KR0151499B1 - Start code detection apparatus of pal plus image signal - Google Patents

Abstract

The present invention relates to an apparatus for detecting a start code of a PAL PLUS video signal. When the start code detection apparatus of the FalPlus video signal according to the present invention detects the start code in the 23rd line in which the relevant information of the Falplus video is recorded, only the remaining data except for the edge portion where the Falth width may be deformed It is determined whether the detected signal is correct using the start code. Therefore, the present invention has the effect of improving the detection capability of the start code.

Description

Start code detection device of PAL PLUS video signal.

1 is a block diagram showing an apparatus for detecting a start code of an arm plus image signal according to the present invention.

FIG. 2 is a timing diagram for explaining the operation of the window signal generation unit 20 in FIG.

3 is a timing diagram for explaining the operation of the data slice unit 30 in FIG.

4 is a timing diagram for comparing the operation of the start code detection unit 40 according to the present invention of FIG.

＊ Explanation of symbols on main parts of drawing

10: synchronization signal separation unit 20: window signal generation unit

30: data slice unit 40: start code detection unit

CNT: Counter AND1, AND2: Logic element

D1 ~ D24: D-Flip Flop

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a PAL-PLUS image reproducing apparatus, and more particularly, by accurately detecting a start code of the 23rd line of a PALPLUS image signal, using the information recorded in this line, using a PALPLUS image. The present invention relates to an apparatus for detecting a start code of an arm plus image signal to clarify a distinction between a signal and a normal PAL signal.

The PalPlus video signal currently being tested in Europe includes a Helper signal that enables users to watch Palplus video signals with a 16: 9 signal without distortion on a regular TV with a 4: 3 aspect ratio. .

When recording the FalPlus video signal, the helper signal is demodulated to the original luminance signal in order to prevent the modulated helper signal from being lost during the recording or reproducing operation. In order to indicate that the helper signal is demodulated, the signal bit of the 23rd line of the FalPlus video signal is changed to the demodulated helper signal and recorded.

Therefore, when reproducing the arm video signal, it is determined whether the signal is a Falplus video signal or a general Falplus video signal according to the information on the 23rd line, and the signal processing conforms to each standard.

An object of the present invention starts by excluding data of an edge part which is prone to error when determining whether the start code detected in the 23rd line of the Falplus video signal matches the value specified in the format. The present invention provides an apparatus for detecting a start code of an arm plus image signal, which improves a code detection capability.

An apparatus for detecting a start code of an arm plus image signal according to the present invention for achieving the above object comprises: detecting an start code of a 23rd line in which information relating to an arm plus is recorded in an arm plus image signal; A synchronization signal separating unit for receiving vertical plus horizontal synchronization signals by receiving an arm plus image signal, a window signal generating unit generating window pulses when a line count value of the synchronization signals is 23, and the window pulse section A data slice unit for slicing the data of the Falplus video signal input therein, and the remaining data except for the data adjacent to the rising or falling edge in the start code defined in the Falplus video format and the slide data corresponding thereto; And a start code detection unit for detecting a start code by determining whether there is a match.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an apparatus for detecting a start code of an arm plus image signal according to the present invention. The start code detection apparatus of FIG. 1 includes a synchronization signal separator 10 for separating the vertical and horizontal synchronization signals V_SYNC and H_SYNC from the image input signal Video. The output terminal of the synchronization signal separator 10 is connected to a window signal generator 20 for generating a window pulse to detect data of a desired line in the video input signal Video. The window signal generation unit 20 includes a counter CNT that counts a line using the synchronization signals V_SYNC and H_SYNC, and an AND product AND1 that generates a window pulse when the count value matches a predetermined value. It is composed of

The data slice unit 30 which slices and outputs an image signal Video input in the window pulse section is connected to an output terminal of the window signal generator 20. In addition, a start code detector 40 for detecting a start code from sliced data is connected to an output terminal of the data slice unit 30. The start code detector 40 is configured to receive data in a sliced unit, to include 24 D-flip flops D1 to D24 connected in series, and adjacent data among 24 D-flip flops D1 to D24. It consists of a logical AND device (AND2) connected to the output terminals of 12 D-flip flops having the same value. The clock CLK from the outside for controlling the operation is input to the D-flip flops D1 to D24.

The operation of the start code detecting apparatus according to the present invention configured as described above will be described in more detail as follows.

First, the sync signal separator 10 receives the Arm Plus video signal Video and separates the vertical and horizontal sync signals V_SYNC and H_SYNC. The counter CNT of the window signal generator 20 receives the vertical synchronizing signal V_SYNC as the clear terminal CLR, and counts the horizontal synchronizing signal H_SYNC input from the clock terminal CLK. When the count value reaches 23, the counter CNT inverts the value output as '0' in the binary bit representing 23 and outputs the inverted value. The AND product generates a window pulse, as shown in FIG. 2, when the coefficient value reaches 23. FIG.

The data slice unit 30 receives the window pulse and slices the Palplus video signal Video inputted within the window pulse section. That is, the data slice unit 30 slices the data of the 23rd line of the FalPlus video signal Video bit by bit.

3 (a) shows a sliced data string. As shown, the 23rd line is composed of 14 items of data related to Clock Run In, Start Code, and FalPlus video signal. Here, the pulse width of each bit is 200ns. However, according to the characteristics of the data slice IC, as shown in FIG. 3 (b), the pulse width of the sliced data may be slightly changed, and the deformation width is about 50 to 150 ns.

FIG. 4 (a) is a timing diagram for explaining the start code detection operation according to the prior art, and shows a value obtained by sampling slice data whose pulse width is slightly modified as described above according to a clock CLK supplied from the outside. At this time, comparing the sampled value with the start code defined in the Palflexor format, it can be seen that an error occurs in the edge portion of the slice data. When a large number of errors occur as described above, it is conventionally determined that this data is not a start code. Therefore, although the input signal is the arm plus image signal, it is determined to be a general arm image signal, and the corresponding signal processing is performed.

On the other hand, in the start code detection operation according to the present invention of FIG. 4 (b), the start code detection unit 40 of the present invention firstly connects the D-flip flops in series whenever the clock CLK is applied from the outside. The slice data is applied to the next D-flip flops D1 to D24 at D1 to D24, respectively. Each of the D-flip flops D1 to D24 corresponds to one bit of the start code specified in the format, and when the corresponding bit value is '1', it is a Q output terminal. Output signal to output terminal. Therefore, each of the D flip-flops D1 to D24 generates a high level output signal from each output terminal when the slice data to be applied coincides with a prescribed value.

Here, the output signals of the D-flip flops corresponding to the output signals adjacent to the rising or falling edge of the pulse, which are prone to errors, are not input to the AND product AND2 in consideration of the deformation width of the pulse. In FIG. 1, the D-flip flops, denoted by '×', represent the D-flip flops that generate an output signal that is not related to the start code detection operation.

The AND product AND2 determines that this data matches the start code specified in the format when the input signals except for the edge portion are all at the high level, and generates a high level start code detection signal Start.

Such a start code detection apparatus of an arm plus image signal according to the present invention, when detecting the start code in the 23rd line where the relevant information of the arm plus image is recorded, except for the data of the edge portion where the pulse width may be changed. Use only the data to determine if the detected code is correct for the start code. Therefore, the present invention has the effect of improving the detection capability of the start code.

Claims (3)

An apparatus for detecting a start code of a 23 th line in which information related to an arm plus is recorded in an arm plus image signal, the apparatus comprising: a synchronization signal separator configured to receive the arm plus image signal and separate vertical and horizontal synchronization signals; A window signal generator for generating a window pulse when the value of counting a line using the synchronization signals is 23; A data slice unit which slices data of the Falplus image signal input in the window pulse section; And a start code detection unit for detecting a start code by determining whether the remaining data except for the data adjacent to the rising or falling edge and the sliced data corresponding thereto are identical to the starting code defined in the Armplus video format. Start code detection device for PAL PLUS video signal. 2. The apparatus of claim 1, wherein the start code detector comprises: a plurality of delayers connected in series to receive the sliced data in series and generate an output signal when the sliced data matches the prescribed start code; And a logical multiplication device for generating a start code detection signal by receiving and outputting only the output signals of the delayers having the same output terminal as the adjacent delayers among the plurality of delayers. Device for detecting start code of signal. The apparatus of claim 2, wherein the retarder comprises a D-flip flop.