JP2014053790A - Transmitter and transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmitter and a transmission system which can prevent reduction in the error rate by performing error correction of the header part of a packet, when transmitting a time-division multiplex signal while packetizing, thereby reducing destruction of a payload portion.SOLUTION: A transmitter includes a packet assembly section generating a packet having a payload portion for storing the data of time-division multiplex signal and a header portion for storing the transmission control information of data, an error correction code adding section generating an error correction code for the header portion and adding it to a packet, a packet transmission section for transmitting a packet outputted from the error correction code adding section to a packet network, a packet reception section for receiving a packet from the packet network, an error correction section performing error correction of the header portion of the packet by extracting an error correction code added to a packet received by the packet reception section, and a packet disassembly section for restoring the data stored in the payload portion of a packet subjected to error correction in the error correction section to a time-division multiplex signal.

Description

  The present invention relates to a transmission apparatus and a transmission system.

  In recent years, with the development of network technology, packet networks are rapidly spreading. On the other hand, there is a demand for a system in which an SDH / SONET signal of a time division multiplex transmission line is packetized and transmitted through a packet network (for example, see Patent Document 1). Here, SDH is an abbreviation of Synchronous Digital Hierarchy (synchronous digital hierarchy), and SONET is an abbreviation of Synchronous Optical NETwork (synchronous optical transmission network). A method for packetizing the SDH / SONET signal using CEP (Circuit Emulation Over Packet) is defined in IETF (Internet Engineering Task Force) RFC4842.

JP 2011-040992 A

  In the conventional technique, when an error is detected by FCS (Frame Check Sequence) processing when an SDH / SONET signal is converted into a CEP packet and transmitted, the transmission apparatus discards the packet. In this case, when the transmission apparatus on the receiving side restores the CEP packet to the SDH / SONET frame, it processes all data stored in the discarded packet as a block error. As described above, in the SDH / SONET transmission line, all data stored in the packet is discarded in the packet network even if an error that can be handled as a part of bit errors occurs. For this reason, there is a problem that the error rate in the packet network is worse than the error rate in the SDH / SONET transmission path.

  An object of the present invention is to provide a transmission apparatus and transmission capable of reducing the discard of the payload portion by correcting the error of the header portion of the packet and preventing the error rate from being lowered when the time division multiplexed signal is packetized and transmitted. Is to provide a system.

  A transmission apparatus according to one aspect includes a packet assembly unit that generates a packet including a payload unit that stores data of time division multiplexed signals, a header unit that stores data transmission control information, and an error correction code for the header unit. An error correction code adding unit that generates and adds to the packet, a packet transmission unit that transmits a packet output from the error correction code adding unit to the packet network, a packet reception unit that receives the packet from the packet network, and a packet reception The error correction unit that extracts the error correction code added to the received packet and corrects the header of the packet, and the data stored in the payload part of the packet that has been corrected by the error correction unit And a packet decomposing unit that restores the multiplexed signal.

  A transmission system according to one aspect includes a packet assembly unit that generates a packet in which data of a time division multiplexed signal input from a time division multiplexing line is stored in a payload portion and data transmission control information is stored in a header portion, and a header portion An error correction code adding unit that generates an error correction code for the packet and adds the error correction code to the packet; a transmission device on the transmission side having a packet transmission unit that transmits the packet output from the error correction code addition unit to the packet network; A packet receiving unit that receives a packet transmitted by the transmission apparatus, an error correcting unit that extracts an error correction code added to the packet received by the packet receiving unit and corrects an error in the header of the packet, and an error correction The data stored in the payload part of the packet whose error is corrected by the unit is restored to the time division multiplexed signal and output to the time division multiplexed line. And having an a transmission apparatus on the receiving side with a part.

  In the transmission apparatus and transmission system according to the present invention, when time division multiplexed signals are packetized and transmitted, the header portion of the packet is error-corrected to reduce the discard of the payload portion and prevent the error rate from being lowered. it can.

It is a figure showing an example of transmission system 100 concerning this embodiment. It is a figure which shows the mode at the time of the error generation in SDH / SONET. It is a figure which shows the mode at the time of the error generation in the conventional CEP packet transmission. It is a figure which shows the format example of a packet. It is a figure which shows an example of the transmission apparatus 101 which concerns on this embodiment. It is an example of a flowchart which shows the reception process of the transmission apparatus 101 which concerns on this embodiment. It is a figure which shows the example of a flowchart which shows the flow of the conventional receiving process.

  Hereinafter, embodiments of the present disclosure will be described in detail.

  FIG. 1 is a diagram illustrating an example of a transmission system 100 according to the present embodiment. In the example of FIG. 1, the transmission system 100 includes a transmission apparatus 101 a connected to a TDM (time division multiplexing) line and a transmission apparatus 101 b connected to another TDM line via the packet network 102. Here, in the following description, when the matters common to the transmission apparatus 101a and the transmission apparatus 101b are described, the alphabet symbol at the end of the code is omitted and the transmission apparatus 101 is represented. In addition, when a specific transmission apparatus 101 is indicated, an alphabetic symbol is added to represent the transmission apparatus 101, for example, as a transmission apparatus 101a. Similarly, other blocks with the same name (such as the SDH / SONET transmission apparatus 201) are also expressed in the same rule.

  In this embodiment, an SDH / SONET line is assumed as the TDM line, but another TDM line such as an OTN (Optical Transport Network) may be used.

  In FIG. 1, a transmission apparatus 101 a packetizes a TDM signal input from an SDH / SONET line 103 and outputs the packet to the packet network 102. The transmission apparatus 101 b receives the packetized TDM signal via the packet network 102 and outputs it to the SDH / SONET line 104. Similarly, the transmission apparatus 101b packetizes the TDM signal input from the SDH / SONET line 104 and outputs it to the packet network 102. The transmission apparatus 101a receives the packetized TDM signal and transmits it to the SDH / SONET line 103. Output. In this manner, in the transmission system 100 according to the present embodiment, the packet network 102 can relay between the SDH / SONET line 103 and the SDH / SONET line 104. The packet network 102 is a network using, for example, 10GE Ethernet (registered trademark). In FIG. 1, only two transmission apparatuses 101, the transmission apparatus 101a and the transmission apparatus 101b, are connected via the packet network 102, but a plurality of transmission apparatuses 101 having similar functions are connected to the packet network 102. Has been.

  FIG. 2 is a diagram illustrating a situation when an error occurs when the SDH / SONET transmission apparatus 201a and the SDH / SONET transmission apparatus 201b are connected via the SDH / SONET line 202. In the example of FIG. 2, an SDH / SONET frame 250 is transmitted from the SDH / SONET transmission apparatus 201b to the SDH / SONET transmission apparatus 201a via the SDH / SONET line 202. Here, the SDH / SONET frame 250 includes control data 251a in which information such as an SDH / SONET operation state and error monitoring is stored, and a payload 251b in which user data is stored.

  In FIG. 2, it is assumed that an error has occurred in the SDH / SONET line 202 during transmission of the SDH / SONET frame 250 from the SDH / SONET transmission apparatus 201b to the SDH / SONET transmission apparatus 201a. In this case, a bit error 252 is included in the SDH / SONET frame 250a received by the SDH / SONET transmission apparatus 201a.

  Here, a signal degradation detection method in SDH / SONET will be described. Note that the signal degradation detection method in SDH / SONET is described in ITU-T G.264. 707 / Telcordia GR-253-CORE. In SDH / SONET, a code error is monitored using B1 / B2 bytes arranged in a section overhead in order to monitor transmission quality. This monitoring method is called BIP (Bit Interleaved Parity). Specifically, the transmitting device inserts the calculation result of each predetermined calculation range of the SDH / SONET frame into the B1 / B2 byte of the next frame, and the receiving device stores it in B1 / B2. The transmission quality is monitored by comparing the calculation result with the received frame. By this monitoring, the transmission apparatus 101 calculates a BER (Bit Error Rate), and can determine that the transmission line is faulty or quality is deteriorated if the BER exceeds a set threshold value. Note that the thresholds of transmission line failure and transmission line quality degradation are described in ITU-T G. 806.

  On the other hand, in the Ethernet frame error detection method, a CRC (Cyclic Redundancy Check) value is obtained from each value of each field such as a destination address, a source address, a length / type, and data. Then, the device on the transmission side sets the CRC value in the FCS field of the packet and transmits it, and also obtains the CRC value in the same way on the reception side, and the calculated CRC value and the value of the FCS field of the received packet do not match Determines that an error has occurred and discards the frame. For this reason, there is a problem that the error rate when the SDH / SONET frame is expanded into CEP packets and transmitted over the packet network is significantly lower than when the SDH / SONET line is transmitted over the SDH / SONET line.

  This problem will be specifically described with reference to FIG. FIG. 3 shows a state in which an error occurs in the packet network 102 when the conventional transmission apparatus 901a and the transmission apparatus 901b packetize the SDH / SONET signal and transmit it through the packet network 102. In FIG. 3, the same reference numerals as those in FIGS. 1 and 2 denote the same components.

  In FIG. 3, an SDH / SONET frame 250 transmitted from the SDH / SONET transmission apparatus 201b is converted into a packet 300 by the transmission apparatus 901b and output to the packet network 102. Here, the packet 300 has a header 301a, a payload 301b, and an FCS bit 301c. The portion of the payload 251b of the SDH / SONET frame 250 is divided into a plurality of data according to the CEP standard, stored in the payload 301b of the packet 300, and transmitted. At this time, since the sequence number is added to the header 301a of the packet 300, the transmission apparatus 901a on the receiving side can restore the plurality of divided data to the payload 251b of the SDH / SONET frame 250.

  Here, it is assumed that an error occurs during transmission in the packet network 102 and a bit error 302 occurs in the payload 301b of the packet 300. In this case, since the received packet 300 includes the bit error 302, the transmission apparatus 901a detects the packet error by checking the FCS bit 301c, and discards the packet 300. Then, according to the CEP rules, the transmission apparatus 901a outputs all “1” data to the SDH / SONET transmission apparatus 201a. Accordingly, the transmission apparatus 901a that has received the packet 300 including the bit error 302 generates an SDH / SONET frame 250b by replacing all the portions of the packet 300 with data of “1”, and outputs the SDH / SONET transmission apparatus 201a. . As described above, due to the bit error 302 in the packet network 102, the transmission apparatus 901a discards all data in the payload 301b including data that has no error that can be used in the SDH / SONET transmission apparatus on the receiving side. The rate will be reduced.

  Next, an example of a packet transmitted through the packet network 102 will be described with reference to FIG. FIG. 4A shows a format example of a general MPLS (Multi-Protocol Label Switching) labeled L2 packet 300 transmitted by 10GE Ethernet. The packet 300 includes a header 301a, a payload 301b, and an FCS bit 301c. The header 301a includes information such as a destination address (DA), a transmission source address (SA), a type indicating the type of packet (Type), an MPLS label, and the like. Then, check data for detecting an error in the header 301a and the payload 301b is stored in the FCS bit 301c. The transmission apparatus 101 in FIG. 1 or the transmission apparatus 901 in FIG. 3 checks the FCS bit when receiving a normal L2 packet 300, and discards the packet 300 if an error is detected in the header 301a and the payload 301b.

  FIG. 4B shows a format example of a general CEP packet 300a when an SDH / SONET frame is packetized and transmitted by 10GE Ethernet. The packet 300a has a header 301a1, a payload 301b, and an FCS bit 301c. The header 301a1 of the CEP packet 300a stores a CEP header in addition to the information of the header 301a of FIG. The CEP header has control information such as a sequence number for restoring the SDH / SONET frame. Then, check data for detecting an error between the SDH / SONET frame data stored in the payload 301b and the header 301a1 is stored in the FCS bit 301c. 3 receives the CEP packet 300a, checks the FCS bit, and when an error is detected in the header 301a and the payload 301b, the packet 300a is discarded. On the other hand, in the transmission apparatus 101 according to this embodiment of FIG. 1, as shown in FIG. 4C, a header error correction code (redundant bit) having an error correction range in the header 301a of the CEP packet 300a. Is generated. Then, as illustrated in FIG. 4D, the transmission apparatus 101 inserts the generated error correction code into the payload 301b to form a payload 301b1, and generates a CEP packet 300b having a header 301a1, a payload 301b1, and an FCS bit 301c. To do. Although FIG. 4D shows an example in which the error correction code is added to the head part of the payload 301b1, the rear part of the payload 301b1 may be used as long as it is a predetermined position.

  As described above, in the transmission system 100 according to the present embodiment, the error correction code of the header 301a1 portion of the CEP packet 300b is stored in the payload 301b1 and transmitted. 4A to 4D, the FCS bit 301c has the same sign, but the packet 300, the packet 300a to which the CEP header is added, and the packet 300b to which the header error correction code is further added. And the value stored in the FCS bit 301c is different. In FIG. 4, DA, SA, Type, MPLS label, and CEP header are described as header information, but an RTP (Realtime Transport Protocol) header of the CEP packet is also stored.

  Next, an example of the transmission apparatus 101 according to the present embodiment will be described with reference to FIG. In FIG. 5, the transmission apparatus 101 includes an SDH / SONET_IF (interface) 151, a CEP_IF (interface) 152, a switch 153, and a 10GE_IF (interface) 154.

  The SDH / SONET_IF 151 is an interface for connecting to a TDM line such as an SDH / SONET line, and includes a TDM receiving unit 161 and a TDM transmitting unit 162. The TDM receiver 161 receives the SDH / SONET signal from the SDH / SONET line and outputs the SDH / SONET frame to the CEP_IF 152. Conversely, the TDM transmission unit 162 receives an SDH / SONET frame from the CEP_IF 152 and transmits an SDH / SONET signal to the SDH / SONET line.

  The CEP_IF 152 is an interface for converting an SDH / SONET frame and a CEP packet, and includes a CEP assembly unit 163 and a CEP decomposition unit 164. The CEP assembling unit 163 divides the SDH / SONET frame input from the SDH / SONET_IF 151 to assemble a CEP packet and outputs the CEP packet to the switch 153. The CEP decomposition unit 164 decomposes the CEP packet input from the switch 153 to generate an SDH / SONET frame, and outputs the SDH / SONET_IF 151 to the SDH / SONET_IF 151. Here, the CEP packet input / output between the CEP_IF 152 and the switch 153 corresponds to the packet 300a illustrated in FIG.

  The switch 153 performs a process of switching the transfer destination according to the destination of the packet input from the CEP_IF 152 or 10GE_IF 154. For example, the transmission apparatus 101 transmits a packet other than the CEP packet input from the 10GE_IF 154 to the packet network 102 from the 10GE_IF 154 again according to the destination. Alternatively, the transmission apparatus 101 outputs the CEP packet input from the 10GE_IF 154 to the CEP_IF 152 when it is addressed to the own apparatus, and transmits the CEP packet to the packet network 102 from the 10GE_IF 154 again when addressed to another apparatus. In this embodiment, the description will focus on the operation of the transmission apparatus 101 that converts an SDH / SONET frame into a CEP packet, transmits the received CEP packet, and converts the received CEP packet into an SDH / SONET frame. The detailed explanation is omitted.

  The 10GE_IF 154 is an interface for connecting to the 10GE Ethernet packet network 102, and includes a packet transmission unit 167 and a packet reception unit 168. Furthermore, in this embodiment, the transmission apparatus 101 includes a correction code addition unit 165 and an error correction unit 166.

  The packet transmission unit 167 receives the CEP packet from the switch 153 and transmits it to the packet network 102. Conversely, the packet receiver 168 receives the CEP packet from the packet network 102 and outputs it to the switch 153.

  The correction code adding unit 165 generates and adds an error correction code for correcting an error in the header part of the CEP packet input from the CEP_IF 152 via the switch 153. At this time, the correction code adding unit 165 recalculates the value of the FCS bit when adding the error correction code. In addition, the error correction unit 166 performs error correction of the header portion of the CEP packet received from the packet network 102, deletes the header error correction code that is a redundant portion, and outputs the header error correction code to the CEP_IF 152 via the switch 153. Alternatively, if error correction cannot be performed, the error correction unit 166 sets all payload portions to “1” and outputs the result to the CEP_IF 152 or notifies the CEP_IF 152 that error correction cannot be performed. In this case, the CEP assembling unit 163 of the CEP_IF 152 sets all data corresponding to the packet of the SDH / SONET frame to “1”. Actually, since general L2 packets other than the CEP packet also flow through the packet network 102, the error correction unit 166 also determines whether or not the packet received from the packet network 102 is a CEP packet. . Then, when the received packet is not a CEP packet, the error correction unit 166 performs error detection by checking the FCS bit, and discards the packet when there is an error. Further, any method for generating an error correction code may be used as long as it is a well-known technique, and a detailed description thereof will be omitted. Here, the CEP packet transmitted / received to / from the packet network 102 corresponds to the packet 300b shown in FIG.

  In this way, in the transmission system 100 according to the present embodiment, an error correction code for correcting an error in the header portion of the CEP packet is added and transmitted onto the packet network 102. Then, even when there is an error in the header part of the CEP packet, the transmission apparatus 101 can transmit the corrected error without correcting the packet. Thereby, the transmission system 100 can suppress a decrease in error rate when the time division multiplexing line is emulated between the SDH / SONET transmission apparatuses by the packet network 102. If the error in the header part of the CEP packet cannot be corrected, the transmission apparatus 101 discards the packet as in the conventional case, but is discarded when there is an error in either the header part or the payload part. Compared with the conventional method, the decrease in error rate can be suppressed.

  Next, the flow of reception processing in the transmission apparatus 101 will be described. Note that, as described with reference to FIG. 4, the transmission process is merely a process of generating and transmitting the CEP packet 300b to which the error correction code of the header 301a1 of the conventional CEP packet 300a is added.

  FIG. 6 is a flowchart showing a processing flow when the transmission apparatus 101 receives a packet from the packet network 102. 6 is a process performed by the packet reception unit 168, the error correction unit 166, the CEP decomposition unit 164, and the TDM transmission unit 162 of FIG.

  (Step S <b> 101) The packet receiving unit 168 waits until a packet is received from the packet network 102. Then, when receiving the packet, the packet receiving unit 168 proceeds to the process of step S102.

  (Step S102) The packet receiving unit 168 determines whether or not the received packet is a CEP packet. If it is not a CEP packet, the packet receiver 168 proceeds to the process of step S103, and if it is a CEP packet, the packet receiver 168 proceeds to the process of step S106. Note that the packet receiving unit 168 determines whether the packet is a CEP packet based on the CEP header of the CEP packet 300b illustrated in FIG. For example, a packet without a CEP header is a normal packet, and a packet with a CEP header is a CEP packet.

  (Step S103) The packet receiver 168 checks the FCS bit of the received packet. For example, since the packet 300 in FIG. 4A is not a CEP packet, the packet receiving unit 168 detects an error in the header 301a and the payload 301b using the FCS bit 301c. The packet receiving unit 168 proceeds to the process of step S104 when an error is detected in the header 301a and the payload 301b, and proceeds to the process of step S105 when no error is detected.

  (Step S104) The packet receiving unit 168 discards the packet in which the error is detected by checking the FCS bit, returns to step S101, and waits until the next packet is received.

  (Step S <b> 105) The packet reception unit 168 outputs to the switch 153 a packet for which no error has been detected by checking the FCS bit. Then, the packet reception unit 168 transfers the packet again from the packet transmission unit 167 to the packet network 102 according to the destination of the packet.

  Here, the processing from step S103 to step S105 described above is normal packet processing when the received packet is not a CEP packet. When the received packet is a CEP packet, the transmission apparatus 101 performs the following processing.

  (Step S106) When the packet received by the packet receiving unit 168 is a CEP packet, the error correcting unit 166 determines whether there is a header error. Specifically, in the CEP packet 300b of FIG. 4, the error correction unit 166 extracts a header error correction code at a predetermined head portion of the payload 301b1, and determines whether or not there is an error in the header 301a1. . The error correction unit 166 proceeds to the process of step S107 when the error of the header 301a1 is detected, and proceeds to the process of step S109 when the error is not detected.

  (Step S107) The error correction unit 166 determines whether or not error correction of the header 301a1 in which an error is detected is possible. For example, when the number of bits that can be corrected with the error correction code is 2 bits, the error correction unit 166 can correct the error when the error of the header 301a1 is 2 bits or less, and when the error is 3 bits or more, Judge that error correction is impossible. The error correction unit 166 proceeds to the process of step S108 when the error correction of the header 301a1 is possible, and proceeds to the process of step S110 when the error correction is impossible.

  (Step S108) The error correction unit 166 performs error correction of the header 301a1.

  (Step S109) The error correction unit 166 outputs the CEP packet in which the error of the header 301a1 is not detected or the CEP packet in which the error of the header 301a1 is corrected to the CEP decomposition unit 164 of the CEP_IF 152 via the switch 153. The CEP decomposition unit 164 decomposes the CEP packet input from the 10GE_IF 154 via the switch 153, generates an SDH / SONET frame, and outputs the SDH / SONET frame to the TDM transmission unit 162. The TDM transmission unit 162 converts the SDH / SONET frame input from the CEP decomposition unit 164 into an SDH / SONET signal synchronized with TDM, and transmits the SDH / SONET signal to the SDH / SONET line.

  If the transmission apparatus 101 is not the transmission apparatus that is the destination of the CEP packet, the transmission apparatus 101 transfers the CEP packet to the packet network 102 again by the switch 153. Then, returning to the process of step S101, the packet receiving unit 168 waits until the next packet is received.

  (Step S110) The error correction unit 166 discards the CEP packet 300b in which the error of the header 301a1 cannot be corrected. Then, the error correction unit 166 notifies the CEP decomposition unit 164 that the CEP packet is discarded.

  (Step S111) Upon receiving a CEP packet discard notification from the error correction unit 166, the CEP decomposition unit 164 replaces all data portions of the CEP packet with “1” to generate an SDH / SONET frame, and generates a TDM transmission unit. It outputs to 162. The TDM transmission unit 162 converts the SDH / SONET frame input from the CEP decomposition unit 164 into an SDH / SONET signal synchronized with TDM, and transmits the SDH / SONET signal to the SDH / SONET line. Since the SDH / SONET frame is divided into a plurality of CEP packets and transmitted as described with reference to FIG. 3, the CEP decomposing unit 164 combines the data of the plurality of CEP packets according to the sequence number of the CEP header. An SDH / SONET frame is generated.

  In this manner, the transmission system 100 according to the present embodiment adds an error correction code for correcting an error in the header portion of the CEP packet and transmits the packet network 102. Then, even when there is an error in the header part of the CEP packet, the transmission apparatus 101 can transmit the corrected error without correcting the packet. Thereby, the transmission system 100 can suppress a decrease in error rate when the packet network 102 emulates between SDH / SONET transmission apparatuses.

  Here, CEP packet reception processing in the conventional transmission apparatus 901 in FIG. 3 will be described with reference to FIG. 7 so that the characteristics of the transmission system 100 according to this embodiment can be easily understood. In FIG. 7, processes having the same reference numerals as those in FIG. 6 are denoted by the same step numbers.

  In FIG. 7, the transmission apparatus 901 waits until a packet is received in step S101, and checks the FCS bit of the packet received in the next step S103. Here, the transmission apparatus 901 is different from the transmission apparatus 101 of FIG. 6 in that the FCS bit is checked for all received packets including the CEP packet in the process of step S103. In the case of FIG. 6, the transmission apparatus 101 determines whether or not it is a CEP packet in step S102, and checks the FCS bit only for packets other than the CEP packet. As a result, the CEP packet is not discarded by the FCS bit check, but in the case of FIG. 7, the CEP packet is discarded when an error due to the FCS bit check is detected in the process of step S104. Will be. In step S111, the transmission device 901 replaces all the data in the payload 301b including the error-free data that can be used by the receiving-side SDH / SONET transmission device with the data “1”. This causes a significant decrease in the error rate between the transmission apparatuses. If no FCS bit error is detected in step S103, the transmission apparatus 901 transfers data other than the CEP packet and the CEP packet in step S105.

  As described above, the transmission system 100 according to the present embodiment corrects the data in the payload portion by correcting the error in the header portion of the CEP packet, and reduces the error rate in the packet network that relays between the SDH / SONET transmission devices. Can be prevented.

  As described above, in the transmission system 100 according to the present embodiment, when time-division multiplexed signals are packetized and transmitted, the header portion of the packet is error-corrected to reduce the discard of the payload portion, and the error rate Can be prevented. In particular, the transmission apparatus 101 transmits the packet to the SDH / SONET transmission apparatus 201 regardless of whether or not there is an error in the payload portion when there is no error in the header portion of the packet and when error correction of the header portion is possible. As a result, the data in the payload portion that has been discarded when there is an error in the payload portion in the conventional transmission apparatus 901 is always transmitted to the SDH / SONET transmission apparatus 201, so that it is used on the SDH / SONET transmission apparatus 201 side. It becomes possible.

  As described above, the transmission device and the transmission system of the present disclosure reduce the discard of the payload portion by correcting the error of the header portion of the packet and reduce the error rate when the time division multiplexed signal is transmitted in packets. Can be prevented.

  From the above detailed description, features and advantages of the embodiments will become apparent. This is intended to cover the features and advantages of the embodiments described above without departing from the spirit and scope of the claims. Further, any person having ordinary knowledge in the technical field should be able to easily come up with any improvements and modifications, and there is no intention to limit the scope of the embodiments having the invention to those described above. It is also possible to rely on suitable improvements and equivalents within the scope disclosed in.

DESCRIPTION OF SYMBOLS 100 ... Transmission system; 101,901 ... Transmission apparatus; 102 ... Packet network; 103 ... SDH / SONET line; 104 ... SDH / SONET line; 151 ... SDH / SONET_IF; ... CEP_IF; 153... Switch; 154... 10GE_IF; 161... TDM receiver; 162... TDM transmitter; ... Correction code adding section; 166 ... Error correcting section; 167 ... Packet transmitting section; 168 ... Packet receiving section; 201 ... SDH / SONET transmission apparatus; 202 ... SDH / SONET line

Claims (8)

A packet assembling unit for generating a packet having a payload part for storing data of time division multiplexed signals and a header part for storing transmission control information of the data;
Generating an error correction code for the header part and adding the error correction code to the packet;
A packet transmission unit that transmits the packet output by the error correction code adding unit to a packet network;
A packet receiver for receiving the packet from the packet network;
An error correction unit that performs error correction of the header portion of the packet by extracting the error correction code added to the packet received by the packet reception unit;
A transmission apparatus comprising: a packet decomposing unit that restores data stored in the payload portion of the packet error-corrected by the error correcting unit to a time division multiplexed signal. The transmission apparatus according to claim 1,
The error correction code adding unit stores an error correction code for the header unit in the payload unit,
The transmission apparatus, wherein the error correction unit extracts the error correction code stored in the payload portion of the packet received by the packet reception unit, and performs error correction of the header portion of the packet. The transmission apparatus according to claim 1 or 2,
The error correction code adding unit adds an error detection code for detecting an error to the entire packet including the payload portion and the header portion to the packet,
When the error correction unit detects an error by the error detection code of the packet received by the packet reception unit, the error correction unit extracts the error correction code stored in the payload unit and causes the error of the packet. It is determined whether or not it is the header part, and when the header part is the cause, the error of the header part is corrected by the error correction code, and when the header part is not the cause or by the error correction code A transmission device characterized by discarding the packet if it cannot be corrected. The transmission apparatus according to any one of claims 1 to 3,
The time division multiplexed signal is an SDH / SONET signal,
The transmission apparatus, wherein the packet is a CEP packet. A packet assembly unit that stores data of a time division multiplexed signal input from a time division multiplexing line in a payload portion and generates a packet in which transmission control information of the data is stored in a header portion;
Generating an error correction code for the header part and adding the error correction code to the packet;
A transmission device on the transmission side having a packet transmission unit that transmits the packet output by the error correction code addition unit to a packet network;
A packet receiver for receiving the packet transmitted by the transmission device on the transmission side;
An error correction unit that performs error correction of the header portion of the packet by extracting the error correction code added to the packet received by the packet reception unit;
A receiving side transmission apparatus comprising: a packet decomposing unit that restores data stored in the payload portion of the packet corrected by the error correcting unit to a time division multiplexed signal and outputs the data to a time division multiplexed line. Characteristic transmission system. The transmission system according to claim 5, wherein
The error correction code adding unit stores an error correction code for the header unit in the payload unit,
The transmission system, wherein the error correction unit extracts the error correction code stored in the payload portion of the packet received by the packet reception unit and performs error correction of the header portion of the packet. The transmission system according to claim 5 or 6,
The error correction code adding unit adds an error detection code for detecting an error to the entire packet including the payload portion and the header portion to the packet,
When the error correction unit detects an error by the error detection code of the packet received by the packet reception unit, the error correction unit extracts the error correction code stored in the payload unit and causes the error of the packet. It is determined whether or not it is the header part, and when the header part is the cause, the error of the header part is corrected by the error correction code, and when the header part is not the cause or by the error correction code A transmission system characterized by discarding the packet if it cannot be corrected. The transmission system according to any one of claims 5 to 7,
The time division multiplexed signal is an SDH / SONET signal,
The transmission system, wherein the packet is a CEP packet.

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