KR20050104945A - Optical path monitoring device - Google Patents

Abstract

The present invention relates to an optical communication system in which a plurality of optical subscriber stages are configured to receive light of different wavelengths through different optical paths, such as a wavelength division multiplexing-passive optical network (WDM-PON) system. The present invention relates to a light path monitoring device capable of easily identifying an obstacle of a light path coupled to each optical subscriber end.

The optical path monitoring apparatus according to the present invention includes a variable wavelength light source means for varying a wavelength of light to provide predetermined monitoring information to the optical path through light of a corresponding wavelength, and an arbitrary light path from the variable wavelength light source means by varying the wavelength of the received light. A variable wavelength light receiving means for receiving light of a wavelength reflected through the light and converting the light into an electrical signal, and calculating the disconnection position of the optical path to which the corresponding monitoring information is transmitted based on the reflected light information applied from the variable wavelength light receiving means. And a control means for changing and setting a wavelength band of the receiving light analyzer and the variable wavelength light source means and the variable wavelength light receiving means.

Description

Optical path monitoring device

The present invention relates to an optical communication system in which a plurality of optical subscriber stages are configured to receive light of different wavelengths through different optical paths, such as a wavelength division multiplexing-passive optical network (WDM-PON) system. The present invention relates to a light path monitoring device capable of easily identifying an obstacle of a light path coupled to each optical subscriber end.

Recently, the interest in the so-called WDM-PON system that directly connects the optical fiber to the optical subscriber end to provide a wide variety of broadband multimedia services to a large number of subscribers to enter the information society has been increasing.

The WDM-PON connects a service providing device that provides information to serve the optical subscriber end through a predetermined communication network, and a passive optical element between the optical subscriber end, which is a service user, and multiplexes various character / video / audio data to an optical signal. It is a network that distributes transmission to each subscriber.

1 is a block diagram schematically showing a configuration of a general WDM-PON system.

As shown in FIG. 1, the WDM-PON system includes one end of an optical wavelength distribution / combiner 20 through an optical path S ₀ composed of a single optical fiber and a service providing device 10 for providing predetermined information. The coupling end is connected, and the other end of the optical wavelength distribution / combiner 20, that is, the distribution end is configured by combining a plurality of optical subscriber ends 30 through optical paths S ₁ to S _N each composed of different optical fibers. do.

At this time, each of the optical subscriber stage 30 is configured to transmit and receive predetermined information to the service providing device 10 through the light of different wavelengths. That is, each optical subscriber stage 30 is fixed in advance for the wavelength for information transmission and information reception.

In addition, in FIG. 1, the service providing apparatus 10 is installed at a specific place such as, for example, a telephone station, the optical subscriber stage 30 is installed in the subscriber's home, and the optical wavelength distribution / combiner 20 provides a plurality of subscriber homes. It will be installed in a place under jurisdiction, such as a government office or a management room of an apartment. Therefore, the length of the optical subscriber end optical paths S ₁ to S _N formed between the optical wavelength divider / combiner 20 and the optical subscriber end 30 has a length of several m to several hundred m.

On the other hand, as in all communication systems, in order to provide a smooth service, it is required to monitor a communication line for transmitting information and to perform a repair service for a communication line having a failure. In particular, optical communication systems are no exception. In other words, when a disconnection of the optical path occurs, it is required to provide a repair service such as partial replacement of the optical path.

 Currently, optical time domain reflectometer (OTDR) devices are commonly used to monitor optical paths in optical communication systems. The OTDR device provides predetermined monitoring information to the optical path to be monitored, receives the light intensity of the optical signal scattered in the reverse direction through the optical path, and based on the received optical signal, the distance and the loss value of the optical path on the time axis. It is configured to measure.

However, the OTDR device is configured to enable monitoring of a line only for one wavelength. Therefore, in order to apply to a system using different wavelengths, such as the WDM-PON system, a large number of expensive optical elements are required to transmit and receive optical signals for each wavelength. Due to the arrangement of the ruler, there is a problem that the overall size of the OTDR equipment becomes large.

Accordingly, the present invention has been made in view of the above-described circumstances, and in an optical communication system in which different wavelengths are provided to optical subscribers through different optical paths, light of different wavelengths is variably generated and received accordingly. By providing a light path monitoring device that can easily monitor the state of each light path coupled to a plurality of subscribers by using a single light generating device and a light receiving device by receiving a reflected light of the transmitted light by changing the wavelength arbitrarily. Its technical purpose is.

The optical path monitoring apparatus according to the present invention for achieving the above object is a variable wavelength light source means for varying the wavelength of the light to provide a predetermined monitoring information to the optical path through the light of the wavelength, and the variable by varying the wavelength of the received light A variable wavelength light receiving means for receiving light having a wavelength reflected from a wavelength light source through an arbitrary optical path and converting the light into an electrical signal, and a light path for transmitting the corresponding monitoring information based on the reflected light information applied from the variable wavelength light receiving means. And a control means for changing and setting the wavelength band of the variable wavelength light source means and the variable wavelength light receiving means.

That is, according to the above, it is possible to avoid the trouble of checking and repairing, as well as saving time for checking, thereby improving the quality of service provision.

In addition, since it is possible to monitor the optical path using light of different wavelengths by using one light source means, light receiving means, and receiving light analyzer, it is possible to economically maintain and maintain the optical system. The size of the equipment can be prevented from being enlarged.

Next, an embodiment according to the present invention will be described.

The optical path monitoring device according to the present invention is applied to various optical communication systems in which a plurality of devices, that is, optical subscriber stages transmit and receive light having different wavelengths through different optical paths, will be described below based on the case where it is applied to a WDM-PON system. The configuration of the optical path monitoring apparatus according to the present invention will be described.

2 is a view schematically showing a state in which the optical path monitoring device 50 according to the present invention is applied to the WDM-PON system.

As shown in FIG. 2, the service providing apparatus 10 for providing predetermined information is combined with one end, that is, the coupling end, of the optical wavelength distribution / combiner 20 through the optical path S ₀ composed of a single optical fiber, the other end of the light wavelength distribution / combiner 20, that is the distribution stage includes a plurality of optical network stage (30: 30 ₁ ~30 _N) through a (S ₁ ~S _N) respectively to the optical customer premises beam consisting of different fiber In the combined WDM-PON system, the optical fiber optic monitoring device 50 is coupled to the WDM-PON system via an optocoupler 40 disposed on the single optical path S ₀ .

Here, the optical subscriber stage 30 receives the light of a specific wavelength applied from the optical transmitter 31 and the service providing apparatus 10 for transmitting the light of a specific wavelength for providing to the service providing apparatus 10. To filter the light of a predetermined wavelength of the wavelength applied from the optical receiver 32 and the optical wavelength divider / combiner 20, that is, the optical subscriber stage 30 to the optical receiver 32 And a wavelength division multiplexer (WDM) 33 which provides light of a predetermined transmission wavelength applied from the optical transmitter 31 to the optical wavelength divider / combiner 20. That is, each optical subscriber stage 30 is fixed in advance by the operator so that the transmission wavelength and the reception wavelength are different from each other.

In addition, the optical coupler 40 provides an optical signal applied from the service providing apparatus 10 to the optical wavelength distributor / combiner 20, and the optical subscriber terminal 30 applied from the optical wavelength distributor / combiner 20. The transmitted light of is divided into a certain ratio, for example, 90:10, and an optical signal corresponding to "90" is output to the service providing apparatus 10 through a single optical path S ₀ , and corresponds to "10". The optical signal is output to the monitoring device 50 in the light beam. In addition, the optical coupler 40 provides the optical wavelength distribution / combiner 20 with a monitoring optical signal applied from the optical path monitoring device 50.

On the other hand, the optical path monitoring device 50 is a variable wavelength light source unit 51 for outputting the predetermined monitoring information through the light of the wavelength by varying the output wavelength based on a predetermined control signal, as shown in FIG. The variable wavelength light receiver 52 and the variable wavelength light receiver 52 for selectively receiving the light reflected from the optical subscriber end optical paths S ₁ to S _N by varying the wavelength of the received light based on a predetermined control signal. The received light analyzer 53 and the reflected light applied from the optical coupler 40 calculate the fault information of the corresponding light path, in particular, the disconnection state and the location information by analyzing the signal strength of the reflected light applied from the variable wavelength light receiver. 52, an optical distribution unit 54 for providing a monitoring optical signal applied from the variable wavelength light source unit 51 to the optical coupler 40, an information input unit 551 for inputting a user's command, and an optical path monitoring. Copper of device 50 The user interface 55 having the display unit 552 for displaying and outputting the operation status and the optical beam monitoring result information, and the optical subscriber terminal receiving wavelength band information for each optical subscriber end optical path S ₁ to S _N are stored. The reception light analyzer is configured to variably set the output wavelength of the variable wavelength light source unit 51 and the reception wavelength of the variable wavelength light receiver 52 based on the information applied through the data memory 56 and the user interface 55. And a control unit 57 for controlling to display and output the analysis result information applied from the 53 through the display unit 552.

Here, the reception light analyzer 53 is a device for analyzing the state of the light path based on the reflected light, and may be configured as a reception light analysis module of the conventional OTDR device.

When the optical subscriber end optical path information to be monitored is applied from the information input unit 551, the control unit 57 extracts the wavelength band information of the corresponding optical path from the data memory 56 based on the information. 51 and the wavelength band of the variable wavelength light receiving unit 52 are controlled to be variable.

In addition, the controller 57 may control to vary the wavelength bands of the variable wavelength light source 51 and the variable wavelength light receiver 52 based on the wavelength band information applied from the information input unit 551.

In addition, the control unit 57 receives the information of the disconnected light path or the wavelength band of the disconnected light path from the outside, that is, the system operator or the service providing apparatus 10, and the variable wavelength light source unit 51 and the variable wavelength light source unit 51 are variable. It is also possible to control the wavelength band of the wavelength light receiving unit 52 to be variably set.

In addition, although not shown, the user interface 55 further includes wireless processing means for wirelessly transmitting information for monitoring a light path applied from the receiving optical analyzer 53, and the data memory 56. By storing the user's wireless communication terminal information of the control unit 57 may be configured to wirelessly transmit information for monitoring the optical path to the user's wireless communication terminal.

That is, the optical path monitoring device 50 variably sets and sets optical signals for monitoring various wavelengths having a predetermined signal strength in optical subscriber end optical paths S ₁ to S _N for transmitting and receiving light having different wavelengths. In addition to transmitting, the reception wavelength band is also changed and set to be the same as the transmission wavelength band, and when the monitoring optical signal transmitted through the corresponding optical path is reflected at the disconnection part of the optical path, the corresponding optical subscriber based on the signal strength of the reflected light The disconnection position of the disconnection beams S ₁ to S _N is analyzed.

4 to 10 are views for explaining an internal configuration of the variable wavelength light source unit 51 shown in FIG.

First, the variable wavelength light source unit 51 has a wavelength band based on a pulse signal generator 501 for generating a pulse signal corresponding to monitoring information and a control signal applied from the controller 57 as shown in FIG. A variable wavelength laser diode 502 for modulating and outputting a pulse signal applied from the pulse signal generator 501 to light having a variable wavelength, and a monitoring optical signal applied from the laser diode 502. The optical amplifier 503 can be configured to have a level amplified output.

In addition, the variable wavelength light source unit 52 is filtered based on a broadband light source 505 for generating a wide light source, for example, a light source having a wavelength band of 1530 to 1610 nm, and a control signal applied from the control unit 57, as shown in FIG. A wavelength variable filter 506 having a variable wavelength band set, a pulse signal generator 507 for generating a pulse signal corresponding to monitoring information, and a pulse signal applied from the pulse signal generator 507 with the wavelength variable filter 506 And an optical signal modulator 508 for modulating and outputting the light of the wavelength applied from the optical signal modulator 508 and an optical amplifier 509 for amplifying and outputting the light output from the optical signal modulator 507 at a predetermined level. .

At this time, the broadband light source 505 may be configured as shown in FIG. That is, the first pumping light output from the first pumping laser diode 50 ₁ 1 is coupled to the input of the optical amplifying fiber 50 ₃ through the first wavelength division multiplexer 50 _{2 2} . Here, the optical amplification optical fiber (505, ₃₎ and outputs the amplified wavelength band is different from a naturally occurring light as in the (A) or (B) Figure 7a along its length, according to the present invention by a longer set its length At the output terminal, long wavelength band light as shown in Fig. 7A is set.

That is, the optical amplification optical fiber (505 _3), and outputs to the first that the 1560nm~1620nm band generated from the light output end a second wavelength division multiplexer (505, ₅₎ by the pumping light. At this time, the backlight is 1530nm~1560nm for the output is reflected in a direction opposite to the first wavelength division multiplexer (505 _2), a first wavelength division multiplexer (505 ₂₎ generated by the first pumping light in the optical amplifying fiber (505 ₃₎ and sseokyul through the emulator (505 ₄₎ is applied again to the optical amplification optical fiber (505, ₃₎ by being amplified by the light 1560nm~1620nm band outputted from the output end of the optical amplifying fiber (505 ₃₎ to the light source through the isolator (505 ₇₎ Will print.

In addition, the optical amplifying fiber (505 ₃₎ of the second wavelength division multiplexer (505, ₅₎ via a second pump for the laser diode (505 ₆₎ a second pumping light by the second pumping light is applied in the reverse direction is applied from the At the input terminal, light of 1530 nm to 1560 nm band as shown in FIG. 7A is output through the isolator 50 ₇ . Thus, a broadband light source as shown in Fig. 7B is output.

Meanwhile, as shown in FIG. 8, the variable wavelength light source unit 51 corresponds to a wavelength-variable optical fiber laser 511 for varying and outputting a wavelength based on a control signal applied from the control unit 57 and monitoring information. A pulse signal generator 512 for generating a pulse signal, and an optical signal modulator 513 for modulating and outputting a pulse signal applied from the pulse signal generator 512 to light having a wavelength applied from the wavelength variable fiber laser 511. And an optical amplifier 514 for amplifying and outputting the light output from the optical signal modulator 513 by a predetermined level.

At this time, the variable wavelength optical fiber laser 511, as shown in Figure 9, the pumping light applied from the pumping laser diode (511 ₁ ) through the wavelength division multiplexer (511 ₂ ) optically amplified optical fiber (511 ₃ ) The optical amplified fiber 51 1 ₃ generates natural light as shown in FIG. 7A based on the input pumping light and applies the generated light to the circulator 51 ₄ . Proceeds to the photodiode 51 ₆ through the wavelength division multiplexer 51 ₂ . In this case, it is applied to Kwang from the photodiode (511, ₆₎ is converted to an electrical signal is applied as an input to the LD controller (511, _7), LD controller (511 ₇₎ of the signal received from the photodiode (511 ₆₎ The pumping light output intensity of the pumping laser diode 511 ₁ is adjusted based on.

Further, the circulator (511, ₄₎ is an optical fiber amplifier (511 _3), a naturally occurring light applied from the optical fiber Bragg grating filter module: reflection from the (FBGM 511 ₅₎ optical fiber Bragg grating filter module, with also sent to the (511 ₅₎ The reflected light of the predetermined wavelength to be applied is output as signal light. At this time, the optical fiber Bragg grating filter module 51 ₅ is configured such that a plurality of optical fiber Bragg grating filter (FBG) and a plurality of optical switches (SW) are alternately installed as shown in Figure 10 in accordance with a predetermined control signal an optical switch (SW) as the on / off control, thereby changing the wavelength of the reflected output from the optical fiber Bragg grating filter module (511, _5). Therefore, light of a specific wavelength is output through the circulator 511 ₄ .

On the other hand, Figure 11 is a diagram showing the functional separation of the internal configuration of the variable wavelength light receiving unit 52 shown in Figure 3, as shown in the wavelength band filtered based on the control signal applied from the control unit 57 The variable variable wavelength filter 521 and a photodiode 522 which converts light having a wavelength applied from the wavelength variable filter 521 into an electrical signal and provides the converted optical signal to the receiving optical analyzer 53. Can be configured. In this case, the photodiode 522 provides the reception light analyzer 53 with a voltage level corresponding to the signal strength of the received reflection light.

That is, according to the embodiment, while varying the output wavelength through the variable wavelength light source unit 51 provides a predetermined monitoring optical signal to different optical paths for transmitting different wavelengths, the wavelength for receiving the monitoring optical signal By variably setting the band, it is possible to easily check the disconnection point of the corresponding light path based on the reflected light signal strength of the optical signal for monitoring reflected by the light input due to disconnection of the optical subscriber end light beam transmitting the corresponding wavelength.

Therefore, the user can check the disconnection point in advance, thereby avoiding the hassle of performing repairs by checking the optical paths over a certain length one by one, and also saving time by checking, thereby improving the quality of service provision. It becomes possible.

In addition, since it is possible to monitor the optical path using light of different wavelengths by using one light source means, light receiving means, and receiving light analyzer, it is possible to economically maintain and maintain the optical system. The size of the equipment can be prevented from being enlarged.

In addition, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the technical spirit of the present invention.

For example, the optical path monitoring device 50 may be configured as a handset device that a user can carry. That is, as shown in FIG. 12, a predetermined first optical connector 60 for coupling with the optical path monitoring device 70 is coupled to the output end of the optical coupler 40, and the optical path monitoring device 70 is configured as described above. By configuring the second optical connector 71 corresponding to the first optical connector 60 and the control unit 72, the first optical connector 60 and the second optical connector 71 are fastened to form a communication path. In addition, it can be configured to perform maintenance of the optical subscriber end optical path formed scattered in each region by using a single equipment.

As described above, according to the present invention, the user can check the disconnection point in advance, thereby avoiding the hassle of performing repairs by checking the optical path of a certain length one by one, and of course, saving time due to the check. It is also possible to obtain an improved effect.

In addition, since it is possible to monitor the optical path using light of different wavelengths by using one light source means, light receiving means, and receiving light analyzer, it is possible to economically maintain and maintain the optical system. The size of the equipment can be prevented from being enlarged.

1 is a block diagram schematically showing the configuration of a typical WDM-PON system.

2 is a view showing a configuration in which the optical path monitoring device 50 according to the present invention is applied to a WDP-PON system.

Figure 3 is a block diagram showing the functional separation of the internal configuration of the optical path monitoring device 50 shown in FIG.

4 to 10 are views for explaining an internal configuration of the variable wavelength light source unit 51 shown in FIG.

FIG. 11 is a view for explaining an internal configuration of the variable wavelength light receiver 52 shown in FIG.

Fig. 12 is a diagram showing another configuration example in which the optical path monitoring device 70 according to the present invention is applied to a WDM-PON system.

******* Brief description of the main parts of the drawing *******

10: service providing device, 20: optical wavelength distribution / combiner,

30: optical subscriber stage, 40: optocoupler,

50: ray monitoring device,

51: variable wavelength light source unit, 52: variable wavelength light receiving unit,

53: receiving light analyzer, 54: light distribution unit,

55: user interface, 56: data memory,

57: control unit.

Claims (10)

Variable wavelength light source means for varying the wavelength of the light and providing predetermined monitoring information to the optical path through the light of the wavelength; Variable wavelength light receiving means for varying the wavelength of the received light and receiving light having a wavelength reflected from the variable wavelength light source means through an arbitrary optical path and converting the light into an electrical signal; A reception light analyzer for calculating the disconnection position of the optical path to which the monitoring information is transmitted based on the reflected light information applied from the variable wavelength light receiving means; And control means for changing and setting the wavelength band of said variable wavelength light source means and said variable wavelength light receiving means. The method of claim 1, And the control means sets the wavelength bands of the variable wavelength light source means and the variable wavelength light receiving means based on wavelength information provided from the outside. The method of claim 1, And a user interface having information input means for inputting a user's command and display means for displaying and outputting information. The control means sets the wavelength bands of the variable wavelength light source means and the variable wavelength light receiving means based on the information applied from the user interface, and displays disconnection position information applied from the receiving light analyzer through the display means. And monitoring the light beam. The method of claim 3, And a data memory for storing wavelength band information for each optical line information. The control means extracts the corresponding wavelength band information from the data memory based on the optical path information applied through the user interface to set the wavelength bands of the variable wavelength light source means and the variable wavelength light receiving means. Thorns. The method of claim 2, The variable wavelength light source means includes a pulse signal generator for generating a pulse signal corresponding to the monitoring information; A wavelength tunable laser diode that varies the wavelength band based on a control signal applied from the control means and modulates and outputs a pulse signal applied from the pulse signal generator to light having a variable wavelength; And an optical amplifier configured to amplify and output a predetermined level of the optical signal applied from the laser diode. The method of claim 2, The variable wavelength light source means includes a broadband light source for generating a broadband light source; A wavelength variable filter having a variable wavelength band filtered based on a control signal applied from the control means; Pulse signal generator for generating a pulse signal corresponding to the monitoring information, An optical signal modulator for modulating and outputting a pulse signal applied from the pulse signal generator to light having a wavelength applied from the wavelength variable filter; And an optical amplifier configured to amplify and output a predetermined level of light output from the optical signal modulator. The method of claim 2   The variable wavelength light source means includes: a variable wavelength optical fiber laser for outputting a variable wavelength based on a control signal applied from the control means; Pulse signal generator for generating a pulse signal corresponding to the monitoring information, An optical signal modulator for modulating and outputting a pulse signal applied from the pulse signal generator to light having a wavelength applied from the wavelength variable fiber laser; And an optical amplifier configured to amplify and output a predetermined level of light output from the optical signal modulator. The method of claim 2, The variable wavelength light receiving means includes: a wavelength tunable filter having a variable wavelength band that is filtered based on a control signal applied from the control means; And a photodiode for converting light of a wavelength applied from the wavelength variable filter into an electrical signal and providing the light to the receiving optical analyzer. The method according to claim 1, wherein The optical path monitoring device is coupled to the coupling end of the optical wavelength distribution combiner through a single optical path, and the distribution terminal of the optical wavelength distribution combiner transmits light having different wavelengths through different optical paths. In the WDM-PON system to be connected to the optocoupler coupled between the single optical path and the wavelength division combiner, The optical coupler divides an optical signal applied from the optical wavelength division combiner at a predetermined ratio to provide an optical signal of a first level to the service providing apparatus and an optical signal of a second level to the optical path monitoring device. And an optical signal applied from the optical path monitoring device to the optical wavelength distribution combiner. The method according to claim 1, wherein WDM-PON is coupled to the service providing device and the coupling end of the optical wavelength distribution combiner through a single optical path, and the distribution end of the optical wavelength distribution combiner allows a plurality of optical subscriber terminals to transmit light of different wavelengths through different optical paths. A first optical coupling means of the optocoupler coupled between the single optical path and the optical wavelength combiner in the system, The optical path monitoring device is configured in the form of a handset and further comprises a second optical coupling means corresponding to the first optical coupling means, The optical coupler divides an optical signal applied from the optical wavelength division combiner at a predetermined ratio to provide an optical signal of a first level to the service providing apparatus and an optical signal of a second level to the optical path monitoring device. And an optical signal applied from the optical path monitoring device to the optical wavelength distribution combiner.