JP2754981B2 - Loop type data transmission system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a loop data transmission system, and more particularly, to a data transmission system in a loop network system.

[0002]

2. Description of the Related Art Conventionally, in a loop network system, one master node and a plurality of slave nodes are connected on a loop via a transmission line. When data transmission is performed in this loop, an STM-1 frame in which one multiframe is composed of 4 or 24 270 (octet) × 9 (row) time slots is used.

[0003] An STM-1 frame includes an SOH (section overhead) containing control information of the frame, and an SOH-1.
VC4 whose head position is specified by the AU pointer in
It consists of VC4 is a P containing control information of VC4.
OH and C4 which uses the H4 pointer in the POH as a multi-frame synchronization pattern. That is, for the data transmission in the loop, the H4 pointer in the POH constituting the VC4 in the STM-1 frame is used as a multi-frame synchronization pattern, and the C4 time slot in the STM-1 frame is used as a service channel for storing data and the like. A time-division multiplex frame is used.

[0004] The master node generates the above-described time-division multiplex frame, drops the line data connected to the own node into the service channel (C4) of the time-division multiplex frame, and then transmits the time-division multiplex frame. It is sent to the next slave node via the path.

[0005] The slave node is subordinately synchronized with the time division multiplex frame received via the transmission path, and after the line data connected to its own node is dropped and inserted into the service channel of the time division multiplex frame, the slave node performs the time division multiplexing. The frame is transmitted to the next slave node or master node via the transmission path.

When the master node receives the time division multiplex frame via the transmission line, the master node corrects the delay between the time division multiplex frame generated and transmitted by the own node and the received time division multiplex frame. Therefore, a loop delay correction is performed.

[0007] In such a conventional loop network system, according to the CCITT recommendation, the VC4 in the STM-1 frame is used.
The H4 pointer in the POH constituting
Since the H4 pointer is a multi-frame synchronization pattern, one multi-frame has a disadvantage that only four or twenty-four STM-1 frames can be realized.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in order to eliminate the above-mentioned drawbacks of the prior art, and has as its object to provide a loop-type data transmission system in which the configuration of one multi-frame can be freely set.

[0009]

A loop-type data transmission system according to the present invention uses a time-division multiplex frame composed of one or more STM-1 frames in which a master node and a plurality of slave nodes are connected in a loop via a transmission line. A loop-type data transmission system for performing data transmission between the master node and the plurality of slave nodes, wherein the STM-
Frame synchronization pattern insertion means for inserting a frame synchronization pattern for synchronizing C4 including data information in one frame into virtual C4 fixedly arranged at a predetermined position and connected to the own node Data insertion means for exchanging data between a line and the virtual C4; and transmitting the time-division multiplexed frame including the virtual C4 in which the frame synchronization pattern is inserted and the data is exchanged on the transmission path. Transmitting means for transmitting, loop correction means for correcting the delay between the time division multiplex frame transmitted on the transmission path and the time division multiplex frame received via the transmission path, provided in the master node, The virtual C4 of the time division multiplex frame received via the transmission path
Data insertion means for transmitting and receiving data between the virtual C4 and the line connected to the own node in synchronization with the frame synchronization pattern inserted into the virtual C4, and inserted into the virtual C4 of the time division multiplex frame. Frame synchronization pattern insertion means for inserting the frame synchronization pattern into the virtual C4 to which the data has been transmitted and received by the data insertion means, and the frame synchronization pattern has been inserted and the data has been transmitted and received. Transmitting means for transmitting the time-division multiplexed frame including the virtual C4 on the transmission path, is provided for each of the plurality of slave nodes.

[0010] Another loop type data transmission system according to the present invention uses a time division multiplex frame composed of one or more STM-1 frames in which a master node and a plurality of slave nodes are connected in a loop via a transmission line. A loop-type data transmission system for performing data transmission between the master node and the plurality of slave nodes, wherein the STM
-1 frame synchronization pattern inserting means for inserting a frame synchronization pattern for synchronizing C4 into C4 including data information in one frame, and exchanging data between the line connected to the own node and the C4. Data insertion means for performing the transmission, the transmission means for transmitting the time-division multiplexed frame including the C4 in which the frame synchronization pattern is inserted and the data transmission / reception is performed on the transmission path, and the transmission of the data on the transmission path. Loop correction means for correcting a delay between the division multiplex frame and the time division multiplex frame received via the transmission path is provided in the master node, and the time division multiplex frame received via the transmission path is Data insertion for exchanging data between the C4 and the line connected to the own node in synchronization with the frame synchronization pattern inserted in the C4 A frame synchronization pattern insertion unit for inserting the frame synchronization pattern inserted into the C4 of the time division multiplex frame into the C4 where the data has been transmitted / received by the data insertion unit; and a frame synchronization pattern. And transmitting means for transmitting the time-division multiplexed frame including the C4 to which the data has been transmitted and received on the transmission path, in each of the plurality of slave nodes.

[0011]

Next, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of a master node according to an embodiment of the present invention, FIG. 2 is a block diagram showing a configuration of a slave node according to an embodiment of the present invention, and FIG. FIG. 1 is a block diagram illustrating a system configuration according to one embodiment. In these figures, a master node A and slave nodes B1 to BN are connected in a loop via a transmission path C to form a loop network system (see FIG. 3).

The STM-1 frame synchronization detecting section (hereinafter referred to as the frame synchronization detecting section) 1 of the master node A
When the receiving data (RD) is received from the receiving device, the receiving clock (RC) is extracted from the receiving data and the STM-
One frame synchronization is detected and the received frame pulse (RF
P). The frame synchronization detector 1 sends the received data, the received clock, and the received frame pulse to the SOH terminator 2.

The SOH terminator 2 terminates the SOH of the STM-1 frame, which is the received data, based on the received data, the received clock, and the received frame pulse received from the frame synchronization detector 1. When terminating the SOH of the STM-1 frame, the SOH terminator 2 terminates the received data excluding the SOH, that is, the virtual C4 fixedly arranged at a predetermined position of the STM-1 frame, the received clock, and the received frame pulse. It is sent to the multi-frame synchronization detector 3.

When receiving the received data, the received clock, and the received frame pulse from the SOH terminator 2, the multi-frame synchronization detector 3 detects the multi-frame synchronization from the multi-frame synchronization pattern stored in a predetermined time slot in the virtual C4. Detect and receive multi-frame pulse (RMF
P). When generating the received multi-frame pulse, the multi-frame synchronization detector 3 sends the received data, the received clock, the received frame pulse, and the received multi-frame pulse to the loop delay corrector 6.

The clock generator 4 is a master clock (MC) of the loop network system according to one embodiment of the present invention.
K) is generated and the master clock is set to a frame pulse /
It is transmitted to a multi-frame pulse generator (hereinafter referred to as a pulse generator) 5.

When the pulse generator 5 receives the master clock from the clock generator 4, it transmits a transmission clock (SC) from the master clock, a transmission frame pulse (SFP) indicating the frame synchronization pattern position of the STM-1 frame, and a virtual A transmission multi-frame pulse (SMFP) indicating a multi-frame synchronization pattern position stored in a predetermined time slot in C4 is generated. The pulse generation unit 5 sends the transmission clock, the transmission frame pulse, and the transmission multi-frame pulse to the loop delay correction unit 6.

The loop delay correction unit 6 receives the received data, received clock, received frame pulse, and received multi-frame pulse from the multi-frame synchronization detecting unit 3, and transmits the transmitted clock, transmitted frame pulse, and transmitted multi-frame pulse from the pulse generation unit 5. Thus, the loop delay correction for the virtual C4 is performed. When the loop delay correction unit 6 performs the loop delay correction for the virtual C4, the transmission data (S
D), the transmission clock, the transmission frame pulse, and the transmission multi-frame pulse are transmitted to the add / drop unit 7.

The add / drop unit 7 sends the transmission data, the transmission clock, the transmission frame pulse,
When the transmission multi-frame pulse is received, the data from the line connected to the service channel connection unit 8 is dropped and inserted into the service channel in the virtual C4 in the transmission data. Also, the add / drop unit 7 transmits data (such as maintenance information and monitoring information) from the line connected to the housekeeping channel connection unit 9 to the housekeeping channel in the virtual C4 in the transmission data from the loop delay correction unit 6. )
Is inserted and dropped.

When the add / drop unit 7 adds / drops data to the service channel and the housekeeping channel in the virtual C 4, the transmission data with the data dropped / added to the service channel and the housekeeping channel,
The transmission clock, the transmission frame pulse, and the transmission multi-frame pulse are transmitted by the multi-frame synchronization
To send to.

When the multi-frame synchronization pattern insertion unit 10 receives the transmission data, the transmission clock, the transmission frame pulse, and the transmission multi-frame pulse from the drop-and-insert unit 7, the multi-frame synchronization pattern insertion unit 10 The multi-frame synchronization pattern is inserted into a predetermined time slot for the multi-frame synchronization pattern in the virtual C4.
The multi-frame synchronization pattern insertion unit 10 sends the transmission data with the multi-frame synchronization pattern inserted into a predetermined time slot, a transmission clock, and a transmission frame pulse to the SOH adding unit 11.

The SOH adding unit 11 transmits the transmission data from the multi-frame synchronization pattern insertion unit 10, a transmission clock,
Transmission data (virtual C4) by transmission frame pulse
, And sends the transmission data with the SOH added, the transmission clock, and the transmission frame pulse to an STM-1 frame synchronization pattern addition unit (hereinafter, referred to as a frame synchronization pattern addition unit) 12.

The frame synchronization pattern adding unit 12 adds a frame synchronization pattern to the SOH of the transmission data using the transmission data from the SOH addition unit 11, the transmission clock, and the transmission frame pulse, and converts the transmission data with the frame synchronization pattern added. The data is transmitted to the slave node B1 via the transmission line C.

Therefore, by configuring the master node A as described above, one multiframe has 20 S frames.
A predetermined time slot in the virtual C4 is defined as a multi-frame synchronization pattern in which a row and a time slot of the STM-1 frame are virtual C4, and an arbitrary number of time slots in the virtual C4. Can be generated as a housekeeping channel, and a time division multiplexed frame can be generated using the remaining time slots in the virtual C4 as service channels. Also, after the line data connected to the service channel connection unit 8 of the own node is dropped and inserted into the service channel, it can be transmitted to the next slave node B1 via the transmission path C. Further, in the master node A, the delay between the received time division multiplex frame and the time division multiplex frame generated by the own node can be corrected by the loop delay correction unit 6.

When receiving the received data from the transmission line C, the frame synchronization detecting section 1 of the slave node B1 extracts the received clock from the received data, detects the STM-1 frame synchronization, and generates a received frame pulse.
The frame synchronization detector 1 sends the received data, the received clock, and the received frame pulse to the SOH terminator 2.

The SOH terminator 2 terminates the SOH of the STM-1 frame, which is the received data, based on the received data, the received clock, and the received frame pulse received from the frame synchronization detector 1. When terminating the SOH of the STM-1 frame, the SOH terminator 2 terminates the received data excluding the SOH, that is, the virtual C4 fixedly arranged at a predetermined position of the STM-1 frame, the received clock, and the received frame pulse. It is sent to the multi-frame synchronization detector 3.

The multi-frame synchronization detecting unit 3 detects the multi-frame synchronization from the multi-frame synchronization pattern stored in a predetermined time slot in the virtual C4 based on the received data, the received clock and the received frame pulse received from the SOH terminating unit 2. Detect and generate a received multi-frame pulse. When generating the received multi-frame pulse, the multi-frame synchronization detector 3 sends the received data, the received clock, the received frame pulse, and the received multi-frame pulse to the add / drop unit 7.

Upon receiving the received data, the received clock, the received frame pulse, and the received multi-frame pulse from the multi-frame synchronization detector 3, the add / drop unit 7 receives the received data, received clock, received frame pulse, and received multi-frame pulse. The data from the line connected to the service channel connection unit 8 is dropped and inserted. The add / drop unit 7 drops and inserts data (maintenance information, monitoring information, and the like) from the line connected to the housekeeping channel connection unit 9 into the housekeeping channel in the virtual C4 in the received data.

When the add / drop unit 7 adds / drops data to the service channel and the housekeeping channel in the virtual C4, the add / drop unit 7 transmits the reception clock with the received data into which the data is dropped / added to the service channel and the housekeeping channel as transmission data. As a clock,
The reception frame pulse is sent to the multiframe synchronization pattern insertion unit 10 as a transmission frame pulse, and the reception multiframe pulse is sent as a transmission multiframe pulse.

When receiving the transmission data, transmission clock, transmission frame pulse, and transmission multi-frame pulse from the add / drop unit 7, the multi-frame synchronization pattern insertion unit 10 receives the transmission data from the transmission multi-frame pulse based on the transmission multi-frame pulse. The multi-frame synchronization pattern is inserted into a predetermined time slot for the multi-frame synchronization pattern in the virtual C4.
The multi-frame synchronization pattern insertion unit 10 sends the transmission data with the multi-frame synchronization pattern inserted into a predetermined time slot, a transmission clock, and a transmission frame pulse to the SOH adding unit 11.

The SOH adding unit 11 transmits the transmission data from the multiframe synchronization pattern insertion unit 10, a transmission clock,
Transmission data (virtual C4) by transmission frame pulse
The transmission data, the transmission clock, and the transmission frame pulse to which the SOH is added are transmitted to the frame synchronization pattern adding unit 12.

The frame synchronization pattern adding unit 12 adds a frame synchronization pattern to the SOH of the transmission data using the transmission data from the SOH addition unit 11, the transmission clock, and the transmission frame pulse, and transmits the transmission data with the frame synchronization pattern added. The data is transmitted to the slave node B2 via the transmission line C.

Therefore, by configuring the slave node B1 as described above, one multi-frame is composed of 20 STM-1 frames, and the rows and time slots of this STM-1 frame are assumed to be virtual C4. Virtual C
4 is a multi-frame synchronization pattern, an arbitrary number of time slots in the virtual C4 is a housekeeping channel, and the remaining time slots in the virtual C4 are service channels. After subordinate synchronization, the line data connected to the service channel connection unit 8 of the own node is dropped and inserted into the service channel, and can be transmitted to the next slave node B2 via the transmission path C. The other slave nodes B2 to BN have the same configuration as the above-described slave node B1, and their operations are also the same. However, the slave node BN drops the line data connected to the service channel connection unit 8 of the own node into the service channel, and then sends out the data to the master node A via the transmission line C.

FIG. 4 is a diagram showing a frame configuration according to one embodiment of the present invention. In the figure, one multiframe is 2
It consists of zero STM-1 frames F (1) to F (20), and the rows (1 to 9) and the time slots (1 to 9) of the STM-1 frame are SOH, and the rows (1 to 9) of the STM-1 frame are 1-9) and time slots (11-270) are virtual C4s.

In the virtual C4, a predetermined time slot is used as a multi-frame synchronization pattern, an arbitrary number of time slots is used as a housekeeping channel, and the remaining time slots are used as service channels.

FIG. 5 is a block diagram showing a configuration of a master node according to another embodiment of the present invention, and FIG. 6 is a block diagram showing a configuration of a slave node according to another embodiment of the present invention. The system configuration of another embodiment of the present invention is shown in FIG.
It is assumed that a master node A and slave nodes B1 to BN are connected in a loop via a transmission line C to form a loop network system, similarly to the system configuration of the embodiment of the present invention shown in FIG.

When receiving the received data (RD) from the transmission line C, the STM-1 frame synchronization detecting unit (hereinafter, referred to as a frame synchronization detecting unit) 21 of the master node A extracts a received clock (RC) from the received data. With STM
-1 frame synchronization is detected and the received frame pulse (RF
P). The frame synchronization detecting section 21 converts the received data, the received clock and the received frame pulse into SO
It is sent to the H terminal 22.

The SOH termination unit 22 is a frame synchronization detection unit 2
1, the SOH of the STM-1 frame, which is the received data, is terminated by the received data, the received clock, and the received frame pulse. At this time, the SOH terminating unit 2 uses the AU pointer in the SOH of the STM-1 frame to indicate the reception envelope signal (REV) indicating the position of VC4.
And the received data excluding SOH, that is, STM-1
The VC4 of the frame, the reception clock, the reception frame pulse, and the reception envelope signal are transmitted to the VC4 termination unit 23.
To send to.

The VC4 terminating unit 23 uses the received data, the received clock, the received frame pulse, and the received envelope signal received from the SOH terminating unit 22 to generate a VC4 PO.
Terminate H. When the VC4 terminator 23 terminates the POH of the VC4, the received data excluding the POH, that is, the STM-1
The C4 of the frame, the reception clock, the reception frame pulse, and the reception envelope signal are sent to the multi-frame synchronization detection unit 24.

When receiving the received data, the received clock, the received frame pulse, and the received envelope signal from the VC4 terminator 23, the multiframe synchronization detector 24 receives the received data, received clock, received frame pulse, and received envelope signal from the multiframe synchronization pattern stored in a predetermined time slot in C4. Detects frame synchronization and generates a received multi-frame pulse (RMFP). Upon generating the received multi-frame pulse, the multi-frame synchronization detector 24 sends the received data, the received clock, the received frame pulse, the received envelope signal, and the received multi-frame pulse to the loop delay corrector 27.

A clock generator 25 generates a master clock (MCK) of a loop network system according to another embodiment of the present invention, and uses the master clock as a frame pulse / multiframe pulse generator (hereinafter referred to as a pulse generator) 26. To send to.

When the pulse generation unit 26 receives the master clock from the clock generation unit 25, the transmission clock (SC) and the transmission frame pulse (SFP) indicating the frame synchronization pattern position of the STM-1 frame are received from the master clock.
And a transmission envelope signal (SE) indicating the position of VC4.
V) and a transmission multi-frame pulse (SMFP) indicating a multi-frame synchronization pattern position stored in a predetermined time slot in C4. The pulse generation unit 26 sends the transmission clock, the transmission frame pulse, the transmission envelope signal, and the transmission multi-frame pulse to the loop delay correction unit 27.

The loop delay correction section 27 receives the received data from the multi-frame synchronization detecting section 3, the received clock, the received frame pulse, the received envelope signal, the received multi-frame pulse, the transmitted clock from the pulse generating section 5, the transmitted frame pulse, The loop delay correction for C4 is performed using the transmission envelope signal and the transmission multi-frame pulse. When the loop delay correction unit 27 performs the loop delay correction for C4, the transmission data (SD) after the delay correction is performed.
, A transmission clock, a transmission frame pulse, a transmission envelope signal, and a transmission multi-frame pulse to the add / drop unit.

Upon receiving the transmission data, the transmission clock, the transmission frame pulse, the transmission envelope signal, and the transmission multi-frame pulse from the loop delay correction unit 27, the add / drop unit 28 receives the service in C4 in the transmission data. Data from the line connected to the service channel connection unit 29 is dropped and inserted into the channel. Also, the add / drop unit 28 transmits data (such as maintenance information and monitoring information) from the line connected to the housekeeping channel connection unit 30 to the housekeeping channel in C4 in the transmission data from the loop delay correction unit 27. Is inserted and dropped.

When the add / drop unit 28 drops and inserts data into the service channel and the housekeeping channel in C4, the drop and insert unit 28 transmits the transmission data with the data dropped into the service channel and the housekeeping channel, a transmission clock, a transmission frame pulse, and the like. , The transmission envelope signal and the transmission multi-frame pulse are transmitted to the multi-frame synchronization pattern insertion unit 31.

Upon receiving the transmission data, transmission clock, transmission frame pulse, transmission envelope signal, and transmission multi-frame pulse from the drop-and-insert unit 28, the multi-frame synchronization pattern insertion unit 31 generates the multi-frame synchronization pattern based on the transmission multi-frame pulse. The multi-frame synchronization pattern is inserted into a predetermined time slot for the multi-frame synchronization pattern in C4 in the transmission data. The multi-frame synchronization pattern insertion unit 31 sends the transmission data in which the multi-frame synchronization pattern is inserted into a predetermined time slot, the transmission clock, the transmission frame pulse, and the transmission envelope signal to the VC4 generation unit 32.

The VC4 generator 32 transmits the transmission data from the multiframe synchronization pattern insertion unit 31, a transmission clock,
The POH is added to the transmission data (C4) by the transmission frame pulse and the transmission envelope signal, and the transmission data with the POH added, the transmission clock, the transmission frame pulse, and the transmission envelope signal are transmitted to the SOH adding unit 33.
To send to.

The SOH adding unit 33 uses the transmission data from the VC4 generation unit 32, a transmission clock, a transmission frame pulse, and a transmission envelope signal to transmit data (V
C4) to which SOH is added, and the transmission data to which SOH is added, the transmission clock, and the transmission frame pulse are STM-
It is sent to a one-frame synchronization pattern adding unit (hereinafter referred to as a frame synchronization pattern adding unit) 34.

The frame synchronization pattern adding section 34 adds a frame synchronization pattern to the SOH of the transmission data using the transmission data from the SOH addition section 33, the transmission clock, and the transmission frame pulse, and transmits the transmission data with the frame synchronization pattern added. The data is transmitted to the slave node B1 via the transmission line C.

Therefore, by configuring the master node A as described above, one multiframe has 20 S frames.
A predetermined time slot in C4 of this STM-1 frame is used as a multi-frame synchronization pattern, an arbitrary number of time slots in C4 are used as a housekeeping channel, and the remaining time in C4 is used. A time-division multiplex frame using a slot as a service channel can be generated. Further, after the line data connected to the service channel connection unit 29 of the own node is dropped and inserted into the service channel, it can be transmitted to the next slave node B1 via the transmission line C. Further, in the master node A, the delay between the received time division multiplex frame and the time division multiplex frame generated in the own node can be corrected by the loop delay correction unit 27.

When receiving the received data from the transmission line C, the frame synchronization detecting section 21 of the slave node B 1 extracts the received clock from the received data and sets the STM-1
Detects frame synchronization and generates a received frame pulse. The frame synchronization detector 21 sends the received data, the received clock, and the received frame pulse to the SOH terminator 22.

The SOH termination section 22 is a frame synchronization detection section 2
1, the SOH of the STM-1 frame, which is the received data, is terminated by the received data, the received clock, and the received frame pulse. At this time, the SOH terminating unit 2 generates a reception envelope signal indicating the position of the VC 4 by the AU pointer in the SOH of the STM-1 frame,
The received data excluding the SOH, that is, the VC4 of the STM-1 frame, the received clock, the received frame pulse, and the received envelope signal are sent to the VC4 termination unit 23.

The VC4 terminator 23 uses the received data, the received clock, the received frame pulse and the received envelope signal received from the SOH terminator 22 to generate a VC4 PO.
Terminate H. When the VC4 terminator 23 terminates the POH of the VC4, the received data excluding the POH, that is, the STM-1
The C4 of the frame, the reception clock, the reception frame pulse, and the reception envelope signal are sent to the multi-frame synchronization detection unit 24.

When receiving the received data, the received clock, the received frame pulse, and the received envelope signal from the VC4 terminating unit 23, the multi-frame synchronization detecting unit 24 converts the multi-frame synchronization pattern stored in a predetermined time slot in C4 into a multi-frame. A frame synchronization is detected to generate a received multi-frame pulse. Upon generating the received multi-frame pulse, the multi-frame synchronization detecting unit 24 sends the received data, the received clock, the received frame pulse, the received envelope signal, and the received multi-frame pulse to the add / drop unit 28.

Upon receiving the received data, the received clock, the received frame pulse, the received envelope signal, and the received multi-frame pulse from the multi-frame synchronization detecting section 24, the add / drop unit 28 receives the received data, the received multi-frame pulse, and the C4 in the received data. Service channel connection unit 2 for service channel
The data from the line connected to 9 is dropped and inserted. The drop-and-insert unit 28 drops and inserts data (maintenance information, monitoring information, and the like) from the line connected to the housekeeping channel connection unit 30 into the housekeeping channel in C4 in the received data.

When the add / drop unit 28 adds / drops data to the service channel and the housekeeping channel in C4, the add / drop unit 28 uses the received data in which the data is dropped / added to the service channel and the housekeeping channel as transmission data, and sets the reception clock to the transmission clock. The reception frame pulse is transmitted to the multi-frame synchronization pattern insertion unit 31 as a transmission frame pulse, the reception envelope signal is transmitted as a transmission envelope signal, and the reception multi-frame pulse is transmitted as a transmission multi-frame pulse.

When receiving the transmission data, transmission clock, transmission frame pulse, transmission envelope signal, and transmission multi-frame pulse from the drop-and-insert unit 28, the multi-frame synchronization pattern insertion unit 31 generates the transmission multi-frame pulse based on the transmission multi-frame pulse. The multi-frame synchronization pattern is inserted into a predetermined time slot for the multi-frame synchronization pattern in C4 in the transmission data. The multi-frame synchronization pattern insertion unit 31 sends the transmission data in which the multi-frame synchronization pattern is inserted into a predetermined time slot, the transmission clock, the transmission frame pulse, and the transmission envelope signal to the VC4 generation unit 32.

The VC4 generator 32 transmits the transmission data from the multiframe synchronization pattern insertion unit 31, a transmission clock,
The POH is added to the transmission data (C4) by the transmission frame pulse and the transmission envelope signal, and the transmission data with the POH added, the transmission clock, the transmission frame pulse, and the transmission envelope signal are transmitted to the SOH adding unit 33.
To send to.

The SOH adding unit 33 uses the transmission data from the VC4 generation unit 32, the transmission clock, the transmission frame pulse, and the transmission envelope signal to transmit data (V
C4), the SOH is added, and the transmission data with the SOH added, the transmission clock, and the transmission frame pulse are sent to the frame synchronization pattern adding unit 34.

The frame synchronization pattern adding section 34 adds a frame synchronization pattern to the SOH of the transmission data using the transmission data from the SOH addition section 33, the transmission clock, and the transmission frame pulse, and transmits the transmission data with the frame synchronization pattern added. The data is transmitted to the slave node B2 via the transmission line C.

Therefore, by configuring the slave node B 1 as described above, one multi-frame has 20 STs.
M-1 frame, and C of this STM-1 frame
4 is a multi-frame synchronization pattern, an arbitrary number of time slots in C4 is a housekeeping channel, and the remaining time slots in C4 are service channels. Then, after the line data connected to the service channel connection unit 29 of the own node is dropped and inserted into the service channel, it can be transmitted to the next slave node B2 via the transmission path C. In addition, other slave nodes B2 to
BN has the same configuration as the slave node B1, and its operation is also the same. However, slave node B
N drops the line data connected to the service channel connection unit 29 of its own node into the service channel, and then sends it out to the master node A via the transmission line C.

FIG. 7 is a diagram showing a frame configuration according to another embodiment of the present invention. In the figure, one multi-frame is composed of 20 STM-1 frames F (1) to F (20), and rows (1 to 9) and time slots (1 to 9) of the STM-1 frame are SOH.

VC4 whose head position is specified by an AU pointer (not shown) in the SOH is composed of POH and C4. In C4, a predetermined time slot is a multi-frame synchronization pattern, and an arbitrary number of time slots Is a housekeeping channel, and the remaining time slots are service channels.

As described above, the C4 is fixedly arranged at a predetermined position in the STM-1 frame constituting the time division multiplex frame to be a virtual C4, and a frame synchronization pattern is inserted into the virtual C4. As a result, a time-division multiplex frame in which one multi-frame includes 20 STM-1 frames can be realized, and the configuration of one multi-frame can be freely set. That is, STM-1
1. One multi-frame having a frame as a basic frame
In 5 msec, a time-division multiplex frame suitable for accommodating a multimedia interface in which one frame is 125 μsec can be realized.

Further, ST constituting the time division multiplex frame
By inserting a frame synchronization pattern into the C4 of the M-1 frame, a time division multiplex frame in which one multiframe is composed of 20 STM-1 frames can be realized. Can be set freely. That is, one multi-frame having an STM-1 frame as a basic frame is 2.5 msec.
Thus, a time division multiplex frame suitable for accommodating a multimedia interface in which one frame is 125 μsec can be realized.

In one embodiment and another embodiment of the present invention, a case has been described where one multi-frame is composed of 20 STM-1 frames. However, one multi-frame is composed of one or more STM-1 frames. It is obvious that the present invention can be applied to the case, and the present invention is not limited to this.

[0067]

As described above, according to the loop-type data transmission system of the present invention, C4 is fixedly arranged at a predetermined position in the STM-1 frame constituting the time division multiplex frame to be a virtual C4, By inserting a frame synchronization pattern into the virtual C4, there is an effect that the configuration of one multi-frame can be set freely.

According to another loop type data transmission system of the present invention, an STM forming a time division multiplex frame
By inserting the frame synchronization pattern in C4 of -1 frame, there is an effect that the configuration of one multi-frame can be set freely.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a master node according to one embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a slave node according to an embodiment of the present invention.

FIG. 3 is a block diagram illustrating a system configuration according to an embodiment of the present invention.

FIG. 4 is a diagram illustrating a frame configuration according to an embodiment of the present invention.

FIG. 5 is a block diagram illustrating a configuration of a master node according to another embodiment of the present invention.

FIG. 6 is a block diagram illustrating a configuration of a slave node according to another embodiment of the present invention.

FIG. 7 is a diagram illustrating a frame configuration according to another embodiment of the present invention.

[Explanation of symbols]

 1, 21 STM-1 frame synchronization detection unit 2, 22 SOH termination unit 3, 24 multiframe synchronization detection unit 6, 27 loop delay correction unit 7, 28 drop and insertion unit 8, 29 service channel connection unit 9, 30 housekeeping channel Connection section 10, 31 Multi-frame synchronization pattern insertion section 11, 33 SOH addition section 12, 34 STM-1 frame synchronization pattern addition section 23 VC4 termination section 32 VC4 generation section

Continuation of front page (56) References JP-A-5-160843 (JP, A) JP-A-5-145566 (JP, A) JP-A-5-95362 (JP, A) JP-A-5-37537 (JP) JP-A-5-7219 (JP, A) JP-A-4-365243 (JP, A) JP-A-4-35238 (JP, A) JP-A-3-16347 (JP, A) 1-320838 (JP, A) CCITT BLUE BOOK (VOLUME III FASCI CLE III III. 4.) GENERAL ASPECTS OF DIGITAL TRANSMISSION S YSTEMS; ) investigated the field (Int.Cl. ^6, DB name) H04L 12/42 - 12/437 H04J 3/00 - 3/26 H04L 5/22 - 5/26 INSPEC (DIALOG) JICST file (JOIS) WPI (DIAL G)

Claims (2)

(57) [Claims] A master node and a plurality of slave nodes are connected in a loop via a transmission line, and one or more STM-
A loop-type data transmission system for performing data transmission between the master node and the plurality of slave nodes using a time-division multiplex frame consisting of one frame, wherein C4 including data information in the STM-1 frame is Frame synchronization pattern insertion means for inserting a frame synchronization pattern for synchronizing the virtual C4 into a virtual C4 fixedly arranged at a predetermined position; and data between a line connected to the own node and the virtual C4. Data insertion means for transmitting and receiving
Transmitting means for transmitting, on the transmission path, the time division multiplex frame including the virtual C4 in which the frame synchronization pattern is inserted and the data transmission / reception is performed, and the time division multiplex frame transmitted on the transmission path; Loop correction means for correcting a delay between the time-division multiplex frame received via the transmission path and the time-division multiplex frame is provided in the master node, and inserted into the virtual C4 of the time division multiplex frame received via the transmission path. Data insertion means for transmitting and receiving data between the virtual C4 and a line connected to the own node in synchronization with the frame synchronization pattern which has been inserted, and inserted into the virtual C4 of the time-division multiplexed frame. A frame synchronization pattern insertion unit for inserting the frame synchronization pattern into the virtual C4 to which the data has been transferred by the data insertion unit; Transmitting means for transmitting the time-division multiplexed frame including the virtual C4 to which the frame synchronization pattern has been inserted and the data has been transmitted / received, on the transmission path, for each of the plurality of slave nodes. Loop type data transmission system. 2. A master node and a plurality of slave nodes are connected in a loop via a transmission path, and one or more STM-
A loop-type data transmission system for performing data transmission between the master node and the plurality of slave nodes using a time-division multiplex frame composed of one frame, wherein a C4 including data information in the STM-1 frame is provided. The C4
Frame synchronization pattern insertion means for inserting a frame synchronization pattern for synchronizing data, data insertion means for exchanging data between the line connected to the own node and the C4, and the frame synchronization pattern being inserted. Transmitting means for transmitting the time-division multiplexed frame including the C4 in which the data has been transmitted and received on the transmission path, and the time-division multiplexed frame transmitted on the transmission path and the time-division multiplexed frame received via the transmission path. Loop correction means for correcting a delay between the time-division multiplexed frame and the time-division multiplexed frame is provided in the master node, and the slave node is dependent on the frame synchronization pattern inserted into the C4 of the time-division multiplexed frame received via the transmission path. Data insertion means for exchanging data between the C4 and the line connected to the own node, and inserting the data into the C4 of the time division multiplex frame. A frame synchronization pattern insertion unit that inserts the frame synchronization pattern into the C4 where the data has been transmitted and received by the data insertion unit, and the frame synchronization pattern has been inserted and the data has been transmitted and received. Transmitting means for transmitting the time-division multiplexed frame including C4 on the transmission path, provided in each of the plurality of slave nodes.