JPWO2001031819A1 - Transmission System - Google Patents

Abstract

(57) [Summary] Efficient large-capacity transmission is achieved by maintaining the continuity of divided multiplexed signals and restoring the original large-capacity multiplexed signals. Signal dividing means (11) divides a multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format. Guarantee information adding means (12) adds guarantee information that guarantees the continuity of the divided signals to each of the divided signals to generate a transmission signal. Signal transmitting means (13) transmits the transmission signal through a transmission path in the transmission interface format. Signal receiving means (21) receives the transmission signal. Signal restoring means (22) assembles the divided signals based on the guarantee information to restore the multiplexed signal.

Description

Detailed Description of the Invention

TECHNICAL FIELD The present invention relates to a transmission system, and more particularly to a transmission system that controls the transmission of multiplexed signals.
l Network)/SDH (Synchronous Digital H
The SONET/SONET-based network architecture (SONET/SONET-like architecture) defines communication procedures for effectively multiplexing various communication services, and is currently being standardized and developed. In recent years, data traffic has increased, as symbolized by the Internet, and various communication services are required.
There is a demand for SDH transmission systems with even larger capacity to be introduced into the current backbone network.
1 is a diagram showing the format structure of STS-1 (51.84 Mbps)
) is the frame that is the standard unit of SONET (the frame that is the standard unit of SDH is STM (Synchronous Transport Modulation
The STS-1 frame format consists of nine lines of 90 bytes.
The 3 bytes on the left side of the figure are reserved for the OH (overhead) area, and the 8 bytes on the right side are reserved for the
The area of the 7 bytes excluding the POH (Path Overhead) is where actual user data is inserted as the payload. On the other hand, in SONET/SDH, VC (Virtual Container)
Multiplexing control is performed using a standardized multiplexing unit called a VC.
All multiplexing structures are byte multiplexing, and concatenation (concatenation)
e) to generate a concatenation signal.
For example, in SONET, a concatenation signal with N times the VC capacity is transmitted as an STS-
Nc. Figure 21 shows the format structure of STS-12c.
A frame is represented as a two-dimensional byte array with 9 rows and 1080 columns.
Six columns are made up of OH, and the following nine rows and 1044 columns are the payload that stores multiplexing information. Four sets of STS-3c CH1 to CH4 are multiplexed into this payload. Here, the H1 byte is located in the first to twelfth columns of the pointer in the fourth row, and the H2 byte is located in the thirteenth to twenty-fourth columns of the pointer in the fourth row. The seventh and eighth bits of the H1 byte and the eight bits of the H2 byte combine to form a 10-bit pointer. The four bits from the first to fourth bits of H1 are NDF (New Data Forwarding).
This changes the 10-bit pointer value according to changes in the payload. For example, when there is no need to change the pointer value, the N bits are set to "011"
When the pointer value is changed, the N bits are inverted to "1001". This 10-bit pointer is used as a concatenation indicator. Specifically, when all 10 bits are "0", the signal is not a concatenation signal, and when all 10 bits are "1", the signal is a concatenation signal. For example, in the case of STS-12c,
Since it is made up of four channels, the 10-bit pointer of the first channel is all "0", while the 10-bit pointers of channels 2, 3, and 4 are subordinate channels, so they are all "1". By generating and transmitting such a concatenation signal, it is possible to transmit large volumes of data that would not have been possible with a single container. However, for the conventional multiplexed transmission described above, it is not enough to simply add a new system to increase the system capacity; rather, it is important to consider how to utilize the existing network system to provide new services with minimal expansion. For example, when transmitting a 9.953280 Gbps STS-192c concatenation signal, it is necessary to add a new high-speed transmission line or the like to transmit the STS-192c concatenation signal.
2c via a dedicated line, and in the case where a transmission path with a transmission bit rate limitation is installed, it is necessary to transmit these high-capacity signals by efficiently utilizing this transmission path. Disclosure of the Invention The present invention has been made in view of the above points, and an object of the present invention is to provide a transmission system that efficiently transmits high-capacity multiplexed signals by effectively utilizing an existing network system with a transmission bit rate limitation. In order to solve the above problems, the present invention provides a transmission system 1 that performs transmission control for transmission between paths of a multiplexed signal as shown in Figure 1, characterized in that the transmission system 1 comprises: a transmitting device 10 comprising: signal dividing means 11 that divides a multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format that are slower than the speed of the multiplexed signal; assurance information adding means 12 that adds assurance information that ensures the continuity of the divided signals to each of the divided signals to generate a transmission signal; and signal transmitting means 13 that transmits the transmission signal through a transmission path of the transmission interface format; a signal receiving means 21 that receives the transmission signal; and a signal restoring means 22 that assembles the divided signals based on the assurance information to restore the multiplexed signal. Here, the signal dividing means 11 divides the multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format, which is slower than the speed of the multiplexed signal. The assurance information adding means 12 adds assurance information that guarantees the continuity of the divided signals to each of the divided signals to generate a transmission signal. The signal transmitting means 13 transmits the transmission signal through a transmission path in the transmission interface format. The signal receiving means 21 receives the transmission signal. The signal restoring means 22 assembles the divided signals based on the assurance information to restore the multiplexed signal. 15, a transmission system 1a for performing transmission control for transmission between sections of a multiplexed signal includes a transmitting device 10a including a signal dividing means 11a for dividing a multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format that are slower than the speed of the multiplexed signal, a guarantee information adding means 12a for adding guarantee information for guaranteeing the continuity of the divided signals to each of the divided signals, and a WDM signal transmitting means 13a for converting the divided signals with the guarantee information added thereto into optical signals having different wavelengths, wavelength-multiplexing the optical signals, and transmitting the optical signals; and a WDM signal receiving means 20a for receiving an optical signal, separating it into wavelengths, and converting the optical signals into divided signals.
The present invention provides a transmission system 1a characterized by having a receiving device 20a including a signal division unit 11a and a signal restoration unit 22a that assembles divided signals based on assurance information to restore a multiplexed signal. Here, the signal division unit 11a divides the multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format that is slower than the speed of the multiplexed signal. The assurance information addition unit 12a adds assurance information that guarantees the continuity of the divided signals to each of the divided signals. The WDM signal transmission unit 13a converts the divided signals with the assurance information added into optical signals having different wavelengths, wavelength-multiplexes the optical signals, and transmits them. The WDM signal reception unit 21a receives the optical signal, separates it into wavelengths, and converts it into divided signals. The signal restoration unit 22a performs the following based on the assurance information:
The divided signals are reassembled to restore the multiplexed signal. The above and other objects, features and advantages of the present invention will become apparent from the following description in conjunction with the accompanying drawings, which show preferred embodiments of the present invention as examples. BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will now be described with reference to the drawings. FIG. 1 is a diagram illustrating the principle of a transmission system according to the present invention. The transmission system 1 comprises a transmitting device 10 and a receiving device 20, and is intended for transmission of multiplexed signals between paths. The transmitting device 10 and the receiving device 20 are installed in multiplexing nodes 100 and 200, respectively, which control transmission between paths. In practice, the functions of the transmitting device 10 and the receiving device 20 are as follows:
The signal dividing means 11 divides the multiplexed signal into path units (path overhead + payload) for the transmitting device 10, and generates a plurality of divided signals in the transmission interface format of STS (if the original multiplexed signal is SONET) or STM (if the original multiplexed signal is SDH), which are slower than the speed of the multiplexed signal.
In this explanation of processing for ONET, the multiplexed signal is called a concatenation signal. This divided signal has a SONET or SDH multiplexing interface,
This is a pseudo-concatenation signal with a bit rate lower than that of the concatenation signal before division. The guarantee information adding means 12 adds guarantee information that guarantees the continuity of the divided signals to each divided signal to generate a transmission signal. By adding this guarantee information to the divided signals, the receiving side can recognize how the divided signals were divided from the concatenation signal, or the order in which they were divided. This allows the receiving device 20 to properly restore the concatenation signal. The signal transmitting means 13 transmits the transmission signals in parallel through a transmission path between paths in the SONET/SDH transmission interface format. The signal receiving means 21 receives the transmission signals from the receiving device 20. The signal restoring means 22 assembles the divided signals based on the guarantee information to restore the original concatenation signal. Next, regarding the operation when dividing, STS-192c (9.953280 Gbps)
2 is a conceptual diagram showing the division process of a concatenation signal. In the figure, for a concatenation signal called STS-192c corresponding to the optical transmission rate of OC (Optical Carrier) 192,
c is divided to generate the divided signal STS-3c, and
In this case, the STS-3c x 16 corresponding to the optical transmission rate of 20 Gbps is transmitted in four parallel streams #1 to #4.
Rewrite the TS-192c pointer to the STS-3c pointer, and
The signal is divided into 64 bits (with STS-3c OH added) and transmitted as a group as shown in the figure.
To restore S-192c, assurance information, described below, is added to each STS-3c. Since STS-3c only has one column of 9 bytes per POH, it cannot be further divided. The pointer bytes of STS-3c and STM-1 are used by placing a pointer value only in the first byte of the pointer, and placing an indication signal in the remaining two bytes and beyond. Furthermore, STS-3c and STM-1 multiplex one VC-4 in the payload. While the above explanation shows an example of generating a divided signal STS-3c from STS-192c, the signal dividing means 11 of the present invention adaptively divides the concatenation signal according to the transmission bit rate of the installed transmission path, and generates divided signals (concatenation signals) with a speed equal to (or lower than) the transmission bit rate. Next, assurance information will be explained. The assurance information adding means 12 adds assurance information to empty bytes of the POH (path overhead) of the divided signal. Figure 3 shows a diagram of the POH. POH is control information used for inter-path management between multiplexing nodes included in a VC, and is used for error detection, network maintenance, etc. Also, Z3 to Z5 shown in the figure are empty bytes, and in this invention, these empty bytes are used to add assurance information. FIG. 4 shows the contents of assurance information. The figure shows the case of STS-3c, and when assurance information is added to STS-3c, bytes Z3 to Z5 are used. Concatenation information is added to the Z3 byte, and four bits 5 to 8 are used (four bits 1 to 4 are reserved). The contents indicate the type of the original concatenation signal before division. For example, 0 means STS-3c, 1 means STS-12c, 2 means STS-48c, 3 means STS-192c, and 4 means STS-202c.
For example, if the original concatenation signal is OC192, it indicates which OC192 frame it is. The frame information is added to the Z4 byte, with 8 bits from 1 to 8 used. The content indicates the frame number before division. For example, if the original concatenation signal is OC192, it indicates which OC192 frame it is,
A frame number can be set from 0 to 255. Block information is added to the Z5 byte, and the bits used are 1 to 8, making it 8 bits. The contents are the division numbers when the data is divided, and the serial numbers are assigned starting from the earliest division. On the receiving side, the data can be reproduced in this numerical order. In the above explanation, Z3 to Z5 were used for STS-3c, but S
For a concatenation signal of TS-12c or higher, any one byte of Z3 to Z5 can be used multiple times. For example, when STS-192c is converted to STS-12,
When dividing into Z4#1, Z4#2, and Z4#3, for example, assurance information can be added to Z4#1, Z4#2, and Z4#3 for processing. In a normal multiplexing node, cross-connection and other processing is performed on a path-by-path basis (P
Therefore, unlike the line and section OH, the POH is not terminated and lost, so in the present invention, the guarantee information is stored in the PO.
By adding the assurance information to the POH, loss of the assurance information during internal processing is prevented. FIG. 5 is a diagram showing a case where a tributary-compatible multiplexing node is provided between multiplexing nodes 100 and 200. A tributary-compatible multiplexing node 300 is provided between multiplexing nodes 100 and 200. The multiplexing node 300 receives a signal transmitted from the tributary, multiplexes it with the signal transmitted from multiplexing node 100, and transmits the multiplexed signal to the multiplexing node 200 (Add). The multiplexing node 300 also receives a signal transmitted from the multiplexing node 100, separates it, and transmits it to the tributary (Drop). In the transmission system 1 of the present invention, the assurance information is added to the POH because transmission control between paths is performed, from splitting to restoring the concatenation signal. For this reason, a multiplexing node 300 having a cross-connect function as shown in the figure is provided.
Even if 00 is present on the transmission path, the guarantee information is not lost and division/restoration control of the concatenation signal is possible. Next, the block configuration and operation of the transmission system 1 when the functions of the present invention are embodied will be described. Fig. 6 is a diagram showing the block configuration of the transmitting device, and Fig. 7 is a diagram showing the block configuration of the receiving device. Note that the configuration in the figure shows a case where STS-192c is divided and STS-3c x 16 is transmitted in four parallel ways. The transmitting device 10-1 comprises a pointer rewriting unit 101 which rewrites the pointers,
TSA (Time Slot Adapter) that adds guarantee information and divides it into STS-3c
Assignment section 102, memories 103-1 to 103-
4. Signal transmission units 104-1 to 104-4 that control the interface for signal transmission;
The receiver 20-1 is made up of OH termination units 201-1 to 204-4 that terminate the OH, assurance information extraction units 202-1 to 202-4 that extract assurance information, memories 203-1 to 203-4 that perform speed conversion, a TSA unit 204 that performs assembly processing of the divided signals, a signal transmission unit 205 that performs interface control for signal transmission, and a restoration control unit 206 that performs control required for restoration processing for each unit. Next, the operation will be described. [S1] The pointer rewriting unit 101 terminates the OH of STS-192c. Then, it rewrites the STS-192c pointer to an STS-3c pointer. In this way, by rewriting to an STS-3c pointer as preprocessing, the STS-
3c is added to the pseudo OH (to generate a pseudo frame).
[S2] The TSA unit 102 performs cross-connection in units of STS-3c, and
A divided signal with a transmission capacity of 16 STS-3c is generated. Also, for each STS-3c, the concatenation information, frame information, and block information are stored in each POH as guarantee information.
[S3] Memories 103-1 to 103-4 perform clock transfer of data from the internal processing clock to the transmission clock. [S4] Signal transmitters 104-1 to 104-4 add the substantial OH of STS-3c, convert the data into a low-speed signal format, and write the data into OC48 (STS-3c x 16)
[S5] The OH termination units 201-1 to 204-4 terminate the OH of the STS-3c. [S6] The assurance information extraction units 202-1 to 202-4 extract assurance information from the POH and notify the restoration control unit 206 of the contents. [S7] The memories 203-1 to 203-4 perform clock transfer of the data from the internal processing clock to the transmission clock. [S8] The TSA unit 204 performs cross-connection based on the restoration information (assurance information) notified by the restoration control unit 206, and performs STS-3c assembly processing. [S9] The signal transmission unit 205 adds STS-
An OH including a pointer to STS-192c is added to restore the STS-192c and sent to the transmission line. Next, delay correction control during parallel transmission will be explained with reference to Figs. 8 to 14. In parallel transmission of signals, transmission delay occurs in each transmission line. The causes of transmission delay include:
These include variations in the length of each transmission path and the characteristics of circuit components in the transmitting and receiving sections, as well as chromatic dispersion and modal dispersion that occur in optical fiber transmission paths. Chromatic dispersion delay refers to a difference in arrival time at the receiving end caused by changes in refractive index depending on the optical wavelength when light propagates through an optical fiber. Modal dispersion delay refers to a difference in arrival time at the receiving end caused by a phenomenon in which optical pulses spread over time when optically modulated light passes through an optical fiber. Therefore, when transmitting transmission signals in parallel, it is necessary to correct for delays caused by these factors. Figure 8 is a diagram illustrating the delay information notification means. The transmitting device 10 and the receiving device 20 are connected by transmission paths L1 to L4, and transmission signals are transmitted from the transmitting device 10 to the receiving device 20 via the transmission paths L1 to L4. The delay information notification means 23 notifies the signal transmitting means 13 of the transmitting device 10 of delay information related to delays that occurred in each of the transmission paths L1 to L4 when the transmission signals were received by the signal receiving means 21, using sub-channel S. The signal transmitting means 13 then performs the following for each transmission signal based on the delay information:
The bit rate is set to be variable and delay correction is performed. Next, a specific operation of delay correction will be described. Figure 9 shows the time relationship of parallel transmission signals. Data generated by dividing one frame (X bits/s) of information from the transmitting device 10 into four is sent to the receiving device 20 in the order of arrival, data D1 (arrived at time t0) to data D4.
((X/4) bits/s each). The reception end times of the data D1 to D4 are set to t1 to t4. In addition, (t2-t1)=Δt2, (t3-t1)=
Let Δt3, (t4 - t1) = Δt4. The delay information notifying means 23 notifies the transmitting device 10 of the values of Δt2 to Δt4 via sub-channel S, and the signal transmitting means 13 of the transmitting device 10 controls the delay correction of each parallel transmission signal based on this information. In this case, if the data is transmitted so that all data arrives before t1, there is no need to provide a large-scale buffer circuit or the like on the receiving device 20 side to absorb the difference in transmission path delay. Note that the data portions of data D2 to data D4 that have not arrived by time t1 are called delayed data d2 to d4. Figures 10 and 11 are diagrams showing how delay correction works. The signal transmitting means 13 adjusts the bit rate of data D1 to D4 to X1 bits/s to X4 bits/s based on the delay information.
s is calculated and the original frame is divided. Here, the conditions to be met when dividing are that X1 + X2 + X3 + X4 = X, that all data arrives by t1, and that X1 ≥ X2 ≥ X3 ≥ X4 (
(More data is sent to the transmission path that arrives earlier). Based on these conditions, the transmission bit rate of each transmission path L1 to L4 is calculated and mapped as shown in the figure. That is, data D1 is allocated at X1 bits/s so that delayed data d2 is sent on transmission path L1. Similarly, data D2 is allocated at X2 bits/s so that delayed data d3 is sent on transmission path L2, and data D3 is allocated at X3 bits/s so that delayed data d4 is sent on transmission path L3.
However, the bit rate of the transmission line L4 corresponding to the data D4 (the data that arrives latest) is shown as X4 bits/s in the figure, but in reality it is (X/4) bits/s.
, and the line also serves as a clock transmission line. Figure 12 shows a first modification of delay correction. In the first modification, data D1 is left at (X/4) bits/s, and the bit rates of data D2 to D4 are corrected based on (X/4) bits/s, and controlled to arrive by time t1. If t1 - t0 = T, the bit rate at which delayed data d2 of data D2 arrives by time t1 is (X/4) x (T/(T - Δt2)) bits/s. Similarly, the bit rate at which delayed data d3 of data D3 arrives by time t1 is (X/4) x (T/(T - Δt3)) bits/s, and data D4
The bit rate for the delayed data d4 to arrive by time t1 is (X/4)
・(T/(T-Δt4)) bits/s. FIG. 13 is a diagram showing a second modification of delay correction. In the second modification, the signal transmitting means 13 transmits divided data by overlapping a part of another divided data with the head of the divided data. For example, data D1' is transmitted by adding an overlapping part m0, which is part of data D0, to the head of data D1. Similarly, data D2' is transmitted by adding an overlapping part m1 of data D1 to the head of data D2, and data D3' is transmitted by adding an overlapping part m1 of data D3
The data D4' is transmitted with the overlapping portion m2 of data D2 added to the beginning of the data D4, and the data D4' is transmitted with the overlapping portion m3 of data D3 added to the beginning of the data D4. FIG. 14 is a diagram for explaining the second modification. If the arrival of data is delayed on the receiving side, the delay difference is absorbed by using the overlapping data present at the beginning of another divided data to fill in the data of the delayed portion. In the diagram, all data other than data D3' has arrived by time t1. Therefore, the data m3 of data D3' that has not arrived by time t1 is added to the data D
The delay is absorbed by filling in the data of the overlapping portion m3 added to the head of 4'. By performing the delay correction as explained above, a transmission system with improved reliability can be realized. Next, WDM (Wavelength Division Multiplexing)
The transmission system of the present invention will be described when the IEEE 1394 standard (or IEEE 1394 standard) is applied.
5 is a diagram showing the principle of a transmission system to which WDM is applied. The transmission system 1a is composed of a transmitting device 10a and a receiving device 20a, and is intended for transmission between sections of a concatenation signal.
a and receiving device 20a are terminal nodes 110 and 210 that perform transmission control between sections.
In reality, the functions of the transmitting device 10a and the receiving device 20a are contained in the same device. For the transmitting device 10a, the signal dividing means 11a divides the concatenation signal to generate a plurality of divided signals in the STS or STM transmission interface format, which are slower than the speed of the concatenation signal. Here, the terminal nodes 110 and 210 establish a WDM network between sections, and the terminal nodes 110 and 210 do not process on a path-by-path basis (
(There is no need to recognize signals on a path-by-path basis). Therefore, when dividing a concatenation signal, it can be divided in units of blocks including OH. The assurance information adding means 12a adds assurance information that guarantees the continuity of the divided signals to each of the divided signals. The WDM signal transmitting means 13a converts the divided signals with the assurance information added into optical signals having different wavelengths, wavelength-multiplexes the optical signals, and transmits them through a single optical transmission medium. For the receiving device 20a, the WDM signal receiving means 21a receives the optical signals, separates them into wavelengths, and converts them into divided signals. The signal restoring means 22a assembles the divided signals based on the assurance information to restore the concatenation signal. Next, the assurance information will be explained. The assurance information adding means 12a adds assurance information to the C1 byte of the SOH of the divided signal (the C1 byte of the RSOH (relay section overhead)
FIG. 16 shows the OH. The OH is composed of the SOH and LOH, and the OH in the figure shows the case of STS-3c. In the case of the transmission system 1a of the present invention, which employs WDM, assurance information is added using the C1 byte located in the position shown in the figure. FIG. 17 shows the contents of the assurance information. Concatenation information is added to the #2 byte of C1, with four bits used, 1 to 4. The content indicates the type of the original concatenation signal before division. Frame information is added to the #2 byte of C1, with four bits used, 5 to 8. The content indicates the frame number before division. In the case of WDM, there is almost no transmission path delay, so the amount of frame information can be reduced. Block information is added to the #3 byte of C1, with eight bits used, 1 to 8. The content is the division number used when the signal was divided, and consecutive numbers are assigned to each wavelength, starting from the earliest division. On the receiving side, the signal can be reproduced in this numerical order. Next, the block configuration and operation of a transmission system 1a when the functions of the present invention are embodied will be described. Figure 18 shows the block configuration of a transmitting device, and Figure 19 shows the block configuration of a receiving device. The configuration shown in the figure is for STS-192c
The transmitter 10a-1 includes a pointer rewriting unit 111 for rewriting the pointer.
, a DMUX unit 112 for dividing the signal into STS-48c, a memory 11 for converting the signal speed, and
3-1 to 113-4, OH adding units 114-1 to 114-1 for adding OH including guarantee information,
14-4, a WDM transmitter 115 that controls the WDM transmission interface, and a division control unit 116 that controls each unit as required during division processing. The receiving device 20a-1 is made up of a WDM receiver 211 that controls the WDM reception interface, assurance information extractors 212-1 to 212-4 that extract assurance information, memories 213-1 to 213-4 that perform speed conversion, an MUX unit 214 that performs assembly processing of divided signals, a signal transmitter 215 that controls the signal transmission interface, and a restoration control unit 216 that controls each unit as required during restoration processing. Next, the operation will be explained. [S10] The pointer rewriter 111 terminates the STS-192c OH.
Then, the STS-192c pointer is rewritten to the STS-48c pointer. Here, since there is no cross-connect function between the devices, the pointer reassignment process is not necessary, and the OH and SPE (Synchronous Payload)
Therefore, the STS-192c pointer is copied as it is and used as the STS-48c pointer. [S11] The DMUX unit 112 copies the four STSs generated from the STS-192c.
DMUX processing is performed in block units of 48c.
The data is separated into groups of eight to generate four STS-48c signals. [S12] Memories 113-1 to 113-4 perform clock synchronization of the data from the internal processing clock to the transmission clock. [S13] OH adding units 114-1 to 114-4 add, to each STS-48c signal, a substantial OH in which guarantee information such as concatenation information, frame information, and block information is written in the C1 byte. [S14] The WDM transmitting unit 115 assigns different wavelengths to each STS-48c signal, wavelength-multiplexes the signals, and transmits them (transmission of a four-wave multiplexed STS-48c signal). [S15] The WDM receiving unit 211 receives the four-wave multiplexed STS-48c signal, and
The signal is separated into four wavelengths to generate four STS-48c split signals. [S16] The assurance information extractors 212-1 to 212-4 extract assurance information from the C1 byte and notify the restoration control unit 216 of the contents. [S17] The memories 213-1 to 213-4 perform clock transfer of the data from the internal processing clock to the transmission clock. [S18] The MUX unit 214 performs MUX processing based on the restoration information (assurance information) notified by the restoration control unit 216, and performs STS-48c assembly processing. [S19] The signal transmitter 215 adds ST
The OH including the STS-192c pointer is added to restore the STS-192c and sent to the transmission path. As described above, the transmission system 1a of the present invention is configured to perform splitting/restoration control of a concatenation signal within a WDM network. Here, because the transmission bit rate cannot be easily increased due to the dispersion characteristics of optical fiber, which is the transmission medium, WDM technology has been widely used in recent years to expand transmission capacity. Therefore, the present invention is essential for transmitting large-capacity concatenation signals using low-speed WDM networks. Furthermore, by applying the present invention, it becomes possible to stably transmit large-capacity concatenation signals by combining wavelengths concatenated within WDM into one set and exclusively dividing the band within various photonic networks. Next, the application of the present invention to an IP network will be described. In conventional networks, multiple low-speed interfaces are accommodated in the payload of the SONET basic frame STS-1, and frame multiplexing (STS-1 frame-by-STS-1 frame) is simply performed.
In the past, a high-speed SONET frame rate (STS-1xn) was used. This enabled a high-speed SONET frame rate, thereby realizing increased transmission speeds and expanded transmission capacity. Meanwhile, in IP networks, which will become mainstream in the future, it will generally be configured to utilize (occupy) this high-speed SONET frame rate (STS-1xn) as a single IP transmission path, with multiple STS-1 frames used as a single large transmission path (STS-1xnc) through the concatenation function. Therefore, even if the concatenation signal is separated due to the system configuration or other reasons when transmitting large amounts of IP data to a single IP address using the SONET concatenation function, the application of the present invention ensures the continuity of IP packets, enabling failure-free transmission of large amounts of data from IP routers and high-quality, reliable large-capacity transmission. Furthermore, by assigning a SONET path suited to the service content of the IP data, large amounts of IP data (best effort), for example, can be transmitted over a 75-bit bandwidth of the large-capacity concatenation signal STS-192c.
% of the capacity (for STS-144c), and a small capacity but quality-priority I
For P data, the remaining 25% (for STS-48c) can be guaranteed as a dedicated line, allowing for application in a manner that divides STS-192c into two partitions. As described above, according to the present invention, guarantee information is added to guarantee continuity, and the concatenation signal is divided into low-speed signals before transmission. At the receiving end, the original large-capacity concatenation signal is restored based on the guarantee information. This enables efficient transmission of large-capacity concatenation signals via multiple transmission paths across various networks with an economical equipment configuration. While the above description focuses on SONET, the present invention can also be applied to SDH. For example, while the above description describes dividing STS-192c to generate a divided signal STS-3c, in the case of SDH, STM-64 (VC4-64c) is divided to generate a divided signal VC-4. As described above, the transmission system of the present invention is configured such that the transmitting side divides a multiplexed signal, and when dividing, adds guarantee information to guarantee the continuity of the divided signals to generate divided signals in an STS or STM transmission interface format, and the receiving side restores the multiplexed signal based on the guarantee information. This makes it possible to effectively utilize existing network systems with limited transmission bit rates when transmitting large-capacity multiplexed signals, thereby enabling efficient transmission of large-capacity signals. The above description merely illustrates the principles of the present invention. Furthermore, numerous variations and modifications are possible to those skilled in the art, and the present invention is not limited to the exact configurations and applications shown and described above. All corresponding modifications and equivalents are intended to be included.
The scope of the invention is considered to be the appended claims and their equivalents.

[Brief explanation of the drawings]

FIG. 1 illustrates the principle of a transmission system according to the present invention. FIG. 2 is a conceptual diagram showing the division processing of a concatenation signal. FIG. 3 is a diagram showing a POH. FIG. 4 is a diagram showing the contents of guarantee information. FIG. 5 is a diagram showing a case where a tributary-compatible multiplexing node is provided between multiplexing nodes. FIG. 6 is a block diagram of a transmitting device. FIG. 7 is a block diagram of a receiving device. FIG. 8 is a diagram for explaining delay information notification means. FIG. 9 is a diagram showing the time relationship of parallel transmission signals. FIG. 10 is a diagram showing the manner of delay correction. FIG. 11 is a diagram showing the manner of delay correction. FIG. 12 is a diagram showing a first modified example of delay correction. FIG. 13 is a diagram showing a second modified example of delay correction. FIG. 14 is a diagram for explaining the second modified example. FIG. 15 is a diagram showing the principle of a transmission system employing WDM. FIG. 16 is a diagram showing an OH. FIG. 17 is a diagram showing the contents of guarantee information. FIG. 18 is a block diagram of a transmitting device. FIG. 19 is a block diagram of a receiving device. FIG. 20 is a diagram showing the format structure of STS-1. FIG. 21 is a diagram showing the format structure of STS-12c.

───────────────────────────────────────────────────── Continued from the front page (72) Inventor: Hideki Matsui 4-1 Kami-Odanaka, Nakahara-ku, Kawasaki, Kanagawa Prefecture Fujitsu Limited (72) Inventor: Hirotaka Morita 4-1 Kami-Odanaka, Nakahara-ku, Kawasaki, Kanagawa Prefecture Fujitsu Limited (Note) This publication is based on the publication published internationally by the International Bureau of Patents (WIPO). The effect of the international publication of the Japanese patent application (Japanese utility model registration application) related to this publication arises pursuant to Article 184-10, Paragraph 1 of the Patent Act (Article 48-13, Paragraph 2 of the Utility Model Act) and is unrelated to this publication.

Claims (14)

[Claims] [Claim 1] A transmission system that performs transmission control for transmission between paths of a multiplexed signal, characterized in that the transmitting device is provided with a signal dividing means that divides the multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format, a guarantee information adding means that adds guarantee information that guarantees the continuity of the divided signals to each of the divided signals to generate a transmission signal, and a signal transmitting means that transmits the transmission signals, and the receiving device is provided with a signal receiving means that receives the transmission signals and a signal restoring means that assembles the divided signals based on the guarantee information to restore the multiplexed signal. [Claim 2] A transmission system as described in claim 1, characterized in that the guarantee information adding means adds at least one of the type information of the multiplexed signal, the frame number, and the division number at the time of division to the divided signal as the guarantee information. 3. The transmission system according to claim 1, wherein said assurance information adding means adds said assurance information to empty bytes of a path overhead of said divided signal. 4. The transmission system according to claim 1, wherein the receiving device further comprises a delay information notifying means for notifying the transmitting device of delay information relating to a delay that occurs when the transmission signal is received. 5. The transmission system according to claim 4, wherein said signal transmitting means performs delay correction by variably setting a bit rate for each of said transmission signals based on said delay information. 6. The transmission system according to claim 4, wherein said signal transmitting means transmits said transmission signals with a part of said transmission signals overlapped. 7. The transmission system according to claim 6, wherein said signal receiving means, upon receiving said transmission signal, performs delay correction using the overlapping portion. [Claim 8] A transmitting device that controls signal transmission for transmission between paths, characterized by having: a signal dividing means that divides a multiplexed signal to generate multiple divided signals in an STS or STM transmission interface format; a guarantee information adding means that adds guarantee information that guarantees the continuity of the divided signals to each of the divided signals to generate a transmission signal; and a signal transmitting means that transmits the transmission signals. [Claim 9] A receiving device that controls signal reception for transmission between paths, characterized by having: a signal receiving means that receives a transmission signal consisting of divided signals generated by dividing a multiplexed signal; and a signal restoration means that assembles the divided signals based on guarantee information contained in the divided signals that guarantees the continuity of the divided signals, and restores the multiplexed signal. [Claim 10] A transmission system that performs transmission control for transmission between sections of a multiplexed signal, wherein the transmitting device is provided with a signal dividing means that divides the multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format, a guarantee information adding means that adds guarantee information that guarantees the continuity of the divided signals to each of the divided signals, and a WDM signal transmitting means that converts the divided signals with the guarantee information added into optical signals having different wavelengths, wavelength-multiplexes the optical signals, and transmits them; and the receiving device is provided with a WDM signal receiving means that receives the optical signals, separates them by wavelength, and converts them into the divided signals, and a signal restoration means that assembles the divided signals based on the guarantee information to restore the multiplexed signal. [Claim 11] A transmission system as described in Claim 10, characterized in that the guarantee information adding means adds at least one of the type information of the multiplexed signal, the frame number, and the division number at the time of division to the divided signal as the guarantee information. 12. The method according to claim 1, wherein said assurance information adding means adds said assurance information to a C1 byte of a repeating section overhead of said divided signal.
10. The transmission system according to claim 0. [Claim 13] A transmitting device that controls signal transmission for transmission between sections, characterized by having: a signal dividing means that divides a multiplexed signal to generate a plurality of divided signals in an STS or STM transmission interface format; a guarantee information adding means that adds guarantee information that guarantees the continuity of the divided signals to each of the divided signals; and a WDM signal transmitting means that converts the divided signals with the guarantee information added into optical signals having different wavelengths, wavelength-multiplexes the optical signals, and transmits them. [Claim 14] A receiving device that controls signal reception for transmission between sections, characterized by having: a WDM signal receiving means that receives a wavelength-multiplexed optical signal, separates it into wavelengths, and converts the multiplexed signal into divided signals generated by dividing it; and a signal restoration means that assembles the divided signals based on guarantee information contained in the divided signals that guarantees the continuity of the divided signals, and restores the multiplexed signal.