CN117949539B - Engineering building strength detection system and detection method thereof - Google Patents
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Abstract
The invention provides an engineering building strength detection system and a detection method thereof, which relate to the technical field of strength detection, and are used for constructing a plurality of monitoring paths of a region to be detected and respectively collecting path data of the plurality of monitoring paths; analyzing the collected multiple groups of path data, and selecting a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path; extracting reflected wave signals in the optimal monitoring path data; carrying out convolution operation on the reflected wave signals, extracting the characteristics of the reflected wave and carrying out characteristic mapping; the data mapped by the features are classified based on a multi-data fusion algorithm, so that the strength state evaluation is carried out, the accuracy and the reliability of the detection result are improved, and a powerful guarantee is provided for the safety and the durability of the building.
Description
Technical Field
The invention provides an engineering building strength detection system and a detection method thereof, and relates to the technical field of strength detection.
Background
In engineering construction, strength detection is a vital link, which concerns the safety and durability of the building. However, although there are a number of detection methods available, each method has its unique advantages and disadvantages. In addition to selecting an appropriate detection method, other important factors in intensity detection should be considered. For example, the representative part of the sample should be selected as much as possible for detection, so that the influence on the overall evaluation result due to local abnormality is avoided. In addition, the influence of environmental factors such as temperature, humidity, etc. should be focused to ensure the stability and reliability of the detection result.
The direct method is the most intuitive method of strength detection, which measures the strength of a structure by performing a pressure test directly on the building structure. The method has high result accuracy, but has great operation difficulty, and can cause damage to building structures. In addition, the direct method is very difficult to implement for large or complex building structures.
The rebound method uses a rebound instrument to measure the hardness of the concrete surface, thereby calculating the compressive strength thereof. The method is simple and convenient to operate, does not damage the surface of the structure, has relatively low precision, and has certain requirements on the water content and carbonization depth of the concrete.
The core drilling method detects the compressive strength of a concrete core sample by drilling it. The method has accurate results, but can cause certain damage to the structure, and has great difficulty in drilling core samples for large or complex building structures.
The comprehensive method combines a plurality of detection methods to improve the accuracy and reliability of the detection result. For example, by combining the rebound method and the core drilling method, the advantages of both methods can be fully utilized, thereby improving the detection accuracy. However, the complex operation of the overall process is high, requiring more equipment and human input.
Disclosure of Invention
In order to solve the technical problems, the invention provides an engineering building strength detection system and a detection method thereof, wherein the detection method comprises the following steps:
s1, constructing a plurality of monitoring paths of a region to be detected, and respectively acquiring path data of the plurality of monitoring paths;
S2, analyzing the collected multiple groups of path data, and selecting a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path;
S3, extracting reflected wave signals in the optimal monitoring path data;
S4, carrying out convolution operation on the reflected wave signals, extracting the characteristics of the reflected wave and carrying out characteristic mapping;
and S5, classifying the data mapped by the features based on a multi-data fusion algorithm, so as to evaluate the intensity state.
Further, in step S2: the fuzzy clustering gap V D is:
Wherein V D represents a fuzzy clustering gap, d b represents an outer gap, d w represents an inner gap, Represents the mean of class 1 data,/>Represents the average of class 2 data, w represents the aggregation direction, T represents the transpose, x i represents the i-th data, n 1 represents the number of class 1 data, and n 2 represents the number of class 2 data.
Further, in step S3: x A (t) is the signal when weak intensity occurs at time t; x B (t) is the signal when the intensity is normal at time t; taking the peak of the first arriving pulse as a reference to perform normalization processing, wherein the signals after normalization processing are as follows:
;
;
In the middle of Is the maximum of the peak of the head wave of the x A (t) signal; /(I)Is the maximum of the peak of the head wave of the x B (t) signal;
the expression of the reflected wave signal r (t) is:
。
Further, in step S4, the expression of reflected wave feature extraction is:
Wherein, Representing convolution operation, H being a convolution window; m represents the number of convolution kernels, M represents the total number of convolution kernels, and Y (t) is the characteristic of the output reflected wave;
And combining the reflected wave characteristics generated at all the moments T in the monitoring period T to form a reflected wave characteristic sequence, wherein the number of the reflected wave characteristic sequences is equal to the number of the moments T in the monitoring period T.
Further, a reflected wave signal sequence obtained in the monitoring period T is setTransmitting the reflected wave signal sequence to the full connection layer for weighted feature mapping:
;
;
;
Wherein W S is the weight of the full connection layer, b S is the bias term, u (t) is the output variable of the full connection layer, And f is the final weighted feature map.
Further, in step S5, the category function is expressed as:
;
Output predicted value corresponding to feature map f Expressed as:
;
Where y represents the actual class, L is the error function, As a regularization function,/>And (3) the M-th iteration is performed on the diagnostic network model, M is the total iteration number, and Q is all mode spaces of the diagnostic network model.
The invention also provides an engineering building strength detection system for realizing the engineering building strength detection method, which comprises the following steps: the system comprises a plurality of sensors, a central ultrasonic generator, a data acquisition unit, a data processing unit, a monitoring unit and a processor;
Installing a plurality of sensors and a central ultrasonic generator on a region to be detected of a building, constructing a plurality of monitoring paths of the region to be detected, and respectively acquiring path data of the plurality of monitoring paths by a data acquisition unit;
the data processing unit analyzes the multiple groups of path data acquired by the data acquisition unit, and selects a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path;
The monitoring unit extracts reflected wave signals in the optimal monitoring path data;
The processor carries out convolution operation on the reflected wave signals extracted by the monitoring unit, extracts the characteristics of the reflected wave and carries out characteristic mapping; classifying the feature mapped data based on a multi-data fusion algorithm;
and the evaluation unit is used for evaluating the intensity state according to the classification result of the processor.
Compared with the prior art, the invention has the following beneficial technical effects:
The method comprises the steps of constructing a plurality of monitoring paths of a region to be detected, and respectively collecting path data of the plurality of monitoring paths; analyzing the collected multiple groups of path data, and selecting a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path; extracting reflected wave signals in the optimal monitoring path data; carrying out convolution operation on the reflected wave signals, extracting the characteristics of the reflected wave and carrying out characteristic mapping; classifying the data mapped by the features based on a multi-data fusion algorithm, thereby evaluating the intensity state. The invention can effectively perform nondestructive detection and strength evaluation, and can perform comprehensive scanning and data acquisition on a region to be detected by utilizing the propagation characteristic of ultrasonic waves, thereby providing detailed information about structural integrity and strength, greatly reducing the storage amount and transmission amount of data, improving the accuracy and reliability of detection results and providing powerful guarantee for the safety and durability of a building.
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In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort to a person skilled in the art.
FIG. 1 is a flow chart of the method for detecting the strength of an engineering building.
Fig. 2 is a schematic diagram of a reflected wave signal according to the present invention.
Fig. 3 is a schematic diagram of a monitoring path according to the present invention.
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 some embodiments of the present application, but not all embodiments of the present application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.
In the drawings of the specific embodiments of the present invention, in order to better and more clearly describe the working principle of each element in the system, the connection relationship of each part in the device is represented, but only the relative positional relationship between each element is clearly distinguished, and the limitations on the signal transmission direction, connection sequence and the structure size, dimension and shape of each part in the element or structure cannot be constructed.
As shown in fig. 1, the method for detecting the strength of the engineering building according to the invention comprises the following steps:
s1, constructing a plurality of monitoring paths of a region to be detected, and respectively acquiring path data of the plurality of monitoring paths.
A central ultrasonic generator having a plurality of transducers is mounted on the area of the structure of the building to be measured. The plurality of sensors and the central ultrasonic generator form a plurality of monitoring paths, each of which is composed of the central ultrasonic generator and the sensor, and then data acquisition is performed on each of the monitoring paths.
S2, analyzing the collected multiple groups of path data, and selecting a monitoring path corresponding to the path data with the largest fuzzy clustering gap value as an optimal monitoring path.
And analyzing the plurality of path data by adopting linear discriminant analysis, calculating fuzzy clustering gap values of the plurality of path data, and taking a monitoring path with the maximum fuzzy clustering gap value as an optimal monitoring path.
Based on mass data collection of each monitoring path, the difference among a plurality of monitoring paths is analyzed by utilizing a linear discriminant analysis method, so that the monitoring capability of each monitoring path is evaluated, and the optimal monitoring path is extracted.
The linear discriminant analysis method is a statistical learning method. It projects data from a multidimensional space to a one-dimensional space by finding the most easily classified direction of aggregation to achieve mathematical transformations. The basic idea is to find an aggregation direction such that the gap between two categories in this direction is as large as possible, which gap is also called the outer gap, and the gap inside the same category is as small as possible, which is called the inner gap. To achieve this goal, linear discriminant analysis determines the direction of aggregation by maximizing the ratio of the outer variance to the minimized inner variance.
The key of the optimal monitoring path extraction is to evaluate the capability of each path to monitor damage, and the size of the fuzzy clustering gap determines the damage separability based on the idea that the outer gap is as discrete as possible and the inner gap is as concentrated as possible. The fuzzy clustering gap V D is defined as the ratio of the outer gap to the inner gap:
Wherein V D represents a fuzzy clustering gap, d b represents an outer gap, d w represents an inner gap, Represents the mean of class 1 data,/>Represents the mean of class 2 data, w represents the aggregation direction, x i represents the i-th data, n 1 represents the number of class 1 data, and n 2 represents the number of class 2 data.
The damage monitoring capability assessment is mapped into the assessment of the size of a fuzzy clustering gap value of a monitored path, the fuzzy clustering gap of one path represents the damage monitoring capability of the path, and the larger the fuzzy clustering gap is, the stronger the damage distinguishing capability is, otherwise, the smaller the fuzzy clustering gap is, and the weaker the damage monitoring capability is. And selecting a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path.
And S3, extracting the reflected wave signals in the optimal monitoring path data.
During the propagation of ultrasonic waves, the amplitude of the ultrasonic waves is attenuated along with the propagation gap. In order to make the signals sensed by different sensors have the same effect on weak intensity, the signals need to be normalized.
X A (t) is the signal when weak intensity occurs at time t; x B (t) is the signal when the intensity is normal at time t; taking the peak of the first arriving pulse as a reference to perform normalization processing, wherein the signals after normalization processing are as follows:
;
;
In the middle of Is the maximum of the peak of the head wave of the x A (t) signal; /(I)Is the maximum of the first wave peak of the x B (t) signal.
The expression of the reflected wave signal r (t) is:
S4, carrying out convolution operation on the reflected wave signals, extracting the characteristics of the reflected wave and carrying out characteristic mapping.
Using a convolutional neural network, performing convolutional operation on the reflected wave signals by using a plurality of convolutional checks in a convolutional layer, and performing feature extraction and feature mapping;
a plurality of convolution kernels are defined, each of which can be regarded as a small filter, for identifying and extracting the reflected wave signal sequence.
For each time in the sequence of reflected wave signals, a convolution operation is performed using a defined convolution kernel. The convolution operation may cause each convolution kernel to perform feature extraction on the input reflected wave signal to generate an output reflected wave feature.
As shown in fig. 2, a schematic diagram of a reflected wave signal r (t), where the reflected wave signal r (t) forms a one-dimensional time sequence along with the propagation of the wave, and the distribution of the reflected wave signal r (t) along the time axis changes. When one-dimensional convolution window is used for convolution feature extraction along a time axis, the extracted features have time sequence characteristics
The expression of reflected wave feature extraction is:
Wherein, Representing convolution operation, H being a convolution window; m represents the number of convolution kernels, M represents the total number of convolution kernels, and Y (t) is the output reflected wave characteristic.
And combining the reflected wave characteristics generated at all the moments T in the monitoring period T to form a reflected wave characteristic sequence, wherein the number of the reflected wave characteristic sequences is equal to the number of the moments T in the monitoring period T.
Set up the reflected wave signal sequence obtained in the monitoring period TAnd transmitting the reflected wave signal sequence to the full connection layer for weighted feature mapping.
The process can be shown by the following formula:
;
;
;
wherein W S is the weight of the full connection layer, b s is the bias term, u (t) is the output variable of the hidden layer, And f is the weight of the output variable at the moment t, and f is the final weighted feature mapping, so that important features are enhanced, and finally, the features for model classification have more expressive ability.
And S5, classifying the data mapped by the features based on a multi-data fusion algorithm, so as to evaluate the intensity state.
And establishing an intensity state diagnosis network model by using a fault classifier, and carrying out fault diagnosis on the data to be tested according to a diagnosis strategy of the intensity state diagnosis network model to obtain a diagnosis result.
Output predicted value corresponding to feature map fExpressed as:
;
In the method, in the process of the invention, And (3) the M-th iteration is performed on the diagnostic network model, M is the total iteration number, and Q is all mode spaces of the diagnostic network model.
The class function of this embodiment classifies the intensity state, and represents the relationship between the predicted class and the actual class of the intensity state. The class functions include an output predicted value, an actual class, an error function, and a regularization function, in a given class function, the predicted output value is compared to the actual class by the error function to calculate a predicted error, and the difference between the predicted value and the actual value is measured by the error function.
The class function is expressed as:
;
In the method, in the process of the invention, And the output predicted value is represented, y represents the actual category, L is an error function, and the error function can adopt any one of square error and cross entropy error.
The regularization function is used for preventing the model from being overfitted, and constraint or punishment is applied to the model parameters, so that the model is more focused on generalization capability in the training process.
The invention also provides an engineering building strength detection system, which comprises: the system comprises a plurality of sensors, a central ultrasonic generator, a data acquisition unit, a data processing unit, a monitoring unit, a processor and an evaluation unit.
The method comprises the steps of installing a plurality of sensors and a central ultrasonic generator on a region to be detected of a building, constructing a plurality of monitoring paths of the region to be detected, and respectively carrying out path data acquisition on the plurality of monitoring paths by a data acquisition unit.
And selecting a proper region to be tested, and installing a plurality of sensors and a central ultrasonic generator according to a preset layout. The sensor and the generator are tightly attached to the area to be detected, so that accurate monitoring data can be obtained.
And constructing a plurality of monitoring paths according to the actual requirements and the shape of the region to be detected. These monitoring paths should cover all directions and critical areas of the area under test to ensure that their integrity is fully assessed. As shown in fig. 3, a schematic diagram of a monitoring path is shown.
The data acquisition unit is configured to be capable of respectively carrying out data acquisition on each monitoring path. The data acquisition unit can record the propagation time, speed and waveform of the ultrasonic wave in the region to be measured.
The data processing unit is used for analyzing the multiple groups of path data acquired by the data acquisition unit, extracting information about the structural strength and the integrity of the region to be detected, comparing the data of different monitoring paths, and selecting the monitoring path corresponding to the path data with the largest clustering gap value as the optimal monitoring path.
The monitoring unit extracts reflected wave signals in the optimal monitoring path data.
The processor carries out convolution operation on the reflected wave signals extracted by the monitoring unit, extracts the characteristics of the reflected wave and carries out characteristic mapping; classifying the feature mapped data based on a multi-data fusion algorithm,
And the evaluation unit is used for evaluating the strength state according to the classification result of the processor and evaluating the structural strength of the building. Further, corresponding advice or repair measures may be provided and detailed intensity detection reports generated based on the evaluation results.
In the above embodiments, it may be implemented in whole or in part by software, hardware, firmware, or any combination thereof. When implemented in software, may be implemented in whole or in part in the form of a computer program product. The computer program product includes one or more computer instructions. When loaded and executed on a computer, produces a flow or function in accordance with embodiments of the present application, in whole or in part. The computer may be a general purpose computer, a special purpose computer, a computer network, or other programmable apparatus. The computer instructions may be stored in or transmitted across a computer-readable storage medium. The computer readable storage medium may be any available medium that can be accessed by a computer or a data storage device such as a server, data center, etc. that contains an integration of one or more available media. The usable medium may be a magnetic medium (e.g., floppy disk, hard disk, tape), an optical medium (e.g., DVD), or a semiconductor medium (e.g., solid State Disk (SSD)), etc.
While the application has been described with reference to certain preferred embodiments, it will be understood by those skilled in the art that various changes and substitutions of equivalents may be made and equivalents will be apparent to those skilled in the art without departing from the scope of the application. Therefore, the protection scope of the application is subject to the protection scope of the claims.
Claims (2)
1. The method for detecting the strength of the engineering building is characterized by comprising the following steps of:
s1, constructing a plurality of monitoring paths of a region to be detected, and respectively acquiring path data of the plurality of monitoring paths;
S2, analyzing the collected multiple groups of path data, and selecting a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path;
the clustering gap value V D is:
;
wherein d b represents the outer gap, d w represents the inner gap, Represents the mean of class 1 data,/>Represents the average value of class 2 data, w represents the aggregation direction, T represents the transpose, x i represents the i-th data, n 1 represents the number of class 1 data, and n 2 represents the number of class 2 data;
S3, extracting reflected wave signals in the optimal monitoring path data;
x A (t) is the signal when weak intensity occurs at time t; x B (t) is the signal when the intensity is normal at time t; taking the peak of the head wave as a reference to perform normalization processing, wherein the signals after normalization processing are as follows:
;
;
In the middle of Is the maximum of the peak of the head wave of signal x A (t); /(I)Is the maximum of the peak of the head wave of signal x B (t);
the expression of the reflected wave signal r (t) is:
;
S4, carrying out convolution operation on the reflected wave signals, extracting the characteristics of the reflected wave and carrying out characteristic mapping;
The expression of reflected wave feature extraction is:
;
Wherein, Representing convolution operation, H being a convolution window; m represents the number of convolution kernels, M represents the total number of convolution kernels, and Y (t) is the characteristic of the output reflected wave;
Combining the reflected wave characteristics generated at all times T in the monitoring period T to form a reflected wave characteristic sequence, wherein the number of the reflected wave characteristic sequences is equal to the number of all times T in the monitoring period T;
set up the reflected wave signal sequence obtained in the monitoring period T Transmitting the reflected wave signal sequence to a full connection layer for weighted feature mapping:
;
;
;
Wherein W S is the weight of the full connection layer, b S is the bias term, u (t) is the output variable of the full connection layer, The weight of the output variable at the moment t is given, and f is the weighted feature mapping;
S5, classifying the data of the feature map based on a multi-data fusion algorithm so as to evaluate the strength state, and weighting the predicted value corresponding to the feature map f Expressed as:
;
The class function H is expressed as:
;
Where y represents the actual class, L is the error function, As a regularization function,/>And (3) the M-th iteration is performed on the diagnostic network model, M is the total iteration number, and Q is all mode spaces of the diagnostic network model.
2. An engineering building strength detection system for implementing the engineering building strength detection method of claim 1, comprising: the system comprises a plurality of sensors, a central ultrasonic generator, a data acquisition unit, a data processing unit, a monitoring unit and a processor;
Installing a plurality of sensors and a central ultrasonic generator on a region to be detected of a building, constructing a plurality of monitoring paths of the region to be detected, and respectively acquiring path data of the plurality of monitoring paths by a data acquisition unit;
the data processing unit analyzes the multiple groups of path data acquired by the data acquisition unit, and selects a monitoring path corresponding to the path data with the largest clustering gap value as an optimal monitoring path;
The monitoring unit extracts reflected wave signals in the optimal monitoring path data;
The processor carries out convolution operation on the reflected wave signals extracted by the monitoring unit, extracts the characteristics of the reflected wave and carries out characteristic mapping; classifying the feature mapped data based on a multi-data fusion algorithm;
and the evaluation unit is used for evaluating the intensity state according to the classification result of the processor.
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