CN117132716B - Power environment monitoring method and device, electronic equipment and storage medium - Google Patents
Power environment monitoring method and device, electronic equipment and storage medium Download PDFInfo
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Abstract
The application relates to the technical field of power environment monitoring, in particular to a power environment monitoring method, a device, electronic equipment and a storage medium, wherein the display mode of a client for a monitoring machine room is determined to be a 3D display mode or a data view display mode according to the number of the monitoring machine room sent by the client and hardware parameters of the client; the method comprises the steps of constructing a mapping relation between monitoring equipment and a monitoring area of the monitoring equipment in the panoramic view of each monitoring machine room in advance; determining a panoramic view of the target monitoring machine room according to the serial number of the monitoring machine room sent by the client; determining a monitoring area to which the coordinate points belong based on the selected coordinate points, and determining target monitoring equipment according to the mapping relation; and sending the monitoring data to a client for display. Therefore, under the condition of insufficient hardware resources, the real-time data of various monitoring devices can be intuitively displayed through data view display, so that the 3D display mode or the data view display mode is effectively combined, and the display of power environment monitoring is completed.
Description
Technical Field
The present disclosure relates to the field of power environment monitoring technologies, and in particular, to a power environment monitoring method, a device, an electronic apparatus, and a storage medium.
Background
With the wide use of power environment monitoring systems in various industries, visual display and business early warning of power environment monitoring platforms are particularly important. At present, a power environment monitoring platform generally adopts a 3D display mode, has the advantages of strong display stereoscopic impression, good beautifying effect and the like, but also has the defect that 3D rendering and page switching of a display terminal are relatively time-consuming, and along with different power monitoring environments, 3D modeling of a monitoring scene needs to be completed in advance, so that the requirements on related technical thresholds of the 3D modeling are higher. The display terminal has the advantages that the display of the power environment monitoring platform in various different scenes cannot be well met under the conditions that the hardware resources of the display terminal are limited and the manufacturing time is limited.
Disclosure of Invention
In order to overcome the defects in the prior art, the application provides a power environment monitoring method, a device, electronic equipment and a storage medium, which can intuitively display real-time data of various monitoring equipment by replacing a 3D display mode with a data view display mode under the condition of insufficient hardware resources.
In a first aspect, an embodiment of the present application provides a power environment monitoring method, including the steps of:
determining a display mode of the client for the monitoring machine room according to the monitoring machine room number sent by the client and hardware parameters of the client;
wherein; inquiring whether the monitoring machine room number and the corresponding 3D resource exist or not from a preset 3D model resource library; if the 3D modeling complexity is determined based on the queried 3D resources, judging whether the hardware parameters of the client meet the 3D modeling complexity, if so, determining the display mode of the client for the monitoring machine room as a 3D display mode, and if not, determining the display mode of the client for the monitoring machine room as a data view display mode;
and the data view presentation mode is performed by:
based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas;
determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display;
Determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation;
and acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display.
In some embodiments, the mapping relationship between the monitoring device and the monitoring area in each monitoring machine room panorama is pre-built based on the plurality of monitoring machine room panoramas sent by the client, and the mapping relationship comprises the following steps:
storing SVG vector images of a plurality of monitoring machine room panoramic images sent by a client, and corresponding storage paths, monitoring machine room codes and SVG sizes of the SVG vector images; the panoramic view of the monitoring machine room is generated by the client based on videos shot by each monitoring machine room;
acquiring a monitoring area screenshot of all monitoring equipment in each monitoring machine room panoramic image determined by a client, and corresponding coordinates of a monitoring machine room code and a monitoring area;
determining a monitoring equipment code corresponding to the monitoring area screenshot;
and pre-constructing a mapping relation between the coordinates of the monitoring area in the panoramic view of each monitoring machine room and the codes of the monitoring equipment.
In some embodiments, the determining the monitoring device code corresponding to the screenshot of the monitoring area includes the following steps:
determining a corresponding monitoring machine room code based on the screenshot of the monitoring area, and inquiring product pictures of all monitoring devices in the monitoring machine room from a preset monitoring product database;
comparing the screenshot of the monitoring area with the product picture to obtain a first type and a first model of corresponding monitoring equipment; wherein the first model is a model array;
detecting whether monitoring equipment identifiers for acquiring the monitoring equipment codes exist in the monitoring area screenshot, and if yes, inquiring a second type and a second model of the monitoring equipment corresponding to the monitoring equipment codes from a preset monitoring product database;
and if the first type is the same as the second type and the first type comprises the second type, determining the monitoring equipment code acquired according to the monitoring equipment identifier as the monitoring equipment code corresponding to the monitoring area screenshot.
In some embodiments, the determining the monitoring device code corresponding to the screenshot of the monitoring area further includes the following steps:
if the monitoring equipment identification for acquiring the monitoring equipment code is not detected in the monitoring area screenshot, inquiring the second type and the monitoring equipment code and position information corresponding to the second model from a preset monitoring product database;
And if a plurality of monitoring equipment codes corresponding to the second type and the second type are provided, determining the monitoring equipment codes corresponding to the screenshot of the monitoring area according to the position information or the received specified instruction.
In some embodiments, the determining the panoramic view of the target monitoring room according to the serial number of the monitoring room sent by the client, and sending the panoramic view of the target monitoring room to the client for display, includes the following steps:
receiving a monitoring machine room number and a display parameter of a client, wherein the monitoring machine room number and the display parameter are sent by the client;
determining the SVG size of the panoramic image and the SVG vector image of the target monitoring machine room according to the serial number of the monitoring machine room sent by the client;
determining the scaling of the panoramic view of the target monitoring machine room based on the display parameters and the SVG size, and scaling the panoramic view of the target monitoring machine room according to the scaling;
and sending the scaled panoramic image of the target monitoring machine room to the client for display.
In some embodiments, the determining, based on a coordinate point selected on the panorama of the target monitoring machine room, a monitoring area to which the coordinate point belongs, and determining the target monitoring device according to the mapping relationship, includes the following steps:
Acquiring all monitoring equipment codes and corresponding coordinates of a monitoring area in a monitoring machine room according to the monitoring machine room number sent by a client;
scaling the obtained coordinates of all the monitoring areas according to the scaling proportion;
receiving a coordinate point selected on the panoramic view of the target monitoring machine room, which is displayed by the client, sent by the client;
and determining a monitoring area to which the coordinate point belongs based on the coordinate point, and determining target monitoring equipment according to the pre-constructed mapping relation.
In some embodiments, the acquiring real-time monitoring data of the target monitoring device and sending the monitoring data to the client for display includes the following steps:
judging whether the corresponding target monitoring equipment is abnormal or not according to the monitoring data, and if so, carrying out alarm display on a monitoring area corresponding to the target monitoring equipment.
In a second aspect, an embodiment of the present application provides a power environment monitoring device, residing on a server side of a power environment monitoring system, the device including:
the determining module is used for determining a display mode of the client for the monitoring machine room according to the monitoring machine room number sent by the client and the hardware parameters of the client;
Wherein; inquiring whether the monitoring machine room number and the corresponding 3D resource exist or not from a preset 3D model resource library; if the 3D modeling complexity is determined based on the queried 3D resources, judging whether the hardware parameters of the client meet the 3D modeling complexity, if so, determining the display mode of the client for the monitoring machine room as a 3D display mode, and if not, determining the display mode of the client for the monitoring machine room as a data view display mode;
the data view display module is used for performing the data view display mode in the following way:
based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas; determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display; determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation; and acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display.
In a third aspect, an embodiment of the present application provides an electronic device, including a processor, a memory, and a bus, where the memory stores machine-readable instructions executable by the processor, where the processor and the memory communicate via the bus when the electronic device is running, and where the machine-readable instructions, when executed by the processor, perform the steps of the power environment monitoring method according to any one of the first aspect above.
In a fourth aspect, embodiments of the present application provide a computer-readable storage medium having a computer program stored thereon, which when executed by a processor performs the steps of the power environment monitoring method according to any one of the first aspects above.
According to the power environment monitoring method, the device, the electronic equipment and the storage medium, according to the monitoring machine room number sent by the client and the hardware parameters of the client, the display mode of the client for the monitoring machine room is determined to be a 3D display mode or a data view display mode; and the data view presentation mode is performed by: based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas; determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display; determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation; and acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display. Therefore, the display of the power environment monitoring is completed by effectively combining a 3D display mode or a data view display mode.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and that other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.
FIG. 1 illustrates a flow chart of a method of power environment monitoring according to an embodiment of the present application;
fig. 2 shows a flowchart of pre-constructing a mapping relationship between a monitoring device and a monitoring area thereof in a panoramic view of each monitoring machine room according to an embodiment of the present application;
FIG. 3 is a flowchart of determining a monitoring device code corresponding to the screenshot of the monitoring area according to an embodiment of the present application;
fig. 4 shows a flowchart of sending the panoramic view of the target monitoring room to the client for display in the embodiment of the present application;
FIG. 5 shows a schematic structural diagram of a power environment monitoring device according to an embodiment of the present application;
fig. 6 shows a block diagram of an electronic device according to an embodiment of the present application.
Detailed Description
For the purpose of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application, and it should be understood that the accompanying drawings in the present application are only for the purpose of illustration and description, and are not intended to limit the protection scope of the present application. In addition, it should be understood that the schematic drawings are not drawn to scale. A flowchart, as used in this application, illustrates operations implemented according to some embodiments of the present application. It should be understood that the operations of the flow diagrams may be implemented out of order and that steps without logical context may be performed in reverse order or concurrently. Moreover, one or more other operations may be added to the flow diagrams and one or more operations may be removed from the flow diagrams as directed by those skilled in the art.
In addition, the described embodiments are only some, but not all, of the embodiments of the present application. The components of the embodiments of the present application, which are generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present application, as provided in the accompanying drawings, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present application without making any inventive effort, are intended to be within the scope of the present application.
It should be noted that the term "comprising" will be used in the embodiments of the present application to indicate the presence of the features stated hereinafter, but not to exclude the addition of other features.
In view of the technical problems set forth in the background art, the application provides a power environment monitoring method, a device, electronic equipment and a storage medium, which can effectively combine a 3D display mode or a data view display mode to complete the display of power environment monitoring.
Referring to fig. 1 of the specification, a power environment monitoring method provided in an embodiment of the application is applied to a server of a power environment monitoring system, and includes the following steps:
P1, determining a display mode of a client for a monitoring machine room according to a monitoring machine room number sent by the client and hardware parameters of the client;
p2, inquiring whether the monitoring machine room number and the corresponding 3D resource exist in a preset 3D model resource library; if the 3D modeling complexity is determined based on the queried 3D resources, judging whether the hardware parameters of the client meet the 3D modeling complexity, if so, determining the display mode of the client for the monitoring machine room as a 3D display mode, and if not, determining the display mode of the client for the monitoring machine room as a data view display mode;
and P3, performing the data view display mode by the following steps: s1, constructing a mapping relation between monitoring equipment and a monitoring area thereof in each monitoring machine room panorama in advance based on a plurality of monitoring machine room panoramas sent by a client; s2, determining a target monitoring machine room panorama according to the number of the monitoring machine room sent by the client, and sending the target monitoring machine room panorama to the client for display; s3, determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation; s4, acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display.
Specifically, in step P1-step P2, the 3D display mode or the data view display mode is decided to be used according to the monitoring room number sent by the client (display terminal) and the hardware parameters of the client.
In an embodiment, a server firstly queries whether a monitoring machine room number and corresponding 3D resources (GLB 3D files and corresponding file paths) exist in a preset 3D model resource library according to the monitoring machine room number sent by a client, if so, further obtains the complexity of 3D modeling in the scene, and the complexity is divided into a plurality of grades of low, medium, high, extra-high and the like, and each grade has hardware parameters (CPU core number, main frequency, GPU core number, main frequency and total memory) defined by matching with the grade; and judging whether hardware parameters of the client side meet requirements according to the complexity of the 3D modeling, if so, selecting a 3D display mode, if not, inquiring whether the monitoring machine room number and corresponding view resources (SVG data of a monitoring machine room panoramic image, monitoring equipment and corresponding monitoring areas) exist in a preset resource view model library, and if so, selecting a data view display mode.
The method includes the steps that if a specified monitoring machine room only has 3D resources, only a 3D mode is adopted to finish display; if only view resources are provided, completing display by loading and monitoring the panoramic image; if both display modes are provided, the method is used for judging the proper display mode later according to the hardware parameters of the client or a user designates to adopt a 3D display mode or a data view display mode.
Since the 3D display mode is mature, which is a technical means well known to those skilled in the art, the present application specifically states the data view display mode only in step P3. The process of carrying out the data view display mode comprises two parts, wherein the first part is the input of the data view, namely, the step S1; the second part is the presentation of the data view, step S2-step S4.
In an embodiment, referring to fig. 2 of the specification, in step S1, a mapping relationship between a monitoring device and a monitoring area thereof in each monitoring machine room panorama is pre-built based on a plurality of monitoring machine room panoramas sent by a client, and the method includes the following steps:
s101, storing SVG vector diagrams of a plurality of monitoring machine room panoramic pictures sent by a client, and corresponding storage paths, monitoring machine room codes and SVG sizes of the SVG vector diagrams; the panoramic view of the monitoring machine room is generated by the client based on videos shot by each monitoring machine room;
s102, acquiring a screenshot of a monitoring area of all monitoring equipment in each monitoring machine room panoramic image determined by a client, and corresponding coordinates of a monitoring machine room code and a monitoring area of the monitoring equipment;
S103, determining a monitoring equipment code corresponding to the monitoring area screenshot;
s104, pre-constructing a mapping relation between the coordinates of the monitoring area in the panoramic view of each monitoring machine room and the codes of the monitoring equipment.
Specifically, in step S101, the current monitoring room is photographed by multiple groups of cameras or cameras with a cloud mirror function, and the video stream is sent to the client, the client acquires and analyzes the video stream, and intercepts frame data required in the video stream to form a panoramic view of the monitoring room, optionally, multiple frames of video pictures are edited and synthesized into the panoramic view of the monitoring room at the client. The panoramic image of the monitoring machine room is used as a background image layer of a data view display scheme, and the image is converted into an SVG vector image and uploaded to a server; the server stores the SVG vector diagram under a source folder, stores a vector diagram path, and monitors machine room codes and SVG sizes;
in step S102, a screenshot of the monitoring area of the monitoring device may be created manually. Optionally, dragging a mouse from the left upper corner of the monitoring equipment, intercepting the area where the monitoring equipment is located, and after intercepting, sending the codes of the monitoring machine room and the coordinates of the monitoring area (the left upper corner coordinates of the intercepting area, the length and the width of the intercepting area) to a server;
Referring to fig. 3 of the specification, in step S103, determining a monitoring device code corresponding to the screenshot of the monitoring area includes the following steps:
s1031, determining corresponding monitoring machine room codes based on the monitoring area screenshot, and inquiring product pictures of all monitoring devices in the monitoring machine room from a preset monitoring product database;
s1032, comparing the screenshot of the monitoring area with the product picture to obtain a first type and a first model of the corresponding monitoring equipment; wherein the first model is a model array;
s1033, detecting whether monitoring equipment identifiers for acquiring the monitoring equipment codes exist in the monitoring area screenshot, and if yes, inquiring a second type and a second model of the monitoring equipment corresponding to the monitoring equipment codes from a preset monitoring product database;
s1034, if the first type is the same as the second type and the first type contains the second type, determining the monitoring equipment code obtained according to the monitoring equipment identification as the monitoring equipment code corresponding to the monitoring area screenshot.
Specifically, in step S1031-step S1032, a monitoring product database is queried according to a monitoring machine room code, all monitoring devices and corresponding product pictures under the monitoring machine room are obtained, view information of the monitoring devices is obtained according to a monitoring area screenshot sent by a client, the view information is compared with the product pictures one by one, for example, a SIFT (scale invariant transform) algorithm is adopted, and after comparison is completed, the type of the monitoring devices is obtained. It should be noted that, there may be multiple types of monitoring devices with the same appearance but different device types, and at this time, a one-dimensional array of the monitoring device types may be formed;
In step S1033, it may be directly detected whether the acquired view information of the monitoring device has a device barcode, if yes, the monitoring device code may be resolved, if the monitoring device code is resolved successfully, it is confirmed whether the monitoring device code is in a monitoring device list under the monitoring machine room, if the cost is confirmed, the type and model of the monitoring device are acquired according to the monitoring device code;
in step S1034, the type and model of the monitoring device acquired in step S1032 are compared with the type and model of the monitoring device acquired in step S1033, and if the type is the same and the model of the monitoring device acquired in step S1033 is included in the model of the monitoring device acquired in step S1032, the monitoring device encoding bidirectional verification is considered to be successful;
if the bidirectional verification is not successful, all monitoring equipment under the monitoring machine room is encoded to form a one-dimensional monitoring equipment object array, and the one-dimensional monitoring equipment object array is returned to the client, and if the monitoring product database stores the position information of the monitoring equipment, the position information is added into the returned object array; selecting the correct monitoring equipment code by manual direct selection or according to the position information;
In addition, if in step S1033, the monitoring device identifier for obtaining the monitoring device code is not detected in the screenshot of the monitoring area, the type and the model of the monitoring device are obtained according to step S1032, if the type and the model are unique, the corresponding monitoring device code can be determined, if not, a one-dimensional monitoring device object array is also generated and returned to the client, and the correct monitoring device code is selected directly by a person or according to the position information.
Thereby ensuring the accuracy of the mapping relationship between the coordinates of the monitoring area in the panoramic view of each monitoring machine room and the codes of the monitoring equipment, which are pre-constructed in step S104.
Referring to fig. 4 of the specification, in step S2, the determining a panoramic view of the target monitoring machine room according to the number of the monitoring machine room sent by the client, and sending the panoramic view of the target monitoring machine room to the client for display, includes the following steps:
s201, receiving a monitoring machine room number and a display parameter of a client, wherein the monitoring machine room number and the display parameter are sent by the client;
s202, determining the SVG size of a panoramic image of a target monitoring machine room and an SVG vector image of the panoramic image according to the number of the monitoring machine room sent by a client;
s203, determining the scaling of the panoramic view of the target monitoring machine room based on the display parameters and the SVG size, and scaling the scaling;
S204, sending the scaled panoramic image of the target monitoring machine room to the client for display.
Specifically, in step S201-step S204, the display terminal sends the number of the monitoring machine room and the display parameters of the client to the server, where the display parameters include the display size width Wr and the display height Hr of the client; and then the server calls the SVG size (width Wd, height Hd) of the panoramic image of the target monitoring machine room and the SVG vector image thereof according to the monitoring machine room number, and the scaling ratio is:
β(W) = Wd / Wy
β(H) = Hd / Hy
if the beta (W) value is different from the beta (H) value, taking a larger value as a scaling ratio, scaling the panoramic image of the target monitoring machine room according to the larger value beta ratio, and sending the scaled panoramic image to a client for display; and meanwhile, the beta value is stored for the next time or other clients with the same size.
And after the target monitoring machine room panorama is obtained according to the number of the monitoring machine room and is displayed by taking the client as a background layer, executing a step S3, selecting a coordinate point from the target monitoring machine room panorama displayed by the client, transmitting the coordinate point to a server, firstly obtaining all monitoring equipment codes in the monitoring machine room and coordinates of corresponding monitoring areas according to the number of the monitoring machine room by the server, calculating the coordinates of the corresponding monitoring areas according to a scaling ratio, determining in which monitoring area the coordinate point transmitted by the client is, determining the target monitoring equipment code through the monitoring areas according to a mapping relation with the building, and further transmitting the target monitoring equipment code, the corresponding monitoring areas and the monitoring data to the client for displaying.
Further, after a serious alarm occurs to a certain monitoring device in the monitoring machine room (the serious alarm level can be configured in the server), the client can highlight the monitoring area and flash, which indicates that the serious alarm event occurs to the monitoring device.
Therefore, according to the power environment monitoring method, the 3D display mode and the data view display mode are effectively combined, the 3D display mode can be selected to optimize the display effect when the performance of the client is enough, and the data view display mode can be selected to better process the scene that the rendering capacity of the client is insufficient but the real-time data of various monitoring devices are needed to be visually seen when the performance of the client is insufficient; and when the data view display mode is adopted, the requirements of various machine rooms can be responded rapidly by constructing the mapping relation between the monitoring equipment and the monitoring areas in the panoramic view of each monitoring machine room, the display cost is reduced greatly, and the timeliness of display is improved.
Based on the same inventive concept, the embodiment of the present application further provides a power environment monitoring device, and since the principle of solving the problem by the device in the embodiment of the present application is similar to that of the power environment monitoring method in the embodiment of the present application, the implementation of the device may refer to the implementation of the method, and the repetition is omitted.
As shown in fig. 5 of the specification, the present application further provides a power environment monitoring device, which is applied to a server of a power environment monitoring system, and the device includes:
the determining module 501 is configured to determine, according to a monitoring machine room number sent by a client and a hardware parameter of the client, a display mode of the client for the monitoring machine room;
wherein; inquiring whether the monitoring machine room number and the corresponding 3D resource exist or not from a preset 3D model resource library; if the 3D modeling complexity is determined based on the queried 3D resources, judging whether the hardware parameters of the client meet the 3D modeling complexity, if so, determining the display mode of the client for the monitoring machine room as a 3D display mode, and if not, determining the display mode of the client for the monitoring machine room as a data view display mode;
a data view display module 502, configured to perform the data view display mode in the following manner:
based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas; determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display; determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation; and acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display.
In some embodiments, the data view display module 502 pre-constructs a mapping relationship between the monitoring device and the monitoring area thereof in each monitoring machine room panorama based on a plurality of monitoring machine room panoramas sent by the client, including:
storing SVG vector images of a plurality of monitoring machine room panoramic images sent by a client, and corresponding storage paths, monitoring machine room codes and SVG sizes of the SVG vector images; the panoramic view of the monitoring machine room is generated by the client based on videos shot by each monitoring machine room;
acquiring a monitoring area screenshot of all monitoring equipment in each monitoring machine room panoramic image determined by a client, and corresponding coordinates of a monitoring machine room code and a monitoring area;
determining a monitoring equipment code corresponding to the monitoring area screenshot;
and pre-constructing a mapping relation between the coordinates of the monitoring area in the panoramic view of each monitoring machine room and the codes of the monitoring equipment.
In some embodiments, the data view display module 502 determines a monitoring device code corresponding to the monitoring region screenshot, including:
determining a corresponding monitoring machine room code based on the screenshot of the monitoring area, and inquiring product pictures of all monitoring devices in the monitoring machine room from a preset monitoring product database;
Comparing the screenshot of the monitoring area with the product picture to obtain a first type and a first model of corresponding monitoring equipment; wherein the first model is a model array;
detecting whether monitoring equipment identifiers for acquiring the monitoring equipment codes exist in the monitoring area screenshot, and if yes, inquiring a second type and a second model of the monitoring equipment corresponding to the monitoring equipment codes from a preset monitoring product database;
and if the first type is the same as the second type and the first type comprises the second type, determining the monitoring equipment code acquired according to the monitoring equipment identifier as the monitoring equipment code corresponding to the monitoring area screenshot.
In some embodiments, the data view display module 502 determines a monitoring device code corresponding to the monitoring area screenshot, and further includes:
if the monitoring equipment identification for acquiring the monitoring equipment code is not detected in the monitoring area screenshot, inquiring the second type and the monitoring equipment code and position information corresponding to the second model from a preset monitoring product database;
and if a plurality of monitoring equipment codes corresponding to the second type and the second type are provided, determining the monitoring equipment codes corresponding to the screenshot of the monitoring area according to the position information or the received specified instruction.
In some embodiments, the data view display module 502 determines a target monitoring room panorama according to a monitoring room number sent by a client, and sends the target monitoring room panorama to the client for display, including:
receiving a monitoring machine room number and a display parameter of a client, wherein the monitoring machine room number and the display parameter are sent by the client;
determining the SVG size of the panoramic image and the SVG vector image of the target monitoring machine room according to the serial number of the monitoring machine room sent by the client;
determining the scaling of the panoramic view of the target monitoring machine room based on the display parameters and the SVG size, and scaling the panoramic view of the target monitoring machine room according to the scaling;
and sending the scaled panoramic image of the target monitoring machine room to the client for display.
In some embodiments, the data view display module 502 determines, based on a coordinate point selected on the panoramic view of the target monitoring room, a monitoring area to which the coordinate point belongs, and determines the target monitoring device according to the mapping relationship, including:
acquiring all monitoring equipment codes and corresponding coordinates of a monitoring area in a monitoring machine room according to the monitoring machine room number sent by a client;
scaling the obtained coordinates of all the monitoring areas according to the scaling proportion;
Receiving a coordinate point selected on the panoramic view of the target monitoring machine room, which is displayed by the client, sent by the client;
and determining a monitoring area to which the coordinate point belongs based on the coordinate point, and determining target monitoring equipment according to the pre-constructed mapping relation.
In some embodiments, the data view display module 502 obtains real-time monitoring data of the target monitoring device, and sends the monitoring data to the client for display, including:
judging whether the corresponding target monitoring equipment is abnormal or not according to the monitoring data, and if so, carrying out alarm display on a monitoring area corresponding to the target monitoring equipment.
According to the power environment monitoring device, the display mode of the client side for the monitoring machine room is determined to be a 3D display mode or a data view display mode through the determining module according to the monitoring machine room number sent by the client side and the hardware parameters of the client side; and performing, by the data view presentation module, the data view presentation mode by: based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas; determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display; determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation; and acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display. Therefore, the display of the power environment monitoring is completed by effectively combining a 3D display mode or a data view display mode.
Based on the same concept of the present invention, fig. 6 of the present disclosure shows a structure of an electronic device 600 according to an embodiment of the present application, where the electronic device 600 includes: at least one processor 601, at least one network interface 604 or other user interface 603, memory 605, at least one communication bus 602. The communication bus 602 is used to enable connected communications between these components. The electronic device 600 optionally includes a user interface 603 including a display (e.g., a touch screen, LCD, CRT, holographic imaging (Holographic) or projection (Projector), etc.), a keyboard or pointing device (e.g., a mouse, trackball, touch pad or touch screen, etc.).
Memory 605 may include read-only memory and random access memory and provide instructions and data to processor 601. A portion of the memory 605 may also include non-volatile random access memory (NVRAM).
In some implementations, the memory 605 stores the following elements, protectable modules or data structures, or a subset thereof, or an extended set thereof:
an operating system 6051 containing various system programs for implementing various basic services and handling hardware-based tasks;
The application program module 6052 includes various application programs such as a desktop (desktop), a Media Player (Media Player), a Browser (Browser), and the like for implementing various application services.
In the embodiment of the present application, the processor 601 is configured to execute steps in a power environment monitoring method by calling a program or instructions stored in the memory 605, and can effectively combine with a 3D display mode or a data view display mode to complete display of power environment monitoring.
The present application also provides a computer readable storage medium having stored thereon a computer program which when executed by a processor performs steps as in a power environment monitoring method.
In particular, the storage medium can be a general-purpose storage medium, such as a removable disk, a hard disk, or the like, on which a computer program can be executed to perform the above-described power environment monitoring method.
In the embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the division of units is merely a logical function division, and there may be other manners of division in actual implementation, and for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some communication interface, device or unit indirect coupling or communication connection, which may be in electrical, mechanical or other form.
The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed over a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.
In addition, each functional unit in the embodiments provided in the present application may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit.
The functions, if implemented in the form of software functional units and sold or used as a stand-alone product, may be stored in a computer-readable storage medium. Based on such understanding, the technical solution of the present application may be embodied essentially or in a part contributing to the prior art or in a part of the technical solution, in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of the methods of the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, or an optical disk, or other various media capable of storing program codes.
Finally, it should be noted that: the foregoing examples are merely illustrative of specific embodiments of the present application, and are not intended to limit the scope of the present application, although the present application is described in detail with reference to the foregoing examples, it will be understood by those skilled in the art that: any person skilled in the art may modify or easily conceive of the technical solution described in the foregoing embodiments, or make equivalent substitutions for some of the technical features within the technical scope of the disclosure of the present application; such modifications, changes or substitutions do not depart from the spirit and scope of the corresponding technical solutions. Are intended to be encompassed within the scope of this application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.
Claims (9)
1. A power environment monitoring method, characterized by being applied to a server of a power environment monitoring system, the method comprising the steps of:
determining a display mode of the client for the monitoring machine room according to the monitoring machine room number sent by the client and hardware parameters of the client;
Wherein; inquiring whether the monitoring machine room number and the corresponding 3D resource exist or not from a preset 3D model resource library; if the 3D modeling complexity is determined based on the queried 3D resources, judging whether the hardware parameters of the client meet the 3D modeling complexity, if so, determining the display mode of the client for the monitoring machine room as a 3D display mode, and if not, determining the display mode of the client for the monitoring machine room as a data view display mode;
and the data view presentation mode is performed by:
based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas;
determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display;
determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation;
acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display;
The mapping relation between monitoring equipment and monitoring areas in each monitoring machine room panoramic image is built in advance based on a plurality of monitoring machine room panoramic images sent by a client, and the mapping relation comprises the following steps:
storing SVG vector images of a plurality of monitoring machine room panoramic images sent by a client, and corresponding storage paths, monitoring machine room codes and SVG sizes of the SVG vector images; the monitoring machine room panoramic image is generated by the client based on videos shot by each monitoring machine room;
acquiring a monitoring area screenshot of all monitoring equipment in each monitoring machine room panoramic image determined by a client, and corresponding coordinates of a monitoring machine room code and a monitoring area;
determining a monitoring equipment code corresponding to the monitoring area screenshot;
and pre-constructing a mapping relation between the coordinates of the monitoring area in the panoramic view of each monitoring machine room and the codes of the monitoring equipment.
2. The method for monitoring a power environment according to claim 1, wherein the determining the monitoring device code corresponding to the screenshot of the monitoring area includes the following steps:
determining a corresponding monitoring machine room code based on the screenshot of the monitoring area, and inquiring product pictures of all monitoring devices in the monitoring machine room from a preset monitoring product database;
Comparing the screenshot of the monitoring area with the product picture to obtain a first type and a first model of corresponding monitoring equipment; wherein the first model is a model array;
detecting whether monitoring equipment identifiers for acquiring the monitoring equipment codes exist in the monitoring area screenshot, and if yes, inquiring a second type and a second model of the monitoring equipment corresponding to the monitoring equipment codes from a preset monitoring product database;
and if the first type is the same as the second type and the first type comprises the second type, determining the monitoring equipment code acquired according to the monitoring equipment identifier as the monitoring equipment code corresponding to the monitoring area screenshot.
3. The power environment monitoring method according to claim 2, wherein the determining the monitoring device code corresponding to the screenshot of the monitoring area further comprises the following steps:
if the monitoring equipment identification for acquiring the monitoring equipment code is not detected in the monitoring area screenshot, inquiring the second type and the monitoring equipment code and position information corresponding to the second model from a preset monitoring product database;
and if a plurality of monitoring equipment codes corresponding to the second type and the second type are provided, determining the monitoring equipment codes corresponding to the screenshot of the monitoring area according to the position information or the received specified instruction.
4. The power environment monitoring method according to claim 3, wherein the determining the panoramic view of the target monitoring machine room according to the number of the monitoring machine room sent by the client, and sending the panoramic view of the target monitoring machine room to the client for display, comprises the following steps:
receiving a monitoring machine room number and a display parameter of a client, wherein the monitoring machine room number and the display parameter are sent by the client;
determining the SVG size of the panoramic image and the SVG vector image of the target monitoring machine room according to the serial number of the monitoring machine room sent by the client;
determining the scaling of the panoramic view of the target monitoring machine room based on the display parameters and the SVG size, and scaling the panoramic view of the target monitoring machine room according to the scaling;
and sending the scaled panoramic image of the target monitoring machine room to the client for display.
5. The power environment monitoring method according to claim 4, wherein the determining the monitoring area to which the coordinate point belongs based on the coordinate point selected on the panorama of the target monitoring machine room, and determining the target monitoring device according to the mapping relationship, includes the following steps:
acquiring all monitoring equipment codes and corresponding coordinates of a monitoring area in a monitoring machine room according to the monitoring machine room number sent by a client;
Scaling the obtained coordinates of all the monitoring areas according to the scaling proportion;
receiving a coordinate point selected on the panoramic view of the target monitoring machine room, which is displayed by the client, sent by the client;
and determining a monitoring area to which the coordinate point belongs based on the coordinate point, and determining target monitoring equipment according to the pre-constructed mapping relation.
6. The method for monitoring power environment according to claim 5, wherein the steps of obtaining real-time monitoring data of the target monitoring device and sending the monitoring data to the client for display include the following steps:
judging whether the corresponding target monitoring equipment is abnormal or not according to the monitoring data, and if so, carrying out alarm display on a monitoring area corresponding to the target monitoring equipment.
7. A power environment monitoring device residing on a server side of a power environment monitoring system, the device comprising:
the determining module is used for determining a display mode of the client for the monitoring machine room according to the monitoring machine room number sent by the client and the hardware parameters of the client;
wherein; inquiring whether the monitoring machine room number and the corresponding 3D resource exist or not from a preset 3D model resource library; if the 3D modeling complexity is determined based on the queried 3D resources, judging whether the hardware parameters of the client meet the 3D modeling complexity, if so, determining the display mode of the client for the monitoring machine room as a 3D display mode, and if not, determining the display mode of the client for the monitoring machine room as a data view display mode;
The data view display module is used for performing the data view display mode in the following way:
based on a plurality of monitoring machine room panoramas sent by a client, pre-constructing a mapping relation between monitoring equipment and monitoring areas thereof in each monitoring machine room panoramas; determining a target monitoring machine room panoramic image according to the number of the monitoring machine room sent by a client, and sending the target monitoring machine room panoramic image to the client for display; determining a monitoring area to which the coordinate point belongs based on the coordinate point selected on the panoramic view of the target monitoring machine room, and determining target monitoring equipment according to the mapping relation; acquiring real-time monitoring data of the target monitoring equipment, and sending the monitoring data to the client for display; the method comprises the steps of constructing a mapping relation between monitoring equipment and a monitoring area thereof in each monitoring machine room panorama based on a plurality of monitoring machine room panoramas sent by a client, wherein the mapping relation comprises SVG vector diagrams for storing the plurality of monitoring machine room panoramas sent by the client, and corresponding storage paths, monitoring machine room codes and SVG sizes of the SVG vector diagrams; the monitoring machine room panoramic image is generated by the client based on videos shot by each monitoring machine room; acquiring a monitoring area screenshot of all monitoring equipment in each monitoring machine room panoramic image determined by a client, and corresponding coordinates of a monitoring machine room code and a monitoring area; determining a monitoring equipment code corresponding to the monitoring area screenshot; and pre-constructing a mapping relation between the coordinates of the monitoring area in the panoramic view of each monitoring machine room and the codes of the monitoring equipment.
8. An electronic device, comprising: a processor, a memory and a bus, said memory storing machine readable instructions executable by said processor, said processor and said memory communicating over the bus when the electronic device is running, said machine readable instructions when executed by said processor performing the steps of the power environment monitoring method according to any one of claims 1 to 6.
9. A computer readable storage medium, characterized in that the computer readable storage medium has stored thereon a computer program which, when executed by a processor, performs the steps of the power environment monitoring method according to any of claims 1 to 6.
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