KR100588351B1 - Apparatus for measuring cable transmission performance in a optical subscriber network - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical subscriber network, and more particularly, to an apparatus for measuring line transmission performance in an optical subscriber network for measuring a transmission capability of an optical fiber section connecting between a telephone station and a subscriber.

The present invention for this purpose, in order to measure the transmission performance for the optical path section between the telephone station and the subscriber side, the telephone station side multiplexes the monitoring optical signal and the communication optical signal and transmits to the subscriber side, and is reflected from the subscriber side and transmitted The bit error rate value is measured from the power value of the optical signal, and when the minimum bit error value is measured, it is configured to be replaced with another ray.

Therefore, the present invention provides an effect of preventing the occurrence of a failure on the optical path in advance to secure the efficiency and stability of the system.

Description

Line transmission performance measuring apparatus in optical subscriber network {APPARATUS FOR MEASURING CABLE TRANSMISSION PERFORMANCE IN A OPTICAL SUBSCRIBER NETWORK}

1 is a general optical subscriber network configuration diagram,

2 is a block diagram showing the configuration of an apparatus for measuring line transmission performance in an optical subscriber network according to the present invention;

FIG. 3 is a detailed configuration diagram of the light reflection part shown in FIG. 2.

<Description of the symbols for the main parts of the drawings>

11 to 25: optical path section 210: pattern forming portion

211: monitoring optical signal generating unit 212: optical transmitting and receiving unit

213: multiplexing / demultiplexing section 214, 216: section light reflecting section

215, 217: light distribution unit 218 to 220: vertical light reflection unit

235: demultiplexer 236: optical splitter

237: monitoring light reflection receiver 238: optical switch

239: bit error measurement unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical subscriber network, and more particularly, to an apparatus for measuring line transmission performance in an optical subscriber network for measuring a transmission capability of an optical fiber section connecting between a telephone station and a subscriber.

1 is a block diagram of a general distribution type / broadcast type optical subscriber network, in which an optical signal output from the telephone station-side optical communication transceiver 110 is inserted into each optical line section 11 to 23. And is inputted to the optical communication transceivers 130 to 138 located at the subscriber side.

The optical subscriber network monitors communication failures occurring on the optical path other than a method of monitoring a communication failure on the optical path by exchanging information using the overhead of the communication protocol between the telephone station optical communication transceiver and the subscriber optical communication transceiver. The test method is not implemented at all and has the following problems.

Since the failure monitoring device that occurs on the optical path is not implemented, the failure of the optical subscriber line can be known only when the subscriber directly reports the failure, and the information exchange method due to the overhead of the communication protocol is limited to the digital transmission method. However, when the subscriber and the telephone station are not communicating, that is, when the subscriber station is in the idle state, it cannot be used, so it cannot be recognized in advance even if a line failure occurs.

In addition, even when performing a test for maintenance due to a line failure, the fault section cannot be accurately identified from the beginning. Therefore, a test for detecting a fault section is performed to detect a fault section within the corresponding section and then a test for maintenance. Because of this, it takes a lot of time to not provide efficient services to subscribers, but also causes a great economic loss.

In addition, when the maintenance test is performed, the test is performed by separating the connection between the optical splitter and the optical path, so that the service through all the optical path sections connected to the optical splitter under test has a problem of being interrupted.

The present invention has been made to solve the problems described above, the object of the present invention is to monitor the optical subscriber line in real time in the telephone station and to measure the transmission performance of each optical line section to the other optical path to the optical fiber degradation performance The present invention provides an apparatus for measuring line transmission performance in an optical subscriber network to prevent failures in advance and increase efficiency and stability of the system.

The present invention for achieving the above object is a line transmission performance measuring apparatus in the optical subscriber network for measuring the transmission performance by monitoring the optical path state between the telephone station and the subscriber side by section; Monitoring light source generating means for generating an optical signal for monitoring the light path section; Multiplexing / demultiplexing means for multiplexing the monitoring optical signal and the communication optical signal transmitted from the telephone station side to the subscriber side, and demultiplexing the optical signal reflected from the subscriber side; Demultiplexing means for separating and transmitting the optical signal reflected to the subscriber for each wavelength; Separating means for separating the optical signal transmitted from the demultiplexing means; Reflected light receiving means for receiving the separated and transmitted optical signal; And a bit error rate measuring means for measuring a minimum bit error value from a power value of the optical signal transmitted separately.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation of the preferred embodiment according to the present invention.

2 is a block diagram of an optical subscriber network for measuring optical transmission performance according to the present invention, a pattern forming unit 210 for converting an optical signal to be transmitted into a predetermined pattern, and monitoring light for monitoring optical path sections. The monitoring optical signal generating unit 211 for generating a signal, the communication optical transmitting and receiving unit 212 for generating a communication optical signal, multiplexed the monitoring optical signal and the communication optical signal and reflected with the communication optical signal transmitted from the subscriber side The multiplexing / demultiplexing unit 213 which separates and transmits the transmitted monitoring optical signal, reflects the monitoring optical signal in the monitoring wavelength band from the multiplexed optical signal to the multiplexing / demultiplexing unit 213 and does not reflect pure The wavelength band component for communication is distributed and transmitted by the section light reflecting unit 214 for transmitting, the light distribution unit 215 for distributing the optical signal transmitted from the section light reflecting unit 214, and the light distribution unit 215. Sectional light reflecting unit 216 reflects the optical signal in the monitoring wavelength band from the optical signal to the multiplexing / demultiplexing unit 213 and passes only the pure communication wavelength band component among the unreflected wavelength component and the communication wavelength component. For example, the optical splitters 217 for distributing optical signals correspondingly connected to the section light reflecting units 216 and the optical signals transmitted in each of the optical splitters 217 in the communication wavelength band. From the terminal type light reflection units 218 to 220 and the optical signal generator 211 for monitoring, which transmits only the signal to the optical transmission / reception units 231 to 233 on the subscriber side and reflects the optical signal outside the communication wavelength band to the outside. Surveillance light separated by the optical circulation unit 234 for transmitting the optical signal and the optical signal for monitoring from the multiplexing / demultiplexing unit 213 and the multiplexing / demultiplexing unit 213 and transmitted through the optical circulation unit 234 Inverse to demultiplex the signal by wavelength Through the neutralizing unit 235, the monitoring reflected light receiving unit 237 for receiving the demultiplexed monitoring optical signal, the optical splitter 236 and the optical splitter 236 for branching and transmitting the demultiplexed monitoring optical signal An optical switch 238 for switching the transmitted optical signal, and a bit error rate measuring unit 239 for measuring a bit error ratio (BER) value of the optical signal transmitted through the optical switch 238.

The optical fiber transmission performance measuring apparatus having the above-described configuration is operated as follows.

In the above configuration, the light distribution structure may be changed according to the type of the light distribution device, but in the preferred embodiment of the present invention, the 1 × 3 light distribution device is shown, and the same reference numerals are not given to the same components. .

The light source of the monitoring optical signal generator 211 is a continuous wave (CW), and emits a monitoring optical signal for monitoring the occurrence of failures in the optical path sections 11 to 25, and the optical transmission and reception unit 212 The communication optical signal is transmitted to the subscriber side and the communication optical signal transmitted from the subscriber side is received.

At this time, the wavelength band of the light source used for the monitoring optical signal generating unit 211 uses a wavelength band different from the wavelength band used by the optical transmitting and receiving unit 212, the wavelength line width of the light source is all the interval type to be used in the system Wider than the sum of the reflection wavelength bandwidths of the light reflection portions 214 and 216 and all of the longitudinal light reflection portions 218 to 220.

The light source of the monitoring optical signal generator 211 is input to the a port of the optical circulation unit 234 and output to the b port, which is output from the optical transmitter / receiver 212 by the multiplexer / demultiplexer 213 of the next stage. Multiplexed with the communication optical signal is input to the section light reflecting section 214 through the optical path section (14).

In this case, the section light reflecting units 214 and 216 are installed for each section, and as shown in FIG. 3A, the optical fiber grating reflector 311, the asymmetric light splitter 312, and the non-reflective output port 313 are provided. The optical fiber grating reflector 311 reflects only the reflection wavelength and passes the remaining non-reflected wavelength components to be input to the light distribution units 215 and 217 connected to each other.

That is, the interval type light reflection parts 214 and 216 are optical fiber grating reflectors 311 reflecting the monitoring optical signal transmitted in the monitoring wavelength band from the monitoring optical signal and the communication optical signal transmitted as shown in FIG. An asymmetric light splitter 312 for asymmetrically reflecting the optical signal transmitted from the optical fiber grating reflector 311 and an anti-reflective output port 313 for outputting some of the optical signals transmitted from the asymmetric light splitter 312 without reflecting them. ) So that it can be used as a connection port of the instrument during line test.

The light distribution units 215 and 217 are connected to the light distribution units 214 and 216 correspondingly to distribute the optical signals transmitted from each of the light distribution units 214 and 216, and the light distribution units 215 and 217. The optical signal distributed in each is input to the terminal light reflection parts 218 to 220, and reflects only the reflected wavelength by the optical fiber grating reflector 321 as shown in FIG. Only the unreflected wavelength component among the components of the wavelength band and the communication wavelength component among the communication wavelength components are passed through and outputted to the anti-reflective output port 323.

That is, each of the end-type light reflecting units 218 to 220 is installed on a subscriber side in-door terminal box or a conduit close to the subscriber side, and as shown in FIG. 3B, for monitoring transmitted through the light distribution unit 270. The optical signal transmitted from the optical fiber grating reflector 321 and the optical fiber grating reflector 321 reflecting the optical signal for monitoring in the monitoring wavelength band from the optical signal and the communication optical signal is multiplexed for each wavelength band to output only the monitoring wavelength band component. It consists of a demultiplexer 322 and the non-reflective output port 323 for outputting the monitoring wavelength band component transmitted from the demultiplexer 322 to the outside, and is used as a connection port for the line test in the event of a line failure.

On the contrary to the above-described process, the monitoring optical signal reflected from the section light reflecting units 214 and 216 and the communication optical signal output from the subscriber side optical transmitting and receiving units 231 to 233 are connected to the telephone station through the optical path section. Coming into the side.

As such, the wavelength band signal for monitoring among the optical signals transmitted to the telephone station is separated by the communication optical signal and the wavelength band from the multiplexing / demultiplexing unit 213 and input to the b port of the optical circulation unit 234, and then through the c port. After being output to the demultiplexer 235 and separated for each wavelength, the light splitter 236 passes through a part of the signal to the monitoring reflection light receiver 237, and a part of the bit error rate measuring part 239 passes through the optical switch 230. To come back.

At this time, the monitoring reflection light receiving unit 237, as can be seen from the above, because it can receive a signal for each wavelength, it is possible to continuously monitor the presence or absence of the failure of a particular light path section or light subscriber line.

If a failure is detected and a maintenance test is performed, the line maintainer connects the test meter to the antireflective output ports 313 and 323 and repairs the line as shown in FIGS. The work can be carried out, and the monitoring light signal can be used without the need for preparing a test light source for the line repair work.

Meanwhile, the bit error rate measuring unit 239 determines whether the optical path is abnormal on the optical path according to the optical power value of the optical signal input through the optical splitter 236 and the optical switch 238.

That is, the bit error rate measuring unit 239 represents a bit error rate in the range of about 10 ⁻⁴ to 10 ⁻¹² from the optical power value of the received optical signal. When the minimum bit error value is 10 ^_7 , the light source for monitoring With 51.84 Mbps, 5.184. Errors are generated per second.

Accordingly, the bit error rate measuring unit 239 determines that an abnormality has occurred in the optical path when a minimum bit error rate value, that is, a bit error rate value of 10 ^_7 or less is measured from the power value of the optical signal received through the optical switch 238. By displaying it to the operator, the operator replaces the corresponding optical path with another one so that the desired optical signal is transmitted.

As described above, the optical subscriber line transmission performance measuring apparatus according to the present invention measures the bit error rate from the power value of the optical signal received from the optical path, and when the minimum bit error value or less is detected, the transmission capability of the optical path is deteriorated. It is determined that the system has been replaced and replaced with another light beam to prevent the occurrence of failure in advance, thereby obtaining the effect of securing the efficiency and stability of the system.

Claims (3)

An apparatus for measuring line transmission performance in an optical subscriber network for measuring transmission performance by monitoring a line condition between a telephone station and a subscriber side by section; Monitoring light source generating means for generating an optical signal for monitoring the light path section; Multiplexing / demultiplexing means for multiplexing the monitoring optical signal and the communication optical signal transmitted from the telephone station side to the subscriber side, and demultiplexing the optical signal reflected from the subscriber side; Demultiplexing means for separating and transmitting the optical signal reflected to the subscriber for each wavelength; Separating means for separating the optical signal transmitted from the demultiplexing means; Reflected light receiving means for receiving the separated and transmitted optical signal; And a bit error rate measuring means for measuring a minimum bit error value from a power value of the optical signal transmitted separately. The method of claim 1, And if the minimum bit error value is measured by the bit error rate measuring means, replaces the optical path with another optical path. The method according to claim 1 or 2, And the minimum bit error value is 10 ⁻⁷ .

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