CN116736407A

CN116736407A - Earthquake emergency detection adjustment method and system

Info

Publication number: CN116736407A
Application number: CN202310564245.6A
Authority: CN
Inventors: 曾旻; 杨港; 李松柏; 伍良燕; 杨浩翔
Original assignee: Chengdu Meihuan Technology Co ltd; Jiangchuan Jinsha Hydropower Development Co ltd
Current assignee: Chengdu Meihuan Technology Co ltd; Jiangchuan Jinsha Hydropower Development Co ltd
Priority date: 2023-05-18
Filing date: 2023-05-18
Publication date: 2023-09-12

Abstract

The application relates to an earthquake emergency detection adjustment method and system, which belong to the technical field of communication equipment detection, wherein the detection adjustment method comprises the following steps: receiving earthquake early warning information; the earthquake early warning information comprises earthquake intensity grades; acquiring preset anti-seismic grades of communication equipment in each building in the hydropower station; judging whether the earthquake intensity level exceeds the preset earthquake resistance level of the communication equipment in each building or not respectively, and if so, adjusting the detection frequency of the communication equipment in the building to a corresponding preset detection frequency peak value; if not, calculating a grade ratio according to the seismic intensity grade and a preset earthquake-resistant grade threshold, obtaining a detection frequency value to be adjusted according to the grade ratio and the preset detection frequency peak value, and adjusting the detection frequency of the communication equipment in the building according to the detection frequency value to be adjusted. The application can simultaneously meet the detection requirements of communication equipment in different buildings when facing different earthquake magnitudes.

Description

Earthquake emergency detection adjustment method and system

Technical Field

The application relates to the technical field of communication equipment detection, in particular to a method and a system for adjusting earthquake emergency detection.

Background

Earthquake is a natural phenomenon of earthquake waves generated during vibration caused by the process of rapidly releasing energy from the crust. The mutual extrusion collision between the earth upper plate and the plate causes the dislocation and cracking of the edge of the plate and the inside of the plate, which is the main cause of the earthquake.

Hydropower stations are taken as indispensable infrastructure for life and production of people in modern society, so that the earthquake emergency early warning system is often required to be built according to the conditions of environmental conditions, earthquake dangers, earthquake early warning characteristics, engineering earthquake early warning requirements and the like of the hydropower stations in order to fully exert the scientific disaster reduction effect, improve the earthquake prevention and disaster reduction capability of the hydropower stations and furthest reduce casualties and property losses caused by earthquakes. In the earthquake early warning process, the normal operation of the communication equipment is an important link, and in the hydropower station, each building is provided with corresponding communication equipment to meet the communication requirements in the hydropower station, wherein the communication equipment is more complete and stable for the building with higher importance level, and the earthquake resistance is stronger.

At present, because the earthquake can seriously damage the communication equipment in the hydropower station, the early warning notification of the early warning system and the timely response of partial personnel are affected, the working state of the communication equipment in each building needs to be detected through the detection system and timely maintained when abnormal conditions occur, so that the timely transmission of the early warning signals and the normal operation of business communication are ensured.

With respect to the related art in the above, the inventors found that: in the process of detecting the communication devices in each building, the configured detection frequency is usually a fixed frequency, but because the earthquake resistance of the communication devices in different buildings is different, and the possibility of damaging the communication devices caused by different earthquake levels is also different when an earthquake occurs, the common detection system cannot meet the detection requirements of the communication devices in different buildings at the same time when facing different earthquake levels, so that the situation that the communication state information is not obtained timely due to the fact that the detection frequency of the communication devices in part of the buildings is set to be low, or the situation that the communication device detection frequency in part of the buildings is set to be high, and the cost is high and resources are wasted may occur.

Disclosure of Invention

In order to simultaneously meet the detection requirements of communication equipment in different buildings when facing different earthquake magnitudes, the application provides an earthquake emergency detection adjustment method and system.

In a first aspect, the application provides a method for adjusting earthquake emergency detection, which adopts the following technical scheme:

a method of seismic emergency detection adjustment, the detection adjustment method comprising:

receiving earthquake early warning information; the earthquake early warning information comprises earthquake intensity grades;

acquiring preset anti-seismic grades of communication equipment in each building in the hydropower station;

judging whether the earthquake intensity level exceeds the preset earthquake resistance level of the communication equipment in each building or not respectively, and if so, adjusting the detection frequency of the communication equipment in the building to a corresponding preset detection frequency peak value;

if not, calculating a grade ratio according to the seismic intensity grade and a preset earthquake-resistant grade threshold, obtaining a detection frequency value to be adjusted according to the grade ratio and the preset detection frequency peak value, and adjusting the detection frequency of the communication equipment in the building according to the detection frequency value to be adjusted.

By adopting the technical scheme, the actual conditions such as historical earthquake data in each building, damage conditions of communication equipment and the like are combined, the preset earthquake resistant level corresponding to the communication equipment in each building is estimated and determined in advance, after earthquake early warning information sent by an earthquake bureau or an earthquake early warning center is received, if the earthquake intensity level exceeds the preset earthquake resistant level of the communication equipment in a certain building, the detection frequency of the communication equipment in the building is adjusted to a preset detection frequency peak value, and the communication equipment in the building is detected and maintained in time, so that the communication equipment in the building can respond to and cope with sudden events in time; if the earthquake intensity level does not exceed the preset earthquake-resistant level of the communication equipment in a certain building, calculating a level ratio according to the earthquake intensity level and a preset earthquake-resistant level threshold value, and obtaining a to-be-adjusted detection frequency value according to a preset detection frequency peak value by referring to the level ratio so as to adjust the detection frequency of the communication equipment in the building, thereby meeting the detection requirements of the communication equipment in different buildings when facing different earthquake levels, ensuring that early warning signals in part of the buildings can be transmitted in time, and reducing the condition that the resource waste is caused by too frequent detection frequency of the communication equipment in part of the buildings.

Optionally, the step of obtaining the preset detection frequency peak value includes:

determining the building importance level of the building according to the building information of the building;

and determining a corresponding preset detection frequency peak value according to the building importance level of the building based on a first preset mapping table.

By adopting the technical scheme, corresponding preset detection frequency peaks are required to be flexibly set and adjusted according to actual conditions and requirements for communication equipment in different buildings in the hydropower station, and for the buildings with higher building importance levels, higher preset detection frequency peaks can be set so as to ensure that the communication equipment in the buildings can respond and cope with emergencies in time; and for the buildings with low building importance level, the configured preset detection frequency peak value can be properly reduced so as to reduce the working cost and burden.

acquiring the equipment type of each communication equipment in the building, and determining the equipment importance level corresponding to each communication equipment according to the equipment type;

based on a preset calculation formula, calculating and obtaining a comprehensive importance score corresponding to communication equipment according to the building importance level of the building and the equipment importance level corresponding to the communication equipment in the building;

and determining a corresponding scoring interval according to the comprehensive importance scores corresponding to the communication equipment based on a second preset mapping table, and determining a preset detection frequency peak value corresponding to the communication equipment according to the scoring interval.

By adopting the technical scheme, the importance levels corresponding to the communication devices of different types are usually different in the same building, so that when the communication devices of different importance levels exist in the same building, the comprehensive importance score of each communication device can be calculated according to a preset calculation formula, a plurality of scoring intervals are preset, proper preset detection frequency peaks are distributed for each interval, a second preset mapping table is obtained, the corresponding preset detection frequency peaks are matched for each communication device according to the second preset mapping table, and the corresponding preset detection frequency peaks are obtained according to the building importance levels of different buildings and the equipment importance levels of different communication devices, so that the detection requirements of the communication devices of different importance levels in each building can be met at the same time.

Optionally, the detection adjustment method further includes:

detecting whether the communication equipment in each building has abnormal detection conditions;

if yes, acquiring comprehensive importance scores corresponding to the communication equipment with abnormal detection and sequencing to obtain maintenance priority sequencing;

respectively acquiring current position information of each overhaul terminal;

and according to the current position information of each overhaul terminal, sequentially sending overhaul prompt information to the overhaul terminal closest to the communication equipment for detecting the abnormality based on the overhaul priority order.

By adopting the technical scheme, when a plurality of communication devices are abnormal, the overhaul priority ranking is carried out according to the comprehensive importance scores of the communication devices with abnormal detection, the position of each overhaul terminal can be known by acquiring the position information of each overhaul terminal, the overhaul terminal closest to the communication device is determined, and then the overhaul prompt information is sequentially sent to the overhaul terminal closest to the communication device with abnormal detection according to the overhaul priority ranking.

Optionally, the step of obtaining the detection frequency value to be adjusted according to the level ratio and the preset detection frequency peak value includes:

based on a third preset mapping table, determining a corresponding grade ratio interval according to the grade ratio, and determining a corresponding preset detection frequency adjustment ratio according to the grade ratio interval;

and calculating to obtain a detection frequency value to be adjusted according to the preset detection frequency adjustment proportion and the preset detection frequency peak value.

Through adopting above-mentioned technical scheme, set up a plurality of level ratio intervals in advance and for every interval distribution suitable detection frequency adjustment proportion of predetermining, obtain the third and predetermine mapping table, again according to predetermine detection frequency adjustment proportion and predetermine detection frequency peak value, calculate and obtain and wait to adjust the detection frequency value and adjust the detection frequency, reduced the too frequent condition of detection frequency adjustment to can satisfy the detection demand better.

Optionally, the step of adjusting the detection frequency of the communication device in the building according to the detection frequency value to be adjusted includes:

and adjusting the detection frequency of the communication equipment in the building to the detection frequency value to be adjusted.

Optionally, the detecting the communication device in the building includes any one or more of signal strength detection, signal-to-noise ratio detection, fault detection, anti-interference capability detection and network call detection.

By adopting the technical scheme, the working condition of the communication equipment is detected by utilizing a plurality of detection methods singly or in combination, so that the communication fault can be found in time, the reliability and stability of a communication system are improved, and the timely transmission of early warning signals and the normal operation of business communication can be ensured.

In a second aspect, the application provides an earthquake emergency detection adjustment system, which adopts the following technical scheme:

a seismic emergency detection adjustment system, the detection adjustment system comprising:

the receiving module is used for receiving earthquake early warning information; the earthquake early warning information comprises earthquake intensity grades;

the acquisition module is used for acquiring preset anti-seismic grades of communication equipment in each building in the hydropower station;

the judging module is used for judging whether the earthquake intensity level exceeds the preset earthquake resistance level of the communication equipment in each building or not respectively, and if so, outputting a first judging result; if not, outputting a second judgment result;

the detection frequency adjusting module is used for responding to the first judging result and adjusting the detection frequency of the communication equipment in the building to a preset detection frequency peak value corresponding to the building;

the calculating module is used for responding to a second judging result, calculating a grade ratio according to the seismic intensity grade and a preset seismic grade threshold value, and obtaining a to-be-adjusted detection frequency value according to a preset detection frequency peak value corresponding to the building by the grade ratio;

the detection frequency adjusting module is further used for adjusting the detection frequency of the communication equipment in the building according to the detection frequency value to be adjusted.

In a third aspect, the present application provides a computer device, which adopts the following technical scheme:

a computer device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the method of the first aspect when executing the program.

In a fourth aspect, the present application provides a computer readable storage medium, which adopts the following technical scheme:

a computer readable storage medium storing a computer program capable of being loaded by a processor and executing any one of the methods of the first aspect.

In summary, the present application includes at least one of the following beneficial technical effects: when facing different jolt levels, can satisfy the detection demand to the communication equipment in the different buildings simultaneously to ensure that the early warning signal in the partial building can in time communicate, also reduced the condition that the communication equipment's in the partial building detection frequency too frequently leads to the wasting of resources simultaneously.

Drawings

FIG. 1 is a schematic flow chart of a seismic emergency detection adjustment method according to an embodiment of the application.

FIG. 2 is a second flow chart of a seismic emergency detection adjustment method according to an embodiment of the application.

FIG. 3 is a schematic view of a third flow chart of a seismic emergency detection adjustment method according to an embodiment of the application.

Fig. 4 is a fourth flowchart of a seismic emergency detection adjustment method according to an embodiment of the application.

Fig. 5 is a schematic diagram of a fifth flow chart of a seismic emergency detection adjustment method according to an embodiment of the application.

FIG. 6 is a block diagram of a seismic emergency detection adjustment system according to one embodiment of the application.

FIG. 7 is a block diagram of a seismic emergency detection adjustment system according to another embodiment of the application.

Reference numerals illustrate: 101. a receiving module; 102. an acquisition module; 103. a judging module; 104. a detection frequency adjustment module; 105. a computing module; 201. a detection module; 202. a comprehensive importance degree scoring calculation module; 203. a maintenance priority ordering module; 204. the current position information acquisition module; 205. and the overhaul prompt information sending module.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to the accompanying drawings 1 to 7 and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

The embodiment of the application discloses a seismic emergency detection adjustment method.

Referring to fig. 1, a method for adjusting an earthquake emergency detection includes:

step S101, receiving earthquake early warning information;

when an earthquake with the intensity above the preset earthquake intensity threshold value occurs, receiving earthquake early warning information sent by an earthquake bureau or an earthquake early warning center, wherein the earthquake early warning information comprises earthquake intensity levels;

step S102, obtaining preset anti-seismic grades of communication equipment in each building in a hydropower station;

wherein the specific type of communication equipment within each building may vary depending on the size, structure and function of the individual buildings of the hydroelectric power plant; in addition, communication devices within a building may include telephones, walkie-talkies, radio systems, data network systems, radio measurement and navigation systems, satellite communication devices, and the like, to which embodiments of the present application are not limited;

it will be appreciated that the preset level of earthquake resistance of the communication devices within the respective buildings requires a combination of factors such as: the building structure, the installation condition of communication equipment, the geological condition of the area where the building is located, historical earthquake and other factors; specifically, the preset earthquake-resistant level can be evaluated and determined by combining actual conditions such as historical earthquake data in the building and damage conditions of communication equipment;

generally, because the building in which the communication device is located is the first protection of the communication device, the earthquake resistance of the building is also a big standard for measuring the preset earthquake resistance level of the communication device, and the higher the earthquake resistance of the building is, the smaller the influence on the communication device in the building is, namely the smaller the possibility of damaging the communication device is; correspondingly, for some buildings with higher importance level, the design of the earthquake resistance of the building is higher than that of other buildings, and the configured communication equipment is required to be more perfect and stable; thus, it can be appreciated that for buildings of higher importance, the preset level of earthquake resistance of the communication device is generally relatively higher to ensure that normal communication is still ensured when an earthquake occurs;

step S103, judging whether the earthquake intensity level exceeds the preset earthquake resistance level of communication equipment in each building or not respectively, if so, jumping to step S104; if not, jumping to step S105;

step S104, the detection frequency of the communication equipment in the building is adjusted to a corresponding preset detection frequency peak value;

step S105, calculating a grade ratio according to the seismic intensity grade and a preset earthquake-resistant grade threshold value, obtaining a detection frequency value to be adjusted according to the grade ratio and a preset detection frequency peak value, and adjusting the detection frequency of communication equipment in the building according to the detection frequency value to be adjusted.

The grade ratio is the ratio of the seismic intensity grade to a preset earthquake-resistant grade threshold value, the grade ratio is used as a reference ratio, and the grade ratio and a preset detection frequency peak value are calculated to obtain the detection frequency value to be adjusted.

In the above embodiment, in combination with actual situations such as historical seismic data in each building and damage situations of communication equipment, preset earthquake resistant grades corresponding to the communication equipment in each building are estimated and determined in advance, after receiving earthquake early warning information sent by an earthquake bureau or an earthquake early warning center, if the earthquake intensity grade exceeds the preset earthquake resistant grade of the communication equipment in a certain building, the detection frequency of the communication equipment in the building is adjusted to a preset detection frequency peak value, and detection maintenance is performed on the communication equipment in the building in time, so that the communication equipment in the building can respond and cope with sudden events in time; if the earthquake intensity level does not exceed the preset earthquake-resistant level of the communication equipment in a certain building, calculating a level ratio according to the earthquake intensity level and a preset earthquake-resistant level threshold value, and obtaining a to-be-adjusted detection frequency value according to a preset detection frequency peak value by referring to the level ratio so as to adjust the detection frequency of the communication equipment in the building, thereby meeting the detection requirements of the communication equipment in different buildings when facing different earthquake levels, ensuring that early warning signals in part of the buildings can be transmitted in time, and reducing the condition that the resource waste is caused by too frequent detection frequency of the communication equipment in part of the buildings.

As an embodiment of step S105, the step of adjusting the detection frequency of the communication device in the building according to the detection frequency value to be adjusted is: and adjusting the detection frequency of the communication equipment in the building to be the detection frequency value to be adjusted.

As one implementation mode of the earthquake emergency detection adjustment method, the detection of the communication equipment in the building comprises any one or more of signal strength detection, signal-to-noise ratio detection, fault detection, anti-interference capability detection and network call detection.

The signal intensity detection is to measure the intensity of the signal through a signal intensity meter; signal-to-noise ratio detection, namely measuring the proportion of signals to noise; fault detection, i.e. detecting a fault of the communication device by means of a fault detection tool, e.g. using a spectrum analyzer to detect antenna faults, line faults, amplifier faults, etc.; the anti-interference capability detection is to simulate communication channels under different conditions, such as electromagnetic interference, multi-channel signal concurrency and the like, so as to detect the anti-interference capability of a communication system; network call detection is to test whether the communication network is working properly by testing the call, and to test the response time and response quality of the network with audio or data calls.

In the embodiment, the working condition of the communication equipment is detected by utilizing a plurality of detection methods singly or in combination, so that the communication fault can be found in time, the reliability and the stability of a communication system are improved, and the timely transmission of an early warning signal and the normal operation of service communication can be ensured.

Referring to fig. 2, as an embodiment of step S104, the step of obtaining the preset detection frequency peak includes:

step S201, determining the building importance level of the building according to the building information of the building;

the corresponding importance levels can be preset according to the importance levels of the buildings, the higher the importance levels of the buildings are, the more critical areas or the buildings with higher safety warning risks are indicated, and the lower the importance levels of the buildings are, the more general areas or the buildings with lower safety warning risks are indicated;

step S202, based on a first preset mapping table, corresponding preset detection frequency peaks are determined according to building importance levels of the building.

The first preset mapping table is pre-stored with preset detection frequency peaks corresponding to the building importance levels, and the higher the building importance level is, the higher the corresponding preset detection frequency peak is; in addition, the preset detection frequency peak value corresponding to each building importance level can be preset according to actual conditions, and therefore the timeliness of detection is guaranteed.

In the above embodiment, for the communication devices in different buildings in the hydropower station, the corresponding preset detection frequency peak value needs to be flexibly set and adjusted according to the actual situation and the needs, and for the building with higher building importance level, the higher preset detection frequency peak value can be set, so as to ensure that the communication devices in the building can respond and cope with the emergency in time; and for the buildings with low building importance level, the configured preset detection frequency peak value can be properly reduced so as to reduce the working cost and burden.

Referring to fig. 3, as another embodiment of step S104, the step of obtaining the preset detection frequency peak includes:

step S301, determining the building importance level of a building according to the building information of the building;

step S302, obtaining equipment types of all communication equipment in a building, and determining equipment importance levels corresponding to the communication equipment according to the equipment types;

among them, device types of higher importance such as wireless communication devices for information exchange with the outside, power carrier communication devices, and the like, device types of medium importance such as IP telephone systems providing communication of voice, video, and the like, and network communication devices such as switches, routers, and the like for connecting internal devices and external communication networks, and the like, and device types of lower importance such as facsimile machines and the like for internal file transfer; it should be noted that, the importance level of each equipment type may be preset according to the actual situation, and the embodiment of the present application is not limited;

step S303, calculating and obtaining a comprehensive importance grade corresponding to the communication equipment according to the building importance grade of the building and the equipment importance grade corresponding to the communication equipment in the building based on a preset calculation formula;

the preset calculation formula is as follows: building preset weight and equipment preset weight, wherein the building preset weight and the equipment preset weight are used for balancing the importance degree relation between the building importance level and the equipment importance level, and can be preset and adjusted according to actual conditions; for example, the building preset weight may be set to 0.6 and the equipment preset weight to 0.4, so that the importance of the building importance level of the building is higher;

step S304, based on the second preset mapping table, corresponding scoring intervals are determined according to the comprehensive importance scores corresponding to the communication equipment, and preset detection frequency peaks corresponding to the communication equipment are determined according to the scoring intervals.

The second preset mapping table comprises a plurality of groups of corresponding relation between scoring intervals and preset detection frequency peaks, and each scoring interval corresponds to one preset detection frequency peak; in addition, the preset detection frequency peak value corresponding to the selected scoring interval may be an optimal detection frequency peak value capable of achieving the expected effect after being optimized and adjusted according to the actual situation, and it is understood that the higher the comprehensive importance scoring interval is, the larger the corresponding preset frequency peak value is.

It should be noted that, each scoring section has no intersection, and the opening and closing of the end points, the section length and the section number of each section can be preset and adjusted according to the actual situation.

In the above embodiment, the importance levels corresponding to the different types of communication devices are generally different in the same building, so when a plurality of communication devices with different importance levels exist in the same building, the comprehensive importance score of each communication device can be calculated according to a preset calculation formula, then a plurality of scoring intervals are preset, an appropriate preset detection frequency peak value is allocated to each interval, a second preset mapping table is obtained, and the corresponding preset detection frequency peak value is matched for each communication device according to the second preset mapping table, thereby integrating the building importance levels of different buildings and the device importance levels of different communication devices to obtain the corresponding preset detection frequency peak value so as to simultaneously meet the detection requirements of the communication devices with different importance levels in each building.

Referring to fig. 4, as a further embodiment of the seismic emergency detection adjustment method, the detection adjustment method further includes:

step S401, detecting whether the communication equipment in each building has abnormal detection conditions; if yes, go to step S402; if not, determining that the communication equipment in the current building does not have abnormal detection conditions, and re-executing the step S401 on the communication equipment in the next building;

step S402, obtaining comprehensive importance scores corresponding to communication equipment for detecting abnormality and sequencing the comprehensive importance scores to obtain maintenance priority sequencing;

the higher the comprehensive importance score of the communication equipment is, the higher the corresponding overhaul priority is, namely the higher the overhaul priority is ordered;

step S403, current position information of each overhaul terminal is respectively obtained;

in the process of equipment maintenance of a hydropower station, a plurality of overhaul maintenance personnel are usually arranged, and each overhaul maintenance personnel is provided with a corresponding overhaul terminal; in addition, the overhaul terminal can be an intelligent mobile terminal of overhaul maintainers, such as a mobile phone, a tablet personal computer and the like;

step S404, according to the current position information of each maintenance terminal, the maintenance prompt information is sequentially sent to the maintenance terminal closest to the communication equipment for detecting the abnormality based on the maintenance priority order.

The distance between each overhaul terminal and the communication equipment is compared, so that the overhaul maintainer closest to the communication equipment at present can be determined.

In the above embodiment, when the abnormal condition is detected in the plurality of communication devices, the overhaul priority ranking is performed according to the comprehensive importance scores of the communication devices with abnormal detection, the position information of each overhaul terminal is obtained, the overhaul terminal closest to the communication device can be determined, and then the overhaul prompt information is sequentially sent to the overhaul terminal closest to the communication device with abnormal detection according to the overhaul priority ranking, so that the overhaul maintenance can be performed on the position of the communication device by the overhaul maintainer corresponding to the overhaul terminal, the current position of the allocated overhaul maintainer and the condition that the distance between the communication device with abnormal detection is far are reduced, the inspection efficiency is improved to a certain extent, and meanwhile, the overhaul is sequentially performed according to the overhaul priority ranking, so that the most important communication device can be overhauled and maintained in time, the reliability of the communication system is improved, and a powerful guarantee is provided for the maintenance work of the communication device.

Referring to fig. 5, as an embodiment of step S105, the step of obtaining the detection frequency value to be adjusted according to the level ratio and the preset detection frequency peak value includes:

s1051, determining a corresponding grade ratio interval according to the grade ratio based on a third preset mapping table, and determining a corresponding preset detection frequency adjustment ratio according to the grade ratio interval;

the third preset mapping table comprises a plurality of groups of corresponding relation between the grade ratio intervals and preset detection frequency adjustment ratios, and each grade ratio interval corresponds to one preset detection frequency adjustment ratio; in addition, the preset detection frequency adjustment proportion corresponding to the selected class ratio interval can be the optimal detection frequency adjustment proportion which can achieve the expected effect after being optimized and adjusted according to the actual situation;

s1052, according to the preset detection frequency adjustment proportion and the preset detection frequency peak value, calculating to obtain a detection frequency value to be adjusted.

It should be noted that, each level ratio section has no intersection, and the opening and closing of the end points, the section length and the section number of each section can be preset and adjusted according to the actual situation.

In the above embodiment, a plurality of level ratio intervals are preset, and a proper preset detection frequency adjustment proportion is allocated to each interval to obtain a third preset mapping table, and then according to the preset detection frequency adjustment proportion and the preset detection frequency peak value, a detection frequency value to be adjusted is obtained by calculation, and the detection frequency is adjusted, so that the condition that the detection frequency is adjusted too frequently is reduced, and the detection requirement can be better met.

The embodiment of the application discloses an earthquake emergency detection and adjustment system.

Referring to fig. 6, a seismic emergency detection adjustment system, the detection adjustment system comprising:

a receiving module 101, configured to receive earthquake early warning information;

the earthquake early warning information comprises earthquake intensity grades;

the obtaining module 102 is used for obtaining preset anti-seismic grades of communication equipment in each building in the hydropower station;

a judging module 103, configured to respectively judge whether the seismic intensity level exceeds a preset seismic level of the communication device in each building, and if yes, output a first judging result; if not, outputting a second judgment result;

the detection frequency adjustment module 104 is configured to adjust a detection frequency of the communication device in the building to a preset detection frequency peak value corresponding to the building in response to the first determination result;

the calculating module 105 is configured to respond to the second determination result, calculate a level ratio according to the seismic intensity level and a preset seismic level threshold, and obtain a detection frequency value to be adjusted according to a preset detection frequency peak corresponding to the level ratio and the building;

the detection frequency adjustment module 104 is further configured to adjust the detection frequency of the communication device in the building according to the detection frequency value to be adjusted.

In the above embodiment, when facing different earthquake levels, the detection requirements for communication equipment in different buildings can be simultaneously met, so that early warning signals in part of the buildings can be timely transmitted, and the condition that resource waste is caused by too frequent detection frequency of the communication equipment in part of the buildings is also reduced.

As an embodiment of the detection frequency adjustment module 104, the detection frequency adjustment module 104 includes:

a building importance level determining unit for determining a building importance level of a building based on building information of the building;

the preset detection frequency peak value determining unit is used for determining a corresponding preset detection frequency peak value according to the building importance level of the building based on the first preset mapping table.

In the above embodiment, for the communication devices in different buildings in the hydropower station, the corresponding preset detection frequency peak value needs to be flexibly set and adjusted according to the actual situation and the requirement.

As another embodiment of the detection frequency adjustment module 104, the detection frequency adjustment module 104 includes:

the device importance level determining unit is used for obtaining the device type of each communication device in the building and determining the device importance level corresponding to each communication device according to the device type;

the comprehensive importance degree score calculating unit is used for calculating and obtaining a comprehensive importance degree score corresponding to the communication equipment according to the building importance level of the building and the equipment importance level corresponding to the communication equipment in the building based on a preset calculation formula;

the preset detection frequency peak value determining unit is used for determining a corresponding scoring interval according to the comprehensive importance score corresponding to the communication equipment based on the second preset mapping table, and determining the preset detection frequency peak value corresponding to the communication equipment according to the scoring interval.

In the above embodiment, the building importance levels of different buildings and the device importance levels of different communication devices are combined to obtain the corresponding preset detection frequency peak value, so as to simultaneously meet the detection requirements of the communication devices with different importance levels in each building.

Referring to fig. 7, as a further embodiment of the seismic emergency detection adjustment system, the detection adjustment system further includes:

a detection module 201, configured to detect whether a detection abnormality occurs in a communication device in each building; if yes, outputting a detection abnormal result;

the comprehensive importance score calculation module 202 is configured to obtain comprehensive importance scores corresponding to the communication devices that detect the anomalies;

the overhaul priority ranking module 203 is configured to rank the comprehensive importance scores corresponding to the communication devices that detect the abnormality, so as to obtain overhaul priority ranking;

the current position information obtaining module 204 is configured to obtain current position information of each maintenance terminal;

and the overhaul prompting information sending module 205 is used for sequentially sending overhaul prompting information to the overhaul terminals closest to the communication equipment for detecting the abnormality based on the overhaul priority order according to the current position information of each overhaul terminal.

As an embodiment of the calculation module 105, the calculation module 105 includes:

the grade ratio interval determining unit is used for determining a corresponding grade ratio interval according to the grade ratio based on a third preset mapping table and determining a corresponding preset detection frequency adjustment proportion according to the grade ratio interval;

the detection frequency value to be adjusted calculating unit calculates the detection frequency value to be adjusted according to the preset detection frequency adjustment proportion and the preset detection frequency peak value.

The earthquake emergency detection adjustment system provided by the embodiment of the application can realize any one of the earthquake emergency detection adjustment methods, and the specific working process of each module in the earthquake emergency detection adjustment system can be referred to the corresponding process in the method embodiment.

In several embodiments provided by the present application, it should be understood that the methods and systems provided may be implemented in other ways. For example, the system embodiments described above are merely illustrative; for example, a division of a module is merely a logical function division, and there may be another division manner in actual implementation, for example, multiple modules may be combined or may be integrated into another system, or some features may be omitted or not performed.

The embodiment of the application also discloses computer equipment.

Computer apparatus comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing a seismic emergency detection adjustment method as described above when executing the computer program.

The embodiment of the application also discloses a computer readable storage medium.

A computer readable storage medium storing a computer program loadable by a processor and performing any of the methods of seismic emergency detection adjustment described above.

Wherein a computer readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device; program code embodied on a computer readable medium may be transmitted using any appropriate medium, including but not limited to wireless, wireline, optical fiber cable, RF, etc., or any suitable combination of the foregoing.

In the foregoing embodiments, the descriptions of the embodiments are focused on, and for those portions of one embodiment that are not described in detail, reference may be made to the related descriptions of other embodiments.

The foregoing description of the preferred embodiments of the application is not intended to limit the scope of the application in any way, including the abstract and drawings, in which case any feature disclosed in this specification (including abstract and drawings) may be replaced by alternative features serving the same, equivalent purpose, unless expressly stated otherwise. That is, each feature is one example only of a generic series of equivalent or similar features, unless expressly stated otherwise.

Claims

1. An earthquake emergency detection adjustment method is characterized by comprising the following steps:

2. The seismic emergency detection adjustment method of claim 1, wherein: the step of obtaining the preset detection frequency peak value comprises the following steps:

3. The seismic emergency detection adjustment method of claim 1, wherein: the step of obtaining the preset detection frequency peak value comprises the following steps:

4. A seismic emergency detection adjustment method according to claim 3, wherein: the detection adjustment method further comprises the following steps:

respectively acquiring current position information of each overhaul terminal;

5. The seismic emergency detection adjustment method of claim 1, wherein: the step of obtaining the detection frequency value to be adjusted according to the grade ratio and the preset detection frequency peak value comprises the following steps:

6. The seismic emergency detection adjustment method of claim 1, wherein: the step of adjusting the detection frequency of the communication device in the building according to the detection frequency value to be adjusted comprises the following steps:

7. A seismic emergency detection adjustment method according to any one of claims 1 to 6, wherein: the detection of the communication equipment in the building comprises any one or more of signal strength detection, signal-to-noise ratio detection, fault detection, interference resistance detection and network call detection.

8. A seismic emergency detection adjustment system, the detection adjustment system comprising:

a receiving module (101) for receiving earthquake early warning information; the earthquake early warning information comprises earthquake intensity grades;

the acquisition module (102) is used for acquiring preset anti-seismic grades of communication equipment in each building in the hydropower station;

the judging module (103) is used for respectively judging whether the earthquake intensity level exceeds the preset earthquake resistance level of the communication equipment in each building, and if so, outputting a first judging result; if not, outputting a second judgment result;

a detection frequency adjustment module (104) for adjusting the detection frequency of the communication equipment in the building to a preset detection frequency peak value corresponding to the building in response to the first judgment result;

the calculating module (105) is used for responding to a second judging result, calculating a grade ratio according to the seismic intensity grade and a preset earthquake-resistant grade threshold value, and obtaining a to-be-adjusted detection frequency value according to a preset detection frequency peak value corresponding to the building by the grade ratio;

the detection frequency adjustment module (104) is further configured to adjust the detection frequency of the communication device in the building according to the detection frequency value to be adjusted.

9. A computer device, characterized by: comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the method according to any of claims 1 to 7 when the program is executed.

10. A computer-readable storage medium, characterized by: a computer program stored which can be loaded by a processor and which performs the method according to any one of claims 1 to 7.