KR101008969B1 - Apparatus for controlling led - Google Patents

Abstract

PURPOSE: An apparatus for controlling LED is provided to convert an inputted differential signal a digital signal of parallel configuration by using a DVI distribution circuit and a converter at channel. CONSTITUTION: A connector receives an LVDS signal. A signal converting unit(110) is synchronized with the LVDS signal. The signal converting unit outputs a plurality of LVDS signals. First and second distribution circuits(120,130) distribute the LVDS signal. Decoding units(140,150) decodes the LVDS signal and converts the LVDS signal into parallel digital signals. The decoding unit outputs the digital signal to a serialize unit.

Description

LED integrated control device {Apparatus for Controlling LED}

The present invention relates to an LED integrated control device.

More specifically, by removing the T-bridge and inducing the unmodified differential signal as close as possible to each serialization part, the incoming differential signal is separated into two using a DVI distribution circuit, and in front of each serialization part. The present invention relates to an integrated LED controller for converting a parallel digital signal using a channel-specific converter.

Conventionally, in the case of the LED controller, the maximum resolution is sufficient up to 1280X1200 (SXGA), but as the size of the broadcast gradually increases, the need for a larger display screen is required, so that resolutions of 1600X1200 (UXGA) and 1900X1200 grades can be controlled. You need a controller that can do that.

Through such a necessity, a resolution control apparatus as shown in FIG. 1 has been proposed.

As shown in FIG. 1, the proposed resolution controller includes a decoder 10, an encoder 20, an IC 30, a serialization serializer 40, and a scu 50.

The decoder 10 decodes a signal input from DVI or HDMI and outputs the IC 30 to the IC 30, and the IC 30 converts the decoded signal into a parallel digital signal and outputs the serialized serialization unit 40. do. Meanwhile, the IC 30 outputs a DVI or HDMI signal input from the decoder 10 to the encoder 20, and the encoder 30 encodes the input DVI or HDMI signal and outputs the same to the monitor.

As can be seen from the Besa table, the circuit that operates as described above has to process data of 162MHZ in the case of UXGA 1600 for 8 bits of R.G.B.

However, there is a problem that an impedance matching problem occurs on the T-bridge as the channel increases due to the high frequency.

In addition, the line length is not matched, there is a problem showing a partially unstable phenomenon in the display.

Further, when decoding a signal output through various input devices such as a graphic output terminal of a computer, a graphic output device, etc., there is a problem that a minute error occurs due to a minute difference of various encoders provided in various input devices.

That is, various encoders (input devices, such as computers) for each manufacturer have a certain standard, but when a small difference occurs due to the characteristics of each device, the decoder performs a decoding process simultaneously in a plurality of decoders when matching with a decoder applied to the present invention. If performed, there is a problem in that a fine result difference occurs.

Meanwhile, in the related art, in order to install and use an LED product for various uses in the same place, a separate control device capable of controlling a plurality of LED products is required. For example, if you want to use four products such as LED signboard, LED tube light, LED line light, LED flood light, you need four controllers, which is inefficient and cost-effective in terms of operation and cost. There is also a problem that, in addition, there is a problem that not only the manpower to control each product should be put, but also cause the occurrence of defects.

As described above, the existing LED has been reported and used in electronic display devices as a means for simple information transmission or advertisement, but now it is not only simple information transmission but also designing the exterior of the building and utilizing the media art and media. With the integration of digital, the concept of media facade and media canvas, which is used as a single art canvas in a large building, has been expanded.

The present invention has been made in accordance with the needs as described above, the method of removing the T-bridge and the method of inducing a non-deformed differential signal as close as possible to each serialization part, by using a DVI distribution circuit to the incoming differential signal into two An object of the present invention is to provide an LED integrated control device that can be separated and converted into a digital signal in a parallel form using a converter for each channel in front of each serialization part.

In addition, the present invention is to decode a signal that is already encoded and input at the decoder and then encoded again by using an encoder that matches well with a plurality of decoders and then transmitted through a signal synchronization circuit and a distribution circuit provided at a later stage. It is an object of the present invention to provide an integrated LED control device that can achieve a good error-free result in all the various input devices even when the decoding operation in each of the decoders at the same time.

In addition, an object of the present invention is to provide a plurality of decoders with different outputs to control all the products using the LED, such as media facade, media canvas, LED signboard, LED lighting, LED tube from one controller.

One embodiment of the present invention for achieving the above object, a connector for receiving an LVDS signal; A signal converter for synchronizing the LVDS signals inputted through the connector and outputting the plurality of LVDS signals; First and second distribution circuits for receiving and distributing the LVDS signal output after the synchronization; And a decoder unit which receives the LVDS signal output from the first distribution circuit, decodes the signal, converts the signal into a parallel digital signal, and outputs the serialized serialization unit.

The signal conversion unit is a signal synchronization circuit, and includes a decoder for decoding the LVDS signal input through the connector and an encoder for encoding the LVDS signal decoded by the decoder.

The first and second distribution circuits may convert the LVDS signals inputted from the signal converter into DVI or HDMI output signals and output them to a monitor or another separate system (cascade cascade).

The first and second decoders may include a plurality of decoders, and the decoders may be provided as many as the number of channels, and the serialized serialization units may be matched one-to-one for each channel. It is characterized in that the media facade, LED lighting, LED cube, etc. can be integrated control for each channel.

The present invention removes the T-bridge and induces the unaltered differential signal as close as possible to each serialization part. The inflow differential signal is separated into two using a DVI distribution circuit, and each channel in front of each serialization part. By converting to digital in parallel form by using a separate converter, it is possible to solve the problem of the T-bridge method and bring the original signal as close as possible to the serialized part to display the decoded signal completely without noise. Therefore, there is an effect of obtaining a stable display.

In addition, the present invention is to decode each of the plurality of decoders by decoding the input signal already encoded and input at the decoder, and then by adding a plurality of circuits to be encoded and then transmitted through the signal synchronization circuit and the distribution circuit provided at the rear end. Even when the operation is performed at the same time, it is effective to obtain good results without error in all the various input devices.

1 is a block diagram for explaining the configuration of the LED integrated control apparatus according to the prior art.
2 is a block diagram for explaining the configuration of the LED integrated control apparatus according to the present invention.

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

LED integrated control device according to the present invention is a signal for outputting a plurality of LVDS signals after synchronizing the LVDS signal inputted through the connector 104 and the LVDS signal input through the connector 104, as shown in FIG. The LVDS signal output from the conversion unit 110, the first and second distribution circuits 120 and 130 that receive and distribute the LVDS signal as an input, and the first and second distribution circuits 120 and 130. The first and second decoders 140 and 150 are converted into digital signals in parallel and output to the serialized serialization units 160 and 170.

The signal conversion unit 110 is a signal synchronization circuit, and a decoder 106 for decoding the LVDS signal input through the connector 104 and an encoder 108 for encoding the LVDS signal decoded by the decoder 106. )

The first and second distribution circuits 120 and 130 convert the LVDS signals input from the signal converter 110 into DVI or HDMI output signals and output them to a monitor or a next controller (cascade).

The first and second decoders 140 and 150 are formed of a plurality of decoders, and the decoders are provided as many as the number of channels so as to have one-to-one matching with the serialization serialization units 160 and 170 for each channel. .

The signals output by the serialization serialization unit 160 and 170 are respectively input to the optical module unit 190 and converted into optical signals, and the converted optical signals are transmitted through the optical cable.

Referring to the operation of the LED integrated control device configured as described above are as follows.

First, the signal converter 110, which is a signal converter, is input through a DVI or HDMI connector 104, is decoded by the decoder 106, and then receives an LVDS signal encoded by the encoder 106 and is generated according to the surrounding environment. The distortion may be removed and then output to the first distribution circuit 120 and the second distribution circuit 130. Through the connector 104, the decoder 106, and the encoder 108 as described above, it is possible to obtain the same error-free results in all the various input devices.

Then, the first distribution circuit 120 and the second distribution circuit 130 distributes the LVDS signal input from the signal conversion unit 110 and outputs them to the first decoder unit 130 and the second decoder unit 140. The LVDS signal input from the signal converter 110 is converted into a DVI or HDMI output signal and output to a monitor or a next controller (cascade).

Then, the decoders provided for each channel provided in the first decoder unit 130 and the second decoder unit 140 respectively parallel the LVDS signals distributed by the first distribution circuit 120 and the second distribution circuit 130. The digital signal is converted into a digital signal in the form of a digital signal and outputted to each of the serialized serialized units provided in the serialized serialized units 160 and 170.

In addition, the signals output from the serialization serialization unit 160, 170 are transmitted to the SCU (sub control unit) through the optical cable, thereby preventing noise that can penetrate the cable, as well as when the cable is shorted. It is possible to prevent electrical defects such as sparks that may occur on the interface.

In addition, it enables the long-distance transmission so that it is not saved at the installation site or conditions.

The LED integrated control device according to the present invention described above is a control device that can be used not only for all the equipment using the LED, but also can use different types of systems.

That is, since the decoder unit is designed to adjust the resolution and display data for each decoder unit (decoder) in each decoder unit (decoder), each decoder unit (decoder) in one control unit is used for LED lighting, LED image, and LED tube. It can be lit by lighting or any information or image can be displayed.

As described above, the preferred embodiment according to the present invention has been described, but the present invention is not limited to the above-described embodiments, and the present invention is generally not limited to the scope of the present invention as claimed in the following claims. Anyone with knowledge of the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

110: signal conversion unit
120, 130: first and second distribution circuit
140 and 150: first and second decoder units
160 and 170: first and second serialization serialization unit

Claims (5)

In the LED integrated control device,
A connector receiving an LVDS signal;
A signal converter for synchronizing the LVDS signals inputted through the connector and outputting the plurality of LVDS signals;
First and second distribution circuits for receiving and distributing the LVDS signal output after the synchronization; And
A decoder unit which receives the LVDS signal output from the first distribution circuit, decodes the signal, converts the signal into a parallel digital signal, and outputs the serial signal to each serialized serializer;
LED integrated control device, characterized in that consisting of.
The method of claim 1,
And the signal conversion unit is a signal synchronization circuit, and comprises a decoder for decoding the LVDS signal input through the connector and an encoder for encoding the LVDS signal decoded by the decoder.
The method according to claim 1 or 2,
The first and second distribution circuits, the LVDS signal input from the signal conversion unit converts into a DVI or HDMI output signal and outputs to the monitor or the next controller.
The method of claim 1,
The first and second decoder units may include a plurality of decoders, and the decoders may be provided as many as the number of channels and matched one-to-one to each of the serialized serialization units for each channel. LED integrated control device characterized in that the integrated control for each channel at least one or more of the media canvas, media facade, LED lighting, LED cube consisting of each LED.
The method of claim 1,
And an optical signal converter for converting the serialized signal into an optical signal and transmitting the optical signal to a sub control unit.

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