DE1254179B - Circuit arrangement for controlling an AC voltage divider by light - Google Patents

Description

Circuit arrangement for controlling an AC voltage divider by light The invention relates to a circuit arrangement for controlling an AC voltage divider, especially in the video amplifier part of a television receiver, through changeable lighting of a light-sensitive one contained in the voltage divider Resistance (photoconductor) with a light source fed by alternating current.

The resistance of a photoconductor generally does not follow immediately the intensity of the incident light, but has a noticeable aftereffect so that there is a certain indolence. The resistance changes with transitions roughly exponential, and the decay time can be defined as the time in which In the event of a sudden change in light, the resistance value changes to a residual of lfe (about 3511 / o) has approached the final state. Preferably when using from gas discharge lamps (e.g. glow lamps, fluorescent lamps) indicates the light Mains alternating current supply causes considerable fluctuations, which affect the voltage divider have a strong effect, since the inertia effect of a photoconductor is generally considerable is smaller than one period of the mains alternating current.

If now the voltage divider itself carries alternating current, z. B. low frequency or video signals, there is a disruptive modulation of these signals and possibly an interference signal component corresponding to the network frequency or a harmonic thereof.

In order to do this in the case of a light-sensitive element responsive to momentary fluctuations, e.g. B. a photocell, to avoid, according to British patent specification 581373, the alternating current feeding the illuminating incandescent lamp is changed so that it has an approximately rectangular curve shape. Such changes in the curve of an alternating feed current require considerable effort. According to British patent specification 566 429, in a television camera for a scene illuminated with fluorescent lamps, part of the fluctuating light is fed to the receiving element which is sensitive to rapid instantaneous fluctuations, and compensation is sought as a result. For a good effect, the compensation circuit must be adjusted with tight tolerances, and this precise setting must also be maintained in the long term, which also requires considerable effort.

In a circuit arrangement of the type mentioned above, the Effects of the alternating current feeding the light source in a simple manner sufficient security is avoided, and an undisturbed transmission of AC signals achieved via the photosensitive resistor if according to of the invention, the fluctuations in the alternating feed current of the light source from the photoconductor be kept away.

This can be achieved by taking action on the light source which prevents the occurrence of fluctuations in brightness, or by taking measures on the photoconductor, which causes a change in the resistance value due to the fluctuations in brightness is avoided, or by arranging compensation means between the light source and photoconductors, through which the transmission of the brightness fluctuations to the photoconductor is prevented.

Fluctuations in brightness of the light source can be avoided by using an incandescent lamp, the filament of which has a high thermal inertia. This is achieved in particular when using a filament made of relatively thick wire; it is therefore appropriate to use a low voltage incandescent lamp, e.g. B. between 0.5 and 6 volts to use. It is also possible to use several light sources which are fed by alternating currents shifted in phase with respect to one another in such a way that the brightness maxima and minima overlap one another.

The desired effect can also be achieved in that the period of the alternating feed current for the light source is significantly smaller than the decay time of the photoconductor. At a given frequency of the alternating feed current, a photoconductor with a correspondingly long decay time should be used; However, if the photoconductor and its decay time are given, an alternating supply current must be selected whose period is shorter to the extent mentioned. This is particularly important when the decay time is in the order of magnitude of the period of the mains alternating current; the supply of the light source should be of a Ge - carried genüber the network significantly higher frequency power source. In a television set, the line deflection circuit can be used for this purpose.

A direct measurement of the decay time of the photoconductor can be avoided if the photoresistor is illuminated with an alternating light source and the frequency of the light change is regulated, e.g. B. in a range between 20 and 200 Hz. The resistance fluctuations occurring on the photoconductor can be made visible on an oscilloscope or measured in another way. A cut-off frequency can then be determined at which the change in resistance has decreased to 70 % of the resistance with bright permanent lighting. The desired independence of the resistance is achieved when the frequency of the brightness fluctuations of the light source is significantly higher than this limit frequency.

The effects of fluctuations in the intensity of the light source can also be avoided by arranging a light storage device in the vicinity of the photoconductor. This absorbs light during the maximum brightness and emits it again during the minimum brightness. It is expedient to use phosphorescent material whose afterglow time is considerably greater, preferably 10 to 1000 times greater, than the period of the alternating feed current. Since the brightness of the light emitted by phosphorescence is generally considerably lower than the brightness of the incident light, it is advantageous to arrange the phosphorescent material as a, in particular light-permeable, layer between the light source and the photoconductor. Then the incident light is only weakened, but the phosphorescent light is passed through to the photoconductor with practically no influence, so that the intensity ratio becomes more favorable.

The invention is explained in more detail below with reference to the drawing, for example, which is shown in FIG. 1 shows part of a television receiver with a circuit arrangement according to the invention, while in FIG. 2 and 3 show the arrangement of an incandescent lamp and a photoconductor with an adjustable diaphragm or with a phosphorescent layer.

The television signals are the grid of a video amplifier pentode 1, z. B. of type PL 83, lead to-J., Cr the cathode of which is grounded. Your screen grid is via a series resistor 2 of z. B. 4 kOhm with the positive pole of the other hand grounded supply source of z. B. 200 volts and connected via a capacitor 3 of z. B. 8 pF grounded, the i anode of the tube 1 via an inductor 4 and a resistor 5 of z. B. 3 kOhm connected to the positive pole. At the anode of the tube 1 , the amplified video and sync signals occur, which are fed to the picture tube 6 and the deflection device 7 1.

In a television receiver, it is important to have the contrast, i. H. to change the amplitude of the video signals fed to the picture tube, in particular to allow adaptation to the wishes of the viewer. In known circuits, the contrast control was carried out by changing the gain of the preceding stages, in particular of the intermediate frequency part. This can also change the operating point of the video tube and a shift in the black level can occur. Furthermore, there is a change in the amplitude of the sync pulses to be fed to the deflection stages. This requires additional circuitry to compensate for these changes. A much simpler solution is obtained if the signal amplitude is kept constant up to the output of the video amplifier and the desired control of the contrast is carried out by a voltage divider placed between the video tube and the picture tube. Since such a voltage divider has to carry a video frequency, i.e. oscillations from 0 to 5 MHz, it must be ensured that the variable part in particular has as few additional elements as possible so that the stray capacitances of the video channel do not increase in an inadmissible manner and thus the transmission for the high frequencies is affected. The use of a mechanically adjustable resistor, which would also have to be operable from the outside, should therefore be avoided.

A cheap solution is obtained by using a voltage divider, which uses a light-sensitive resistor (photoconductor), its resistance value is changed by a controllable exposure. As in the usual devices for the A light source is generally only supplied with alternating current, the difficulties mentioned at the beginning of a periodic change in resistance arise due to fluctuations in brightness.

In the arrangement of FIG. 1 , the voltage divider consists of the photoconductor 10, which is connected in series with a resistor 11 of, for. B. 18 kOhm is switched on between the anode of the tube 1 and the positive pole. The cathode of the picture tube 6 is connected to the connection point of the resistors 10 and 11 . The video voltage supplied to the picture tube 6 is thus changed depending on the ratio of the resistance of the photoconductor 10 to the value of the fixed resistor 11 ; Preferably, a photoconductor 10 is used, the value of which, when there is no illumination, is about 10 to 30 kOhm or significantly more, while at an illuminance of 1000 lux the resistance drops to about 100 to 3000hm. The value of the photoconductor 10 is controlled by the light of an incandescent lamp 12, for example in that an adjustable diaphragm 13 is arranged between the incandescent lamp 12 and the photoconductor 10.

According to the invention, the alternating supply current for the incandescent lamp 12 is taken from the line deflection circuit 7. The above-mentioned cut-off frequency of conventional photoconductors is approximately between 20 and 150 Hz. Since the line frequency is approximately 15 kHz, the exposure fluctuations have no effect on the resistance value of the photoconductor 10 .

A change in the brightness of the light source 12 can of course also be changed by means of a series and / or parallel resistance in the supply line circuit, as indicated by dotted lines at 14. The lead for the light source 12 can be connected to a suitable tap of a suitable voltage of the flyback / deflection transformer. One can also assume a tap that delivers a much higher voltage if one uses a series resistor, e.g. B. turns on a capacitor or an inductor. In this case, the brightness of the light source 12 is expediently regulated by a resistor lying parallel to it. Of course, it is also possible to use an incandescent lamp 12 whose operating voltage corresponds to the voltage at the desired tap of the flyback transformer, which z. B. 110 V.

When change in resistance of the photoconductor 10, the position of the black level shifts to the picture tube in general 6. To compensate for this, the photoconductor 10 and the resistor 11 may be a potentiometer 15 of z. B. 50 kOhm be connected in parallel, the slider via a series resistor 16 of z. B. 47 kOhm is connected to a brightness potentiometer 17 , which on the other hand is connected to earth. To the wiper of the brightness potentiometer 17 is via a series resistor 19 of z. B. 100 kOhm another control electrode of the picture tube 6, z. B. the Wehnelt cylinder connected, with a smoothing capacitor 18 of z. B. 5 pF is switched on between the wiper of the potentiometer 17 and earth.

A change in the black level when the photoconductor 10 is controlled can also be avoided by connecting the resistor 11 not to the positive pole but to a potential point corresponding to the black level.

This is in FIG. 1 indicated by dashed lines by a voltage divider composed of resistors 28 and 29, which is placed parallel to the supply source. Its tap is connected to resistor 11 . This voltage divider can optionally contain a potentiometer in order to be able to set the desired level value. In the circuit specified, the impedance between the cathode of the tube 6 and the supply source by the voltage divider 28, 29 should not be changed significantly, that is, the impedance obtained by connecting the resistors 28 and 29 in parallel should be small compared to the value of the resistor 11 . This allows for the resistors 28 and 29 provide, if appropriate, values that bring an undesirable load of the power source with it. An improvement can be achieved if the resistor 11 is omitted and replaced by a direct connection and if the resistors 28 and 29, which are dimensioned taking into account the desired voltage divider ratio, have correspondingly larger values for this. As a result, the cross-flow that loads the supply source can be significantly reduced.

F i g. 2 shows an arrangement for changing the exposure of the photoconductor 10 with the aid of an adjustable diaphragm 13.

An incandescent lamp 12 is arranged on a chassis 20 and is connected to the power source via connecting wires 21. In addition to the incandescent lamp 12, the photoconductor 10 is arranged, the connections 22 of which are connected to the relevant voltage divider. In a wall 23 of the device housing, an axle 24 is mounted, which on the one hand carries an adjustment button 25 and on the other hand the diaphragm disk 13. The edge of the diaphragm disk is approximately spiral-shaped, as in particular in FIG. 3 can be seen, which represents a section perpendicular to the axis 24. When the button 25 is moved, the diaphragm 13 is pushed between the light source 12 and the photoconductor 10 in such a way that the photoconductor is exposed increasingly weaker and thus its resistance increases, so that the desired change in the voltage divider 10, 11 occurs.

Even if the incandescent lamp 12 is connected to a power source of mains frequencies via the line 21, the effects of the light fluctuations can be eliminated or at least substantially reduced if a plate 26 is arranged between the light source 12 and the photoconductor 10 and carries a layer of phosphorescent material . This plate can effect a certain compensation of the fluctuations in brightness, so that disruptive fluctuations in resistance of the photoconductor 10 are avoided.

Claims (2)

Claims: 1. Circuit arrangement for controlling an alternating current voltage divider, in particular in the video amplifier part of a television receiver, through variable lighting of a light-sensitive resistor (photoconductor) contained in the voltage divider with a light source fed by alternating current, characterized in that the fluctuations in the alternating supply current of the light source (12) be kept away from the photoconductor (10). 2. Circuit arrangement according to claim 1, characterized in that the light source (12) is an incandescent lamp which is fed by alternating current, preferably low voltage, for example 0.5 to 6 volts, and the filament has a high thermal inertia, such that none the resistance of the photoconductor (10) noticeably changing brightness fluctuations occur. 3. Circuit arrangement according to claim 1, characterized in that a plurality of lamps, for. B. incandescent lamps, which are fed with alternating currents shifted in phase with respect to one another. 4. Circuit arrangement according to claim 1, 2 or 3, characterized in that the period of the alternating feed current for the light source (12) is significantly smaller than the time constant of the photoconductor (10). 5. Circuit arrangement according to claim 4 in a television receiver, characterized in that the alternating feed current is taken from the line deflection circuit (7). 6. Circuit arrangement according to at least one of the preceding claims, characterized in that the photoconductor (10) phosphorescent material (26) is arranged, the persistence of which is considerably, preferably 10 to 1000 times, greater than the period of the alternating feed current. 7. Circuit arrangement according to claim 6, characterized in that the phosphorescent material (26) is formed in layers. 8. Circuit arrangement according to claim 7, characterized in that a particularly transparent layer of phosphorescent material (26) is attached parallel to the exposed surface of the photoconductor (10) , preferably between the light source (12) and the photoconductor (10). 9. circuit arrangement according to at least one of the preceding claims in the video part of a television receiver, characterized in that one end of the voltage divider (10, 11) is connected to a potential point corresponding to the black level of the video signal. 10. Circuit arrangement according to claim 9, characterized in that the voltage divider (10, 11) is connected to the tap of a potentiometer circuit (28, 29) lying parallel to the supply source. 11. Circuit arrangement according to claim 9 and 10, characterized in that the resistor (11) of the voltage divider (10, 11) which is not dependent on the light is formed by the potentiometer circuit (28, 29) lying parallel to the supply source. Documents considered: French Patent Specifications Nos. 1201 512, 1 247 855; British Patent Nos. 566 429, 581373.