KR200246560Y1 - A line doubler equipment of video signals - Google Patents

Abstract

The present invention relates to a line doubler device of a video signal, in particular, the A / D converter 20 for converting a video signal input at 15.75KHz into a digital signal, and R, G in the digital signal output from the A / D converter Color signal separation circuit section 30 for extracting the B color signal data, buffer 40 temporarily storing the color signal data extracted by the color signal separation circuit section, and synchronization signal data from the digital signal output from the A / D converter. A timing unit 70 for generating a clock signal for reading the color signal data stored in the buffer at 31.5 KHz by using the synchronization signal separation circuit unit 60 and the synchronization signal data extracted by the synchronization signal separation circuit unit; By using the D / A converter 50 for converting the color signal data read from the buffer into an analog signal according to the clock signal, and using the clock signal and the synchronization signal data output from the timing unit. A synchronous signal generator 80 for generating a synchronous signal corresponding to the color signal data read at .5 kHz, and a color signal output from the D / A converter and a synchronous signal output from the synchronous signal generator are sequentially scanned twice. The video signal is sequentially scanned at a transmission rate of 60 frames per second as the signal output unit 90 repeatedly outputs and the microcomputer 10 controls such an operation. Therefore, even if the image signal is projected on the screen through a large projector can provide a clear picture quality.

Description

A line doubler equipment of video signals

The present invention relates to a line doubler device of a video signal, and in particular, by doubling a video signal output from a TV broadcast signal or a VTR, LDP, etc., the image signal is transferred to a screen through a large projector. The present invention relates to a line doubler device of an image signal capable of providing clear image quality even when projecting.

In general, an image signal is transmitted at a rate of 30 frames per second, and the transmitted frame is scanned by an interlaced scanning method. That is, in the case of scanning one frame as shown in FIG. 4, the first scans as a solid line and the second scans as a dotted line to form a frame.

Since the horizontal scanning line constituting one frame is usually composed of 525 lines, a horizontal scanning frequency of 525 x 30 = 15.75 KHz is used to transmit 30 frames per second as described above. Therefore, the video signal transmitted at 15.75KHz is interlaced to form a screen.

However, when the image signal transmitted at 15.75KHz is projected on the screen using a beam projector, which is a large screen projector, the image quality is not clear as the scanning lines are visible to the naked eye, and this causes the eyestrain. There was this.

Therefore, the present invention is designed to solve the above-mentioned problems. As a result, a large projector is produced by non-interlaced scanning at a transmission rate of 60 frames per second by line doubling a TV broadcast signal or a video signal such as a VTR or LDP. It is an object of the present invention to provide a line doubler device of an image signal that can provide high image quality even if the image signal is projected onto a screen.

In order to achieve the above object, the present invention provides an A / D converter for converting an image signal input at 15.75 KHz into a digital signal, and R, G, and B color signal data from the digital signal output from the A / D converter. Separating the color signal separation circuit unit, a buffer for temporarily storing the R, G, B color signal data extracted by the color signal separation circuit unit, and the synchronization signal separation to extract the synchronization signal data from the digital signal output from the A / D converter A timing section for generating a clock signal for reading R, G, and B color signal data stored in a buffer at 31.5 KHz using the circuit section, the synchronization signal data extracted by the synchronization signal separation circuit section, and a clock signal of the timing section. A D / A converter for converting R, G, and B color signal data read from the buffer into an analog signal, and a clock signal and a synchronization signal data output from the timing unit. A synchronization signal generator for generating a synchronization signal corresponding to the R, G, and B color signal data read at 31.5 KHz, and outputted from the R, G, B color signal and the synchronization signal generator output from the D / A converter. And a signal output unit for repeatedly outputting the synchronization signal twice in a non-interlaced scanning manner and a microcomputer for controlling such an operation.

1 is a block diagram schematically showing a line doubler device according to the present invention;

2 is a view for explaining a scanning method according to the present invention,

3 is a view for comparing the present invention and a conventional video signal transmission method,

4 is a view for explaining a conventional scanning method.

Explanation of symbols for main parts of the drawings

10: microcomputer 20: A / D converter

30: color signal separation circuit 40: buffer

50: D / A converter 60: synchronization signal separation circuit

70 timing unit 80 synchronization signal generator

90: signal output unit

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the present invention in detail as follows.

1 is a block diagram schematically showing the configuration of a video signal line doubler device according to the present invention, wherein the A / D converter 20 converts a video signal including a color signal and a synchronization signal input at 15.75 KHz into a digital signal. The output terminal is connected with a color signal separation circuit section 30 and a synchronization signal separation circuit section 60 which extract R, G, B color signal data and synchronization signal data, respectively, from the converted digital signals.

On the other hand, a buffer 40 for temporarily storing the extracted R, G, and B color signal data is connected to the output terminal of the color signal separation circuit unit 30, and the extracted synchronization signal data is output to the output terminal of the synchronization signal separation circuit unit 60. The timing unit 70 is connected to generate a clock signal for reading the R, G, and B color signal data stored in the buffer 40 at 31.5 KHz.

The output terminal of the buffer 40 is connected with a D / A converter 50 for converting R, G, B color signal data read at 31.5 KHz into an analog signal according to the clock signal of the timing unit 70. A synchronizing signal generator 80 is connected to the output terminal of 70 for generating a synchronizing signal corresponding to the color signal data read out at 31.5 KHz using the clock signal and the synchronizing signal data.

The color signal converted into the analog signal by the D / A converter 50 and the synchronization signal output from the synchronization signal generator 80 are applied to the signal output unit 90, and the signal output unit 90 is R, G The B color signal and the synchronization signal are repeatedly output twice in the manner of non-interlaced scanning as shown in FIG.

Next, the operation method of the line doubler device according to the present invention configured as described above will be described in detail.

When a video signal mixed with a synchronous signal and a color signal having a horizontal scanning frequency of 15.75 KHz is applied to the line doubler device according to the present invention, the A / D converter 20 converts the applied video signal into a digital signal. The R, G, and B color signal data of the digital signals converted as described above are extracted by the color signal separation circuit unit 30 and temporarily stored in the buffer 40.

Meanwhile, the synchronous signal data among the digital signals is extracted by the synchronous signal separating circuit unit 60 and applied to the timing unit 70. When the synchronous signal data is applied in this way, the timing unit 70 stores the R and G stored in the buffer 40. , B Generate a clock signal for reading the color signal data at 31.5 KHz.

Accordingly, the color signal data stored in the buffer 40 is output according to the clock signal generated by the timing unit 70, and the color signal data is converted into an analog signal by the D / A converter 50 and then the signal output unit 90. Is applied.

Meanwhile, the synchronization signal generator 80 generates a synchronization signal corresponding to the color signal data read at 31.5 KHz using the clock signal and the synchronization signal data output from the timing unit 70 and applies it to the signal output unit 90. do. As such, when the color signal and the synchronization signal are applied, the signal output unit 90 repeatedly outputs the color signal and the synchronization signal twice in a non-interlaced scanning manner at 31.5 KHz.

That is, as shown in FIG. 3, one frame is conventionally transmitted in the interlaced scanning method for 33.333 ms, but in the present invention, one frame is used in the non-interlaced scanning method for 33.333 ms. By repeating the transmission twice, it is possible to provide a clearer screen.

As described above, the present invention is capable of projecting an image signal on a screen through a large projector by non-interlaced scanning at a transmission rate of 60 frames per second by line doubling a TV broadcast signal or a video signal such as a VTR or LDP. High picture quality can be provided. Therefore, the screen is clear and eye fatigue is alleviated.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention should be determined only by the appended utility model registration claims.

Claims (1)

An A / D converter 20 for converting an image signal input at 15.75 KHz into a digital signal, and a color signal separation circuit unit for extracting R, G, and B color signal data from the digital signal output from the A / D converter 20 ( 30, a buffer 40 for temporarily storing the R, G, and B color signal data extracted by the color signal separation circuit unit 30, and the synchronization signal data in the digital signal output from the A / D converter 20. For reading the R, G, B color signal data stored in the buffer 40 at 31.5 KHz by using the synchronization signal separation circuit unit 60 for extracting and the synchronization signal data extracted by the synchronization signal separation circuit unit 60. A timing unit 70 for generating a clock signal and a D / A converter 50 for converting R, G, and B color signal data read from the buffer 40 into an analog signal according to the clock signal of the timing unit 70. And, using the clock signal and the synchronization signal data output from the timing unit 70 To generate a synchronization signal corresponding to the R, G, B color signal data read at 31.5 KHz, and the R, G, B color signal and the synchronization signal output from the D / A converter 50. And a signal output unit 90 which repeatedly outputs the synchronization signal output from the generator 80 twice in a non-interlaced scanning manner, and the microcomputer 10 for controlling such an operation. A line doubler device for a video signal.