CN116703130B - Engineering measurement wisdom planning design management system - Google Patents

Abstract

The invention belongs to the technical field of engineering measurement management, in particular to an engineering measurement intelligent planning design management system, which comprises a server, a port registration module, a terminal allocation selection module, a visual display module and a visual regulation decision module; according to the invention, all registered terminals are subjected to preliminary analysis and screening out the front-end terminals, all the front-end terminals are subjected to sequencing selection analysis to determine the measurement planning terminals, the optimal processing terminals are judged and screened out through multi-step selection analysis, automatic and reasonable selection of the processing terminals is realized, the processing efficiency of the measurement engineering planning design is ensured, meanwhile, the processing effect is improved, the specific situation of the engineering measurement planning scheme is intuitively displayed through visual display of the measurement planning scheme, and the visual display module is subjected to display regulation analysis to judge whether corresponding regulation instructions are generated or not, so that the automatic adaptive regulation of the display process of the visual display module is realized.

Description

Engineering measurement wisdom planning design management system

Technical Field

The invention relates to the technical field of engineering measurement management, in particular to an intelligent planning, designing and managing system for engineering measurement.

Background

The engineering measurement mainly refers to the general name of building engineering measurement, bridge engineering measurement, hydraulic engineering measurement, underground pipeline engineering measurement and mine measurement, and the content of the engineering measurement mainly comprises plane control measurement, elevation control measurement, engineering deployment measurement, topography measurement, cadastral and house property measurement, mine survey, bridge and culvert engineering and the like, and according to the proceeding procedure of engineering construction, the engineering measurement can be divided into measurement in planning and design stage, measurement in construction and construction stage and measurement in operation and management stage after completion;

before engineering measurement is carried out, the planning and design of the measurement scheme are required, an operator uploads engineering information of a corresponding project and sends the engineering information to a server, and the server sends the engineering information to a processing terminal to carry out the planning and design of the measurement scheme;

in view of the above technical drawbacks, a solution is now proposed.

Disclosure of Invention

The invention aims to provide an engineering measurement intelligent planning design management system, which solves the problems that the reasonable and automatic selection of a processing terminal cannot be carried out before the planning and design of a measurement scheme are carried out, the planning effect of the scheme is difficult to be improved while the processing efficiency is ensured, the reasonable regulation and control of the display process cannot be carried out when the display of the measurement engineering planning and design scheme is carried out, and the clear and detailed knowledge of the scheme content of corresponding staff is not facilitated.

In order to achieve the above purpose, the present invention provides the following technical solutions: an engineering measurement intelligent planning design management system comprises a server, a port registration module, a terminal allocation selection module, a visual display module and a visual regulation decision module;

the port registration module is used for submitting terminal information through the computer terminal to register and sending the terminal information which is successfully registered to the server, marking the computer terminal which is successfully registered as a registration terminal, and connecting the server with the registration terminal in real time in a communication way; the user uploads engineering information to be subjected to engineering measurement to a server, the server generates a terminal analysis signal and sends the terminal analysis signal to a terminal allocation selection module, when the terminal allocation selection module receives the terminal analysis signal, all registered terminals are subjected to preliminary analysis and front-end terminal screening, all front-end terminals are subjected to sequencing selection analysis, and a measurement planning terminal is determined;

the method comprises the steps that after the server receives engineering information of corresponding engineering, the engineering information is distributed to a measurement planning terminal, after the measurement planning terminal receives the engineering information of the corresponding engineering, planning and designing of corresponding engineering measurement are carried out, a measurement planning scheme is generated, the measurement planning scheme is sent to the server, and the server stores the measurement planning scheme; and the server sends the measurement planning scheme to the visual display module, the visual display module performs visual display on the measurement planning scheme, the visual regulation and control decision module performs display regulation and control analysis on a display area of the visual display module, a corresponding regulation and control instruction is generated through the display regulation and control analysis, and the visual display module performs adaptive regulation and control based on the corresponding regulation and control instruction.

Further, the specific analytical process for the display control analysis is as follows:

the method comprises the steps of collecting the number of people in a display area, marking the number of people in the display area as a human visual value, marking the people in the display area as visual people i, wherein i is a natural number larger than 1, collecting a top plan view of the display area, taking a geometric center point of a display surface of a visual display module as a capturing point, taking the position of the visual people i as an analysis point, connecting the capturing point with the corresponding analysis point through a line segment to obtain a man-machine line, marking the length of the man-machine line as a line distance value, taking the capturing point as an endpoint, establishing rays perpendicular to the visual display module and marking the capturing point as a vertical line, marking an included angle between the man-machine line and the vertical line as a line angle value, and obtaining a visual clear value of the visual people i through analysis and calculation based on the line distance value and the line angle value;

marking visual personnel i with visual clarity exceeding a preset visual clarity threshold as visual trapping personnel, marking the number of visual trapping personnel as visual trapping value, marking the ratio of the number of visual trapping personnel to the visual trapping value as a visual trapping value, obtaining a regional visual value based on the visual trapping value and the visual trapping value through analysis and calculation, and obtaining a display ring value of a display region, respectively comparing the regional visual value and the display ring value with the preset regional visual threshold and the preset display ring threshold in numerical terms, generating a highlight regulation instruction if the regional visual value and the display ring value exceed the corresponding preset threshold, generating a low-light regulation instruction if the regional visual value and the display ring value do not exceed the corresponding preset threshold, and generating a medium-light regulation instruction if the rest conditions are met.

Further, the display brightness range corresponding to the highlight regulation instruction is a primary brightness range, the display brightness range corresponding to the medium brightness regulation instruction is a secondary brightness range, the brightness regulation range corresponding to the low brightness regulation instruction is a tertiary brightness range, the primary brightness range is larger than the secondary brightness range and larger than the tertiary brightness range, if the current actual display brightness of the visual display module is in the corresponding brightness range, the brightness regulation of the visual display module is not needed, and otherwise, the visual display module is automatically subjected to adaptive regulation.

Further, the analysis and acquisition method of the expansion ring value is as follows:

the brightness value and the brightness penetration value of the display area are collected, weight coefficients a1 and a2 are distributed to the brightness value and the brightness penetration value, the brightness value and the brightness penetration value are multiplied by the corresponding weight coefficients respectively, summation calculation is carried out on two groups of product values to obtain a ring table value, if the ring table value exceeds a preset ring table threshold value, the difference value of the brightness value and the brightness penetration value is marked as a ring table exceeding value, the number of ring table values exceeding the preset ring table threshold value in unit time is collected and marked as non-optimal ring values, summation calculation is carried out on all the ring table exceeding values to obtain a ring super total value, and the ring expanding value is obtained through analysis calculation based on the non-optimal ring value and the ring super total value.

Further, the preliminary analysis process of the terminal allocation selection module is as follows:

the method comprises the steps of marking a registered terminal as u, enabling u to be a natural number larger than 1, collecting computer terminal models of the registered terminal u, presetting a preset model representation value corresponding to all computer terminal models, determining the corresponding preset model representation value based on the computer terminal models of the registered terminal u and marking the preset model representation value as a model table value, calculating the distance between the position of the registered terminal u and the position of a server to obtain an end distance value, obtaining an end condition value of the registered terminal u, obtaining an end initial value based on the model table value, the end distance value and the end condition value through numerical calculation, sorting all the registered terminals according to the order from large to small based on the end initial value, marking the registered terminal positioned at the first third as a front terminal, and carrying out sorting selection analysis on all the front terminals.

Further, the specific analysis process of the sorting selection analysis is as follows:

the method comprises the steps of collecting planning design times of engineering measurement of a front-end terminal corresponding to a historical period, marking the planning design times as measurement rule values, collecting transmission time of engineering information sent to the corresponding front-end terminal by a historical period server, collecting feedback time of a feedback measurement planning scheme of the corresponding front-end terminal, calculating time difference between the corresponding feedback time and the transmission time to obtain planning schedule values, marking the planning schedule values exceeding a corresponding preset planning schedule threshold value as planning defect values, summing all the planning defect values with exceeding values of the preset planning schedule threshold value to obtain planning super-total values, calculating the ratio of the number of the planning defect values to the measurement rule values to obtain planning abnormal occupation values, carrying out normalization calculation on the measurement rule values, the planning super-total values and the planning abnormal occupation values to obtain values, marking the values as end score values, sequencing all the front-end terminals according to the order of the end score values, and marking the front-end terminals at the beginning position as measurement planning terminals.

Further, the end condition value is obtained by analysis of an end condition collecting and analyzing module, the server is in communication connection with the end condition collecting and analyzing module, the end condition collecting and analyzing module carries out end condition detection and analysis on the registered terminal u, the end condition value of the registered terminal u is obtained through the end condition detection and analysis, and the specific analysis process of the end condition detection and analysis is as follows:

collecting a voltage maximum value and a voltage minimum value in the operation process of the registered terminal u, carrying out difference calculation on the voltage maximum value and the voltage minimum value to obtain a voltage span value, similarly obtaining a temperature span value and a current span value, collecting an average temperature value, an average voltage value and an average current value of the registered terminal u in the operation process, marking a deviation value of the average temperature value compared with a preset average temperature value as a temperature deviation value, similarly obtaining a pressure deviation value and a current deviation value, carrying out normalization calculation on the temperature span value, the voltage span value, the current span value, the Wen Pian difference value, the pressure deviation value and the current deviation value, taking the values of the temperature span value, the voltage span value, the current span value, the Wen Pian difference value, the pressure deviation value and the current deviation value, marking the values of the voltage span value and the current span value as end condition values, and sending the end condition values of the registered terminal i to a terminal allocation and selection module through a server.

Further, the server is in communication connection with the back-end measurement checking module, the back-end measurement checking module is used for carrying out step-by-step measurement evaluation on the corresponding engineering, marking the corresponding measurement item k as an obstacle item or no obstacle item, and subsequently strengthening measurement training on the obstacle item and personnel supervision during strengthening measurement, wherein the specific analysis process is as follows:

acquiring a measurement planning scheme of a corresponding project, acquiring all measurement items of the corresponding project based on the measurement planning scheme, and marking the measurement items as k, wherein k is a natural number larger than 1; when the measurement of the measurement item k is completed, obtaining the frequency of errors and the number of measurement personnel with errors in the measurement process of the measurement item k, and carrying out numerical calculation on the frequency of errors and the number of measurement personnel with errors to obtain a measurement error value; if the measured error value exceeds the corresponding preset measured error threshold value, marking the measured item k as an obstacle item;

otherwise, acquiring the measurement completion time length of the measurement item k, and marking the measurement item k as an unimpeded item if the measurement completion time length does not exceed a corresponding preset measurement completion time length threshold value in the measurement planning scheme; if the measurement completion time exceeds a corresponding preset measurement completion time threshold in the measurement planning scheme, marking the exceeding value of the measurement completion time compared with the corresponding preset measurement completion time threshold as a measurement timeout value, obtaining an obstacle value through analysis based on the measurement timeout value and a measurement error value, marking a measurement item k as an obstacle item if the obstacle value exceeds the corresponding preset obstacle threshold, and marking the measurement item k as an unimpeded item if the obstacle value does not exceed the corresponding preset obstacle threshold.

Further, the analysis process of the back-end measurement and inspection module further comprises:

in the measuring process of the corresponding engineering, obtaining all measurement items of incomplete measurement, calling the time occupation ratio of the corresponding measurement items based on a measurement planning scheme, and summing the time occupation ratios of all measurement items of incomplete measurement to obtain a to-be-measured occupation ratio; and calculating the ratio of the remaining measurement time length to the planned measurement time length to obtain a time limit occupation ratio, calculating the difference between the to-be-measured occupation ratio and the time limit occupation ratio to obtain a time difference coefficient, if the time difference coefficient is a non-positive number, generating a progress normal signal, if the time difference coefficient exceeds a preset time difference threshold, generating a progress high urgent signal, otherwise, generating a progress low urgent signal, transmitting the progress normal signal, the progress low urgent signal or the progress high urgent signal to a server, and then appropriately accelerating the measurement progress when the progress low urgent signal is received, and then adding measurement personnel and accelerating the measurement progress and strengthening the measurement management when the progress high urgent signal is received.

Compared with the prior art, the invention has the beneficial effects that:

1. in the invention, all registered terminals are subjected to preliminary analysis and screening out the front-end terminals through the terminal allocation selection module, all the front-end terminals are subjected to sequencing selection analysis and the measurement planning terminal is determined, and the optimal processing terminal is judged and screened out through multi-step selection analysis, so that the automatic and reasonable selection of the processing terminal is realized, the processing efficiency of the measurement engineering planning design is ensured, and the processing effect is improved; the measurement planning terminal performs planning design of corresponding engineering measurement and generates a measurement planning scheme, the visual display module performs visual display of the measurement planning scheme, the visual regulation decision module visually displays specific conditions of the engineering measurement planning scheme, and the visual regulation decision module performs display regulation analysis on a display area of the visual display module to judge whether a corresponding regulation instruction is generated or not, so that automatic adaptive regulation of the display process of the visual display module is realized;

2. according to the invention, the corresponding engineering is subjected to step-by-step measurement evaluation through the back-end measurement inspection module, the corresponding measurement item is marked as an obstacle item or no obstacle item through analysis and judgment, the subsequent measurement training of the obstacle item and personnel supervision during the reinforcement measurement are enhanced, the targeted measurement training and the improvement of the working capacity of the corresponding measurement personnel are facilitated, the smooth and efficient performance of the subsequent related measurement operation is ensured, the corresponding management personnel can intuitively know the measurement progress of the corresponding engineering through analysis and judgment and generate a normal progress signal, a low progress urgent signal or a high progress urgent signal, the management personnel can monitor the measurement progress in time, the supervision of the measurement personnel and the measurement process is facilitated, and the smooth and timely completion of the corresponding engineering measurement work is ensured.

Drawings

For the convenience of those skilled in the art, the present invention will be further described with reference to the accompanying drawings;

FIG. 1 is an overall system block diagram of the present invention;

fig. 2 is a system block diagram of a second embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Embodiment one:

as shown in fig. 1, the engineering measurement intelligent planning design management system provided by the invention comprises a server, a port registration module, a terminal allocation selection module, a visual display module and a visual regulation decision module, wherein the server is in communication connection with the port registration module, the terminal allocation selection module, the visual display module and the visual regulation decision module; the port registration module is used for submitting terminal information through the computer terminal to register and sending the terminal information which is successfully registered to the server, marking the computer terminal which is successfully registered as a registration terminal, and connecting the server with the registration terminal in real time in a communication way;

the user uploads engineering information to be subjected to engineering measurement to a server, the server generates a terminal analysis signal and sends the terminal analysis signal to a terminal allocation selection module, when the terminal allocation selection module receives the terminal analysis signal, all registered terminals are subjected to preliminary analysis and front-end terminal screening, all front-end terminals are subjected to sequencing selection analysis, and a measurement planning terminal is determined; the preliminary analysis process is specifically as follows:

the method comprises the steps that a registered terminal is marked as u, u is a natural number larger than 1, the computer terminal model of the registered terminal u is collected, all computer terminal models are preset to correspond to one preset model representation value, the corresponding preset model representation value is determined based on the computer terminal model of the registered terminal u and marked as a model representation value XBu, and the better the equipment performance of the corresponding model of the registered terminal u is, the larger the numerical value of the corresponding model representation value is; the method comprises the steps of performing distance calculation on the position of a registered terminal u and the position of a server to obtain an end distance value DJu, obtaining an end condition value DKu of the registered terminal u, and performing numerical calculation through a formula XZu =a1× XBu +a2/(DJu +0.657) +a3/(DKu +0.864) based on a model table value, the end distance value and the end condition value to obtain an end initial value XZu;

wherein a1, a2 and a3 are preset weight coefficients, a1 is more than 1 and a2 is more than 3; as can be seen from the above formula, the value of the initial value XZu is in a proportional relationship with the small-scale table value, and in an inverse relationship with the end distance value and the end condition value, and the smaller the value of the initial value XZu, the less suitable the corresponding registered terminal u is for performing the current processing operation; based on the initial value of the terminal, sequencing all the registered terminals according to the sequence from big to small, marking the registered terminals positioned in the first third as front terminals, realizing the preliminary screening of all the registered terminals, and being beneficial to the subsequent screening of the most suitable processing terminals;

the specific analysis process of the sequencing selection analysis is as follows: acquiring planning design times of engineering measurement by a front-end terminal corresponding to a historical period, marking the planning design times as measurement rule values GPu, acquiring transmission time of engineering information transmitted to the corresponding front-end terminal by a historical period server, acquiring feedback time of a feedback measurement planning scheme of the corresponding front-end terminal, performing time difference calculation on the corresponding feedback time and the transmission time to obtain planning schedule values, marking the planning schedule values exceeding a corresponding preset planning schedule threshold as planning defect values, summing up and calculating excess values of all the planning defect values compared with the preset planning schedule threshold to obtain planning overtotal values GCu, and performing ratio calculation on the number of the planning defect values and the measurement rule values to obtain planning abnormal occupation values GZu;

normalizing the measurement rule value, the planning superstotal value and the planning differential occupation value by a formula DFu = (eF1× GPu)/(eF2×GCu+eF3× GZu +1.324) and taking the numerical values, and marking the numerical values as end scores DFu, wherein, ef1, ef2 and ef3 are preset weight coefficients, and ef3 > ef2 > ef1 > 0; moreover, as can be known from the formula, the numerical value of the end score DFu is in a direct proportion relation with the measured standard frequency value, and is in an inverse proportion relation with the planned super-total value and the planned different occupation value, the larger the numerical value of the end score DFu is, the more suitable the corresponding front-end terminal is for carrying out the current processing operation; and based on the end scores, all the front-end terminals are ordered according to the order from large to small, and the front-end terminal positioned at the first position is marked as a measurement planning terminal, so that reasonable selection of the processing terminal is realized, and the planning design efficiency and the planning design effect of engineering measurement are improved.

The server is in communication connection with the end condition acquisition and analysis module, the end condition value is obtained by the end condition acquisition and analysis module, the end condition acquisition and analysis module carries out end condition detection and analysis on the registered terminal i, the end condition value of the registered terminal i is obtained through the end condition detection and analysis, and the specific analysis process of the end condition detection and analysis is as follows:

acquiring a voltage maximum value and a voltage minimum value in the operation process of the registration terminal u, performing difference calculation on the voltage maximum value and the voltage minimum value to obtain a voltage span value YKu, acquiring a temperature span value WKu and a current span value LKu in the same way, acquiring an average temperature value, an average voltage value and an average current value of the registration terminal u in the operation process, marking a deviation value of the average temperature value compared with a preset average temperature value as a temperature deviation value HWu, and acquiring a pressure deviation value HYu and a current deviation value HLu in the same way;

the temperature span value, the voltage span value, the current span value, the Wen Pian difference value, the pressure deviation value and the flow deviation value are normalized and calculated according to a formula DKu =b1× WKu +b2× YKu +b3× LKu +b4× HWu +b5× HYu +b6× HLu, and the values are marked as end condition values DKu, wherein b1, b2, b3, b4, b5 and b6 are preset weight coefficients with values larger than 1, and the larger the value of the registered terminal u is, the worse the operation condition of the corresponding registered terminal u is, the harder the current processing operation is smoothly and rapidly performed, and the end condition value of the registered terminal i is sent to the terminal allocation selection module through the server.

The method comprises the steps that after the server receives engineering information of corresponding engineering, the engineering information is distributed to a measurement planning terminal, after the measurement planning terminal receives the engineering information of the corresponding engineering, planning and designing of corresponding engineering measurement are carried out, a measurement planning scheme is generated, the measurement planning scheme is sent to the server, and the server stores the measurement planning scheme; the server sends the measurement planning scheme to a visual display module, the visual display module visually displays the measurement planning scheme, related staff can intuitively know the specific condition of the engineering measurement planning scheme, a visual regulation and control decision module displays a display area of the visual display module for regulation and control analysis, a corresponding regulation and control instruction is generated through the display and control analysis, and the visual display module is adaptively regulated and controlled based on the corresponding regulation and control instruction; the specific analytical process for the display control analysis is as follows:

the method comprises the steps of collecting the number of people in a display area, marking the number of people in the display area as a human visual value, marking the people in the display area as visual people i, wherein i is a natural number larger than 1, collecting a top plan view of the display area, taking a geometric center point of a display surface of a visual display module as a capturing point, taking the position of the visual people i as an analysis point, connecting the capturing point with the corresponding analysis point through a line segment to obtain a man-machine line, marking the length of the man-machine line as a line distance value XLI, establishing a ray perpendicular to the visual display module by taking the capturing point as an endpoint and marking the capturing point as a vertical line, marking an included angle between the man-machine line and the vertical line as a line angle value XJi, and obtaining a visual clear value SQI of the visual people i based on the line distance value and the line angle value and through analysis calculation of a formula SQI= (eu1+eu2× XJi)/(eu1+eu2); wherein, eu1 and eu2 are preset proportionality coefficients, and eu1 is more than eu2 and more than 1; in addition, the numerical value of the visual clear value Sqi is in a direct proportion relation with the line distance value and the line angle value, and the larger the numerical value of the visual clear value Sqi is, the more difficult the corresponding personnel can see the displayed scheme content;

marking visual staff i with visual acuity value exceeding a preset visual acuity threshold value as visual acuity staff, marking the number of the visual acuity staff as visual acuity value KS, marking the ratio of the number of the visual acuity staff to the visual acuity value as a visual acuity value KB, and analyzing and calculating through a formula QS=h1+h2×KB based on the visual acuity value and the visual acuity value to obtain a regional vision value QS, wherein h1 and h2 are preset weight coefficients, and h2 is more than h1 and more than 0; in addition, the magnitude of the regional visual value QS is in a direct proportion relation with the trapping visual value and the trapping ratio value, and the larger the magnitude of the regional visual value QS is, the more difficult the current personnel is to see the display content clearly;

the brightness value and the brightness penetration value of the display area are collected, the brightness penetration value is a data value representing the visibility of the corresponding area, and the smaller the dust concentration of the area is, the better the visibility is, and the smaller the value of the brightness penetration value is; the brightness value and the brightness penetration value are distributed with weight coefficients a1 and a2, the brightness value and the brightness penetration value are multiplied by the corresponding weight coefficients respectively, summation calculation is carried out on two groups of product values to obtain a ring table value, if the ring table value exceeds a preset ring table threshold value, the difference value of the brightness value and the brightness penetration value is marked as a ring table exceeding value, the number of ring table values exceeding the preset ring table threshold value in unit time is collected and marked as non-optimal ring values FY, and summation calculation is carried out on all the ring table exceeding values to obtain a ring super-total value CZ;

based on a non-optimal ring value and a ring super total value, analyzing and calculating through a formula ZH=h3 x FY+h4 x CZ to obtain a ring expanding value ZH, wherein h3 and h4 are preset weight coefficients, and h3 is more than h4 is more than 0; and respectively comparing the zone view value and the display ring value with a preset zone view threshold value and a preset display ring threshold value, generating a highlight regulation instruction if the zone view value and the display ring value exceed the corresponding preset threshold values, generating a low-highlight regulation instruction if the zone view value and the display ring value do not exceed the corresponding preset threshold values, and generating a medium-bright regulation instruction under the other conditions. It should be noted that, the display luminance range corresponding to the highlight regulation command is a first-level luminance range, the display luminance range corresponding to the medium-level luminance command is a second-level luminance range, the luminance regulation range corresponding to the low-level luminance command is a third-level luminance range, and the first-level luminance range is larger than the second-level luminance range and larger than the third-level luminance range;

the current actual display brightness of the visual display module is acquired, if the current actual display brightness of the visual display module is in the corresponding brightness range, the brightness of the visual display module is not required to be regulated and controlled, otherwise, the visual display module is automatically regulated and controlled in adaptive brightness, and adaptive content amplification display or reduced display can be carried out according to the requirements, so that the corresponding staff can be guaranteed to see the displayed design scheme content clearly.

Embodiment two:

as shown in fig. 2, the difference between the present embodiment and embodiment 1 is that the server is communicatively connected to the back-end measurement verification module, and the back-end measurement verification module is configured to perform step-by-step measurement and evaluation on the corresponding engineering, mark the corresponding measurement item k as an obstacle item or no obstacle item, and subsequently strengthen measurement training on the obstacle item and personnel supervision during measurement, so as to facilitate targeted measurement training and improve the working capacity of the corresponding measurement personnel, and facilitate ensuring smooth and efficient performance of subsequent related measurement operations; the specific analysis process is as follows:

acquiring a measurement planning scheme of a corresponding project, acquiring all measurement items of the corresponding project based on the measurement planning scheme, and marking the measurement items as k, wherein k is a natural number larger than 1; when the measurement of the measurement item k is completed, obtaining the frequency WPk of errors and the number WRk of error measurement personnel in the measurement process of the measurement item k, and carrying out numerical calculation on the frequency of errors and the number of error measurement personnel through a formula CWk =fp1× WPk +fp2× WRk to obtain a measurement error value CWk; wherein fp1 and fp2 are preset weight coefficients, fp2 > fp1 > 0; and, the larger the value of the measured error value CWk, the greater the operation difficulty of the corresponding measured item is; comparing the measured error value with a preset measured error threshold value, and marking the measured item k as an obstacle item if the measured error value exceeds the corresponding preset measured error threshold value;

if the measurement error value does not exceed the corresponding preset measurement error threshold value, acquiring the measurement completion time length of the measurement item k, and if the measurement completion time length does not exceed the corresponding preset measurement completion time length threshold value in the measurement planning scheme, marking the measurement item k as an unimpeded item; if the measurement completion time exceeds the corresponding preset measurement completion time threshold in the measurement planning scheme, marking the exceeding value of the measurement completion time compared with the corresponding preset measurement completion time threshold as a measurement timeout value SCk, and obtaining an obstacle value ZAi after analysis and calculation based on the measurement timeout value and the measurement error value through a formula ZAi =fp CWk +fp4sck; wherein fp3 and fp4 are preset weight coefficients, fp4 is more than fp3 and more than 1;

it should be noted that, the magnitude of the obstacle value ZAi is in a proportional relation with the measurement timeout value and the measurement error value, the greater the magnitude of the measurement timeout value and the greater the magnitude of the measurement error value, the greater the magnitude of the obstacle value ZAi indicates that the measurement process of the corresponding measurement item has a certain difficulty compared with the measurement process of the corresponding measurement item, and the subsequent needs to strengthen the measurement training and the on-site measurement supervision of the corresponding item; and comparing the obstacle value with a corresponding preset obstacle threshold value, marking the measured item k as an obstacle item if the obstacle value exceeds the corresponding preset obstacle threshold value, and marking the measured item k as an unimpeded item if the obstacle value does not exceed the corresponding preset obstacle threshold value.

Embodiment III:

the difference between this embodiment and embodiments 1 and 2 is that, in the measurement process of the corresponding engineering, the analysis process of the back-end measurement inspection module further includes:

acquiring all measurement items which are not measured, calling the time occupation ratio of the corresponding measurement items based on a measurement planning scheme, and summing the time occupation ratios of all the measurement items which are not measured to obtain a to-be-measured occupation ratio; calculating the ratio of the remaining measurement time length to the planned measurement time length to obtain a time limit occupation ratio, calculating the difference between the to-be-measured occupation ratio and the time limit occupation ratio to obtain a time difference coefficient, and if the time difference coefficient is a non-positive number, indicating that the to-be-measured occupation ratio is smaller than or equal to the time limit occupation ratio, and then smoothly completing the measurement work of the corresponding project according to the current progress, so as to generate a progress normal signal;

if the time difference coefficient is positive, the time difference coefficient is compared with a preset time difference threshold value, if the time difference coefficient exceeds the preset time difference threshold value, a progress high-urgency signal is generated, otherwise, a progress low-urgency signal is generated, a progress normal signal, a progress low-urgency signal or a progress high-urgency signal is sent to a server, the measurement progress is accelerated appropriately subsequently when the progress low-urgency signal is received, the measurement staff is increased and the measurement progress is accelerated and the measurement management is enhanced subsequently when the progress high-urgency signal is received, the corresponding management staff can intuitively know the measurement progress of the corresponding engineering, management staff can manage and control the measurement progress timely, supervision of the measurement staff and the measurement process is facilitated, and smooth and on-time completion of the corresponding engineering measurement work is guaranteed.

When the method is used, a user uploads engineering information to be subjected to engineering measurement and sends the engineering information to the server, the server generates a terminal analysis signal and sends the terminal analysis signal to the terminal allocation selection module, the terminal allocation selection module performs preliminary analysis on all registered terminals and screens out front terminals, and performs sequencing selection analysis on all front terminals and determines a measurement planning terminal, and the optimal processing terminal is judged and screened out through multi-step selection analysis, so that automatic and reasonable selection of the processing terminal is realized, the processing efficiency of measurement engineering planning design is ensured, and the processing effect is improved; the server distributes engineering information of corresponding engineering to the measurement planning terminal, the measurement planning terminal performs planning design of corresponding engineering measurement and generates a measurement planning scheme, the server stores the measurement planning scheme and sends the measurement planning scheme to the visual display module, the visual display module visually displays the measurement planning scheme, relevant staff can intuitively know the specific condition of the engineering measurement planning scheme, the visual regulation decision module visually displays a display area of the visual display module, judges whether a corresponding regulation command is generated or not, and performs adaptive brightness regulation and adaptive content amplification display or reduction display on the basis of the corresponding regulation command, so that the corresponding staff can see the displayed design scheme content clearly.

The above formulas are all formulas with dimensions removed and numerical values calculated, the formulas are formulas with a large amount of data collected for software simulation to obtain the latest real situation, and preset parameters in the formulas are set by those skilled in the art according to the actual situation. The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (4)

1. The engineering measurement intelligent planning design management system is characterized by comprising a server, a port registration module, a terminal allocation selection module, a visual display module and a visual regulation decision module;

the port registration module is used for submitting terminal information through the computer terminal to register and sending the terminal information which is successfully registered to the server, marking the computer terminal which is successfully registered as a registration terminal, and connecting the server with the registration terminal in real time in a communication way; the user uploads engineering information to be subjected to engineering measurement to a server, the server generates a terminal analysis signal and sends the terminal analysis signal to a terminal allocation selection module, when the terminal allocation selection module receives the terminal analysis signal, all registered terminals are subjected to preliminary analysis and front-end terminal screening, all front-end terminals are subjected to sequencing selection analysis, and a measurement planning terminal is determined;

the method comprises the steps that after the server receives engineering information of corresponding engineering, the engineering information is distributed to a measurement planning terminal, after the measurement planning terminal receives the engineering information of the corresponding engineering, planning and designing of corresponding engineering measurement are carried out, a measurement planning scheme is generated, the measurement planning scheme is sent to the server, and the server stores the measurement planning scheme; the server sends the measurement planning scheme to a visual display module, the visual display module performs visual display on the measurement planning scheme, the visual regulation and control decision module performs display regulation and control analysis on a display area of the visual display module, a corresponding regulation and control instruction is generated through the display regulation and control analysis, and the visual display module performs adaptive regulation and control based on the corresponding regulation and control instruction;

the specific analytical process for the display control analysis is as follows:

the method comprises the steps of collecting the number of people in a display area, marking the number of people in the display area as a human visual value, marking the people in the display area as visual people i, wherein i is a natural number larger than 1, collecting a top plan view of the display area, taking a geometric center point of a display surface of a visual display module as a capturing point, taking the position of the visual people i as an analysis point, connecting the capturing point with the corresponding analysis point through a line segment to obtain a man-machine line, marking the length of the man-machine line as a line distance value, taking the capturing point as an endpoint, establishing rays perpendicular to the visual display module and marking the capturing point as a vertical line, marking an included angle between the man-machine line and the vertical line as a line angle value, and obtaining a visual clear value of the visual people i through analysis and calculation based on the line distance value and the line angle value; marking visual staff i with visual clearance exceeding a preset visual clearance threshold as visual staff, marking the number of the visual staff as visual staff, marking the ratio of the number of the visual staff to the visual staff as a visual staff value, and obtaining a regional visual value through analysis and calculation based on the visual staff value and the visual staff value;

the brightness value and the brightness penetration value of the display area are collected, weight coefficients a1 and a2 are distributed to the brightness value and the brightness penetration value, the brightness value and the brightness penetration value are multiplied by corresponding weight coefficients respectively, summation calculation is carried out on two groups of product values to obtain a ring table value, if the ring table value exceeds a preset ring table threshold value, the difference value of the brightness value and the brightness penetration value is marked as a ring table exceeding value, the number of ring table values exceeding the preset ring table threshold value in unit time is collected and marked as non-optimal ring values, summation calculation is carried out on all ring table exceeding values to obtain a ring super total value, numerical comparison is carried out on a region visual value and a display ring value with a preset region visual threshold value and a preset display ring threshold value respectively, if the region visual value and the display ring value exceed the corresponding preset threshold value, a high-brightness regulation command is generated, and if the region visual value and the display ring value do not exceed the corresponding preset threshold value, a low-brightness command is generated, and otherwise a medium-brightness regulation command is generated;

the display brightness range corresponding to the high brightness control instruction is a first-level brightness range, the display brightness range corresponding to the medium brightness control instruction is a second-level brightness range, the brightness control range corresponding to the low brightness control instruction is a third-level brightness range, the first-level brightness range is larger than the second-level brightness range and larger than the third-level brightness range, if the current actual display brightness of the visual display module is in the corresponding brightness range, the brightness control of the visual display module is not needed, and otherwise, the visual display module is automatically subjected to adaptive control;

the preliminary analysis process of the terminal allocation selection module is as follows:

marking a registered terminal as u, u is a natural number greater than 1, acquiring the computer terminal model of the registered terminal u, presetting a preset model representation value corresponding to all computer terminal models, determining the corresponding preset model representation value based on the computer terminal model of the registered terminal u and marking the preset model representation value as a model table value, calculating the distance between the position of the registered terminal u and the position of a server to obtain an end distance value, acquiring an end condition value of the registered terminal u, calculating the end initial value based on the model table value, the end distance value and the end condition value through numerical calculation, sorting all the registered terminals according to the order from large to small based on the end initial value, marking the registered terminal positioned at the front third as a front terminal, and carrying out sorting selection analysis on all the front terminals;

the specific analysis procedure for the rank selection analysis is as follows:

the method comprises the steps of collecting planning design times of engineering measurement of a front-end terminal corresponding to a historical period, marking the planning design times as measurement rule values, collecting transmission time of engineering information sent to the corresponding front-end terminal by a historical period server, collecting feedback time of a feedback measurement planning scheme of the corresponding front-end terminal, calculating time difference between the corresponding feedback time and the transmission time to obtain planning schedule values, marking the planning schedule values exceeding a corresponding preset planning schedule threshold value as planning defect values, summing all the planning defect values with exceeding values of the preset planning schedule threshold value to obtain planning super-total values, calculating the ratio of the number of the planning defect values to the measurement rule values to obtain planning abnormal occupation values, carrying out normalization calculation on the measurement rule values, the planning super-total values and the planning abnormal occupation values to obtain values, marking the values as end score values, sequencing all the front-end terminals according to the order of the end score values, and marking the front-end terminals at the beginning position as measurement planning terminals.

2. The engineering measurement intelligent planning design management system according to claim 1, wherein the end condition value is obtained by analysis of an end condition collecting and analyzing module, the server is in communication connection with the end condition collecting and analyzing module, the end condition collecting and analyzing module carries out end condition detection analysis on the registered terminal u, the end condition value of the registered terminal u is obtained through the end condition detection analysis, and the specific analysis process of the end condition detection analysis is as follows:

collecting a voltage maximum value and a voltage minimum value in the operation process of the registered terminal u, carrying out difference calculation on the voltage maximum value and the voltage minimum value to obtain a voltage span value, similarly obtaining a temperature span value and a current span value, collecting an average temperature value, an average voltage value and an average current value of the registered terminal u in the operation process, marking a deviation value of the average temperature value compared with a preset average temperature value as a temperature deviation value, similarly obtaining a pressure deviation value and a current deviation value, carrying out normalization calculation on the temperature span value, the voltage span value, the current span value, the Wen Pian difference value, the pressure deviation value and the current deviation value, taking the values of the temperature span value, the voltage span value, the current span value, the Wen Pian difference value, the pressure deviation value and the current deviation value, marking the values of the voltage span value and the current span value as end condition values, and sending the end condition values of the registered terminal i to a terminal allocation and selection module through a server.

3. The intelligent planning and design management system for engineering measurement according to claim 1, wherein the server is in communication connection with a back-end measurement and verification module, the back-end measurement and verification module is used for performing step-by-step measurement and evaluation on a corresponding engineering, marking the corresponding measurement item k as an obstacle item or an unimpeded item, subsequently strengthening measurement training on the obstacle item and personnel supervision during strengthening measurement, and the specific analysis process is as follows:

acquiring a measurement planning scheme of a corresponding project, acquiring all measurement items of the corresponding project based on the measurement planning scheme, and marking the measurement items as k, wherein k is a natural number larger than 1; when the measurement of the measurement item k is completed, obtaining the frequency of errors and the number of measurement personnel with errors in the measurement process of the measurement item k, and carrying out numerical calculation on the frequency of errors and the number of measurement personnel with errors to obtain a measurement error value; if the measured error value exceeds the corresponding preset measured error threshold value, marking the measured item k as an obstacle item;

otherwise, acquiring the measurement completion time length of the measurement item k, and marking the measurement item k as an unimpeded item if the measurement completion time length does not exceed a corresponding preset measurement completion time length threshold value in the measurement planning scheme; if the measurement completion time exceeds a corresponding preset measurement completion time threshold in the measurement planning scheme, marking the exceeding value of the measurement completion time compared with the corresponding preset measurement completion time threshold as a measurement timeout value, obtaining an obstacle value through analysis based on the measurement timeout value and a measurement error value, marking a measurement item k as an obstacle item if the obstacle value exceeds the corresponding preset obstacle threshold, and marking the measurement item k as an unimpeded item if the obstacle value does not exceed the corresponding preset obstacle threshold.

4. The engineering survey intelligent planning design management system of claim 3, wherein the back-end survey verification module analysis process further comprises:

in the measuring process of the corresponding engineering, obtaining all measurement items of incomplete measurement, calling the time occupation ratio of the corresponding measurement items based on a measurement planning scheme, and summing the time occupation ratios of all measurement items of incomplete measurement to obtain a to-be-measured occupation ratio; and calculating the ratio of the remaining measurement time length to the planned measurement time length to obtain a time limit occupation ratio, calculating the difference between the to-be-measured occupation ratio and the time limit occupation ratio to obtain a time difference coefficient, if the time difference coefficient is a non-positive number, generating a progress normal signal, if the time difference coefficient exceeds a preset time difference threshold, generating a progress high urgent signal, otherwise, generating a progress low urgent signal, transmitting the progress normal signal, the progress low urgent signal or the progress high urgent signal to a server, and then appropriately accelerating the measurement progress when the progress low urgent signal is received, and then adding measurement personnel and accelerating the measurement progress and strengthening the measurement management when the progress high urgent signal is received.