 can optionally with the rectified High frequency of the first relay can be operated. In this case the second speaks Relay only on if there is a rectified high frequency voltage from the first relay is delivered. It is therefore not absolutely necessary to use the first tube of the second To release Iinptilsrelais only by a special signal; the switching device S can then be omitted.

Claims (5)

PATENT CLAIMS: i. Process for the production of a control image for the monitoring of television transmissions, characterized in that the control image is made visible under the action of an impulse (c), which in turn passes through a signal given at any point in time (a) - comes into effect and its Beginning coincides with the beginning of the picture following the signal, while its duration is equal to the duration of the transmission of the control image, either a complete image of the transmitted image containing all image elements only once Scene or a single partial image of a color or stereo image or a single one Line of an interlaced image is. 2. The method according to claim i, characterized in that that at the beginning of the first line of the image following the signal a previously blocked Katliodenstrahlrölire opened for image writing and at the end of the last line of this image again j is blocked. 3. A circuit for performing the method according to claims i and 2, characterized in that the z. B. by means of a button (A) arbitrarily given trigger signal (a) controls a pulse relay (R1) in such a way that with the beginning of this signal (a) until the arrival of a pulse of opposite polarity (second pulse of d) at output 1, the im- 1 pulse relay (R1) a voltage is generated, which switches on another pulse relay R. which, at the beginning of the control image to be recorded, supplies a positive control pulse (c) to the control electrode of the cathode ray tube that is generating the image and opens it . d. Arrangement according to claim 3, characterized in that the Cathode i ray tube opening control pulse (c) in the second pulse relay (R.) from the positive one Impulse (b) of a working with half frame rate, synchronized 1Vlultivibrator (bT) triggered and by its negative 'pulse (b) is limited. 5. Arrangement according to claims i to .I, characterized in that after a complete line jump, image by supplying the negative blocking pulse (b or d) both to the first (R1) and to the second pulse relay (R =) the prior to the arrival of the trip signal, the current state of the alarm is restored.