KR19990008996U - Display device displaying a resolution mode change message using the OSD - Google Patents

Abstract

The present invention relates to a display device that can display a message using OSD characters when the user changes the input frequency out of the possible range.

A microcomputer receiving the synchronization signal transmitted from the computer to output phase adjustment data and OSD data, an OSD-IC receiving the OSD data output from the microcomputer to process the OSD signal, and outputting the OSD gain signal; and outputting from the OSD-IC. And a video amplifier circuit for receiving the OSD gain signal and the video signal and amplifying the video signal to a predetermined level, a CRT displaying the video signal sufficiently amplified by the video amplifier circuit, and a power supply unit for supplying power to the overall circuit. In the display device;

When the user artificially changes the display mode outside the range that can be implemented, the microcomputer operates at its own oscillation frequency and displays a message about specification over in the OSD-IC.

Description

Display device displaying a resolution mode change message using the OSD

The present invention relates to a display device, and more particularly, to a display device that can display a message by using OSD characters when the user changes the input frequency out of the possible range.

A general display device is a representative peripheral device of a computer that forms and displays an image so that a user can recognize a signal transmitted from the computer.

The basic configuration of the internal circuit will be briefly described with reference to FIG. 1.

The computer 100 receives and processes a keyboard signal, processes the CPU 110 to generate data according to the processed result, and receives the data output from the CPU 110 to process the image signals R, G, and B. And a video card 120 for outputting a horizontal synchronizing signal H_Sync and a vertical synchronizing signal V_Sync for synchronizing them.

Meanwhile, the image signals R, G, and B and the horizontal / vertical synchronization signals provided from the video card 120 in the computer 100 are transmitted to the display device according to the characteristics of the computer program.

The microcomputer 210 receives a horizontal / vertical signal provided through a signal cable and outputs a control signal such as a phase adjustment signal and a reference oscillation signal at a rear end thereof.

The control button unit 220 outputs various screen control signals for the operation of the microcomputer 210. At this time, when the selection of the input signal is changed according to the user's intention, the signal is transmitted to the microcomputer 210.

The horizontal / vertical output circuit 230 receives the screen control signal and the reference oscillation signal output from the microcomputer 210 to synchronize the raster.

The video circuit unit 240 receives and amplifies the image signals R, G, and B output from the video card 120.

Power required for driving is supplied to the microcomputer 210, the horizontal / vertical output circuit unit 230, and the video circuit unit 240 through the power circuit unit 250.

Looking at each block in the display device having such a configuration in more detail as follows.

The microcomputer 210 receiving the horizontal sync signal H-sync and the vertical sync signal V-Sync adjusts an image displayed on the screen according to a screen control signal applied from the control button unit 220. Will output a signal.

The horizontal / vertical oscillation signal processor 231 receiving the phase adjustment signal and the reference oscillation signal output from the microcomputer 210 controls the switching speed of the on / off operation of the sawtooth wave generating circuit according to the transmitted horizontal / vertical synchronization signal. The vertical pulse is applied to the vertical drive circuit 232.

The vertical drive circuit 232 receiving a vertical pulse is generally used with one stage of vertical amplification type. The vertical drive circuit 232 has an emitter follower type that applies an input to a base terminal of a transistor and extracts an output voltage from an emitter terminal. It is used a lot. Therefore, the linearity improvement operation is performed rather than the gain.

The vertical output circuit 233 receiving the current signal output from the vertical drive circuit 232 generates a sawtooth current corresponding to the vertical synchronizing pulse flowing through the vertical deflection yoke (V-DY) 234. The vertical scan period is determined.

The horizontal oscillation signal output from the horizontal / vertical oscillation signal processor 231 is applied to the horizontal drive circuit 235. The horizontal drive circuit 235 applied with the horizontal oscillation signal supplies sufficient current to turn on / off the horizontal output circuit 236.

The horizontal output circuit 236 receiving the current output from the horizontal drive circuit 235 generates a sawtooth wave current in the horizontal deflection yoke (H-DY) 237. This sawtooth current determines the horizontal scanning period.

Also, a flyback transformer (hereinafter referred to as FBT) 239 is used to supply a stable direct current (DC) voltage to an anode of the CRT 244.

The FBT uses a harmonic caused by the leakage inductance and the distribution capacity of the high voltage circuit 238 to generate a high voltage even when the collector pulse is small, and apply it to the anode terminal of the CRT 244.

The anode terminal receiving the high voltage adjusts the luminance of the image signals R, G, and B that are amplified and output from the video circuit unit 240. The OSD unit 241 receives OSD data according to the screen control signal output from the microcomputer 210 to output the OSD gain signal.

The video preamplifier 242 receives the OSD gain signal output from the OSD unit 241 and the image signals R, G, and B applied from the video card 120. The video preamplifier 242 amplifies low image signals R, G, and B with a low voltage amplifier to maintain a constant voltage level.

For example, a signal less than 1 VPP is amplified into a signal of 4 to 6 VPP. The video output amplifier 243 amplifies the 4 to 6 VPP signal in this manner to amplify the 40 to 60 VPP signal to supply energy to each pixel. The video signal amplified by the video output amplifier 243 is applied to a cathode of the CRT 244 to display an image on the screen.

In addition, when the OSD is selected, the OSD is selected by the video preamplifier 242 and amplified to a predetermined level, and finally amplified by the video output amplifier 243 to display the OSD data on the screen of the CRT 244.

The power supply circuit unit 250 supplying the driving voltage of the display device receives the alternating current through an alternating current (hereinafter referred to as AC) input terminal 251 that receives commercial alternating current. The degaussing coil 252, which receives the alternating current output through the AC input terminal 251, restores the color bleeding state of the screen to the original color due to the geomagnetic field or external conditions.

In this operation, when an alternating current is applied to the degaussing coil 252 for 2 to 8 seconds, the magnetic field formed in the shadow mask in the display apparatus 200 is scattered to restore the color bleeding state.

In addition, the direct current rectified and output through the rectifier 253 is applied to the switching transformer 254. The switching transformer 254 receiving a direct current performs a switching operation to supply various driving voltages required in the display apparatus 200 through the voltage output terminal 255.

At this time, if the vertical synchronizing signal V-SYNC is not applied, the microcomputer 210 applies the suspend mode signal to the voltage regulator 256 to block the deflection voltage.

The square wave pulse of the pulse width modulation circuit (PWM) unit 257 performs on / off drive operation of the switching device, and the change in the pulse width increases and decreases the conduction time to stabilize the output voltage. Will cause.

In addition, the microcomputer 210 executes the DPMS mode according to whether the horizontal / vertical synchronization signal is detected to reduce the power consumption consumed in the display apparatus 200, thereby reducing the power consumed in the display apparatus 200. .

The computer user may change the display mode depending on the program used. In other words, if you want to change the resolution of the screen occurs.

Here, the resolution refers to the degree to which a detailed image can be displayed. There can be several things that affect the resolution. First of all, the signal must be fine, the circuit must be able to process the fine signal well, and the CRT's sharpness, hue, brightness (luminance), etc. must be well balanced. As a way of displaying the resolution, the monitor uses the unit of dot x line. CRT expresses an image with a dot or line, and the most detailed representation is Dot.

It is common for the monitor to display the maximum resolution using the number of points that can be displayed with the finest detail between the horizontal syringes and the number of horizontal lines that can be displayed with the finest detail in the vertical scanning period.

For example, a monitor with a resolution of 640x480 has a horizontal resolution that can distinguish up to 640 dots horizontally and a vertical resolution that can distinguish 480 lines vertically.

Video characteristics are not standardized among video card manufacturers, but they are generally the same.

A computer program, for example, when a user who runs a Windows screen wants to change the graphic resolution, the display mode is set. At this time, the Windows program runs the screen according to the set resolution mode. That is, when the screen of the 640x480 mode is displayed as shown in FIG. 2A, when the screen is switched to 800x600 mode, when the screen is changed to the 1024x768 mode as shown in FIG.

In addition, whether to implement the mode depends on the video card mounted in the computer, and also varies depending on the maximum resolution of the display device used.

If the user can artificially change the display mode, but can be implemented in the computer, but can not be implemented in the display device, the display device appears as shown in FIG.

The microcomputer operates at its own oscillation frequency while the monitor is operating at DPMS or the LED blinks to indicate that the input frequency is wrong.

When the signal cable that carries the display signal from the computer is disconnected, the OSD text Signal Check is displayed. However, if the user changes the input frequency (mode) out of a certain range while the signal cable is connected, the user may not realize this because the display device operates as a DPMS.

The present invention is to solve this problem, and when the user changes the display mode to a mode that can be implemented in the computer, but not implemented in the display device, the purpose of informing the user about the information through the OSD character.

The present invention for achieving the above object is to receive a synchronization signal transmitted from a computer to output the phase adjustment data and OSD data, and the OSD- output OSD gain signal by receiving and processing the OSD data output from the microcomputer An IC, a video amplifier circuit that receives an OSD gain signal and an image signal output from the OSD-IC and amplifies it to a predetermined level, a CRT displaying a video signal sufficiently amplified by the video amplifier circuit, and an overall circuit In the display device comprising a power supply for providing a; When the user artificially changes the display mode outside the range that can be implemented, the microcomputer operates at its own oscillation frequency and displays a message about specification over in the OSD-IC.

1 is an internal configuration diagram showing a general display device;

2A to 2C are diagrams illustrating a display state according to a change in resolution;

3 is a monitor state occurring when the display mode is out of the implementation range,

4 is an internal configuration diagram of a display device for implementing the present invention,

5 is an exemplary operation diagram according to the operation of the present invention.

Hereinafter, an operation implementation of the present invention will be described with reference to the accompanying drawings.

4 is a block diagram showing the configuration of a display device according to the present invention. The different numbers given to the same components shown in Figure 1 for convenience of description and does not have a special meaning.

The computer user changes the display mode to change the resolution as needed. The video card 10 in the computer 1 outputs by changing the vertical frequency and the horizontal frequency in order to implement the changed resolution mode. At this time, the horizontal / vertical synchronization signal is transmitted to the synchronization processor 20 of the display device 2. The mode may be implemented in the video card 10 in the computer, but may not be implemented in the display device.

That is, the video card 10 may support the 1280 × 1024 mode in addition to the 1024 × 768 mode, and the sync processor 20 detects this when the user selects it.

The microcomputer 30 recognizes whether the display device can implement the recognized resolution. If outside the implementation range, a control signal is output to output the corresponding message to the OSD-IC 120.

This control signal is transmitted to the cathode ray tube 80 via the video preamplifier 100 and the video main amplifier 110 and displayed.

On the other hand, an example of the message output as OSD characters may be simply expressed as SPEC OVER, as shown in Figure 5, the other message may be displayed as being beyond the display range for the user to understand easily.

In addition to displaying a message through the OSD-IC 120, a warning message may be displayed through a speaker. That is, when the microcomputer 30 controls to output a corresponding message, the signal is output through the speaker SP through the sound input terminal 130 and the sound amplifiers 140 and 150.

As described above, the present invention has an effect that the user can easily recognize by using an OSD character when the user changes the display mode at random.

Claims (2)

A microcomputer that outputs phase adjustment data and OSD data by receiving a synchronization signal from a computer; An OSD-IC for receiving and processing OSD data output from the microcomputer to output an OSD gain signal; A video amplifier circuit which receives an OSD gain signal and an image signal output from the OSD-IC and amplifies them to a predetermined level; A CRT displaying a video signal sufficiently amplified by the video amplifier circuit; A display device comprising a power supply for supplying power to an overall circuit; When the user artificially changes the display mode outside the range that can be implemented, the microcomputer operates at its own oscillation frequency and indicates a resolution mode change message using the OSD, wherein the OSD-IC displays a message about specification over. Display device. The method of claim 1, Display device characterized in that a beep sound with the OSD message when the user changes the mode out of the Spec.