JPH10322380A - Transmission delay difference absorbing system in optical pds system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To absorb a transmission delay time difference on a salve station-side and to prevent inconvenience at the time of switching a transmission line by inserting delay data measured in the delay time measuring part of a master station device into down data, receiving it in a slave station device, detecting delay data, holding '0' system delay data and '1' system delay data and selecting either data so as to control the transmission timing of up data. SOLUTION: The frame synchronous pulse of outgoing data, which is received in a synchronism detection part 202 via a '0' system transmission line, is detected. A synchronous counter 203 is reset by the timing and counting is executed at every frame. The frame synchronous pulse of outgoing data, which is received via a '1' system transmission line, is detected. A comparison part 204 compares the timing with the output timing of the synchronous counter 203 and the delay time difference of a reception side is obtained. The output timing of the synchronous counter 203 is shifted by the received delay time difference from the next frame receiving a switch request signal and the delay time difference of the reception side at the time of switching the system is adjusted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical PDS (Pass) for connecting a master station device and a plurality of slave station devices by optical single-core bidirectional transmission using a TCM transmission system and a TDMA control system.
In particular, when the optical transmission / reception unit employs a redundant configuration, the transmission delay time difference of the optical transmission line is not equal even if the distance intervals between the optical transmission lines constituting the redundant system are not equal. The present invention relates to a transmission delay difference absorption scheme that absorbs power and realizes instantaneous interruption forced switching.

[0002]

2. Description of the Related Art FIG. 7 is a block diagram showing a circuit for controlling a transmission delay time on the slave station side of a conventional optical PDS system. The slave station device includes an optical transmission / reception unit 221, a synchronization detection unit 22
2, a synchronization counter 223, a delay data detection unit 223, a downlink signal processing unit 225, an uplink signal processing unit 227, and a delay control unit 226.

[0003] In an optical PDS system in which the section from the master station to the star coupler in the optical single-core bidirectional transmission has a redundant system of two systems of system 0 and system 1, the optical transmission paths of the master station device and the slave station device are different. Therefore, when switching between the two transmission lines is performed, the system becomes out of synchronization and the transmission line is switched so that the signal is not interrupted for a long time. The transmission distances of the two systems are made equal to each other so that the transmission delay time is the same regardless of which optical transmission line is used.

[0004]

In this conventional optical PDS system configuration, a transmission delay time difference due to a difference in optical transmission line cannot be absorbed.
The transmission distance must be equalized by adjusting the length of the optical fiber. If the transmission distance is different, as shown in FIG. 8, when switching from the 0 system to the 1 system, the upstream data and the downstream data collide. (See FIG. 8B), and synchronization is lost.

[0005] After that, in order to achieve synchronization, the measurement must be performed again from the delay measurement, so that the switching causes a long-term disconnection of the line and a problem that the service is interrupted for a long time.

Accordingly, the present invention has been made in view of the above problems, and has as its object to provide a redundant configuration of a transmission section from a master station device to a star coupler in order to improve reliability. The difference in transmission delay due to the difference in transmission path is absorbed by the slave station device side, and the transmission delay difference that can prevent the service from being interrupted for a long time due to a long line disconnection when switching the transmission path. It is to provide an absorption system.

[0007]

In order to achieve the above object, a transmission delay difference absorption system according to the present invention employs a TCM (Time Compression) system in which a master station apparatus and a plurality of slave station apparatuses are connected.
Multiplex) transmission method and TDMA (Tim
e Division Multiple Accesses
s) Connected by optical single-core bidirectional transmission using a control method,
The section from the master station device to the star coupler is 0 system / 1 system and 2
Optical PDS (Passive D) having a redundant system configuration
In the (Star) system, the slave station receives the downlink data from the master station for phase adjustment on the receiving side in the optical transmitting / receiving unit, and detects the frame synchronization pulse. The system counter receives the data of the system 1 after the system 0 and counts the data of the system 1 and compares the output timing of the synchronous counter, which is the synchronization timing of the system 0, with the reception timing of the system 1. The comparison unit that compares the reception side timing and controls the synchronization timing, and inserts the delay data measured by the delay time measurement unit of the master station device into the downlink data, and receives the downlink data by the optical transceiver unit of the slave station device. And a delay data detection unit for extracting delay data for delay adjustment on the transmission side, a memory unit for holding 0-system delay data, and a memory for holding 1-system delay data Unit, a system selection signal detection unit for detecting a selection signal of the optical transmission line (0 system / 1 system) from the system selection control unit of the master station device, It is characterized by including a selection unit that performs selection control, a delay control unit that controls transmission timing of uplink data based on the selected delay data, and an optical transmission and reception unit that transmits uplink data to the master station device.

[0008]

Embodiments of the present invention will be described below. In a preferred embodiment of the present invention, the slave station device receives a downlink data from the master station device and detects a frame synchronization pulse (202 in FIG. 3) for receiving side adjustment, A synchronization counter (20 in FIG. 3) that counts in synchronization with the timing of the frame synchronization pulse.
3), the reception data of the 1 system is received next to the 0 system, and the output timing of the synchronization counter, which is the synchronization timing of the 0 system, is compared with the reception timing of the 1 system.
And a comparing unit (204 in FIG. 3) for comparing the receiving-side timing of the system and controlling the synchronization timing, and a delay-data detecting unit (204) for extracting delay data transmitted from the master station device for transmission-side adjustment. 3), a 0-system / 1-system memory unit (206, 207 in FIG. 3) for holding delay data,
Optical transmission path from system selection control unit of master station device (0 system / 1 system)
System selection signal detection unit (20 in FIG. 3) for detecting the selection signal of
8) and 0 by the system selection signal from the system selection signal detector.
A selection unit (20 in FIG. 3) for selecting the delay data of the system 1 and the system 1
9), a delay control unit (211 in FIG. 2) that controls the transmission timing of uplink data based on the selected delay data,
An optical transmitting / receiving unit (2 in FIG. 3) for transmitting uplink data to the master station device.
01).

[0009]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of the present invention; FIG. 1 is a block diagram showing the configuration of one embodiment of the present invention. Referring to FIG. 1, in the present embodiment, a master station device 1 and a plurality (n) of
(Time Compression Multipl
ex) Transmission system and TDMA (Time Divisi)
On-Multiple Access) control system is used for optical single-core bidirectional transmission, and the section from the master station device 1 to the star coupler 7 has a two-system redundant configuration of a 0-system optical transmission line 5 and a 1-system optical transmission line 6. Optical PDS (Passi
ve Double Star) system.

FIG. 3 is a diagram showing a configuration of a slave station device according to one embodiment of the present invention. Referring to FIG. 3, the slave station device receives downlink data from the master station device 1 for reception side adjustment,
A synchronization detection unit 202 for detecting a frame synchronization pulse, and a synchronization counter 20 for counting in synchronization with the timing.
3 and a comparing section 204 for comparing the reception timings of the 0-system and the 1-system and controlling the synchronization timing, and detects the delay data transmitted from the master station device for adjusting the transmission side. Unit 205 and 0-system /
1-system memory units 206 and 207, a system-selection-signal detection unit 208 that detects a transmission-line selection signal, and a selection unit that selects 0-system and 1-system delay data based on a selection signal from the system-selection-signal detection unit. 209 and a delay control unit 211 for controlling the transmission timing of the uplink data based on the selected delay data
And an optical transmitting / receiving unit 201 for transmitting uplink data to the master station device.
And have

FIG. 2 is a diagram showing a configuration of a master station device according to one embodiment of the present invention. Referring to FIG. 2, the master station device includes, for transmission control, downlink signal processing units 101 and 111 for each of system 0 and system 1, delay time measurement unit 104 for measuring delay time from received data, A delay time transfer unit 103, 1 for setting delay data in a downlink signal based on the output of 114
13 and the optical transmission / reception unit 0 system 105 or 1 system 115
A down signal is sent to the 0-system or 1-system optical transmission lines 5 and 6 via the optical transmission line. A delay time measuring unit 104 for measuring and calculating a delay delay from
114, the upstream signal processing units 102 and 112, and the 0 system,
A selection unit 122 that selects the outputs of the 1-system uplink signal processing units 102 and 112 and outputs the selected signal as a received signal, and a system selection control unit 121 that controls selection of the 0-system / 1-system. You.

The receiving-side adjustment unit of the slave station device 2 receives the downlink data from the master station device 1 and detects the frame synchronization pulse by the synchronization detection unit 202. At this timing, the synchronization counter 203 is reset and reset. Perform frame counting.

Next, the comparison unit 20 receives downlink data of another system and detects a frame synchronization pulse in the synchronization detection unit 202.
In step 4, the input timing is compared with the output timing of the synchronous counter 203 to determine a reception delay time difference.

In the transmission-side adjustment unit of the slave station device 2, the delay data detection unit 205 extracts the delay data subjected to the delay measurement / calculation processing by the delay time measurement units 104 and 114 of the master station device 1.

Further, the system selection information of the optical transmission line is detected by the system selection signal detection unit 208 from the master station device 1, and the received delay data is stored in the memory 0 system 206 based on the system selection information. A selection is made as to whether the data is to be retained in the system 207.

Next, the selector 209 selects the delay data of the system selected from the system 0 or the system 1 and outputs the selected data to the delay controller 211. The delay controller 211 increments the delay data by the value of the delay data. The data is transmitted to the master station device 1 with a delay.

Next, the operation of one embodiment of the present invention will be described. FIG. 4 is a timing chart for explaining the comparison operation on the receiving side in the slave station device according to one embodiment of the present invention. FIG. 5 is a timing chart for explaining the switching operation on the receiving side in the slave station device according to one embodiment of the present invention. FIG. 6 is a timing chart for explaining the switching operation on the transmitting side in the slave station device according to one embodiment of the present invention.

First, referring to FIG. 3 and FIG.
In the receiving-side adjustment unit, in the reception-side adjustment unit, the synchronization detection unit 202 detects a frame synchronization pulse of downlink data received via the 0-system transmission line 5, and
At this timing, the synchronous counter 203 is reset, and the synchronous counter 203 performs counting for each frame.

Referring to FIG. 4, next, a frame synchronization pulse of downlink data received via the 1-system transmission line 6 is detected. This timing is compared with the output timing of the synchronization counter 203 by the comparison unit 204 to determine the delay time difference Tn on the receiving side.

Next, the switching operation on the receiving side in the slave station device 2 will be described with reference to FIGS. 2, 3 and 5. When a switching request signal from the system selection control unit 121 of the master station device 1 is received. From the next frame, the output timing of the synchronization counter 203 is shifted by the reception delay time difference Tn,
The output timing detected at 02 (timing of synchronization detection when the 1 system is selected) is compared with the output of the synchronization counter 203 by the comparison unit 204. If the synchronization is established, the switching is completed. As described above, the delay time difference on the receiving side at the time of system switching is adjusted.

Next, the switching operation on the transmitting side in the slave station device 2 will be described with reference to FIGS. 2 and 6. In the transmitting side adjusting unit, the switching request signal from the system selection control unit 121 of the master station device 1 is transmitted. Is transmitted from the selection unit 209 in the frame next to the memory 1 received from the memory 1 system 207, the uplink data is delayed by the delay control unit 211 by the delay data Nc1, and transmitted to the master station device. Thus, the delay time difference on the transmission side due to the switching of the optical transmission path is adjusted.

[0022]

As described above, in the transmission delay difference absorption system of the present invention, in order to improve the reliability, when the transmission section from the master station apparatus to the star coupler has a redundant configuration, the optical transmission path Because the difference in transmission delay time due to the difference can be absorbed by the slave station device side, it is possible to prevent a long-term line disconnection and a long service interruption when the transmission path is switched.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the overall configuration of a PDS system according to an embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a master station device of the PDS system according to one embodiment of the present invention.

FIG. 3 is a block diagram illustrating a configuration of a slave station device according to one embodiment of the present invention.

FIG. 4 is a time chart showing a comparison operation on the receiving side according to one embodiment of the present invention.

FIG. 5 is a time chart showing a switching operation on the receiving side according to one embodiment of the present invention.

FIG. 6 is a time chart showing a switching operation on the transmission side according to one embodiment of the present invention.

FIG. 7 is a block diagram illustrating a configuration of a slave station device according to the related art.

FIG. 8 is a time chart illustrating a switching operation according to the related art.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 master station device 2 slave station device 1 3 slave station device 2 4 slave station device n 5 0-system optical transmission line 6 1-system optical transmission line 7 star coupler 101 downstream signal processing unit (0 system) 102 upstream signal processing unit (0 103) Delay time transfer unit (0 system) 104 Delay time measurement unit (0 system) 105 Optical transmission / reception unit (0 system) 106 Downlink signal processing unit (1 system) 107 Uplink signal processing unit (1 system) 108 Delay time transfer Unit (1 system) 109 Delay time measurement unit (1 system) 110 Optical transmission / reception unit (1 system) 111 System selection control unit 112 Selection unit 201 Optical transmission / reception unit 202 Synchronization detection unit 203 Synchronization counter 204 Comparison unit 205 Delayed data detection unit 206 Memory 0 system 207 Memory 1 system 208 System selection signal detection unit 209 Selection unit 210 Downlink signal processing unit 211 Delay control unit 212 Uplink signal processing unit 220 Optical transmission / reception unit 221 Synchronization Out section 222 synchronization counter 223 delays the data detecting unit 224 downlink signal processor 225 delay controller 226 uplink signal processor

Claims (3)

[Claims] 1. A master station device and a plurality of slave station devices are connected to a TCM (Ti
me Compression Multiplex)
Transmission system and TDMA (Time Division)
Optical PDS (Passive Double Star) having a redundant configuration of 0 system / 1 system and 2 systems in the section from the master station device to the star coupler by connecting using a single access bi-directional transmission using a Multiple Access control system.
In the system, the slave station device is an optical transmitting / receiving unit, which receives downlink data from the master station device for phase adjustment on the receiving side, detects a frame synchronization pulse, and synchronizes with the timing of the frame synchronization pulse. And a synchronization counter that counts the number of received signals. The received data of the system 1 is received next to the system 0, and the output timing of the synchronization counter, which is the synchronization timing of the system 0, is compared with the reception timing of the system 1. A comparison unit that compares the reception timing of the system and controls the synchronization timing, and the delay data measured by the delay time measurement unit of the master station device is inserted into the downlink data, and the downlink data is transmitted by the optical transmission and reception unit of the slave station device. , A delay data detection unit that extracts delay data for delay adjustment on the transmission side, a 0-system memory unit that holds 0-system delay data, and a 1-system delay data. And the 1-system memory section for lifting, the optical transmission path from the system selection control portion of the master station (the 0-system / 1 system)
And a system selection signal detection unit that detects the selection signal of the above. The delay data extracted by the delay data detection unit based on the selection signal is stored and held in a 0-system or 1-system memory unit. A selection unit that controls selection from 0-system delay data or 1-system delay data by a signal, a delay control unit that controls the transmission timing of uplink data based on the selected delay data, and a light that transmits the uplink data to the master station device. A transmission / reception unit, comprising: a transmission delay difference absorption method for an optical PDS system. 2. The method according to claim 1, wherein the master station device and the plurality of slave station devices are connected by TCM (TiM).
me Compression Multiplex)
Transmission system and TDMA (Time Division)
An optical PDS (Passive Double Sta) having a redundant configuration of a 0-system / 1-system and a 2-system redundant section from the master station device to the star coupler is connected by optical single-core bidirectional transmission using a multiple access (Multiple Access) control method.
r) In the system, the slave station device receives downlink data from the master station device for receiving side adjustment, detects a frame synchronization pulse, and counts in synchronization with the timing of the frame synchronization pulse. And a comparing unit that controls the synchronization timing by comparing the reception timings of the 0-system and the 1-system, and delay data for extracting delay data transmitted from the master station device for transmission-side adjustment. A detection unit, a 0-system / 1-system storage unit that holds delay data, a system selection signal detection unit that detects a transmission path selection signal, a selection unit that performs control using a selection signal, and transmission based on the selected delay data. An optical PDS system comprising: a delay control unit that controls timing. 3. The method according to claim 1, wherein the master station device and the plurality of slave station devices are connected by TCM (Ti
me Compression Multiplex)
And TDMA (Time Division Multi)
An optical PD that is connected by optical single-core bidirectional transmission using an I / O access control system and has a redundant system configuration of 0 system / 1 system and 2 systems in the section from the master station device to the star coupler.
In an S (Passive Double Star) system, a slave station device receives downlink data from a master station device for phase adjustment and detects a frame synchronization pulse, and counts in synchronization with the timing of the frame synchronization pulse. A synchronization counter, and a comparison unit for comparing the output of the synchronization counter with the output of the synchronization detection unit, and the frame synchronization of downlink data received from the master station device via the 0-system transmission path via the star coupler. After resetting the synchronization counter with the pulse, the frame synchronization pulse of the downlink data received via the star coupler via the 1-system transmission line is detected, and the detection timing of the synchronization pulse, the output timing of the synchronization counter, and the comparison unit The delay time difference Tn between the two systems is determined by comparing The output timing of the synchronization counter is shifted by the delay time difference Tn from the frame of the above frame, and the phase difference between the output timing of the detection signal of the synchronization detection unit and the output timing of the detection signal is compared by the comparison unit. A delay data detection unit that detects delay data received from the master station device, and holds the delay data detected by the delay data detection unit in a 0-system or 1-system storage unit; A system selection signal detecting unit that detects a system switching request, based on the delay data held in the storage unit corresponding to the system to be switched from the next frame that has received the system switching request, An optical PDS system, wherein data is transmitted with a delay.