KR20000031912A - Device for detecting signal loss of optical path - Google Patents

Abstract

PURPOSE: A device for detecting signal loss of an optical path is provided to accurately detect the signal loss in a receiving terminal and out of frame in the next terminal of the receiving terminal. CONSTITUTION: An optical receiver(10) transmits the optical signal received from the optical path to an electrical signal, a clock and data, and outputs a first detection signal when receiving a signal having not been synchronized. An arrayed wave guide grating(20) receives the demodulated clock and data from the optical receiver and outputs the same after multiplexing. A buffer(30) outputs one output to a system and the other to a low pass filter(40) after receiving the output of the arrayed wave guide grating(20). A comparator(50) removes high frequency of the signal output from the buffer(30) and compares with set voltage, if under the set voltage, outputs a second detection signal.

Description

Signal Loss Detection Device

The present invention relates to an optical transmission device, and more particularly, to an apparatus for detecting a loss of a signal in the optical transmission device.

In general, a transmission apparatus has developed into a synchronous transmission network with the appearance of a broadband information communication network, and transmits and receives data through an optical fiber to transmit and receive a larger amount of data. Accordingly, the transmission device has been developed based on the SDH (Synchronous Digital Hierarchy) method and the SONET (Synchronus Optical NETwork) method. It also receives data from the transmitter and transmits it to other transmitters, and on the other hand, it can be used within a transmitter. At this time, data and clock are extracted from the transmitted data. Therefore, a device for extracting data and clocks is provided. Looking at the optical transmission device as follows. First, the received optical signal is converted into an electrical signal, and data and a clock are extracted from the converted electrical signal. However, in the process of transmitting an optical signal, an abnormal clock or data may be extracted according to a change in light intensity. In this case, the current optical transmission device detects a loss of signal (LOS), and therefore, the optical transmission device enters an alarm state according to the signal loss. In practice, however, the loss of these signals does not occur frequently in optical transmission devices. That is, as described above, in most cases, the intensity of the optical signal is changed in the transmission process, and thus, the signal is transmitted as an abnormal signal only in a specific frame. Therefore, noise generated in the optical path or optical signal transmission may be detected as a loss of a signal. This is a problem that a large amount of data is lost in the optical transmission device is a very fast data transmission.

Accordingly, an object of the present invention is to provide an apparatus capable of detecting a more accurate loss of an optical signal in an optical transmission device.

The present invention for achieving the above object is a signal loss detection device of the optical path, which converts an optical signal received from the optical path into an electrical signal, and converts into a clock and data, and outputs a first detection signal upon receiving an unsynchronized signal An optical receiver, a demultiplexer that receives the demodulated clock and data from the optical receiver, demultiplexes the output, and outputs the output of the demultiplexer, outputs one output to the system, and outputs another output to the low pass filter And a comparison detector for removing a high frequency of the signal output from the buffer and comparing the voltage with a predetermined voltage and outputting a second detection signal when the voltage is lower than the set voltage.

1 is a block diagram of a signal loss detection apparatus of an optical transmission apparatus according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a signal loss detection apparatus of an optical transmission apparatus according to an embodiment of the present invention. The optical signal received through the optical receiver is received by the optical signal receiver 10. The optical / electric converter 11 of the optical signal receiver 10 converts the received optical signal into an electrical signal and outputs the electrical signal to the clock / data demodulator 12. The clock / data demodulator 12 demodulates the clock and data from the optical signal received from the optical / electric converter 11 and outputs the demodulated clock and data to the demultiplexer 20. In addition, the clock / data demodulator 12 generates a first detection signal and outputs the first detection signal to one input terminal of the AND gate 60 when the clock and data are not normally extracted due to a noise component or a damage to the optical path. The demultiplexer 20 separates a clock and data from a signal received from the clock / data demodulator 12, demultiplexes the received data and outputs the received data to the buffer 30. At this time, the demultiplexer 20 outputs the demultiplexed data to the 1: 2 buffer 30. The buffer 30 outputs the received data in two stages, one output to the next system in the transmitter, and the other to the low pass filter 40. The low pass filter 40 then filters the received data and inputs the filtered signal to the inverting end of the comparator 50. In addition, a reference voltage Vref is applied to the non-inverting end of the comparator 50. The reference voltage applied to the low pass filter 40 outputs a low level voltage when there is no data. The maximum value of the low level voltage is set as the reference voltage Vref and applied to the non-inverting end of the comparator 50. Then, the comparator 50 receives a constant voltage value in the inverting stage when there is data output from the low pass filter. Then, since the voltage applied to the non-inverting stage is applied as the maximum voltage value when there is no data, the comparator 50 outputs a low level voltage. However, when no data is received by the low pass filter 40, a low DC value is output. Thus, in this case, the comparator 50 outputs a high level signal. This output of the comparator 50 is called a second detection signal. The AND gate 60, which is a logic gate, outputs a LOS signal by multiplying the received signal.

By adding the above-described device at the receiving end of the optical transmission device as described above, the signal loss can be accurately detected, and the out-of-frame can be detected in a system located next to the receiving end.

Claims (3)

In the optical signal loss detection device, An optical receiver which converts an optical signal received from the optical path into an electrical signal, converts it into a clock and data, and outputs a first detection signal upon reception of an unsynchronized signal; A demultiplexer for receiving a demodulated clock and data from the optical receiver and demultiplexing the same; A buffer which receives the output of the demultiplexer and outputs one output to the system and the other output to a low pass filter; And a comparison detector for removing the high frequency of the signal output from the buffer and outputting a second detection signal when the voltage is less than or equal to the set voltage. The method of claim 1, wherein the comparison detection circuit, A buffer for storing data received from the demultiplexer and outputting the data in two lines; A low pass filter for extracting only the low pass signal from the output of the buffer; And a comparator configured to output a second detection signal by comparing the output of the low pass filter with a set reference voltage. The method of claim 2, wherein the reference voltage of the comparator, And a signal loss detection apparatus for the optical path, in which there is no data received through the optical path, the maximum voltage that can be received from the low pass filter is set.