KR200224853Y1 - Monitor with signal processor - Google Patents

Abstract

The present invention relates to a monitor having a signal processor, and when the signal processed by the signal processor is a signal that must be processed independently, the video memory sequentially inputs and writes it to the video memory and the video memory. In a monitor including a video processor that reads sequentially written signals and displays them on the CRT, the signals generated from the keyboard and mouse as peripheral devices are transmitted to the PC main body, and the resulting video signals are received and processed again. It is configured to further include a processor, when one monitor is equipped with a plurality of monitors, one monitor processes and displays video signals generated by the PC body as in the conventional manner, and the other is a peripheral receiving TV You can use your card, CD-ROM, or DVD-ROM drive to listen to music or movies. So that as each has to perform other tasks.

Description

Monitor with signal processor

The present invention relates to a monitor having a signal processor, and in particular, a signal processor capable of processing and displaying signals generated from a peripheral device by mounting a signal processor capable of processing signals independently. And a monitor having a processor.

In general, a PC using system includes a peripheral device such as a keyboard, a mouse, a CD-ROM drive, a PC main body including a CPU and a video card, and a monitor for receiving and displaying a signal generated from the PC main body.

Looking at the PC using the system having such a configuration using the accompanying drawings as follows.

As shown in FIG. 1, the PC main body 100 of the general PC using system receives a signal generated by the peripheral device 110, processes the CPU 120 to output data, and outputs the data from the CPU 120. To output the video signal (R, G, B) and process the horizontal sync signal (H-SYNC) and vertical sync signal (V-SYNC) to synchronize the output video signals (R, G, B). The video card 130 is output.

The display monitor 200 that receives and displays the video signals R, G, and B output from the video card 130 in the PC main body 100 controls to generate a key signal for adjusting the display monitor screen. The key unit 210 and the horizontal and vertical synchronization signals (H-SYNC, V-SYNC) output from the video card 130 are received, and the phase adjustment signal and the reference according to the key signal output from the control key unit 210. A microcomputer 220 for outputting an oscillation signal, horizontal and vertical output circuits 230 for synchronizing the video signals R, G, and B by receiving a phase adjustment signal and a reference oscillation signal output from the microcomputer 220; A video signal processor 240 for receiving and amplifying and displaying the video signals R, G, and B output from the video card 130, the microcomputer 220, the horizontal and vertical output circuits 230, and The image signal processor 240 It is a power supply circuit 250 for supplying a voltage.

Looking at each block in the PC-using system having such a configuration in more detail as follows.

The PC main body 100 receives signals input through the keyboard 111, the mouse 112, and the CD-ROM drive 113 of the peripheral device 110 from the CPU 120 to generate data. The video card 130 that receives the data generated by the CPU 120 processes the input data to output the video signals R, G, and B, and a horizontal synchronous signal H-SYNC and a vertical synchronous signal for synchronizing them. V-SYNC) is generated and output.

The horizontal and vertical synchronization signals H-SYNC and V-SYNC output from the video card 130 are applied by the microcomputer 220. The microcomputer 220 receiving the horizontal and vertical synchronization signals H-SYNC and V-SYNC receives a phase adjustment signal and a reference oscillation signal for adjusting an image displayed on the screen according to a key signal applied from the control key unit 210. Will print.

The horizontal and vertical oscillation signal processor 231 receiving the phase adjustment signal and the reference oscillation signal output from the microcomputer 220 may receive the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V applied from the video card 120. SYNC) generates horizontal and vertical oscillation pulses for controlling the switching speed of the on / off operation of the sawtooth wave generating circuit.

The generated vertical oscillation pulse is applied by the vertical drive circuit 232 and amplified to output a drive current. In the vertical drive circuit 232 for amplifying the vertical oscillation pulse, a vertical amplification type of one stage is generally used, and an emitter follower which applies an input to a base stage of a transistor and draws an output voltage from an emitter stage. Follower type is used a lot.

Therefore, the linearity improvement operation is performed rather than the gain. The vertical output circuit 233 receiving the drive current amplified and output from the vertical drive circuit 232 generates a sawtooth current corresponding to the vertical synchronizing pulse in the deflection yoke DY to determine the vertical scan period. do.

In addition, the horizontal drive circuit 234, which receives the horizontal oscillation signal output from the horizontal and vertical oscillation signal processors 231, supplies a sufficient current to turn on / off the horizontal output circuit 235. Will generate a current. The horizontal output circuit 235 receiving the drive current output from the horizontal drive circuit 234 generates a sawtooth wave current in the deflection yoke DY to determine a horizontal scanning cycle.

The drive method of the horizontal drive circuit 234 includes an in-phase (dynamic polarity) method in which the output stage is turned on when the drive stage is on, and an inverse phase in which the output stage is turned off when the drive stage which is used frequently is on. Polarity).

In addition, in order to supply high voltage to the anode terminal of the CRT, the high voltage circuit 236 and the flyback transformer (hereinafter referred to as FBT) 237 are output from the horizontal and vertical oscillation signal processor 231. High voltage is generated by driving according to the cycle of horizontal oscillation pulse. The generated high pressure is applied to the anode terminal of the CRT to form an anode surface of the CRT.

The video preamplifier 241 of the video signal processor 240 amplifies the low level video signals R, G, and B output from the video card 130 to maintain a predetermined voltage level. E.g., for example, a peak-to-peak voltage; amplifies a signal of less than (Peak to peak voltage as represented below V _PP) to the signal of 4 ~ 6V _PP. Video preamplifier video signal amplified by the 241, a signal of 4 ~ 6V _PP to (R, G, B) is applied to take between 40 and amplifies a signal each pixel of the CRT screen of 60V _PP in the video main amplifier (242) The energy is supplied to display the phase.

The phase according to the video signals R, G, and B displayed through the CRT is determined by the horizontal and vertical sawtooth wave currents generated in the deflection yoke DY and displayed on the screen of the CRT. In addition, the image displayed on the screen brightness is controlled by the anode surface formed inside the CRT to display the video signals (R, G, B) generated by the video card 130 of the PC main body 100.

In the conventional PC-using system, the monitor is configured to receive and display a video signal generated from only one PC main body, and thus has a dependent relationship with one PC main body. Therefore, when working on a PC main body having a plurality of monitors, one monitor processes and displays a video signal generated from the PC main body, and another monitor cannot perform other operations.

Accordingly, an object of the present invention is to provide a monitor having a signal processor that can process a signal independently by receiving a signal generated from a peripheral device by configuring a signal processor in the monitor to solve the above problems. .

The present invention for achieving the above object is, when the signal processed in the signal processor is a signal to be processed independently, the video memory to sequentially receive and write (write), and the signal sequentially written to the video memory A monitor comprising a video processor for reading and displaying on a CRT, the monitor further comprising a signal processor for transmitting a signal generated from a keyboard and a mouse, which is a peripheral device, to the PC main body and receiving and processing the resulting video signal again. There is a characteristic.

1 is a block diagram showing the configuration of a conventional PC using system;

2 is a block diagram showing an internal circuit configuration of a monitor having a signal processor according to the present invention;

3 is a flowchart illustrating an operation process of a signal processor according to the present invention.

Looking at the present invention using the accompanying drawings as follows.

2 is a block diagram showing an internal circuit configuration of a monitor having a signal processor according to the present invention. As shown, the peripheral device 10 for generating a signal, the monitor 20 for receiving and processing the signal generated from the peripheral device 10, and transmits the signal processed by the monitor 20 It is composed of a PC main body 30 to receive and process the output to the monitor 20 to display the processed results.

During this configuration, the peripheral device 10 may process a TV broadcast signal by processing a keyboard 11 for generating a key signal, a mouse 12 for generating a pointing signal, and a TV broadcast signal transmitted from the outside. The TV reception card 13 generated, the CD-ROM drive 14 which processes the signal stored in the CD-ROM (not shown), and generates the signal, and the DVD-ROM generated by processing the signal stored in the DVD-ROM. It consists of a drive 15.

The monitor 20 for processing signals generated by the peripheral device 10 includes a signal processor 21 for receiving and processing a signal generated by the peripheral device 10 and the signal processor 21. If the signal is a signal to be independently processed, the video memory 22 sequentially receives and writes the signal, and the signal sequentially written to the video memory 22 is read, and the CRT is read. It consists of a video processor 23 to be displayed on.

At this time, the signal which the signal processor 21 can independently process may include a TV reception card 13 included in the peripheral device 10, a CD-ROM drive 14, and a DVD-ROM drive 15. There is).

The signal input by the signal processor 21 is a signal generated by the keyboard 11 and the mouse 12 of the peripheral device 10 to be processed through the CPU 31 of the PC main body 30. Is processed through the CPU 31 of the PC main body 30.

Looking at the present invention having such a configuration in more detail with reference to Figure 3 as follows.

By the user's selection, the peripheral device 10 generates a signal. The generated signal is input from the signal processor 21 of the monitor 20 (S11). More specifically, the signal generated from the keyboard 11, mouse 12, TV receiving card 13, CD-ROM drive 14, DVD-ROM drive 15, etc. of the peripheral device 10 can be monitored ( 20 is transmitted by the signal processor 21 configured in the processor.

Signal processor 21 receiving signals generated from keyboard 11, mouse 12, TV receiving card 13, CD-ROM drive 14, DVD-ROM drive 15, etc. of peripheral device 10 Analyzes whether the transmitted signal is a signal generated from the keyboard 11 and the mouse 12 or a signal generated from the TV receiving card 13, the CD-ROM drive 14, the DVD-ROM drive 15, or the like. (S12).

That is, the signal processor 21 analyzes whether the signal generated from the peripheral device 10 is a signal to be processed by the monitor 20 alone or a signal to be processed through the PC main body 30.

As a result of the analysis, if the signal processed by the monitor 20 alone, that is, a signal generated from the TV receiving card 13, the CD-ROM drive 14, the DVD-ROM drive 15, or the like, the signal processor 21 may generate the signal. The signal is sequentially written to the video memory 22 (S13).

That is, the video processor 22 sequentially writes the R, G, and B signals generated from the TV receiving card 13, the CD-ROM drive 14, the DVD-ROM drive 15, and the like, and then the video processor. Read is sequentially performed at 23. The read signal is generated by the video processor 23 as an R, G, B signal and a synchronization (hereinafter referred to as SYNC) signal (S14).

When the R, G, and B signals and the SYNC signal for synchronizing them are generated by the video processor 23, the video processor 23 applies them to the CRT and displays them on the CRT screen (S15). At this time, the signals displayed on the CRT screen are TV broadcast signals or CD-ROMs generated by the TV receiving card 13, the CD-ROM drive 14, the DVD-ROM drive 15, and the like of the peripheral device 10, respectively. The signals stored in the drive 14 and the DVD-ROM drive 15 are displayed.

In addition, if the signal is generated from the keyboard 11 and the mouse 12 by the analysis of the signal processor 21, the signal processor 21 transmits it to the CPU 31 of the PC main body 30 (S16). . The CPU 31, which has received the signals generated by the keyboard 11 and the mouse 912 by the signal processor 21, executes a program or a command according to the transmitted signals, and generates a resultant video signal (S17). .

The video signals generated by the CPU 31, that is, the R, G, and B signals and the SYNC signal, are transmitted to the signal processor 21 of the monitor 20 again. At this time, the result processed by the CPU 31 of the PC main body 30 is generated by video processing means (not shown) in the PC main body 30.

The signal processor 21 receiving the R, G, B signals generated from the PC main body 30 and the video signal which is a SYNC signal transmits the transmitted video signals to the TV receiving card 13, CD-ROM drive 14, The signal is generated by the DVD-ROM drive 15 and displayed on the CRT.

As such, when the signal processor 21 capable of independently processing signals generated by the peripheral device 10 is installed in the monitor 20, one PC main body may be used when the operating system of the PC provides a multi-monitor environment in the future. By using the server 30 as a server, a multi-working environment can be provided.

In addition, when a plurality of monitors are installed in one PC main body, one monitor processes signals generated by the main body of the PC, and the other PC is a peripheral device such as a TV receiving card, CD-ROM drive, or DVD-ROM drive. By displaying signals generated by the drive, etc., you can perform different tasks.

As described above, in the present invention, when a plurality of monitors are mounted on one PC main body, one monitor processes and displays a video signal generated from the PC main body as in the conventional method, and the other is a peripheral TV. It can be used to listen to music or movies using a receiving card, CD-ROM or DVD-ROM drive.

In addition, if the PC operating system provides a multi-monitor environment, the PC can be used as a server to run different applications on the monitor.

Claims (1)

When the signal processed in the signal processor is a signal to be processed independently, the video memory for writing the input bar (write) sequentially, and a video processor for reading the signal sequentially written to the video memory to display on the CRT In the monitor to say, And a signal processor for transmitting a signal generated from a peripheral keyboard and a mouse to a PC and receiving and processing the resultant video signal again.