KR0134886Y1 - System down preventing device - Google Patents

Abstract

The present invention relates to a system down prevention device for protecting the microcomputer of the monitor from switching noise. In the related art, a core component for the overall control of the internal operation of the monitor is used. It was insufficient.

Therefore, in order to solve this problem, the microcomputer section with the delay buffer built in has a function of separately outputting a delay buffer between the microcomputer and the horizontal / vertical oscillator and outputting the output signal of the microcomputer to the rear horizontal / vertical oscillator, In addition, the device is configured to generate an interrupt signal that wakes up the microcomputer in the standby state, thereby solving the problem of the microcomputer malfunctioning or being down by the ambient noise on the printed circuit board.

Description

System down prevention device

1 is a general monitor schematic.

2 is a system down prevention device devised in the present invention.

* Explanation of symbols for the main parts of the drawings

10: D-sub 20: Video Section

21: preamplifier 25: video output

40: CRT 50: Mycom section

51: Microcomputer 52: Microcomputer section with delay buffer

53: delay buffer 60: deflection section

61: horizontal / vertical oscillator 63: vertical sync signal output stage

65: horizontal synchronizing signal output stage 66: horizontal yoke

67: vertical yoke 68: FBT

The present invention relates to a microcomputer section (μ-com section) to control the overall operation of the monitor (monitor), and relates to a device for preventing the microcomputer from malfunctioning or down by the switching noise of the microcomputer will be.

Commonly used monitors include the D-sub (10), which is a terminal for receiving color signals (Red, Green, Blue) and synchronization signals output from the computer as shown in FIG. 1, and the microcomputer section (μ) for controlling the operation of the monitor. -com section; 50) and a video section 20 for outputting the color signal to the CRT 40, and a deflection for adjusting the deflection of the electron beam emitted from the electron gun inside the CRT 40. A section (deflection section) 60 and a CRT 40 for outputting an image, wherein the video section 20 receiving the color signal applied from the D-sub 10 is a preamplifier 21 for amplifying the color signal. And a video output stage 25 for supplying the amplified signal to the CRT 40 at a later stage, and a CRT 40 finally generating a video signal, wherein the synchronization applied from the D-sub 10 is applied. The microcomputer section 50 which receives the signal is a microcomputer 51 of the one chip for overall control of the monitor. The deflection section 60, which is configured to deflect the electron beam using the synchronization signal applied from the microcomputer section 50, has a difference between a horizontal / vertical synchronization signal and a flyback transformer (FBT) signal. horizontal / vertical oscillator 61 for recognizing a difference, a vertical synchronizing signal output terminal 63 for outputting a vertical synchronizing signal, a vertical yoke 67 for deflecting the above signals, and a horizontal for outputting a horizontal synchronizing signal A synchronizing signal output terminal 65, a horizontal yoke 66 for deflecting the above signals, and an FBT 68 for adjusting image brightness in the CRT 40.

Looking at the operation of the monitor configured as described above are as follows.

The video section 20 amplifies the 0.7 volt color signal applied through the D-sub 10 to a size of 4 to 7 volts, and the preamplifier 21 amplifies the rear video signal to a size of 4 to 7 volts. The preamplifier 21 amplifies and the video output stage 25 on the rear stage amplifies the signal to a size of 10 volts and applies it to the electron gun of the CRT 40 that emits an electron beam.

In addition, the synchronization signal passing through the microcomputer 51 is applied to the horizontal / vertical oscillator 61. Among the signals passing through the horizontal / vertical oscillator 61, the vertical signal passes through the vertical synchronization signal output terminal 63 and the CRT (40). Is applied to the vertical yoke 66 of the vertical beam deflection, and the horizontal signal is applied to the horizontal yoke 67 of the CRT 40 through the horizontal synchronizing signal output terminal 65 to vertically deflect the electron beam. In addition, the horizontal signal applied to the FBT 68 adjusts the image brightness of the CRT 40 by adjusting the amount of the electron beam directed to the screen of the CRT 40.

In the conventional monitor having the configuration and function as described above, when the microcomputer 51 outputs a control signal to the rear stage in order to switch the operation mode, the switching noise of the various elements of the rear stage flows into the microcomputer 51 and thus the microcomputer. (51) resulted in defects such as unstable operation, reset or jump to an unspecified address.

Accordingly, an object of the present invention is to provide a microcomputer section further including a delay buffer in a conventional monitor, which is designed to solve the above problems.

Hereinafter, the configuration of the present invention will be described with reference to FIG. 2. The microcomputer section 52 incorporating the delay buffer receives the signals of the microcomputer 51 and the microcomputer 51 which receive the synchronization signal output from the above D-sub 10, and receives the signals of the microcomputer 51 on the display section 60 of the rear stage. It consists of a portion of the delay buffer 53 for storing the output signal of the microcomputer 51 while applying.

Referring to the operation of the monitor having the above configuration in detail as follows.

The synchronization signal input to the microcomputer 51 through the D-sub 10 of the monitor is output by separating the horizontal synchronization signal and the vertical synchronization signal from the horizontal / vertical oscillator 61 according to the characteristics of each synchronization signal.

However, a commonly used multi-sync monitor uses a capacitor switch (C / S) to display a screen on the CRT 40 or to increase the resolution, and inputs a signal to the horizontal / vertical oscillator 61. In order to prevent the microcomputer from being exposed to a large number of devices capable of introducing noise into the microcomputer 51 such as using a frequency (voltage to voltage), in the present design, the signal output from the microcomputer 51 is a delayed buffer of the rear stage ( 53).

The output of the microcomputer 51 input to the delay buffer 53 is output to the horizontal / vertical oscillator 61 and the capacitor switch of the rear stage so that the display section 60 operates and stores the synchronization signal for a predetermined time.

The microcomputer 51 outputs the output signal to the delay buffer 53 at the rear end, and the microcomputer 51 stores the current address and data on the stack and then waits in the stop mode. The synchronization signal stored for a predetermined time in the delay buffer 53 is connected to the microcomputer 51 to be fed back as a wake up interrupt signal, and the microcomputer 51 in the standby state is stored on the stack. It fetches its address and data and waits for input of the next mode.

Therefore, the system down prevention device devised in the present invention has an effect of contributing to the improvement of the quality assurance of the monitor as well as solving the real problem such as the microcom of the monitor being down when the mode is changed.

Claims (2)

Adjust the deflection of the video section 20 for outputting the color signal input to the monitor to the CRT 40, the microcomputer section 50 for overall control of the operation of the monitor, and the electron beam emitted from the electron gun inside the CRT 40. Including the deflection section 60 and the CRT 40 for outputting an image, the delay buffer 53 to block the switching noise flowing into the micom 51 in the micom section 50 System down prevention device, characterized in that provided. The method according to claim 1, wherein the wake up interrupt signal is stored after the output of the microcomputer 51 is stored in the delay buffer 53 to wake up the microcomputer 51 in the standby state. And a control signal applied to 51).