JP2011188010A - Ip packet distribution system, receiver switching method, receiver switching program, and program recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an IP packet distribution system for normally decoding IP packets by rapidly switching a receiver for decoding the received IP packets to a standby receiver, even in unicast distribution, when an abnormality of an operation state of the receiver is detected. <P>SOLUTION: A receiving station 5 equipped with present and standby decoders 51, 5Z for decoding IP packets which are unicast-distributed via layer-3 switches 2, 4 for performing route control includes a monitoring control terminal 6 for monitoring and controlling the operation states of the present and standby decoders 51, 5Z at a predetermined period. If an abnormal operation is detected in the present decoder 51, it is immediately switched to the standby decoder 5Z, the layer-3 switch 4 positioned at an input side is informed of the fact, the input route of the IP packets is switched to the standby decoder 5Z and matrix switches 7 provided on the output side of the present and standby decoders 51, 5Z are so controlled so as to output decoding information from the standby decoder 5Z. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an IP packet distribution system, a receiver switching method, a receiver switching program, and a program recording medium, and is particularly specified in a video IP packet distribution system that distributes a video signal of content information as an IP (Internet Protocol) packet. Even in the unicast distribution method in which an IP packet is distributed only to a single destination, IP packet distribution that can quickly switch between receivers (decoders) that receive and decode the IP packet The present invention relates to a system, a receiver switching method, a receiver switching program, and a program recording medium.

  In recent years, there has been a rapid increase in demand for an IP packet distribution system that can distribute IP packets including broadband information in real time and stably, such as video stream distribution. In other words, in the IP packet distribution system, when trouble occurs in IP packet distribution, it is strongly desired that an operation for eliminating the trouble is performed quickly and normal IP packet distribution operation is continuously performed. It is becoming

  From such a background, for example, as disclosed in Japanese Patent Application Laid-Open No. 2005-26902, “Network failure monitoring method in network relay device and relay device to which this is applied”, network relay such as a router that performs route control of IP packets. When the ARP (Address Resolution Protocol) update process between the devices is used to check the normality of the network relay device on the other side and it is detected that a failure has occurred in the network relay device on the other side, Techniques for controlling packets to be bypassed have been proposed.

  Further, in Japanese Patent Laid-Open No. 2006-174299 “Data distribution method, receiving device, computer program and recording medium on which this computer program is recorded” of Patent Document 2, the same IP packet is distributed to a plurality of receiving devices. Necessary for repairing IP packets lost in each communication path by using a redundant coding method on the receiving device side based on the IP packet loss rate in each communication path when performing multicast distribution A technique has been proposed in which the number of redundant packets is calculated, and the maximum number of redundant packets among the number of redundant packets calculated on each receiving device side is multicast-distributed from the transmitting device. Furthermore, Japanese Patent Application Laid-Open No. 2008-22393 “IP broadcast receiving system and IP broadcast receiving terminal device” of Patent Document 3 distributes the same packet when an abnormality of the distribution packet is detected when multicast distribution is performed. We propose a technique for quickly switching to a normal route by joining with a normal channel.

Japanese Patent Laying-Open No. 2005-26902 (page 5-7) JP 2006-174299 A (page 6-9) JP 2008-22393 A (page 7-10)

  However, the conventional techniques such as Patent Document 1 and Patent Document 2 both use the monitoring result in the IP layer on the path from the transmission device to the reception device via the communication network, This is a mechanism for detecting the presence / absence of a failure, and is not a technique that can detect an abnormality other than the IP layer, for example, an abnormality of a decoder that decodes an IP packet. However, there is a problem that information distributed on the receiving device may not be displayed on the screen or used normally.

  Further, in the case of an IP packet distribution system that performs a multicast distribution operation as in Patent Document 3, for example, when a failure is detected, the same IP packet as the channel in which the failure has occurred is distributed to the channel. It was possible to quickly switch to a normal route using a technique such as Join, but in the case of a unicast delivery method that delivers only to one receiver (decoder) There is also a problem that it cannot be switched quickly.

(Object of the present invention)
The present invention has been made in view of such circumstances. Even when an IP packet is unicasted, an abnormality in the operating state of a receiver (decoder) that decodes the received IP packet is detected. To provide an IP packet distribution system, a receiver switching method, a receiver switching program, and a program recording medium capable of quickly switching to a standby receiver (decoder) and continuously performing an IP packet decoding operation. is there.

  In order to solve the above-described problems, the IP packet distribution system according to the present invention employs the following characteristic configuration.

  (1) In an IP packet distribution system that converts content information into an IP packet and distributes it via a network, a receiver on the working side as a receiver that receives the distributed IP packet, decodes it to the original content information, and outputs it And a standby side receiver, and further, when an operational abnormality is detected by monitoring the operating state of the active side receiver and the standby side receiver of the receiving station Controlling switching to the receiver that should receive the subsequent IP packet, and controlling the receiver that should receive the subsequent IP packet, among the working receiver and the standby receiver Then, the IP packet is sent as information for address resolution to the layer 3 switch which is a relay device on the network side that performs route control of the IP packet to the receiving station. IP packet delivery system comprising a monitor control terminal having at least a function of the address information on the receiver to receive transmitted including at least ARP (Address Resolution Protocol) notification information.

  According to the IP packet distribution system, receiver switching method, receiver switching program, and program recording medium of the present invention, in order to decode an IP packet that is unicast distributed via a layer 3 switch such as a router that performs path control. The monitoring station that monitors and controls the operating state of the receiver (decoder) at a predetermined cycle is provided on the receiving station side having receivers (decoders) on the active side and the standby side, and reception on the active side When an abnormal operation of the decoder (decoder) is detected, the IP packet is immediately switched to the standby receiver (decoder) and controlled by a network relay device such as a router on the input side, that is, a layer 3 switch. The input path is switched to the standby side (decoder) and provided on the output side of the working side and standby side (decoder) receivers. And it controls the matrix switch, since the control to output the decoded information from the standby side of the receiver (decoder), can be obtained the following effects.

  First, not only an abnormality at the IP layer level of an IP packet to be distributed, but also when the operation of the working receiver (decoder) accommodated in the receiving station becomes abnormal, In addition, the receiver (decoder) that has entered an abnormal operation is switched to a normal standby-side receiver (decoder), and the received IP packet is correctly decoded into the original content information, for example, a video signal, based on the video signal. The video can be displayed on the screen.

  Secondly, when the receiver (decoder) that decodes the received IP packet is switched from the active receiver (decoder) to the standby receiver (decoder), it is set as the standby receiver (decoder). The IP address (that is, the IP address assigned to the working receiver (decoder)) and the MAC address of the standby receiver (decoder) are transferred to the network relay device that performs path control of the IP packet, that is, the layer 3 switch. Since it is notified, even in the case of the unicast distribution method, when only the same IP address as the failed working side decoder (receiver) is set in the standby side receiver (decoder), In a layer 3 switch that performs route control of IP packets, it is necessary to perform address resolution for route selection to the receiver (decoder) on the standby side It is possible to solve the problem because it takes a long time to.

  Thirdly, a monitoring control terminal is provided which constantly monitors the operation status of the working side decoder and the spare decoder stored in the receiving station and controls switching between the working side and the spare side of the decoder to be used. Therefore, it is possible to perform a quick switching control as compared with the case where the decoders of the working decoder and the spare decoder mutually monitor the state.

It is a block block diagram which shows the structural example of the video IP packet delivery system which concerns on the 1st Embodiment of this invention. It is a sequence chart for demonstrating an example of operation | movement of the video IP packet delivery system of FIG. It is a block block diagram which shows the structural example of the video IP packet delivery system which concerns on the 2nd Embodiment of this invention. It is a sequence chart for demonstrating an example of operation | movement of the video IP packet delivery system of FIG. It is a block block diagram which shows the structural example of the video IP packet delivery system which concerns on the 3rd Embodiment of this invention. It is a sequence chart for demonstrating an example of operation | movement of the video IP packet delivery system of FIG.

  Hereinafter, preferred embodiments of an IP packet distribution system, a receiver switching method, a receiver switching program, and a program recording medium according to the present invention will be described with reference to the accompanying drawings, taking a video IP packet distribution system for distributing video IP packets as an example. I will explain. In the following description, an IP packet distribution system and a receiver (decoder) switching method for decoding an IP packet according to the present invention will be described. A receiver switching program capable of executing such a receiver switching method by a computer. Needless to say, the receiver switching program may be recorded on a computer-readable recording medium. In the following description, an embodiment of the video IP packet distribution system will be described as an example of the IP packet distribution system according to the present invention. However, the present invention is limited only to the video IP packet distribution system. However, any system that distributes information using IP packets can be applied in exactly the same way.

(Features of the present invention)
Prior to the description of the embodiments of the present invention, an outline of the features of the present invention will be described first. In the IP packet distribution system, the receiver (decoder) that decodes the IP packet becomes abnormal when the operation of the receiver (decoder) that decodes the IP packet becomes abnormal as well as the abnormality at the IP layer level of the IP packet to be distributed. It is characterized in that a mechanism for switching to a decoder) quickly and smoothly is also possible in unicast distribution.

(Configuration of the first embodiment)
First, a configuration example of the video IP packet distribution system according to the first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration example of a video IP packet distribution system according to the first embodiment of the present invention.

  A video IP packet distribution system 100 shown in FIG. 1 includes at least a content distribution server 1, a receiving station 5, a monitoring control terminal 6, a matrix switch 7, and a monitor 8. The content distribution server 1 has an encoder 11 that converts content information such as a video signal into an IP packet, and the receiving station 5 receives a receiver (decoder) that decodes the IP packet into original content information such as a video signal and outputs it. The decoder 51 and the spare decoder 5Z are housed. Here, the receiver housed in the receiving station 5 is expressed as a decoder. And between the content distribution server 1 and the receiving station 5 via the network 3 such as the Internet via the layer 3 switch (L3-SW) 2 and the layer 3 switch (L3-SW) 4, respectively. Are connected to each other.

  The encoder 11 accommodated in the content distribution server 1 is an apparatus that converts the video signal of the content information into an IP packet and sends it to the receiving station 5 regardless of whether or not the video signal of the content information is compressed / uncompressed. It is. Here, the encoder 11 unicasts the video material of each program from the content distribution server 1 as necessary.

  The IP packet transmitted from the content distribution server 1 is received by the receiving station 5 via the layer 3 switch 2, the layer 3 switch 4 and the network 3. The network 3 may be either a public line or a dedicated line, and is a network communication network conforming to the IP protocol for transferring IP packets.

  Each of the layer 3 switch 2 and the layer 3 switch 4 is a network relay device and performs route control by an IP address, and has a function of transferring a received IP packet to an output port corresponding to a target IP address. I have. The layer 3 switch 2 and the layer 3 switch 4 are devices that process the layer 3 protocol, and devices such as routers are also included in this class.

  The decoder 51 accommodated in the receiving station 5 depacketizes (deassembles) the IP packet received from the encoder 11 and then outputs the original content information, for example, a video signal to the matrix switch 7. The video signal output from the decoder 51 is input to the monitor 8 via the matrix switch 7, and the monitor 8 displays a video image based on the input video signal.

  The monitoring control terminal 6 is an information processing apparatus such as a personal computer, and is a monitoring terminal installed on the receiving station 5 side. The supervisory control terminal 6 can always monitor the operation status of the receiving station 5 by accessing the decoder 51 and the spare decoder 5Z, and has a function of controlling the receiving station 5. The supervisory control terminal 6 also has a function of controlling the matrix switch 7 which is a switching means for switching the outputs of the decoder 51 and the spare decoder 5Z and inputting them to the monitor 8 of the subsequent apparatus. Control to connect any output destination of the decoder 5Z to the monitor 8 is performed.

(Description of operation of the first embodiment)
Next, an example of the operation of the video IP packet distribution system 100 shown in FIG. 1 will be described in detail with reference to the sequence chart of FIG. FIG. 2 is a sequence chart for explaining an example of the operation of the video IP packet distribution system 100 in FIG. 1, and a decoder 51 housed in the layer 3 switch (L3-SW) 4 and the receiving station 5 in FIG. The operations of the spare decoder 5Z, the supervisory control terminal 6 and the matrix switch 7 are shown.

  In the sequence chart of FIG. 2, the IP packet sent from the encoder 11 of the content distribution server 1 is unicasted as a layer 3 switch (L3-SW) 2, a network 3, and a layer 3 switch (L3-SW) 4. Via the decoder 51 of the receiving station 5. In addition, the supervisory control terminal 6 always accesses the decoder 51 and the spare decoder 5Z at a predetermined cycle in order to perform supervisory control of the receiving station 5 (sequences A1 and A3).

  Then, the decoder 51 and the spare decoder 5Z responding to the access from the supervisory control terminal 6 return the respective operational statuses to the supervisory control terminal 6, and the supervisory control terminal 6 receives the respective operational statuses. (Sequence A2, A4). Furthermore, the working decoder 51 can also voluntarily transmit the operation status to the monitoring control terminal 6 at predetermined intervals or whenever IP packet decoding processing is performed (sequence A5). ). Information transmitted to the monitoring control terminal 6 as the operating status of the decoder 51 and the spare decoder 5Z is the respective device alarm / device status, setting parameter information, and the like.

  The supervisory control terminal 6 determines that the received decoder 51 cannot decode the IP packet into a video signal and output it to the monitor 8 due to a failure or the like as an analysis result of the received operation status. Then (sequence A6) immediately, the same setting parameter as that of the failed decoder 51 is set for the spare decoder 5Z (sequence A7). At this time, network parameters such as the IP address assigned to the working decoder 51 are also set in the spare decoder 5Z.

  Furthermore, the supervisory control terminal 6 controls the matrix switch 7 to switch the input of the video signal to the monitor 8 from the active decoder 51 whose operation is abnormal to the output from the spare decoder 5Z (sequence A8).

  Thereafter, when the spare decoder 5Z taking over the setting parameters of the decoder 51 receives a control signal for instructing the start of the IP packet reception operation from the supervisory control terminal 6 (sequence A9), the layer 3 switch 4 that performs path control of the IP packet. ARP (Address Resolution Protocol) notification information including at least the IP address of the own spare decoder 5Z (the IP address assigned to the working decoder 51) and the MAC address of the own spare decoder 5Z is transmitted (sequence). A10).

  The layer 3 switch 4 that has received the ARP notification information uses the MAC address corresponding to the IP address of the decoder 51 and the transfer port in the data on the ARP table provided therein, and the MAC address of the spare decoder 5Z. The transfer port is rewritten (sequence A11). Thereby, in the layer 3 switch 4, the IP packet originally transferred to the decoder 51 is switched to a state where it is transferred to the port of the spare decoder 5Z (sequence A12).

  Thus, when the operation of the working decoder 51 in the receiving station 5 becomes abnormal, the IP packet sent from the encoder 11 is operated normally instead of the decoder 51 whose operation is abnormal. Can be quickly switched to a state of being received by the spare decoder 5Z capable of being decoded, correctly decoded into a video signal, and output to the corresponding monitor 8 via the matrix switch 7 whose output is switched to the spare decoder 5Z side. Then, the video image based on the video signal is continuously displayed on the monitor 8.

(Description of the effect of the first embodiment)
As described in detail above, according to the first embodiment, not only an abnormality at the IP layer level of the IP packet to be distributed, but also the operation of the working decoder 51 accommodated in the receiving station 5 is abnormal. When the control signal is received, the supervisory control terminal 6 instantly switches the decoder 51, which has malfunctioned, to the normal spare decoder 5Z, and correctly decodes the received IP packet into the original video signal. An image based on the signal can be displayed on the screen of the monitor 8.

  Further, when the decoder for decoding the received IP packet is switched from the working decoder 51 to the spare decoder 5Z, the IP address set in the spare decoder 5Z (that is, the IP address assigned to the working decoder 51) and the spare. Since the MAC address of the decoder 5Z is notified to the relay device on the network 3 side that controls the route of the IP packet, that is, the layer 3 switch 4, even in the case of the unicast distribution method, the failed working In the case where only the same IP address as that of the side decoder 51 (active side receiver) is set in the backup decoder 5Z (backup side receiver), the standby decoder 5Z ( It takes time to resolve the address for route selection to the receiver on the standby side) It is possible to solve the problem of Tsu.

  Furthermore, a monitoring control terminal 6 is provided which constantly monitors the operating status of the working decoder 51 and the spare decoder 5Z accommodated in the receiving station 5 and controls switching between the working side and the spare side of the decoder to be used. Therefore, it is possible to perform a quick switching control as compared with the case where the decoders of the active side decoder and the spare decoder perform mutual state monitoring.

(Configuration of Second Embodiment)
Next, a configuration example of the video IP packet distribution system according to the second embodiment of the present invention will be described with reference to FIG. FIG. 3 is a block diagram showing a configuration example of the video IP packet distribution system according to the second embodiment of the present invention. Unlike the IP distribution system 100 shown in FIG. 1, the video IP packet distribution system 100A shown in FIG. 3 distributes a plurality of pieces of content information such as video signals from the content distribution server 1A as respective IP palettes, and receives them in the receiving station 5A. ,..., And decoder 5N, the video data based on the video signals is decoded into a plurality of monitors 81,. In the receiving station 5A, a plurality of decoders 51,..., A spare decoder 5Z that can be used as a spare for the decoder 5N are housed (N + 1). The case where the configuration of the spare system is adopted is shown.

  That is, the video IP packet distribution system 100A shown in FIG. 3 includes at least the content distribution server 1A, the receiving station 5A, the monitoring control terminal 6A, the matrix switch 7A, and the monitor group 8A. Further, the content distribution server 1A includes N pieces of content information, for example, N signals (N: positive integer), for example, N pieces of encoders 11,..., Encoder 1N that convert video signals into IP packets, and the receiving station 5A includes .., Decoder 5N and spare decoder 5Z as receivers (decoders) for decoding and outputting original content information, for example, video signals, and the monitor group 8A. , N monitors 81,..., Monitor 8N are housed. Here, the receiver housed in the receiving station 5A is expressed as a decoder. Then, between the content distribution server 1A and the receiving station 5A, via the network 3 such as the Internet via the layer 3 switch (L3-SW) 2A and the layer 3 switch (L3-SW) 4A, respectively. Are connected to each other.

  The N encoders 11,..., Encoder 1N stored in the content distribution server 1A are not limited to whether or not the video signal of the content information is compressed / uncompressed, and each video signal is converted into an IP packet. Thus, it is a device that sends it out to the receiving station 5A. Here, the encoder 11,..., The encoder 1N distributes the video material of each program from the content distribution server 1A as necessary.

  The IP packet transmitted from the content distribution server 1A is received by the receiving station 5A via the layer 3 switch 2A, the layer 3 switch 4A, and the network 3. The network 3 may be either a public line or a dedicated line, and is a network communication network conforming to the IP protocol for transferring IP packets.

  Each of the layer 3 switch 2A and the layer 3 switch 4A is a network relay device and performs route control by an IP address, and has a function of transferring a received IP packet to an output port corresponding to a target IP address. I have. The layer 3 switch 2A and the layer 3 switch 4A are devices that process the layer 3 protocol, and devices such as routers are also included in this class.

  The N active-side decoders 51,..., Decoder 5N accommodated in the receiving station 5A all depacketize (deassemble) the IP packets received from the opposing encoders 11,. The original content information such as a video signal is output to the matrix switch 7A. The video signals output from the decoder 51,..., The decoder 5N are connected to the N monitors 81, housed in the monitor group 8A, facing the decoder 51,. ... Is input to the monitor 8N, and the N monitors 81,...

  Further, the spare decoder 5Z accommodated in the receiving station 5A can receive the received IP packet in place of the failed decoder, even if any of the N working decoders 51,... Is a spare device that can be output as a video signal after being depacketized (deassembled), and is a common spare device for each decoder on the active side, and the decoder group housed in the receiving station 5A is an (N + 1) spare configuration It is said that.

  The monitoring control terminal 6A is an information processing apparatus such as a personal computer, and is a monitoring terminal installed on the receiving station 5A side. The monitoring control terminal 6A can always monitor the operating status of the receiving station 5A by accessing the N working decoders 51,..., The decoder 5N and the spare decoder 5Z, and the receiving station 5A. It has a function to control. The supervisory control terminal 6A also has a function of controlling the matrix switch 7A, which is a switching means for switching the outputs of the decoders 51,..., The decoder 5N, and the spare decoder 5Z and inputting them to the monitor group 8A of the subsequent apparatus. And monitor the output destination of each of the N active decoders 51,..., The decoder 5N, or the output destination of the spare decoder 5Z when one of the decoders 51,. Control is performed to connect to the N monitors 81,..., The monitor 8N housed in the group 8A.

(Description of the operation of the second embodiment)
Next, an example of the operation of the video IP packet distribution system 100A shown in FIG. 3 will be described in detail with reference to the sequence chart of FIG. FIG. 4 is a sequence chart for explaining an example of the operation of the video IP packet distribution system 100A of FIG. 3, and the N units housed in the layer 3 switch (L3-SW) 4A and the receiving station 5A of FIG. ,..., The operation of an arbitrary decoder 5i (1 ≦ i ≦ N) of the decoder 5N, the spare decoder 5Z, the supervisory control terminal 6A, and the matrix switch 7A.

  In the sequence chart of FIG. 4, IP packets sent from the encoders 11,..., Encoder 1 N of the content distribution server 1 A are transmitted as unicast distribution as a layer 3 switch (L 3 -SW) 2 A, a network 3, and a layer 3 switch. (L3-SW) It is in a state of being received by the decoder 5i of the receiving station 5A via 4A. Also, the monitoring control terminal 6A performs N monitoring control of the receiving station 5A, and N active decoders 5i (decoders 51,..., Decoder 5N) are always in a predetermined order at predetermined intervals. And the spare decoder 5Z are accessed (sequences B1 and B3).

  Then, the working side decoder 5i (decoder 51,..., Decoder 5N) and the spare decoder 5Z responding to the access from the monitoring control terminal 6A return the respective operation statuses to the monitoring control terminal 6A, and monitor them. The control terminal 6A can receive the operation statuses in a predetermined order (sequences B2 and B4). Further, the active side 5i (decoder 51,..., Decoder 5N) voluntarily transmits the operation status to the monitoring control terminal 6A at a predetermined period or whenever the IP packet is decoded. It is also possible (sequence B5). Information transmitted to the monitoring control terminal 6A as the operating status of the decoder 5i (decoder 51,..., Decoder 5N) and the spare decoder 5Z is the respective device alarm / device status, setting parameter information, and the like.

  As a result of analysis of the received operation status, the supervisory control terminal 6A determines that one of the N working decoders 51,..., Decoder 5N, for example, the working decoder 5i decodes the IP packet into a video signal due to a failure or the like. If it is determined that output to the corresponding monitor 8i is impossible (sequence B6), the same setting parameter as that of the failed decoder 5i is immediately set to the spare decoder 5Z (sequence B7). At this time, network parameters such as the IP address assigned to the working decoder 5i are also set in the spare decoder 5Z.

  Further, the supervisory control terminal 6A controls the matrix switch 7A to switch the input of the video signal to the corresponding monitor 8i from the active decoder 5i having an abnormal operation to the output from the spare decoder 5Z (sequence B8). .

  After that, when the spare decoder 5Z taking over the setting parameters of the decoder 5i receives a control signal for instructing the start of the IP packet reception operation from the supervisory control terminal 6A (sequence B9), the layer 3 switch 4A that performs path control of the IP packet In response to this, ARP (Address Resolution Protocol) notification information including at least the IP address of the own spare decoder 5Z (the IP address assigned to the working decoder 5i) and the MAC address of the own spare decoder 5Z is transmitted (sequence) B10).

  The layer 3 switch 4A that has received the ARP notification information uses the MAC address corresponding to the IP address of the decoder 5i and the transfer port in the data on the ARP table provided therein, and the MAC address of the spare decoder 5Z. The transfer port is rewritten (sequence B11). Thereby, in the layer 3 switch 4A, the IP packet originally transferred to the decoder 5i is switched to a state where it is transferred to the port of the spare decoder 5Z (sequence B12).

  Thus, when the operation of the working decoder 5i in the receiving station 5A becomes abnormal, the IP packet sent from the encoder 1i is operated normally instead of the decoder 5i whose operation is abnormal. Can be quickly switched to a state of being received by the spare decoder 5Z capable of being decoded, correctly decoded into a video signal, and output to the corresponding monitor 8i via the matrix switch 7A whose output is switched to the spare decoder 5Z side. Then, the video image based on the video signal is continuously displayed on the monitor 8i.

(Description of the effect of the second embodiment)
According to the second embodiment, as described in detail above, the receiving station 5A that receives a plurality of content information, for example, a plurality of IP packets encoded with video signals, includes a plurality of working-side decoders. 51,..., The IP of the IP packet to be distributed even when a (N + 1) spare redundant system including one spare decoder 5Z that can be commonly used as a spare is configured. In addition to the abnormalities at the layer level, the operation of any of the working side decoders 5i (1 ≦ i ≦ N) is abnormal in the receiving station 5A housing a plurality of working side decoders 51,. When the error occurs, the control of the supervisory control terminal 6A instantaneously switches the decoder 5i that has entered an abnormal operation to the normal spare decoder 5Z, and receives the received IP packet. Correctly decode the original content information, for example video signals, can be displayed on the screen in the corresponding monitor 8i an image based on the video signal.

  Similarly to the case of the first embodiment, when the decoder for decoding the received IP packet is switched from the working decoder 5i (1 ≦ i ≦ N) to the spare decoder 5Z, the IP set in the spare decoder 5Z Since the address (that is, the IP address assigned to the working decoder 5i) and the MAC address of the spare decoder 5Z are notified to the relay device on the network 3 side that controls the route of the IP packet, that is, the layer 3 switch 4A. Even in the case of the unicast distribution method, in the case where only the same IP address as that of the faulty working side decoder 5i (working side receiver) is set in the spare decoder 5Z (standby side receiver) Is the address resolution for route selection to the spare decoder 5Z in the layer 3 switch that controls the route of the IP packet. It is possible to solve the problem of cormorants it takes a long time because it is necessary.

  Further, the operation statuses of the plurality of working decoders 51,..., Decoder 5N and spare decoder 5Z accommodated in the receiving station 5A are monitored in order, and the working side and the spare side of the decoder to be used are monitored. Since the monitoring control terminal 6A for controlling the switching is provided, as in the case of the first embodiment, the switching can be performed more quickly than in the case where the decoders of the working decoder and the spare decoder perform mutual state monitoring. Control can be performed.

(Configuration of Third Embodiment)
Next, a configuration example of a video IP packet distribution system according to the third embodiment of the present invention will be described with reference to FIG. FIG. 5 is a block diagram showing a configuration example of a video IP packet distribution system according to the third embodiment of the present invention. A video IP packet distribution system 100B shown in FIG. 5 distributes content information, for example, a video signal as an IP palette from the content distribution server 1 and is stored in the receiving station 5B, like the IP distribution system 100 shown in FIG. After the decoder 51 decodes the video signal, the video based on the video signal is displayed on the monitor 8. However, unlike the IP distribution system 100 shown in FIG. 1, the video IP packet distribution system 100B shown in FIG. 5 starts from the standby side spare decoder 5Z when the working side decoder 51 of the receiving station 5B fails. Routing information for instructing rewriting of the routing table in the layer 3 switch (L3-SW) 4B instead of transmitting the ARP notification information to the layer 3 switch (L3-SW) 4B that performs route control of the IP packet The case where the rewrite control information is directly transmitted from the monitoring control terminal 6B to the layer 3 switch (L3-SW) 4B that performs path control is shown.

  That is, the video IP packet distribution system 100B shown in FIG. 5 is substantially the same as the configuration of the video IP packet distribution system 100 shown in FIG. 1, and the content distribution server 1, the receiving station 5B, the monitoring control terminal 6B, and the matrix switch 7 And at least the monitor 8. Also, the content distribution server 1 has an encoder 11 that converts content information such as a video signal into an IP packet, and the receiving station 5B receives a receiver (decoder) that decodes the IP packet into original content information such as a video signal and outputs it. As shown, a working side decoder 51 and a spare decoder 5Z are stored. Here, the receiver housed in the receiving station 5B is expressed as a decoder. And between the content distribution server 1 and the receiving station 5B, via the network 3 such as the Internet via the layer 3 switch (L3-SW) 2B and the layer 3 switch (L3-SW) 4B, respectively. Are connected to each other.

  The encoder 11 accommodated in the content distribution server 1 is an apparatus that converts the video signal of the content information into an IP packet and sends it to the receiving station 5B, regardless of whether or not the video signal of the content information is compressed / uncompressed. It is. Here, the encoder 11 unicasts the video material of each program from the content distribution server 1 as necessary.

  The IP packet transmitted from the content distribution server 1 is received by the receiving station 5B via the layer 3 switch 2B, the layer 3 switch 4B, and the network 3. The network 3 may be either a public line or a dedicated line, and is a network communication network conforming to the IP protocol for transferring IP packets.

  Each of the layer 3 switch 2B and the layer 3 switch 4B is a network relay device and performs route control by an IP address, and has a function of transferring a received IP packet to an output port corresponding to a target IP address. I have. The layer 3 switch 2B and the layer 3 switch 4B are devices that process the layer 3 protocol, and devices such as routers are also included in this class.

  The decoder 51 accommodated in the receiving station 5B depacketizes (deassembles) the IP packet received from the encoder 11, and then outputs the original content information, for example, a video signal to the matrix switch 7. The video signal output from the decoder 51 is input to the monitor 8 via the matrix switch 7, and the monitor 8 displays a video image based on the input video signal.

  The monitoring control terminal 6B is an information processing apparatus such as a personal computer, and is a monitoring terminal installed on the receiving station 5B side. The monitoring control terminal 6B can always monitor the operation status of the receiving station 5B by accessing the decoder 51 and the spare decoder 5Z, and has a function of controlling the receiving station 5B. The monitoring control terminal 6B also has a function of switching the outputs of the decoder 51 and the spare decoder 5Z and controlling the matrix switch 7 which is a switching means for inputting to the monitor 8 of the subsequent apparatus. Control to connect any output destination of the decoder 5Z to the monitor 8 is performed. Further, the monitoring control terminal 6B transmits routing information rewriting control information for instructing rewriting of the routing table in the layer 3 switch 4B to the layer 3 switch 4B that performs route control of the IP packet as necessary. Rewriting routing information for instructing to switch the forwarding destination of the IP packet from the working decoder 51 to the spare decoder 5Z when a failure of the working decoder 51 in the receiving station 5B is detected. Control information is directly transmitted to the layer 3 switch 4B, and the routing table in the layer 3 switch 4B is rewritten.

(Description of operation of the third embodiment)
Next, an example of the operation of the video IP packet distribution system 100B shown in FIG. 5 will be described in detail with reference to the sequence chart of FIG. FIG. 6 is a sequence chart for explaining an example of the operation of the video IP packet distribution system 100B in FIG. 5, and the decoder 51 accommodated in the layer 3 switch (L3-SW) 4B and the receiving station 5B in FIG. The operations of the spare decoder 5Z, the supervisory control terminal 6B, and the matrix switch 7 are shown.

  In the sequence chart of FIG. 6, as in the case of the first embodiment, the IP packet sent from the encoder 11 of the content distribution server 1 is converted into a layer 3 switch (L3-SW) 2B, a network as unicast distribution. 3. It is being received by the decoder 51 of the receiving station 5B via the layer 3 switch (L3-SW) 4B. Similarly to the case of the first embodiment, the monitoring control terminal 6B accesses the decoder 51 and the spare decoder 5Z at all times in a predetermined cycle in order to perform monitoring control of the receiving station 5B. (Sequences C1, C3).

  Then, the working side decoder 51 and the spare decoder 5Z responding to the access from the supervisory control terminal 6B return the respective operation statuses to the supervisory control terminal 6B, and the supervisory control terminal 6B performs the first implementation. As in the case of the embodiment, each operation status can be received (sequence C2, C4). Furthermore, the active side 51 can also voluntarily transmit the operation status to the monitoring control terminal 6B at a predetermined cycle or whenever the IP packet is decoded (sequence C5). . Information transmitted to the supervisory control terminal 6B as the operating status of the decoder 51 and the spare decoder 5Z is the respective device alarm / device status, setting parameter information, and the like.

  In the monitoring control terminal 6B, as a result of analysis of the received operation status, the N working-side decoders 51 cannot decode IP packets into video signals and output them to the monitor 8 due to a failure or the like. If it is determined (sequence C6), the same setting parameter as that of the failed decoder 51 is immediately set for the spare decoder 5Z (sequence C7) as in the case of the first embodiment. At this time, network parameters such as the IP address assigned to the working decoder 51 are also set in the spare decoder 5Z.

  Further, the supervisory control terminal 6B controls the matrix switch 7 to switch the input of the video signal to the monitor 8 from the active decoder 51 whose operation is abnormal to the output from the spare decoder 5Z (sequence C8).

  Thereafter, when the spare decoder 5Z taking over the setting parameters of the decoder 51 receives a control signal instructing the start of the IP packet reception operation from the supervisory control terminal 6B (sequence C9), unlike the case of the first embodiment, Instead of transmitting ARP (Address Resolution Protocol) notification information to the layer 3 switch 4B that performs route control of the IP packet, the state shifts to a reception waiting state for the IP packet from the layer 3 switch 4B (sequence C10).

  On the other hand, the supervisory control terminal 6B switches the routing table held in the layer 3 switch 4B from the routing information to the working decoder 51 to the routing information to the spare decoder 5Z for the layer 3 switch 4B. Routing information rewriting control information for instructing this is transmitted (sequence C11).

  The layer 3 switch 4B that has received the routing information rewrite control information sets the transfer port corresponding to the IP address of the decoder 51 in the data on the routing table provided therein to the transfer port of the spare decoder 5Z. (Sequence C12). Thereby, in the layer 3 switch 4B, the IP packet originally transferred to the decoder 51 is switched to a state where it is transferred to the port of the spare decoder 5Z (sequence C13).

  Thus, when the operation of the working decoder 51 in the receiving station 5B becomes abnormal, the IP packet sent from the encoder 11 is operated normally instead of the decoder 51 whose operation is abnormal. Is quickly switched to a state of being received by the spare decoder 5Z capable of being decoded, correctly decoded into a video signal, and output to the monitor 8 via the matrix switch 7 whose output is switched to the spare decoder 5Z side, The video by the video signal is continuously displayed on the monitor 8.

(Description of the effect of the third embodiment)
According to the third embodiment, as described in detail above, not only the same effect as in the case of the first embodiment is obtained, but also the layer 3 switch 4B that performs route control of the IP packet. Is not performed by the spare decoder 5Z of the receiving station 5B, but by the supervisory control terminal 6B, the spare decoder 5Z of the receiving station 5B uses the address for the layer 3 switch 4B. It is not necessary to specially implement the ARP notification function for performing information change notification, and the receiving station 5B can be simplified.

The configuration of the preferred embodiment of the present invention has been described above. However, it should be noted that such examples are merely illustrative of the invention and do not limit the invention in any way. Those skilled in the art will readily understand that various modifications and changes can be made according to a specific application without departing from the gist of the present invention. For example, the embodiment of the present invention can be expressed as the following configuration in addition to the configuration (1) in the means for solving the problems.
(2) The monitoring control terminal monitors the operating state of the working side receiver and the standby side receiver of the receiving station, and detects the subsequent IP packet when an abnormal operation is detected. Routing information rewriting control information for instructing rewriting of a routing table in the layer 3 switch instead of transmitting the ARP notification information to the layer 3 switch by controlling the receiver to be received. The IP packet distribution system according to (1), wherein the monitoring packet is directly transmitted to the layer 3 switch from the monitoring control terminal.
(3) The receiving station receives, as the working side receiver, a plurality of working side receptions that receive each of a plurality of delivered IP packets and decode and output the original content information. The IP packet distribution system according to (1) or (2), wherein the standby receiver can be commonly used for backup with respect to each of the plurality of active receivers.
(4) The monitoring control terminal further includes switching means for switching the output of the working-side receiver and the backup-side receiver of the receiving station and inputting the output to a subsequent apparatus. The operating state of the working side receiver and the standby side receiver is monitored, and when an abnormal operation is detected, the switching means is controlled to receive the subsequent IP packet. The IP packet distribution system according to any one of (1) to (3), wherein the output from the receiver is controlled to be input to the subsequent device.
(5) Receiver switching method for switching a receiver that receives a distributed IP packet, decodes it into original content information, and outputs it in an IP packet distribution system that converts content information into IP packets and distributes them via a network The monitoring control includes a working-side receiver and a backup-side receiver as the receiver, and further monitors and controls operating states of the working-side receiver and the backup-side receiver. A receiver that is to receive subsequent IP packets among the working-side receiver and the backup-side receiver when the monitoring control terminal detects an abnormality in the operation of the receiver. A switching device on the network side that controls the receiver that should receive the IP packet and controls the route of the IP packet to the receiving station. Layer for the three switches, the address including at least ARP (Address Resolution Protocol) receiver switching method for transmitting notification information address information about the receiver should receive the IP packet as information for solving that.
(6) The monitoring control terminal monitors the operating state of the working side receiver and the standby side receiver of the receiving station, and detects the subsequent IP packet when an abnormal operation is detected. Routing information rewriting control information for instructing rewriting of a routing table in the layer 3 switch instead of transmitting the ARP notification information to the layer 3 switch by controlling the receiver to be received. (5) The receiver switching method according to (5) above, in which the monitoring control terminal directly transmits to the layer 3 switch.
(7) The working side receiver includes a plurality of working side receivers that receive each of a plurality of delivered IP packets, decode the original content information, and output the content information; The receiver switching method according to (5) or (6) above, wherein the standby receiver can be used in common as a spare for each of the plurality of active receivers.
(8) It further comprises switching means for switching the output of the working side receiver and the standby side receiver and inputting the output to the subsequent apparatus, and the monitoring control terminal is configured to switch the working side of the receiving station. When the operation state of the receiver and the standby receiver is monitored and an abnormal operation is detected, the switching means is controlled to receive the subsequent IP packet from the receiver. The receiver switching method according to any one of the above (5) to (7), wherein the output is controlled to be input to the subsequent apparatus.
(9) A receiver switching program in which the receiver switching method according to any one of (5) to (8) is implemented as a program executable by a computer.
(10) A program recording medium in which the receiver switching program of (9) is recorded on a computer-readable recording medium.

1 Content distribution server 1A Content distribution server 2 Layer 3 switch (L3-SW)
2A Layer 3 switch (L3-SW)
2B Layer 3 switch (L3-SW)
3 Network 4 Layer 3 switch (L3-SW)
4A Layer 3 switch (L3-SW)
4B Layer 3 switch (L3-SW)
5 receiving station 5A receiving station 5B receiving station 6 monitoring control terminal 6A monitoring control terminal 6B monitoring control terminal 7 matrix switch 7A matrix switch 8 monitor 8A monitor group 11 encoder 1N encoder 51 decoder 5N decoder 5Z spare decoder 81 monitor 8N monitor 100 video IP Packet distribution system 100A Video IP packet distribution system 100B Video IP packet distribution system

Claims (10)

  In an IP packet distribution system that converts content information into IP packets and distributes them via a network, a receiver on the working side and a standby side as receivers that receive the distributed IP packets and decode and output the original content information A receiver station, further monitoring the operating state of the receiver on the working side and the receiver on the standby side of the receiver station, and detecting an abnormal operation, Controlling switching to the receiver that should receive the subsequent IP packet, among the receiver on the side and the spare side receiver, and controlling the receiver that should receive the subsequent IP packet, Receives the IP packet as information for address resolution to the layer 3 switch, which is a relay device on the network side that controls the route of the IP packet to the receiving station IP packet delivery system characterized by comprising a monitoring control terminal having at least a function to transmit at least containing ARP (Address Resolution Protocol) notification information address information on the receiver to.   The supervisory control terminal should monitor the operating state of the working side receiver and the standby side receiver of the receiving station and receive the subsequent IP packets when an abnormal operation is detected. Instead of causing the layer 3 switch to transmit the ARP notification information by controlling the receiver, routing information rewriting control information for instructing rewriting of a routing table included in the layer 3 switch, 2. The IP packet distribution system according to claim 1, wherein the IP packet distribution system transmits directly to the layer 3 switch from the monitoring control terminal.   The receiving station includes, as the working receiver, a plurality of working receivers that receive each of a plurality of delivered IP packets, decode the original content information, and output the decoded content information. 3. The IP packet distribution system according to claim 1, wherein the spare side receiver can be commonly used as a spare for each of the plurality of working side receivers.   The monitoring control terminal further comprises switching means for switching the output of the receiver on the working side and the receiver on the standby side of the receiving station and inputting the output to a subsequent device, and the monitoring control terminal is configured to switch the working of the receiving station. The operating state of the receiver on the side and the receiver on the backup side is monitored, and when an abnormal operation is detected, the switching means is controlled to receive the subsequent IP packet from the receiver The IP packet distribution system according to any one of claims 1 to 3, wherein the output is controlled to be input to the device at a subsequent stage.   In an IP packet distribution system that converts content information into IP packets and distributes them via a network, a receiver switching method for switching a receiver that receives a distributed IP packet, decodes it to the original content information, and outputs it A receiver on the active side and a receiver on the standby side as the receiver, and a monitoring control terminal for monitoring and controlling the operating state of the receiver on the active side and the receiver on the standby side When the monitoring and control terminal detects an abnormality in the operation of the receiver, switching to the receiver that should receive the subsequent IP packet among the working-side receiver and the backup-side receiver And a relay device on the network side that controls the receiver that should receive the IP packet and controls the route of the IP packet to the receiving station. A receiver switching method, characterized in that ARP (Address Resolution Protocol) notification information including at least address information related to the receiver that is to receive the IP packet is transmitted as information for address resolution to the group 3 switch. .   The supervisory control terminal should monitor the operating state of the working side receiver and the standby side receiver of the receiving station and receive the subsequent IP packets when an abnormal operation is detected. Instead of causing the layer 3 switch to transmit the ARP notification information by controlling the receiver, routing information rewriting control information for instructing rewriting of a routing table included in the layer 3 switch, 6. The receiver switching method according to claim 5, wherein the monitoring control terminal directly transmits to the layer 3 switch.   The active-side receiver includes a plurality of active-side receivers that receive each of a plurality of delivered IP packets, decode the original content information, and output the content information. The receiver switching method according to claim 5 or 6, wherein the receiver can be commonly used as a spare for each of the plurality of working-side receivers.   The monitoring control terminal further includes switching means for switching the output of the working receiver and the standby receiver and inputting the output to a subsequent apparatus, and the monitoring control terminal is configured to receive the working receiver of the receiving station. And monitoring the operating state of the receiver on the standby side, and detecting an abnormal operation, the switching means is controlled, and the output from the receiver that is to receive the subsequent IP packet, The receiver switching method according to any one of claims 5 to 7, wherein control is performed so that the device in the subsequent stage is input.   9. A receiver switching program, wherein the receiver switching method according to claim 5 is implemented as a program executable by a computer.   A program recording medium, wherein the receiver switching program according to claim 9 is recorded on a computer-readable recording medium.

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