JP2003309594A - Video information transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To transmit video information requiring a high transmission range by using a plurality of transmission paths having limited transmission capacity such as a mobile telephone. <P>SOLUTION: The video information coded in a transmission terminal is divided for a plurality of transmission terminals, the divided data are transmitted by using the plurality of transmission terminals. On this occasion, the most important data are transmitted through the plurality of transmission paths and less important data are discarded if the transmission range is in short, depending on priority of the coded video information. On a receiver side, the data are re-constructed and decoded from the divided data into the original video information, thereby increasing transmission capacity in proportion to the number of transmission terminals and enabling stable transmission of the video information without imposing a load such as error correction processing on the carriers of the transmission paths themselves. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission system for transmitting digitized and encoded video information via a plurality of transmission paths.

[0002]

2. Description of the Related Art With the development of modulation systems and coding systems, it has become possible to transmit video information via a wireless transmission path, and various services have started. As a transmission terminal using wireless, mobile phones and PHS (P
personal Handyphone System)
In the above, the transmission capacity is limited due to restrictions such as the usable bandwidth and the number of people in the area, and the video information that can be transmitted by these transmission terminals is a still image that does not require a large amount of information. The quality of a moving image is generally inferior to that of a conventional TV. In order to improve the image quality, it is necessary to increase the transmission capacity of the transmission path together with the improvement of the encoding method. As an example of increasing the transmission capacity without changing the modulation method, for example, Japanese Patent Application No. 10-56479 can be cited. it can. In this example, a plurality of transmission terminals, that is, mobile phones and PHSs are connected to the information transmission device. Transmission data is divided in a transmission device, the divided data is transmitted using a plurality of transmission devices at the same time, and the data is transmitted to a single receiving terminal. The receiving terminal increases the transmission capacity in proportion to the number of transmission terminals used by combining the received data transmitted through the respective transmission paths and restoring the original data.

Further, when transmitting video information, a method has been devised in which the data is divided according to the degree of importance, and the processing is performed so that the important data can be surely transmitted. For example, in Japanese Patent Application No. 3-124927, image information is hierarchically divided and transmitted in order from an important part, and an important part is increased in error correction capability by increasing a transmission parity addition amount in a transmission device. It improves and realizes reliable and prompt transmission.

[0004]

However, the first known example does not take into consideration the case where the transmission line is unstable. In practice, the wireless transmission path is often unstable, especially during mobile communications, and if there is an error in the transmission data of one of the multiple transmission paths used, or if the transmission path itself is disconnected, the reception It becomes impossible for the side to restore the correct data. Therefore, when the video information is transmitted, there arises a problem that an error occurs in the reproduced video on the receiving side or the video itself cannot be reproduced.

Further, the above-mentioned second known example corresponds to a transmission line with low stability by controlling the amount of addition of parity. However, since the parity added by the transmitter is switched according to the data importance, the receiving side also needs to switch the error correction process according to the process on the transmitting side. However, in general, the error correction processing is provided by a transmission line carrier such as a mobile phone, and in order to carry out the second known example, the transmission line carrier corresponds to the above-described error correction processing switching. Need to be Therefore, there is a problem that the load on the transmission line carrier increases in order to handle a plurality of error correction processes and their switching.

Further, when a plurality of transmission terminals are used and the transmission line carriers are different as in the first known example, not all transmission line carriers perform the same error correction processing. Then, it becomes impossible to perform data transmission using a plurality of transmission line carriers.

The present invention was devised in order to solve the above problems, in which video information is divided for a plurality of transmission terminals in a transmission device and the divided data is used by a plurality of transmission terminals. Providing a video information transmission system that can increase transmission capacity and perform stable reception by adopting a division method according to the importance of video information without transmitting the transmission line carrier, without burdening the transmission line carrier. Especially.

[0008]

To achieve the above object, a dividing means for dividing encoded video information into a plurality of data, and a plurality of dividing means connected to the dividing means for transmitting the divided data. A transmission terminal, a plurality or a single base station that receives signals from the plurality of transmission terminals, a circuit network to which the plurality or base stations are connected, and a plurality of circuits connected to the circuit network Exchange receiving means for receiving the divided data, reconstructing means for obtaining the divided data from the exchange receiving means and reconstructing the original video information, and decoding means for decoding the reconstructed video information, Composed of and. Further, the dividing means divides or duplicates the encoded video information so that the most important data and the next most important data can be transmitted through a plurality of transmission paths according to the importance of the encoded video information, Supply to the plurality of transmission terminals. At this time, the number of transmission paths in the previous period is divided and duplicated so that the number of transmission paths transmitting the most important data is larger than the number of transmission paths transmitting the next most important data. The low data is divided by the first division means so as to be transmitted through a single transmission path, and the divided data is supplied to the transmission terminal.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to FIG. In FIG. 1, 10 is an encoding unit that encodes the digitized video information, 11 is a dividing unit that divides the encoded video information into a plurality of data, and 121 to 123 are the divided data that are transmitted. , 131-132 are base stations for receiving the data transmitted from 121-123, 141-143
Is a line network of a transmission line carrier connected to the base station, 15 is a public line network, 16 is an exchange receiving means for receiving the divided data from the public line network 15 using a plurality of lines, and 17 is the exchange reception. Reconstructing means for obtaining the divided data from the means and reconstructing the original video information, 18
Is a decoding means for decoding the reconstructed video information, and 19 is a display means for displaying the decoded video.

First, the digitized video information is encoded by the encoding means 10 and the amount of information is compressed. As an encoding method, for example, MPEG (Motion P)
image Experts Group) 1 and MPE
G2 is widely used as a general method. The encoded video information is divided into a plurality of data by the dividing means 11. The dividing means 11 includes a plurality of transmission terminals 121.
~ 123 are connected. An existing mobile communication device such as a mobile phone or PHS can be used as the transmission terminal. Further, the number of connections of the transmission terminals can be set to an arbitrary number, and the connection method may be wired or wireless.

The transmission capacity of each of the transmission terminals 121 to 123 is lower than the transmission capacity of the video information coded by the coding means 10, but a value obtained by adding the transmission capacities of 121 to 123 is the coded video information. It shall be equal to or larger than the transmission capacity. Therefore, the dividing means 11 has the transmission terminals 121 to 121.
The encoded video information is divided according to the transmission capacity of each 123, and is supplied to each of the transmission terminals 121 to 123. Details of the dividing method will be described with reference to FIG.

In FIG. 2, 20 is encoded video information, 21 to 23 are divided data, and 201 to 2013.
Is a video packet of encoded video information, 211-21
4 is a video packet assigned to the divided data 21, 22
Reference numerals 1 to 227 are video packets assigned to the divided data 22, and reference numerals 231 to 237 are video packets assigned to the divided data 23. The divided data 21 to 23 are assigned to the transmission terminals 121 to 123 in FIG. 1, respectively. The length of the vertical axis of the coded video information 20 and each of the divided data 21 to 23 indicates the transmission capacity, and the divided data 21 indicates the transmission path with high reliability of the transmission path but low transmission capacity, divided data 2
2 and 23 indicate low reliability and high transmission capacity transmission. The total transmission capacity of the divided data 21, 22 and 23 is equal to the transmission capacity of the encoded video information 20.

In video information coding in MPEG1 and MPEG2, coding processing is performed in frame units. Depending on the processing method, intra-frame coded video (I picture), forward predictive coded video (P picture) )
And bi-directionally predicted video (B picture). Since the I picture uses only the information in the frame at the time of encoding, it can be decoded only by the information of the I picture. On the other hand, P picture is I picture or P picture.
Since the forward prediction is performed from the picture and the coding is performed, the information of the I picture or the P picture already decoded at the time of decoding is required. Further, since a B picture uses bidirectional prediction temporally at the time of encoding, an already decoded I picture or P picture that is temporally positioned at the time of decoding and an I picture or P picture that is temporally positioned later is also decoded. Both sides need information.

As described above, the amount of information required for decoding differs for each picture. If there is I-picture data, the frame can be decoded, and I-picture information is required for P-picture decoding. Further, decoding of B picture requires I picture and P picture information. Therefore, the I picture data is the most important in terms of the importance of the data at the time of decoding, and subsequently, the P picture and the B picture are the least important. In the present invention, the most important I picture data and the next most important P picture data are transmitted through the plurality of transmission paths 21 to 23, and the B picture having the lowest importance is transmitted through a single transmission path. Further, the number of transmission paths for transmitting I picture data is set to be larger than the number of transmission paths for P picture data so that the transmission can be performed more reliably.

In the coded video information 20 of FIG. 2, I picture data is 201 and P picture data is 205, 20.
9 and 2113, the remaining 202-204, 20
Reference numerals 6 to 209 and 2010 to 21012 denote B picture data. Although one picture is shown in one video packet for the sake of convenience, one picture may actually be transmitted in a plurality of packets. As explained above, I
Since the picture data is the most important data for decoding, the divided data 21 to 23 are all used for transmission. In FIG. 2, packets 211, 221, and 231 are 201
Is the duplicated data. Further, in this example, the P picture data is transmitted in the divided data 21 and 22,
Packet 205 is duplicated in packets 212 and 223, packet 209 is duplicated in packets 213 and 225, and packet 214 is duplicated in packets 214 and 227. In addition, the B picture packet is packet 202 23
2, 203 to 222, 205 to 233, 206 to 233, 207 to 224, 208 to 235, 20
10 for 236, 2011 for 226, 2012 for 23
7 has been transmitted. Thus, since the I picture data is transmitted through three transmission paths, the P picture is transmitted through two transmission paths, and the B picture is transmitted through one transmission path, the I picture data is most reliably transmitted. Even if an error occurs in the divided data 22 and 23 or the transmission line itself is disconnected by using the low-reliability transmission line, at least the encoded video information 2 can be obtained by using the divided data 21.
The I picture and P picture at 0 can be decoded, and the video, though not perfect, can be displayed on the receiving side.

In the above description, the case where the number of transmission terminals is 3 has been described, but the present invention is not limited to this, and can be easily expanded to the case where the number of transmission terminals is more than 3. In this case, the transmission capacity can be increased in proportion to the number of transmission terminals, and as a result, the image quality of video can be improved. The method for dividing the coded video information is not limited to the method shown in FIG. 2, and can be arbitrarily changed according to the change in the coding method and the transmission capacity. For example, in an encoding method for performing object-based encoding such as MPEG4, main objects of high importance are transmitted through a plurality of transmission paths, and background of low importance is transmitted by a single terminal, which causes instability. Even if a different transmission path is used, it is possible to transmit data of the highest importance.

Here, returning to FIG. 1 again, transmission of divided data will be described. The divided data supplied to the plurality of transmission terminals 121 to 123 is transmitted via the wireless transmission path to the base stations 131 to 131.
133 is transmitted. In FIG. 1, the base station 131
˜133 are different, and in this case, the transmission terminals 121 to 123 are all using different transmission line carriers. In practice, all transmission line carriers do not have to be different, and there is no problem in using a single transmission line carrier. In that case, the base stations 131 to 1
33 is a single base station, and all the transmission terminals 121 to 123 communicate with the base station.

The base stations 131 to 133 are carrier circuit networks 141 to 141 which are the backbones of the respective transmission line carriers.
143, and a carrier network 141
˜143 are connected to the public line network 15. When the transmission path carrier used is single and the base stations 131 to 133 are single, the carrier circuit networks 141 to 143 are also single. Exchange receiving means 16 which is a destination of the divided data is connected to the public line network 15. This exchange receiving means 1
6 has a single number on the public network 15,
Each of the transmission terminals 121 to 123 calls the number, each secures a line, and transmits the divided data. Exchange receiving means 16
The divided data received by is supplied to the reconstructing means 17.

The reconstructing means 17 rearranges the divided data received by the exchange receiving means 16 in a timely correct order, and reconstructs the encoded video information before the division processing by the dividing means 11. Subsequently, the reconstructed video information is decoded by the decoding means 18, and the decoded video information is displayed on the display means 19. Since the coded video information is restored to the original state in the reconstructing unit 17, the decoding unit 18 does not need to be aware of being divided and transmitted on the transmission path, and the normal decoding unit is used as it is. be able to.

As described above, according to the present invention, a plurality of existing transmission terminals such as mobile phones are used, the transmission capacity is increased, and the number of transmission paths to be used is switched according to the importance of video information. Even when a reliable transmission path is used, the image information can be transmitted so that the image cannot be displayed on the receiving side as much as possible.

Further, since it is not necessary for the transmission terminals 121 to 123 and the base stations 131 to 133 to recognize the importance of the data to be transmitted, it is not necessary to switch the error correction processing and the existing transmission line can be used as it is. Therefore, an extra burden is not imposed on the transmission line carrier.

The transmission capacity obtained by adding the transmission capacities of the transmission lines using the plurality of transmission terminals 121 to 123, that is, the transmission capacity obtained by adding 21, 22, and 23 in FIG. 2 is the transmission of the original encoded video information 20. It may be less than the capacity. In this case, all the information cannot be transmitted without delay. In this case, the B picture data of low importance is first appropriately discarded by the dividing means 11 so that the transmission capacity of the coded video information after the data destruction becomes smaller than the transmission capacity of the sum of 21, 22, and 23.
Further, the coded video information after data discard is divided and supplied to the transmission terminals 121 to 123. If the transmission capacity is still insufficient even after discarding the B picture data, a part of the P picture data is discarded by the dividing means 11, the coded video information after the data discard is divided, and the divided video information is supplied to the transmission terminals 121 to 123. To do. The divided data is reconstructed by the reconstructing means 1 as described above.
Although the data that has been transmitted to No. 7 and that can be received by the reconstructing unit 17 is reconstructed, the data having low importance is discarded by the dividing unit 11 and cannot be restored to complete encoded video information. In this case, by decoding only the pictures that can be decoded by the decoding means 18, it becomes possible to display an image of a certain image quality on the display means 19. In this way, by performing the process of discarding the data of low importance in the dividing unit 11, it is possible to reduce the capacity of the transmission information while reducing the influence on the decoded video.

In the above description, the public line network 1
Although the configuration in which the direct exchange receiving means 16 is connected to 5 has been described, the present invention is not necessarily limited to this configuration, and the public line network is connected to another network such as the Internet and the like. A configuration may be adopted in which an exchange receiving means for receiving divided data is connected.

Next, FIG. 3 shows a block diagram of the second embodiment of the present invention. 3 is a partial modification of the configuration of FIG. 1, and the same constituent factors as in FIG. 1 are indicated by the same numbers. Further, 311 to 313 are base stations, and 301 to 303 are transmission terminals.

Similar to the configuration example shown in FIG. 1, first, the digitized video information is encoded by the encoding means 10 and then divided into a plurality of data by the dividing means 11. The dividing means 11 includes a plurality of transmission terminals 121 to 12
3 are connected, and the dividing means 11 includes transmission terminals 121 to 121.
123 The encoded video information is divided according to each transmission capacity and supplied to each transmission terminal. The method of dividing the coded video information by the dividing means 11 is the same as the example shown in FIGS. 1 and 2. The divided data supplied to the plurality of transmission terminals 121 to 123 is transmitted via the wireless transmission path to the base station 131.
To 133, the base stations 131 to 133 are connected to carrier circuit networks 141 to 143 which are the backbones of the respective transmission line carriers. Further base station 301
˜303 transmits the divided data via the carrier line networks 141 to 143 to the transmission terminals 311 to 313.

As in the case of FIG. 1, it is not always necessary for the base stations 131 to 133 to use different transmission carriers, and a single transmission line carrier may be used. In that case, the base stations 131 to 133 are single, and all the transmission terminals 121 to 123 communicate with the base station, and the carrier circuit networks 141 to 143 and the base stations 301 to 303 are inevitably united. Become one.

The transmission terminals 311 to 313 are connected to the reconstructing means 17, and the transmission terminals 121 to 123 call the numbers of the transmission terminals 311 to 313 to secure the line and transmit the divided data. . Transmission terminals 311 to 31
The divided data received by 3 is supplied to the reconstructing means 17. The reconstructing means 17 arranges the divided data in a temporally correct order, and restores the video information before the division by the dividing means 11. Subsequently, the restored video information is supplied to the decoding means 18 to be decoded, and the display means 19 displays the video.

In the second embodiment of the present invention described above, a plurality of transmission lines are secured without using a switching receiving means for securing a plurality of lines, and even if a low-reliability transmission line is used, reception is performed. The video information can be transmitted so that the video cannot be displayed on the side as much as possible.

Next, FIG. 4 shows a block diagram of the third embodiment of the present invention. 4 is a partial modification of the configuration of FIG. 1, and the same constituent factors as in FIG. 1 are indicated by the same numbers. Reference numeral 40 is a reconfiguring unit, 41 is a base station, and 43 is a transmission terminal.

Similar to the configuration example shown in FIG. 1, first, the digitized video information is encoded by the encoding means 10, and then divided by the dividing means 11 into a plurality of data. The dividing means 11 includes a plurality of transmission terminals 121 to 12
3 are connected, and the dividing means 11 includes transmission terminals 121 to 121.
123 The coded video information is divided according to each transmission capacity and supplied to each transmission terminal. The method of dividing the coded video information by the dividing means 11 is the same as the example shown in FIGS. 1 and 2.

The divided data supplied to the plurality of transmission terminals 121 to 123 are transmitted via the wireless transmission path to the base stations 131 to 13.
3 are transmitted to the base stations 131 to 133, and each of the base stations 131 to 133 is a backbone of each transmission line carrier.
To 143. Furthermore, carrier line network 14
1 to 143 are connected to the public line network 15, and an exchange transmitting / receiving means 44 is connected to the public line network 15. The divided data received by the base stations 131 to 133 is transmitted to the exchange transmitting / receiving means 44 via the carrier line networks 141 to 143 and the public line network 15. The exchange transmitting / receiving means 44 has a single number on the public line network, and the transmission terminals 121 to 123 call the number to secure the line and transmit the divided data. The divided data received by the exchange transmitting / receiving unit 44 is supplied to the reconstructing unit 40.

The reconstructing means 40 arranges the divided data in a timely correct order, and reconstructs the video information before division by the dividing means 11. Subsequently, the reconstructed video information is returned to the exchange transmitting / receiving means 44 again. Exchange transmitting / receiving means 4
Reference numeral 4 has a function of securing a single line and transmitting the reconstructed video information, and the reconstructed video information is transmitted to the base station 41 via the public line network 15 and the carrier line network 141.

The reconstructed video information is transmitted from the base station 41 to the transmission terminal 43 via a wireless transmission path. The reconstructed video information received by the transmission terminal 43 is decoded by the decoding means 18 and displayed on the display means 19.

As in the example shown in FIG. 1, it is not always necessary for the base stations 131 to 133 to use different transmission carriers, and there is no problem even if a single transmission line carrier is used. In that case, the base stations 131 to 133 are single, and the base station and all the transmission terminals 121 to 123 communicate with each other.
143 is also single.

In the third embodiment of the present invention described above, by arranging the exchange transmitting / receiving means and the reconfiguring means on the line network, the processing of the receiving terminal can be lightened and the transmission of low reliability is possible. Even when the road is used, the image information can be transmitted so that the image cannot be displayed on the receiving side as much as possible.

[0036]

According to the present invention, the video information coded in the transmission terminal is divided for a plurality of transmission terminals, the divided data is transmitted using the plurality of transmission terminals, and the importance of the video information is determined. Depending on the number of transmission lines used, the transmission capacity can be increased in proportion to the number of transmission terminals, and a low-reliability transmission line can be provided without imposing load such as error correction processing on the transmission line carrier itself. Even when used, it is possible to provide a video information transmission system capable of transmitting video information so that the reception side cannot display the video as much as possible.

[Brief description of drawings]

FIG. 1 is a configuration diagram according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a division process of video information.

FIG. 3 is a configuration diagram according to a second embodiment of the present invention.

FIG. 4 is a configuration diagram according to a third embodiment of the present invention.

[Explanation of symbols]

10 ... Encoding means 11 ... Dividing means 121 to 123 ... Transmission terminal 131-132 ... Base station 141-143 ... Carrier network 15 ... Public network 16 ... Exchange receiving means 17 ... Reconstruction means 18 ... Decoding means 19 ... Display means

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Sadao Tsuruga             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media Development Book             Department (72) Inventor Takanori Eda             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media Development Book             Department (72) Inventor Satoshi Takashimizu             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media Development Book             Department F-term (reference) 5C053 GB21 LA11 LA14                 5K030 GA11 HA08 HB02 HC09 JL01                       LA03 LE14                 5K033 AA01 AA07 BA15 CB06 DA17                 5K034 AA01 AA05 CC02 DD01 EE07                       FF02 HH01 HH02 HH09 HH12                       HH14 HH18 JJ11 LL07 MM01                       MM25

Claims (6)

[Claims] 1. A video information transmission system for transmitting encoded video information, comprising: dividing means for dividing the encoded video information into a plurality of divided data; and the divided data connected to the dividing means. A plurality of transmission terminals for transmitting, a plurality of or a single base station for receiving signals from the plurality of transmission terminals, a network to which the plurality of or a single base station is connected, and a connection to the network An exchange receiving means for receiving the divided data received by the base station using a plurality of lines; a reconstructing means for obtaining the divided data from the exchange receiving means and reconstructing the original video information; Decoding means for decoding the encoded video information, and the data having high importance according to the importance of the encoded video information is transmitted by the dividing means so that the data can be transmitted through a plurality of transmission paths. The encoded video information is divided or duplicated and is transmitted redundantly by using a plurality of transmission terminals, and the less important data is divided by the dividing means so as to be transmitted by a single transmission path. The video information transmission system, wherein the transmission is performed using the transmission terminal. 2. A video information transmission system for transmitting coded video information, comprising: dividing means for dividing the coded video information into a plurality of division data; and the division data connected to the division means. A plurality of transmission terminals for transmission, a plurality of or a single reception base station for receiving signals from the plurality of transmission terminals, a circuit network to which the reception base station is connected, and a circuit network connected to the circuit network A plurality of or a single transmission base station that receives the divided data via the transmission source station to the transmission terminal, a plurality of transmission terminals that receive the divided data transmitted from the transmission base station, from the plurality of transmission terminals Reconstructing means for retrieving the divided data and reconstructing the original video information, and decoding means for decoding the reconstructed video information, depending on the importance of the encoded video information, In the dividing means, the coded video information is divided or duplicated in the dividing means so that it can be transmitted through a plurality of transmission paths, and it is transmitted redundantly by using a plurality of transmission terminals. A video information transmission system, characterized in that the transmission means is divided by the dividing means so as to be transmitted through a single transmission path, and is transmitted using a single transmission terminal. 3. A video information transmission system for transmitting encoded video information, comprising: dividing means for dividing the encoded video information into a plurality of divided data; and the divided data connected to the dividing means. A plurality of transmission terminals for transmission, a plurality of or a single reception base station for receiving signals from the plurality of transmission terminals, a circuit network to which the reception base station is connected, and a circuit network connected to the circuit network An exchange transmitting / receiving unit capable of receiving the divided data via a plurality of lines and transmitting the divided data via a single line, and obtaining the divided data from the exchange receiving unit to reconstruct the original video information to reconstruct video information. To the exchange receiving means again, a transmitting base station for transmitting the reconstructed video information from the reconstructing means to a transmission terminal via a line network, and the division data transmitted from the transmitting base station. And a decoding means for decoding the video information received by the transmission terminal, and the data having high importance according to the importance of the encoded video information is The coded video information is divided or duplicated so that it can be transmitted through multiple transmission routes, and it is transmitted redundantly by using multiple transmission terminals, and data of low importance is transmitted through a single transmission route. As described above, the video information transmission system is characterized in that it is divided by the dividing means and is transmitted using a single transmission terminal. 4. The video information transmission system according to claim 1, wherein the divided coded video information is divided so as to be transmitted using a number of the transmission terminals according to its importance. A video information transmission system, wherein means divides the coded video information. 5. The video information transmission system according to any one of claims 1 to 3, wherein when the transmission capacity transmitted by a plurality of transmission terminals is insufficient, the importance of the divided encoded video information is low. A video information transmission system, wherein the dividing means divides the encoded video information so that the data is discarded and transmitted. 6. The video information transmission system according to any one of claims 1 to 3, wherein when the transmission line of any of a plurality of transmission terminals is disconnected and the divided data cannot be transmitted, the exchange is performed. A video information decoding device, wherein the decoding means performs decoding using only the divided data that can be received by the receiving means.