KR200328680Y1 - Color Monitor Kinema Complementary Circuit - Google Patents

Abstract

The present invention relates to a luminance compensation circuit for a color monitor for an image diagnosis device, such as an ultrasound diagnostic device used in clinical practice, and a method thereof.

An object of the present invention is to allow the cathode potential to maintain the initial value even when light emission at a high brightness for a long time, for this purpose, the present invention is a known thing that the cathode bias is controlled by a diode and a transistor connected to the cathode, Detects the cathode voltage at the beginning of operation and stores it as a digital value, detects the cathode voltage continuously changing during the operation, converts it to a digital value, and compares the value corresponding to the difference with the digital value stored at the beginning of operation. The cathode bias voltage is controlled by controlling the electric transistor in terms of the value. Accordingly, the present invention has an effect of providing a precise image with stable color, by preventing the luminance deterioration even if the color monitor is maintained at a high state for a long time.

Description

Color Monitor Luminance Compensation Circuit for Image Diagnostics {Color Monitor Kinema Complementary Circuit}

The present invention relates to a luminance compensation circuit for a color monitor for an image diagnosis device, such as an ultrasound diagnostic device used in clinical practice, and a method thereof.

As is well known, in an image diagnosis apparatus such as an ultrasound diagnosis apparatus, accurate diagnosis is possible by expressing a clinical image precisely.

Therefore, the color monitor for image diagnosis should emit light with a high luminance of 2 to 4 times higher than that of a normal monitor. In this state, the luminance decreases as the cathode potential decreases due to the change in phosphor characteristics of the CRT for a long time. It becomes impossible to express an accurate image such as unstable color, and in this case, it is inconvenient to readjust luminance by manual operation.

An object of the present invention is to provide a color monitor brightness compensation circuit and method for an image diagnosis apparatus to maintain the initial value of the cathode potential even when the light emission at high luminance for a long time to solve this problem.

1 is a circuit diagram showing a conventional brightness adjustment unit.

Figure 2 is a color monitor luminance compensation circuit diagram for an image diagnostic apparatus according to the present invention.

Figure 3 is a flow chart showing a color monitor brightness compensation method for an image diagnostic apparatus according to the present invention.

* Explanation of symbols for the main parts of the drawings

1: Cathode 2: Diode 3, 3 ': Transistor

4: Amplifier 5: A / D Converter 6: D / A Converter

7: memory 8: microprocessor

An object of the present invention is to provide a cathode bias controlled by a diode and a transistor connected to a cathode. The cathode voltage is detected and stored as a digital value at an initial stage of operation. Color monitor luminance compensation for image diagnosis by controlling the cathode bias voltage by controlling the electric transistor by converting the value corresponding to the difference into analog value compared with the digital value stored at the beginning of operation after converting to digital value. Suggest a circuit.

Accordingly, the present invention has an effect of providing a precise image with stable color, by preventing the luminance deterioration even if the color monitor is maintained at a high state for a long time.

This invention is described in more detail with reference to the accompanying drawings as follows.

2 shows a color monitor luminance compensation circuit for an image diagnosis apparatus according to the present invention.

As can be seen from the above, the present invention allows the cathode (1) bias to be adjusted by the diodes (2) and transistors (3,3 ') connected to the plurality of cathodes (1) corresponding to R, G, and B. In the known art, a plurality of amplifiers 4 connected to the cathode 1, an A / D converter 5 connected to the output of the amplifier 4, and a memory 7 connected to the A / D converter 5 It is composed of a microprocessor 8 and a D / A converter 6 is connected to the output and the input of the microprocessor 8, the output and the base of the electric transistor (3).

When described in detail by the flow diagram shown in Figure 3 the operation of the present invention as described above are as follows.

According to the present invention, when a monitor starts normal operation by applying power, a corresponding bias voltage is applied to a plurality of cathodes 1, which are amplified to a sufficient magnitude through an amplifier 4, and then the A / D converter 5 Is converted into a digital signal and then stored in the memory 7 by the microprocessor 8. In this state, when the high luminance is maintained for a long time, the potential of the cathode 1 is lowered due to the characteristic change of the phosphor, and thus the output voltage of the amplifier 4 is also lowered. Accordingly, the digital voltage output from the A / D converter 5 is also changed, where the microprocessor 8 initially converts the voltage stored in the memory 7 and the digital value output from the current A / D converter 5. Will detect the difference between. In this case, the microprocessor 8 immediately outputs a digital value corresponding to the deviation to the D / A converter 6 so that the D / A converter 6 outputs an analog voltage for compensating for luminance deterioration. This analog voltage is applied to the base of the transistor 3, and the current flowing in the transistor 3 'is increased by reducing the current flowing through the transistor 3 so that the base potential of the transistor 3' is raised. This decreases the potential of the selected cathode 1 to rise.

As a result, the luminance of the CRT is increased, thereby providing a clear image through the monitor.

On the contrary, if the cathode (1) voltage rises abnormally, the microprocessor (8) detects the rise by comparing the first stored cathode (1) potential value and the elevated cathode (1) potential value and corresponding digital output. Therefore, the potential output from the D / A converter 6 applies an elevated voltage to the base of the electric transistor 3, and thus the transistor 3 ′ also receives a current flowing through the diode 2. It is possible to increase the cathode 1 potential by increasing it. Therefore, the cathode 1 potential can be kept constant in any case, thereby providing a stable screen as the luminance is stabilized.

In addition, in the present invention, the accuracy of adjusting the bias voltage of the cathode 1 is determined according to the resolution of the A / D converter 5 and the D / A converter 6, and a sufficient practical degree can be obtained even at low cost. Will be.

In addition, in the present invention, if necessary, the cathode 1 voltage may be programmed to be maintained above a certain voltage in any case.

In addition, in the present invention, the memory 7 may be of a type embedded or external to the microprocessor 8, and of course, EEPROM or various RAMs may be used. In addition, in the embodiment of the present invention, a part of the voltage of the cathode 1 is grounded via the diode 2 and the transistor 3, but the cathode 1 current is caused by the collector and the emitter of the transistor 3. Of course, some may flow directly to ground.

In this way, the present invention stores the voltage of the cathode (1) at the beginning of operation to detect the voltage of the cathode (1) that is changed afterwards, and maintains the cathode (1) voltage at the beginning of operation, thereby preventing the luminance deterioration during operation, thus providing clear and high picture quality. It is a useful design to provide a color monitor luminance compensation circuit for a high quality image diagnosis device by stabilizing image quality such as color because it can express the image.

Claims (2)

In the well-known thing by connecting the diode 2 for bias adjustment and the transistors 3 and 3 'to the plurality of cathodes 1 corresponding to (correction) R, G, and B, the plurality of cathodes connected to the cathode 1 A microprocessor (8) having four amplifiers (4), an A / D converter (5) connected to the output of the amplifier (4), an A / D converter (5), and a memory (7); And a D / A converter (6) connected to the input / output port of the microprocessor (8), the output of which is connected to the base of the electrical transistor (3). delete