阅读说明：本技术 一种光纤温度数据处理监测系统 (Optical fiber temperature data processing and monitoring system ) 是由 张琪 彭雪占 李周鹏 吕毅 李焕超 申莲梅 韩伟 徐广伟 娄雪峰 刘华建 李玉国 于 2019-11-05 设计创作，主要内容包括：本发明提供一种光纤温度数据处理监测系统,包括：光纤监测服务器,在每个通信区域配置光纤通信网络,在每个通信区域的预设位置配置用于监控光纤温度的光纤监控终端；光纤温度传感器检测预设位置的光纤温度,将检测的光纤温度传输给数据处理器；数据处理器通过数据通信模块与光纤监测服务器通信连接,获取光纤监测服务器发送的数据信息以及光纤温度的预设温度范围信息；还将检测的光纤温度传输给光纤监测服务器；监测服务器能够将光纤监控数据进行收集管理,并提供访问接口,还对光纤监控数据进行归集,分析,并通过数据处理储存到数据库中,还通过相应的数据处理方式进行提取处理,供用户使用。(The invention provides an optical fiber temperature data processing and monitoring system, which comprises: the optical fiber monitoring server is used for configuring an optical fiber communication network in each communication area and configuring an optical fiber monitoring terminal for monitoring the temperature of the optical fiber at a preset position in each communication area; the optical fiber temperature sensor detects the optical fiber temperature at a preset position and transmits the detected optical fiber temperature to the data processor; the data processor is in communication connection with the optical fiber monitoring server through the data communication module, and acquires data information sent by the optical fiber monitoring server and preset temperature range information of the optical fiber temperature; the detected optical fiber temperature is transmitted to an optical fiber monitoring server; the monitoring server can collect and manage the optical fiber monitoring data, provide an access interface, collect and analyze the optical fiber monitoring data, process and store the optical fiber monitoring data into a database through data processing, and extract and process the optical fiber monitoring data through a corresponding data processing mode for a user to use.)

1. An optical fiber temperature data processing and monitoring system, comprising: the optical fiber monitoring server is used for configuring an optical fiber communication network in each communication area and configuring an optical fiber monitoring terminal for monitoring the temperature of the optical fiber at a preset position in each communication area;

the optical fiber monitoring terminal includes: the system comprises an optical fiber temperature communication module, an optical fiber temperature signal amplification module, an optical fiber temperature signal modulation module, an optical fiber temperature information filtering module, a signal data processor, an optical fiber temperature sensor and a touch screen;

the optical fiber temperature sensor detects the optical fiber temperature at a preset position, and transmits the detected optical fiber temperature to the data processor after sequentially passing through the optical fiber temperature signal amplification module, the optical fiber temperature signal modulation module and the optical fiber temperature information filtering module; the data processor is connected with the touch screen, displays the current temperature information and acquires a control instruction input by a user;

the data processor is in communication connection with the optical fiber monitoring server through the data communication module, and acquires data information sent by the optical fiber monitoring server and preset temperature range information of the optical fiber temperature; the detected optical fiber temperature is transmitted to an optical fiber monitoring server; and when the temperature of the optical fiber exceeds a preset threshold value, sending an alarm prompt.

2. The fiber optic temperature data processing monitoring system of claim 1,

the optical fiber monitoring server is also used for acquiring data information of the optical fiber monitoring terminals configured at the preset positions of each communication area, wherein the acquired information comprises optical fiber temperature data, optical fiber temperature acquisition time data and acquired area position information;

the system is also used for storing the acquired data into a database, analyzing and processing the data, packaging and analyzing the optical fiber temperature data according to a data frame structure preset by the system, and processing the optical fiber temperature data into an optical fiber temperature data format which is displayed and identified; a handheld terminal of a user accesses a database through an optical fiber monitoring server; acquiring optical fiber data;

the optical fiber monitoring system is also used for presenting a visual and operable interface for a user, the user interacts with the optical fiber monitoring server through the operation interface, and the user interacts with the optical fiber monitoring server through the handheld terminal

The user requests the optical fiber monitoring server for service by entering the user operation interface according to the requirement, and the optical fiber monitoring server feeds optical fiber temperature data back to the user according to the user request.

3. The fiber optic temperature data processing monitoring system of claim 1,

the optical fiber monitoring server is provided with an optical fiber temperature data access operation module;

the optical fiber temperature data access operation module presents an operation Login interface and a verification process to a user through logins, and when the user logs in for the first time, monitoring setting is carried out through an onCreat function, wherein the monitoring setting comprises monitoring optical fiber temperature area setting, optical fiber detection time period, a monitored optical fiber communication area, a user name and a password;

the method is also used for matching the user name and the password when the user logs in the database, and judging by using a displaySetting function;

calling a Setting class operation when the optical fiber monitoring Setting is modified, wherein the Setting class inherits an Activity class;

initializing the optical fiber monitoring setting by calling an onCreat function, inputting an optical fiber monitoring terminal address at a corresponding position by calling a displaySettingInfo function after the setting is finished, and storing the optical fiber monitoring terminal address in a database;

the optical fiber monitoring server provides an entrance and a display interface of an optical fiber monitoring main interface through a NineGridView class.

4. The fiber optic temperature data processing monitoring system of claim 1,

the optical fiber monitoring server is also used for integrating data of optical fiber temperature monitoring in a preset time period, a detection time point and a detection area into a display end for displaying through Pro _ StyleTab;

the system is also used for configuring data of Pro _ todaytab class for monitoring the current optical fiber temperature, the detection time point and the detection area provide query ports, the Pro _ todaytab class inherits the Activity class, the display is also carried out by configuring an optical fiber temperature monitoring list and an optical fiber temperature monitoring graph, when the display end is loaded, a request is sent to the optical fiber monitoring server to obtain the query data, and the Pro _ Dtaotatab class displays the data of the optical fiber temperature monitoring;

the getDateServer () function is also configured while displaying a corresponding list of data for fiber temperature monitoring on a line graph.

5. The fiber optic temperature data processing monitoring system of claim 4,

the optical fiber monitoring server is further used for obtaining an optical fiber monitoring data obtaining instruction input by a user, obtaining the optical fiber monitoring data by sending an http set request, calling a login method according to a storage area code of the optical fiber monitoring data and a production controller, calling the optical fiber monitoring data in a database, enabling the user to access the database through a mobile terminal through a MySqlDataReader, extracting the optical fiber monitoring data, returning the extracted optical fiber monitoring data to a control layer, converting a transmitted optical fiber monitoring data set into Json data according to the optical fiber monitoring data obtaining instruction in the control layer, obtaining the optical fiber monitoring data obtaining instruction in a responseInfo type through a getResponse method through htpResponseAddress, converting the optical fiber monitoring data needing to be accessed currently into a productModel entity through a fromJson method, and converting the Json optical fiber monitoring data into the optical fiber monitoring data in an Xml form at the mobile terminal.

6. The optical fiber temperature data processing and monitoring system according to claim 1 or 2,

the optical fiber monitoring server is also used for carrying out data transmission with the optical fiber monitoring terminal based on different protocols, converting the data into a unified optical fiber monitoring data format according to a data setting mode preset by a system, forming an optical fiber monitoring template by the optical fiber monitoring server according to the converted optical fiber monitoring data format, forming optical fiber monitoring data summarization of each communication area, and judging the maximum value and the minimum value of the optical fiber temperature of each communication area;

the optical fiber monitoring server is configured with optical fiber monitoring data retrieval keywords, configured with optical fiber monitoring data keyword extraction, and analyzed with optical fiber monitoring data keywords, displays optical fiber monitoring terminals corresponding to the optical fiber monitoring data, and supports optical fiber monitoring data retrieval and query.

Technical Field

The invention relates to the technical field of optical communication, in particular to an optical fiber temperature data processing and monitoring system.

Background

The optical fiber temperature sensor is designed by directly or indirectly relating the characteristics of optical fiber light transmission with heat, light energy and the like generated when a technical object generates heat. The optical fiber temperature sensor has a technical standard which cannot be achieved by other temperature sensors because the optical fiber is introduced as a transmission medium or is directly used as a sensing element. The method is often applied to severe working environments, such as high temperature, high pressure, high electromagnetic field and the like. The light emitted by the light source is transmitted to the temperature sensing element through the incident optical fiber, the temperature sensing element transmits the detected temperature signal to the emergent optical fiber in the form of optical wave parameters, the emergent optical fiber transmits the temperature signal to the photoelectric detector, and the optical signal is converted into an electric signal and transmitted to a subsequent monitoring system.

At present, the detection mode mainly adopts a manual mode for detection, namely, a professional carries an instrument to measure the temperature of a joint and the like in a cable, and the operation condition of the cable is analyzed according to the temperature data of the cable, so that the insulation state, the connection reliability and the aging degree of components are observed and measured. The measured data is manually transmitted to a command control center for system processing. The defects of the mode are that the manual investment is large, the detection period is long, and the real-time monitoring cannot be realized. At present, automatic monitoring is mainly carried out through a network, and fault self-checking can be realized. However, because the optical fiber is widely used, there are many areas to be detected and many positions to be detected, and generally many data information are uploaded at the same time point, or time period, and stored in the server. When the optical fiber data management system is used in the later period, the optical fiber data management system needs to be called at any time according to the needs of users, so that in the calling process, the optical fiber data management process is complicated, the data access calling time is long, and the problem of inconvenient system operation is caused when the optical fiber data management system is not in time.

Disclosure of Invention

In order to overcome the above-mentioned deficiencies in the prior art, the present invention provides an optical fiber temperature data processing and monitoring system, comprising: the optical fiber monitoring server is used for configuring an optical fiber communication network in each communication area and configuring an optical fiber monitoring terminal for monitoring the temperature of the optical fiber at a preset position in each communication area;

the optical fiber monitoring terminal includes: the system comprises an optical fiber temperature communication module, an optical fiber temperature signal amplification module, an optical fiber temperature signal modulation module, an optical fiber temperature information filtering module, a signal data processor, an optical fiber temperature sensor and a touch screen;

the optical fiber temperature sensor detects the optical fiber temperature at a preset position, and transmits the detected optical fiber temperature to the data processor after sequentially passing through the optical fiber temperature signal amplification module, the optical fiber temperature signal modulation module and the optical fiber temperature information filtering module; the data processor is connected with the touch screen, displays the current temperature information and acquires a control instruction input by a user;

the data processor is in communication connection with the optical fiber monitoring server through the data communication module, and acquires data information sent by the optical fiber monitoring server and preset temperature range information of the optical fiber temperature; the detected optical fiber temperature is transmitted to an optical fiber monitoring server; and when the temperature of the optical fiber exceeds a preset threshold value, sending an alarm prompt.

Preferably, the optical fiber monitoring server is further configured to acquire data information of the optical fiber monitoring terminal configured at the preset position of each communication area, where the acquired information includes optical fiber temperature data, optical fiber temperature acquisition time data, and acquired area position information;

the system is also used for storing the acquired data into a database, analyzing and processing the data, packaging and analyzing the optical fiber temperature data according to a data frame structure preset by the system, and processing the optical fiber temperature data into an optical fiber temperature data format which is displayed and identified; a handheld terminal of a user accesses a database through an optical fiber monitoring server; acquiring optical fiber data;

the optical fiber monitoring system is also used for presenting a visual and operable interface for a user, the user interacts with the optical fiber monitoring server through the operation interface, and the user interacts with the optical fiber monitoring server through the handheld terminal

The user requests the optical fiber monitoring server for service by entering the user operation interface according to the requirement, and the optical fiber monitoring server feeds optical fiber temperature data back to the user according to the user request.

Preferably, the optical fiber monitoring server is configured with an optical fiber temperature data access operation module;

the optical fiber temperature data access operation module presents an operation Login interface and a verification process to a user through logins, and when the user logs in for the first time, monitoring setting is carried out through an onCreat function, wherein the monitoring setting comprises monitoring optical fiber temperature area setting, optical fiber detection time period, a monitored optical fiber communication area, a user name and a password;

the method is also used for matching the user name and the password when the user logs in the database, and judging by using a displaySetting function;

calling a Setting class operation when the optical fiber monitoring Setting is modified, wherein the Setting class inherits an Activity class;

initializing the optical fiber monitoring setting by calling an onCreat function, inputting an optical fiber monitoring terminal address at a corresponding position by calling a displaySettingInfo function after the setting is finished, and storing the optical fiber monitoring terminal address in a database;

the optical fiber monitoring server provides an entrance and a display interface of an optical fiber monitoring main interface through a NineGridView class.

Preferably, the optical fiber monitoring server is further configured to integrate data of optical fiber temperature monitoring within a preset time period, a detection time point, and a detected region statistic into one display terminal for display through Pro _ style tab class;

the system is also used for configuring data of Pro _ todaytab class for monitoring the current optical fiber temperature, the detection time point and the detection area provide query ports, the Pro _ todaytab class inherits the Activity class, the display is also carried out by configuring an optical fiber temperature monitoring list and an optical fiber temperature monitoring graph, when the display end is loaded, a request is sent to the optical fiber monitoring server to obtain the query data, and the Pro _ Dtaotatab class displays the data of the optical fiber temperature monitoring;

the getDateServer () function is also configured while displaying a corresponding list of data for fiber temperature monitoring on a line graph.

Preferably, the fiber monitoring server is further configured to obtain a fiber monitoring data obtaining instruction input by the user, obtain the fiber monitoring data by sending an http get request, calling a logic method according to the storage region code of the optical fiber monitoring data and a production controller, the optical fiber monitoring data is called in a database, a user accesses the database through a mobile terminal by a MySqlDataReader, extracting the optical fiber monitoring data, returning the extracted optical fiber monitoring data to the control layer, converting the transmitted optical fiber monitoring data set into json data at the control layer according to the optical fiber monitoring data acquisition instruction, an httprescensemessage defines that an optical fiber monitoring data acquisition instruction is obtained in a responseInfo class through a getResult method, the optical fiber monitoring data needing to be accessed currently is converted into a production model entity through a fromJson method, and the Json optical fiber monitoring data is converted into optical fiber monitoring data in an Xml form at the mobile terminal.

Preferably, the optical fiber monitoring server is further configured to perform data transmission with the optical fiber monitoring terminal based on different protocols, convert the data into a unified optical fiber monitoring data format according to a data setting mode preset by the system, form an optical fiber monitoring template with the converted optical fiber monitoring data format, form an optical fiber monitoring data summary of each communication area, and determine an optical fiber temperature maximum value and an optical fiber temperature minimum value of each communication area;

the optical fiber monitoring server is configured with optical fiber monitoring data retrieval keywords, configured with optical fiber monitoring data keyword extraction, and analyzed with optical fiber monitoring data keywords, displays optical fiber monitoring terminals corresponding to the optical fiber monitoring data, and supports optical fiber monitoring data retrieval and query.

According to the technical scheme, the invention has the following advantages:

the optical fiber monitoring server can collect and manage optical fiber monitoring data, provide an access interface, collect and analyze the optical fiber monitoring data, process and store the optical fiber monitoring data into a database through data processing, and extract and process the optical fiber monitoring data through a corresponding data processing mode for users to use. The time of the calling process is short, the optical fiber data is simply and conveniently managed, the display data is clear, and the operation and the use of a user are convenient.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description will be briefly introduced, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

Fig. 1 is a schematic diagram of an optical fiber temperature data processing and monitoring system.

Detailed Description

Those of ordinary skill in the art will appreciate that the elements and algorithm steps of the examples described in connection with the embodiments disclosed herein may be embodied in electronic hardware, computer software, or combinations of both, and that the components and steps of the examples have been described in a functional general in the foregoing description for the purpose of illustrating clearly the interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The block diagrams shown in the figures are functional entities only and do not necessarily correspond to physically separate entities. I.e. the functional entities may be implemented in the form of software, or in one or more hardware modules or integrated circuits, or in different networks and/or processor means and/or data processor means.

The invention provides an optical fiber temperature data processing and monitoring system, as shown in fig. 1, comprising: the optical fiber monitoring server 1 is configured with an optical fiber communication network in each communication area 2, and an optical fiber monitoring terminal 3 for monitoring the temperature of an optical fiber is configured at a preset position of each communication area 2;

the optical fiber monitoring terminal 3 includes: the system comprises an optical fiber temperature communication module, an optical fiber temperature signal amplification module, an optical fiber temperature signal modulation module, an optical fiber temperature information filtering module, a signal data processor, an optical fiber temperature sensor and a touch screen;

the optical fiber temperature sensor detects the optical fiber temperature at a preset position, and transmits the detected optical fiber temperature to the data processor after sequentially passing through the optical fiber temperature signal amplification module, the optical fiber temperature signal modulation module and the optical fiber temperature information filtering module; the data processor is connected with the touch screen, displays the current temperature information and acquires a control instruction input by a user;

the data processor is in communication connection with the optical fiber monitoring server 1 through the data communication module, and acquires data information sent by the optical fiber monitoring server 1 and preset temperature range information of the optical fiber temperature; the detected optical fiber temperature is also transmitted to the optical fiber monitoring server 1; and when the temperature of the optical fiber exceeds a preset threshold value, sending an alarm prompt.

The fiber monitoring terminal 3 may be implemented in hardware, software, firmware or any combination thereof. Various features are described as modules, units or components that may be implemented together in an integrated logic device or separately as discrete but interoperable logic devices or other hardware devices. In some cases, various features of an electronic circuit may be implemented as one or more integrated circuit devices, such as an integrated circuit chip or chipset.

The fiber monitoring terminal 3 may be implemented as a processor or an integrated circuit device, such as an integrated circuit chip or chip set. Alternatively or additionally, if implemented in software or firmware, the techniques may implement a data storage medium readable at least in part by a computer, comprising instructions that when executed cause a processor to perform one or more of the above-described methods. For example, a computer-readable data storage medium may store instructions that are executed, such as by a processor.

The fiber monitoring terminal 3 includes one or more processor implementations such as one or more Digital Signal Processors (DSPs), general purpose microprocessors, Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs), or other equivalent integrated or discrete logic circuitry. Thus, the term "processor," as used herein, may refer to any of the foregoing structure or any other structure more suitable for implementing the techniques described herein. In addition, in some aspects, the functionality described in this disclosure may be provided in software modules and hardware modules.

The optical fiber monitoring server 1 is further configured to acquire data information of the optical fiber monitoring terminals 3 configured at preset positions of each communication area 2, where the acquired information includes optical fiber temperature data, optical fiber temperature acquisition time data and acquired area position information;

the system is also used for storing the acquired data into a database, analyzing and processing the data, packaging and analyzing the optical fiber temperature data according to a data frame structure preset by the system, and processing the optical fiber temperature data into an optical fiber temperature data format which is displayed and identified; a handheld terminal of a user accesses a database through the optical fiber monitoring server 1; acquiring optical fiber data;

and is also used for presenting a visual and operable interface for a user, the user interacts with the optical fiber monitoring server 1 through the operation interface, and the user interacts with the optical fiber monitoring server 1 through the handheld terminal

The user requests the optical fiber monitoring server 1 to service by entering the user operation interface according to the requirement, and the optical fiber monitoring server 1 feeds optical fiber temperature data back to the user according to the user request.

The optical fiber monitoring server 1 is configured with an optical fiber temperature data access operation module; the optical fiber temperature data access operation module presents an operation Login interface and a verification process to a user through logins, and when the user logs in for the first time, monitoring setting is carried out through an onCreat function, wherein the monitoring setting comprises monitoring optical fiber temperature area setting, optical fiber detection time period, monitored optical fiber communication area 2, user name and password;

the method is also used for matching the user name and the password when the user logs in the database, and judging by using a displaySetting function;

calling a Setting class operation when the optical fiber monitoring Setting is modified, wherein the Setting class inherits an Activity class;

initializing the optical fiber monitoring setting by calling an onCreat function, inputting the address of the optical fiber monitoring terminal 3 at a corresponding position by calling a displaySettingInfo function after the setting is finished, and storing the address in a database;

the fiber monitoring server 1 provides an entrance of a fiber monitoring main interface and a display interface through a NineGridView class.

The optical fiber monitoring server 1 is further configured to integrate data of optical fiber temperature monitoring within a preset time period, a detection time point, and a detected region statistic into one display terminal for display through Pro _ style tab class;

the system is also used for configuring data of Pro _ todaytab class for monitoring the current optical fiber temperature, the detection time point and the detection area to provide a query port, the Pro _ todaytab class inherits the Activity class, the display is also carried out by configuring an optical fiber temperature monitoring list and an optical fiber temperature monitoring graph, when the display end is loaded, a request is sent to the optical fiber monitoring server 1 to obtain the query data, and the Pro _ Dtaotatab class displays the data of the optical fiber temperature monitoring;

the getDateServer () function is also configured while displaying a corresponding list of data for fiber temperature monitoring on a line graph.

The optical fiber monitoring server 1 is further configured to obtain an optical fiber monitoring data obtaining instruction input by a user, obtain the optical fiber monitoring data by sending an http set request, call a login method according to a storage area code of the optical fiber monitoring data and a production controller, call the optical fiber monitoring data in a database, enable the user to access the database through a mobile terminal through a MySqlDataReader, extract the optical fiber monitoring data, return the extracted optical fiber monitoring data to a control layer, convert a transmitted optical fiber monitoring data set into Json data in the control layer according to the optical fiber monitoring data obtaining instruction, obtain an optical fiber monitoring data obtaining instruction in a responseInfo class through a getstatement method through htpresponsemessage, convert the optical fiber monitoring data which needs to be accessed currently into a productmodell entity through a fromJson method, and convert the Json optical fiber monitoring data into optical fiber monitoring data in an Xml format at the mobile terminal.

The optical fiber monitoring server 1 is also used for carrying out data transmission with the optical fiber monitoring terminal 3 based on different protocols, converting the data into a unified optical fiber monitoring data format according to a data setting mode preset by a system, forming an optical fiber monitoring template by the optical fiber monitoring server 1 according to the converted optical fiber monitoring data format, forming optical fiber monitoring data summarization of each communication area 2, and judging the highest value and the lowest value of the optical fiber temperature of each communication area 2;

the optical fiber monitoring server 1 is configured with optical fiber monitoring data retrieval keywords, configured with optical fiber monitoring data keyword extraction, optical fiber monitoring data keyword analysis, and displays the optical fiber monitoring terminal 3 corresponding to the optical fiber monitoring data, and supports optical fiber monitoring data retrieval and query.

Program code for carrying out operations for the present disclosure may be written in any combination of one or more programming languages, including an object oriented programming language such as Java, C + + or the like and conventional procedural programming languages, such as the "C" programming language or similar programming languages. The program code may execute entirely on the user's computing device, partly on the user's device, as a stand-alone software package, partly on the user's computing device and partly on a remote computing device, or entirely on the remote computing device or server. In the case of a remote computing device, the remote computing device may be connected to the user computing device through any kind of network, including a Local Area Network (LAN) or a Wide Area Network (WAN), or may be connected to an external computing device (e.g., through the internet using an internet service provider).

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.