KR20100019515A - A system for optical fiber detection, an optical wavelength division multiplexing network system and a method for optical fiber fault localization - Google Patents

Abstract

Disclosed are a fiber test system, a wavelength division multiplexing optical network system, and a fiber defect location measurement method. The fiber test system includes a light source, a first arrayed waveguide grating, a pulse generator, an optical signal amplification and modulation module, a circulator, a first selection module, and a reflected optical signal receiving module. The method includes the following steps: The fiber defect location measuring device detects a defect in an uplink channel, notifies the optical line terminal to block transmission of the downlink by a transmitter in this uplink channel, and a line diagnostic signal. Generate a light source and send a light source of the modulator to the downlink; The fiber defect location measuring device selects to receive the reflected line diagnostic signal, analyzes and processes the line diagnostic signal to determine the specific location of the defect, and reports the defect location to the network management server. Since the optical time domain reflection wavelength selection module is applied to the fiber defect localization device of the present invention, the cost of the fiber defect localization system is reduced.

Description

AN OPTICAL FIBER DETECTION, AN OPTICAL WAVELENGTH DIVISION MULTIPLEXING NETWORK SYSTEM AND A METHOD FOR OPTICAL FIBER FAULT LOCALIZATION}

TECHNICAL FIELD The present invention relates to optical access network technology, and more particularly, to a fiber test system, a wavelength division multiplexing optical network system, and a method for measuring fiber defect positions in a wavelength division multiplexing optical network.

Data services have emerged extensively in recent years, followed by a rapid demand for broadband access. To meet high bandwidth and high capacity access requirements such as Asynchronous Transfer Mode (ATM), Passive Optical Network (APON), Broadband Passive Optical Network (BPON), Ethernet Passive Optical Network (EPON), Gigabit Passive Optical Network (GPON), and TDAM-PON (Time Division Multiple Access-Passive Optical Network) has entered service. However, if higher bandwidth is required, it is difficult for the TDMA-PON to increase bandwidth and transmission capacity due to burst techniques for transmission and constraints of only one wavelength. As a result, the increase in bandwidth must be realized by adding optical wavelengths for data transmission. Currently, multi-wavelength transmission based on Wavelength Division Multiplexing-Passive Optical Network (WDM-PON) is considered to be the ultimate solution for increased bandwidth. The WDM-PON solution is shown in FIG. During maintenance of the WDM-PON system, it is necessary to detect and measure fiber defects. Currently, GPON / EPON often employs Optical Time Domain Reflectometers (OTDRs) to detect and position fiber bonds: In the Central Office (CO), the laser light source of the OTDRs transmits light pulses to the fiber under test. This optical signal is reflected back to the OTDR from the fiber and its feature points (connectors, fiber critical points, excessively bent fiber portions, etc.); The reflected optical signal is transmitted to the receiver of the OTDR by directional coupling and converted into an electrical signal; Finally, the OTDR test curve is displayed on the OTDR screen, whereby the defect and the specific location of the defect can be detected. Unlike TDMA-PON systems such as APON, BPON, GPON, and EPON, in WDM-PON systems, wavelength routers (such as arrayed waveguide gratings (AWG)) are located at remote nodes so that feeder fibers Only the optical signal of the channel wavelength corresponding to the router can be transmitted. Therefore, in order to detect and find faults, multiple OTDR test wavelengths must be provided in the OTDR test signal reaching the feeder fiber portion.

In the prior art, two fiber defect localization methods are provided with respect to single-fiber bidirectional and dual-fiber bidirectional WDM-PON systems. In single-fiber bidirectional WDM-PON systems, an external test device is employed to measure the location of fiber defects. As shown in Fig. 2, the test principle is as follows: The control unit controls the tunable optical filter to block the OTDR wavelength (which is related to the WAG channel wavelength corresponding to the feeder fiber portion under test); The OTDR optical signal is then scanned and amplified in Fabri-Perot Laser Diodes (FP-LD); The amplified optical signal is supplied to the feeder fiber by a tunable optical filter, port 3 of the circulator, and a coarse wavelength division multiplexing (CWDM) filter; The reflected OTDR optical signal passes back through the CWDM filter and reaches the optical-to-electrical (O / E) converter through port 4 of the circulator; After proper amplification and signal processing, the OTDR test curve is displayed on the screen. In this solution, the OTDR is a standalone device and, if a WDM-PON system is deployed, the CWDM filter is pre-installed on the optical line terminal (OLT). When it is necessary to measure the location of fiber defects, an OTDR test device must be inserted into the CWDM filter. However, in conventional OTDR test methods, a tunable optical filter needs to be tuned such that the center frequency of the OTDR is dynamically aligned with the WAG wavelength at the remote node in the system under test. This alignment operation is difficult and the tunable optical filter is expensive. This inevitably leads to high costs in the use of the fiber bonding position measuring system.

For the purpose of reducing the cost of the fiber defect localization system and improving the operation of the fiber defect localization system, embodiments of the present invention are directed to the location of fiber defects in fiber test systems, wavelength division multiplexed optical network systems and wavelength division multiplexed optical networks. It provides a method of measuring. The technical solutions are as follows:

The fiber test system includes a light source, a first arrayed waveguide diffraction grating, a pulse generator, an optical signal amplification and modulation module, a circulator, a first selection module, and a reflected optical signal receiving module,

The first arrayed waveguide diffraction grating spectrally splits seed light output by the light source,

The optical signal amplification and modulation module amplifies the line diagnostic signal generated by the pulse generator and converts the line diagnostic signal after spectral division by the first arrayed waveguide diffraction grating into an optical signal of at least one wavelength channel. Modulate to generate a line diagnostic optical signal, wherein the line diagnostic optical signal is transmitted to the circulator through the first arrayed waveguide diffraction grating,

The first selection module is configured to select at least one wavelength channel,

The circulator is configured to supply an optical signal from the first arrayed waveguide diffraction grating to the system under test and to supply the optical signal from the system under test to the reflected optical signal receiving module, The optical signal includes the reflected line diagnostic optical signal,

The reflected optical signal receiving module is configured to analyze and process the received optical signal to obtain analysis and processing results.

The wavelength division multiplexing optical network system includes the fiber test system described above.

A fiber defect position measuring method for measuring a position of a fiber defect in a wavelength division multiplexing optical network comprising a light source, a first arrayed waveguide diffraction grating, a pulse generator, an optical signal amplification and modulation module, and a reflected optical signal receiving module,

Generating a line diagnostic signal by the pulse generator;

Detecting a defect in an uplink channel and supplying said line diagnostic signal generated by said pulse generator to said optical signal amplification and modulation module;

The optical signal amplification and modulation module receiving the line diagnostic signal and modulating the line diagnostic signal with seed light to generate a line diagnostic optical signal, wherein the line diagnostic optical signal is coupled to the first array waveguide Generating a line diagnostic optical signal, sent to a system under test via a diffraction grating, wherein said seed light is obtained by spectral division of a light source by said first arrayed waveguide grating;

Receiving from the system under test an optical signal comprising a reflected line diagnostic optical signal; And

Supplying the optical signal to the reflective optical signal receiving module, wherein the reflective optical signal receiving module analyzes and processes the received optical signal to obtain an analysis and processing result;

It includes.

The technical solution provided in the embodiments of the present invention provides the following advantages: The test light source is spectrum-sliced by an arrayed waveguide grating and using an appropriate spectral division wavelength channel. Modulate OTDR test data; The wavelength channel is selected with a 1 × N optical switch or electrical switch. This makes the wavelength channel of the test signal more stable and effectively reduces the cost of the fiber defect localization system. Further, since the arrayed waveguide diffraction grating in the fiber defect position measuring device is the same model as the arrayed waveguide diffraction grating in the central station of the system under test, the center wavelengths of the two arrayed waveguide diffraction gratings are aligned and fixed, and thus more easily. The fiber defect position measuring device can be operated.

1 is a schematic diagram illustrating networking of a prior art WDM-PON system.

2 is a schematic diagram illustrating the principle of measuring the location of fiber defects in a single fiber bidirectional WDM-PON with prior art external fiber defect location measuring devices.

3 is a schematic diagram showing the principle of a fiber defect position measuring device according to an embodiment of the present invention.

4 is a schematic diagram illustrating the principle of a first method for measuring the location of fiber defects in a single fiber bidirectional WDM-PON system according to an embodiment of the present invention.

5 is a flow chart of a first method for measuring the location of fiber defects in a single fiber bidirectional WDM-PON system according to an embodiment of the present invention.

6 is a schematic diagram illustrating the principle of a first method for measuring the location of fiber defects in a dual fiber bidirectional WDM-PON system according to an embodiment of the present invention.

7 is a schematic diagram illustrating the principle of a second method for measuring the location of fiber defects in a single fiber bidirectional WDM-PON system according to an embodiment of the present invention.

8 is a flow chart of a second method for measuring the location of fiber defects in a single fiber bidirectional WDM-PON system according to an embodiment of the present invention.

9 is a schematic diagram illustrating the principle of a second method for measuring the location of fiber defects in a dual fiber bidirectional WDM-PON system according to an embodiment of the present invention.

10 is a schematic diagram showing a structure of a fiber defect position measuring device according to an embodiment of the present invention.

BRIEF DESCRIPTION OF DRAWINGS To make the technical solutions, objects, and advantages of the present invention clearer, embodiments of the present invention are described in detail below with reference to the accompanying drawings.

As shown in FIG. 3, the fiber defect position measuring device in the embodiment of the present invention includes a light source 301, a pulse generator 302, a control unit 303, an OTDR wavelength selection module 304, an output optical signal amplification and Modulation module 305, circulator 306 and reflected signal receiving module 307. The OTDR wavelength selection module 304 consists of a 1xN optical switch 304a and an AWG 304b and replaces the prior art tunable optical filter. The combination of 1 × N optical switch 304a and AWG 304b provides a plurality of OTDR wavelengths. The N channels of the WAG output N optical signals having different wavelengths, and the control unit 303 controls the 1 × N optical switch 304a such that the 1 × N optical switch 304a is connected to one AWG optical channel. The output of the selected AWG optical channel is taken as the OTDR optical signal. Thereby, the fiber defect position measuring device according to the embodiment of the present invention can provide N OTDR wavelengths. The output optical signal amplification and modulation module 305 is substantially an implantation fixed FP-LD (IL-FP-LD) or reflective semiconductor optical amplifier (RSOA). The reflected optical signal receiving module 307 includes an O / E converter 307a, an electrical signal amplifier 307b, a digital / analog converter 307c, a signal processor 307d and a monitor 307e. The light source 301 may be a wide spectrum optical source.

The operating principle of the fiber defect position measuring device according to the embodiment of the present invention is as follows: The optical signal output by the wide spectrum light source 301 is passed through the circulator 306 to the public port of the AWG 304b. After being provided to, the control unit 303 controls the optical switch 304a to select a given OTDR wavelength and scan the LTDR light waves into the IL-FP LD or ROSA 305 for amplification and OTDR data modulation; The amplified and modulated signal is provided to the system under test via the circulator 306; O / E converter 307 via circulator 306 receives the reflected OTDR optical signal; Finally, after the signal is processed by the electrical signal amplifier 307c and the digital-to-analog converter 307c, the OTDR test curve is displayed on the monitor 307e; According to this OTDR test curve, the location of the defect can be determined and then recovered. For example, if the first channel fails in a WDM-PON system, the fiber defect positioning device provided according to an embodiment of the present invention is connected to a CWDM filter pre-installed in the WDM-PON system and then the device starts operation. To; The control unit 303 controls the 1xN optical switch 304a to be connected to the first channel of the AWG 304b so that the OTDR signal of this first channel is output; The OTDR test curve is then observed to determine the specific location where light line defects occur and perform maintenance in time.

The AWG 304b of the OTDR wavelength selection module 304 in the fiber defect localization device provided according to an embodiment of the present invention is the same model as the AWG at the remote node in the system under test and the center wavelengths of the two AWGs are aligned. And fixed. Once the wavelengths are aligned, the 1 × N optical switch 304a is controlled to connect to the appropriate AWG 304b channel so that the appropriate OTDR wavelength optical signal is automatically generated. This facilitates the alignment of the center wavelength of the AWG channel with the center wavelength of the OTDR at the remote node of the system under test. Further, in comparison with the tunable optical filter, the combination of the AWG 304b and the 1xN optical switch 304a can save cost. Therefore, the cost of the fiber defect localization system is effectively reduced.

In all WDM-PON solutions, spectral splitting is applied to two wide spectral light sources to provide a seed optical source; IL-FP LD or RSOA sends downlink data in CO; The IL-FP LD or RSOA sends uplink data at the optical network terminal (ONT). Such WDM-PON systems include single fiber bidirectional and dual fiber bidirectional WDM-PON systems. In the embodiment of the present invention, a single fiber bidirectional WDM-PON system based on the spectral division of a wide spectrum light source is taken as an example for explaining the fiber defect position measuring method of the present invention.

Method 1:

As shown in FIG. 4, in the case of a WDM-PON system based on the spectral division of a wide spectrum light source, a fiber defect localization device is assembled to the OLT, and through the downlink light source of the OLT, a line diagnosis such as an OTDR test signal. Send a signal The reflected OTDR signal is received by the tunable optical filter and then analyzed and processed to determine the specific location of the fiber defect. The fiber defect position measuring device includes a control unit 401, a pulse generator 402, an OTDR receiver 403 and a tunable optical filter 404. The control unit 401 is configured to check the transmission quality of the uplink data to determine whether the uplink channel fails; The control unit 401 is also configured to control the pulse generator 402 to generate a pulse signal; The control unit 401 also controls the electrical switch 405 to modulate the signal into an OTDR test signal and the tunable optical filter 404 to block the reflected OTDR signal; The control unit 401 also analyzes and processes the reflected OTDR signal received by the OTDR receiver 403 to determine the specific location of the fiber defect. The tunable optical filter 404 is configured to block the reflected OTDR signal. The electrical switch 405 is configured to complete the modulation and switching of the OTDR test signal and the normal downlink signal.

According to the above technical solution, the method of measuring the position of the fiber defect in the WDM-PON system includes the following steps as shown in Figs.

Step 501: The control unit 401 detects a defect in one uplink channel and sends a control command to the electrical switch 405 of this channel to notify the electrical switch 405 to block transmission of downlink data, The pulse generator 402 is controlled to output a pulse signal (or diagnostic electrical signal) to modulate the OLT light source to generate an OTDR test signal (or diagnostic optical signal).

The control unit 401 monitors in real time the received optical power and / or signal bit error rate (BER) of all uplink channels in the WDM-PON system. Upon detecting a sharp change in the received optical power and / or signal BER of one uplink channel, the control unit 401 assumes that the uplink channel has failed and sends a control command to the electrical switch 405 of that channel. Notify the transmission of downlink data to be blocked and alert the network management system. The electrical switch 405 of the channel receives the control command and switches the OLT light source to OTDR modulation.

The control unit 401 modulates the OLT light source by generating a OTDR test signal by sending a control command to the pulse generator 402 to notify the pulse generator to output a pulse signal. In the pulse signal generated by the pulse generator 402, a command to turn off the ONT light source needs to be included to prevent the ONT uplink light signal and the OTDR test signal from interfering.

Step 502: The pulse signal generated by the pulse generator 402 is modulated and amplified by the IL-FP LD or RSOA 406 and then sent to the AWG1 407.

The wide spectrum light source 408 includes a wide spectrum light source 1 and a wide spectrum light source 2. The seed optical signal generated by the wide spectrum light source 408 is demultiplexed by the AWG1 407 to generate an optical signal of each wavelength λ ₁ , λ ₂ ,..., Λ _n , These optical signals are sent to the IL-FP LD or RSOA 406. The IL-FP LD or RSOA 406 modulates and amplifies the received optical signal in accordance with the pulse signal generated by the pulse generator 402 to obtain an OTDR test signal and sends this OTDR test signal to the AWG1 407.

Step 503: AWG1 407 sends the received optical signal, including the OTDR test signal, to the ONT via circulator 409.

Step 504: The optical signal including the reflected OTDR test signal is sent to the tunable optical filter 404 through the circulator 409; Tunable optical filter 404 blocks the reflected OTDR test signal and sends the signal to OTDR receiver 403.

The tunable optical filter 404 adjusts its parameters under control of the control unit 401 so that the reflected OTDR test signal is blocked by the received optical signal.

Step 505: The OTDR receiver 403 converts the received reflected OTDR test signal into an electrical signal and sends the electrical signal to the control unit 401.

Step 506: The control unit 401 analyzes and processes the signal received from the OTDR receiver 403 to determine the location of the defect and reports the location to the network management server.

By analyzing and processing the reflected OTDR test signal, the control unit 401 can obtain the OTDR test curve, thereby determining the position of the fiber defect relatively accurately. The control unit 401 also reports its location to the network management server so that it can be maintained in time.

In fact, in the case of the WDM-PON system based on the spectral division of the wide spectral light source (as shown in Fig. 6), the method of measuring the position of the fiber defect is the same as the method in this embodiment, and thus the description is omitted.

In this embodiment, the fiber defect localization device is embedded in the OLT, and the IL-FP LD or RSOA acts as an optical signal generator of the fiber defect localization device in the WDM-PON system. The electrical pulse signal of the OTDR test is modulated and amplified to generate an OTDR test signal. This effectively reduces the cost of the fiber defect localization system in the WDM-PON system.

Method 2:

As shown in FIG. 7, in the case of the WDM-PON system based on the spectral division of a wide spectrum light source, a fiber defect localization device is embedded in the OLT, and through the downlink light source of the OLT, a line diagnosis such as an OTDR test signal is performed. Send a signal. The reflected OTDR signal is received by a combination of AWG (same model as AWG in CO) and 1 × N optical switch and then analyzed and processed to determine the specific location of the fiber defect.

The fiber defect position measuring device includes a control unit 701, a pulse generator 702, an OTDR receiver 703, and a combination of an AWG2 704b and a 1 × N optical switch 704b. The control unit 701 checks the transmission quality of the uplink data to determine whether the uplink channel fails; The control unit 701 also controls the pulse generator 702 to generate a pulse signal; The control unit 701 also controls the electrical switch 705 to modulate the signal into an OTDR test signal and the combination 704 of the AWG 704a and 1xN optical switch 704b to control the appropriate signal from the reflected OTDR test signal. To select; The control unit 701 also analyzes and processes the signal received by the OTDR receiver 703 to determine the specific location of the fiber defect. The combination 704 of the AWG 704a and the 1xN optical switch is configured to block the reflected OTDR test signal and select the appropriate signal. The electrical switch 705 is configured to complete the modulation and switching of the OTDR test signal and the normal downlink signal.

According to the above technical solution, the method of measuring the position of the fiber defect in the WDM-PON system includes the following steps as shown in Figs.

Step 801: The control unit 701 detects a defect of one uplink channel and sends a control command to the electrical switch 705 of that channel to notify the electrical switch 705 to block transmission of the downlink data, The pulse generator 702 is controlled to generate a pulse signal to modulate the OLT light source to generate an OTDR test signal.

The control unit 701 monitors in real time the received optical power and / or signal BER of all uplink channels in the WDM-PON system. If a sudden change in the received optical power and / or signal BER of one uplink channel is detected, the control unit 701 assumes that the uplink channel has failed and sends a control command to block transmission of the downlink data. The electric switch 705 is notified and an alarm signal is sent to the network management system. The electrical switch 705 of the channel receives the control command and converts the OLT light source to OTDR modulation.

The control unit 701 sends a control command to the pulse generator 702 to notify the pulse generator to generate a pulse signal, thereby modulating the OLT light source and generating an OTDR test signal. In the pulse signal generated by the pulse generator 702, in order to prevent the ONT uplink light signal and the OTDR test signal from interfering, it needs to be included in a command for turning off the ONT light source.

Step 802: The pulse signal generated by the pulse generator 7020 is modulated and amplified by the IL-FP LD or RSOA 706 to generate an OTDR test signal, which is sent to the AWG1 707.

The wide spectrum light source 708 includes a wide spectrum light source 1 and a wide spectrum light source 2. The seed optical signal generated by the wide spectrum light source 708 is demultiplexed by the AWG1 707 to generate optical signals of respective wavelengths λ ₁ , λ ₂ , ..., λ _n , which are IL- Sent to FP LD or RSOA 706. The IL-FP LD or RSOA 706 modulates and amplifies the received optical signal according to the pulse signal generated by the pulse generator 702 to obtain an OTDR test signal and transmits the OTDR test signal to the AWG1 707. .

Step 803: AWG1 707 sends its received optical signal, including the OTDR test signal, to the ONT via circulator 709.

Step 804: The optical signal including the reflective OTDR test signal is sent to the combination 704 of the AWG2 704a and the 1xN optical switch 704b, intercepting the reflective OTDR test signal among the received optical signals to test the reflected OTDR test. Sends a signal to the OTDR receiver 703.

The 1xN optical switch 704b is connected to the AWG 704a corresponding to the OTDR test signal under the control of the control unit 701 so that the OTDR test signal can transmit the optical signal through the AWG2 704a and the 1xN optical switch 704b. have. AWG2 704a is the same model as AWG1 707 in CO, the center wavelengths of which are aligned and fixed.

Step 805: The OTDR receiver 703 receives the reflected OTDR test signal and converts it into an electrical signal, which is sent to the control unit 701.

Step 806: The control unit 701 analyzes and processes the signal received from the OTDR receiver 703 to determine the location of the defect and reports the location to the network management server.

By analyzing and processing the reflected OTDR test signal, the control unit 701 can obtain the OTDR test curve, thereby determining the position of the fiber defect relatively accurately. The control unit 701 also reports its location to the network management server so that it can be maintained in time.

In fact, in the case of the WDM-PON system based on the spectral division of the wide spectrum light source (as shown in Fig. 9), the method of measuring the position of the fiber defect is the same as the method in this embodiment, and thus the description is omitted.

In this embodiment, the fiber defect localization device is embedded in the OLT, and the IL-FP LD or RSOA acts as an optical signal generator of the fiber defect localization device in the WDM-PON system. The combination of AWG and 1xN optical switch replaces a tunable optical filter. The electrical pulse signal of the OTDR test is modulated and amplified to generate an OTDR test signal. This effectively reduces the cost of the fiber defect localization system in the WDM-PON system. In addition, since the AWG in the fiber defect localization device is the same model as the AWG in the CO of the tested WDM-PON system, the center wavelengths of the AWGs are aligned and fixed, making it easy to implement.

As shown in FIG. 10, the fiber defect position measuring apparatus according to the embodiment of the present invention includes a control module 1001, a signal generating module 1002, a transmission module 1003, and a fiber defect position measuring module 1004. do.

The control module 1001 is configured to check whether the uplink channel is a failure and notify the signal generation module 1002 and the transmission module 1003 if it detects that the uplink channel is a failure.

The signal generation module 1002 is configured to generate a line diagnostic signal upon receiving a notification from the control module 1001 and to send the line diagnostic signal to the transmission module 1003.

The transmission module 1003 receives the line diagnostic signal from the signal generation module 1002 and the notification from the control module 1001. When receiving the notification from the control module 1001, the transmission module 1003 blocks the transmission of the downlink data. And modulate the received line diagnostic signal on the seed light and send the modulated signal to the downlink.

The fiber defect position measuring module 1004 is configured to receive the line diagnostic signal reflected by the optical line and report the position of the fiber defect to the network management server according to the analysis and processing of the line diagnostic signal.

The control module 1001 includes a signal BER testing unit and a received optical power testing unit. The control module 1001 also includes a notification sending unit.

The signal BER testing unit is configured to check whether the signal BER on the uplink channel has degraded and send a signal to the notification sending unit as a result.

The receiving optical power testing unit is configured to check whether a sudden change in the received optical power of the uplink channel has occurred and send the test result to the notification transmitting unit.

The notification transmitting unit is configured to send a notification to the signal generating module 1002 and the transmitting module 1003 upon receiving a test result indicating a drop in the signal BER and / or a sudden change in the received optical power.

The transmitting module 1003 includes a notification receiving unit, an amplifying unit and a transmitting unit.

The notification receiving unit is configured to receive a notification from the notification sending unit and send the received notification to the sending unit.

The amplifying unit is configured to receive the line diagnostic signal from the signal generating module 1002, amplify the line diagnostic signal, and send the amplified line diagnostic signal to the transmission unit.

The transmitting unit is configured to block transmission of the downlink data upon receiving a notification from the notification receiving unit, modulate the received line diagnostic signal on the seed light and send the modulated signal to the downlink.

The amplification unit and the transmission unit may be one physical entity, such as IL-FP LD or RSOA.

The fiber defect location measuring module 1004 includes an analysis and processing unit and a reporting unit.

The analyzing and processing unit is configured to receive the line diagnostic signal reflected from the optical line, analyze and process the line diagnostic signal to find the specific location of the fiber defect and send the position information to the reporting unit.

The reporting unit is configured to receive information from the analysis and processing unit and send the information to the network management server. In this embodiment, the IL-FP LD or RSOA is adapted to amplify and modulate the diagnostic signal, effectively reducing the cost of the fiber defect localization system.

According to the technical solution of the embodiment of the present invention, the fiber defect positioning device is embedded in the OLT; IL-FP LD or RSOA acts as the light source of the WDM-PON fiber defect localization device; The AWG modulates the OTDR test signal by dividing the spectrum of the light source and then selecting an appropriate spectral division wavelength channel; The 1xN optical switch or electrical switch is configured to assist with its selection. This ensures that the wavelength channel of the test signal is more stable and that the cost of the fiber defect localization system in the WDM-PON system is effectively reduced. In addition, since the AWG of the fiber defect localization device is the same model as the AWG in the CO of the tested WDM-PON system, the center wavelengths of these two WAGs are aligned and fixed, thus operating the fiber defect localization device. Much easier.

Although the present invention has been described through some exemplary embodiments, the present invention is not limited to these embodiments. It will be apparent to those skilled in the art that modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is intended that the present invention cover the modifications and variations that come within the scope of protection defined by the following claims and their equivalents.

Claims (14)

A fiber test system comprising a light source, a first arrayed waveguide grating, a pulse generator, an optical signal amplification and modulation module, a circulator, a first selection module, and a reflected optical signal receiving module, The first arrayed waveguide diffraction grating spectrally splits seed light output by the light source, The optical signal amplification and modulation module amplifies the line diagnostic signal generated by the pulse generator and converts the line diagnostic signal after spectral division by the first arrayed waveguide diffraction grating into an optical signal of at least one wavelength channel. Modulate to generate a line diagnostic optical signal, wherein the line diagnostic optical signal is transmitted to the circulator through the first arrayed waveguide diffraction grating, The first selection module is configured to select at least one wavelength channel, The circulator is configured to supply an optical signal from the first arrayed waveguide diffraction grating to the system under test and to supply the optical signal from the system under test to the reflected optical signal receiving module, The optical signal includes the reflected line diagnostic optical signal, And the reflective optical signal receiving module is configured to analyze and process the received optical signal to obtain analysis and processing results. The method of claim 1, A second selection module coupled between the reflected optical signal receiving module and the circulator, And the second selection module is configured to control select a wavelength channel aligned with the wavelength channel selected by the first selection module. The method of claim 2, The second selection module is a tunable optical filter and is controlled to select a wavelength channel aligned with the wavelength channel selected by the first selection module; or The second selection module is a combination of a second arrayed waveguide diffraction grating and at least one optical switch, wherein the at least one optical switch is controlled to select a wavelength channel aligned with the wavelength channel selected by the first selection module, Textile testing system. The method of claim 3, And the first arrayed waveguide diffraction grating and the second arrayed waveguide diffraction grating each have channels, the center wavelengths of the channels being aligned. The method of claim 1, The first selection module includes at least one optical switch coupled between the first arrayed waveguide diffraction grating and the optical signal amplification and modulation module and controlled to select an appropriate wavelength channel; or And said first selection module comprises at least one electrical switch coupled between said first arrayed waveguide diffraction grating and said optical signal amplification and modulation module and controlled to select an appropriate wavelength channel. The method of claim 1, Further comprising a control unit, The control unit, Testing the received optical power and / or signal bit error rate of the system under test and detecting a sudden change in the received optical power and / or a decrease in the signal bit error rate on one uplink channel, the first selection module Is configured to select the appropriate wavelength channel by controlling The analysis and processing results include specific locations of fiber defects. The method of claim 1, And the pulse signal generated by the pulse generator includes instructions to turn off a light source of the system under test. The method of claim 1, Wherein said analysis and processing results comprise a specific location of fiber defects determined according to an optical time domain reflection test curve and / or said optical time domain reflection test curve. A wavelength division multiplexing optical network system comprising the fiber test system of claim 1. The method of claim 9, Further comprising a third arrayed waveguide grating, And wherein the first arrayed waveguide diffraction grating and the third arrayed waveguide diffraction grating each have a channel, the center wavelengths of the channels being aligned. The method of claim 10, Wherein said first selection module selects a downlink data electrical signal or said line diagnostic signal generated by said pulse generator and supplies it to said optical signal amplification and modulation module. A fiber defect position measuring method for measuring a position of a fiber defect in a wavelength division multiplexing optical network comprising a light source, a first arrayed waveguide diffraction grating, a pulse generator, an optical signal amplification and modulation module, and a reflected optical signal receiving module, Generating a line diagnostic signal by the pulse generator; Detecting a defect in an uplink channel and supplying said line diagnostic signal generated by said pulse generator to said optical signal amplification and modulation module; The optical signal amplification and modulation module receiving the line diagnostic signal and modulating the line diagnostic signal with seed light to generate a line diagnostic optical signal, wherein the line diagnostic optical signal is coupled to the first array waveguide Generating a line diagnostic optical signal, sent to a system under test via a diffraction grating, wherein said seed light is obtained by spectral division of a light source by said first arrayed waveguide grating; Receiving, from the system under test, an optical signal comprising the reflected line diagnostic optical signal; And Supplying the optical signal to the reflective optical signal receiving module, wherein the reflective optical signal receiving module analyzes and processes the received optical signal to obtain an analysis and processing result; Fiber defect position measuring method comprising a. The method of claim 12, Selects an optical signal amplification and modulation module applicable to an appropriate wavelength channel by controlling an electrical switch installed between the pulse generator and the optical signal amplification and modulation module, and the line diagnostics generated by the pulse generator Supplying a signal to the selected optical signal amplification and modulation module; or Control an optical switch to select an arrayed waveguide diffraction grating applicable to the appropriate wavelength channel, and the optical signal amplification and modulation module selects seed light of the selected arrayed waveguide diffraction grating channel, and the line diagnostic electrical signal Modulating the seed light into a seed light to generate a line diagnostic light signal, and supplying the line diagnostic light signal to the system under test through the first arrayed waveguide diffraction grating. Fiber defect position measuring method further comprising. The method of claim 13, The process of receiving the optical signal from the system under test, Selecting an optical signal of the appropriate wavelength channel from the optical signal of the system under test via a tunable optical filter; or Selecting an optical signal of the appropriate wavelength channel from the optical signal of the system under test through a combination of an arrayed waveguide diffraction grating and an optical switch Comprising a fiber defect position measurement method.

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