KR100238583B1 - Display apparatus having a remote control function to a peripherals - Google Patents

Abstract

The present invention relates to a display device having a remote control function that can control the operation of each peripheral device by a microcomputer of the display device using a communication line (I ² C) with the peripheral device connected to the display device.

The operation of each peripheral device can be controlled by supplying a control signal from the microcomputer of the display device to the microcomputer of the peripheral device connected to the display device using the I ² C bus.

Description

Display device with remote control of peripherals

The present invention relates to a display device, and more particularly, a display having a remote control function capable of controlling the operation of each peripheral device with a microcomputer of the display device using a communication line (I ² C) with a peripheral device connected to the display device. Relates to a device.

The display device is a representative computer peripheral device, the configuration of which can be represented as shown in FIG.

As shown in the drawing, the computer 100 receives an input signal and processes the input signal, and generates data according to the processed result, and receives the data output from the CPU 110 and receives the image signals R and G. And a video card 120 for outputting the horizontal synchronizing signal HS and the vertical synchronizing signal VS for processing with B) and synchronizing them.

The monitor 200 receives image signals R, G, and B and a horizontal / vertical synchronization signal from the video card 120 in the computer 100, and outputs a control signal such as a phase adjustment signal and a reference oscillation signal at a rear end thereof. A microcomputer 210, a control button unit 220 for outputting a screen control signal for the operation of the microcomputer 210, and a monitor screen control signal and a reference oscillation signal output from the microcomputer 210. Horizontal and vertical output circuits 230 for receiving and synchronizing rasters; video circuits 240 for receiving and amplifying and displaying image signals output from the video card 120; and the microcomputer 210. And a power supply circuit section 250 for supplying a driving voltage to the horizontal and vertical output circuit sections 230 and the image signal processing section 240.

Looking at each block in the monitor 200 having such a configuration in more detail as follows.

The horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC output from the video card 120 of the computer 100 are applied by the microcomputer 210 that stores various screen control data. The microcomputer 210 receiving the horizontal synchronizing signal H-SYNC and the vertical synchronizing 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 and vertical oscillation signal processor 231 receiving the phase adjustment signal and the reference oscillation signal output from the microcomputer 210 receive the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V- applied from the video card 120. SYNC) applies a vertical pulse to the vertical drive circuit 232 for controlling the switching speed of the on / off operation of the sawtooth wave generating circuit.

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 234, and thus vertical The scanning cycle is determined.

Horizontal oscillation signals output from the horizontal and vertical oscillation signal processors 231 are 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.

In addition, a flyback transformer (hereinafter referred to as FBT) 239 is used to supply a stable direct current (DC) voltage to an anode of a cathode ray tube (hereinafter referred to as a CRT) 243. do.

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.

An anode terminal receiving high voltage adjusts the luminance of the image signals R, G, and B that are amplified and output from the image signal processor 240. The OSD unit 241 receives OSD data according to the screen control signal output from the microcomputer 21 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. By using the OSD data displayed on the CRT 244, the user of the monitor 200 may provide the function or information of the monitor 200.

The power supply circuit unit 250 supplying the driving voltage of the monitor 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 monitor 200 is dispersed to restore the color bleeding state.

In addition, a direct current rectified and output through the rectifier 253 is applied to the switching transformer 254. The switching transformer 254 receiving direct current performs a switching operation to supply various driving voltages required in the monitor 200 through the voltage output terminal 255. At this time, if the vertical synchronizing signal V-SYNC is not applied from the video card 120, the microcomputer 210 applies the suspend mode signal to the voltage regulator 256 to apply the deflection voltage transmitted through the voltage output terminal 255. Will be blocked.

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 a DPMS mode according to whether the horizontal sync signal H-SYNC and the vertical sync signal V-SYNC are detected to reduce power consumption consumed in the monitor 200. 200) to reduce the power consumption inside.

On the other hand, according to the recent trend, such display devices have been gradually diversifying their functions. It plays the role of multimedia with various functions such as watching specific graphics, movies, etc. using a CD-ROM, watching TV, and listening to music.

Therefore, the display device has a multimedia function and processes video and sound signals transmitted from various peripheral devices such as a DV, a VCR, and an externally mounted camera as shown in FIG. 2.

In this state, when controlling each device connected around the display, a control button attached to each device is used or a remote controller that generates an adjustment signal to each device is used.

Therefore, they had to spend extra labor on adjusting each device.

This inconvenience is further increased when the display status is checked by continuously adjusting the functions of each peripheral device.

An object of the present invention is to provide a display device capable of controlling each peripheral device by using a communication line connected to the microcomputer of the display device and the microcomputer mounted on each peripheral device.

In order to achieve the above object, the present invention provides a display device capable of controlling a peripheral device connected to a display device to perform a multimedia function, wherein the microcomputer of the display device operates the peripheral device through a communication line with the microcomputer of each peripheral device. Characterized in that can be controlled.

In addition, the communication between each microcomputer is an additional feature of the present invention using the I ² C bus.

1 is a block diagram showing the configuration of a general display device;

2 is a block diagram of a display device for implementing a multimedia function;

3 is an exemplary diagram in which a USB hub is mounted on a display device stand;

4 is an exemplary diagram illustrating a signal transmission scheme using an I ² C bus;

5 is a signal waveform diagram illustrating the start and end of an I ² C signal system.

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

For actual communication between the microcomputer of the display device and the microcomputer of the peripheral device, it is assumed that each device is connected through a USB hub.

In response to the demand for more and more user-friendly peripherals, specifications have been developed that use Universal Serial Bus (USB) hubs.

This USB hub eliminates the need for users to open their computers to connect peripherals or related cards. Adding peripherals is as easy as fitting a desk lamp instead.

These expansion hubs provide additional connection sockets and can be connected in a stacked tree. Each peripheral device can be up to several meters away from one another or from an expansion hub.

3 shows an example in which the USB hub is mounted on the stand of the display device. It is assumed that a computer is connected to the upstream ports, and DVD, VCR and camera are connected to each downstream port.

If the user wants to drive the VCR, the user opens the OSD screen of the display device and operates to apply power to the VCR. This signal is sent to the microcomputer's microcomputer via a VCR communication line connected to a USB hub.

The microcomputer of the VCR supplies power by switching the power supply terminal of the VCR according to this signal.

Meanwhile, as shown in FIG. 4, the communication signal between two microcomputers is transmitted using a control signal transmission system of an I ² C bus.

As shown in the figure, information transfer between components is performed using the I ² C bus.

Here, I ² C (Inter-Integrated Circuit) a little description of the serial data (SDA) and the serial clock (SCL) through the two lines connected to the bus (Bus) to transfer information between each other.

The data of the serial data SDA should be kept stable while the clock SCL is in the high "High" period.

In addition, a change in the state of the serial data SDA, that is, a change from high to low, or from low to high, is possible only when the serial clock SCL is in a low state. .

Start and end of data communication are as shown in FIG. That is, when the serial data SDA is changed from high to low in the state where the serial clock SCL is high "High", this state is a start signal.

In addition, when the serial data SDA is changed from low to high in the state where the serial clock SCL is "high", it means a stop.

In addition, according to the characteristics of the signal can be delivered a signal that can control the functions such as play, stop, mute of the VCR.

As described above, the present invention has the effect of controlling the functions of each peripheral device using a communication line between the microcomputer of each peripheral device and the microcomputer of the display device in a display device to which multimedia devices such as a DVD and a VCR are connected.

Claims (3)

A display device capable of controlling a peripheral device connected to a display device to perform a multimedia function, The display device having a remote control function for the peripheral device, characterized in that the microcomputer of the display device can control the operation of each peripheral device through a communication line with the microcomputer of each peripheral device. The method of claim 1, The microcommunication communication is a display device having a remote control function for the peripheral device, characterized in that using the I ² C bus. The method of claim 1, Display device having a remote control function for the peripheral device, characterized in that for controlling the remote control signal of the display device via the OSD screen.

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