JP3637823B2 - Video signal switching device and video signal switching method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a video signal switching device and a video signal switching method thereof, and more particularly, to a method of switching a television video signal for compressing a video signal by MPEG1 (Moving Picture Experts Group phase 1) or MPEG2 (Moving Picture Experts Group phase 2) system. .
[0002]
[Prior art]
With the recent development of digital technology, the amount of information can be greatly compressed by information compression technology using digital processing. In communication media, image communication over a narrow-band communication path such as 3 kbps, which has been impossible in the past, is possible, and multimedia communication such as images is possible with a communication charge as low as a telephone.
[0003]
In the storage medium, image data for one hour can be stored in an inexpensive storage medium of about 1 Gbyte, and the storage space of the storage device can be reduced. Broadcast media can perform high-quality transmission without deterioration, and can be multi-channeled.
[0004]
The following three techniques are combined in the image signal information compression technique. In the first technique, the values between adjacent pixels in a natural image are close to each other (high correlation). Therefore, orthogonality called DCT (Discrete Cosine Transform) using in-screen (spatial) correlation is used. Information compression is performed by performing conversion processing and removing high-frequency terms.
[0005]
In the second technique, the screen is created as if the video is continuous by displaying screens that are slightly different one after another, so that the screens before and after are very similar (temporal) Use the correlation to store the information on the previous screen, compare the current screen with the previous screen, and keep only the information that there is no change in the non-moving part, and the moving part is the same picture in the whole screen The information compression using the inter-screen (temporal) correlation is performed by finding the information by the amount of information corresponding to the movement amount (motion vector) of the portion.
[0006]
In the third technique, when these compressed signals are encoded, there is a bias in the probability of occurrence in the above-described DCT-transformed information values, and the motion vector has a similar bias tendency, The average amount of information is reduced by assigning a short code length to a value with a high probability of occurrence and assigning a long code length to a value with a low probability of occurrence.
[0007]
In the second technique, the comparison result between the information on the previous screen and the information on the current screen is used as original information for compression. When the information is decoded, it cannot be decoded only with the comparison result information. Requires comparison information with the screen.
[0008]
If it is assumed that the beginning of the composition of the compressed screen is the beginning of a broadcast program or the first scene of a movie story, it is impossible to combine information from the middle, and it must be traced back to the beginning of the broadcast program or the beginning of the story. Don't be. Therefore, if the channel adjustment is in the middle of a broadcast program, it becomes impossible to reproduce from the middle of a video tape or disk story.
[0009]
In order to solve this, in the MPEG1 or MPEG2 system, compression processing is performed in units of GOPs (Group of Pictures) in which several pieces of screen data are grouped. At least one I picture is required in one GOP, and the I picture is a screen encoded only from I picture information in order to maintain the independence of the GOP. Generated without using predictions based on
[0010]
In addition, in the MPEG1 or MPEG2 system, a P picture and a B picture are defined, and the P picture is image information obtained by predictive coding in the interframe forward direction (future time direction) based on the I picture. The B picture is image information obtained by predictive coding in both directions (both future time and past time) on an image inserted between an I picture and a P picture.
[0011]
An example of a 1 GOP structure is shown in FIG. In FIG. 3, A1 to A15 in the upper stage indicate the original screen before encoding, and one sheet corresponds to one frame of the screen. The information obtained by encoding this screen is the middle stage information. I1 is the only I picture in this GOP. P1 to P4 indicate P pictures, and B1 to B10 indicate B pictures.
[0012]
In this example, the number of pictures of 1 GOP N = 15 and the period M = 3 of I and P pictures are taken as an example. It shows that the information encoded within the frame (on a single screen, not related to the previous and subsequent screens) of the A3 screen before encoding is the I picture indicated by I1.
[0013]
In encoding the original screen of A6, this is predictively encoded in the interframe forward direction (future time direction) based on the picture information of I1, and information of the P picture shown in P1 is obtained. The A9 original screen is predicted in the forward direction between frames based on P1, and P2 is obtained. Also for the original screen of A12, P3 is obtained based on P2 as described above. Also for the original screen of A15, P4 is obtained based on P3 in the same manner as described above.
[0014]
The original picture of A1 is predictively encoded in the reverse direction between frames (past time direction) based on the I picture of I1, and information of the B picture shown in B1 is obtained. The original screen of A2 is also predicted in the reverse direction between frames based on the I picture of I1, and B2 is obtained.
[0015]
The A4 original screen is predicted in both directions (both past time direction and future time direction) based on both the I picture of I1 and the P picture of P1, and the B picture shown in B3 is obtained. The A5 original screen is predicted in both directions (both past time direction and future time direction) based on both the I picture of I1 and the P picture of P1, and the B picture shown in B4 is obtained.
[0016]
The B picture of B5 for the original picture of A7 and the B picture of B6 for the original picture of A8 are bi-directionally predictive-coded based on both the P picture of P1 and the P picture of P2, respectively, to obtain information. Similarly to the above, B7 for the original screen of A10 and B8 for the original screen of A11 are bi-directional predictively encoded based on both the P picture of P2 and the P picture of P3 to obtain information. Also, B9 for A13 and B10 for A14 obtain information by the same encoding process.
[0017]
The lower part of FIG. 3 shows the order of the encoding process. The B picture prediction process is an insertion screen process, and the process is started after the future screen is stored, and thus is a post process. For this reason, the processing order of the screen and the order of the original screen are different.
[0018]
Therefore, the order on the storage medium and the transmission medium is defined to be the order according to the order after the encoding process. This compressed signal is called a TS (Transport Stream) signal.
[0019]
Although the number of image signals per 1 GOP unit is not defined as a standard, there is an appropriate condition for a practical encoder, and a value corresponding to 0.4 seconds (12 screens) to several seconds is used. For broadcasting, 0.5 seconds (15 screens), which is closer to the break of the time function, is generally used frequently.
[0020]
The structure of the encoded data is shown in FIG. The encoded data is a group of the above GOP data, a sequence header for identifying each GOP data is added to the head, and a series of continuous images (screen # 1 data to screen #N data) are assembled one after another.
[0021]
An example of a system in the case of switching the encoded data signal is shown in FIG. S1 and S2 are encoding data to be input, and are switched by the encoding switch (SW) 13. In this example, the encoding switch 13 is tilted to the encoding data S1 side, and the encoding data S1 is output.
[0022]
In this figure, the output encoded data S3 is connected to the MPEG decoder 6 so that the encoded data output from the MPEG decoder 6 can be confirmed on the monitor 7 as an image. In FIG. 5, 10-1 and 10-2 indicate cameras, 11 and 12 indicate encoders, and V1 and V2 indicate video signals.
[0023]
FIG. 6 is a diagram showing the timing of the encoded signal when the encoded data shown in FIG. 5 is switched. S1 indicates the signal timing of the encoded data S1, and s2 indicates the encoded data. The signal timing of S2 is shown, and s3 shows the signal timing of the encoded data S3 output after switching.
[0024]
In the example shown in FIG. 6, the encoded data S1 and the encoded data S2 are not synchronized with each other. In this example, switching is performed at the timing of T3, and an example of switching from timing in the middle of s1 GOP data # 1 to timing in the middle of s2 GOP data # 3 is shown.
[0025]
Since the GOP data is switched in the middle of the MPEG decoder 6, it is impossible to process a series of continuous signals. In the encoded data 3 output from the MPEG decoder 6, the GOP data # The image from the timing T3 of 1 is not reproduced and enters a frozen state (stiffens and stops moving).
[0026]
The reproduction process can be resumed by reproducing the encoded signal by the GOP data # 4 from the timing of T4, and a moving image can be confirmed. The decoder output screen during the period from the timing of T3 to the timing of T4 is in a freeze state, the screen switching does not become smooth, and the appearance of a still image is in the middle of switching as shown in FIG. The image is the screen inserted.
[0027]
The transfer rate of the GOP data changes depending on the state of the input image signal. The content of the TS signal is actually a clock in which only a valid image signal is placed on a fixed clock for transmitting the TS signal, dummy data is placed on the remaining clock portion, and the TS signal is input. The signal reproduction and decoding processes are average loads, and the processes are performed stably.
[0028]
When the effective coding data rate is increased so that it exceeds the clock of the TS signal, it becomes impossible to put all of the effective data, the data overflows, and the signal format In general, the clock signal is set to a sufficiently high rate.
[0029]
Therefore, there is usually dummy data. Since the encoding apparatus performs encoding processing in units of GOPs, although there are dummy data in the GOP data, in general, there are many dummy data between the GOP data and the next GOP data. -Data is present.
[0030]
By utilizing this fact, a synchronization signal indicating a GOP data delimiter is supplied to an encoder to be encoded, and the encoder encoders 11 and 12 delimit the encoding process based on the GOP synchronization signal. Thus, the dummy data can be biased behind the GOP data. Since the dummy data is ignored in the decoding process, when switching between the dummy data, the shock of the TS signal at the switching point can be ignored on the MPEG decoder 6 side.
[0031]
FIG. 8 shows a system for preventing the above-mentioned unnatural screen. The encoder encoders 3 and 4 are supplied with a GOP synchronization signal to synchronize the output TS signal.
[0032]
On the other hand, by supplying the GOP synchronization signal to the synchronization switch 14 which is a switch of the encoded signal as well as the encoders 3 and 4, the GOP synchronization signal is used as a reference in FIG. As shown, both the S1 signal and the S2 signal are switched at timing T5 in accordance with a period in which the GOP data # 1 and # 3 and the next GOP data # 2 and # 4 are output.
[0033]
In this way, by performing encoding and switching synchronization based on the GOP synchronization signal, the TS signal can be switched without causing any disturbance. The screen output from the MPEG decoder 6 to the monitor 7 is not an unnatural screen as shown in FIG.
[0034]
FIG. 11 shows a system in the case where the video signal switching and the TS signal switching are performed. In this example, for example, the encoding device encoder 3 is for an SDTV (conventional standard television with 525 scanning lines) program, and the encoding device encoder 4 is an HDTV (high 1 scanning line 1 1). The signal format handled by encoding is very different as in the case of a program for fine television) and cannot be handled in one device, so it is configured with separate devices and the TS signal is switched. The case is shown.
[0035]
Reference numeral 1-1 denotes a camera, which is an example of a video material. Reference numerals 1-2, 1-3, and 1-4 denote cameras similar to those described above. The output video signals are the video signal V1 corresponding to the camera 1-1, the video signal V2 corresponding to the camera 1-2, and the camera 1. -3 and the video signal V4 corresponding to the camera 1-4. The contents of these video signals are different. In this example, a camera is taken as an example of a video signal material, but if a video signal such as a VTR (video tape recorder) is output, it is not specified.
[0036]
Reference numeral 15 denotes a video signal changeover switch (SW). In this example, the switch 15a of the changeover switch 15 switches between the video signals V1 and V2 and outputs the video signal V21. Further, the switch 15b of the changeover switch 15 indicates that the video signals V3 and V4 are switched and the video signal V22 is output.
[0037]
The encoding device encoder 3 is a device for encoding the video signal V21 and outputs the encoded TS signal S1. Similarly, the encoding device encoder 4 is a device for encoding the video signal V22 and outputs the encoded TS signal S2.
[0038]
The synchronization switch 16 is a switch for switching the TS signals S1 and S2, and supplies the GOP synchronization signal as described above, and the TS signal S1 of the encoder encoder 3 and the TS signal S2 of the encoder encoder 4 are supplied. Are switched in a dummy data output period between GOPs, and encoded data S3 is output.
[0039]
In this example, an MPEG decoder 6 is connected to confirm this output signal, and a monitor 7 is connected to the output of the MPEG decoder 6 so that the video can be confirmed on the monitor 7.
[0040]
A video synchronization signal is supplied to the cameras 1-1 to 1-4, and a video signal is output based on the synchronization signal. Therefore, the phases of the video signals output from these cameras 1-1 to 1-4 are the same. The video synchronization signal is also supplied to the switches 15a and 15b of the video signal changeover switch 15. When switching is performed, the video is switched within the vertical blanking period of the video signal based on the video synchronization signal.
[0041]
By doing this, the switching point of the video signal will be switched in the middle of the return from the bottom of the screen to the top, and the switching point is not in the screen, so you can feel the switching point It is possible to switch without any change.
[0042]
FIG. 12 is a timing chart showing switching between the switched video signal and the encoded signal and the video screen of the decoded video signal. The video signal is switched at the timing of T6, and is switched in the vertical blanking period of the video with reference to the video synchronization signal. The signal of the output line V21 is v1, and similarly the signal of the output line V22 is v2.
[0043]
These switched video signals are encoded by the encoders 3 and 4 and switched at the timing of T7 by the synchronization switch 16 to which the GOP synchronization signal is supplied. When the switched TS signal is decoded, as shown in the lower part of FIG. 12, the timing of the video signal divided by the GOP unit and the video signal switched by the video signal changeover switch 15 do not match. Switching from the video signal to the V4 video signal is not smooth, and the V2 video signal is inserted in the middle, resulting in an unnatural image signal.
[0044]
[Problems to be solved by the invention]
In the switching method in which the television video signal described above is switched, the output is compressed by the encoding device, and the compressed signal is switched and transmitted, the video signal switching point and the GOP unit break point do not match. Therefore, there is a problem that the switching point of the video signal is in the middle of the compressed GOP unit, and the switching point of the video signal is visible when decoding.
[0045]
Therefore, an object of the present invention is to eliminate the above-mentioned problems, and when switching between a video signal and a compressed signal, a video signal switching device capable of switching to a video signal and making it invisible when decoded. And a video signal switching method thereof.
[0046]
[Means for Solving the Problems]
A video signal switching device according to the present invention switches a plurality of television video signals output based on a video synchronization signal for switching video within a vertical blanking period of the video signal to one output, and compresses the video signal. Input to a plurality of compression encoding devices that perform compression encoding in units of GOP (Group of Pictures) indicating a group of video signal frames corresponding to one unit of encoding, and each of the plurality of compression encoding devices A video signal switching device for switching the output of each of the plurality of compression encoding devices in response to a synchronization signal for adjusting to the GOP data delimiter when switching the output, wherein the synchronization signal the video and logic operation means for taking a logical product of the synchronizing signal, the operation result of and the logic operation means provided corresponding to said plurality of compression encoding apparatus, each said the And a plurality of switching means for outputting the timing indicating a match between the period signal and the video synchronization signal to the compression encoding device to the corresponding switching the video signal.
[0047]
According to the video signal switching method of the present invention, a plurality of television video signals output based on a video synchronization signal for switching video within a vertical blanking period of the video signal are switched to one output, and the video signal is compressed. Input to a plurality of compression encoding devices that perform compression encoding in units of GOP (Group of Pictures) indicating a group of video signal frames corresponding to one unit of encoding, and each of the plurality of compression encoding devices A video signal switching method for switching the output of each of the plurality of compression encoding devices in response to a synchronization signal for matching the GOP data delimiter when the output is switched for transmission, wherein the synchronization signal the ANDs the video sync signal, the a plurality of switching means provided corresponding to said plurality of compression encoding device each logical product operation result before and At a timing indicating a match of the synchronous signal and the video sync signal by switching the video signal and outputs the corresponding compression encoding device.
[0048]
That is, the video signal switching method of the present invention uses the GOP synchronization signal to make an image segmented by the GOP unit that generates the compressed signal as the image unit to be switched, and further uses the video synchronization signal as a reference when switching the video signal. By means of switching in the video vertical blanking period, the GOP data break coincides with the switching of the video signal, so that the video signal is switched to be invisible when decoded.
[0049]
DETAILED DESCRIPTION OF THE INVENTION
Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a video signal switching device according to an embodiment of the present invention. In FIG. 1, a video signal switching device according to an embodiment of the present invention includes cameras 1-1 to 1-4, a video signal switching switch (SW) 2, encoders 3 and 4, and a synchronous switch 5. , An MPEG decoder 6, a monitor 7, a delay circuit 8, and an AND gate 9.
[0050]
Video signals output from the cameras 1-1 to 1-4 include a video signal V1 corresponding to the camera 1-1, a video signal V2 corresponding to the camera 1-2, a video signal V3 corresponding to the camera 1-3, and a camera. It consists of a video signal V4 corresponding to 1-4. The contents of the video signal are different. In this example, the cameras 1-1 to 1-4 are taken as examples of the video signal material, but the video signal such as a VTR is not specified as long as the video signal is output.
[0051]
The change-over switch 2 includes switches 21 and 22, the switch 21 switches the video signals V1 and V2 and outputs the video signal V21, and the switch 22 switches the video signals V3 and V4 and outputs the video signal V22.
[0052]
The encoding device encoder 3 is a device for encoding the video signal V21 and outputs the encoded TS signal S1. Similarly, the encoding device encoder 4 is a device for encoding the video signal V22 and outputs the encoded TS signal S2.
[0053]
The synchronous switch 5 is a switch for switching between the TS signals S1 and S2, and switches between the TS signal S1 output from the encoder encoder 3 and the TS signal S2 output from the encoder encoder 4 for encoding. Data S3 is output. The encoded data S3 output from the synchronous switch 5 is transmitted as an encoded output signal for broadcasting.
[0054]
In this example, in order to confirm the output signal, the MPEG decoder 6 is connected to the synchronization switch 5, the monitor 7 is connected to the output of the MPEG decoder 6, and the video can be confirmed on the monitor 7. I am doing so.
[0055]
The delay circuit 8 delays the GOP synchronization signal supplied to the synchronization switch 5 by a predetermined time and outputs it to the synchronization switch 5. The AND circuit 9 takes the AND of the GOP synchronization signal and the video synchronization signal and outputs the result to the changeover switch 2.
[0056]
FIG. 2 is a timing chart showing the operation of the video signal switching device according to the embodiment of the present invention. The operation of the video signal switching apparatus according to the embodiment of the present invention will be described with reference to FIGS.
[0057]
The video synchronization signals shown in FIG. 2 are supplied to the cameras 1-1 to 1-4, and video signals V1 to V4 are output based on the video synchronization signals. Therefore, the phases output from these cameras 1-1 to 1-4 are the same.
[0058]
The video synchronization signal is also supplied to the switches 21 and 22 of the changeover switch 2, and when switching is performed, the video is switched within the vertical blanking period of the video signal based on the video synchronization signal.
[0059]
By doing this, the switching point of the video signal is switched in the middle of the vertical blanking from the bottom to the top of the screen, so that the switching point is not in the screen, so you can feel the switching point It is possible to switch without any change.
[0060]
However, the switching timing is usually 0.017 second interval finer than the GOP unit of 0.5 second interval, and the GOP synchronization signal is supplied to the changeover switch 2 in order to match the GOP unit. After being ANDed with the video synchronization signal by the circuit 9, it is supplied to the changeover switch 2. That is, the changeover switch 2 switches the video signal with an AND condition between the GOP synchronization signal and the video synchronization signal.
[0061]
The GOP synchronization signal needs to have an accuracy with which the frame of an image to be processed can be clearly defined in the encoding process. The encoding device encoders 3 and 4 are supplied with a GOP synchronization signal, and the video encoding processing is divided and processed based on the GOP synchronization signal. In this example, the timing of T2 is processed as an encoding break.
[0062]
The TS signals S1 and S2 output from the encoder encoders 3 and 4 have the structure shown in the lower part of FIG. 2, and a sequence header and dummy data are inserted with the GOP data interposed therebetween.
[0063]
A GOP synchronization signal is supplied to the synchronization switch 5. This GOP synchronization signal is delayed by a delay circuit 8 for a predetermined time. Therefore, the synchronization switch 5 switches the encoded data at the dummy data portion. In the synchronous switch 5, as described in the prior art, since the switching shock on the TS signal is stored in the dummy data, the screen in the MPEG decoder 6 is frozen. There is no shock.
[0064]
As described above, when the video signal and the encoded signal are switched, the video signal is also switched in units of GOP which is the unit of encoding, so that the unnatural appearance caused by the difference between the video signal switching and the GOP unit during decoding. An image signal is not output. Therefore, when the video signal and the compressed signal are switched, the video signal can be switched to be invisible when decoded.
[0065]
【The invention's effect】
As described above, according to the present invention, a plurality of television video signals are switched to one output, and the video signal is input to a compression coding device that performs compression coding, and the output of the compression coding device is switched for transmission. In the video signal switching device, a logical operation is performed between a segment of a video signal frame corresponding to one unit of compression encoding and a vertical blanking period of the video signal, and the video is processed at a timing satisfying the calculation result. By switching the signal, there is an effect that when the video signal and the compressed signal are switched, the video signal is switched to be invisible when decoded.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a video signal switching device according to an embodiment of the present invention.
FIG. 2 is a timing chart showing the operation of the video signal switching device according to the embodiment of the present invention.
FIG. 3 is a diagram illustrating an example of a 1 GOP structure.
FIG. 4 is a diagram illustrating a structure example of encoded data.
FIG. 5 is a block diagram showing a system for switching encoded data.
6 is a timing chart showing the switching timing when the encoded data shown in FIG. 5 is switched. FIG.
FIG. 7 is a diagram illustrating an example of a video screen obtained by decoding data after switching.
FIG. 8 is a block diagram showing a system in a case where encoded data is switched based on a GOP synchronization signal.
FIG. 9 is a timing chart showing the switching timing when the encoded data is switched based on the GOP synchronization signal.
FIG. 10 is a diagram illustrating an example of a video screen obtained by decoding data after synchronous switching.
FIG. 11 is a block diagram showing a system in the case of switching encoded data and switching video signals.
FIG. 12 is a diagram illustrating a switching timing and a video screen example when switching between encoded data and a video signal is performed.
[Explanation of symbols]
1-1 to 1-4 Camera 2 Video signal selector switches 3 and 4 Encoder encoder 5 Synchronous switch 6 MPEG decoder 7 Monitor 8 Delay circuit 9 AND gates 21 and 22 switches

Claims (6)

A plurality of television video signals output based on a video synchronization signal for switching video within a vertical blanking period of the video signal are switched to one output, and the video signal is a video corresponding to one unit of compression coding. When inputting to a plurality of compression encoding devices that perform compression encoding in units of GOP (Group of Pictures) indicating a group of signal frames, and switching and transmitting the output of each of the plurality of compression encoding devices, A video signal switching device that switches the output of each of the plurality of compression encoding devices in response to a synchronization signal for matching a GOP data delimiter, the logical product of the synchronization signal and the video synchronization signal And a logical operation means that is provided corresponding to each of the plurality of compression encoding devices, and the operation result of the logical operation means matches the synchronization signal and the video synchronization signal. Video signal switching apparatus, comprising a plurality of switching means for outputting switching the video signal at a timing indicated by the corresponding compression encoding device. A delay unit that delays the synchronization signal for a predetermined time, and outputs the output of the compression encoding device in dummy data between the GOP data and the next GOP data based on the synchronization signal delayed by the delay unit. The video signal switching device according to claim 1 , wherein the video signal switching device is configured to be switched for transmission. The video signal, MPEG1 (Moving Picture Experts Group phase 1) system and MPEG2 (Moving Picture Experts Group phase 2 ) according to claim 1 or claim, characterized in that it has to be one compressed coded using method 2. The video signal switching device according to 2. A plurality of television video signals output based on a video synchronization signal for switching video within a vertical blanking period of the video signal are switched to one output, and the video signal is a video corresponding to one unit of compression coding. When inputting to a plurality of compression encoding devices that perform compression encoding in units of GOP (Group of Pictures) indicating a group of signal frames, and switching and transmitting the output of each of the plurality of compression encoding devices, A video signal switching method for switching an output of each of the plurality of compression encoding devices in response to a synchronization signal for adjusting to a GOP data delimiter, wherein a logical product of the synchronization signal and the video synchronization signal In the plurality of switching means provided corresponding to each of the plurality of compression encoding devices, the operation result of the logical product is one of the synchronization signal and the video synchronization signal. Video signal switching method and outputting switches the video signal to a corresponding compression encoding device at a timing indicated a. The synchronization signal is delayed for a predetermined time, and based on the delayed synchronization signal, the output of the compression encoder is switched and transmitted in dummy data between the GOP data and the next GOP data . 5. A video signal switching method according to claim 4, wherein: The video signal, MPEG1 (Moving Picture Experts Group phase 1) system and MPEG2 (Moving Picture Experts Group phase 2 ) according to claim 4 or claim, characterized in that it has to be one compressed coded using method 5. The video signal switching method according to 5 .

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