CS243541B1 - Cathode-ray tubes' further luminance levels control connection - Google Patents

Abstract

The goal of the solution is to create a simple one wiring with continuous adjustment luminance level and thus the possibility of setting any screen brightness together for both brightness levels with the brightness regulator in the screen control grid; in the cathode. The target is achieved by connecting with an image amplifier containing the first transistor, whose collector is connected through the first resistance to the first DC source terminal the voltage and its base through the second resistor to the first DC source terminal voltage, while its emitter is connected first, through a diode based on the first transistor, first on the output terminal, below containing a second transistor whose collector it is connected on the base of the first transistor and its emitter to the second source terminal DC voltage. His base is attached to the video signal input terminal one luminance level. The wiring also includes a third transistor whose base is connected to the next video signal input terminal the luminance level and whose emitter is connected to the second DC power supply terminal Tension. Between the base of the first transistor and the collector at least one of a pair of transistors consisting of the second and third transistors, variable resistor is connected.

Description

The invention relates to an arrangement for controlling further luminance levels of displays, in particular in the alphanumeric display units of an information processing device.

An additional luminance level, which is usually higher than the basic luminance level, is used to highlight a part of the displayed information. In this case, it is desirable that, apart from adjusting the overall brightness level of the screen and the display contrast, there is the possibility of separately controlling this additional brightness level.

Modulation of image pulse length is still used to express this additional luminance level. The disadvantage of this is that the length of the image pulses is adjusted by changing the capacity in the monostable flip-flop, which results in a very difficult and in practice difficult to control this additional luminance level.

Another disadvantage is that with a greater difference in luminance levels, there is a noticeable difference in the length of the light segment on the screen. Another disadvantage is that it is necessary to include a pulse length modulator in the path of the video signal.

These drawbacks are eliminated by the wiring for controlling further luminance levels of the screens of the present invention, which comprises a third transistor whose base is connected to an input terminal of a video signal of another luminance level and whose emitter is connected to a second terminal of a DC voltage source. the base of the first transistor and the collector of at least one of the pair of transistors formed by the second and third transistors is a variable resistor.

The advantage of wiring to control other luminance levels of the screens according to the invention is its simplicity, the possibility of continuous adjustment of the next luminance level and thus the possibility of adjusting any contrast while maintaining the possibility of adjusting the overall luminance level together for both luminance levels. in the cathode.

An example of a wiring to control other luminance levels of screens according to the invention is shown in the accompanying drawings, in which Fig. 1 shows the wiring diagram, Fig. 2 an alternative wiring diagram, Fig. 3 shows a timing diagram of input signals and output signal of alternate wiring.

The collector of the first transistor Q1 is connected via a first resistor R1 to the positive terminal 8 of a DC power supply (not shown). The base of the first transistor Q1 is connected via a second resistor R2 to the positive terminal 6 of the DC voltage source.

The emitter of the first transistor Q6 is connected both to the anode of the diode D, the cathode of which is connected on the basis of the first transistor Q1, and to the output terminal 01 of the OSV signal for connection to the cathode of a not shown screen.

The base of the first transistor Q1 is further connected to one terminal of the potentiometer R3, the second terminal of which is connected to the collector of the second transistor Q2. The emitter of the second transistor Q2 is connected to the negative terminal 6 of the DC voltage source, while its base is connected to the input terminal 8 of the video signal OS1 of the basic luminance level.

The slider of the potentiometer R3 is connected to the collector of the third transistor Q3, whose emitter is connected to the negative terminal 6 of the DC voltage source. The base of the third transistor Q3 is connected to the input terminal 8 of the video signal OS2 of the next luminance level.

In contrast to the diagram of FIG. 1, the base of the first transistor is shown in the diagram of FIG

Q6 is connected directly to the collector of the second transistor Q1 and the collector of the third transistor Q3 is connected with a variable resistor R4. The OSV signal output terminal 01 is then connected to a control grid of the display.

24354

In both circuits, npn transistors are used. When using pnp transistors, the polarity of the DC source and the polarity of the diode D are changed.

If present at the input terminal 8 / FIG. 1 / video signal OSI of the basic luminance level, the second transistor Q2 is saturated. The potentiometer R3 with the second resistor R2 then forms a voltage divider.

The output voltage from this divider appears at the output terminal Ol as the OSV signal. If a further brightness level video signal OS2 is present at the input terminal 2, the third transistor Q3 is saturated. The magnitude of the OSV signal at the output terminal Ol depends on the slider position of the potentiometer R3.

This can be used to continuously control the magnitude of the next luminance level. If there is no OS1 or 0S2 signal at the input terminals 1/6, the first transistor Q1 is saturated and the DC voltage is full at the output terminal 01 as the OSV signal.

This wiring is intended when the next luminance level is higher than the basic luminance level, the wiring operation is further evident from the timing diagram of the OSI, OS2 and OSV signals in Fig. 3.

The wiring shown in FIG. 2 works differently, except that the other luminance level is lower than the basic luminance level. The operation of the wiring is further evident from the timing diagram of the signals OS1, 0S2, OSV in Fig. 4.

The invention can be used to control other luminance levels of displays, particularly in the alphanumeric display units of an information processing device.

Claims (1)

SUBJECT OF THE INVENTION Wiring for controlling further luminance levels in video amplifier screens incorporating a first transistor whose collector is connected via a first resistor to a first terminal of a DC voltage source and its base via a second resistor to a first terminal of a DC voltage source, its emitter being connected via a diode to a base of a first transistor, on an output terminal, further comprising a second transistor, the collector of which is connected on the basis of the first transistor and its emitter to the second terminal of the DC voltage source, its base connected to the video input terminal of one luminance level; further comprising a third transistor (Q3), the base of which is connected to the input terminal (2) of the video signal of the next luminance level and whose emitter is connected to the second terminal of the DC voltage source, a pair of transistors formed by the second and third transistors (Q2, Q3) is connected to a variable resistor (R4).