DE1257194B - Arrangement for comparative measurement of the transmission properties of three transmission four-pole poles in color television signals by means of a single-beam oscillograph - Google Patents

Description

Arrangement for comparative measurement of the transmission properties of three transmission quadripoles in color television signals using a single-beam oscilloscope The present invention relates to an arrangement for comparative measurement the transmission properties of three transmission quadrupoles in color television systems by means of a single-beam oscilloscope, on whose screen the three output color signal components the quadrupoles are apparently made visible at the same time. For this purpose the signals of the three transmission poles one after the other to the oscilloscope used for the measurement fed in cyclic sequence and displayed on its screen. If it is faster enough Sequence of the individual images, these appear to the observer simultaneously and can be viewed together and compared with one another.

An electronic switch containing three electron paths is used to alternately supply the signals to the oscilloscope. For the alternating connection of three signals from three transmission poles, the electronic switch can be designed with two groups of three controlled electron paths each, the switching state of the electron paths of the first group (commutator) being changed by a pulse sequence synchronous with the measurement signals and the Electron paths of the second group (switches) are controlled by those of the first group. In a known arrangement (according to German patent 1 042 016) to generate the switching pulses by means of the electron paths of the first group (commutator), the output electrode of each electron path is connected to the suitably biased control electrodes of the other two electron paths via a directional conductor and via a resistor. In this known arrangement, the electron paths of the second group (switch) are controlled in such a way that each electron path of the first group controls the associated electron path of the second group by means of a common resistor in the cathode circuit.

When the three signals fed to the measuring plates of the oscilloscope on the screen of the oscilloscope, shifted against each other in the vertical direction, are to be recorded separately, it is necessary that the three signals have different mean values or that the reference values contained in the signals are at different potentials. It is known for this on the control electrodes to provide clamping circuits of the electron paths of the second group (switches), whose base points are at different potentials. In the common output of the triple switch the three signals then appear with different potentials of their reference values.

This known arrangement has a number of disadvantages. on the characteristics of the electron paths consisting of amplifier tubes (switches) the operating point has a different position for each signal, and therefore from the signal amplitudes, different parts of the characteristics are swept by the signal. It it is now difficult to make the characteristic curves so linear over large areas that that all three signals are transmitted in exactly the same way with regard to their amplitude, as must be required for exact comparative measurements. Same difficulty occurs in the amplifier between the electronic switch and the measuring plates of the Oscilloscope on. Another difficulty arises from the need to the level spacing of the three black levels of the three color signal components and their position on the oscilloscope screen when the mean values in the individual signals change to hold on. A DC amplifier could be used for this purpose, but would be the effort due to the large linear dynamic range, the considerable output voltage as well as very large for the inclusion of a stable mode of operation.

When using an AC amplifier, it is necessary to reintroduce the DC component of the signal. When transferring A simple black control cannot be used for color television signals, because there can be negative amplitudes in the color television signal that are more negative than the blanking (black) value, and the Black control therefore on a changing signal value instead of the constant blanking or black value would appeal. A keyed black control (clamping circuit) that only works during the time the black shoulder occurs in the signals is also effective not applicable as they have each of the three color signal components at the same potential for the black level and the previously introduced shift in the reference values would undo. To avoid this, the clamping circuit should be used can only be opened for one signal at a time, the clamping then always being open the same potential would occur. This would generate special clamping pulses with 1/3 line frequency and measures for their assignment to the signals to be clamped make necessary. Finally, there is still a compromise between the two stated Possibilities of black control applicable, of a simple black control with a diode, but this diode only for the duration of the reference potential opens in the signal by a test pulse (German patent 954 708).

To avoid these disadvantages, an arrangement is used for comparative purposes Measurement of the transmission properties of three transmission poles in color television systems with measurement signals having periodic reference values by means of a single-beam oscillograph, on its luminescent screen the three output signals of the four-pole transmission appear to be can be made visible at the same time by the measurement signals in cyclic order by means of a triple electron switch via an amplifier to the measuring plates applied to the cathode ray tube of the oscilloscope and this also has a stepped shape Auxiliary voltage for the separate representation of the corresponding to the three measurement signals Oscillograms is supplied, according to the invention, the push-pull circuit Amplifier at the same time as an addition stage for the stepped auxiliary voltage used in such a way that the grid of a push-pull tube successively the three Output color signal components of the transmission quadrupoles and the grid of the other Push-pull tube the stepped auxiliary voltage is fed and both tubes are coupled via a common cathode resistor.

The arrangement according to the invention has the advantage that the oscilloscope amplifier can be implemented as an AC coupled amplifier up to the output stage and only for the smaller dynamic range required for processing a measurement signal needs to be measured. Because all three measurement signals have the same range of the modulation characteristic take, there is also the guarantee that all three signals in completely similar Way to be reinforced.

The push-pull amplifier designed according to the invention can instead with tubes can also be built with transistors. In this case the output signals the base of one transistor and the stepped auxiliary voltage of the base of the second transistor fed to the push-pull stage, and the coupling of both transistors takes place via a common emitter resistor.

To define the potential of the reference value (black value), the is now the same for all three signals, is sufficient in the case of the invention Arrangement a conventional clamping circuit that is keyed for the duration of the porch on the control electrode of the output stage of the oscilloscope amplifier.

So that the output signals supplied by the triple electron switch have the same potential of their reference value, are according to a development of the invention the control electrodes of the electron paths of the first group (commutator) galvanically connected to those of the second group (switches) so that the control electrodes of the interrupters in the conductive state the potential defined by the use of grid current of the control electrodes of the commutator tubes.

The invention is now to be based on the illustrative embodiment Figure will be explained in more detail.

The F i g. 1 and 2 show exemplary embodiments for the invention essential circuit arrangement of a device for comparative measurement of three components of a color television signal using a single-beam oscilloscope. F i g. 1 is the circuit diagram of a preferred embodiment of a triple electron switch with tubes, in FIG. 2 is a circuit example of the circuit with the switch according to FIG G. 1 cooperating amplifier, also with electron tubes, shown. Further circuit groups necessary for the operation of the device, e.g. B. for the time deflection of the oscilloscope and for the power supply of the oscilloscope tube, are omitted.

The triple electron switch of FIG. 1, the three color signal components to be compared are fed to the connections 101, 201, 301. It can be, for. B. the Y component (luminance signal) and the I and Q component (color signals of a color television signal or the signals corresponding to the three primary colors (red, green, blue), e.g. the output signals of a color image signal generator For amplification and linearity, a measurement signal is generally used which has the form of a voltage that rises linearly between the extreme values. The signal can be generated electrically and fed to the inputs of the four-pole transmission to be measured, if necessary via an electronic three-way switch. In the case of a color image signal generator the measurement signal can also be obtained by an optical gray scale, the division between the three four-pole terminals being carried out by the beam-splitting optics of the color image signal generator.

The controlled electron paths of the triple electron switch according to FIG. 1 are formed by single-grid tubes. The tubes 110, 210, 310 are the switching tubes; the tubes 120, 220, 320 are the commutator tubes which control the switching tubes from the closed to the open state. Each interrupter can with the associated commutator tube to a double triode, z. B. of the type ECC 85, be combined. The Kommutatorröhren 120, 220 and 320 are in turn controlled by a synchronous with the period number of the signals pulse sequence which the control grids of three Kommutatorröhren each via a capacitor 121, 221, 321, z. B. 20 pF, optionally with the interposition of protective resistors 122, 222, 322, of z. B. 25.f2, is supplied to suppress unwanted vibrations. In addition, the control grids of the three tubes 120, 220, 320 are connected to the taps of voltage dividers which are arranged between the anodes of the tubes 120, 220 and 320 . The anode of each tube is finally connected via an anode resistor 123 or 223 and 323, e.g. B. 10 kQ, with the positive operating voltage, of z. B. 150 V, with the interposition of adjustable resistors 30, 40, z. B. each with 500 Q, the purpose of which will be discussed later.

The aforementioned voltage dividers between the anodes of the tube are each composed of the resistors 125 and 225, 325 with z. B. 1 MQ and 124 or 224, 324 with e.g. B. 0.5 MD built. A capacitor 126 or 226, 326 with z. B. 20 pF.

To explain the operation of the electronic triple switch, it is assumed that, for. B. the tube 120 energized and the other two tubes 220 and 320 are blocked. The two last-mentioned tubes therefore carry no anode current and their anodes have approximately the full positive operating voltage of z. B. 150 V. At the anode of the current-carrying tube 120 , on the other hand, there is a voltage which is reduced by the voltage drop across the anode resistor 123 in relation to the positive operating voltage. Therefore, the voltage dividers with the resistors 125, 224 and 124, 325 connected to the anode of the tube 120 also have a smaller positive voltage at their tapping points between the said resistors than the tapping between the resistors 225 and 324 between the anodes of the tubes 220 and 320. This also keeps the voltage on the grids of tubes 220 and 320 at such a large negative voltage from bias terminal 90 (e.g. -85 V) that the blocking of the two tubes 220 and 320 is maintained; on the other hand, the voltage at the grid of the tube 120 corresponds to the grid current start point and thus approximately the potential of the cathode, so that the tube 120 remains live.

If a negatively directed switching pulse is now sent from terminal 20 via capacitors 121, 221 and 321 to the control grids of the three tubes 120, 220, 320, the switching state of the blocked tubes 220 and 320 is not changed. On the other hand, the voltage at the grid of the tube 120 will decrease so much that the anode current of this tube drops to zero and the voltage at the anode of the tube rises approximately to the positive operating voltage. This sudden increase in voltage is transmitted via the capacitor 126 to the grid of the tube 320 and makes this so positive that the tube 320 now carries an anode current. The voltage drop across the resistor 323 lowers the voltage at the anode of the tube 320 so that the voltages on the grids of the tubes 120 and 220 are shifted into the negative region via the voltage dividers 324, 225 and 325, 124, respectively Tubes are locked. This switching state is maintained until the now opened tube 320 is blocked by the next pulse at the connection 20 and the tube 120 is opened, while the tube 220 remains in the blocked state. The third pulse now blocks the tube 120 and this opens the tube 220. The fourth pulse finally establishes the initial state in which the tube 120 is opened and the tubes 220 and 320 are blocked. A continuous pulse sequence at the connection 20 therefore changes the switching status of the tubes in a cyclical sequence in such a way that one tube is energized and the other two are blocked.

The grid of each commutator tube 120 or 220, 320 is now galvanically connected to the control grid of the associated switching tube 110 or 210, 310 . As a result, each interrupter has the same switching status as the associated commutator tube, so that one interrupter is always open and the other two are blocked.

The signals to be measured come from the input terminals 101, 201, 301 via the resistors 111, 211 and 311 of z. B. 50 S2 to the cathodes of the interrupters, which also via the cathode resistors 112, 212 and 312 of z. B. 200 S2 to ground. The anodes of the three interrupter tubes are connected to one another and via a common anode resistor, which z. B. consists of a fixed resistor 60 (z. B. 250 D) and a potentiometer 70 (z. B. 100 12), applied to the positive operating voltage. If, for example, the interrupter 110 is open, the signal is transmitted from the connection 101 in the tube 110 to its anode circuit and causes a voltage drop at the anode resistor 60, 70 corresponding to the signal curve, while the path for the other two signals through the blocked interrupter 210 and 310 is interrupted. When the interrupter 210 is open, the signal from terminal 201 is transmitted to the common output of the electronic switch in the next period of the measurement signal, and in the third switching period the signal from terminal 301 is transmitted via the now open interrupter 310.

Due to the galvanic connection of the control electrodes of the associated Commutator and switch tubes have the potential at the control grid of the respectively open Switching tube the same given by the grid current insert of the commutator tubes Value on. This means that the potential of the reference value is also in the anode circuit of the interrupter the same for each of the three measurement signals.

From the tap of the potentiometer 70 an adjustable amount of the output voltage of the triple electron shadow is applied to the input of the oscilloscope amplifier according to FIG. 2 transferred. In the present circuit example, this contains three preamplifier stages which are connected in a resistance-capacitance coupling. The first two stages of the amplifier (FIG. 2) are constructed with single-grid tubes 410 and 420 which form a double triode, e.g. B. of the type ECC 85, can be combined. The voltage picked up at the potentiometer 70 of the triple electron switch is transmitted to the control grid of the tube 410 via the line 80, the coupling capacitor 401 (e.g. 0.22 #tF) and a protective resistor 402 (e.g. 25 D). The gain of this tube is adjustable by a resistor 404 (z. B. 500 D) which is in series with the resistor 403 of z. B. 250 D is arranged in the cathode circle of the tube 410 . From the junction of the two resistors, the tube 410 receives the required negative bias voltage via the grid bleeder resistor 405 (e.g. 1 MS2). The voltage amplified by the tube 410 occurs at the anode resistor, which consists of an ohmic resistor 406 (e.g. 1.25 kn) and an inductance 407 , and is generated via the coupling capacitance 411 (e.g. 0.22 #tF ) to the control bit of the second amplifier stage with the tube 420. This stage is constructed similarly to the first amplifier stage with the tube 410, but contains only a fixed cathode resistor 413 with e.g. B. 200 D, the grid bleeder resistor 415 (e.g. 1 MS?) And the anode impedance from the ohmic resistor 416 (e.g. 1.6 kΩ) and the inductance 417. Via a further coupling capacitor 421 (e.g. 0.22 #tF) the third amplifier stage is connected to the tube 430, a pentode of the E 81 L type. A protective resistor 422 (e.g. 50 S?) Is located in front of the control grid of the tube 430. The grid bias voltage supplied via the resistor 425 (e.g. 1 MD) is produced by the voltage drop in the anode current at the cathode resistor 423 (e.g. 75 D). The output voltage of the preamplifier appearing at the anode resistor 427 (e.g. 1 kΩ) of the tube 430 is used as a control voltage for the output stage of the oscilloscope amplifier. The tubes 410, 420 and 430 of the preamplifier receive a common positive operating voltage of e.g. B. 150 V, which is bridged by a capacitor 429 (z. B. 50 #tF) to ground.

The output stage of the oscilloscope amplifier is designed as a push-pull amplifier to supply a deflection voltage symmetrical to ground for the measuring plates 501 and 502 of the oscilloscope tube. It is equipped with two power pentodes 450, 460, e.g. B. of the type EL804, built up.1mAnodekreis each of the two tubes is an anode resistor of the same size 456 or 466, z. B. with 2 kD each, switched on in series with an inductance 457 or 467 to increase the output impedance for the higher frequencies contained in the measurement signal. The measuring plates 501 and 502 of the oscilloscope tube are connected directly to the anodes of the output tubes 450 and 460 via series inductors 458 and 468.

The output voltage of the last tube 430 of the preamplifier becomes Via a series inductance 431 and the coupling capacitor 432 (e.g. 4000 pF) with the interposition of a protective resistor 433 (e.g. 50 _2) on the control grid of the end tube 450. The potential at the grid of the tube 450 is for the Reference values contained in the measurement signal by means of a double-sided clamping circuit 470 stabilized. In the circuit example, this consists of two high vacuum diodes 471 and 472 (e.g. EAA 91) in series with resistors 473 and 474, with e.g. B. 200 kD. The opposing clamping pulses to the opening of the diodes during the time of the Occurrence of the reference value in the measurement signal are controlled by the clamping circuit via the capacitors 475 and 476 (e.g. 0.02 #tF) are supplied.

A noticeable weakening of the clamping circuit during the sampling times To avoid the color sync pulse contained in the television signal is after another Proposal of the inventor a resistor 477 of z. B. 10 kQ between the signal line and the clamping circuit inserted.

The anti-phase control of the second tube 460 of the push-pull output stage takes place via a cathode resistor 453 common to both push-pull tubes with z. B. 800 D. This resistance also makes the cathode potential of the first tube 450 strongly positive with respect to the grounded reference line; Therefore, for setting the proper grid voltage for the tube 450 and the reference voltage for the grid of the tube must be positively selected 450 from the reference line. This positive voltage is taken off at a voltage divider with resistors 481 (e.g. 170 kD), 482 (e.g. 10 kD), 483 (e.g. 20 kD) and 484 (e.g. 250 kΩ ) between the reference line and a positive operating voltage of e.g. B. 150 V. To set the voltage, it is removed from the wiper of the resistor 482 formed on the potentiometer and fed from this to the base of the clamping circuit 470. To reduce the AC resistance of the voltage divider, the resistor 481 is bridged by a capacitor 485 (e.g. 10,000 pF).

By maintaining the same reference potential for the alternating of the three signals transmitted via the oscilloscope amplifier becomes - how already mentioned - the advantage achieved is that the transmission of all three signals is perfect the same happens that the control range of the amplifier only for the signal amplitude needs to be dimensioned and that a normal two-sided effective clamping circuit is applicable to stabilize the reference values of all three signals.

In order to reproduce the three signals on the screen of the oscilloscope tube separately from one another, according to the invention, a shift voltage is transmitted to the grid of the second push-pull tube 460 , which has a different value for each of the three signals and thus has a stepped profile. This shift voltage is obtained in the anode circuit of the triple electron switch (FIG. 1) and arises as a voltage drop across resistors 30 and 40 or parts thereof. The anode current flows when the tube 120, which transmits the signal from the terminal 101, is open via part of the resistor 30 and causes a voltage drop at this point, by which the voltage in the line 50 is smaller than the positive operating voltage of, for. B. 150 V.

A part of the voltage prevailing on the line 50 is now transferred via the voltage divider from the resistors 491 (e.g. 250 kD), 492 (e.g. 25 kΩ) and 493 (e.g. 200 kΩ) -) the protective resistor 462 (z. B. 50 S_) transferred to the control grid of the tube 460 . If the tube 220 of the electronic switch is conductive, and the signal is therefore transmitted from the terminal 201, the entire resistor 30 is in the anode circuit of the tube 220, and the voltage in the line 50 is lower than when the tube 120 is open. Accordingly, it is also reduced the voltage on the grid of the tube 460, and there is a corresponding increase in voltage on the measuring plate 501 of the oscilloscope, so that the signal from terminal 201 is written on a different position on the screen than the signal from terminal 101. In an analogous manner when opening of the tube 320 of the triple electron switch, an additional resistor 40 in the anode circuit of the tube 320 is effective, so that the voltage in the line 50 becomes even smaller. Accordingly, the voltage on the grid of the tube 50 is reduced even more, so that the signal from the terminal 301 is again written at a different point on the screen of the oscilloscope tube. To improve the transmission of the voltage jumps to the grid of the tube 460, a capacitor 494 (e.g. 10,000 pF) is provided in parallel to the voltage divider resistors. The tubes 450 and 460 are supplied with an anode operating voltage of e.g. B. 250 V operated, which is bridged by the capacitor 495 (z. B. 50 #tF) to the reference line.

Claims (2)

Claims: 1. Arrangement for the comparative measurement of the transmission properties of three transmission quadripoles in color television systems with measurement signals having periodic reference values by means of a single-beam oscilloscope, on the luminescent screen of which the three output signals of the transmission quadripoles are apparently made visible at the same time by the measurement signals in cyclical order by means of a triple electronic switch an amplifier is applied to the measuring plates of the cathode ray tube of the oscilloscope and this is also supplied with a stepped auxiliary voltage for the separate display of the oscillograms corresponding to the three measurement signals, characterized in that the push-pull amplifier is used at the same time as an addition stage for the stepped auxiliary voltage (a), such that the grid of the one push-pull tube (450) successively the three output color signal components of the transmission four-pole and the grid of the the step-shaped auxiliary voltage (a) is fed to another push-pull tube (460) and both tubes are coupled via a common cathode resistor (453) (FIG. 2). 2. Arrangement according to claim 1, characterized in that the control electrodes of the electron paths of the commutator tubes (120, 220, 320) are galvanically connected to those of the switching tubes (110, 210, 310) of the electronic triple switch to set the reference values in the measurement signal at the same potential so that the control electrodes of the switching tubes (110, 210, 310 ) assume the same potential, defined by the use of grid current, of the control electrodes of the commutator tubes (120, 220, 320). Documents considered: German Patent No. 911 397; "Electronic Engineering", February 1958, pp. 66 to 70.