KR20060062307A - A digital image equipment and signal processing method thereof - Google Patents

Abstract

The present invention relates to a digital imaging apparatus and a signal processing method thereof, and an object of the present invention is to provide a digital imaging apparatus capable of completely reconstructing an image while transmitting a non-standard signal according to the ITU-R 656 standard when an external input is performed. It is to provide a signal processing method.

In addition, the present invention provides a digital imaging apparatus and a signal processing method capable of stably restoring a non-standard signal even when using only a low bit number interface of the ITU-R 656.

To this end, the present invention, when inputting a non-standard video signal that does not meet the transmission standard to the digital imaging device, and inserts the information about the synchronization signal to the signal modified by the non-standard video signal according to the transmission standard to transmit to the output device It is done.

Description

Digital imaging equipment and signal processing method

1 is a block diagram illustrating a digital imaging apparatus according to a conventional ITU-R 656.

2 is a block diagram illustrating a digital imaging apparatus according to a conventional ITU-R 601.

3 is a block diagram illustrating components of a digital imaging apparatus according to an embodiment of the present invention.

4 is a block diagram illustrating components of a digital imaging apparatus according to an embodiment of the present invention.

FIG. 5 is a flowchart illustrating a signal processing method when inputting a non-standard signal of the digital imaging apparatus shown in FIG. 4.

Explanation of symbols on the main parts of the drawings

10: color decoder

12: ITU-R 656 Encoder

14: ITU-R 656 decoder

16: color encoder

18: Modified ITU-R 656 Encoder

20: Modified ITU-R 656 Decoder

The present invention relates to a digital imaging apparatus and a signal processing method thereof, and more particularly, to a digital imaging apparatus and a signal processing method capable of stably restoring an image even when a non-standard video signal is input.

In general, a video service has a large amount of data, and when the existing communication technology is applied as it is, high quality real time transmission is impossible. Therefore, in the signal processing method capable of processing a large amount of data, the digital signal processing method can easily reduce the size of the transmitting and receiving terminals by using digital elements and easily remove noise generated in the transmission path, thereby providing high quality voice and image. Can be transmitted. In addition, in the case of digital, image signal compression is facilitated by using high correlation and low recognition rate of human vision.

International Telecommunication Union (ITU) defines such an international standard for encoding video services, among which ITU-R (Radio communication) deals with international standards for video signals.

ITU-R is divided into several standards, including ITU-R 656 and ITU-R 601. The video signal (video signal) is encoded and transmitted according to each standard, and the video output device decodes the transmitted signal according to each standard and displays the image on an output device such as a monitor. Will be able to completely restore the.

On the other hand, when a non-standard signal that does not conform to the standard of the ITU-R is input according to the line in function, as shown in FIG. 1, according to the conventional ITU-R 656 interface, first, a non-standard signal is a digital signal. It is input to the color decoder 1 in the form of a jitter signal. In the color decoder 1, the composite signal is separated into color, brightness, and synchronization signals, input to the ITU-R 656 encoder 3, and converted into an 8-bit signal according to the 656 standard. The converted 8-bit signal is transmitted to the output device, and the ITU-R 656 decoder 5 on the output device side receives the signal and outputs the corresponding image on the screen.

However, because the non-standard signal has a different frame size from the standard signal, the vertical synchronous signal in the ITU-R 656 encoder 3 does not match the vertical synchronous signal of the actual non-standard signal, so the vertical synchronous signal transmitted from the ITU-R 656 decoder 5 is transmitted. As a result, when the image is output, the screen is not stably output and a problem occurs that synchronization is not correct.

As a solution to this problem, it may be considered to use the ITU-R 601 interface as shown in FIG. Like 656, a non-standard signal is input to the color decoder 1 in the form of a composite signal, and then separated into color, brightness, and synchronization signals. The separated signals are input to the ITU-R 601 encoder 2 and then converted according to the 601 standard. Unlike 656, the 601 transmits the signal to the output device in the form of a 20 to 24 bit signal input from the color decoder 1. The ITU-R 601 decoder 4 on the output side receives this signal and outputs it to the screen. As described above, in the 601 standard, the vertical synchronization signal separated from the color decoder 1 is transmitted to the ITU-R 601 decoder 4 as it is, so that the restoration of the image signal is made stable.

However, compared to the ITU-R 656 standard, the ITU-R 601 standard increases the number of bits by about three times at the interface, which makes it difficult to apply to a device that simply uses the interface.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a digital imaging apparatus capable of completely reconstructing an image while transmitting a non-standard signal according to the ITU-R 656 standard when an external input and a signal processing method thereof. In providing.

In addition, the present invention provides a digital imaging apparatus and a signal processing method capable of stably restoring a non-standard signal even when using only a low bit number interface of the ITU-R 656.

According to an aspect of the present invention, a non-standard video signal that does not conform to a transmission standard is input to a digital imaging apparatus, and the output device further inserts information on a synchronization signal into a signal obtained by transforming the non-standard video signal according to the transmission standard. It characterized in that the transmission to.

The non-standard video signal input to the decoder is separated into a color signal, a brightness signal, and a synchronization signal, and the separated signal is transformed into a predetermined bit in accordance with the transmission standard by a transmission standard encoder, and the vertical synchronization signal separated by the decoder and the The transmission standard encoder retransforms the transformed signal into predetermined bits and transmits the signal to the output device.

The output device may be further configured to separate the retransformed signal into a signal according to the transmission standard and a vertical synchronization signal, and to output the signal according to the transmission standard to the output device in accordance with the vertical synchronization signal.

In addition, the transmission standard is characterized in that the standard according to ITU-R 656.

In addition, a decoder that separates a video signal into color, brightness, and synchronization signals, a first encoder that transforms the separated signal into predetermined bits according to a transmission standard, and a modification in the encoder when the video signal is a non-standard signal that does not meet the transmission standard. And a second encoder for remodifying the obtained signal and the synchronization signal separated by the decoder into predetermined bits.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

3 shows a digital imaging apparatus according to an embodiment of the present invention, which is a video signal processing block according to the ITU-R 656 standard, including a color decoder 10, an ITU-R 656 encoder 12, and an ITU- An R 656 decoder 14 and a color encoder 16.

In some cases, non-standard signals output from analog devices are input by the LINE IN function. First, the LINE IN function is a function that accepts an externally input signal and processes it in a digital video device. It is a device that supports LINE IN function of digital video device such as DVD or camcorder, and it can be input through interface such as USB cable and output to the screen such as monitor or TV.                     

The non-standard signal input to the digital imaging apparatus according to the LINE IN function is converted into a composite signal which is a digital signal and input to the color decoder 10. The color decoder 10 separates the composite signal into a Y signal representing brightness, a C signal representing color, and a synchronization signal. Each signal is about 8 bits long. The separated signal is input to the ITU-R 656 encoder 12 and encoded into a signal conforming to the ITU-R 656 standard, which is an interface standard for digital video signals. The encoded signal has a size of about 8 bits.

The 8-bit signal converted according to the ITU-R 656 standard is transmitted to an output device such as a monitor or TV. In this case, the vertical synchronization signal (V Sync) among the sync signals separated by the color decoder 10 in addition to the converted 8-bit signal. ) Will also be sent.

The output device receives an 8-bit signal and a vertical synchronization signal, and the 8-bit signal is separated from the Y signal, the C signal, and the synchronization signal by the ITU-R 656 decoder 14 according to the ITU-R 656 standard. 16, and the vertical synchronization signal is directly input to the color encoder 16. The color encoder 16 outputs image data transmitted from the ITU-R 656 decoder 14 to a monitor or a TV in synchronization with the vertical synchronization signal directly transmitted from the color decoder 10.

In this way, by transmitting data related to the vertical synchronization signal to 8-bit data encoded according to the ITU-R 656 standard, non-standard signals such as analog signals can be stably reproduced on the screen. However, since this requires transmitting more data corresponding to the vertical synchronization signal than the conventional transmission method according to ITU-R 656, the number of bits in the interface increases slightly. Hereinafter, referring to FIG. 4, a configuration capable of reducing bits required for an interface as compared to FIG. 3 will be described.

4 further includes a modified ITU-R 656 encoder 18 and a modified ITU-R 656 decoder 20 as compared to FIG. 3. The modified ITU-R 656 encoder 18 carries information on the vertical synchronization signal transmitted from the color decoder 10 on 8-bit transformed data according to the ITU-R 656 standard in the ITU-R 656 encoder 12. It is responsible for retransforming into bit data. In the 8-bit data modified by the ITU-R 656 encoder 12, there is a part in which no information is contained, and a specific position is designated among these parts to contain information about a vertical synchronization signal. In the modified ITU-R 656 decoder 20, the 8-bit transformed signal is further divided into 8-bit ITU-R 656 standard signals and vertical synchronization signals, and then the ITU-R 656 decoder 14 and It is responsible for transmitting to the color encoder 16. The vertical synchronization signal can be separated by previously storing information about the position of the portion of the 8-bit signal that has been retransformed in the modified ITU-R 656 decoder 20 on which the vertical synchronization signal is carried.

Hereinafter, a signal processing method when a non-standard signal is input to the digital imaging device shown in FIG. 4 will be described with reference to FIG. 5.

The analog signal input to the digital imaging apparatus according to the LINE IN function is converted into a composite signal in the form of a digital signal and then input to the color decoder 10. The color decoder 10 separates the compositor signal into a Y signal, a C signal, and a synchronization signal (S100).

Data about the separated signal is input to the ITU-R 656 encoder 12. The ITU-R 656 encoder 12 transforms the received signal into an 8-bit signal according to the ITU-R 656 standard and inputs the transformed signal to the modified ITU-R 656 encoder 18. (S110) Then, the color decoder 10 The vertical sync signal (V Sync) among the sync signals separated from) is input to the separately modified ITU-R 656 encoder 18 (S120).

In the modified ITU-R 656 encoder 18, the vertical synchronization signal is loaded on the 8-bit data transformed according to the ITU-R 656 standard and re-modified into an 8-bit signal again (S130). It is transmitted to the output device side through the interface (S140).

The modified ITU-R 656 decoder 20 on the output side receives the 8-bit transformed signal and transmits the vertical synchronization signal to the color encoder 16 separately (S150). Is transmitted to the ITU-R 656 decoder 14 and decoded according to the ITU-R 656 standard. The decoded signal is transmitted to the color encoder 16 (S160).

The color encoder 16 encodes the signal decoded by the ITU-R 656 decoder 14 in accordance with the vertical synchronization signal, and outputs the information on a screen such as a monitor or a TV (S170).

According to this method, when non-standard signals such as analog signals are interfaced by the ITU-R 656 standard, not only can the signal be stably synchronized with the vertically synchronized signal transmitted separately, but also the ITU-R 656 standard. You can interface with the same number of bits.

On the other hand, the present invention takes the signal processing according to the ITU-R 656 standard as an example, of course, the present invention can be applied to signal processing related to other international standards.

As described in detail above, when the non-standard signal is input, the present invention can completely reconstruct the synchronization of the video signal by modifying only a part of the block according to the signal processing of the existing ITU-R 656.

In addition, it is possible to transmit both information about the signal and the synchronization signal according to the ITU-R 656 standard without increasing the number of bits in the interface, it can be applied to the device that needs to simplify the interface.

Claims (5)

When inputting a non-standard video signal that does not meet the transmission standard to the digital imaging device, the digital imaging device characterized in that the non-standard video signal to the output device by inserting the information on the synchronization signal in the signal modified according to the transmission standard further Signal processing method. The method of claim 1, The non-standard video signal input to the decoder is separated into a color signal, brightness signal, sync signal,  The separated signal is transformed into a predetermined bit in the transmission standard encoder according to the transmission standard, And retransforming the vertical synchronization signal separated by the decoder and the signal modified by the transmission standard encoder into predetermined bits and transmitting the same to the output device. The method of claim 2, In the output device, the retransformed signal is separated into a signal according to the transmission standard and a vertical synchronization signal, And a signal according to the transmission standard to the output device in accordance with the vertical synchronization signal. The method of claim 1, The transmission standard is a signal processing method of a digital imaging device, characterized in that the standard according to ITU-R 656. A decoder that separates the video signal into color, brightness, and sync signals, A first encoder for transforming the separated signal into predetermined bits in accordance with a transmission standard, And a second encoder for transforming the modified signal from the encoder and the synchronous signal separated from the decoder into predetermined bits when the video signal is a non-standard signal that does not meet the transmission standard.

Images