DE1135030B - Circuit arrangement for generating a pulse-shaped test signal for television purposes - Google Patents

Description

The invention relates to a circuit arrangement for generating a pulse-shaped signal with the aid of a pulse generator with a relaxation oscillation duration of τ seconds, which is controlled by erasing start pulses b ' with a fixed period time Tq, where T ₀ > τ, and where both the duration of the pulses b 'and the duration of the relaxation oscillation can be changed as desired. This signal should, if necessary, after conversion in a pulse-shaping circuit for testing pick-up tubes, e.g. B. of the type. BiIdikonoskops or the image orthicon, serve. During this test, it is important to have a test signal available to determine whether the geometry of the image provided by the pickup tube is a faithful representation of the scene being recorded.

For this purpose it is known to have a test card with a large number of small circles in front of the receiving tube to arrange. The test image of this card is recorded by the recording tube and using a control tube.

This control tube is also supplied with a test signal, by means of which a measuring grid on the Display screen of this tube is written. Because the lines of the measuring grid are perpendicular Direction can be shifted to the greatest possible extent with the centers of the Circles of the test pattern are brought to coincide. Because the test signal has almost no deviations and the errors of the control tube on the reproduction of the test image have the same influence how to exercise on the measuring grid are the deviations of the test pattern with respect to the measuring grid almost equal to the errors of the pickup tube.

The circuit arrangement described in the present application is used to supply a control voltage, with the help of which the test signal can be generated. The circuit device becomes for this purpose indirectly through image and line synchronization pulses controlled. These synchronization pulses are supplied by a common pulse generator for the camera and not only control the circuit arrangement mentioned, but also the deflection circuits for the recording and control tube so that there is a close relationship between deflection currents or voltages the recording and control tubes and the test signal.

The circuit arrangement for generating a pulse-shaped signal which, if necessary after Conversion into a pulse-shaping circuit, circuit arrangement

to generate a pulse-shaped

Test signals for television purposes

Applicant:

NV Philips' Gloeilampenfabrieken,
Eindhoven (Netherlands)

Representative: Dr. rer. nat. P. Roßbach, patent attorney, Hamburg 1, Mönckebergstr. 7th

Claimed priority:
Netherlands of 8 May 1958 (no.227 635)

Louis Maarten Swart, Eindhoven (Netherlands),
has been named as the inventor

a control tube is fed as a test signal in order to write a measuring grid on the screen of the same in connection with the scanning mechanism of this tube for the purpose of testing the geometry of the pick-up tubes, the output signal of which is also fed to the control tube, the test signal being generated with the aid of a pulse generator which has a relaxation oscillation period of τ seconds, which is essentially determined by the discharge time of a resistor capacitor combination, during which time the voltage across the capacitor decreases from a first to a second voltage value determined by the generator circuit, and the pulse generator is activated by erasing start pulses b ' is controlled with a fixed period of r _o -seconds, where T ₀ > τ applies and both the duration of the pulses b ' and the relaxation period τ can be changed as desired, is now characterized in that the pulses b' on two separate, one another non-influencing ways of the impulse genera tor are supplied, in such a way that the pulses supplied on the first path block the pulse generator for the duration of their occurrence, while the pulses supplied on the second path b ' the pulse generator as quickly as possible after the occurrence of their leading edge, but within the duration of a Impulse b ', get ready to start, what this second way is for

209 637/180

consists of a second capacitor and a one-sided conductive element, and the pulses b ' are fed via the latter two elements to the first-mentioned capacitor with such a polarity that the resulting current discharges the first-mentioned capacitor. A first pulse shaping circuit, to which image synchronization pulses are supplied, can be connected upstream of the circuit arrangement mentioned, and a second pulse shaping circuit can be connected downstream from which the test signal can be taken.

Signal generators for generating a test signal are known. The delete start impulses are but fed here on a single path, while in the test signal generator according to the Invention, these pulses are fed in two mutually non-influencing ways.

A possible embodiment of a circuit arrangement according to the invention is shown below Hand of the figures explained in more detail.

Fig. 1 shows that displayed on the control tube Test image with measuring grid;

2 serves to explain the pulses necessary for generating the measuring grid;

3 shows the actual circuit arrangement schematically;

FIG. 4 again serves to explain the mode of operation of the circuit according to FIGS. 3, and

Fig. 5 shows a somewhat expanded circuit diagram, as is the case with a signal generator for generating a test signal is used.

In Fig. 1, the circles /? represents the test image originating from the pick-up tube, while the lines r \ to rj _{3 form} the measurement grid written by the test signal. By first bringing the lines as closely as possible to coincide with the centers of the circles P ₁ to P ₁₇ and then shifting the lines r ₂ to r ₁₃ with respect to r \ , ie changing the distances between the lines r \ to r _13, it can be determined which are the deviations of the pick-up tube in the vertical direction. It should be evident that the numbers chosen here of thirteen lines per grid and seventeen circles per line, as they are normally customary, can be increased or decreased as required. In order to generate a test signal which can write a measuring raster which fulfills the above-mentioned requirements, a control voltage according to FIG. 2a must be supplied by the circuit arrangement according to FIG.

In Fig. 2a, the pulses Z ₁ to Z ₂ K +1 are the actual output pulses that are fed as start pulses to the downstream pulse shaping circuit that delivers the actual test signal. It is important that the pulses' Z ₁ , Z _{K + 1} , Z ₂ B + 1 etc. coincide with the trailing edges of the pulses b \, _{έ 2} , lh, etc., which also, albeit without any functional purpose , are contained in the output signal and correspond to the erase start pulses b \, b ₂ , b $, etc. which are fed to the input terminals of the circuit arrangement according to FIG.

For television purposes, the period 7J) of the pulses b \, Z) ₂ , b} etc. must correspond to the time required for scanning a raster of the television picture to be checked. It is necessary that no pulses Z are emitted at the beginning of a new raster, because a test signal should only be generated after a few lines of the raster have been written, namely after a time T ₁ . In Fig. 2a there are e.g. B. J _{1 at} the end of a grid time, and at time ty + T ₁ , which corresponds to the beginning of line J ₁ , the first test pulse must be generated. For this it is necessary that T _{1 is} equal to the vertical retrace time plus a few line times, the number of line times corresponding to the number of lines of the raster to be rewritten that are to be allowed to pass before a test pulse is emitted.

The following problems also arise in generating the test signal.

The line r \ must be movable, that is, the point in time t _x + T ₁ , at which the first test pulse per grid is emitted, must be adjustable as required. At a certain value of r, the period time of the pulses Z, this means that in each case the last of the pulses Z belonging to a certain grid (ie the pulses Z ₀ , Z _n , Z _2n , etc.) at a relatively arbitrary point in time before subsequent erase start pulses O ₁ , b ₂ , h etc. occurs. Nevertheless, it must always be ensured that the pulse generator delivering the pulses Z is blocked by the leading edge of the relevant pulse b and unblocked by the trailing edge of the same pulse.

From Fig. 1 it can be seen that only thirteen test lines are written per image, so that only thirteen test pulses have to be generated during a raster period ( η- 13 is selected here). In addition, because the lines r ₂ to r ₁₃ must be movable with respect to / ·], the period time τ must be variable, so that not only the time of occurrence of the first pulse of each raster, but also the times of occurrence of the subsequent pulses, which belong to the same grid must be freely adjustable.

As a result of the interlace principle, the test pulse belonging to the odd-numbered grid is shifted by half a number of lines with respect to the test pulse belonging to the even-numbered grid. If z. For example, if it is assumed that b \ belongs to an odd ^{-numbered raster and Z ^ to} an even-numbered raster, then T ₀ corresponds to the time required to write half the number of lines which together form the image. Because Ti of b _{x is the} same as Tj of b ₂ , the pulse Z _n + \ is shifted by half a line time with respect to the even-numbered grid to be written, as is the pulse Z ₁ with respect to the odd-numbered grid to be written. As a result, the line t \ consists of two mutually shifted lines, namely one line written during the even-numbered raster and one written during the odd-numbered raster. However, this shift in relation to the diameter of the circles is so small that they can be viewed as a single line for the measuring grid. The same applies, of course, to lines r ₂ to π 3.

Because only a few test pulses are emitted per grid period, the period time τ is usually greater than the duration T _{1 of} one of the pulses b. However, because both T ₁ and τ can be changed at will, there is a possibility that τ <T _{1 may also} occur. In the latter case, the problem of locking and unlocking the pulses Z

5 6

delivering pulse generator in a simple way flank of the pulse b { the tube 1 and holds it releasably in that z. B. the pulses b {', b ₂ ', b / blocked for the duration T _{x of} this pulse. The etc. with a polarity blocking the generator, however, affects the voltage at the resistor 10 which are supplied. Discharge of the capacitor 8 does not, so that if, on the other hand, τ> T ₁ , then from Fig. 2b, 5 the leading edge of b _{x occurs} shortly before the moment that the pulses b _h b ₂ , b \ etc. the generator occurs in which the voltage across the capacitor 8 insufficiently influence. the value - V _g volts would reach, this Kon-If one looks at the pulses Z ₀ and Z ₁ , the capacitor can calmly continue to occur up to earth potential from the times fo or to + .τ occurs. This ground potential can be seen in FIG. 4 by the fact that the pulse generator indicates the line 0 from the top. From the trailing edge of the emerging pulse b _x is not controlled at all. If pulse b _{x were to occur} , tube 2 would be blocked again at time t \ + T _x, however, time t ₀ + τ before the time. The capacitor 8 had, as ti + 71 fall, then the pulse b _x would have assumed the occurrence ¹ above, no more charge, so the pulse Z ₁ at time t ₀ + τ prevent the tube 1 from being affected by the voltage and this occurrence after time t \ + T _x , 15 is blocked at resistor 10, anode and in which the generator is no longer blocked, conduct grid current and start a new cycle. can until the leading edge of the pulse bi in time

The circuit arrangement according to Fig. 3 gives center point t _x + T _0, the tube 1 locks again,
in order to achieve that in every situation an off. If τ < T _x , then the circuit output signal according to FIG. 2a is generated. 2 ° arrangement good without the auxiliary diodes 5 and 6, because this circuit arrangement consists of a discharge tube 1 connected as the capacitor 8 regardless of the time difference blocking oscillator, an h - * b always has the opportunity to connect to ground potential, blocking tube 2, at whose control grid the Pulses b ' or at least to a negative voltage, the containing input signal via the capacitor 3 is less than | V ₀ | Volt is to be discharged, so that the and the bleeder resistor 4 is fed, and 25 new cycle of the blocking oscillator always almost always consisting of the preferably formed as germanium diodes at the same time with the occurrence of the trailing edge of an auxiliary diode 5 and 6. The blocking oscillator of the pulses b ' begins.

itself consists of the tube 1, the transformer 7, but if τ> T ₁ , the two cases described above for the charging capacitor 8 and the variable above can occur.
Resistor 9. It is known that the Aufladekonden- 30 Smaller namely the timing t \ immediately before sator 8 by momentarily flowing from the control grid point in time t ₀ + τ, so the tube is due to the fact 1 derived grid current in a negative that the capacitor 8 is already largely discharged meaning charged and then via the resistor 9, the oscillator is ready to discharge at time t _x + T _x until the voltage on this capacitor start. The less the points in time to and t _x differ from each other from the reverse voltage - V _{0 of} the tube 1 35, the lower it becomes, after which the anode and grid currents can in turn cause the capacitor to flow on the and 8 is recharged . This is in value - V _{9 can} discharge, so that the case a-Fig. 4, in which the grid voltage can also occur, that although the tube 2 does not have any current peaks Z ', Z " , etc., which lead to more, the blocking oscillator does not yet have time intervals of ν seconds from one another is ready for the start, so that the pulse Z _x does not occur. coincides with the trailing edge of b _x (see Fig. 2b). In the above explanation, it was noted that the tube 2 does not Current leads, so tive impulses b ' not only the tube 2, but that, if the negative voltage on the capacitor 8 is also greater than | V _g | volts to the auxiliary diodes 5 via the capacitor 11, the cathodes of both 45 and 6 are fed positive impulses b ' tubes are at ground potential. Each after now able to supply the capacitor 8 via the diode 5 T-seconds, the tube 1 briefly supplies anode with a positive charge is thus quickly reduced voltage pulses Z over the common cathode.

resistance 10 can be generated. The Kippschwin- 50 By correct choice of the capacitance values of the duration τ of this oscillator can be ensured on a capacitors 11 and 8, by changing the resistor 9, that in every situation the remaining negative span lengthen or shorten. voltage at the capacitor 8 is less than [ V _a \ volts (which As already mentioned, the pulses b ' above the reverse voltage of the tube 1) is so that the tube 2 is supplied in the eye, in such a way that, for. B. the 55 look by the tube 2 unlocked from the trailing edge of the pulse b \ at time t _x, the tube 2, the relevant delete start pulse is blocked, so that a large current through the resistor 10-locking oscillator ready to start is. The fast one flows. The cathodes of the two tubes are discharging of the capacitor 8 is favored by the fact that the current economy is thus at a positive potential with respect to earth, so that the potential difference between the voltage at the capacitor 8 and the voltage between the grid and the cathode of the tube 1 equal to the sum of the input terminals (which is generated by the impulses A 'occurring in this of the voltages on the capacitor 8 and on the resistive moment ) was 10. The voltage across the resistor must add up to each other. De * discharging current (if 10 is so large that the tube i is blocked, even if the grid of the capacitor 8 supplied by the control grid of tube 1 would be completely discharged. How 65 current is regarded as the charging current) through the times? O and U also correspond to each other, the capacitors 11 and 8 k * are thus larger, vv-nn are distant (whereby of course t _x - to never the negative voltage on capacitor 8 is large. Can be larger than τ ), the front ie if the time Ό vi ~; "- can be changed before the

Time ti falls as if the negative voltage vibrators are preferable, if, on the other hand, the period is small, that is, if to and J _{1 are} further apart from each other, time τ is long (as in the embodiment described

^en ^ ^ern J: ^smd ', " _E . ,, AVA * ο example, in which τ = - ^ s ), then there is a blocking-Da for the rapid discharge of the capacitor 8 ^v ' - 650 ^{BJ F}

the resistor 9 hardly plays a role and the 5 oscillator is preferred ".

Impedance of the diode 5 in the conductive state. It should also be noted that the blocking of the

is negligible, with some approximation the pulse generator can not always be written by the pulses b ' : this needs to be done via a separate blocking tube.

If the internal resistance of the pulses b '

ρ _ (ρ ι ρ \ Q ίο supplying voltage source is small enough, can

ii ^ ₁ -ι- & o) _{Cii + Cg this} j _m p _{ulse aucn} directly to the resistance 10

and FIG. 3 are supplied.

ρ - ff ·. Λ. ρ) Cn Di ^e main thing is that the pulses b 'single

£% - \ ι + <v Q ₁ ^. Q _ma i lock the pulse generator and turn it to

15. get others ready to start at the same time,

The following applies: however, without lifting the block early.

ε- α- α ι · + α α τ 1 ui If, in addition, the duration of the pulses b 'is smaller

E _{1 is} the amplitude of the pulses * as the relaxation period τ of the pulse generator

E ₀ the voltage at the capacitor in the time ^ _while ££ _d ^% _{e take into account} the last

pun ti, 30 mentioned condition both the pulse duration and

E ₁₁ the resulting voltage on the condenser - _the relaxation period independent of one another

sa or ίί,, ο T ^ j are changeable, so it is imperative that the

Ek the resulting voltage on the condenser- Function of locking and unlocking of the-

sator », that of bringing the impulse ready to start

C _{8 the capacitance value of} the capacitor 8 and ₂₅ ^J * _{rator m separate} . _Otherwise £ _{Wanting nd as vorsten} e

C _{11 is} the capacitance value of the capacitor 11. The desired effect has not been proven

If necessary, E% can also be achieved as a positive one.

Assume value if only care is taken that Fig. 5 shows the circuit of the complete signal, the tube 1 is consequently not unlocked, generator. The circuit according to FIG. 3 is a first pulse shaping circuit before the trailing edge of the relevant pulse b '30 , which initiates the start of a new cycle from a. the monostable containing the tubes 12 and 13 The possibility that E $ exists upstream of a positive value multivibrator and assumes a second, becomes greater as t ₀ and I ₁ pulse shaping circuits are connected downstream which are further apart. also from a monostable multivibrator-The diode 6 ensures that the circuit with the cathode 35, which contains the tubes 14 and 15, the diode 6 connected coating of the capacitor 11 is the first multivibrator in the stable received only such a negative charge can, state, the tube 12 is blocked and the tube that the potential of this coating is equal to - V ₀ . 13 unlocked. The control grid of the tube 12 is supplied with the voltage of | V ₀ | Volt. 40 supplied by a separate, not shown, now the positive image synchronization pulses b " voltage source, whereby the first multivibrator is used for this purpose stable set in the unstable state voltage source to the anode of the diode 6, and which is. the duration of this unstable state, the positive terminal connected to ground. Thus, the duration T \ is equal to the obtained from this multivibrator at the same time that the voltage at the condensate given impulses b ' is not greater than - V _c correct by the capacitor 8, which is charged by the grid current of the tube 1 in the negator 16 and the variable resistor 17. With the help of this resistor 17 volts can thus change the value of Ti , which is indicated in Fig. 4. Of course, this has the advantage that, as the tube 1 ages, the Da outside of the momenta b 'is never less than the- | the period of the ImpulseZ almost does not change, one who der.Impulse b "are made, because the capacitor 8 is given by the up 50. The pulses thus obtained b 'are the scarf always the same charge voltage of | V ₀ j volts, tung arrangement 3, which in spite of the fact that as the tube ages in the manner described above, a signal after grid peak current may decrease sharply because of Fig. 2a, this signal becomes the second blocking voltage of -V ₉ volts as it ages This second tube changes relatively little, the multivibrator is in a stable state, the capacitor 8 always has the fixed value of when the tube 14 is blocked and the tube 15 is reduced to -Vc volts to which it blocks relatively little The output signal according to Fig. 2a is _{now fed to the control grid of the tube 14 in a changing value from −F −} volts via the resistor 9 and is discharged, so that the relaxation oscillation period er τ always puts this multivibrator in the unstable state due to the set resistance value of 9. The duration of this unstable condition is true. which is approximately equal to a line time, is also evident from the fact that the pulse generator Z capacitor 18 and the variable retransmitting pulse generator is not necessarily designated as a blocking state 19 and can thus again be formed by an oscillator. A change in the latter resistance can also be arbitrarily set-multivibrator with two different unstable 65 sets. It should also be noted here that states can be used for the relevant purpose such that only impulses Z should be able to find the second application. If the period time τ is too short a ratio multivibrator in the unstable state, the use of a multivibrator is to be used, but not those that occur in the Z series

ό pulses (Fig. 2), which have a lower amplitude.

The output signal can be taken from the anode of the tube 15. However, it will be a If a signal of opposite polarity is desired, it can also be taken from the anode of the tube 14 will.

Because the aforementioned output signals must be determined not only by the frame synchronization pulses b ", but also by the line synchronization pulses /, the latter are also fed to the first multivibrator circuit and the pulse generator via the capacitors 20 and 21. The positive ones fed via the capacitor 20 Line pulses ensure that the trailing edges of the pulses b ' always coincide with the beginning of a line, while the line pulses supplied via the capacitor 21 ensure that each of the pulses Z coincides with the beginning of a line.

The amplitudes of these line pulses must be small so that the trailing edges or the Pulses Z shifted by a fraction of a line time and not by a whole or several line times can be.

The output signal of the signal generator is thus a pulse-shaped signal, the duration of the pulses almost corresponding to that of a line time. The beginning of the first pulse of each grid can be relocated as required by changing the time T \ , while the starting times of the following pulses of each grid can be shifted as required by changing the time τ. This test signal is fed to the control tube so that the measuring grid can be written in conjunction with the scanning mechanism of this tube.

If vertical lines, which also go through the circles P, are to be added to this measuring grid of horizontal lines, this can be done by generating a second pulse-shaped signal, the period of which must be chosen so that the same number of pulses are emitted per scanned line of the relevant image grid how there are circles.

This pulse-shaped signal can be achieved in that the line synchronization pulses by a Pulse shaping circuit are deformed and then trigger an oscillating circuit, which is based on a Frequency is tuned, which is equal to the reciprocal of the mentioned period time. Also is a feedback loop provided in order to de-dampen the oscillation circuit at the right moments. A pulse-shaped signal is derived from this oscillation generated in this way, which corresponds to that of the Circuit arrangement according to FIG. 5 resulting test signal is combined, after which the combination is fed to the control tube.

Claims (7)

PATENT CLAIMS: 1. Circuit arrangement for generating a pulse-shaped signal, which, if necessary after conversion in a pulse-shaping circuit, is fed to a control tube as a test signal in order to write a measuring grid on the screen of the tube in conjunction with the scanning mechanism for the purpose of testing the geometry of Recording tubes, the output signal of which is also fed to the control tube, the test signal being generated with the aid of a pulse generator, which has a relaxation period of -r-seconds, which is essentially determined by the discharge time of a resistor capacitor combination, during which time the voltage across the capacitor of a first to a second voltage value determined by the generator circuit, and the pulse generator is controlled by erasing start pulses b ' with a fixed period of Γο seconds, where Tq> τ applies and both the duration of the pulses b' and the relaxation period τ arbitrary are changeable, characterized in that the pulses b ' are fed to the pulse generator (1) on two separate, mutually non-influencing paths, namely in such a way that the pulses (Z> 0) fed to the first path (2) the pulse generator ( 1) for the duration of their occurrence, while the pulses b ' supplied on the second path (11, 5) bring the pulse generator (1) ready to start as soon as possible after the occurrence of its leading edge, but within the duration of a pulse b' , for which this second path consists of a second capacitor (11) and a one-sided conductive element (5), and the pulses b ' via the latter two elements (11,5) are supplied to the first-mentioned capacitor (8) with such a polarity that the resulting current discharges the first-mentioned capacitor (8). 2. Circuit arrangement according to claim 1, in which the pulse generator is designed as a blocking oscillator with a discharge tube and a transformer, the primary winding of which is in the anode circuit and the secondary winding of which is in the control grid circuit of the discharge tube, while the whole is fed from a supply voltage source, characterized in that the The resistance capacitor combination (8, 9) determining the breakover period τ is connected as a parallel circuit between the end of the secondary winding facing away from the control grid and the negative terminal of the supply voltage source, the one-sided conductive element (5) preferably being designed as a germanium diode, the cathode of which is connected to the resistance capacitor combination (8, 9) and whose anode is connected to the second capacitor (11), while the erase start pulses b ' are fed to the second capacitor (11) with positive polarity. 3. Circuit arrangement according to claim 2, characterized in that there is an impedance (10) in the cathode circuit of the discharge tube (1), the erase start pulses b ' via the first path (2) with a positive polarity of the cathode of the discharge tube ( 1) can be supplied. 4. Circuit arrangement according to claim 3, characterized in that the first path (2) consists of a second discharge tube (2), to whose control grid the positive pulses b 'are supplied and whose cathode is connected to the cathode of the first-mentioned discharge tube (1) is, the output signal can be taken from the two directly connected cathodes. 209 637/180 5. Circuit arrangement according to one of claims 2, 3 or 4, characterized in that the cathode of a second, preferably designed as a diode, unilaterally conductive element (6) is connected to the anode of the first unilaterally conductive element (S) , while the anode of the second unilaterally conductive element (6) is connected to the minus terminal (—V _c ) of a second supply voltage source, the plus terminal of which is connected to the minus terminal of the first supply voltage source. 6. Circuit arrangement according to one of the preceding claims, characterized in that that the pulse generator (1) has a first pulse shaping circuit (12,13) which is the beginning synchronization pulses that determine the vertical return are supplied, and a second converting the output signal obtained from the pulse generator (1) Pulse shaping circuit (14,15), from which the test signal can be taken, is connected downstream. 7. Circuit arrangement according to claim 6, characterized in that synchronization pulses, which determine the beginning of the horizontal return, both of the first pulse shaping circuit (12,13) and the second capacitor (11) of the pulse generator circuit are fed. Considered publications:
Electronic Rundschau, No. 10, 1956, pp. 270 to 274; Archive of electrical transmission (AEÜ), 1955, no. 12, pp. 547 to 558. 1 sheet of drawings