CN115309303B

CN115309303B - Construction area management and control method and device, electronic equipment and readable storage medium

Info

Publication number: CN115309303B
Application number: CN202210947177.7A
Authority: CN
Inventors: 郑文
Original assignee: Fujian Huichuan Internet Of Things Technology Science And Technology Co ltd
Current assignee: Fujian Huichuan Internet Of Things Technology Science And Technology Co ltd
Priority date: 2022-08-09
Filing date: 2022-08-09
Publication date: 2023-12-15
Anticipated expiration: 2042-08-09
Also published as: CN115309303A

Abstract

The application provides a control method, a control device, electronic equipment and a readable storage medium for a construction area, wherein a panoramic image corresponding to any thumbnail image is displayed in a graphical user interface in response to a first selection operation for the thumbnail image; in order to intuitively show the construction position with the hidden quality trouble, for each construction monitoring point, if the spatial variation value of any one space monitoring parameter between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, the first color is adjusted to be a second color, and the point position icon of the construction monitoring point is displayed in the second color. Therefore, the construction area related to the target engineering project can be remotely, visually, fully and digitally controlled, the construction position with the quality hidden trouble can be timely positioned, and the construction details of the construction position with the quality hidden trouble can be intuitively observed.

Description

Construction area management and control method and device, electronic equipment and readable storage medium

Technical Field

The present application relates to the field of monitoring technologies, and in particular, to a method and an apparatus for managing and controlling a construction area, an electronic device, and a readable storage medium.

Background

At present, along with the rapid development of the building industry, the construction engineering is more and more huge in scale and various and complex in working procedures, so that the quality safety supervision work and the construction progress data acquisition work of a construction site are particularly important, and higher requirements are also faced.

The traditional quality safety supervision work and construction progress data acquisition work mainly depend on manpower, but the construction period of building construction is generally long, and the construction process is influenced by various factors, and the quality supervision and the data recording by staff all have the problems of hysteresis, easy error and the like, so that the progress management and the quality management of construction projects cannot be mastered in time, the progress of the construction progress is easy to be slow, the quality guarantee and the quality guarantee of the construction project are difficult to finish, and the engineering quality and the safety construction are not guaranteed.

Disclosure of Invention

In view of the above, an object of the present application is to provide a method, an apparatus, an electronic device, and a readable storage medium for controlling a construction area, which can remotely, visually, fully, digitally control a construction area related to a target engineering project, intuitively observe construction details of a construction position where a quality hidden trouble exists, and further, timely locate the construction position where the quality hidden trouble exists.

The embodiment of the application provides a control method of a construction area, which comprises the steps of displaying a graphical user interface through terminal equipment, wherein at least part of thumbnail image of the construction area related to a target engineering project is displayed in the graphical user interface; the control method comprises the following steps:

responding to a first selection operation aiming at any thumbnail image, and displaying a panoramic image corresponding to the thumbnail image in the graphical user interface; the panoramic image map displays measurement information of each construction object in the construction area and point location icons of each construction monitoring point location; the point location icon is displayed in a first color;

for each construction monitoring point, if the spatial variation value of any one of the spatial monitoring parameters between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, adjusting the first color to a second color, and displaying the point icons of the construction monitoring point in the second color.

In one possible embodiment, the control method further includes:

responding to a second selection operation of a point position icon aiming at any construction monitoring point position, and displaying space change information between historical construction details and current construction details of a target monitoring point position selected by the second selection operation; wherein the spatial variation information comprises a plurality of spatial variation values.

In one possible embodiment, the control method further includes:

responding to a first touch operation aiming at the panoramic image, dividing the panoramic image into a plurality of local detail images for display;

for each local detail image, responding to measurement selection operation for the local detail image, and determining a measurement mode for measuring target parameters of a target construction object in the local detail image;

and measuring the target parameters of the target construction object according to the measurement mode, determining the measurement result of the target parameters of the target construction object, and displaying the measurement result.

In one possible implementation manner, the first touch operation includes a detail amplifying operation and an image dividing operation; the responding to the first touch operation of the panoramic image map divides the panoramic image map into a plurality of local detail images for display, and the responding comprises the following steps:

responding to a detail amplifying operation aiming at the panoramic image map, and determining an amplifying area selected by the detail amplifying operation from the panoramic image map;

displaying the region measurement image of the enlarged region;

responding to the image dividing operation of the region measurement image, and determining a detail display region selected from the region measurement image by the image dividing operation;

And displaying a plurality of local detail images of the detail display area.

In one possible embodiment, the target construction object includes at least one of a designated area, a designated location, and a designated target object;

the measuring mode comprises at least one of size measurement, area measurement, thickness measurement, volume measurement, interval measurement and space measurement;

the target parameters comprise at least one of building boundary red line, building axis deviation, size, length, width, thickness, height, elevation, perpendicularity, levelness, flatness, gradient, area, volume, scaffold horizontal and vertical spacing, support system spacing, upper and lower support size, steel bar diameter, steel bar spacing, pipeline diameter, pipeline length, pipeline trend, welding size, sleeve connection size and lap joint length.

In one possible embodiment, the control method further includes:

responding to a second touch operation aiming at the panoramic image map, and acquiring a CAD design map of the panoramic image map;

determining a space comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map with the CAD design map, and displaying the space comparison result in the graphical user interface; and the space comparison result shows the difference of the anastomosis degree between the panoramic image map and the CAD design map.

In one possible embodiment, the control method further includes:

amplifying the panoramic image map and/or the CAD design map in response to an amplifying touch operation for the panoramic image map and/or the CAD design map; or alternatively, the first and second heat exchangers may be,

and responding to a zoom-out touch operation aiming at the panoramic image map and/or the CAD design map, and zooming out the panoramic image map and/or the CAD design map.

In a possible implementation manner, the determining a spatial comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map and the CAD design map, and displaying the spatial comparison result in the graphical user interface includes:

responding to a first reference point selection operation aiming at the panoramic image map, and determining a first reference point and a second reference point from the panoramic image map;

determining a third reference point and a fourth reference point from the CAD design drawing in response to a second reference point selection operation for the CAD design drawing; the first reference point and the third reference point have a corresponding relation, and the second reference point and the fourth reference point have a corresponding relation;

Determining a comparison mapping relation between the panoramic image map and the CAD design map based on the first reference point, the second reference point, the third reference point and the fourth reference point;

determining a space comparison result between the panoramic image map and the CAD design map by utilizing space measurement information carried by the panoramic image map and space data information carried by the CAD design map according to the comparison mapping relation;

and superposing and displaying the space comparison result in the panoramic image.

In a possible implementation manner, the graphic user interface also displays patrol detail information; the control method further comprises the following steps:

responding to a third touch operation aiming at the inspection detail information, and displaying an abnormal facility image of an abnormal scene facility included in the inspection detail information and a correction facility image obtained after correction of the abnormal scene facility in the graphical user interface;

responding to a fourth touch operation aiming at any abnormal scene facility, and displaying the actual position of the abnormal scene facility in the construction area in the graphical user interface; and/or the number of the groups of groups,

Responding to a fifth touch operation aiming at any abnormal scene facility, and displaying a plurality of historical image graphs of the abnormal scene facility in different historical time periods in the graphical user interface; and determining the facility change information of the abnormal scene facility by comparing the plurality of historical image maps of the abnormal scene facility.

In one possible embodiment, the control method further includes:

acquiring a plurality of panoramic image maps and a BIM model of the construction area;

according to the actual size of the construction area, the multiple panoramic image maps and the BIM model are fused in equal proportion to obtain a twinning demonstration model;

the twinning demonstration model is displayed in the graphical user interface.

The embodiment of the application also provides a control device of the construction area, which is characterized in that a graphical user interface is displayed through the terminal equipment, and a thumbnail image of the construction area related to at least part of target engineering projects is displayed in the graphical user interface; the management and control device includes:

the image display module is used for responding to a first selection operation aiming at any thumbnail image and displaying a panoramic image corresponding to the thumbnail image in the graphical user interface; the panoramic image map displays measurement information of each construction object in the construction area and point location icons of each construction monitoring point location; the point location icon is displayed in a first color;

The display adjustment module is used for aiming at each construction monitoring point, adjusting the first color to a second color if the spatial variation value of any one spatial monitoring parameter between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, and displaying a point position icon of the construction monitoring point with the second color.

In one possible implementation manner, the control device further comprises an information display module, wherein the information display module is used for:

In a possible embodiment, the control device further comprises a measurement result display module, and the measurement result display module is used for:

In one possible implementation manner, the first touch operation includes a detail amplifying operation and an image dividing operation; the measurement result display module is configured to, when responding to a first touch operation for the panoramic image, divide the panoramic image into a plurality of local detail images for display, where the measurement result display module is configured to:

determining a zoom-in area selected by the detail zoom-in operation from the panoramic image in response to the detail zoom-in operation for the panoramic image;

displaying the region measurement image of the enlarged region;

and displaying a plurality of local detail images of the detail display area.

In one possible embodiment, the control device further includes a difference comparison module for:

In one possible embodiment, the control device further comprises a sizing module for:

In one possible implementation manner, when the difference comparison module is configured to determine a spatial comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map and the CAD design map, and display the spatial comparison result in the graphical user interface, the difference comparison module is configured to:

In a possible implementation manner, the graphic user interface also displays patrol detail information; the control device further comprises a rectification detail display module, wherein the rectification detail display module is used for:

In a possible implementation manner, the management and control device further comprises a model fusion module, wherein the model fusion module is used for:

the twinning demonstration model is displayed in the graphical user interface.

The embodiment of the application also provides electronic equipment, which comprises: the system comprises a processor, a memory and a bus, wherein the memory stores machine-readable instructions executable by the processor, the processor and the memory are communicated through the bus when the electronic device runs, and the machine-readable instructions are executed by the processor to execute the steps of the construction area management method.

The embodiment of the application also provides a computer readable storage medium, wherein a computer program is stored on the computer readable storage medium, and the computer program is executed by a processor to execute the steps of the construction area management method.

The method, the device, the electronic equipment and the readable storage medium for managing and controlling the construction area respond to the first selection operation aiming at any thumbnail image and display the thumbnail image corresponding to the panoramic image in the graphical user interface; the panoramic image map is displayed with point icons of construction monitoring points related to construction areas corresponding to the panoramic image map; the point location icon is displayed in a first color; for each construction monitoring point, if the spatial variation value of any one of the spatial monitoring parameters between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, adjusting the first color to a second color, and displaying the point icons of the construction monitoring point in the second color. Therefore, the construction area related to the target engineering project can be remotely, visually, fully and digitally controlled, construction details of the construction position with the quality hidden trouble can be intuitively observed, and further, the construction position with the quality hidden trouble can be timely positioned.

In order to make the above objects, features and advantages of the present application more comprehensible, preferred embodiments accompanied with figures are described in detail below.

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 application and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a flowchart of a method for controlling a construction area according to an embodiment of the present application;

FIG. 2 is a diagram of a graphical user interface according to an embodiment of the present application;

FIG. 3 is a diagram illustrating a second graphical user interface according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a control device for a construction area according to an embodiment of the present application;

FIG. 5 is a second schematic structural diagram of a control device for a construction area according to an embodiment of the present application;

fig. 6 is a schematic structural 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 apparent, 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 is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. The components of the embodiments of the present application 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 application, as presented in the figures, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. Based on the embodiments of the present application, every other embodiment obtained by a person skilled in the art without making any inventive effort falls within the scope of protection of the present application.

According to research, the traditional quality safety supervision work and construction progress data acquisition work mainly depend on manpower, but the construction period of building construction is generally long, and the construction process is influenced by various factors, and the problems of hysteresis, error easiness and the like exist in quality supervision and data recording by staff, so that the progress management and quality management of construction projects cannot be mastered in time, the progress of construction is easy to slow, quality guarantee and quality guarantee are difficult to achieve, and the engineering quality and safety construction are not guaranteed.

Based on the above, the embodiment of the application provides a control method for a construction area, which can remotely, visually, fully and digitally control the construction area related to a target engineering project, can intuitively observe construction details of a construction position with quality hidden danger, and further can timely locate the construction position with the quality hidden danger.

Referring to fig. 1, fig. 1 is a flowchart of a method for controlling a construction area according to an embodiment of the present application. Displaying a graphic user interface through terminal equipment, wherein at least part of thumbnail image of a construction area related to a target engineering project is displayed in the graphic user interface; as shown in fig. 1, the method for controlling a construction area provided by the embodiment of the present application includes:

S101, responding to a first selection operation aiming at any thumbnail image, and displaying a panoramic image corresponding to the thumbnail image in the graphical user interface.

S102, aiming at each construction monitoring point, if the spatial variation value of any one spatial monitoring parameter between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, adjusting the first color into a second color, and displaying a point position icon of the construction monitoring point in the second color.

According to the construction area management and control method provided by the embodiment of the application, thumbnail images of the construction areas related to the target engineering project are provided for a user in a graphical user interface, and the user can check the panoramic image of the construction area corresponding to any thumbnail image by selecting the thumbnail image; and displaying the point position icons of each construction monitoring point position in the panoramic image, and when any spatial variation value of any construction monitoring point position exceeds a preset variation threshold, namely when any construction monitoring point position has a quality hidden trouble, achieving the purpose of warning a user by changing the color of the point position icons of the construction monitoring point position. Therefore, the user can realize comprehensive monitoring on each construction area, and can intuitively observe the construction position with the hidden quality trouble, and further, the construction position with the hidden quality trouble can be timely positioned.

When a user monitors each construction area related to a target engineering project, related information such as a panoramic image of the construction area shot by using the panoramic imaging range finding camera can be opened through corresponding software, and the related information is displayed in a graphical user interface so that the user can know the construction condition of the construction area.

In order to facilitate the user to check the construction conditions of different construction periods or different construction areas, thumbnail image images of a plurality of construction areas can be displayed in a graphical user interface, and further, the user can check the construction conditions of different construction periods or different construction areas by selecting corresponding thumbnail image images according to requirements.

In step S101, a plurality of thumbnail images are displayed in the gui, and the constructor may apply a first selection operation to any one of the thumbnail images, determine the thumbnail image selected by the first selection operation, and display a panoramic image corresponding to the thumbnail image selected by the constructor in the gui.

Here, scene detail information matched with each thumbnail image is also displayed in the graphical user interface; specifically, the scene detail information includes at least one of: time, weather, number of piles, elevation, construction instruction, coordinates, cost, number of workers on working face and inspection information.

Here, the plurality of thumbnail images displayed in the gui may be thumbnail images of the same construction area at different construction times; alternatively, the thumbnail images of different construction areas at the same construction time can be obtained; alternatively, thumbnail images of different construction times in different construction areas may be obtained.

For example, 6 thumbnail images, i.e., thumbnail images 1 to 6, are displayed in the gui, wherein the thumbnail images 1 to 6 may be monitoring images of the construction area a from 1 month to 6 months, respectively; alternatively, the thumbnail images 1 to 6 may be the monitoring images of the construction areas a to F, respectively; still alternatively, the thumbnail images 1 to 2 are monitoring images of the construction area a from 4 months to 6 months, the thumbnail images 3 to 4 are monitoring images of the construction area B from 4 months to 6 months, and the thumbnail images 5 to 6 are monitoring images of the construction area C from 4 months to 6 months.

In the scheme provided by the application, the response to the first selection operation for any thumbnail image can be specifically that when a user touches any thumbnail image, a selection instruction for issuing the thumbnail image can be triggered; the user can touch the thumbnail image and/or preset a selection instruction of the thumbnail image by the combined key; specifically, the player can touch the thumbnail image through fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The first selection operation includes a click operation, a slide operation, a double click operation, a long press operation, and the like.

The panoramic image is a panoramic digital image of the construction area in a target time period; measuring information of each construction object in the construction area and point location icons of each construction monitoring point location are displayed in the panoramic image map; and displaying the point location icon in a first color.

Here, there are a plurality of construction monitoring points that need to carry out quality hidden danger monitoring in different construction areas of a target engineering project, that is, constructors need to monitor whether quality hidden danger exists in each construction monitoring point, so that constructors can intuitively see the positions of each construction monitoring point, and point icons corresponding to each construction monitoring point can be displayed in a panoramic image map in a first color.

In addition, in order to be convenient for constructors find the construction monitoring point position with the quality hidden trouble from a plurality of construction monitoring point positions, the constructors can timely find the construction monitoring point position with the quality hidden trouble by changing the display color of the point position icons of the construction monitoring point position.

For example, when the construction monitoring point does not have a quality hidden trouble, the point icon corresponding to the construction monitoring point may be displayed as "green"; and when the construction monitoring point position has a quality hidden trouble, the display color of the point position icon corresponding to the construction monitoring point position is changed, and the point position icon corresponding to the construction monitoring point position is displayed as yellow so as to reach the purpose of warning constructors.

In step S102, for each construction monitoring point, monitoring of construction quality of the construction monitoring point may be achieved by comparing current construction details and historical construction details of the construction monitoring point; specifically, the quality of the construction monitoring point location can be monitored by comparing the current construction details of the construction monitoring point location with the spatial variation values of various spatial monitoring parameters in the historical construction details in the period of time; if the spatial variation value of any one of the spatial monitoring parameters between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold value in the period of time, the condition that the construction monitoring point has a quality hidden trouble can be indicated, at the moment, the display color of the point position icon corresponding to the construction monitoring point can be adjusted from the first color to the second color, and the point position icon of the construction monitoring point with the quality hidden trouble is displayed in the panoramic image picture in the second color.

Here, in order to facilitate the user to check the change details of each spatial monitoring parameter of each construction monitoring point, spatial change information of the construction monitoring point selected by the constructor may also be displayed in the graphical user interface according to the relevant operation of the constructor.

In one embodiment, the method of managing further comprises: and responding to a second selection operation of the point position icon of any construction monitoring point position, and displaying the space change information between the historical construction details and the current construction details of the target monitoring point position selected by the second selection operation.

In the step, in response to a second selection operation applied by constructors to point location icons of any construction monitoring point location, determining a target monitoring point location corresponding to the point location icon selected by the constructors through the second selection operation, and displaying space change information between historical construction details and current construction details of the target monitoring point location selected by the second selection operation on a graphical user interface or a panoramic image map; wherein the spatial variation information comprises a plurality of spatial variation values.

Referring to fig. 2, fig. 2 is a schematic diagram of a graphical user interface according to an embodiment of the present application; as shown in fig. 2, the point icons 2c-1 of the construction monitoring point (CJ 1) 2b-1, the point icon 2c-2 of the construction monitoring point (CJ 2) 2b-2, the point icon 2c-3 of the construction monitoring point (CJ 3) 2b-3, and the point icon 2c-4 of the construction monitoring point (CJ 4) 2b-4 are displayed in the graphical user interface 2a, and the constructor may display spatial variation information 2d between the historical construction details and the current construction details of the construction monitoring point 2b-4 (i.e., the target monitoring point) in the graphical user interface 2a, wherein the spatial variation information 2d includes the historical construction image 2d-1 of the construction monitoring point 2b-4, the current construction image 2d-2, the horizontal displacement cumulative variation curve 2d-3, the horizontal displacement variation rate curve 2d-4, the vertical displacement cumulative variation curve 2d-5, the vertical displacement variation rate curve 2d-6, and the like.

The spatial variation value includes a variation value of a displacement variation parameter (including a horizontal displacement variation parameter, for example, a horizontal displacement cumulative variation curve and a horizontal displacement variation rate curve; and also includes a vertical displacement variation parameter, for example, a vertical displacement cumulative variation curve and a vertical displacement variation rate curve) of each target point of the construction monitoring point, a variation value of a falling parameter (including a horizontal falling variation parameter, for example, a horizontal falling cumulative variation curve and a horizontal falling variation rate curve; and also includes a vertical falling variation parameter, for example, a vertical falling cumulative variation curve and a vertical falling variation rate curve), and a shape variation parameter.

The construction personnel have the requirement of measuring building materials such as formwork support ground rods, steel bars, pipelines and the like in the construction environment, and if the construction personnel personally take the measurement in the construction environment, the construction personnel are relatively dangerous; therefore, the application provides a possibility for a constructor to realize the measurement of the relevant parameters of the target construction object in the construction area through the displayed panoramic image.

In the scheme provided by the application, the second selection operation of the point position icon aiming at any construction monitoring point position is responded, specifically, when a user touches the point position icon of any construction monitoring point position, a selection instruction for issuing the construction monitoring point position can be triggered; the user can issue a selection instruction of the construction monitoring point position through touch control of the point position icon of any construction monitoring point position and/or a preset combination key; specifically, the player can construct the point location icon of the monitoring point location through touch control of fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The second selection operation includes a click operation, a slide operation, a double click operation, a long press operation, and the like.

In one embodiment, the method of managing further comprises:

and step 1, responding to a first touch operation aiming at the panoramic image map, and dividing the panoramic image map into a plurality of local detail images for display.

In the step, a constructor can apply a first touch operation to the panoramic image displayed in the graphical user interface to display the panoramic image in the form of a plurality of local detail images; here, the details displayed by the plurality of local detail images may be detail images of all the details included in the panoramic image, or may be detail images of local details included in a certain area in the panoramic image.

In the scheme provided by the application, the response to the first touch operation of the panoramic image map can be specifically that when a user touches the panoramic image map, a division instruction of the panoramic image map can be triggered; the user can issue a division instruction of the panoramic image through touching the panoramic image and/or presetting a combined key; specifically, the player can touch the panoramic image map through fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The first touch operation comprises clicking operation, sliding operation, double-clicking operation, long-press operation and the like.

In one embodiment, the first touch operation includes a detail amplifying operation and an image dividing operation; the step 1 comprises the following steps: and step 11, responding to the detail amplifying operation aiming at the panoramic image map, and determining the amplifying area selected by the detail amplifying operation from the panoramic image map.

In the step, a constructor can apply detail amplifying operation to the panoramic image displayed in the graphical user interface, and at the moment, an amplifying area with amplifying requirements of the constructor can be determined according to the touch position of the detail amplifying operation in the panoramic image.

In the scheme provided by the application, the response to the detail amplifying operation for the panoramic image map can be specifically that when a user touches an amplifying control of the detail amplifying operation, a local amplifying instruction for issuing the panoramic image map can be triggered; the user can issue a local amplifying instruction of the panoramic image through an amplifying control and/or a preset combined key of the touch detail amplifying operation; specifically, the player can zoom in on the zoom-in control operated by the touch details such as fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The detail amplifying operation includes clicking operation, sliding operation, double clicking operation, long pressing operation, and the like.

And step 12, displaying the region measurement image of the enlarged region.

In the step, after an enlarged area with an enlarged requirement of a constructor is determined, an area measurement image of the enlarged area can be displayed in a graphical user interface; the area measurement image of the enlarged area may be displayed superimposed on the panoramic image, and may be determined according to the specific actual situation, without limitation.

And step 13, responding to the image dividing operation of the region measurement image, and determining a detail display region selected from the region measurement image by the image dividing operation.

In the step, for the region measurement image, the constructor can apply image division operation for the region measurement image, and the detail display region with detail display requirements of the constructor can be determined according to the touch position of the image division operation in the region measurement image.

In the scheme provided by the application, the response to the image dividing operation of the region measurement image can be specifically that when a user touches a dividing control of the image dividing operation, a dividing instruction of the region measurement image can be triggered; the user can issue a dividing instruction of the region measurement image through a dividing control of touch image dividing operation and/or a preset combination key; specifically, the player can divide the division control operated by the touch control images such as fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The image dividing operation includes clicking operation, sliding operation, double clicking operation, long pressing operation and the like.

And 14, displaying a plurality of local detail images of the detail display area.

Displaying a plurality of local detail images of the detail display area in a graphical user interface; here, the plurality of partial detail images can clearly show all construction details included in the detail display area; correspondingly, a plurality of local detail images of the detail display area can be displayed in a graphical user interface; the plurality of local detail images of the detail display area can be displayed on the panoramic image in a superimposed manner, and the detail display area can be determined according to actual conditions and is not limited herein.

And 2, for each local detail image, determining a measurement mode for measuring the target parameter of the target construction object in the local detail image in response to the measurement selection operation for the local detail image.

In this step, for each local detail image displayed in the gui, the constructor may apply a measurement selection operation with respect to the local detail image, and determine a target construction object for which the constructor desires to perform the measurement of the relevant parameter and a measurement manner for measuring a target parameter of the target construction object through the measurement selection operation.

The target construction object comprises at least one of a designated area, a designated position and a designated target object; the measuring mode comprises at least one of size measurement, area measurement, thickness measurement, volume measurement, interval measurement and space measurement;

Illustratively, a constructor can select to measure the area of a designated area through measurement selection operation; alternatively, diameter measurements are made of specified settings (e.g., rebar, steel pipe); or alternatively, spacing measurements may be made on a given setting (e.g., a formwork support ground bar).

Referring to fig. 3, fig. 3 is a second diagram of a graphical user interface according to an embodiment of the application. As shown in fig. 3, a local detail image 3b is displayed in the graphical user interface 3a, in response to a measurement selection operation applied by a constructor to any two points 3c-1 to 3c-2 in the local detail image 3b, it is determined that a distance measurement needs to be performed on an actual distance value between any two points 3c-1 to 3c-2, it is determined that the actual distance value before any two points 3c-1 to 3c-2 is 30cm, and an actual distance value 3d (i.e., 30 cm) is displayed in the local detail image 3 b.

In the scheme provided by the application, the response to the measurement selection operation for the local detail image can be specifically that when a user touches a measurement control of the measurement selection operation, a measurement instruction of a target construction object in the local detail image can be triggered; the user can select the measurement control of the operation and/or preset the measurement instruction of the target construction object through touch measurement; specifically, the player can select the measurement control of the operation through touch measurement such as a finger, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The measurement selection operation includes operations such as a single click operation, a slide operation, a double click operation (two-point touch operation), a three-point touch operation, a multi-point touch operation, and a long press operation.

Illustratively, a constructor can select a designated area for which target parameter measurement is required through a double-click operation; alternatively, the constructor may select a specified target object, etc., for which target parameter measurement is required, through a click operation.

And 3, measuring the target parameters of the target construction object according to the measurement mode, determining the measurement result of the target parameters of the target construction object, and displaying the measurement result.

In the step, the determined target parameters of the target construction object are measured according to the determined measurement mode, measurement results (such as the area of a designated area, the diameter of a reinforcing steel bar, the diameter of a steel pipe, the distance between formwork support ground rods and the like) of the target parameters of the target construction object are obtained, and the measurement results of the target construction object are displayed in a graphical user interface so as to be convenient for constructors to check.

In order to intuitively and accurately check the deviation condition between the actual size and the design size of the construction area, the CAD design drawing aiming at the construction area before construction can be compared with the panoramic image drawing acquired by the panoramic imaging range finding camera in the construction process.

In one embodiment, the method of managing further comprises: responding to a second touch operation aiming at the panoramic image map, and acquiring a CAD design map of the panoramic image map; and determining a space comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map with the CAD design map, and displaying the space comparison result in the graphical user interface.

In the step, a CAD design drawing of a construction area related to the panoramic image is obtained in response to a second touch operation applied by a constructor aiming at the panoramic image; determining a space comparison result between the panoramic image map and the CAD design map of the construction area by comparing the panoramic image map with the CAD design map; the space comparison result shows the difference of the coincidence degree between the panoramic image map and the CAD design map; namely, the deviation between the actual size and the design size of the construction area.

The difference in fitness indicates the degree of deviation between the panoramic image map and the CAD design map.

In the scheme provided by the application, the response to the second touch operation for the panoramic image map can be specifically that when a user touches the panoramic image map, an acquisition instruction for issuing a CAD design map can be triggered; the user can send an acquisition instruction of the CAD design drawing through the touch panoramic image drawing and/or a preset combination key; specifically, the player can touch the panoramic image map through fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The second touch operation includes at least one of click operation, sliding operation, double click operation, long press operation, and the like.

Further, considering that the panoramic image and the CAD design displayed in the gui are different in terms of display size, display position, and the like, the problem of dislocation display between the panoramic image and the CAD design is easy to occur, so that a constructor cannot clearly understand the content displayed in the gui, and cannot compare the panoramic image and the CAD design under the condition that the mapping relationship between the panoramic image and the CAD design cannot be known, thereby providing a possibility of adjusting parameters such as display size, display position, and the like of the panoramic image and the CAD design for the constructor on the basis.

In one embodiment, the determining a spatial comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map and the CAD design map, and displaying the spatial comparison result in the graphical user interface includes:

and a step a, responding to a first reference point selection operation aiming at the panoramic image map, and determining a first reference point and a second reference point from the panoramic image map.

In response to a first reference point selection operation by a constructor with respect to a panoramic image displayed in a graphical user interface, a first reference point and a second reference point that can be used to determine a comparison mapping relationship between the panoramic image and a CAD design are determined from the panoramic image.

The first reference point selection operation may be a double click operation, where a first click position of the double click operation in the panoramic image is a first reference point, and a second click position of the double click operation in the panoramic image is a second reference point.

Here, in the embodiment of the present application, two reference points are determined by a double click operation as an example for explanation, and in other embodiments, the first reference point selecting operation may further include a single click operation, where two reference points are selected by the double click operation; the first reference point selection operation may also be a three-point selection operation, in which three reference points are selected; the first reference point selection operation may also be a multi-point selection operation, selecting a plurality of reference points.

And b, responding to a second reference point selection operation aiming at the CAD design drawing, and determining a third reference point and a fourth reference point from the CAD design drawing.

In response to a second reference point selection operation by a constructor for the CAD design drawing displayed in the graphical user interface, determining a third reference point and a fourth reference point which can be used for determining a comparison mapping relation between the panoramic image drawing and the CAD design drawing from the CAD design drawing; the third reference point of the CAD design drawing corresponds to the first reference point in the panoramic image drawing, namely when the panoramic influence drawing and the CAD design drawing are displayed in a superimposed mode, the display position of the first reference point coincides with the display position of the third reference point; and the fourth reference point of the CAD design drawing corresponds to the second reference point in the panoramic image drawing, namely, when the panoramic influence drawing is displayed in a superposition manner with the CAD design drawing, the display position of the second reference point coincides with the display position of the fourth reference point.

The second reference point selection operation may be a double-click operation, where a first click position of the double-click operation in the CAD design is a third reference point, and a second click position of the double-click operation in the CAD design is a fourth reference point.

Here, in the embodiment of the present application, two reference points are determined by a double click operation as an example, and in other embodiments, the second reference point selecting operation may further include a single click operation, where two reference points are selected by the double click operation; the second reference point selection operation may also be a three-point selection operation, in which three reference points are selected; the second reference point selection operation may also be a multi-point selection operation, selecting a plurality of reference points.

And c, determining a comparison mapping relation between the panoramic image map and the CAD design map based on the first reference point, the second reference point, the third reference point and the fourth reference point.

Determining a comparison mapping relation between the panoramic image map and the CAD design map according to the positions of the first reference point and the second reference point in the panoramic influence map and the positions of the third reference point and the fourth reference point in the CAD design map; the corresponding relation between the panoramic image map and other positions in the CAD design map can be determined through the corresponding relation between the first reference point and the third reference point and the corresponding relation between the second reference point and the fourth reference point, so that the comparison mapping relation between the panoramic image map and the CAD design map is determined.

Step d, determining a space comparison result between the panoramic image map and the CAD design map by using space measurement information carried by the panoramic image map and space data information carried by the CAD design map according to the comparison mapping relation;

in the step, according to the determined comparison mapping relation, the space measurement information carried by the panoramic image map is corresponding to the space data information carried by the CAD design map, and the space comparison result of the construction area related to the panoramic image map and the CAD design map is determined by comparing the space measurement information carried by the panoramic image map with the space data information carried by the CAD design map.

And e, superposing and displaying the space comparison result in the panoramic image.

Here, the spatial comparison result may also be displayed in the gui alone, and may be determined according to a specific practical situation, which is not limited herein.

In the construction process of the construction area related to the target engineering project, if a problem exists in a construction site, constructors can rectify the encountered construction problem and record the rectified facility image after rectifying the construction problem; therefore, after recording, the image of the whole facility can be checked.

In order to facilitate the constructor to view the details in the panoramic image map and/or the CAD design map, the present embodiment provides the constructor with the possibility to zoom in and out the panoramic image map and/or the CAD design map.

In one embodiment, the method of managing further comprises:

and in response to the zooming-in touch operation for the panoramic image map and/or the CAD design map, zooming in the panoramic image map and/or the CAD design map.

In the step, in response to the amplifying touch operation applied to the panoramic image map and/or the CAD design map by a constructor, amplifying the panoramic image map and/or the CAD design map, and amplifying a target area selected by the touch operation in the panoramic image map and/or the CAD design map; and displaying the enlarged target area in the graphical user interface.

In the scheme provided by the application, the response to the amplifying touch operation of the panoramic image map and/or the CAD design map can be specifically that when a user touches the corresponding control for amplifying touch operation, an amplifying instruction can be issued; the user can give an amplifying instruction through the corresponding control and/or the preset combined key of the touch amplifying touch operation; specifically, the player can enlarge the corresponding control by touch control operations such as fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The amplifying touch operation includes any one of clicking operation, sliding operation, double-clicking operation, long-press operation and the like.

Or, in response to a zoom-out touch operation for the panoramic image map and/or the CAD design map, zooming out the panoramic image map and/or the CAD design map.

In the step, responding to the shrinking touch operation applied by constructors to the panoramic image map and/or the CAD design map, shrinking the panoramic image map and/or the CAD design map, and shrinking the display size of the panoramic image map and/or the CAD design map in a graphical user interface; and displaying the zoomed panoramic image map and/or CAD design map in the graphical user interface.

In the scheme provided by the application, the response to the zoom-out touch operation of the panoramic image map and/or the CAD design map can be specifically that when a user touches a corresponding control for the zoom-out touch operation, a zoom-out instruction can be issued; the user can execute the zoom-out instruction through the corresponding control and/or the preset combined key by the touch-out touch operation; specifically, the player can zoom out the corresponding control by touching with fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The zoom-out touch operation includes any one of click operation, slide operation, double click operation, long press operation, and the like.

In one embodiment, the graphical user interface also displays inspection details; the control method further comprises the following steps: and responding to a third touch operation aiming at the inspection detail information, and displaying an abnormal facility image of an abnormal scene facility included in the inspection detail information and a correction facility image obtained after correction of the abnormal scene facility in the graphical user interface.

In the step, the inspection detail information is displayed in a graphical user interface, and an abnormal facility image of an abnormal scene facility included in the inspection detail information is displayed in the graphical user interface in response to a third touch operation of constructors on the inspection detail information; meanwhile, displaying in a graphical user interface, and recording obtained images of the rectifying facilities after rectifying the abnormal scene facilities by constructors.

In the scheme provided by the application, the response to the third touch operation for the inspection detail information can be specifically that when a user touches the corresponding control of the inspection detail information, a viewing instruction of the inspection detail information can be triggered; the user can issue a checking instruction of the inspection detail information through a touch inspection detail information corresponding control and/or a preset combination key; specifically, the player can patrol the detailed information corresponding control through the touch control of fingers, a mouse and the like; or through preset combination keys in the keyboard, for example, ctrl keys, alt keys, a keys and other keys in the keyboard, the preset keys can be set manually according to the requirements of users.

The third touch operation includes clicking operation, sliding operation, double-clicking operation, long-press operation, and the like.

In response to a fourth touch operation for any one of the abnormal scene facilities, the actual position of the abnormal scene facility in the construction area is displayed in the graphical user interface.

In this step, in response to a fourth touch operation by the constructor with respect to any abnormal scene facility, the actual position of the abnormal scene facility in the construction area is displayed in the graphical user interface, so that the constructor can go to the actual position to view the abnormal scene facility in the subsequent process.

And/or responding to a fifth touch operation aiming at any abnormal scene facility, and displaying a plurality of historical image graphs of the abnormal scene facility in different historical time periods in the graphical user interface; and determining the facility change information of the abnormal scene facility by comparing the plurality of historical image maps of the abnormal scene facility.

In the step, responding to fifth touch operation of a constructor on any abnormal scene facility, and displaying a plurality of historical image graphs acquired by the abnormal scene facility in different historical time periods in a graphical user interface; and determining facility change information of the abnormal scene facility in the construction process by comparing a plurality of historical image maps of the abnormal scene facility in different historical time periods.

The facility change information indicates the change condition of the abnormal scene facility in the construction process; specifically, the facility change information includes information such as a change image, a change parameter, and a change trend of the abnormal scene facility.

Furthermore, in order to facilitate completion acceptance of the target engineering project, multiple panoramic image maps of the construction area related to the target engineering project and the BIM model can be visually fused and displayed, so that reference and guidance are provided for subsequent acceptance links.

In one embodiment, the method of managing further comprises: acquiring a plurality of panoramic image maps and a BIM model of the construction area; according to the actual size of the construction area, the multiple panoramic image maps and the BIM model are fused in equal proportion to obtain a twinning demonstration model; the twinning demonstration model is displayed in the graphical user interface.

In the step, BIM models corresponding to Zhang Quanjing image graphs of different construction time periods of a construction area and target engineering projects are obtained; and fusing the construction area with the BIM model according to the actual size of the construction area, the acquisition time sequence of the panoramic image maps or the spatial corresponding positions of the panoramic image maps.

For example, when fusion is performed according to the acquisition time sequence of the plurality of panoramic image maps, each panoramic image map is ordered according to the corresponding acquisition time sequence of each panoramic image map, and then each panoramic image map is sequentially overlapped into the BIM model from bottom to top according to the acquisition time sequence, so that the twin demonstration module is obtained.

When fusion is carried out according to the space corresponding positions of the panoramic image, determining the position information of each panoramic image in the BIM according to the three-dimensional coordinate information carried by the panoramic image; and then sequentially adding each panoramic image into the BIM according to the position information of each panoramic image in the BIM so as to obtain a twinning demonstration model, displaying the whole construction process of the target engineering project, and truly tracing the actual construction condition of the target engineering project.

It should be noted that the BIM model refers to a three-dimensional model of a building corresponding to the building in the target engineering project. The twin demonstration model refers to a demonstration model obtained by carrying out equal proportion fusion on the BIM model and the panoramic image map.

According to the construction area management and control method provided by the embodiment of the application, a first selection operation for any thumbnail image is responded, and a panoramic image corresponding to the thumbnail image is displayed in the graphical user interface; the panoramic image map is displayed with point icons of construction monitoring points related to construction areas corresponding to the panoramic image map; the point location icon is displayed in a first color; for each construction monitoring point, if the spatial variation value of any one of the spatial monitoring parameters between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, adjusting the first color to a second color, and displaying the point icons of the construction monitoring point in the second color. Therefore, the construction area related to the target engineering project can be remotely, visually, fully and digitally controlled, construction details of the construction position with the quality hidden trouble can be intuitively observed, and further, the construction position with the quality hidden trouble can be timely positioned.

Referring to fig. 4 and 5, fig. 4 is a schematic structural diagram of a control device for a construction area according to an embodiment of the present application, and fig. 5 is a schematic structural diagram of a second control device for a construction area according to an embodiment of the present application. Displaying a graphic user interface through terminal equipment, wherein at least part of thumbnail image of a construction area related to a target engineering project is displayed in the graphic user interface; as shown in fig. 4, the management apparatus 400 includes:

an image display module 410, configured to display, in response to a first selection operation for any thumbnail image, a panoramic image corresponding to the thumbnail image in the graphical user interface; the panoramic image map displays measurement information of each construction object in the construction area and point location icons of each construction monitoring point location; the point location icon is displayed in a first color;

the display adjustment module 420 is configured to adjust the first color to a second color for each construction monitoring point, and display a point icon of the construction monitoring point with the second color if a spatial variation value of any one of spatial monitoring parameters between current construction details and historical construction details of the construction monitoring point exceeds a preset variation threshold.

Further, as shown in fig. 5, the management and control device 400 further includes an information display module 430, where the information display module 430 is configured to:

Further, as shown in fig. 5, the control device 400 further includes a measurement result display module 440, where the measurement result display module 440 is configured to:

Further, as shown in fig. 5, the first touch operation includes a detail amplifying operation and an image dividing operation; the measurement result display module 440 is configured to, in response to a first touch operation for the panoramic image, divide the panoramic image into a plurality of local detail images for display, where the measurement result display module 440 is configured to:

displaying the region measurement image of the enlarged region;

and displaying a plurality of local detail images of the detail display area.

Further, the target construction object includes at least one of a designated area, a designated location, and a designated target object;

Further, as shown in fig. 5, the control device 400 further includes a difference comparison module 450, where the difference comparison module 450 is configured to:

Further, as shown in fig. 5, the management apparatus 400 further includes a resizing module 460, where the resizing module 460 is configured to:

Further, when the difference comparison module 450 is configured to determine a spatial comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map and the CAD design map, and display the spatial comparison result in the gui, the difference comparison module 450 is configured to:

Further, as shown in fig. 5, the graphical user interface also displays inspection details; the management and control device 400 further includes a modification detail display module 470, where the modification detail display module 470 is configured to:

Further, as shown in fig. 5, the management apparatus 400 further includes a model fusion module 480, where the model fusion module 480 is configured to:

the twinning demonstration model is displayed in the graphical user interface.

The control device for the construction area provided by the embodiment of the application responds to a first selection operation aiming at any thumbnail image, and displays the thumbnail image corresponding to the panoramic image in the graphical user interface; the panoramic image map is displayed with point icons of construction monitoring points related to construction areas corresponding to the panoramic image map; the point location icon is displayed in a first color; for each construction monitoring point, if the spatial variation value of any one of the spatial monitoring parameters between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, adjusting the first color to a second color, and displaying the point icons of the construction monitoring point in the second color. Therefore, the construction area related to the target engineering project can be remotely, visually, fully and digitally controlled, construction details of the construction position with the quality hidden trouble can be intuitively observed, and further, the construction position with the quality hidden trouble can be timely positioned.

Referring to fig. 6, fig. 6 is a schematic structural diagram of an electronic device according to an embodiment of the application. As shown in fig. 6, the electronic device 600 includes a processor 610, a memory 620, and a bus 630.

The memory 620 stores machine-readable instructions executable by the processor 610, when the electronic device 600 is running, the processor 610 and the memory 620 communicate through the bus 630, and when the machine-readable instructions are executed by the processor 610, the steps of the method for controlling a construction area in the method embodiment shown in fig. 1 can be executed, and a specific implementation manner may refer to the method embodiment and will not be described herein.

The embodiment of the present application further provides a computer readable storage medium, where a computer program is stored, and when the computer program is executed by a processor, the steps of the method for controlling a construction area in the method embodiment shown in fig. 1 may be executed, and a specific implementation manner may refer to the method embodiment and will not be described herein.

It will be clear to those skilled in the art that, for convenience and brevity of description, specific working procedures of the above-described systems, apparatuses and units may refer to corresponding procedures in the foregoing method embodiments, and are not repeated herein.

In the several embodiments provided by the present application, it should be understood that the disclosed systems, devices, and methods may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the division of the 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 on 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 of 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 non-volatile computer readable storage medium executable by a processor. Based on this 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, comprising several instructions for causing a computer device (which may be a personal computer, a server, a network device, etc.) to perform all or part of the steps of the method according to 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 (Random Access Memory, RAM), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

Finally, it should be noted that: the above examples are only specific embodiments of the present application, and are not intended to limit the scope of the present application, but it should be understood by those skilled in the art that the present application is not limited thereto, and that the present application is described in detail with reference to the foregoing examples: any person skilled in the art may modify or easily conceive of the technical solution described in the foregoing embodiments, or perform equivalent substitution of some of the technical features, while remaining within the technical scope of the present disclosure; such modifications, changes or substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present application, and are intended to be included in the scope of the present application. Therefore, the protection scope of the application is subject to the protection scope of the claims.

Claims

1. A control method of a construction area is characterized in that a graphic user interface is displayed through terminal equipment, and a thumbnail image of the construction area related to at least part of target engineering projects is displayed in the graphic user interface; the control method comprises the following steps:

for each construction monitoring point, if the spatial variation value of any one of the spatial monitoring parameters between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, adjusting the first color to a second color, and displaying a point icon of the construction monitoring point with the second color;

the control method further comprises the following steps:

responding to a second selection operation of a point position icon aiming at any construction monitoring point position, and displaying space change information between historical construction details and current construction details of a target monitoring point position selected by the second selection operation; wherein the spatial variation information comprises a plurality of spatial variation values;

the control method further comprises the following steps:

responding to a detail amplifying operation aiming at the panoramic image map, and determining an amplifying area selected by the detail amplifying operation from the panoramic image map; displaying the region measurement image of the enlarged region; responding to the image dividing operation of the region measurement image, and determining a detail display region selected from the region measurement image by the image dividing operation; displaying a plurality of local detail images of the detail display area; for each local detail image, responding to measurement selection operation for the local detail image, and determining a measurement mode for measuring target parameters of a target construction object in the local detail image; measuring the target parameters of the target construction object according to the measurement mode, determining the measurement result of the target parameters of the target construction object, and displaying the measurement result;

The target construction object comprises at least one of a designated area, a designated position and a designated target object; the measuring mode comprises at least one of size measurement, area measurement, thickness measurement, volume measurement, interval measurement and space measurement; the target parameters comprise at least one of building boundary red line, building axis deviation, size, length, width, thickness, height, elevation, perpendicularity, levelness, flatness, gradient, area, volume, scaffold horizontal and vertical spacing, support system spacing, upper and lower support size, steel bar diameter, steel bar spacing, pipeline diameter, pipeline length, pipeline trend, welding size, sleeve connection size and lap joint length.

2. The method of controlling according to claim 1, further comprising:

3. The method of controlling according to claim 2, further comprising:

4. The method according to claim 2, wherein the determining a spatial comparison result between the panoramic image map and the CAD design map by comparing the panoramic image map and the CAD design map, and displaying the spatial comparison result in the gui, includes:

5. The method of claim 1, wherein the graphical user interface further displays inspection details; the control method further comprises the following steps:

6. The method of controlling according to claim 1, further comprising:

the twinning demonstration model is displayed in the graphical user interface.

7. The control device of the construction area is characterized in that a graphic user interface is displayed through terminal equipment, and a thumbnail image of the construction area related to at least part of target engineering projects is displayed in the graphic user interface; the management and control device includes:

The display adjustment module is used for aiming at each construction monitoring point, adjusting the first color to a second color if the spatial variation value of any one spatial monitoring parameter between the current construction details and the historical construction details of the construction monitoring point exceeds a preset variation threshold, and displaying a point icon of the construction monitoring point with the second color;

the control device further comprises an information display module, wherein the information display module is used for:

the control device further comprises a measurement result display module, wherein the measurement result display module is used for:

determining a zoom-in area selected by the detail zoom-in operation from the panoramic image in response to the detail zoom-in operation for the panoramic image; displaying the region measurement image of the enlarged region; responding to the image dividing operation of the region measurement image, and determining a detail display region selected from the region measurement image by the image dividing operation; displaying a plurality of local detail images of the detail display area; for each local detail image, responding to measurement selection operation for the local detail image, and determining a measurement mode for measuring target parameters of a target construction object in the local detail image; measuring the target parameters of the target construction object according to the measurement mode, determining the measurement result of the target parameters of the target construction object, and displaying the measurement result;

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 via said bus when the electronic device is running, said machine readable instructions when executed by said processor performing the steps of the method of managing a construction area 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 method for controlling a construction area according to any one of claims 1 to 6.