JP6029805B2 - Distribution apparatus, distribution program, and distribution method - Google Patents

Description

  The present invention relates to a distribution device, a distribution program, and a distribution method.

  In recent years, video distribution systems that distribute on-demand live video to user terminals via the Internet have become widespread. In addition, a video-on-demand mechanism for distributing file contents on demand has been standardized, and compatible digital televisions have become widespread. There is an increasing need to use these mechanisms to deliver live video. FIG. 16 is a diagram illustrating an example of a conventional video distribution system. As shown in FIG. 16, this video distribution system includes encoders 10a to 10d, a storage server 20, a file server 30, a distribution server group 40, and user terminals 50a to 50c. The encoders 10 a to 10 d are connected to the storage server 20 via the Internet 60. The user terminals 50 a to 50 c are connected to the distribution server group 40 via the Internet 70.

  The encoders 10 a to 10 d are devices that encode video information captured by the camera and transmit the encoded video information to the storage server 20 via the Internet 60. The accumulation server 20 is an apparatus that receives the encoded video information from the encoders 10 a to 10 d and transmits the received video information to the file server 30. The file server 30 is a device that converts the video information transmitted from the storage server 20 into a file every predetermined time, and stores the filed video information in the storage units 30a to 30c.

  The distribution server group 40 includes a plurality of distribution servers 40a to 40d. The distribution servers 40a to 40d are devices that distribute video information to the user terminals 50a to 50c on demand. When the distribution servers 40a to 40d receive distribution requests for video information from the user terminals 50a to 50c, the distribution servers 40a to 40d access the storage units 30a to 30c of the file server 30 and store the video stored in the storage units 30a to 30c. Information is distributed to the user terminals 50a to 50c.

  The user terminals 50a to 50c are devices that receive the video information transmitted from the distribution servers 40a to 40d and display the received video information after making a distribution request for the video information to the distribution servers 40a to 40d.

  In the video distribution system described above, the user terminals 50a to 50c can receive live video from the site by transmitting a video information distribution request to the distribution server group 40. For this reason, the users of the user terminals 50a to 50c can view a desired live video at the timing that the user wants to see.

JP-A-10-31454 JP 2009-44485 A

  However, the conventional video distribution system described above has a problem that live video cannot be distributed to the user terminals 50a to 50c in real time.

  Here, the reason why the conventional video distribution system cannot distribute live video in real time will be described. In the video distribution system described above, the file information is stored in the storage units 30a to 30c after the file server 30 converts the video information into a file every predetermined time. For this reason, the distribution servers 40a to 40d cannot access the storage units 30a to 30c and receive the video information until the file formation is completed. Accordingly, the distribution servers 40a to 40d distribute the video information to the user terminals 50a to 50c after the file conversion is completed, and the time for distributing the video information to the user terminals 50a to 50c for the file conversion time. It will be late.

  The disclosed technology has been made in view of the above, and an object thereof is to provide a distribution device, a distribution program, and a distribution method capable of distributing video information to a user terminal without delay.

  In one aspect, the distribution device disclosed in the present application, when receiving a video information distribution request from a user terminal via the Internet and a video reception unit that receives video information including a plurality of divisions from an encoder, Among the breaks included in the video information, a break detection unit that detects the first break after the timing when the distribution request is received, and time information after the break detected by the break detection unit is set starting from an initial value. And a video distribution unit that distributes video information after the delimiter detected by the delimiter detection unit to the user terminal after the time information setting unit sets the time information. And

  According to one aspect of the distribution device disclosed in the present application, there is an effect that the video information can be distributed to the user terminal without delay.

FIG. 1 is a diagram illustrating the configuration of the distribution apparatus according to the first embodiment. FIG. 2 is a diagram illustrating the configuration of the video distribution system according to the second embodiment. FIG. 3 is a diagram for explaining the processing procedure of the video distribution system according to the second embodiment. FIG. 4 is a functional block diagram showing the configuration of the relay server. FIG. 5 is a diagram illustrating an example of the data structure of the address conversion table. FIG. 6 is a functional block diagram of the configuration of the distribution server according to the second embodiment. FIG. 7 is a diagram illustrating an example of a data structure of the session management table. FIG. 8 is a diagram illustrating an example of the data structure of the virtual file configuration table. FIG. 9 is a diagram illustrating an example of a data structure of video information. FIG. 10 is a diagram illustrating an example of the data structure of the buffer. FIG. 11 is a diagram (1) for explaining the processing of the data conversion unit. FIG. 12 is a diagram (2) for explaining the processing of the data conversion unit. FIG. 13 is a flowchart (1) illustrating the processing procedure of the video distribution system according to the second embodiment. FIG. 14 is a flowchart (2) illustrating the processing procedure of the video distribution system according to the second embodiment. FIG. 15 is a diagram illustrating a hardware configuration of a computer constituting the distribution server. FIG. 16 is a diagram illustrating an example of a conventional video distribution system.

  Hereinafter, embodiments of a distribution apparatus, a distribution program, and a distribution method disclosed in the present application will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

  A distribution apparatus according to the first embodiment will be described. FIG. 1 is a diagram illustrating the configuration of the distribution apparatus according to the first embodiment. As illustrated in FIG. 1, the distribution apparatus 100 includes a video reception unit 110, a break detection unit 120, a time information setting unit 130, and a video distribution unit 140.

  The video receiving unit 110 receives video information including a plurality of breaks from the encoder. When receiving a video information distribution request from a user terminal via the Internet, the segment detection unit 120 detects the first segment after the timing at which the distribution request is received, among segments included in the video information.

  The time information setting unit 130 sets the time information after the delimiter detected by the delimiter detection unit 120, starting from the initial value. After the time information setting unit 130 sets the time information, the video distribution unit 140 distributes the video information after the division detected by the division detection unit 120 to the user terminal.

  As described above, the distribution apparatus 100 according to the first embodiment detects the first segment after the timing at which the video information distribution request is received from the user terminal. Then, after setting the time information after the detected break starting from the initial value, the distribution apparatus 100 delivers the detected video information after the first break to the user terminal. Since the distribution apparatus 100 does not file the video information, it can distribute the video information to the user terminal without delay. Further, when the distribution apparatus 100 distributes video information to the user terminal, the time information is set starting from the initial value. For this reason, the user terminal that has made the distribution request can receive the video information with the time information set from the initial value. Therefore, the user terminal can receive the video information on demand without delaying without providing a special processing unit.

  A configuration of the video distribution system according to the second embodiment will be described. FIG. 2 is a diagram illustrating the configuration of the video distribution system according to the second embodiment. As shown in FIG. 2, encoders 10 a to 10 d, user terminals 50 a to 50 c, and a center 200 are included. The encoders 10 a to 10 d are connected to the center 200 via the Internet 60. User terminals 50 a to 50 c are connected to the center 200 via the Internet 70.

  The encoders 10 a to 10 d are devices that encode video information captured by the camera and transmit the encoded video information to the center 200 via the Internet 60. The user terminals 50 a to 50 c are devices that receive video information transmitted from the center 200 after making a video information distribution request to the center 200 and display the received video information.

  The center 200 distributes the video information transmitted from the encoders 10a to 10d to the user terminals 50a to 50c on demand. As shown in FIG. 2, the center 200 includes a portal server 210, a relay server 220, a switch 230, and distribution servers 300a to 300d.

  The portal server 210 is a device that notifies the user terminals 50a to 50c of the type of content distributed by the center 200. The relay server 220 is a device that multicasts video information received from the encoders 10a to 10d to the distribution servers 300a to 300d. The switch 230 is a layer 3 switch that controls transfer of data transmitted from the relay server 220 and the distribution servers 300a to 300d.

  The distribution servers 300a to 300d are devices that convert the video information transferred from the relay server 220 into virtual files and distribute the video information converted into virtual files to the user terminals 50a to 50c. Hereinafter, a process in which the distribution server 300a converts the video information into a virtual file will be described. The distribution server 300b to 300d processes the video information into a virtual file in the same manner as the distribution server 300a.

  For example, when the distribution server 300a receives a distribution request for video information from the user terminal 50a, the distribution server 300a detects the first division after the timing at which the distribution request is received, from among a plurality of divisions included in the video information. Then, the distribution server 300a converts the video information into a virtual file by setting the time stamp information after the detected first break starting from the initial value. Note that the video information break is a head header periodically included in the video information. This head header corresponds to, for example, a PAT (Program Association Table) and includes time stamp information.

  By the way, in FIG. 2, multicast can be passed between the relay server 220 and the distribution servers 300 a to 300 d via the switch 230. For this reason, the relay server 220 multicasts the video information toward the distribution servers 300a to 300d. On the other hand, multicast cannot be passed between the encoders 10a to 10d and the relay server 220 and between the distribution servers 300a to 300d and the user terminals 50a to 50c. Therefore, the encoders 10a to 10d unicast the video information to the relay server 220. The distribution servers 300a to 300d unicast the video information to the user terminal.

  Next, a processing procedure of the video distribution system shown in FIG. 2 will be described. FIG. 3 is a diagram for explaining the processing procedure of the video distribution system according to the second embodiment. In FIG. 3, as an example, it is assumed that the user terminal 50a makes a distribution request for video information to the distribution server 300a, and the distribution server 300a receives the video information from the encoder 10a.

  As shown in FIG. 3, the user terminal 50a first accesses the portal server 210 and receives the type of content distributed by the center 200. Refer to (1) in FIG. The user terminal 50a displays the type of content received from the portal server 210. When the user selects a content from the content type, the user terminal 50a transmits a video information distribution request to the distribution server 300a. See (2) in FIG.

  The distribution server 300a makes a video information transfer request to the encoder 10a via the switch 230 and the relay server 220. See (3) in FIG. The encoder 10a unicasts the video information to the relay server 220 in response to the transfer request from the distribution server 300a. See (4) of FIG.

  The relay server 220 transmits the video information to the distribution server 300a by multicasting the video information received from the encoder 10a. Refer to (5) in FIG. Here, the transmission destination of the video information multicast from the relay server 220 is limited by the switch 230 in accordance with the transfer request status of each of the distribution servers 300a to 300d. For example, when the distribution servers 300a to 300d make a transfer request to the encoder 10a, the switch 230 transmits video information to the distribution servers 300a to 300d. On the other hand, when only the distribution server 300a makes a transfer request to the encoder 10a, the switch 230 transmits the video information only to the distribution server 300a.

  When receiving the video information from the encoder 10a, the distribution server 300a converts the received video information into a virtual file, and unicasts the video information converted into the virtual file to the user terminal 50a. Refer to (6) in FIG. In this way, the distribution server 300a converts the video information into a virtual file without making it into a file, and unicasts the video information to the user terminal 50a, so that the video information can be unicast to the user terminal without delay. it can.

  By the way, the distribution server 300a receives a video information distribution request from the user terminal 50a, and when the video information is already received from the relay server 220 by multicast, does not perform a video information transfer request. In this case, the distribution server 300a unicasts the already received video information to the user terminal 50a.

  Also, the relay server 220 receives the video information transfer request, and transmits the video information transfer request to the encoder that unicasts the corresponding video information only when the video information unicast is not received. .

  Further, the switch 230 receives the video information transfer request from the distribution server 300a, and when the corresponding video information has already been multicast from the relay server 220, the switch 230a displays the video information multicast from the relay server 220. To distribute. That is, when receiving a video information transfer request from the distribution servers 300a to 300d, the switch 230 determines whether or not the corresponding video information has already been multicast from the relay server 220. Then, when the corresponding video information is not multicast, the switch 230 transfers the video information transfer request to the relay server 220. On the other hand, when the corresponding video information is multicast, the switch 230 distributes the video information to the requesting distribution server without transferring the transfer request.

  Next, an example of the configuration of the relay server 220 illustrated in FIG. 2 will be described. FIG. 4 is a functional block diagram showing the configuration of the relay server. As illustrated in FIG. 4, the relay server 220 includes a transfer request reception unit 221, a control unit 222, a unicast transmission unit 223, a unicast reception unit 224, a storage unit 225, a data conversion unit 226, and a multicast transmission unit 227. .

  The transfer request receiving unit 221 is a processing unit that receives video information transfer requests to the encoders 10 a to 10 d from the distribution servers 300 a to 300 d via the switch 230. This video information transfer request includes destination information of an encoder that requests video information. The transfer request receiving unit 221 outputs the received transfer request to the control unit 222.

  The control unit 222 is a processing unit that acquires a transfer request from the transfer request receiving unit 221, controls the unicast transmission unit 223, and transmits the transfer request to the encoder corresponding to the destination information of the transfer request. The unicast transmission unit 223 is a processing unit that unicasts a video information transfer request to the encoder under the control of the control unit 222.

  The unicast receiving unit 224 is a processing unit that receives video information from an encoder that has requested transfer of video information. This video information is transmitted from the encoder to the relay server 220 by unicast. The unicast reception unit 224 outputs the video information to the data conversion unit 226.

  The storage unit 225 is a storage unit that stores the address conversion table 225a. The address conversion table 225a is a table in which unicast addresses and multicast addresses are associated with each other. FIG. 5 is a diagram illustrating an example of the data structure of the address conversion table. As shown in FIG. 5, the address conversion table 225a stores unicast addresses, reception ports, multicast addresses, and transmission ports in association with each other.

  In FIG. 5, the unicast address is an address included in the destination of the video information received by the relay server 220 from the encoder. The reception port is a port that receives video information from the encoder. The multicast address is an address set as a destination of video information to be transmitted to each of the distribution servers 300a to 300d. The relay server 220 sets the multicast address for the video information, so that the video information is multicast. The transmission port is a port for transmitting video information.

  The data conversion unit 226 is a processing unit that converts the destination of the video information acquired from the unicast reception unit 224 based on the address conversion table 225a. Specifically, the data conversion unit 226 searches the address conversion table 225a for the same unicast address as the address included in the video information. Then, the data conversion unit 226 sets the multicast address associated with the searched unicast address as the destination of the video information, and outputs this video information to the multicast transmission unit 227.

  The multicast transmission unit 227 is a processing unit that multicasts video information to the distribution servers 300a to 300d.

  Here, the transfer request receiving unit 221 and the control unit 222 correspond to, for example, an integrated device such as an application specific integrated circuit (ASIC) or a field programmable gate array (FPGA). Alternatively, the transfer request receiving unit 221 and the control unit 222 correspond to electronic circuits such as a CPU (Central Processing Unit) and an MPU (Micro Processing Unit). The unicast transmission unit 223, the unicast reception unit 224, the data conversion unit 226, and the multicast transmission unit 227 correspond to, for example, an ASIC that performs data communication with other devices, a communication card, and the like. The storage unit 225 corresponds to, for example, a semiconductor memory device such as a random access memory (RAM), a read only memory (ROM), or a flash memory, or a storage device such as a hard disk or an optical disk.

  Next, the configuration of the distribution server 300a shown in FIG. 2 will be described. FIG. 6 is a functional block diagram of the configuration of the distribution server 300a according to the second embodiment. As illustrated in FIG. 6, the distribution server 300 a includes a storage unit 301, a unicast receiving unit 302, a session control unit 303, a control unit 304, and a multicast data request unit 305. The distribution server 300a illustrated in FIG. 6 includes a multicast reception unit 306, a buffer 307, a buffer management unit 308, a data conversion unit 309, and a unicast transmission unit 310. The configuration of distribution servers 300b to 300d is the same as the configuration of distribution server 300a shown in FIG.

  The storage unit 301 is a storage unit that stores a session management table 301a and a virtual file configuration table 301b. The session management table 301a is a table that stores the address of a user terminal that has made a distribution request, the URL (Uniform Resource Locator) of content to be distributed, and the like in association with each other.

  FIG. 7 is a diagram illustrating an example of a data structure of the session management table 301a. As shown in FIG. 7, the session management table 301a includes a transmission destination address, a transmission destination port, the latest connection time, a request content URL, and a time stamp. The transmission destination address is the address of the user terminal that has made a distribution request for video information. The transmission destination port is a port connected to the user terminal that has requested the distribution of the video information. The latest connection time is the latest time when the video information distribution request is received. The request content URL corresponds to the URL of video information to be distributed. The time stamp is information for managing the time stamp included in the head header of the video information. The initial value of the time stamp is 0.

  The virtual file configuration table 301b is a table that stores the URL of the video information to be distributed and the destination information of the encoder that is the transmission source of the video information in association with each other. FIG. 8 is a diagram illustrating an example of the data structure of the virtual file configuration table 301b. As shown in FIG. 8, the virtual file configuration table 301b has a request content URL, a multicast address, and a reception port. Among these, the request content URL is the same as the request content URL of the session management table 301a. The multicast address corresponds to the destination information of the encoder that is the transmission source of the video information. The reception port is a port that receives video information.

  The unicast receiving unit 302 is a processing unit that receives video information distribution requests from the user terminals 50a to 50c. The unicast receiving unit 302 outputs the received distribution request to the session control unit 303. The distribution request received from the user terminals 50a to 50c includes, for example, the URL of the video information to be requested, the address of the transmission source user terminal, and the like.

  The session control unit 303 is a processing unit that controls the control unit 304 and the buffer management unit 308 based on the video information distribution request and the session management table 301a. Hereinafter, the processing of the session control unit 303 will be described in detail.

  First, the process of the session control unit 303 when the URL of the video information included in the distribution request is not included in the request content URL of the session management table 301a will be described. If the URL of the video information is not included in the request content URL, it indicates that the video information requested for distribution is not distributed to the distribution server 300a. In this case, the session control unit 303 notifies the control unit 304 of the URL of the video information. In addition, the session control unit 303 makes a read request by notifying the buffer management unit 308 of the URL of the video information requested for distribution and the address of the user terminal that performed the distribution request. In addition, the session control unit 303 combines the URL of the requested video information with the address of the user terminal that has made the distribution request, and registers the request content URL and the transmission destination address in the session management table 301a. In addition, the session control unit 303 registers the port connected to the user terminal in the transmission destination port of the session management table 301a. In addition, the session control unit 303 registers the time when the distribution request is received in the session management table 301a.

  Subsequently, the URL of the video information included in the distribution request is included in the request content URL, and the combination of the URL of the video information and the address of the user terminal of the transmission source is not included in the session management table 301a. Processing of the session control unit 303 will be described. When the URL of the video information is included in the request content URL, the video information requested for distribution is distributed to the distribution server 300a. However, in this case, it is indicated that the video information is not distributed to the user terminal that has requested the distribution of the video information. The session control unit 303 makes a read request by notifying the buffer management unit 308 of the URL of the requested video information and the address of the user terminal that has made the distribution request. In addition, the session control unit 303 combines the URL of the requested video information with the address of the user terminal that has made the distribution request, and registers the request content URL and the transmission destination address in the session management table 301a. In addition, the session control unit 303 registers the port connected to the user terminal in the transmission destination port of the session management table 301a. In addition, the session control unit 303 registers the time when the distribution request is received in the session management table 301a.

  Next, processing of the session control unit 303 when a set of the URL of the video information included in the distribution request and the address of the user terminal that has made the distribution request is registered in the session management table 301a will be described. In this case, the video information requested to be distributed has already been distributed to the distribution server 300a, and the video information is distributed to the user terminal that has requested the distribution. The session control unit 303 makes a read request by notifying the buffer management unit 308 of the URL of the requested video information and the address of the user terminal that has made the distribution request. In addition, the session control unit 303 registers the time when the distribution request is received in the session management table 301a.

  The control unit 304 is a processing unit that controls the multicast data request unit 305 to transmit a video information transfer request to the relay server 220 when the URL of the video information is acquired from the session control unit 303. The control unit 304 stores the destination information of the encoder in the video information transfer request. Note that the control unit 304 compares the URL of the video information with the virtual file configuration table 301b, and acquires a multicast address corresponding to the URL of the video information as destination information of the encoder.

  The multicast data request unit 305 is a processing unit that transmits a video information transfer request to the relay server 220 under the control of the control unit 304. The multicast receiving unit 306 is a processing unit that receives video information multicast from the relay server 220 and outputs the received video information to the buffer management unit 308.

  Here, an example of the data structure of the video information received by the multicast receiving unit 306 from the relay server 220 will be described. FIG. 9 is a diagram illustrating an example of a data structure of video information. As shown in FIG. 9, the video information 80 includes a plurality of frames 81 to 83. Each frame 81-83 has head headers 81a-83a and data 81b-83b, respectively. The top headers 81a to 83a include time stamp information.

  Note that the multicast receiving unit 306 may not be able to receive video information from the beginning of the frame. Hereinafter, the reason why the video information frame cannot be received from the beginning will be described. When the distribution server 300a transmits a transfer request for this video information to the relay server 220 while the relay server 220 is distributing the video information to another distribution server, the point when the transfer request reaches the switch 230 Thus, the video information in the middle of distribution is distributed to the distribution server 300a. Since the switch 230 does not switch the distribution destination of the video information with reference to the video information break, the video information is distributed to the distribution server 300a from the middle of the frame.

  The buffer 307 is a storage unit that temporarily stores video information for each type. FIG. 10 is a diagram illustrating an example of the data structure of the buffer 307. As shown in FIG. 10, the buffer 307 stores each piece of video information divided into video information A, video information B, and video information C. For example, the video information A includes a plurality of frames A1, A2, and A3, the video information B includes a plurality of frames B1, B2, and B3, and the video information C includes a plurality of frames C1. , C2, C3. It is assumed that the frame B1 of the video information B does not include the head header and some data as shown in FIG.

  The buffer management unit 308 executes processing for storing video information acquired from the multicast reception unit 306 in the buffer 307 and processing for reading video information from the buffer 307 in response to a read request from the session control unit 303.

  First, a process in which the buffer management unit 308 stores video information in the buffer 307 will be described. The buffer management unit 308 acquires the video information from the multicast reception unit 306 and stores the acquired video information in the buffer 307 sequentially. Note that the buffer management unit 308 stores the video information in the buffer 307 separately for each type.

  Next, processing in which the buffer management unit 308 reads video information from the buffer 307 in response to a read request from the session control unit 303 will be described. As described above, the read request acquired from the session control unit 303 includes the URL of the video information and the address of the user terminal that made the distribution request. When the buffer management unit 308 acquires a video information read request from the session control unit 303, the buffer management unit 308 sequentially reads out the video information of the type corresponding to the URL of the video information from the buffer 307 and outputs it to the data conversion unit 309. Further, when outputting the video information to the data conversion unit 309, the buffer management unit 308 outputs the user terminal address together with the data conversion unit 309. Note that the buffer management unit 308 holds, for example, a table in which the URL of the video information is associated with the type of video information stored in the buffer 307, and the video information corresponding to the URL of the video information using the table is used. Are read sequentially.

  The data conversion unit 309 is a processing unit that converts video information acquired from the buffer management unit 308 into a virtual file. The data conversion unit 309 controls the unicast transmission unit 310 to distribute the video information converted into a virtual file to the corresponding user terminal. When receiving the video information, the data conversion unit 309 detects the first head header among the head headers included in the received video information. Then, the data conversion unit 309 converts the video information into a virtual file by setting the time stamp information after the detected head header starting from the initial value. The unicast transmission unit 310 is a processing unit that distributes video information converted into a virtual file to the user terminal according to the control of the data conversion unit 309.

  Hereinafter, the processing of the data conversion unit 309 will be specifically described. FIG. 11 is a diagram (1) for explaining the processing of the data conversion unit. Here, a case where the video information B stored in the buffer 307 is distributed to the user terminal will be described as an example. In addition, it is assumed that the distribution server 300a receives a distribution request for the video information B at the timing of S1 in FIG. Moreover, the vertical axis | shaft of FIG. 11 is a time axis.

  First, the data conversion unit 309 receives the frame B1. Since the frame B1 does not include the head header, the data conversion unit 309 discards the frame B1 (step S10).

  Subsequently, the data conversion unit 309 receives the frame B2. The head header included in the frame B2 is the first head header. Therefore, the data conversion unit 309 creates a virtual file by setting the time stamp information included in the head header of the frame B2 to the initial value “0” (step S11). Then, the data conversion unit 309 distributes the video information converted into a virtual file to the user terminal (step S12).

  Subsequently, the data conversion unit 309 receives the frame B3. The head header included in the frame B3 is the second head header. Therefore, the data conversion unit 309 creates a virtual file by setting the time stamp information included in the head header of the frame B3 to “1” (step S13). Then, the data conversion unit 309 distributes the video information converted into a virtual file to the user terminal (step S14).

  Each time the video information is converted into a virtual file, the data conversion unit 309 registers, to the time stamp of the session management table 301a, to what number the time stamp information is set for each user terminal as a transmission destination. Also, the data conversion unit 309 refers to the session management table 302a to determine which number to set the next time stamp information. For example, the data conversion unit 309 sets a value obtained by adding 1 to the time stamp of the session management table 302a as the next time stamp information.

  By the way, when the distribution server 300a starts distributing the video information to the user terminal, the distribution server 300a periodically receives a distribution request for the same video information from the user terminal, and distributes the video information in response to the distribution request. In this case, when the data conversion unit 309 receives the previous distribution request, the data conversion unit 309 can distribute the video information to the user terminal up to a perfect location, thereby distributing the continuous video information to the user terminal. To do.

  FIG. 12 is a diagram (2) for explaining the processing of the data conversion unit. In FIG. 12, a case where the video information A is distributed to the user terminal will be described as an example. In addition, it is assumed that the distribution server 300a receives a distribution request for the video information A from the same user terminal at the timings S1 and S2 in FIG. As shown in FIG. 12, the interval between S1 and S2 does not match the segment of video information A.

  As shown in FIG. 12, the data conversion unit 309 converts the frames A1, A2, and A3 into virtual files by setting the time stamp information of the headers of the frames A1, A2, and A3 to 0, 1, and 2, respectively. The video information converted into a virtual file is distributed to the user terminal (step S20). Subsequently, the data conversion unit 309 sets the time stamp information of the head header of the frame A4 to 3, thereby converting the frame A4 into a virtual file and distributing the video information converted into the virtual file to the user terminal (step S21). . As shown in FIG. 12, the data conversion unit 309 distributes the video information to the end even when the distribution request is delayed, so that the user terminal can receive the video information A without breaks.

  Here, the session control unit 303, the control unit 304, the buffer management unit 308, and the data conversion unit 309 correspond to, for example, an integrated device such as an ASIC or FPGA. Alternatively, the session control unit 303, the control unit 304, the buffer management unit 308, and the data conversion unit 309 correspond to electronic circuits such as a CPU and an MPU. The unicast receiving unit 302, the multicast data requesting unit 305, the multicast receiving unit 306, and the unicast transmitting unit 310 correspond to, for example, an ASIC that performs data communication with other devices, a communication card, and the like. The storage unit 301 corresponds to, for example, a semiconductor memory device such as a RAM, a ROM, or a flash memory, or a storage device such as a hard disk or an optical disk. The buffer 307 corresponds to, for example, a semiconductor memory element.

  Next, a processing procedure of the video distribution system shown in FIG. 2 will be described. FIGS. 13 and 14 are flowcharts illustrating the processing procedure of the video distribution system according to the second embodiment. Here, for convenience of explanation, a case will be described in which the user terminal 50a makes a distribution request for video information to the distribution server 300a. In addition, it is assumed that a switch 230 exists between the distribution server 300a and the relay server 220.

  As shown in FIG. 13, the user terminal 50a transmits a distribution request for video information to the distribution server 300a (step S101), and the distribution server 300a receives the distribution request for video information from the user terminal 50a (step S101). S102). The distribution server 300a updates the session management table 301a (step S103) and transmits a video information transfer request to the relay server 220 (step S104).

  When the distribution server 300a receives the corresponding video information from the switch 230 at the time of receiving the distribution request for the video information from the user terminal 50a, the distribution server 300a displays the received video information. Unicast to user terminal 50a. In the following description, a case where the distribution server 300a has not received corresponding video information from the switch 230 will be described.

  In addition, the transfer request of the video information transmitted in step S104 is transmitted to the relay server 220 via the switch 230. If the corresponding video information has already been multicast from the relay server 220, the switch 230 distributes the video information to the distribution server 300a. On the other hand, when the corresponding video information is not multicast from the relay server 220, the switch 230 transmits a video information transfer request to the relay server 220. In the following description, a case where the switch 230 transmits a video information transfer request to the relay server 220 will be described as an example.

  The relay server 220 receives a video information transfer request from the distribution server 300a (step S105), and requests video information from the encoder (step S106). The relay server 220 receives the video information from the encoder (step S107), and converts the unicast address of the video information into a multicast address (step S108). Then, the relay server 220 multicasts the video information (step S109).

  The video information multicasted in step S109 reaches the switch 230. The switch 230 distributes the video information to the distribution servers 300a to 300d in accordance with the status of the video information transfer request. For example, when the distribution server 300a makes a distribution request for the corresponding video information, the video information is distributed only to the distribution server 300a.

  The distribution server 300a receives the video information from the relay server 220 (step S110), and stores the video information in the buffer 307 (step S111).

  The description shifts to the description of FIG. The distribution server 300a reads the video information from the buffer 307 (step S112), and sets the time stamp information of the head header of the video information to an initial value (step S113). The distribution server 300a transmits the video information to the user terminal 50a (Step S114).

  The user terminal 50a receives the video information (step S115), and determines whether to request the video information continuously (step S116). When the user terminal 50a does not continuously request video information (No at Step S117), the user terminal 50a ends the process.

  If the user terminal 50a continues to request video information (step S117, Yes), the user terminal 50a transmits a video information distribution request to the distribution server 300a (step S118), and proceeds to step S115.

  The distribution server 300a determines whether or not a video information distribution request has been received from the user terminal 50a (step S119). If the distribution server 300a has not received a distribution request (step S120, No), the process ends. On the other hand, when the distribution server 300a receives the distribution request (step S120, Yes), the distribution server 300a stores the value obtained by adding 1 to the previous time stamp information of the video information in the current time stamp information (step S121). The process proceeds to S114.

  As described above, when the distribution server 300 according to the second embodiment distributes video information stored in a buffer in response to a video information distribution request from the user terminal 50, each head included in the video information. Among the headers, the first head header is detected. Then, the distribution server 300 sets the time stamp information after the detected head header starting from the initial value, thereby converting the video information into a virtual file and distributing the video information converted into the virtual file to the user terminal 50. Since the distribution server 300 does not file the video information, the distribution server 300 can distribute the video information to the user terminal 50 without delay.

  Further, when the distribution server 300 distributes the video information to the user terminal 50, the time stamp information is set starting from the initial value. Therefore, the user terminal 50 that has made the distribution request can receive the video information with the time stamp information set from the initial value. Therefore, the user terminal 50 can receive video information on demand without delaying without providing a special processing unit. Further, when distributing the video information, the distribution server 300 distributes the video information up to the break of the video information, so that the user terminal 50 can receive the video information seamlessly.

  By the way, all or some of the processes described as being automatically performed among the processes described in the present embodiment can be manually performed. Alternatively, all or part of the processing described as being performed manually can be automatically performed by a known method. In addition, the processing procedure, control procedure, specific name, and information including various data and parameters shown in the above-described document and drawings can be arbitrarily changed unless otherwise specified.

  Further, each component of each illustrated apparatus is functionally conceptual, and does not necessarily need to be physically configured as illustrated. In other words, the specific form of distribution / integration of each device is not limited to that shown in the figure, and all or a part thereof may be functionally or physically distributed or arbitrarily distributed in arbitrary units according to various loads or usage conditions. Can be integrated and configured. For example, the video information may be stored in the storage unit 301 instead of the buffer 307. Further, the distribution server 300 stores all the video information distributed from the encoder 10 in the storage unit 301, and requests the video information stored in the storage unit 301 for a user who missed the real-time video information. Accordingly, it may be distributed to the user terminal 50.

  Each processing function performed in the distribution server 300a may be realized in whole or in part by a CPU and a program that is analyzed and executed by the CPU, or may be realized as hardware by wired logic. .

  FIG. 15 is a diagram illustrating a hardware configuration of a computer constituting the distribution server. As shown in FIG. 15, the computer 400 includes a CPU 401 that executes various arithmetic processes, an input device 402 that receives input of data from a user, and a monitor 403. The computer 400 includes a medium reading device 404 that reads a program and the like from a storage medium, and a network interface device 405 that exchanges data with other computers via a network. The computer 400 also includes a RAM 406 that temporarily stores various types of information and a hard disk device 407. Each device 401 to 407 is connected to a bus 408.

  The hard disk device 407 stores a distribution processing program 407a. The hard disk device 407 stores a session management table 307b corresponding to the session management table 301a shown in FIG. 6 and a virtual file configuration table 407c corresponding to the virtual file configuration table 301b shown in FIG.

  When the CPU 401 reads the distribution processing program 407a from the hard disk device 407 and expands it in the RAM 406, the distribution processing program 407a functions as the distribution processing process 406a. The distribution processing process 406a stores a distribution processing program 407a corresponding to the session control unit 403, control unit 404, buffer management unit 408, and data conversion unit 409 shown in FIG. Then, the distribution process 406a uses the session management table 407b and the virtual file configuration table 407c to convert the video information into a virtual file, and distributes the video information converted into a virtual file to the user terminal.

  Note that the distribution processing program 407a is not necessarily stored in the hard disk device 407, and the computer 400 may read and execute a program stored in a storage medium such as a CD-ROM. Further, the distribution processing program 407a is stored in a public line, the Internet, a LAN (Local Area Network), a WAN (Wide Area Network), etc., and the computer 400 reads out and executes the distribution processing program 407a. Also good.

100 Distribution Device 110 Video Receiving Unit 120 Break Detection Unit 130 Time Information Setting Unit 140 Video Distribution Unit

Claims (6)

A video receiving unit that periodically stores video information including a plurality of breaks generated by an encoder and stores them in a buffer by dividing them into groups for each type sequentially via a switch that does not perform distribution control based on the breaks ;
When the video information distribution request is received from the user terminal via the Internet at a timing different from any of the timings of the plurality of breaks , the distribution request corresponds to the distribution request from the group of video information stored for each type. For a group of video information, with reference to the buffer storing the video information, a delimiter detection unit that detects a first delimiter after the timing at which the distribution request is received, among delimiters included in the video information,
A time information setting unit that sets the time information value of each video information included in each segment after the first segment detected by the segment detection unit in ascending order from the initial value;
The segment detection is performed after the time information setting unit sets the time information without distributing video information from the timing at which the distribution request is received to the first segment detected by the segment detection unit to the user terminal. A video distribution unit that distributes video information after the first segment detected by the unit to the user terminal.   The video distribution unit includes video information from the first segment after the timing at which a distribution request is received from the user terminal to a segment after the first segment among the plurality of segments included in the video information. The distribution apparatus according to claim 1, wherein the distribution apparatus distributes to a user terminal. On the computer,
A video reception procedure for storing video information periodically including a plurality of breaks generated by an encoder through a switch that does not perform distribution control based on the breaks, divided into groups for each type, and stored in a buffer;
When the video information distribution request is received from the user terminal via the Internet at a timing different from any of the timings of the plurality of breaks , the distribution request corresponds to the distribution request from the group of video information stored for each type. For a group of video information, with reference to the buffer storing the video information, a delimiter detection procedure for detecting a first delimiter after the timing at which the distribution request is received, among delimiters included in the video information,
A time information setting procedure for setting the time information value of each video information included in each segment after the first segment detected by the segment detection procedure in ascending order from the initial value;
The segment information is detected after the time information setting procedure sets the time information without distributing video information from the timing at which the distribution request is received to the first segment detected by the segment detection procedure to the user terminal. And a video delivery procedure for delivering video information after the first segment detected by the procedure to the user terminal.   The video distribution procedure includes video information from the first segment after the timing at which a distribution request is received from the user terminal to a segment after the first segment among a plurality of segments included in the video information. The distribution program according to claim 3, wherein the distribution program is distributed to a user terminal. The distribution device
A video reception step of storing video information periodically including a plurality of breaks generated by the encoder, sequentially through a switch that does not perform distribution control based on the breaks, and grouped into groups for each type ;
When the video information distribution request is received from the user terminal via the Internet at a timing different from any of the timings of the plurality of breaks , the distribution request corresponds to the distribution request from the group of video information stored for each type. For a group of video information, referring to the buffer storing the video information, a delimitation detecting step of detecting a first delimiter after the timing of receiving the distribution request among delimiters included in the video information;
A time information setting step for setting the time information value of each video information included in each segment after the first segment detected by the segment detection step in ascending order from the initial value;
The segment information is detected after the time information setting step sets the time information without distributing the video information from the timing of receiving the distribution request to the first segment detected in the segment detection step to the user terminal. And a video delivery step of delivering video information after the first segment detected in the step to the user terminal.   The video distribution step includes video information from the first segment after the timing at which a distribution request is received from the user terminal to a segment after the first segment among a plurality of segments included in the video information. 6. The distribution method according to claim 5, wherein distribution is performed to a user terminal.

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