Patent Abstract:
A self-healing passive optical network is disclosed. The network includes a central office and a remote node connected to the central office through a main optical fiber. The remote node transmits one portion of power of the upstream optical signal, which has been input from each of the optical network units, to the central office, and returning a remaining portion of the power of the upstream optical signal to the optical network unit. The network also includes a plurality of optical network units connected to the remote node through a plurality of distribution optical fibers. Each of the optical network units transmits an upstream optical signal to the remote node through the directly connected distribution optical fiber, and detects abnormality occurrences from a state of the upstream optical signal returning from the remote node.

Full Description:
CLAIM OF PRIORITY 
   This application claims priority to an application entitled “Self-healing passive optical network,” filed in the Korean Intellectual Property Office on Dec. 19, 2003 and assigned Serial No. 2003-93864, the contents of which are hereby incorporated by reference. 
   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to an optical communication network, and more particularly to a passive optical network (PON). 
   2. Description of the Related Art 
   Wavelength division multiplexing passive optical networks (hereinafter, referred to as WDM-PON) provide ultra high-speed broadband communication service using specific wavelengths assigned to each subscriber unit. WDM-PONs can ensure the secrecy of communication, can easily accommodate special communication services required from each subscriber unit or enlargement of channel capacity, and can easily increase the number of subscriber units by adding specific wavelengths to be assigned to new subscribers. 
   However, in spite of the advantages described above, the WDM-PON has not yet been put to practical use. This is because a central office (CO) and a plurality of optical network units (ONUs) in the WDM-PON require both light sources having specific oscillation wavelengths and additional wavelength stabilization circuits for stabilizing the wavelengths of the light sources. This puts a heavy economic burden on the subscribers. In order to construct an economic WDM-PON, some conventional WDM-PON have tried using a fabry-perot laser wavelength-locked with inherent light or a reflective semiconductor optical amplifier as a WDM light source, which allow a spectrum sliced broadband light source to facilitate wavelength management. 
   Generally, the conventional WDM-PON uses a double star structure in order to minimize the length of optical line. A central office and a remote node (RN) installed at an area adjacent to optical network units are connected to each other through one main optical fiber (MOF). The remote node and each optical network unit are connected to each other through a separate distribution optical fiber (DOF). Multiplexed downstream optical signals are transmitted to the remote node through the main optical fiber. The multiplexed downstream optical signals are demultiplexed by a wavelength division multiplexer installed in the remote node and the demultiplexed signals are transmitted to the optical network units through the distribution optical fibers. The upstream optical signals output from the optical network units are transmitted to the remote node and multiplexed by the wavelength division multiplexer. The multiplexed signal is transmitted to the central office. 
   In such WDM-PON, large amounts of data are transmitted at high speed through wavelengths assigned to each optical network unit. Accordingly, when an abnormality (such as malfunction or deterioration) of an upstream light source or a downstream light source or an abnormality (such as cut or deterioration) of a main optical fiber or distribution optical fiber occurs, the transmitted data may be lost even if the abnormality only occurs for a short time. Accordingly, such an abnormality must be quickly detected and be corrected. 
   However, when the direct optical line between the central office and the optical network units is cut, the central office and the optical network units cannot report the existence or absence of abnormality to each other. For this situation, a separate low speed communication line may be provided. However, in order to install the separate low speed communication line the central office and each optical network unit, additional cost is required and investment is required for continuously managing and supervising the separate low speed communication line. In addition, in order for the central office and each optical network unit to communicate with each other and check the existence or absence of abnormality through the separate low speed communication line, and to report a manager of the abnormality occurrence, a separated time period is required. As a result, a communication interruption state between the central office and each optical network unit is extended by the time period. 
   It is also necessary to develop a monitoring method, which can quickly detect an abnormality of an upstream light source or a downstream light source, or an abnormality of a main optical fiber or a distribution optical fiber, and directly report the manager of the existence or absence of abnormality, and a correction method. 
   The abnormality of the downstream light source or the abnormality of the main optical fiber connecting the central office to the remote node can be monitored by the central office which manages the operation state of the downstream light sources and the received state of all upstream optical signals. For example, when it is assumed that an abnormality does not occur at each distribution optical fiber connecting the remote node to each optical network unit, the state of the upstream light source installed at each optical network unit may be monitored from an upstream optical signal received in an upstream optical receiver installed at the central office. However, when an abnormality occurs at one distribution optical fiber, since the central office cannot receive an upstream optical signal progressing to the distribution optical fiber, the state of the upstream light source cannot be monitored. 
   Accordingly, in the WDM-PON, a method is required, which can monitor an abnormality of the distribution optical fiber. Further, a monitoring method is required, which can distinguish and recognize an abnormality of the upstream light source and an abnormality of the distribution optical fiber. Furthermore, when an abnormality has occurred at the upstream light source or the distribution optical fiber, a method capable of healing the abnormality is required. 
   SUMMARY OF THE INVENTION 
   One aspect of the present invention relates to a passive optical network capable of monitoring an abnormality of a distribution optical fiber. 
   Another aspect of the present invention relates to a passive optical network capable of distinguishing and recognizing an abnormality of an upstream light source and abnormality of a distribution optical fiber. 
   Another aspect of the present invention relates to a passive optical network capable of performing self-healing when an abnormality occurs at an upstream light source or a distribution optical fiber. 
   One embodiment of the present invention it directed to a self-healing passive optical network including a central office and a remote node connected to the central office through a main optical fiber. The remote node transmits one portion of power of the upstream optical signal, which has input from each of the optical network units, to the central office. A remaining portion of the power of the upstream optical signal to the optical network unit is returned. The network also includes a plurality of optical network units connected to the remote node through a plurality of distribution optical fibers, each of the optical network units transmitting an upstream optical signal to the remote node through the directly connected distribution optical fiber, and detecting abnormality occurrence from a state of the upstream optical signal returning from the remote node. 
   Another embodiment of the present invention is directed to a passive optical network including a central office and a remote node. The remote node including a wavelength division multiplexer and a plurality of optical distributors. The wavelength division multiplexer has a multiplexing port connected to the central office through a main optical fiber and a plurality of demultiplexing ports connected to a plurality of distribution optical fibers. The wavelength division multiplexer multiplexes a plurality of upstream optical signals input to the demultiplexing ports to output the multiplexed signal to the multiplexing port, and the optical distributors disposed on the distribution optical fibers, having multiple pairs of the optical distributors, passing input upstream optical signals when the upstream optical signals have specific wavelengths assigned to the optical distributors, and transmitting the upstream optical signals to other optical distributors when the upstream optical signals do not have specific wavelengths assigned to the optical distributors. The network also includes a plurality of optical network units connected to the distribution optical fibers, having multiple pairs of the optical network units, and having a first upstream light source for outputting an upstream optical signal and a first optical switch, the first optical switch transmitting the upstream optical signal to a directly connected distribution optical fiber in a normal state. The first optical switch transmits the upstream optical signal through a distribution optical fiber connected to a corresponding optical network wilt when an abnormality occurs at the distribution optical fiber. 
   Yet another embodiment of the present invention is directed to an optical network unit for an optical network. The unit includes an interface for a distribution optical fiber, an upstream light source for outputting an upstream optical signal and a controller. The optical network units transmits the upstream optical signal via the interface and receives a return signal based upon the upstream optical signal. The control is arranged to detect an abnormality occurrence from a state of the return signal. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above and other aspects, features and embodiments of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: 
       FIG. 1  is a diagram showing the construction of a PON according to one embodiment of the present invention; 
       FIG. 2  is a block diagram illustrating an abnormality position determination process in the PON shown in  FIG. 1 ; 
       FIG. 3  is a block diagram illustrating an optical line switching process in the PON shown in  FIG. 1 ; and 
       FIG. 4  is a block diagram illustrating a light source changing process in the PON shown in  FIG. 1 . 
   

   DETAILED DESCRIPTION 
   Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configuration incorporated herein will be omitted when it may obscure the subject matter of the present invention. 
     FIG. 1  is a diagram showing the construction of a PON according to one embodiment of the present invention. The PON  100  includes a central office  110 , a remote node  130  connected to the central office  110  through an main optical fiber  120 , and a first to an n th  optical network unit  180 - 1  to  180 -n connected to the remote node  130  through a first to an n th  distribution optical fiber  170 - 1  to  170 -n. 
   The central office  110  receives multiplexed upstream optical signals through the main optical fiber  120 . 
   The remote node  130  is connected to the central office  110  through the main optical fiber  120  and includes a reflector  140 , a wavelength division multiplexer (WDM)  150 , and a first to an n th  optical distributor (OD)  160 - 1  to  160 -n. 
   The reflector  140  has one end connected to the main optical fiber  120  and other end connected to a multiplexing port (MP) of the wavelength division multiplexer  150 . The reflector  140  receives upstream optical signals multiplexed by the wavelength division multiplexer  150 , partially transmits the power of the multiplexed upstream optical signals, and partially reflects the power of the multiplexed upstream optical signals to the wavelength division multiplexer  150 . The reflector  140  may also include a multi-layer thin film filter having a predetermined reflection factor in a predetermined wavelength range, at least one fiber Bragg grating (FBG), or a mirror. 
   The wavelength division multiplexer  150  has the multiplexing port and a first to an n th  demultiplexing port (DP). The multiplexing port is connected to the reflector  140 , and the first to the n th  demultiplexing port are respectively connected to the first to the n th  optical distributor  160 - 1  to  160 -n in a one-to-one fashion. The wavelength division multiplexer  150  multiplexes a first to an n th  upstream optical signal input to the first to the n th  demultiplexing port to output the multiplexed signal to the multiplexing port. The wavelength division multiplexer  150  may also include an arrayed waveguides grating (AWG). 
   The first to the n th  optical distributor  160 - 1  to  160 -n each have a first to a fourth port. The first port is connected to a corresponding demultiplexing port. The second port is connected to a fourth port of a corresponding optical distributor. The third port is connected to a corresponding distribution optical fiber. The fourth port is connected to a second port of a corresponding optical distributor. 
   In  FIG. 1 , an X th  optical distributor corresponds to an (n+1−X) th  optical distributor, where, 1≦X ≦(n/2), n and X are natural numbers. For example, the first optical distributor  160 - 1  corresponds to the n th  optical distributor  160 -n, the second optical distributor  160 - 2  corresponds to the (n−1) th  optical distributor  160 -(n−1), and the third optical distributor  160 - 3  corresponds to the (n−2) th  optical distributor  160 -(n−2). 
   In another embodiment, a correspondence method between two optical distributors may be optionally selected. For example, two optical distributors adjacent to each other may correspond. The first optical distributor  160 - 1  corresponds to the second optical distributor  160 - 2 , and the third optical distributor  160 - 3  corresponds to the fourth optical distributor  160 - 4 . 
   Each of the first to the n th  optical distributor  160 - 1  to  160 -n has a specific wavelength. When a wavelength of an upstream optical signal input to the third port coincides with the specific wavelength, the upstream optical signal is output to the first port. Otherwise, the upstream optical signal is output to the second port. In this way, the n th  optical distributor  160 -n outputs the n th  upstream optical signal input to the third port to the first port, and outputs the first upstream optical signal input to the third port to the first port. Further, each of the first to the n th  optical distributor  160 - 1  to  160 -n outputs an upstream optical signal input to the first port to the third port. The n th  optical distributor  160 -n outputs the n th  upstream optical signal input to the first port to the third port. 
   The first to the n th  optical network unit  180 - 1  to  180 -n are connected to the remote node  130  through the first to the n th  distribution optical fiber  170 - 1  to  170 -n. The n th  optical network unit  180 -n includes an n th  optical coupler (OC)  190 -n, an n th  circulator (CIR)  200 -n,a (n−1) th  and a (n−2) th  optical switch (OS)  220 -n and  250 -n, an n th  optical receiver (RX)  260 -n, an n th  beam splitter (BS)  260 -n, a (n−1) th  and a (n−2) th  upstream light source (LS)  230 -n and  240 -n, and an n th  controller (CTRL)  270 -n. An X th  optical network unit corresponds to a (n+1−X)th optical network unit. Since the first to the n th  optical network unit  180 - 1  to  180 -n have the same constructions, the first optical network unit  180 - 1  will be representatively described hereinafter. 
   A ( 1 - 1 ) th  upstream light source and a ( 1 - 2 ) th  upstream light source  230 - 1  and  240 - 1  each output a first upstream optical signal under the control of a first controller  270 - 1 . The ( 1 - 2 ) th  upstream light source  240 - 1  is a reserved light source and operates when an abnormality occurs at the ( 1 - 1 ) th  upstream light source  230 - 1 . 
   A ( 1 - 1 ) th  optical switch  220 - 1  has a first to a fourth port. The first port is connected to a first beam splitter  210 - 1 . The second port is connected to the n th  optical coupler  190 -n of the n th  optical network unit  180 -n. The third port is connected to the ( 1 - 1 ) th  upstream light source  230 - 1 . The fourth port is connected to the ( 1 - 2 ) th  upstream light source  240 - 1 . The ( 1 - 1 ) th  optical switch  220 - 1  connects the first port to the third port in a normal state under the control of a first controller  270 - 1 , connects the first port to the fourth port when an abnormality occurs at the ( 1 - 1 ) th  upstream light source  230 - 1 , and connects the second port to the third port when an abnormality occurs at the first distribution optical fiber  170 - 1 . 
   The first beam splitter  210 - 1  has a first to a third port. The first port is connected to a first circulator  200 - 1 . The second port is connected to a ( 1 - 2 ) th  optical switch  250 - 1 . The third port is connected to the first port of the ( 1 - 1 ) th  optical switch  220 - 1 . The first beam splitter  210 - 1  splits the power of the first upstream optical signal, which is input to the third port, at a predetermined proportion, outputs one portion of the split power to the first port, and outputs the other portion of the split power to the second port. 
   The first circulator  200 - 1  has a first to a third port. The first port is connected to the first port of the first beam splitter  210 - 1 . The second port is connected to a first optical coupler  190 - 1 . The third port is connected to the ( 1 - 2 ) th  optical switch  250 - 1 . The first circulator  200 - 1  outputs the first upstream optical signal input to the first port to the second port, and outputs the first upstream optical signal input to the second port to the third port. 
   The ( 1 - 2 ) th  optical switch  250 - 1  has a first to a third port. The first port is connected to the third port of the first circulator  200 - 1 . The second port is connected to the second port of the first beam splitter  210 - 1 . The third port is connected to a first optical receiver  260 - 1 . The ( 1 - 2 ) th  optical switch  250 - 1  connects the first port to the third port in a normal state under the control of the first controller  270 - 1 , and connects the second port to the third port when an abnormality occurs. 
   The first optical receiver  260 - 1  is connected to the third port of the ( 1 - 2 ) th  optical switch  250 - 1 , and converts the received first upstream optical signal into an electrical signal which will be output. 
   The first controller  270 - 1  detects that an abnormality has occurred at the first distribution optical fiber  170 - 1  or the ( 1 - 1 ) th  upstream light source  230 - 1  according to the state of the electrical signal (abnormality occurrence detection stage), and performs an abnormality position determination stage, an optical line switching stage, or a light source changing stage. 
   The operation of the PON  100  in a normal state will now be described with reference to  FIG. 1 . 
   In the normal state, the first port of the ( 1 - 1 ) th  optical switch  220 - 1  is connected to the third port of the ( 1 - 1 ) th  optical switch  220 - 1 , and the first port of the ( 1 - 2 ) th  optical switch  250 - 1  is connected to the third port of the ( 1 - 2 ) th  optical switch  250 - 1 . The first upstream optical signal output from the ( 1 - 1 ) th  upstream light source  230 - 1  passes through the ( 1 - 1 ) th  optical switch  220 - 1  and is input to the first beam splitter  210 - 1 . 
   The first beam splitter  210 - 1  splits the power of the first upstream optical signal, outputs one portion of the split power to the first port, and outputs the other portion of the split power to the second port. The first upstream optical signal outputted from the second port of the first beam splitter  210 - 1  is input to the second port of the ( 1 - 2 ) th  optical switch  250 - 1  and then disappears. The first upstream optical signal output from the first port of the first beam splitter  210 - 1  is input to the first port of the first circulator  200 - 1  and is output to the second port. The first upstream optical signal then passes through the first optical coupler  190 - 1 , the first distribution optical fiber  170 - 1 , and the first optical distributor  160 - 1  and is input to the first demultiplexing port of the wavelength division multiplexer  150 . 
   The wavelength division multiplexer  150  multiplexes the first upstream optical signal and the second to the n th  upstream optical signal input to the second to the n th  demultiplexing port, and outputs the multiplexed upstream optical signals to the multiplexing port. The power of the multiplexed upstream optical signals is split by the reflection of the reflector  140 , one portion of the split power passes through the reflector  140  and is transmitted to the central office  110  through the main optical fiber  120 . The other portion of the split power is input to the multiplexing port of the wavelength division multiplexer  150 . The wavelength division multiplexer  150  demultiplexes the multiplexed upstream optical signals, which are input to the multiplexing port, according to wavelengths to output the demultiplexed signals the first to the n th  demultiplexing port. 
   The first upstream optical signal output from the first demultiplexing port passes through the first optical distributor  160 - 1 , the first distribution optical fiber  170 - 1 , and the first optical coupler  190 - 1 , is input to the second port of the first circulator  200 - 1  and is output to the third port. The first upstream optical signal output from the third port of the first circulator  200 - 1  is input to the first port of the ( 1 - 2 ) th  optical switch  250 - 1 , is output to the third port, and is input to the first optical receiver  260 - 1 . The first optical receiver  260 - 1  converts the input first upstream optical signal into an electrical signal which will be output. Since the input electrical signal is in a normal state, the first controller  270 - 1  determines that the first distribution optical fiber  170 - 1  or the ( 1 - 1 ) th  upstream light source  230 - 1  is in a normal state. 
   Abnormality Occurrence Detection Stage 
   The first controller  270 - 1  detects that an abnormality has occurred at the first distribution optical fiber  170 - 1  or the ( 1 - 1 ) th  upstream light source  230 - 1  when the input electrical signal is in an abnormal state (e.g., rapid reduction of power or intermittent interruption of a signal), or an electrical signal is not input. 
   Abnormality Position Determination Stage 
     FIG. 2  is a block diagram illustrating an abnormality position determination process in the PON shown in  FIG. 1 . Hereinafter, a process in which the first controller  270 - 1  determines an abnormality position when the abnormality has occurred at the first distribution optical fiber  170 - 1  or the ( 1 - 1 ) th  upstream light source  230 - 1  will be described with reference to  FIG. 2 . 
   The first controller  270 - 1  detects that the abnormality has occurred and controls the second port of the ( 1 - 2 ) th  optical switch  250 - 1  to be connected to the third port of the ( 1 - 1 ) th  optical switch  250 - 1 . When the input electrical signal is in a normal state, the first controller  270 - 1  determines that the abnormality has occurred at the first distribution optical fiber  170 - 1 . When the input electrical signal is in an abnormal state or an electrical signal is not input, the first controller  270 - 1  determines that the abnormality has occurred at the ( 1 - 1 ) th  upstream light source  230 - 1 . 
   When the abnormality has occurred at the first distribution optical fiber  170 - 1 , the first controller  270 - 1  performs the optical line switching process which will be described below. When the abnormality has occurred at the ( 1 - 1 ) th  upstream light source  230 - 1 , the first controller  270 - 1  performs the light source changing process which will be described below. 
   Optical Line Switching Stage 
     FIG. 3  is a block diagram illustrating an optical line switching process in the PON shown in  FIG. 1 . Hereinafter, a process in which the first controller  270 - 1  switches the optical line when the abnormality has occurred at the first distribution optical fiber  170 - 1  will be described with reference to  FIG. 3 . 
   The first controller  270 - 1  detects that the abnormality has occurred at the first distribution optical fiber  170 - 1  and controls the second port of the ( 1 - 1 ) th  optical switch  220 - 1  to be connected to the third port of the ( 1 - 1 ) th  optical switch  220 - 1 . 
   The first upstream optical signal output from the ( 1 - 1 ) th  upstream light source  230 - 1  passes through the ( 1 - 1 ) th  optical switch  220 - 1 , is input to the third port of the n th  optical coupler  190 -n, and is output to the first port thereof. The first upstream optical signal output from the first port of the n th  optical coupler  190 -n passes through the n th  distribution optical fiber  170 -n, is input to the third port of the n th  optical distributor  160 -n, and is output to the second port thereof. The second port of the n th  optical distributor  160 -n is connected to the fourth port of the first optical distributor  160 - 1 , and the first optical distributor  160 - 1  outputs the first upstream optical signal input to the fourth port to the first port. The first upstream optical signal output from the first port of the first optical distributor  160 - 1  is input to the first demultiplexing port of the wavelength division multiplexer  150 . 
   The wavelength division multiplexer  150  multiplexes the first upstream optical signal and the second to the n th  upstream optical signal input to the second to the n th  demultiplexing port, and outputs the multiplexed upstream optical signals to the multiplexing port. The power of the multiplexed upstream optical signals is split by the reflection of the reflector  140 . One portion of the split power passes through the reflector  140  and is transmitted to the central office  110  through the main optical fiber  120 . The other portion of the split power is input to the multiplexing port of the wavelength division multiplexer  150 . 
   Light Source Changing Stage 
     FIG. 4  is a block diagram illustrating a light source changing process in the PON shown in  FIG. 1 . Hereinafter, a process in which the first controller  270 - 1  replaces the ( 1 - 1 ) th  upstream light source  230 - 1  with the ( 1 - 2 ) th  upstream light source  240 - 1  when the abnormality has occurred at the ( 1 - 1 ) th  upstream light source  230 - 1  will be described with reference to  FIG. 4 . 
   The first controller  270 - 1  detects that the abnormality has occurred at the ( 1 - 1 ) th  upstream light source  230 - 1  and controls the first port of the ( 1 - 1 ) th  optical switch  220 - 1  to be connected to the fourth port of the ( 1 - 1 ) th  optical switch  220 - 1 , controls the first port of the ( 1 - 2 ) th  optical switch  250 - 1  to be connected to the third port of the ( 1 - 1 ) th  optical switch  250 - 1 , and operates the ( 1 - 2 ) th  upstream light source  240 - 1 . 
   The first upstream optical signal output from the ( 1 - 2 ) th  upstream light source  240 - 1  passes through the ( 1 - 1 ) th  optical switch  220 - 1 , and is input to the first beam splitter  210 - 1 . The first beam splitter  210 - 1  splits the power of the first upstream optical signal, outputs one portion of the split power to the first port thereof, and outputs the other portion of the split power to the second port thereof. The first upstream optical signal output from the second port of the first beam splitter  210 - 1  is input to the second port of the ( 1 - 2 ) th  optical switch  250 - 1  and then disappears. The first upstream optical signal output from the first port of the first beam splitter  210 - 1  is input to the first port of the first circulator  200 - 1  and is output to the second port thereof. The first upstream optical signal then passes through the first optical coupler  190 - 1 , the first distribution optical fiber  170 - 1 , and the first optical distributor  160 - 1  and is input to the first demultiplexing port of the wavelength division multiplexer  150 . 
   The wavelength division multiplexer  150  multiplexes the first upstream optical signal and the second to the n th  upstream optical signal input to the second to the n th  demultiplexing port, and outputs the multiplexed upstream optical signals to the multiplexing port. The power of the multiplexed upstream optical signals is split by the reflection of the reflector  140 . One portion of the split power passes through the reflector  140  and is transmitted to the central office  110  through the main optical fiber  120 . The other portion of the split power is input to the multiplexing port of the wavelength division multiplexer  150 . The wavelength division multiplexer  150  demultiplexes the multiplexed upstream optical signals, which are input to the multiplexing port, according to wavelengths to output the demultiplexed signals the first to the n th  demultiplexing port. The first upstream optical signal output from the first demultiplexing port passes through the first optical distributor  160 - 1 , the first distribution optical fiber  170 - 1 , and the first optical coupler  190 - 1 , is input to the second port of the first circulator  200 - 1  and is output to the third port thereof. The first upstream optical signal output from the third port of the first circulator  200 - 1  is input to the first port of the ( 1 - 2 ) th  optical switch  250 - 1 , is output to the third port thereof, and is input to the first optical receiver  260 - 1 . 
   The first optical receiver  260 - 1  converts the input upstream optical signal into an electrical signal which will be output. Since the input electrical signal is in a normal state, the first controller  270 - 1  determines that the light source changing process has been normally performed. 
   As described above, abnormality occurrence is detected from a state of a returning upstream optical signal, so that the abnormality occurrence can be quickly detected and instantly processed. 
   In addition, a state of a distribution optical fiber and a state of an upstream light source located at an optical network unit are respectively monitored. Self-healing can then be performed when an abnormality occurs at the distribution optical fiber or the upstream light source. Therefore, the distribution optical fiber and the upstream light source can be economically and efficiently managed and healed. 
   While the invention has been shown and described with reference to certain embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Technology Classification (CPC): 7