JP2003229823A - System, program and method for specifying position - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a position specification system for more accurately specifying the position of a connection in the case of establishing a plurality of optical fibers from a starting point station by connecting the plurality of optical fibers at respective connections, and the position where a failure occurs if the failure occurs in the optical fibers. <P>SOLUTION: In the case of establishing the optical fibers from the starting point station 20 by connecting the optical fibers, the position specification system 10 is provided with a distance information acquiring part 103 for acquiring optical distance information for specifying an optical distance between a connection 42 for connecting a new optical fiber 53 and the starting point station 20 in connecting the new optical fiber 53 to an optical fiber 52 on the side of the starting point station 20, a position information acquiring part 101 for acquiring latitude and longitude information for specifying the latitude and longitude of the connection 42, and a position information generating part 102 for associating the latitude and longitude information with the optical distance information to store in a position information storing part 109 the associated information as connection position information for specifying the position of the connection 42. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a position specifying system, a position specifying program, and a position specifying method for specifying a position on an optical line connected with an optical fiber.

[0002]

2. Description of the Related Art A device for identifying a position on an optical line laid by fusion splicing optical fibers is OTDR.
(Optical Time Domain Refl
ectmeter). This optical pulse tester enters an optical pulse as test light from one end of the optical fiber that constitutes the optical line, and reflects the optical power of the backscattered light that is reflected at each point in the longitudinal direction of the optical fiber and returns to the incident end. By analyzing the distance distribution, the loss of the optical fiber, the distance to the connection point of the optical fiber, the connection loss and the reflection amount generated at the connection point, and the distance to the break point when the optical fiber is broken are measured.

[0003]

By the way, when the optical fibers are fusion-spliced, the loss at the splicing point may be extremely small depending on the degree of fusion. The conventional optical pulse tester measures the optical distance to the connection point by detecting the loss at the connection point, but if the degree of fusion at the connection point is good and the loss is extremely small, the connection point The optical distance to may not be accurately measured.

Further, when a failure occurs on the optical line, the optical distance to the failure occurrence position where the failure occurs is measured by using an optical pulse tester, and the light beam is based on the measured optical distance. The actual fault location is specified by referring to the design information and maps of the optical fibers that make up the path.
However, each optical fiber forming the optical line is provided with an extra length with respect to the design length, and an error may occur when the fault occurrence position is specified based on the design information of the optical fiber. In order to eliminate such an error, the position of each connection point was estimated and the error was corrected using the optical distance to that connection point. Since the target distance cannot be measured accurately, it is difficult to specify the fault occurrence position accurately.

Therefore, in the present invention, the position of the connection point when a plurality of single-core or multi-core optical fibers are connected and laid at each connection point from the origin station, and the occurrence of a failure when the optical fiber fails An object is to provide a position specifying system, a position specifying program, and a position specifying method that specify a position more accurately.

[0006]

The position specifying system of the present invention, when connecting and laying an optical fiber from a starting station, newly connects the optical fiber to the optical fiber on the side of the starting station. Distance information acquisition means to acquire optical distance information to specify the optical distance between the connection point connecting the different optical fibers and the origin station, and latitude / longitude information to specify the geographical position of the connection point And position information generating means for storing in the position information storage means as connection point position information for identifying the position of the connection point by associating the latitude / longitude information and the optical distance information with each other.

The position specifying program of the present invention is to install a new optical fiber when connecting a new optical fiber to the optical fiber on the side of the origin station when the computer is installed by connecting the optical fiber from the origin station. Distance information acquisition means for acquiring the optical distance information for specifying the optical distance between the connection point and the origin station, and position information for acquiring the latitude / longitude information for specifying the geographical position of the connection point It functions as an acquisition unit and a position information generation unit that stores the connection point position information for identifying the position of the connection point in association with the latitude / longitude information and the optical distance information in the position information storage unit.

According to the position specifying method of the present invention, when the optical fiber is connected from the origin station and installed, when the optical fiber is newly connected to the optical fiber on the origin station side, the distance information acquisition means makes the new information. A distance information acquisition step for acquiring optical distance information for specifying the optical distance between the connection point connecting the optical fibers and the origin station, and the position information acquisition means for specifying the geographical position of the connection point. Position information obtaining step of obtaining the latitude and longitude information of the position information, and the position information generating means stores in the position information storing means as connection point position information for associating the latitude and longitude information and the optical distance information to specify the position of the connection point And a position information generating step of

According to the position specifying system and the position specifying method of the present invention, when the distance information acquisition means newly connects an optical fiber to the optical fiber on the side of the originating station, the optical distance between the connection point and the originating station is set. Since the information is acquired, the optical distance information to each connection point can be acquired more accurately. Since the position information generation means stores the optical distance information of each connection point acquired by the distance information acquisition means and the latitude / longitude information of each connection point acquired by the position information acquisition means in the position information storage means in association with each other, The actual position of the connection point can be grasped more accurately. Also, the same operation is achieved by executing the position specifying program of the present invention using a computer.

According to the position specifying system of the present invention, when a failure occurs in the optical line laid by connecting a plurality of single-core or multi-core optical fibers at each connection point from the starting station, the failure occurs from the starting station. Distance information acquisition means for acquiring the optical distance to the fault occurrence position that has occurred, and from each connection point of the optical fiber, is closer to the fault occurrence position on the side of the originating station than the fault occurrence position, or A first proximity connection point that matches and a second proximity connection point that is on the opposite side of the origin station across the failure occurrence position and that is closest to or matches the failure occurrence position, respectively. Proximity connection point specifying means for specifying, the optical distance from the origin point station to the fault occurrence position acquired by the distance information acquisition means, and the first proximity connection point and the second proximity connection point from the origin point station previously stored in the position information storage means. Up to each close connection point of Of the fault occurrence position based on the geometrical distance and the latitude / longitude information for identifying the geographical position of each of the first proximity connection point and the second proximity connection point stored in advance in the position information storage means. Failure occurrence position specifying means for specifying a target position.

The position specifying program of the present invention causes a computer to start from a starting station when a failure occurs in an optical line laid by connecting a plurality of single-core or multi-core optical fibers at each connection point from the starting station. From the distance information acquisition means for acquiring the optical distance to the fault occurrence position where the fault has occurred, and the connection point of the optical fiber, it is closer to the fault occurrence position on the side of the originating station than the fault occurrence position. Or a first proximity connection point that is coincident with the first proximity connection point and a second proximity connection point that is closest to or coincides with the failure occurrence position on the opposite side of the origin station across the failure occurrence position. And the optical distance from the origin station to the fault occurrence position acquired by the distance information acquisition means, and the first proximity connection point from the origin station stored in advance in the position information storage means. And the second proximity Obstacles based on the optical distance to each point and latitude / longitude information for identifying the geographical position of each of the first close connection point and the second close connection point stored in advance in the position information storage means It functions as a failure occurrence position specifying means for specifying the geographical position of the occurrence position.

According to the position specifying method of the present invention, when a failure occurs in the optical line laid by connecting a plurality of single-core or multi-core optical fibers at each connection point from the origin station, the distance information acquisition means The distance information acquisition step of acquiring the optical distance from the origin station to the failure occurrence position where the failure has occurred, and the proximity connection point identification means are provided from the connection points of the optical fiber to the origin station side from the failure occurrence position. Which is closest to or coincides with the fault occurrence position, and is closest to the fault occurrence position on the opposite side of the origin station with the fault occurrence position sandwiched, or Proximity connection point specifying step for specifying each of the matching second proximity connection points, and the failure occurrence position specifying means detects the optical distance from the origin station to the failure occurrence position acquired by the distance information acquiring means and the position in advance. Stored in information storage means And the optical distance from the origin station to each first proximity connection point and the second proximity connection point being,
The geographical position of the fault occurrence position is specified based on the latitude / longitude information for specifying the geographical position of each of the first close connection point and the second close connection point stored in advance in the position information storage means. A fault occurrence position specifying step.

According to the position specifying system and the position specifying method of the present invention, the optical distance from the origin station to the failure occurrence position and the optical fiber which is closest to or coincides with the failure occurrence position from the origin office. Since the optical distances to the first proximity connection point and the second proximity connection point, which are connection points, are used, the relative position of the fault occurrence position with respect to the first proximity connection point and the second proximity connection point. You can understand the relationship. For example,
The optical distance from the origin station to the first proximity connection point is subtracted from the optical distance from the origin station to the fault occurrence position to obtain the optical distance from the origin station to the second proximity connection point to the first proximity connection point. By comparing with the one obtained by subtracting the optical distance, it is possible to grasp where the fault occurrence position is between the first proximity connection point and the second proximity connection point. In this way, if it is possible to grasp where the fault occurrence position is between the first proximity connection point and the second proximity connection point, the design extra length of the optical line from the origin station to the first proximity connection point. The error caused by can be eliminated. Further, since the geographical positions of the first proximity connection point and the second proximity connection point are stored in advance in the position information storage means, the first proximity connection point and the second proximity connection point at the fault occurrence position are compared with each other. If the relative positional relationship can be grasped, the geographical position of the fault occurrence position can be calculated. Also, the same operation is achieved by executing the position specifying program of the present invention using a computer.

Further, in the position specifying system of the present invention, the failure occurrence position specifying means has an optical distance from the starting point station to the failure occurrence position and a first proximity connection from the starting point station previously stored in the position information storing means. The optical distance from the fault occurrence position to the first proximity connection point and the optical distance from the fault occurrence point to the second proximity connection point based on the optical distances to the point and the second proximity connection point, respectively. To calculate the ratio with the distance and specify the calculated optical distance ratio and the geographical position of each of the first proximity connection point and the second proximity connection point stored in advance in the position information storage means. The geographical position of the fault occurrence position may be specified based on the latitude and longitude information of. When the ratio of the optical distance from the fault occurrence position to the first proximity connection point and the optical distance from the fault occurrence position to the second proximity connection point is calculated, the first proximity is calculated according to the calculated ratio. Since the difference between the geographical position of the connection point and the geographical position of the second adjacent connection point can be divided, the geographical position of the failure occurrence position can be calculated.

Further, in the position specifying program of the present invention, the failure occurrence position specifying means sets the optical distance from the starting point station to the failure occurrence position and the first proximity connection from the starting point station stored in the position information storing means in advance. The optical distance from the fault occurrence position to the first proximity connection point and the optical distance from the fault occurrence point to the second proximity connection point based on the optical distances to the point and the second proximity connection point, respectively. To calculate the ratio with the distance and specify the calculated optical distance ratio and the geographical position of each of the first proximity connection point and the second proximity connection point stored in advance in the position information storage means. The geographical position of the fault occurrence position may be specified based on the latitude and longitude information of. When the ratio of the optical distance from the fault occurrence position to the first proximity connection point and the optical distance from the fault occurrence position to the second proximity connection point is calculated, the first proximity is calculated according to the calculated ratio. Since the difference between the geographical position of the connection point and the geographical position of the second adjacent connection point can be divided, the geographical position of the failure occurrence position can be calculated.

Further, in the position specifying method of the present invention, in the failure occurrence position specifying step, the failure occurrence position specifying means sets the optical distance from the starting point station to the failure occurrence position and the starting point station stored in the position information storing means in advance. To the first proximity connection point and the second proximity connection point, respectively, and the optical distance from the failure occurrence position to the first proximity connection point and the failure occurrence point to the second proximity connection point. The ratio of the optical distance to the connection point is calculated, and the calculated ratio of the optical distance and the geography of each of the first proximity connection point and the second proximity connection point stored in advance in the position information storage means. The geographical position of the fault occurrence position may be specified based on the latitude / longitude information for specifying the target position. When the ratio of the optical distance from the fault occurrence position to the first proximity connection point and the optical distance from the fault occurrence position to the second proximity connection point is calculated, the first proximity is calculated according to the calculated ratio. Since the difference between the geographical position of the connection point and the geographical position of the second adjacent connection point can be divided, the geographical position of the failure occurrence position can be calculated.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The findings of the present invention can be easily understood by considering the following detailed description with reference to the accompanying drawings, which are shown for exemplification only. Subsequently, embodiments of the present invention will be described with reference to the accompanying drawings. When possible, the same parts are designated by the same reference numerals, and overlapping description will be omitted.

A position specifying system 10 which is an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a diagram showing a configuration of the position specifying system 10. In the case of this embodiment, the optical fiber 50 and the optical fiber 5 are sequentially arranged from the origin station 20.
1, an example in which the optical fiber 52 and the optical fiber 53 are connected is used. The optical fiber 50 has one end connected to the originating station 20 and the other end at the connection point 40.
It is fusion-spliced with 1. Similarly, the optical fiber 51 is fusion-spliced with the optical fiber 50 at the connection point 40 and the optical fiber 52 at the connection point 41, respectively, and the optical fiber 52 is connected to the optical fiber 51 at the connection point 41.
And the optical fibers 53 are fusion-spliced at the connection points 42.

The origin station 20 is provided with an optical pulse test section 201 and a transmission / reception section 202. Optical pulse test unit 2
01 is OTDR (Optical Time Dom)
ain Reflectometer). The optical pulse test unit 201 receives the optical pulse from one end of the optical fiber 50, reflects the distance distribution of the optical power of the backscattered light reflected at each point in the longitudinal direction of the optical fibers 50 to 53 and returning to the incident end. By analyzing, the loss of the optical fibers 50 to 53, the distance to the connection points 40 to 42 of the optical fibers 50 to 53, the connection loss, and the connection points 40 to 42
The amount of reflection generated in 1 and the distance to the break point when the optical fibers 50 to 53 are broken are measured.

The transmitting / receiving section 202 of the origin station 20 is constructed so as to be able to communicate with the GPS measuring device 30 and the position specifying system 10, respectively. The transmission / reception unit 202 is configured to be able to communicate with the position identification system 10 and the GPS measurement device 30 via a wired communication network or a wireless communication network. The transmission / reception unit 202 receives the measurement instruction signal from the GPS measurement device 30, and outputs the received measurement instruction signal to the optical pulse test unit 201. This measurement instruction signal contains G
The latitude / longitude information for specifying the geographical position such as the latitude and longitude of the current position of the GPS measurement device 30 measured by the PS measurement device 30 may be included. Optical pulse test unit 20
Reference numeral 1 makes an optical pulse incident on the optical fiber 50 as test light based on the measurement instruction signal output from the transmitting / receiving unit 202. The optical pulse test unit 201 detects the backscattered light with respect to the incident test light, measures the optical distance to the connection point by analyzing the distance distribution of the optical power of the backscattered light, and measures the measured optical distance. It is output to the transmitting / receiving unit 202. If the latitude / longitude information is included in the measurement instruction signal, the transmitter / receiver 202 transmits the optical distance to the position identifying system 10 together with the latitude / longitude information.

The GPS measuring device 30 is a device carried by a person who lays an optical fiber, and is a device used to specify a connecting position when the optical fiber is fusion-spliced. The GPS measuring device 30 is physically a CPU
(Central processing unit), memory, input device such as mouse and keyboard, display device such as display, storage device such as hard disk, communication device such as modem, and PHS (Pers)
an online Handyphone System) terminal and a GPS (Global Positioning)
System) and a receiver. Also,
A terminal such as a mobile phone or a wireless LAN may be used instead of the PHS terminal. The GPS measurement device 30 is functionally configured to include a positioning unit 301 and a transmission / reception unit 302.

The positioning section 301 is a section for measuring the latitude and longitude of the current position of the GPS measuring device 30. More specifically, the positioning unit 301 is a unit that calculates the latitude, longitude, altitude, etc. by using radio waves from four GPS satellites arranged in six circular orbits at an altitude of 20,000 kilometers. The positioning unit 301 outputs latitude / longitude information for specifying the measured latitude and longitude to the transmitting / receiving unit 302.

The transmitting / receiving section 302 is a section for transmitting latitude / longitude information for specifying the latitude and longitude of the current position of the GPS measuring device 30 measured by the positioning section 301 to the position specifying system 10. The transmission / reception unit 302 also includes the positioning unit 301.
When the current position is measured by the
The optical pulse test unit 201 of 0 transmits information as a measurement instruction signal to instruct to insert an optical pulse for measuring the optical distance into the optical fiber 50. The measurement instruction signal may include latitude and longitude information.

The position specifying system 10 is physically C
It is configured as a computer system including a PU (Central Processing Unit), a memory, an input device such as a mouse and a keyboard, a display device such as a display, a storage device such as a hard disk, and a communication device such as a modem. The position identifying system 10 is configured to be able to communicate with the origin station 20 and the GPS measuring device 30.

The position measuring system 10 has a functional information element such as a position information acquisition unit (position information acquisition means) 101.
A position information generation unit (position information generation unit) 102, a distance information acquisition unit (distance information acquisition unit) 103, a proximity connection point identification unit (proximity connection point identification unit) 104, and a failure occurrence position identification unit (failure). Occurrence position specifying means) 105 and the display unit 1
06 and a position information storage unit (position information storage means) 109. Subsequently, each component will be described in detail.

The position information acquisition unit 101 includes an optical fiber 50.
This is a part for acquiring the latitude / longitude information for specifying the latitude and longitude of each of the connection points 40 to 42 of No. 53 to No. 53. More specifically, when the optical fibers 50 to 53 are connected, the latitude and longitude information of each of the connection points 40 to 42 measured by the GPS measuring device 30 arranged at each of the connection points 40 to 42 is received and acquired. It is a part. The position information acquisition unit 101 outputs the acquired latitude and longitude information to the position information generation unit 102.

The distance information acquisition unit 103, when connecting and laying the optical fibers 50 to 53 from the origin station 20, lays the optical fiber on the side of the origin station 20 (for example, the optical fiber 5).
When an optical fiber (for example, optical fiber 51) is newly connected to 0), the optical distance between the connection point (for example, connection point 40) connecting this new optical fiber (for example, optical fiber 51) and the origin station 20. Is a portion for receiving and acquiring optical distance information for specifying the information together with latitude / longitude information of the connection point (for example, the connection point 40). The distance information acquisition unit 103 outputs the acquired optical distance information and latitude / longitude information to the position information generation unit 102.

Regarding the method of measuring the optical distance from the origin station 20 to each of the connection points 40 to 42, FIGS.
This will be described with reference to (b) and FIG. 2 (c). Figure 2 (a) shows
It is a figure which made the backscattered light level and optical distance at the time of fusion-splicing the optical fiber 51 to the optical fiber 50 correspond.
According to FIG. 2A, the optical fiber 50 and the optical fiber 51
The backscattered light level drops at the corresponding point 40a corresponding to the connection point 40 with. Before connecting the optical fiber 51, the backscattered light level is presumed to have dropped to 0 at this corresponding point 40a. Therefore, the optical distance L _A corresponding to the corresponding point 40a is the origin point 20
To the connection point 40.

FIG. 2 (b) is a diagram showing the correspondence between the backscattered light level and the optical distance when the optical fiber 52 is fusion-spliced to the optical fiber 51. According to FIG. 2 (b),
Unlike (a), no drop in the backscattered light level is seen at the corresponding point 41a corresponding to the connection point 41 between the optical fibers 51 and 52. This is because the degree of fusion between the optical fibers 51 and 52 at the connection point 41 is good. However, referring to FIG. 2A, before the fusion splicing of the optical fiber 52 to the optical fiber 51, the backscattered light level drops to 0 at the corresponding point 41a. Therefore, if the backscattered light level is measured immediately before the optical fiber 52 is fused, the optical distance to the connection point 41 can be obtained.

FIG. 2C is a diagram in which the backscattered light level and the optical distance when the optical fiber 53 is fusion-spliced to the optical fiber 52 are associated with each other. In this way, the optical fiber 50
When the test light is incident from one end of the optical fiber 50 closest to the origin station 20 after the fusion-splicing of ~ 53, and the backscattered light is measured, the level of the backscattered light drops like the corresponding points 40a and 40c. It can be inferred that the portion where is seen is the connection point, but that portion where no drop in the backscattered light level is seen, such as the corresponding point 40b, should be inferred later that the portion is the connection point. Is difficult, but as described above, each optical fiber 50-53
If the corresponding points 40a to 42a are specified at the time of fusion splicing, the optical distances from the starting point station 20 to the respective connection points 40 to 42 can be grasped more accurately.

The distance information acquisition unit 103 also determines the optical distance from the origin station 20 to the fault occurrence position when the fault occurs such as disconnection in the optical fibers 50 to 53 after being laid. It is acquired as optical distance information for specifying. A method of obtaining the optical distance to the failure occurrence position will be described with reference to FIGS. 3 (a) and 3 (b).
FIG. 3A is a diagram showing the backscattered light level after laying each optical fiber. If no failure occurs in each optical fiber, as shown in FIG. 3A, the backscattered light level is removed except for the local step at the corresponding points 40a and 42a corresponding to the connecting points 40 and 42. Decreases almost linearly. Here, if a failure such as disconnection occurs in the optical fiber 52 between the connection point 41 and the connection point 42, FIG.
As shown in (b), the backscattered light level drops to almost 0 at the corresponding point 60a corresponding to the failure occurrence position 60. Therefore, the optical distance L of the corresponding point 60a is equal to
To the fault occurrence position 60. The distance information acquisition unit 103 outputs the optical distance L to the failure occurrence position 60 received from the origin station 20 to the close connection point identification unit 104 as optical distance information.

The position information generation unit 102 associates the latitude / longitude information output from the position information acquisition unit 101 and the optical distance information output from the distance information acquisition unit 103 to identify each of the connection points 40 to 42. This is a part that is stored in the position information storage unit 109 as connection point position information. More specifically, the latitude / longitude information output from the position information acquisition unit 101 and the optical distance information output together with the same latitude / longitude information are associated with each other, are attached to the connection point ID, and are stored in the position information storage unit 109. To do. For example, if the connection point 40, and the connection point ID "A", and the optical distance L _A m from the origin station 20 as an optical distance information to the connection point 40, the connection point 40 as latitude and longitude information latitude It is stored in the position information storage unit 109 in association with A _LAT and longitude A _LON .

An example of information stored in the position information storage unit 109 is shown in FIG. According to the example shown in FIG. 4, “connection point I
"D", "connection point name", "optical distance", "latitude,"
"Longitude" are stored in association with each other. More specifically, the “connection point ID” and the “latitude, longitude” corresponding to the origin station 20 and the connection points 40 to 42 are stored, and the “optical distance” is measured with the origin station 20 as a reference. The calculated optical distance is stored. Therefore, the origin station 2
The optical distance corresponding to 0 is 0. The information about the origin station 20 is also stored in this way because it is used to specify the failure occurrence position when a failure occurs in the optical fibers 50 to 53, and a method of specifying the failure occurrence position will be described later. To do.

When the optical fibers 50 to 53, which have been laid, have a failure such as a disconnection, the close connection point specifying unit 104 selects a failure from the connection points 40 to 42 of the optical fibers 50 to 53. A first proximity connection point that is closest to or coincides with the failure occurrence position on the side of the origin station 20 with respect to the position, and a failure occurs on the opposite side of the origin station 20 across the failure occurrence position. The second proximity connection point that is closest to or coincides with the position.
For example, when a failure occurs in the optical fiber 52, the connection point 41 is specified as the first close connection point, and the connection point 42 is specified as the second close connection point.

More specifically, the proximity connection point identification unit 104.
Is the origin station 2 stored in the position information storage means 109.
0 and the optical distances of the connection points 40 to 42 and the starting point station 20.
To the fault occurrence position 60, the difference is taken, and the difference is the smallest, the starting point station 20 or the connection points 40 to 4
2 and the second smallest starting point station 20 or connection points 40 to 42
And specify. For example, if the optical fiber 52 has a failure occurrence position 60, the connection point 41 and the connection point 42 are specified.
Then, the connection point 41 closer to the origin station 20 is specified as the first close connection point, and the connection point 42 is specified as the second close connection point.

The fault occurrence position specifying unit 105 detects the fault occurrence position 60 from the origin station 20 acquired by the distance information acquisition unit 103.
To the optical distance information for specifying the optical distance to the origin station 20 previously stored in the position information storage unit 109.
From the first proximity connection point to the second proximity connection point, and the first proximity connection point and the first proximity connection point stored in advance in the position information storage unit 109. Fault occurrence position 6 based on the latitude and longitude information for specifying the latitude and longitude of each of the two close connection points
This is a part that specifies the latitude and longitude of 0.

Assuming that the fault occurrence position 60 is on the optical fiber 52, more specifically, the optical distance L from the origin station 20 to the fault occurrence position 60 and the position information storage unit 1 in advance.
09 and the optical distance L _B from the origin station 20 to the connection point 41 as the first proximity connection point and the origin station 2
The optical distance L-L from the fault occurrence position 60 to the connection point 41 as the first proximity connection point is based on 0 and the optical distance L _C from the second proximity connection point to the connection point 42.
_B and the ratio of the optical length L _C -L from failure position 60 to the connection point 42 of the second proximity connection point (L-L _B)
Calculate / (L _C −L). The calculated optical distance ratio (L−L _B ) / (L _C −L) and the position information storage unit 1 are stored in advance.
Latitude / longitude information (B) for specifying the latitude and longitude of the connection point 41 as the first proximity connection point stored in 09.
_LAT , B _LON ) and a connection point 42 as a second proximity connection point
The latitude and longitude of the fault location 60 are identified based on the latitude and longitude information (C _LAT , C _LON ) for identifying the latitude and longitude of

The display unit 106 includes the origin station 20, the optical fibers 50 to 53, the connection points 40 to 42, and the fault occurrence position 6.
This is a part for displaying information such as 0. FIG. 5 shows an example of information displayed on the display unit 106. As shown in FIG. 5, the display unit 106 overlays the map information of the corresponding area with a display for identifying the position such as the origin station 20, the optical fibers 50 to 53, the connection points 40 to 42, and the failure occurrence position 60. To do.

Next, a method of storing the position specifying information of the connection points 40 to 42 using the position specifying system 10 will be described. FIG. 6 is a flowchart showing a method of storing position specifying information using the position specifying system 10.

First, the person laying the optical fiber brings the GPS measuring device 30 to the planned fusion splicing point of the optical fiber. For example, referring to FIG. 1, when the installation from the starting point station 20 to the optical fiber 52 is completed, the person who installs the optical fiber 53 brings the GPS measurement device 30 to the connection point 42. When the vehicle arrives at the connection point 42, the latitude and longitude of the connection point 42 are acquired using the GPS measuring device 30 (step S01). Specifically, the positioning unit 301 of the GPS measuring device 30 acquires the latitude and longitude of the current position and outputs the latitude and longitude to the transmitting / receiving unit 302.

The transmitting / receiving section 302 of the GPS measuring device 30 is
Latitude / longitude information for specifying the latitude and longitude of the connection point 42 is transmitted to the position identifying system 10 (step S0).
2). Position information acquisition unit 101 of position identification system 10
Receives the latitude and longitude information of the connection point 42 and outputs it to the position information generation unit 102 (step S03).

The transmitting / receiving unit 302 of the GPS measuring device 30 is
The distance measurement request information is transmitted to the origin station 20 (step S
04). The distance measurement request information includes latitude / longitude information for specifying the latitude and longitude acquired in step S01.

The transmitter / receiver 302 of the GPS measuring device 30 transmits
The received distance measurement request information is transmitted / received by the transmitting / receiving unit 20 of the origin station 20.
2 receives. The transmission / reception unit 202 is the optical pulse test unit 201.
To measure the optical distance to the end of the current optical line
To output the instruction information. Optical pulse test unit 201
Causes the test light to enter the optical fiber 50 and
To measure the optical distance to the end of the current optical line.
Set (step S05). For example, as shown in FIG.
If the backscattered light level is measured, the distance L _CThe present
It is measured as the optical distance to the end of the optical line. this
The optical distance measured as
The optical distance is up to 2. The optical pulse test unit 201 is
The transmitting / receiving unit 2 uses the measured optical distance as optical distance information.
Output to 02.

The transmission / reception unit 202 of the origin station 20 associates the optical distance measured by the optical pulse test unit 201 with the latitude / longitude information transmitted from the GPS measuring device 30 and transmits it to the position specifying system (step S06). .

Distance information acquisition unit 1 of position specifying system 10
03 receives the optical distance information and the latitude / longitude information corresponding to it, which are transmitted from the origin station 20, and outputs them to the position information generation unit 102 (step S07).

The position information generation unit 102 includes the latitude and longitude information received by the position information acquisition unit 101 and the distance information acquisition unit 10.
3 collates the received optical distance information and the corresponding latitude / longitude information, and if both latitude / longitude information match,
The latitude / longitude information and the optical distance information are associated and stored in the position information storage unit 109 (step S08). In this way, if the consistency between the latitude / longitude information received by the position information acquisition unit 101 and the optical distance information received by the distance information acquisition unit 103 is confirmed, a new reference number such as a measurement number is not introduced. However, the latitude / longitude information measured by the GPS measurement device 30 and the optical distance measured by the origin station 20 can be acquired in association with each other. In the present embodiment, the GPS measuring device 30 transmits the latitude / longitude information to the origin station 20 and the position identifying system 10, but the GPS measuring device 30
Transmits latitude and longitude information only to the origin station 20,
A simple mode may be adopted in which the latitude / longitude information and the optical distance information are transmitted from the position specifying system 10 to the position specifying system 10. In the case of such a mode, the position information acquisition unit 10
The distance information acquisition unit 103 also plays the role of 1.
On the contrary, the GPS measuring device 30 is used in the position specifying system 10.
The latitude / longitude information may be transmitted only to. Furthermore, rearrangement ID
You may introduce a reference number such as
The optical distance information transmitted after 0 transmits the latitude / longitude information may be associated with the latitude / longitude information.

Next, a method for identifying the fault occurrence position when the fault occurs in the optical fibers 50 to 53 using the position identifying system 10 will be described. FIG. 7 is a flow chart showing a method for identifying a fault occurrence position using the position identifying system 10.

The optical pulse tester 201 of the origin station 20 monitors the respective optical fibers 50 to 53 by periodically injecting the test light into the installed optical fibers 50 to 53. Already in Figure 3
As described with reference to FIGS. 3A and 3B, if no failure occurs in each of the optical fibers 50 to 53, the connection point 40
And the corresponding point 40a and the corresponding point 42 corresponding to the connection point 42
The backscattered light level decreases almost linearly except for the local step at a. Here, when a failure such as a disconnection occurs in the optical fiber 52 between the connection point 41 and the connection point 42, the backscattered light level drops to almost zero at the corresponding point 60a corresponding to the failure occurrence position 60. The optical pulse test unit 201 measures the optical distance L to the point where the backscattered light level has dropped extremely as the optical distance to the fault occurrence position 60, and as the optical distance information, the transmitting / receiving unit 202.
(Step S11).

The transmitting / receiving section 202 of the origin station 20 transmits the optical distance L to the fault occurrence position 60 to the position identifying system 10 as optical distance information (step S12).

Distance information acquisition unit 1 of position specifying system 10
03 receives the optical distance information up to the fault occurrence position 60 and outputs it to the close connection point identifying unit 104 (step S1).
3). In the case of this embodiment, when the distance information acquisition unit 103 receives the latitude / longitude information and the optical distance information from the transmission / reception unit 202 of the origin station 20, the distance information acquisition unit 103 registers the received position information as the position information of each connection point. Position information generation unit 102
When the optical distance information is received from the transmission / reception unit 202, the received information is output to the proximity connection point identification unit 104 as the fault occurrence position is identified.

The close connection point specifying unit 104 determines the optical distance L of the fault occurrence position 60, the starting point station 20 and the connection points 40 to 40.
The difference with the optical distance of 42 is calculated, and the failure occurrence position 60
To the starting point station 20 and each of the connection points 40 to 42 are calculated (step S14). Proximity connection point identification unit 1
04 identifies the connection point closest to the failure occurrence position 60 as a close connection point based on the optical distances from the failure occurrence position 60 to the starting point station 20 and each of the connection points 40 to 42 (step S15). More specifically, the proximity connection point identification unit 10
4 selects first the connection point having the shortest optical distance from the fault occurrence position 60 and the second connection point. The close connection point identification unit 104 selects one of the two selected connection points,
The connection point closer to the origin station 20 is specified as the first proximity connection point, and the connection point farther than the origin station 20 is specified as the second proximity connection point. In the case of this embodiment, the connection point 4
1 is specified as the first close connection point, and the connection point 42 is specified as the second close connection point. Proximity connection point identification unit 1
Reference numeral 04 indicates information on the identified connection point
Output to 05.

The fault occurrence position specifying unit 105 uses the first proximity
Distance from connection point to fault location 60 and second proximity
Calculate the ratio to the distance from the connection point to the fault location 60
(Step S16). In the case of this embodiment, a failure occurs
The position specifying unit 105 is LL _BAnd L_C-Calculate the ratio with L
It The failure occurrence position identification unit 105 uses the calculated ratio as a basis.
Then, the latitude and longitude of the fault occurrence position 60 are specified.
(Step S17). The failure location specifying unit 105
The display 106 displays the latitude and longitude of the determined fault occurrence position 60.
Output to.

The display unit 106 displays the information indicating the position of the fault occurrence position 60 together with the information indicating the positions of the starting point station 20, the optical fibers 50 to 53, and the connection points 40 to 42 (step S18).

Next, the position specifying program 92 for causing the computer to function as the position specifying system 10 of this embodiment and the computer-readable recording medium 9 in which the position specifying program 92 is recorded will be described. FIG. 8 is a diagram showing the configuration of the recording medium 9 in which the position specifying program 92 is recorded. The recording medium 9 is, for example, a magnetic disk, an optical disk, a CD-ROM, a memory built in a computer, or the like.

As shown in FIG. 8, the recording medium 9 has a program area 91 for recording a program and a data area 93 for recording data. In the data area 93, a position information storage database 931 similar to the position information storage unit 109 described with reference to FIG. 1 is stored.

A position specifying program 92 is recorded in the program area 91. Position identification program 92
Is a main module 921 that supervises the processing, a position information acquisition module 922, and a position information generation module 9
23, a distance information acquisition module 924, a proximity connection point identification module 925, a failure occurrence location identification module 926, and a display module 927. here,
Position information acquisition module 922, position information generation module 923, distance information acquisition module 924, proximity connection point identification module 925, failure occurrence position identification module 9
26, the function realized by operating each of the display modules 927 is the same as the position specifying system 10 described above.
The position information acquisition unit 101, the position information generation unit 102, the distance information acquisition unit 103, the proximity connection point identification unit 104, the failure occurrence position identification unit 105, and the display unit 106 have the same functions.

The operation and effect of this embodiment will be described. When the distance information acquisition unit 103 newly connects the optical fiber (for example, the optical fiber 53) to the optical fiber (for example, the optical fiber 52) on the side of the starting point station 20, the connection point (for example, the connecting point 42) and the starting point station 20 Since the optical distance information of is acquired, the optical distance information of each of the connection points 40 to 42 can be acquired more accurately. The position information generation unit 102 acquires the optical distance information of the connection points 40 to 42 acquired by the distance information acquisition unit 103 and the connection points 4 acquired by the position information acquisition unit 101.
Since it is stored in the position information storage unit 109 in association with the latitude and longitude information of 0 to 42, the actual positions of the connection points 40 to 42 can be more accurately grasped.

The optical distance from the origin station 20 to the fault occurrence position 60 and the first proximity connection point which is the connection point of the optical fiber which is closest to or coincides with the fault occurrence position 60 from the origin station 20. Since the optical distance to the (connection point 41) and the second proximity connection point (connection point 42) is used, the first proximity connection point (connection point 41) and the second proximity connection point (connection point 42) It is possible to grasp the relative positional relationship of the failure occurrence position 60 with respect to (1). For example, the optical distance from the origin station 20 to the failure occurrence position 60 is subtracted from the optical distance from the first proximity connection point (connection point 41) to obtain the second proximity connection point (connection point 42) from the origin station 20. ) Is subtracted from the optical distance to the first proximity connection point (connection point 41), the fault occurrence position 60 is determined to be the first proximity connection point (connection point 41) and It is possible to grasp the vicinity of the second proximity connection point (connection point 42).
In this way, if it is possible to know where the fault occurrence position 60 is between the first proximity connection point (connection point 41) and the second proximity connection point (connection point 42), the origin station 20 can determine the first position.
It is possible to eliminate the error caused by the extra design length of the optical line up to the close connection point (connection point 41) of. Further, since the latitude and longitude of the first proximity connection point (connection point 41) and the second proximity connection point (connection point 42) are stored in the position information storage unit 109 in advance, the first occurrence of the failure occurrence position 60 If the relative positional relationship between the close connection point (connection point 41) and the second close connection point (connection point 42) can be grasped, the latitude and longitude of the failure occurrence position 60 can be calculated.

The ratio of the optical distance from the fault occurrence position 60 to the first proximity connection point (connection point 41) and the optical distance from the fault occurrence position to the second proximity connection point (connection point 42) is calculated. Once calculated, the difference between the latitude and longitude of the first close connection point (connection point 41) and the latitude and longitude of the second close connection point (connection point 42) can be divided according to the calculated ratio, so that the obstacle The latitude and longitude of the generation position 60 can be calculated.

[0060]

According to the present invention, the distance information acquisition means is
When the optical fiber is newly connected to the optical fiber on the side of the origin station, the optical distance information between the connection point and the origin station is acquired, so that the optical distance information to each connection point can be more accurately acquired. Since the position information generation means stores the optical distance information of each connection point acquired by the distance information acquisition means and the latitude / longitude information of each connection point acquired by the position information acquisition means in the position information storage means in association with each other, The actual position of the connection point can be grasped more accurately. Therefore, the object of the present invention, the position of the connection point when a plurality of single-core or multi-core optical fibers are connected and laid at each connection point from the origin station, and a failure occurrence when a failure occurs in the optical fiber A position specifying system, a position specifying program, and a position specifying method that specify a position more accurately can be provided.

[Brief description of drawings]

FIG. 1 is a diagram for explaining a position specifying system that is an embodiment of the present invention.

FIG. 2 is a diagram showing an example of a backscattered light level measured by an optical pulse test section in FIG.

FIG. 3 is a diagram showing an example of a backscattered light level measured by an optical pulse test section in FIG.

4 is a diagram showing an example of information stored in a position information storage unit of FIG.

5 is a diagram showing an example of information displayed by the display unit of FIG.

FIG. 6 is a flowchart showing a method for storing position information using the position specifying system according to the embodiment of the present invention.

FIG. 7 is a flowchart showing a method for specifying a position by using the position specifying system which is a portable device for carrying out the present invention.

FIG. 8 is a diagram showing a position specifying program which is an embodiment of the present invention.

[Explanation of symbols]

10 ... Position identification system, 20 ... Origin station, 30 ... GPS
Measuring device, 101 ... Position information acquisition unit, 102 ... Position information generation unit, 103 ... Distance information acquisition unit, 104 ... Proximity connection point identification unit, 105 ... Fault occurrence position identification unit, 106 ... Display unit, 109 ... Position information storage Section, 201 ... optical pulse test section, 202 ... transmission / reception section, 301 ... positioning section, 302 ... transmission / reception section, 40, 41, 42 ... connection section, 50, 51, 52,
53 ... Optical fiber, 60 ... Fault occurrence position.

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 2F103 BA18 CA06 CA07 EB02 EB08                       EB16 EC09                 2G086 CC02                 5J062 AA01 BB08 CC07 FF02 FF05                       HH04 HH05 HH07 HH09                 5K002 EA07 FA01                 5K042 CA10 DA33 EA01 GA11 HA02                       JA07 LA01

Claims (9)

[Claims] 1. When connecting and laying an optical fiber from a starting point station, when newly connecting the optical fiber to the optical fiber on the starting point side, the connection point connecting the new optical fiber and the starting point station Distance information acquisition means for acquiring optical distance information for specifying the optical distance between the connection point, and position information acquisition means for acquiring latitude and longitude information for specifying the geographical position of the connection point, and the latitude and longitude A position specifying system that stores information in the position information storage unit as connection point position information for specifying the position of the connection point by associating the information with the optical distance information. 2. When a failure occurs in an optical line laid by connecting a plurality of single-core or multi-core optical fibers at each connection point from the origin station, the failure occurrence position where the failure occurs from the origin station Distance information acquisition means for acquiring an optical distance to, from each connection point of the optical fiber, is closer to the failure occurrence position on the originating station side than the failure occurrence position or A first proximity connection point and a second proximity connection point on the opposite side of the fault occurrence position from the origin station and closest to or coincident with the fault occurrence position. From the starting point station that is stored in advance in the position information storing section and the optical distance from the starting point station to the fault occurrence position acquired by the distance information acquiring section. Proximity connection point and the Optical distance to each of the two close connection points, and latitude for specifying the geographical position of each of the first close connection point and the second close connection point stored in advance in the position information storage means. A fault occurrence position specifying unit that specifies a geographical position of the trouble occurrence position based on longitude information. 3. The fault occurrence position specifying means is an optical distance from the origin station to the fault occurrence position,
The first proximity from the fault occurrence position is based on the optical distances from the origin station to the first proximity connection point and the second proximity connection point, which are stored in advance in the position information storage means. The ratio of the optical distance to the connection point and the optical distance from the fault occurrence point to the second proximity connection point is calculated, and the calculated optical distance ratio is stored in advance in the position information storage means. The geographical position of the fault occurrence position is specified based on the stored latitude and longitude information for specifying the geographical position of each of the first close connection point and the second close connection point. The position identification system according to 2. 4. A connection point for connecting a new optical fiber when a new optical fiber is connected to the optical fiber on the side of the originating station when the computer is installed by connecting the optical fiber from the originating station. Distance information acquisition means for acquiring optical distance information for specifying the optical distance to the origin station, and position information acquisition means for acquiring latitude and longitude information for specifying the geographical position of the connection point, A position specifying program for functioning as position information generating means for storing in the position information storing means as connection point position information for specifying the position of the connection point by associating the latitude / longitude information and the optical distance information with each other. . 5. When a failure occurs in an optical line laid by connecting a plurality of single-core or multi-core optical fibers at each connection point from a starting station to a computer, the failure occurs from the starting station. Distance information acquisition means for acquiring an optical distance to a failure occurrence position, and among the respective connection points of the optical fiber, which is closer to the failure occurrence position on the originating station side than the failure occurrence position Or a first proximity connection point that is coincident with a second proximity that is on the opposite side of the origin station with the fault occurrence position interposed therebetween and that is closest to or coincides with the fault occurrence position. From the proximity connection point specifying means for specifying the connection point, respectively, and the optical distance from the starting point station acquired by the distance information acquiring means to the fault occurrence position and the starting point station previously stored in the position information storing means. The first neighborhood Optical distance to each of the close connection point and the second close connection point, and the geographical position of each of the first close connection point and the second close connection point stored in advance in the position information storage means. A position specifying program for functioning as a failure occurrence position specifying means for specifying the geographical position of the failure occurrence position based on the latitude and longitude information for specifying. 6. The fault occurrence position specifying means is an optical distance from the origin station to the fault occurrence position,
The first proximity from the fault occurrence position is based on the optical distances from the origin station to the first proximity connection point and the second proximity connection point, which are stored in advance in the position information storage means. The ratio of the optical distance to the connection point and the optical distance from the fault occurrence point to the second proximity connection point is calculated, and the calculated optical distance ratio is stored in advance in the position information storage means. The geographical position of the fault occurrence position is specified based on the stored latitude and longitude information for specifying the geographical position of each of the first close connection point and the second close connection point. The position identification program according to item 5. 7. The distance information acquisition means connects the new optical fiber when the optical fiber is newly connected to the optical fiber on the side of the originating station when the optical fiber is connected from the originating station and installed. A distance information acquisition step of acquiring optical distance information for specifying an optical distance between the connection point and the origin station; and a position information acquisition means, latitude and longitude information for specifying a geographical position of the connection point. And a position information generating unit stores the position information in the position information storage unit as connection point position information for identifying the position of the connection point by associating the latitude and longitude information with the optical distance information. A position specifying method including a position information generating step. 8. When a failure occurs in the optical line laid by connecting a plurality of single-core or multi-core optical fibers at each connection point from the origin station, the distance information acquisition means causes the failure from the origin station. The distance information acquisition step of acquiring the optical distance to the fault occurrence position where the occurrence of the fault occurs, and the proximity connection point identification means is located on the side of the origin station from the fault occurrence position among the connection points of the optical fiber. And a first proximity connection point that is closest to or coincides with the failure occurrence position, and is on the opposite side of the origin station with the failure occurrence position, and is closest to the failure occurrence position. A proximity connection point identifying step for identifying each of the second proximity connection points that match each other, or an optical path from the origin station to the fault occurrence position acquired by the distance information acquisition means, Distance and beforehand The optical distances from the origin station stored in the position information storage means to the first proximity connection point and the second proximity connection point, respectively, and the first distance stored in the position information storage means in advance. A fault occurrence position specifying step of specifying the geographical position of the trouble occurrence position based on the proximity connection point and the latitude and longitude information for specifying the geographical position of each of the second proximity connection points. Identification method. 9. The fault occurrence position specifying means in the trouble occurrence position specifying step, wherein an optical distance from the origin station to the trouble occurrence position is included,
The first proximity from the fault occurrence position is based on the optical distances from the origin station to the first proximity connection point and the second proximity connection point, which are stored in advance in the position information storage means. The ratio of the optical distance to the connection point and the optical distance from the fault occurrence point to the second proximity connection point is calculated, and the calculated optical distance ratio is stored in advance in the position information storage means. The geographical position of the fault occurrence position is specified based on the stored latitude and longitude information for specifying the geographical position of each of the first close connection point and the second close connection point. 8. The position specifying method according to item 8.