JPS63233687A - Picture coder - Google Patents

Abstract

PURPOSE:To send plural digital picture signals through one transmission line by one set of picture coder by multiplexing a digital picture signal being a conversion of a television camera output picture signal and a digital picture signal received externally subject to the state of phase synchronization. CONSTITUTION:When it is required to synchronize a picture signal inputted from input terminals 1, 2 with a received picture signal, a vertical synchronizing position signal R being an output of a decoder 26, a horizontal synchronizing position signal S and a sampling clock T are switched into a vertical synchronizing position signal X being an output of a switch 12, a horizontal synchronizing position signal Y and a sampling clock Z. On the other hand, in synchronizing the phase of the picture signal of other station with a picture signal sent from its own station, the vertical synchronizing position signal U being the output of the internal signal generator 11, the horizontal synchronizing location signal V and the sampling clock W are switched into the vertical synchronizing position signal X being the output of the switch 12, the horizontal synchronizing position signal Y and sampling clock Z. Thus, the picture signal synchronously with the received picture signal is inputted a transmission section of the picture coder.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an image encoding device that encodes an image signal with high efficiency by predictive encoding or transform encoding.

[Conventional technology]

Conventionally, in order to encode and transmit multiple image signals with high efficiency, a reference signal was output from a television signal generator to each television camera, and the image signals output from each television camera were phase-synchronized. Or.

Use the output signal of one TV camera as the reference signal.

Lock onto other TV cameras (generation)
1ock) signal, and the phase synchronization of each television camera output signal is inputted to one image encoding device.

There is a method that performs multiple processing and transmits the outputs of two television cameras through a transmission line with a capacity capable of transmitting one image signal.

[Problem that the invention seeks to solve]

However, in the conventional method described above, the image signal input to the image encoding device and the decoded image signal do not match in frequency or phase, and the above-mentioned decoded image signal and the image signal output from the new television camera are not matched. It is impossible to perform multiplexing and high-efficiency compression encoding using one image encoding device and transmitting the same through one transmission path, so multiple image encoding devices and transmission paths are required, and the encoding It had the disadvantage of low efficiency.

Furthermore, although multiplexing is possible by using a frame synchronizer, there are disadvantages in that, in principle, frames may sometimes be missing or the same frame may be output repeatedly.

In view of the above drawbacks, the second technical problem of the present invention is to provide an image signal that is synchronized with a received external image signal by phase-synchronizing the output of a television camera or the like.

An object of the present invention is to provide an image synchronization signal generating means for outputting to a transmitter of an image encoding device.

[Means for solving problems]

According to the present invention, a transmitter receives a television camera output image signal phase-synchronized with a reference signal, converts it into a digital image signal, multiplexes it, performs high-efficiency compression encoding, and outputs the signal; and a transmitter that receives a digital image signal received from the outside. a decoding means for reproducing a vertical synchronization position signal, a horizontal synchronization position signal, and a sample clock from the signal; and an image synchronization signal generation means for generating a phase synchronization reference signal synchronized with the vertical synchronization position signal, horizontal synchronization position signal, and sample clock. There is obtained an image encoding device characterized in that it has a receiving section provided with a receiver section, and uses the phase synchronization reference signal from the receiving section as the reference signal in the transmitting section.

Therefore, the digital image signal obtained by converting the television camera output image signal and the digital image signal received from the outside can be multiplexed in a phase-synchronized state. Digital image signals can be sent to one transmission path.

〔Example〕

Next, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 shows an embodiment of the present invention.

Analog image signal a from a television camera or image decoder,
b is input from nine image input terminals 1 and 2.

The digital image signals c and d are converted into digital image signals c and d by the first and second A/D converters 3 and 4, and are subjected to predetermined line multiplexing processing within one frame of the image signal by the two-image multiplexing circuit 5. This multiplexed image signal e is subjected to high-efficiency compression encoding in the encoder 6, and is sent out from the digital signal output terminal 7 to the transmission path and transmitted to the other party.

On the other hand, the encoded data transmitted from the other party.

It is input from the input terminal 27. In the decoder 26.

The encoded data F is decoded into a multiplexed image signal E, and the vertical synchronization position signal R2, horizontal synchronization position signal S, and sampling clock T of the multiplexed image signal E are reproduced.

The decoded multiplexed signal E is subjected to separation and interpolation in a separation circuit 25 and output as digital image signals C and D. The third and fourth converters 23 and 24 convert the digital image signals C and D into analog and digital image signals A and B, and output them to a television monitor or the like from output terminals 21 and 22.

Further, a vertical synchronization position signal U, a horizontal synchronization position signal, and a sampling clock W, which are output from the internal signal generator 11,
The switch 12 selects one of the vertical synchronization position signal R1, the horizontal synchronization position signal S, and the sampling clock T output from the decoder 26, and converts the image reference signal in synchronization with the selected signal. G is generated by the image synchronization signal generator 13 and outputted from output terminals 14 and 15 to a terminal such as a TV camera.

Here, if it is necessary to synchronize the image signal input from the input terminal 1.2 with the received image signal.

Vertical synchronization position signal Switch.

On the other hand, when phase-synchronizing the image signal of another station with the image signal transmitted from the own station, the internal signal generator 11 The outputs of the vertical synchronization position signal U, horizontal synchronization position signal, and sampling clock W are switched.

FIG. 3 shows a specific example of the configuration of the image synchronization signal generator 13.

The synchronization signal generation circuit 131 generates a vertical synchronization position signal X and a horizontal synchronization position signal, which are the outputs of the switch 12.

A sampling clock 2 is input, and a composite synchronization signal H and a color burst position signal are output. The color burst signal generation circuit 132 inputs the sampling signal A2 and the color burst position signal signal, and outputs a color burst signal J. The color burst signal J is waveform-shaped by a bandpass filter 133 and then converted into a composite synchronization signal H by two synthesis circuits 134 and 135.
The reference signal G of the image is output.

The operation of the circuit shown in Fig. 3 is explained using Figs. 4 and 5.

The output of the decoder 26, the vertical synchronization position signal R2, the horizontal synchronization position signal S, and the sampling clock T are selected as the vertical synchronization position signal X, the horizontal synchronization position signal Y, and the sampling clock 2, which are the outputs of the switch 13. , the operation of outputting an image reference signal synchronized with a received image signal will be explained.

FIG. 4 shows the phase relationship in the vertical synchronization section, and FIG. 5 shows the phase relationship in the horizontal synchronization section in an enlarged manner.

The synchronization signal generation circuit 131 receives one signal once per frame of two images.
Inputting the vertical synchronization position signal X, which is a line width positive pulse, the horizontal synchronization position signal Y, which outputs a negative pulse for each line, and the sampling signal Z, the vertical synchronization and horizontal synchronization are combined,
composite image signal H.

Outputs the Karami burst position signal ■. The color burst signal generation circuit 132 internally generates a continuous wave of the color synchronization signal from the sampling clock 2 in response to the input of the sampling clock 2 and the color burst position signal, and only the positive section of the color burst position signal is generated. By outputting a color synchronization signal, a color burst signal J is output. The band p-wave generator 133 removes out-of-band components of the color burst signal J and outputs a regular color burst signal K. Synthesis circuit 13
4.135, the color burst signal and the decoded synchronization signal H are combined, and the reference signal G of the image phase-synchronized with the decoded analog image signal A is output.

That is, according to the embodiment of the present invention, two
A/l) converter 3. converts the analog image signals a, b output from the TV camera into digital image signals c, d, respectively; Ay/D converter 4 and A/l) converter 3yA/
1) An image multiplexing circuit 5 that multiplexes the signal of a predetermined portion of the digital image output of the converter 4 onto a predetermined line within one frame of the image signal and outputs a multiplexed image signal e, and two-image multiplexing. a transmitter 6 that performs high-efficiency compression encoding f on the output of the encoding circuit 5 by predictive encoding f or transform encoding; and a transmitter 6 that decodes the highly efficient compression-encoded digital signal F transmitted from the transmitter. A decoder 26 inputs the multiplexed image signal E outputted from the decoder 26 and generates a vertical synchronization position signal R2, a horizontal synchronization position signal S, and a sampling clock T, and inputs the multiplexed image signal E output from the decoder 26 and generates a two-image signal E. An image separation circuit 2 that separates and interpolates from a predetermined line within one frame and outputs two digital image signals C and D.
5 and a D/A converter 23 and a D/A converter 24 that convert the two digital image signal outputs of the image separation circuit 25 into analog image signals A and B, respectively. In the device, the vertical synchronization position signal R2 generated by the decoder 26, the horizontal synchronization position signal S, and the sampling clock T are input, and the reference signal of the image phase-synchronized with the analog image signal outputs a and b of the receiving section is input. A two-image encoding device is obtained, characterized in that it has an image synchronization signal generator that outputs a generation 1ock signal of a television camera.

[Effects of the Invention] As explained above, the present invention outputs the vertical synchronization position signal, the horizontal synchronization position signal reproduced by the decoder, and the reference signal of the image synchronized with the sampling clock to a television camera, etc. 2. For example, during a video conference between three points, an image signal synchronized with the received image signal can be input to the transmitter of the image encoding device by phase synchronizing the output of a television camera or the like.

The signal transmitted from point A is decoded at eight points, and then decoded at eight points.
This has the advantage that the image signal at the point and the decoded image signal at the point A can be transmitted to the point C using one image encoding device.

[Brief explanation of drawings]

Ru. 1.2: Analog image signal input terminal, 3, 4: 1st
and a second converter, 5: image multiplexing circuit. 6: Encoder, 7: P digital signal output terminal. 11: Internal synchronization signal generator, 12: Switching device, 13: Image synchronization signal generator, 14, 15 blank burst signal output terminal, 21.22: Analog image signal output terminal, 23
, 24: third and fourth D/A converters, 25: image separation circuit, 26: decoder. 27: Digital signal input terminal r az b r A
rB: analog image signal; c, d, C, D: digital image signal + e l E: multiplexed 1-combined image signal. f, F: transmission path digital signal, U, R: vertical synchronization position signal, V, S: horizontal synchronization position signal, W, T: sampling clock, 131: synchronization signal generator path. 132: Color burst signal generation circuit, 133: Band P
wave device, 134, 135: synthesis circuit, H: decoding synchronization signal,
I: color burst position signal, J: color burst signal, N: color burst signal with p-band wave. Figure 4X Figure 5

Claims (1)

[Claims] 1. A transmitter that receives an analog image signal phase-synchronized with a reference signal, converts it into a digital image signal, multiplexes it, encodes it with high efficiency compression, and outputs it, and a vertical synchronization position signal from the digital image signal received from the outside. , a receiver comprising decoding means for reproducing the horizontal synchronization position signal and the sample clock, and image synchronization signal generation means for generating a phase synchronization reference signal synchronized with the vertical synchronization position signal, the horizontal synchronization position signal, and the sample clock; An image encoding device characterized in that the image encoding device comprises: the phase synchronization reference signal from the receiving section is used as the reference signal in the transmitting section.