阅读说明：本技术 一种基于深度学习的光缆故障定位方法、装置及设备 (Optical cable fault positioning method, device and equipment based on deep learning ) 是由 赵永利 左颖敏 刘冬梅 张书林 丁正阳 王颖 吴海洋 丁士长 吴子辰 于 2020-04-21 设计创作，主要内容包括：本说明书一个或多个实施例提供一种基于深度学习的光缆故障定位方法、装置及设备,包括：获取光缆的待测光纤；利用BOTDR设备,按照待测光纤的走线方向依次采集得到若干待测光纤的布里渊频移信息；将若干布里渊频移信息依次输入预先训练的故障检测模型,得到与若干布里渊频移信息对应的若干识别结果；若识别结果为待测光纤为熔断处,则定位杆塔位置；根据杆塔位置定位识别结果为待测光纤为熔断处的待测光纤。本发明能够自动识别BOTDR设备采集到的光线运行状态信息,减少人力成本,能够对光缆故障进行精确定位,故障检测模型可以识别出多种故障类型并定位故障。(One or more embodiments of the present specification provide an optical cable fault location method, apparatus, and device based on deep learning, including: obtaining an optical fiber to be tested of an optical cable; sequentially acquiring Brillouin frequency shift information of a plurality of optical fibers to be detected according to the routing direction of the optical fibers to be detected by using BOTDR equipment; sequentially inputting the Brillouin frequency shift information into a pre-trained fault detection model to obtain a plurality of recognition results corresponding to the Brillouin frequency shift information; if the identification result is that the optical fiber to be detected is a fused part, positioning the position of the tower; and positioning and identifying the position of the tower according to the result that the optical fiber to be detected is the optical fiber to be detected at the fusing position. The invention can automatically identify the light running state information collected by the BOTDR equipment, reduce the labor cost, accurately position the fault of the optical cable, and identify various fault types and position the fault by the fault detection model.)

1. An optical cable fault positioning method based on deep learning is characterized by comprising the following steps:

obtaining an optical fiber to be tested of an optical cable;

sequentially acquiring Brillouin frequency shift information of a plurality of optical fibers to be detected according to the routing direction of the optical fibers to be detected by using BOTDR equipment;

sequentially inputting the Brillouin frequency shift information into a pre-trained fault detection model to obtain a plurality of identification results corresponding to the Brillouin frequency shift information; the fault detection model is obtained by training based on an optical cable fault detection data set; the cable fault detection dataset includes: brillouin frequency shift information at the fusion joint of the optical fiber, Brillouin frequency shift information at the broken fiber part of the optical fiber and Brillouin frequency shift information when the optical fiber is in a normal running state; the recognition result comprises: the optical fiber to be detected is normal, the optical fiber to be detected is a fusion joint, and the optical fiber to be detected is a fusion joint;

if any one of the identification results is that the optical fiber to be detected is a fusing part, determining Brillouin frequency shift information of the optical fiber to be detected, which is identified as a welding part at the previous position, and Brillouin frequency shift information of the optical fiber to be detected, which is identified as the welding part at the next position, and positioning the optical fiber to be detected at the welding part as a tower position;

and positioning the optical fiber to be detected at the fusing position according to the position of the tower, wherein the identification result is the optical fiber to be detected.

2. The method of claim 1, further comprising:

before the BOTDR equipment is used for collecting operation, testing operation and automatic parameter configuration are carried out;

and adjusting the BOTDR equipment according to the test operation result to optimize the effect of the acquisition operation.

3. The method according to claim 1, wherein the acquiring, by using the BOTDR apparatus, the brillouin frequency shift information of the optical fibers to be tested in sequence according to the routing direction of the optical fibers to be tested comprises:

acquiring the temperature and strain information of each point on the optical fiber to be detected in a distributed manner by using the BOTDR equipment;

and intercepting Brillouin frequency shift information of the optical fiber to be detected in a segmented manner by adopting a sliding window method.

4. The method of claim 3, wherein the sliding window method comprises:

and setting the size of a sliding window to be between one eighth and one quarter of the gear pitch according to the accuracy of fault location, wherein the distance of each movement of the sliding window is between one quarter and one half of the size of the sliding window.

5. The method of claim 1, wherein the fault detection model is trained based on a cable fault detection dataset, comprising:

the cable fault detection dataset includes: training and testing sets;

inputting the training set into a convolutional neural network;

the convolutional neural network judges the running state of the optical fiber according to the training set, calculates the error of an output value, and adjusts the weight of the convolutional neural network through the back propagation of the error;

and after the upper limit of the training times is reached, inputting the test set to adjust the accuracy of the convolutional neural network to obtain the fault detection model.

6. The method according to claim 1, wherein the sequentially inputting the brillouin frequency shift information into a pre-trained fault detection model to obtain recognition results corresponding to the brillouin frequency shift information specifically comprises:

judging whether the Brillouin frequency shift information of the optical fiber to be detected is abnormal or not by using the fault detection model, wherein if the Brillouin frequency shift information of the optical fiber to be detected is not abnormal, the identification result of the optical fiber to be detected is that the optical fiber to be detected is normal; and if the optical fiber is abnormal, further judging whether the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of the optical fiber welding position by using the fault detection model.

7. The method according to claim 6, wherein if the fault detection model determines that the brillouin frequency shift information of the optical fiber under test is abnormal, further determining whether the brillouin frequency shift information of the optical fiber under test is the same as the brillouin frequency shift information of the optical fiber fusion splice by using the fault detection model, specifically comprising:

if the fault detection model judges that the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of the optical fiber fusion joint, the identification result of the optical fiber to be detected is that the optical fiber to be detected is the fusion joint;

and if the fault detection model judges that the Brillouin frequency shift information of the optical fiber to be detected is different from the Brillouin frequency shift information of the optical fiber fusion joint, the identification result of the optical fiber to be detected is that the optical fiber to be detected is the fusion joint.

8. The method of claim 1, further comprising: and obtaining the position information and position interval of the tower and the serial number of the optical fiber to be detected according to the Brillouin frequency shift information of the optical fiber to be detected, wherein the identification result is that the optical fiber to be detected is a fusion joint.

9. An optical cable fault locating device based on deep learning comprises:

the acquisition module is configured to acquire an optical fiber to be tested of the optical cable;

the acquisition module is configured to acquire Brillouin frequency shift information of the optical fibers to be detected in sequence according to the routing direction of the optical fibers to be detected by using BOTDR equipment;

the recognition module is configured to sequentially input the Brillouin frequency shift information into a pre-trained fault detection model to obtain recognition results corresponding to the Brillouin frequency shift information; the fault detection model is obtained by training based on an optical cable fault detection data set; the cable fault detection dataset includes: brillouin frequency shift information at the fusion joint of the optical fiber, Brillouin frequency shift information at the broken fiber part of the optical fiber and Brillouin frequency shift information when the optical fiber is in a normal running state; the recognition result comprises: the optical fiber to be detected is normal, the optical fiber to be detected is a fusion joint, and the optical fiber to be detected is a fusion joint;

a first positioning module configured to determine brillouin frequency shift information of the optical fiber to be tested, which is identified as a fusion splice at a previous position, and brillouin frequency shift information of the optical fiber to be tested, which is identified as the fusion splice at a next position, if any one of the identification results is that the optical fiber to be tested is a fusion splice, and position the optical fiber to be tested at the fusion splice as a tower position;

and the second positioning module is configured to position the optical fiber to be detected, which is the fusing part of the optical fiber to be detected, according to the tower position.

10. An electronic device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, characterized in that the processor implements the method according to any of claims 1 to 8 when executing the program.

Technical Field

One or more embodiments of the present disclosure relate to the field of power grid security technologies, and in particular, to a method, an apparatus, and a device for optical cable fault location based on deep learning.

Background

The optical cable is an infrastructure for power transmission of a power system, detects the optical cable in real time, determines the running state of the optical cable, and is essential for safe and stable running of a power grid. Optical cable fault location is the most key component in optical cable line maintenance work, and optical cable fault finding location modes in the prior art include manual pulling, using back scattering method (OTDR) handheld equipment under the condition of bending an optical fiber, measuring, finding and locating by adopting a radio frequency detection method, measuring by using OTDR handheld equipment under the condition of adopting quick freezing liquid and the like. Secondly, use OTDR handheld device to look for the location fault point, need maintainer to on-the-spot interrupt communication line, insert the handheld OTDR instrument of optic fibre and just can test, not only waste time and energy, very probably cause the optic fibre to damage moreover, cause secondary failure, use liquid nitrogen to assist and look for and also cause the user to object easily. Thirdly, the above method requires that the maintenance personnel have higher OTDR use experience, which puts forward higher requirements on personnel training of the company and objectively causes increase of company operation cost.

Disclosure of Invention

In view of this, one or more embodiments of the present disclosure are to provide a method, an apparatus, and a device for locating an optical cable fault based on deep learning, so as to solve the problems of the prior art, such as high labor cost, large device consumption, time and labor consuming, low precision, secondary fault, and dependence on the working experience of a maintenance worker.

In view of the above, one or more embodiments of the present specification provide a method for locating a fault of an optical cable based on deep learning, including:

obtaining an optical fiber to be tested of an optical cable;

sequentially acquiring Brillouin frequency shift information of a plurality of optical fibers to be detected according to the routing direction of the optical fibers to be detected by using BOTDR equipment;

sequentially inputting the Brillouin frequency shift information into a pre-trained fault detection model to obtain a plurality of identification results corresponding to the Brillouin frequency shift information; the fault detection model is obtained by training based on an optical cable fault detection data set; the cable fault detection dataset includes: brillouin frequency shift information at the fusion joint of the optical fiber, Brillouin frequency shift information at the broken fiber part of the optical fiber and Brillouin frequency shift information when the optical fiber is in a normal running state; the recognition result comprises: the optical fiber to be detected is normal, the optical fiber to be detected is a fusion joint, and the optical fiber to be detected is a fusion joint;

if any one of the identification results is that the optical fiber to be detected is a fusing part, determining Brillouin frequency shift information of the optical fiber to be detected, which is identified as a welding part at the previous position, and Brillouin frequency shift information of the optical fiber to be detected, which is identified as the welding part at the next position, and positioning the optical fiber to be detected at the welding part as a tower position;

and positioning the optical fiber to be detected at the fusing position according to the position of the tower, wherein the identification result is the optical fiber to be detected.

Optionally, the method further includes:

before the BOTDR equipment is used for collecting operation, testing operation and automatic parameter configuration are carried out;

and adjusting the BOTDR equipment according to the test operation result to optimize the effect of the acquisition operation.

Optionally, the acquiring, by using the BOTDR apparatus, brillouin frequency shift information of the optical fibers to be tested according to the routing direction of the optical fibers to be tested in sequence includes:

acquiring the temperature and strain information of each point on the optical fiber to be detected in a distributed manner by using the BOTDR equipment;

and intercepting Brillouin frequency shift information of the optical fiber to be detected in a segmented manner by adopting a sliding window method.

Optionally, the sliding window method includes:

and setting the size of a sliding window to be between one eighth and one quarter of the gear pitch according to the accuracy of fault location, wherein the distance of each movement of the sliding window is between one quarter and one half of the size of the sliding window.

Optionally, the fault detection model is obtained by training based on an optical cable fault detection data set, and includes:

the cable fault detection dataset includes: training and testing sets;

inputting the training set into a convolutional neural network;

the convolutional neural network judges the running state of the optical fiber according to the training set, calculates the error of an output value, and adjusts the weight of the convolutional neural network through the back propagation of the error;

and after the upper limit of the training times is reached, inputting the test set to adjust the accuracy of the convolutional neural network to obtain the fault detection model.

Optionally, the sequentially inputting the brillouin frequency shift information into a pre-trained fault detection model to obtain a plurality of recognition results corresponding to the brillouin frequency shift information specifically includes:

judging whether the Brillouin frequency shift information of the optical fiber to be detected is abnormal or not by using the fault detection model, wherein if the Brillouin frequency shift information of the optical fiber to be detected is not abnormal, the identification result of the optical fiber to be detected is that the optical fiber to be detected is normal; and if the optical fiber is abnormal, further judging whether the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of the optical fiber welding position by using the fault detection model.

Optionally, if the fault detection model determines that the brillouin frequency shift information of the optical fiber to be detected is abnormal, the fault detection model is further used to determine whether the brillouin frequency shift information of the optical fiber to be detected is the same as the brillouin frequency shift information of the optical fiber fusion splice, which specifically includes:

if the fault detection model judges that the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of the optical fiber fusion joint, the identification result of the optical fiber to be detected is that the optical fiber to be detected is the fusion joint;

and if the fault detection model judges that the Brillouin frequency shift information of the optical fiber to be detected is different from the Brillouin frequency shift information of the optical fiber fusion joint, the identification result of the optical fiber to be detected is that the optical fiber to be detected is the fusion joint.

Optionally, the method further includes: and obtaining the position information and position interval of the tower and the serial number of the optical fiber to be detected according to the Brillouin frequency shift information of the optical fiber to be detected, wherein the identification result is that the optical fiber to be detected is a fusion joint.

Based on the same inventive concept, one or more embodiments of the present specification further provide an optical cable fault location apparatus based on deep learning, including:

the acquisition module is configured to acquire an optical fiber to be tested of the optical cable;

the acquisition module is configured to acquire Brillouin frequency shift information of the optical fibers to be detected in sequence according to the routing direction of the optical fibers to be detected by using BOTDR equipment;

the recognition module is configured to sequentially input the Brillouin frequency shift information into a pre-trained fault detection model to obtain recognition results corresponding to the Brillouin frequency shift information; the fault detection model is obtained by training based on an optical cable fault detection data set; the cable fault detection dataset includes: brillouin frequency shift information at the fusion joint of the optical fiber, Brillouin frequency shift information at the broken fiber part of the optical fiber and Brillouin frequency shift information when the optical fiber is in a normal running state; the recognition result comprises: the optical fiber to be detected is normal, the optical fiber to be detected is a fusion joint, and the optical fiber to be detected is a fusion joint;

a first positioning module configured to determine brillouin frequency shift information of the optical fiber to be tested, which is identified as a fusion splice at a previous position, and brillouin frequency shift information of the optical fiber to be tested, which is identified as the fusion splice at a next position, if any one of the identification results is that the optical fiber to be tested is a fusion splice, and position the optical fiber to be tested at the fusion splice as a tower position;

and the second positioning module is configured to position the optical fiber to be detected, which is the fusing part of the optical fiber to be detected, according to the tower position.

Based on the same inventive concept, one or more embodiments of the present specification further provide an electronic device, which includes a memory, a processor, and a computer program stored on the memory and executable on the processor, wherein the processor implements the method as described in any one of the above when executing the program.

As can be seen from the foregoing, according to the optical cable fault location method, apparatus and device based on deep learning provided in one or more embodiments of the present disclosure, fault types can be divided into three types, namely, full-broken optical cables, broken partial bundle tubes and broken partial optical fibers in single-bundle tubes, according to the blocking condition of the optical fibers in a faulty optical cable. Therefore, under the condition that which optical fiber in the optical cable is not determined to be broken, each optical fiber of the optical cable is sequentially obtained to be used as the optical fiber to be detected, the BOTDR equipment is used for collecting Brillouin frequency shift information of the optical fiber to be detected, higher detection precision and longer detection distance can be achieved, the optical fiber in the running state can be directly detected, normal running of a system is not influenced, secondary faults cannot be caused, the state of the equipment can be directly reflected, and the optical fiber detection method is more effective, timely and reliable compared with offline detection of running stopping. By constructing the fault detection model, training the convolutional neural network by using the optical cable fault detection data set and learning the internal rule and the expression level of the sample data by using the deep learning model, the fault detection model can have the analysis and learning capability like a human, so that the detection task does not excessively depend on the working experience of detection personnel, the labor cost and the equipment consumption are reduced, and a detection result with higher precision is obtained. The method comprises the steps of judging whether the Brillouin frequency shift information of an optical fiber to be detected is abnormal or not by utilizing a fault detection model, judging whether the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of an optical fiber fusion joint or not, obtaining a more accurate identification result, judging the detected optical fiber for multiple times, obtaining more detailed and diversified detection results, outputting and classifying more detailed fault types, determining the Brillouin frequency shift information of the optical fiber to be detected, which is identified as the fusion joint at the previous position, and the Brillouin frequency shift information of the optical fiber to be detected, which is identified as the fusion joint at the next position, positioning the optical fiber to be detected at the fusion joint as a tower position according to the routing direction of the optical fiber, and positioning the optical fiber to be detected at the fusion joint according to the.

Drawings

In order to more clearly illustrate one or more embodiments or prior art solutions of the present specification, the drawings that are needed in the description of the embodiments or prior art will be briefly described below, and it is obvious that the drawings in the following description are only one or more embodiments of the present specification, and that other drawings may be obtained by those skilled in the art without inventive effort from these drawings.

FIG. 1 is a schematic flow chart of a method for locating a fault in an optical fiber cable according to one or more embodiments of the present disclosure;

FIG. 2 is a schematic illustration of a sliding window approach in one or more embodiments of the present disclosure;

FIG. 3 is a schematic view of a cable fault in one or more embodiments of the present disclosure;

FIG. 4 is a schematic view of a cable fault location in one or more embodiments of the present disclosure;

FIG. 5 is a schematic view of a cable fault locating device according to one or more embodiments of the present disclosure;

FIG. 6 is a schematic diagram of an electronic device in one or more embodiments of the present disclosure.

Detailed Description

For the purpose of promoting a better understanding of the objects, aspects and advantages of the present disclosure, reference is made to the following detailed description taken in conjunction with the accompanying drawings.

It is to be noted that unless otherwise defined, technical or scientific terms used in one or more embodiments of the present specification should have the ordinary meaning as understood by those of ordinary skill in the art to which this disclosure belongs. The use of "first," "second," and similar terms in one or more embodiments of the specification is not intended to indicate any order, quantity, or importance, but rather is used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

One or more embodiments of the present specification provide a method, an apparatus, and a device for optical cable fault location based on deep learning.

Referring to fig. 1, the inventor finds, through research, that optical cable fault location and detection in the prior art are both implemented based on the OTDR technology, and it is not high enough to detect a fault based on the OTDR technology, and secondly, it is necessary to interrupt off-line measurement of a line during detection, which may affect network operation, and the inventor finds that the detection accuracy of an optical fiber state by using a BOTDR apparatus is higher, a detection distance is longer, and an optical fiber in an operating state can be directly detected, which does not affect normal operation of a system, and can directly reflect the state of the apparatus, and is more effective, timely and reliable than off-line detection of a stopped operation, and learning of a learning sample by using a deep learning model further improves the accuracy of optical cable fault location and detection, reduces labor cost, and improves detection speed. One or more embodiments of the present specification therefore provide a method comprising the steps of:

s101, obtaining the optical fiber to be tested of the optical cable.

In this embodiment, since the fault type includes the following types according to the fiber blocking condition of the faulty optical cable: the optical cable is completely broken, the partial bundle tube is broken, and the partial optical fibers in the single bundle tube are arranged, so that under the condition that which optical fiber in the optical cable is broken is not determined, each optical fiber of the optical cable is sequentially selected as the optical fiber to be detected respectively.

S102, sequentially collecting Brillouin frequency shift information of the optical fibers to be detected according to the routing direction of the optical fibers to be detected by using BOTDR equipment.

In the embodiment, firstly, a BOTDR device is placed in a communication machine room of an optical cable to be tested, a BOTDR power supply is connected, and control software is started; secondly, before the BOTDR equipment is used for collecting operation, testing operation and automatic parameter configuration are carried out; and finally, adjusting the BOTDR equipment according to the result of the test operation to optimize the effect of the acquisition operation. Collecting Brillouin frequency shift information of the optical fiber to be detected by using BOTDR equipment, which specifically comprises the following steps:

connecting an optical fiber to be tested with BOTDR equipment, wherein one end of the optical fiber to be tested is connected to the BOTDR equipment;

the temperature and strain information of each point on the optical fiber to be measured is acquired in a distributed mode by using BOTDR equipment;

and intercepting Brillouin frequency shift information of the optical fiber to be detected in a segmented manner by adopting a sliding window method.

In this embodiment, referring to fig. 2, a sliding window method is used to intercept brillouin frequency shift information of an optical fiber to be measured in a segmented manner according to a routing direction of the optical fiber, and a fault of the optical fiber is located near a tower, where a span between optical fiber towers is 100 meters to 500 meters.

S103, sequentially inputting the Brillouin frequency shift information into a pre-trained fault detection model to obtain a plurality of recognition results corresponding to the Brillouin frequency shift information; the fault detection model is obtained by training based on an optical cable fault detection data set; the cable fault detection dataset includes: brillouin frequency shift information at the fusion joint of the optical fiber, Brillouin frequency shift information at the broken fiber part of the optical fiber and Brillouin frequency shift information when the optical fiber is in a normal running state; the recognition result comprises: the optical fiber to be detected is normal, the optical fiber to be detected is a fusion joint, and the optical fiber to be detected is a fusion joint.

In this embodiment, a fault detection model is constructed, and the fault detection model is obtained based on the training of the optical cable fault detection data set, and specifically includes:

the cable fault detection data set includes: training and testing sets;

inputting the training set into a convolutional neural network;

the convolutional neural network judges the running state of the optical fiber according to the training set, calculates the error of the output value, and adjusts the weight of the convolutional neural network through error back propagation;

and after the upper limit of the training times is reached, inputting a test set to adjust the accuracy of the convolutional neural network to obtain a fault detection model.

In this embodiment, an optical cable fault detection data set needs to be constructed first, as an optional embodiment, a BOTDR apparatus may be used in a communications room to collect brillouin frequency shift information of an optical fiber, and since brillouin frequency shift may be abnormal when the optical fiber is welded, broken, and aged, and an image of brillouin frequency shift at the optical fiber welded may exhibit a step characteristic, brillouin frequency shift information at the optical fiber welded, brillouin frequency shift information at the optical fiber broken, and brillouin frequency shift information when the optical fiber is in a normal operating state are collected, respectively, so as to construct the optical cable fault detection data set. And when the convolutional neural network is trained by using the training set, if the training times are not reached, continuing training until the upper limit of the training times is reached.

In this embodiment, the brillouin frequency shift information of each section of optical fiber to be detected, which is segmented and captured by using a sliding window method, is sequentially input into the fault detection model, the brillouin frequency shift information of each section of optical fiber to be detected is arranged according to the routing direction of the optical fiber, so that the optical fiber to be detected, of which the last identification result is the optical fiber to be detected, is the fusion joint, can be accurately found when the position of the tower is positioned, and the optical fiber to be detected, of which the next identification result is the optical fiber to be detected, of which the optical fiber to be detected is the fusion joint, and the fault detection model performs subsequent fault identification and fault positioning according to the image characteristics in.

In this embodiment, the fault detection model determines whether the brillouin frequency shift information of the optical fiber to be detected is abnormal, if the determination result is not abnormal, it is proved that the operating state of the optical fiber to be detected is normal, the output identification result is that the optical fiber to be detected is normal, the brillouin frequency shift information of the next optical fiber to be detected is input into the fault detection model, and the fault detection model is repeatedly used to determine whether the brillouin frequency shift information of the optical fiber to be detected is abnormal; if the judgment result is abnormal, the fault detection model is further required to be used for judging whether the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of the optical fiber welding position. If the judgment results are different, the identification result output by the fault detection model is that the optical fiber to be detected is a fusing part, as an optional embodiment, the fault detection model can learn different fault types according to different sample sets learned by the fault detection model, and if the judgment results are different, the identification result output by the fault detection model is other fault types, such as fiber breakage, light aging and other fault types; if the judgment results are the same, the optical fiber to be detected is the optical fiber fusion joint, and the identification result output by the fault detection model is that the optical fiber to be detected is the fusion joint.

S104, if any one of the identification results is that the optical fiber to be tested is a fusing part, determining Brillouin frequency shift information of the optical fiber to be tested, which is identified as a welding part at the previous position, and Brillouin frequency shift information of the optical fiber to be tested, which is identified as the welding part at the next position, and positioning the optical fiber to be tested at the welding part as a tower position.

In this embodiment, if the identification result output by the fault detection model indicates that the optical fiber to be detected is a fusion splice, the fault detection model detects the fault, if the fault is to be located, the tower position needs to be located, and the tower section of the optical fiber to be detected where the fault is located is found, because the brillouin frequency shift information of the optical fiber to be detected is input into the fault detection model in the direction of the optical fiber in step S103, the brillouin frequency shift information of the optical fiber to be detected, where the previous position is identified as the fusion splice, and the brillouin frequency shift information of the optical fiber to be detected, where the next position is identified as the fusion splice, can be determined according to the routing direction of the optical fiber, and the optical fiber at the tower position is the fusion splice, so when the optical fiber to be detected, where the previous position is identified as the fusion splice, and the optical fiber to be detected, where two tower positions are located, and the tower positions are located, the tower information, the position interval and the number of the fault optical fiber can be obtained, and the optical fiber at the fault position can be conveniently and specifically positioned in the subsequent steps.

S105, positioning the optical fiber to be detected at the fusing position according to the tower position, wherein the identification result is the optical fiber to be detected.

In this embodiment, after two adjacent tower positions before and after the optical fiber fusing position are obtained, the optical fiber fusing position is preliminarily located between the two adjacent tower positions before and after, and then the optical fiber fusing position is further located according to tower information, a position section, the number of the faulty optical fiber, and brillouin frequency shift information of the optical fiber to be detected identified as the optical fiber to be detected at the fusing position, and the position information of the optical fiber fusing position is recorded, so that a worker can do further fault repairing work according to the position of the optical fiber fusing position.

As an alternative embodiment, referring to fig. 3, the span between towers is 200 meters, and a fiber break fault occurs in the optical cable between tower 2 and tower 3, and the method provided in one or more embodiments of the present specification is used to perform fault location on the optical cable, including:

selecting an optical fiber to be detected of the optical cable, wherein it is unknown which optical fiber of the optical cable has a broken fiber in this embodiment, so that one optical fiber is selected for detection at the first time, and then other optical fibers are detected in sequence, and the number of the current optical fiber to be detected needs to be recorded in each detection;

placing BOTDR equipment in a communication station machine room at any end of an optical cable, and selecting an optical fiber to be tested to be connected with the BOTDR equipment;

collecting Brillouin frequency shift information of an optical fiber to be tested by using BOTDR equipment, and as an optional embodiment, connecting one end of the optical fiber to be tested to the BOTDR equipment by using an RP4000 type distributed Brillouin optical fiber temperature and strain analyzer and a single-ended working mode;

the BOTDR apparatus outputs an image of the brillouin frequency shift information along the optical fiber, and the sliding window is set to one eighth of the span, i.e., an image of the brillouin frequency shift information of a 25-meter length of optical fiber at a time is intercepted. The distance of each time the sliding window moves is one fourth of the length of the sliding window, namely, each time the sliding window horizontally moves along the horizontal axis of the image by 6.25 meters of scales;

inputting the image of each intercepted Brillouin frequency shift information into a pre-trained fault detection model according to the routing direction of the optical fiber;

the fault detection model firstly judges whether the Brillouin frequency shift information of the optical fiber to be detected is abnormal, if the Brillouin frequency shift information is normal, the identification result output by the fault detection model is that the optical fiber to be detected is normal, and the sliding window continues to slide forwards; if the optical fiber to be detected is abnormal, further judging whether the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of the optical fiber welding position, and if the Brillouin frequency shift information of the optical fiber to be detected is the same, judging that the optical fiber to be detected is the welding position through the identification result output by the fault detection model;

if the sliding window moves to the end of the image and no fault is detected, replacing the optical fiber for detection;

if the Brillouin frequency shift information is abnormal and is not an optical fiber fusion splice, the identification result output by the fault detection model is a fault type corresponding to the optical fiber to be detected, then the Brillouin frequency shift information of the optical fiber to be detected, which is identified as the fusion splice at the previous position, and the Brillouin frequency shift information of the optical fiber to be detected, which is identified as the fusion splice at the next position, are determined according to the routing direction of the optical fiber, the optical fiber to be detected at the fusion splice is positioned as a tower position, as an optional embodiment, referring to FIG. 4, a sliding window moves to an abnormal area, an image containing the abnormal area is intercepted and input into the fault detection model, the fault detection model can identify the fault type, the optical fiber to be detected, which is identified as the fusion splice at the previous position, is found according to the routing direction of the optical fiber, the position of the tower 2 is positioned by using the sliding window, the optical fiber routing, and positioning the position of the tower 3 by using the sliding window, positioning the abnormal area between the tower 2 and the tower 3, outputting the specific position between the tower 2 and the tower 3 as the abnormal area according to the position of the sliding window at the moment, and finishing fault positioning.

As can be seen from the foregoing, according to the optical cable fault location method, apparatus and device based on deep learning provided in one or more embodiments of the present disclosure, fault types can be divided into three types, namely, full-broken optical cables, broken partial bundle tubes and broken partial optical fibers in single-bundle tubes, according to the blocking condition of the optical fibers in a faulty optical cable. Therefore, under the condition that which optical fiber in the optical cable is not determined to be broken, each optical fiber of the optical cable is sequentially obtained to be used as the optical fiber to be detected, the BOTDR equipment is used for collecting Brillouin frequency shift information of the optical fiber to be detected, higher detection precision and longer detection distance can be achieved, the optical fiber in the running state can be directly detected, normal running of a system is not influenced, secondary faults cannot be caused, the state of the equipment can be directly reflected, and the optical fiber detection method is more effective, timely and reliable compared with offline detection of running stopping. By constructing the fault detection model, training the convolutional neural network by using the optical cable fault detection data set and learning the internal rule and the expression level of the sample data by using the deep learning model, the fault detection model can have the analysis and learning capability like a human, so that the detection task does not excessively depend on the working experience of detection personnel, the labor cost and the equipment consumption are reduced, and a detection result with higher precision is obtained. The method comprises the steps of judging whether the Brillouin frequency shift information of an optical fiber to be detected is abnormal or not by utilizing a fault detection model, judging whether the Brillouin frequency shift information of the optical fiber to be detected is the same as the Brillouin frequency shift information of an optical fiber fusion joint or not, obtaining a more accurate identification result, judging the detected optical fiber for multiple times, obtaining more detailed and diversified detection results, outputting and classifying more detailed fault types, determining the Brillouin frequency shift information of the optical fiber to be detected, which is identified as the fusion joint at the previous position, and the Brillouin frequency shift information of the optical fiber to be detected, which is identified as the fusion joint at the next position, positioning the optical fiber to be detected at the fusion joint as a tower position according to the routing direction of the optical fiber, and positioning the optical fiber to be detected at the fusion joint according to the.

It should be noted that the method of one or more embodiments of the present disclosure may be performed by a single device, such as a computer or server. The method of the embodiment can also be applied to a distributed scene and completed by the mutual cooperation of a plurality of devices. In such a distributed scenario, one of the devices may perform only one or more steps of the method of one or more embodiments of the present disclosure, and the devices may interact with each other to complete the method.

The foregoing description has been directed to specific embodiments of this disclosure. Other embodiments are within the scope of the following claims. In some cases, the actions or steps recited in the claims may be performed in a different order than in the embodiments and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing may also be possible or may be advantageous.

Based on the same inventive concept, one or more embodiments of the present specification further provide an optical cable fault location apparatus based on deep learning, including: the device comprises an acquisition module, an identification module, a first positioning module and a second positioning module.

Referring to fig. 5, the apparatus includes:

the acquisition module is configured to acquire an optical fiber to be tested of the optical cable;

the acquisition module is configured to acquire Brillouin frequency shift information of the optical fibers to be detected in sequence according to the routing direction of the optical fibers to be detected by using BOTDR equipment;

the recognition module is configured to sequentially input the Brillouin frequency shift information into a pre-trained fault detection model to obtain recognition results corresponding to the Brillouin frequency shift information; the fault detection model is obtained by training based on an optical cable fault detection data set; the cable fault detection dataset includes: brillouin frequency shift information at the fusion joint of the optical fiber, Brillouin frequency shift information at the broken fiber part of the optical fiber and Brillouin frequency shift information when the optical fiber is in a normal running state; the recognition result comprises: the optical fiber to be detected is normal, the optical fiber to be detected is a fusion joint, and the optical fiber to be detected is a fusion joint;

a first positioning module configured to determine brillouin frequency shift information of the optical fiber to be tested, which is identified as a fusion splice at a previous position, and brillouin frequency shift information of the optical fiber to be tested, which is identified as the fusion splice at a next position, if any one of the identification results is that the optical fiber to be tested is a fusion splice, and position the optical fiber to be tested at the fusion splice as a tower position;

and the second positioning module is configured to position the optical fiber to be detected, which is the fusing part of the optical fiber to be detected, according to the tower position.

For convenience of description, the above devices are described as being divided into various modules by functions, and are described separately. Of course, the functionality of the modules may be implemented in the same one or more software and/or hardware implementations in implementing one or more embodiments of the present description.

The apparatus of the foregoing embodiment is used to implement the corresponding method in the foregoing embodiment, and has the beneficial effects of the corresponding method embodiment, which are not described herein again.

Based on the same inventive concept, one or more embodiments of the present specification further provide an electronic device, which includes a memory, a processor, and a computer program stored in the memory and running on the processor, and when the processor executes the program, the method according to any of the above embodiments is implemented.

Fig. 6 is a schematic diagram illustrating a more specific hardware structure of an electronic device according to this embodiment, where the electronic device may include: a processor 601, a memory 602, an input/output interface 603, a communication interface 604, and a bus 605. Wherein the processor 601, the memory 602, the input/output interface 603 and the communication interface 604 are communicatively connected to each other within the device via a bus 605.

The processor 601 may be implemented by a general-purpose CPU (Central Processing Unit), a microprocessor, an Application Specific Integrated Circuit (ASIC), or one or more Integrated circuits, and is configured to execute related programs to implement the technical solutions provided in the embodiments of the present specification.

The Memory 602 may be implemented in the form of a ROM (Read Only Memory), a RAM (Random access Memory), a static storage device, a dynamic storage device, or the like. The memory 602 may store an operating system and other application programs, and when the technical solution provided by the embodiments of the present specification is implemented by software or firmware, the relevant program codes are stored in the memory 602 and called by the processor 601 for execution.

The input/output interface 603 is used for connecting an input/output module to realize information input and output. The i/o module may be configured as a component in a device (not shown) or may be external to the device to provide a corresponding function. The input devices may include a keyboard, a mouse, a touch screen, a microphone, various sensors, etc., and the output devices may include a display, a speaker, a vibrator, an indicator light, etc.

The communication interface 604 is used for connecting a communication module (not shown in the figure) to realize communication interaction between the device and other devices. The communication module can realize communication in a wired mode (such as USB, network cable and the like) and also can realize communication in a wireless mode (such as mobile network, WIFI, Bluetooth and the like).

Bus 605 includes a path that transfers information between the various components of the device, such as processor 601, memory 602, input/output interface 603, and communication interface 604.

It should be noted that although the above-mentioned device only shows the processor 601, the memory 602, the input/output interface 603, the communication interface 604 and the bus 605, in a specific implementation, the device may also include other components necessary for normal operation. In addition, those skilled in the art will appreciate that the above-described apparatus may also include only those components necessary to implement the embodiments of the present description, and not necessarily all of the components shown in the figures.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to intimate that the scope of the disclosure, including the claims, is limited to these examples; within the spirit of the present disclosure, features from the above embodiments or from different embodiments may also be combined, steps may be implemented in any order, and there are many other variations of different aspects of one or more embodiments of the present description as described above, which are not provided in detail for the sake of brevity.

In addition, well-known power/ground connections to Integrated Circuit (IC) chips and other components may or may not be shown in the provided figures, for simplicity of illustration and discussion, and so as not to obscure one or more embodiments of the disclosure. Furthermore, devices may be shown in block diagram form in order to avoid obscuring the understanding of one or more embodiments of the present description, and this also takes into account the fact that specifics with respect to implementation of such block diagram devices are highly dependent upon the platform within which the one or more embodiments of the present description are to be implemented (i.e., specifics should be well within purview of one skilled in the art). Where specific details (e.g., circuits) are set forth in order to describe example embodiments of the disclosure, it should be apparent to one skilled in the art that one or more embodiments of the disclosure can be practiced without, or with variation of, these specific details. Accordingly, the description is to be regarded as illustrative instead of restrictive.

While the present disclosure has been described in conjunction with specific embodiments thereof, many alternatives, modifications, and variations of these embodiments will be apparent to those of ordinary skill in the art in light of the foregoing description. For example, other memory architectures (e.g., dynamic ram (dram)) may use the discussed embodiments.

It is intended that the one or more embodiments of the present specification embrace all such alternatives, modifications and variations as fall within the broad scope of the appended claims. Therefore, any omissions, modifications, substitutions, improvements, and the like that may be made without departing from the spirit and principles of one or more embodiments of the present disclosure are intended to be included within the scope of the present disclosure.