KR960003164A - Synchronous Optical Transmission - Google Patents

Abstract

The present invention relates to a DSI service unit, a DSIE service unit, a switch unit, an AU multiplexing unit, a DS3 service unit, a through unit, an optical transmission / reception unit, an overall control unit of a system, a data communication unit, , By implementing an optical transmission device including a clock supply unit, multiplexing subscriber lines in a subscriber network between an exchange side and a subscriber axis, optically transmitting them through optical fibers, and demultiplexing them in a large station to connect each service. And maintenance can be handled locally or remotely using CIT instructions.

Description

Synchronous Optical Transmission

As this is a public information case, the full text was not included.

1 is a multiplex structure diagram of the present invention in an optical subscriber transmission system,

2 is a functional configuration diagram of the present invention,

3 is a system monitoring control configuration of the present invention,

4 is a unit configuration diagram showing a connection relationship between units of the present invention.

Claims (9)

In the optical subscriber transmission system, the DSI service unit stores four DSI dependent signals in a buffer, multiplexes them into a TUG2 signal using a synchronous clock, receives a TUG2 signal from an AU multiplexing unit, and demultiplexes the signal into a DSI signal. A DSIE service unit which stores three DSIE slave signals in a buffer and multiplexes them into a TUG3 signal using a synchronous clock; and a switch unit having a switching function that replaces a spare unit when a failure occurs in the DSI or DSIE service unit. Receives up to seven TUG2 signal rates from a low-speed multiplexing unit consisting of a DSI service unit and a DSIE service unit, and connects the AU3 signal to the optical transmission / reception unit by the method of multiplexing by byte interleaving and inserting the pass overhead and stuffing bits. Receives AU multiplexing unit and one asynchronous DS3 signal Temporarily store the data in the buffer, and then use the system synchronization clock to insert the overhead and stuffing bits into the VC, and then generate the AU3 signal by adding the AU pointer and connect it to the optical transmission / reception unit. A through unit which is located between the unit, the AU multiplexing unit or the DS3 service unit and the optical transmitting / receiving unit to secure a spare slot for the branch coupling function of the VCn unit, and up to three AU3s from the AU multiplexing unit or the DS3 service unit; After receiving the signal, the STM-1 signal is formed by multiplexing by byte interleaving and section overhead insertion method, and then converted to an optical signal for optical transmission and its reverse function. System by maintenance and command such as alarm and fault monitoring and signal status monitoring Provides a general control unit of a system having a function of a function, a data communication unit that transmits system status information and control commands to a large station for remote maintenance of a large system, and a clock signal necessary for synchronous multiplexing and control of the system. A synchronous optical transmission device comprising a clock supply unit. According to claim 1, wherein the DSI, DSIE low-speed multiplexer unit is configured in a multi-layer structure in the self to correspond to one band of AU3 per layer, and to implement the mixed acceptance of the DSI, DSIE service unit in each layer A synchronous optical transmission device, characterized in that. According to claim 1, Since the AU multiplexing unit and the DS3 unit is mounted in the same slot, it is possible to mount the AU multiplexing unit when providing the DSI, DSIE service and the DS3 unit when providing the DS3 service according to the service Synchronous optical transmission device, characterized in that implemented to enable the sharing of slots. The system of claim 1, wherein a button having an alarm state, a loopback state, a power alarm and an ACO light emitting diode and a system reset, an alarm history reset, and a light emitting diode test function is provided in front of the comprehensive control unit of the system. Synchronous optical transmission device characterized in that the control function is concentrated. The synchronous optical transmission device according to claim 1, wherein the data communication unit implements a power communication function by a command so that remote control and maintenance of the power supply system can be implemented in software. The synchronous optical transmission device according to claim 1, wherein the clock supply unit provides four synchronization modes of external synchronization, internal synchronization, loop synchronization, and holdover to increase reliability due to the stability of the clock. The method of claim 6. 2. A synchronous optical transmission device characterized by improving the protection switching function of a clock source by implementing a clock source switching function in the event of an input clock failure by dualizing an external synchronous clock source into primary and secondary. The synchronous method according to claim 1, wherein the through-combining unit is replaced with a time slot exchange unit without changing other units in the future to implement the branch-coupling function, and the branch-coupling function can be realized in the future only by mounting the optical transmission / reception unit. Optical transmission device 10. The synchronous optical transmission device according to claim 8, wherein the optical transmission / reception unit can be mounted at positions of the AU multiplexing unit and the DS3 unit when the branch coupling function is implemented. ※ Note: The disclosure is based on the initial application.