NO141857B - DEVICE FOR COLLECTING ONE WITH A TELEPHONE PROVIDED NET TO A NET PACK - Google Patents

Description

Contrast control device for television receivers.

The present invention relates to contrast control devices which are particularly suitable for television receivers.

There are previously known contrast control devices which produce an automatic reduction of the contrast in television images which include many or large white image parts, and an increase of the contrast for televis ion images which mostly consist of black and dark gray halftones. Such contrast control devices are capable of correcting for the normal variation of the black level which is permissible in normal transmissions. These systems will also be able to reduce and largely eliminate the unwanted flickering effect that occurs when the image contains large white areas, even if the contrast is correctly set. Such known contrast arrangements will also be capable of reducing the unfortunate effect that a slight misalignment of the background lighting will cause, i.e. a relatively large loss of information in cases where there is little image contrast and essentially dark reproduction and in cases where where there is insufficient modulation of the transmitter, such as during film transmission.

However, such known contrast control devices have the shortcoming that the dark image parts, which in many cases are already sent with poor quality, are further regulated and thereby have even less contrast.

It is therefore an object of the present invention to provide a contrast control device which overcomes the above-mentioned shortcomings.

Another object of the invention is to provide a contrast control device which has a characteristic such that the reproduction of the darkest shadow values is made possible with the greatest possible accuracy.

The present invention thus relates to a contrast control circuit for television receivers, whereby by varying individual components it is possible to choose between a linear contrast curve between the "Black" and "White" levels of the TV signal and a non-linear curve, and where the non- linear curve (4) in its lower area, which is greater than a quarter, but less than half of the entire area between the "Black" and "White" level, is steeper than the linear contrast curve (1) and in the remaining area is slacker than the linear contrast curve, in that the "White" value for the linear contrast curve is higher (brighter) than for the non-linear contrast curve, and where the brightness of the "grayness" steps located approximately in the middle of the range remains unchanged, as a diode (19) is connected to the contrast control amplifier.

The peculiarity of the invention is that the operating point for the amplifier and a voltage divider assigned to the diode are dimensioned in such a way that the diode, with non-linear contrast regulation, will be made conductive from the fourth (out of ten) "grayness" level and thereby together with a provided resistance is connected in parallel with the amplifier's anode resistance, while the diode is blocked by linear contrast regulation, and a resistance in this case is connected in parallel with said anode resistance.

The above-mentioned and other purposes and special features of the invention will be clear from the following detailed description of embodiments of the invention with reference to the drawings where,

Fig. 1a shows a curve with contrast regulation according to known devices, Fig. 1b shows a curve with an improved contrast regulation, Fig. 1c shows several curves to be used in the explanation of fig. 2 and 3, Fig. Id shows the slope of curve I and parts of curve II in fig. 1c, Fig. 2 shows one embodiment of the invention, and Fig. 3 shows another embodiment of the invention which includes automatic contrast control. Fig. la shows a curve which is divided into

ten different values of grey, between black and white. The above-mentioned known systems for contrast regulation control the entire interval As + Aa + Ab, and the background lighting is also controlled in such a way that the black level is only slightly increased when dark images are to be greatly enhanced, so that the black level remains approximately constant. The previous designs thus have the shortcoming that all greys, including the darkest grays which are often sent with poor quality, are also temporarily regulated down.

However, this known system can be improved by arranging the contrast regulation, so that it only takes effect from a given step on the curve, such as e.g. from the fourth step upwards as shown in fig. lb. This type of regulation can be provided by means of a system which automatically reacts to the white content in the picture part of a television signal, in order to set the gain of the contrast regulation and thereby reduce the steepness of this as shown by the dashed line in fig. lb. The purpose of this regulation is to reproduce the darkest shades of gray in all images with the greatest accuracy, as precisely these shadings are easily lost on the way from the studio to the reproducing picture tube and with slight variations in the background lighting.

When examining several types of scenes, it has been shown that if the contrast control characteristic is arranged so that it has different endpoints than the characteristic of the usual contrast control and consists of two parts, each with a different slope, the most appropriate contrast control is achieved. In fig. lc shows the curve I with dashed lines a typical linear contrast control characteristic

which is achieved using conventional

contrast control devices. It will be seen that the curve I has the usual linear characteristic with the sub-intervals As', Aa', Ab' and with a constant average slope sm, as shown in fig. Id.

When curve II is compared with curve I, it will be seen that curve II has the intervals As, Aa, Al, A2 with an increased slope, s,, fig. Id, up to the fourth stage and with a reduced slope, s„, from there up to the white level in the modified contrast control. With a contrast adjustment having such a characteristic, dark images or images with little contrast are reproduced with the largest contrast gradients, s,, while images with a high contrast are only weakened in the upper six steps of the adjustment. This effective effect on the contrast, i.e. that emphasis is placed on the darkest shadow areas, has a beneficial effect on the entire image. During the transition from curve I to curve II, the subjective light impression is increased somewhat in most of the images, even though the beam current remains constant. Especially when an image is to be viewed in a bright room, it will be clearly seen that the dark tones are more accentuated, without at the same time causing a flickering of the white parts of the image.

In fig. 2 shows an embodiment of the invention which is able to provide a contrast control in two parts, each of which has a different slope than the normal linear slope characteristic of previously<p>known devices. The contrast control device comprises an electronic discharge device or a tube 1, which has a cathode 2 connected to earth through the common cathode resistor 3 and capacitor 4. The control grid 5 for the discharge device 1 is connected to a source for the broadband signal 6, by means of a switching circuit 7. The broadband signal from the source 6 is a composite signal comprising the usual image components, line synchronization pulses and field synchronization pulses and the unidirectional component. The trap grid and screen grid in a pentode tube 1 are connected in the usual way, to provide a practically constant current gain. The anode 8 in the pipe 1 is connected to a conductor 9, which connects the anode 8 to a synchronization separating circuit and likewise to deflection devices (not shown). The anode 8 is also connected to an anode load comprising a resistor 10, a contrast control resistor 11, a resistor 12 and a B+ anode battery.

With respect to the synchronization signal channel, the amplifier stage comprising tube 1 will act as a pre-amplifier for the synchronization signals and the unidirectional component, providing for these synchronization signal components a practically constant gain which is largely unaffected by contrast control the device to be described in the following.

In the embodiment in fig. 2, a switch 13, when connected to a contact 14, will connect a resistor 15 in parallel with part of the anode load circuit, i.e. the contrast control resistor 11 and the resistor 12. When this resistor 15 is connected in this way, the characteristic of the amplifier stage will be practically linear, as shown in curve I, fig. lc, as far as contrast adjustments are concerned.

In parallel with the amplifier stage, a voltage divider comprising resistors 16, 17 and 18 is connected between the anode supply B+ and a reference potential, e.g. earth. A diode has its cathode connected to the connection point between resistors 16 and 17 and its anode connected to anode 8 in tube 1.

By connecting the switch 13 to contact 20, a short circuit will be made of the resistor 18, so that a predetermined positive potential is established on the cathode of the diode 19, to block this diode up to a predetermined gray level or step. By setting the operating characteristic of the amplifier circuit, comprising tube 1, correctly, and likewise the values of the voltage divider comprising resistors 16 and 17, it is possible to keep diode 19 in its non-conducting state up to the time when the amplitude of that signal which is connected to the grid 5 in the pipe 1 reaches the fourth step on curve II. With this arrangement, the characteristic of the amplifier stage comprising tube 1 will follow the solid line of curve II up to the fourth stage with a slope s, as described above. When the signal on the anode 8 in the tube 1 reaches an amplitude which is equal to or which exceeds the fourth step, the blocking of the diode 19 will be lifted so that it begins to conduct. When this occurs, diode 19 and resistor 17 will be connected in parallel with the anode load. With this parallel connection of the aforementioned components, the slope of the characteristic for the contrast control step will be reduced from the slope s, to the slope S:,. When diode 19 conducts, the resistance value of diode 19 and resistor 17 will change due to that the conductivity of the diode 19 increases, in order to change the resistance characteristic of the parallel anode load and thereby provide the reduced slope of the curve II.

After being subjected to the mentioned contrast control, the broadband signal is connected

let from the contrast control resistor 11 to further amplifier stages (not shown).

In fig. 2, it is shown how the characteristic of the contrast control stage is changed from a linear contrast control characteristic, curve I, to the contrast control characteristic with two parts and where the second part has a steeper slope than the slope sm for curve I, and where the upper part has a gentler slope than the slope of the curve I, by means of a manual switch 13. The selection of the desired contrast control characteristic can, however, easily be done automatically, if the resistor 16 is replaced with a voltage-controlled variable resistor whose resistance value is controlled by a control voltage derived from certain components of the image. Such an arrangement is shown in fig. 3, where components corresponding to the components in fig. 2 is given the same reference designation.

In fig. 3, an automatic control of the bias voltage of the diode 19 for selection of the contrast control characteristic is provided by a tube system 21 which may be a triode 22, which has an anode 23 connected to the cathode of the diode 19 and its grid 24 connected to an image signal content detector 25. The detector 25 is connected to the source 6 to provide an output control voltage that is proportional to the white content of the image or the amplitude of the used synchronization frequencies (horizontal and/or vertical) contained in the image components of the television signal, to control the conductivity of the tube 22 and thereby also the bias potential of the diode 19. The operating characteristic of the tube 22 and the remainder of the voltage divider and amplifier stage comprising the tube 1 is set so that the diode 19 remains blocked until the image components have reached an amplitude equal to the fourth step on the curve II in fig. lc. When the diode 19 is thus blocked, the contrast control characteristic will have a slope which is practically equal to the slope s,. After the amplitude of the fourth step in curve II is reached, the diode 19 becomes conductive and this will thereby change the anode load of the tube 1 by placing diode 19 and the resistor 17 in parallel with the resistors 9, 10, the contrast control 11 and the resistor 12. The operation of the contrast in fig. 3 will then be identical to the operation of fig. 2.

Claims (1)

Contrast control circuit for television receivers, whereby by varying individual components it is possible to choose between a linear contrast curve between the "Black" and "White" level of the TV signal and a non-linear curve, and where the non-linear curve (4) in its lower area, which is larger than a quarter, but less than half of the entire area between the "Black" and "White" level, is steeper than the linear contrast curve (1) and in the remaining area is slacker than the linear contrast curve, as the "White" value for the linear contrast curve is higher (brighter) than for the non-linear contrast curve, and where the brightness of the "grayness" steps located approximately in the middle of the range remains unchanged, as a diode (19) is connected to the contrast control's amplifier, characterized in that the operating point for the amplifier and a voltage divider assigned to the diode, are dimensioned in such a way that the diode, with non-linear contrast control, will be made conductive from the fourth (out of ten) "grayness"-t rinn and thereby together with an assigned resistance is connected in parallel with the anode resistance of the amplifier, while the diode is blocked by linear contrast regulation, and a resistance in this case is connected in parallel with said anode resistance.