CN113823088A - Urban road ponding depth prediction and early warning method based on visual recognition technology - Google Patents
Urban road ponding depth prediction and early warning method based on visual recognition technology Download PDFInfo
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Abstract
The invention discloses an urban road ponding depth prediction and early warning method based on a visual recognition technology, which comprises the steps of constructing a target detection model of a scale feature object; collecting traffic intersection monitoring videos, preprocessing video images, then carrying out scale feature object detection, and carrying out distortion correction and anti-perspective transformation on detection results; calculating the depth of each position dot product water by using a proportional measurement and calculation method according to the target detection result of the scale feature object; displaying the depth of accumulated water at each position on a platform in a thermodynamic diagram mode; and constructing a time series model according to the existing water accumulation depth data, and predicting the water accumulation depth of the next time period by using the collected multiple rainfall and water accumulation depth data. According to the method, the characteristic point location information is extracted through the video data of the road video monitoring system, the ponding depth of the measuring point is calculated by using a perspective analysis algorithm, and the information is displayed by being superposed with an electronic map, so that waterlogging forecasting and early warning are conveniently carried out on a meteorological part, and waterlogging disasters are reduced.
Description
Technical Field
The invention relates to the technical field of urban waterlogging monitoring and early warning, in particular to an urban road waterlogging depth prediction and early warning method based on a visual recognition technology.
Background
Due to the fact that the temperature of the earth surface is increased due to global warming, extreme weather events, particularly extreme events such as heavy rainfall, high temperature heat waves and the like, show a continuously increasing trend in the last 50 years, and the occurrence of the extreme events is expected to be more frequent in the future. Heavy rainstorm and extreme rainfall events generate huge pressure on a drainage system of a city, and road ponding and waterlogging disasters occur frequently, so that serious inconvenience is brought to people for going out, and even serious loss of lives and properties is caused seriously.
Traditional rainstorm waterlogging mathematical model based on GIS, the basic spatial information such as set urban geography, river course topography, engineering facility, meteorological monitoring, flood control dispatch found can carry out the early warning forecast to the waterlogging situation to a certain extent, nevertheless receives the influence of factors such as data integrality, accuracy and model generalization, and mathematical model is difficult to provide real-time urban waterlogging information.
The monitoring and early warning system established based on water level rainfall sensing and the Internet of things technology and established in part of cities can provide real-time and accurate accumulated water point information, can improve the precaution level to a certain extent, and enhances the capability of resisting rainstorm disasters. The implementation of the technical scheme needs to rely on a large amount of hardware investment such as water level monitoring and sensing facilities, and large-area coverage and technical popularization are difficult.
At present, with the continuous promotion of construction projects such as smart cities, safe cities and the like, monitoring networks of cities at all levels have reached higher coverage, and monitoring technology is gradually developed from analog signals to high-definition digital technology. If the urban waterlogging early warning system can be developed based on the existing urban monitoring video resources by using the computer vision technology, the artificial intelligence algorithm, the video big data processing technology and the like, the waterlogging monitoring cost can be greatly saved, a point-and-face urban area full-coverage monitoring system is built, and a new method is provided for solving the urban waterlogging problem and perfecting a drainage system.
Disclosure of Invention
The purpose of the invention is as follows: aiming at the problems in the prior art, the invention provides an urban road water accumulation depth prediction and early warning method based on a visual recognition technology, which comprises the steps of collecting video data of a road video monitoring system, extracting feature point position information, recognizing scale features by using binarization processing and pixel feature recognition, calculating the water accumulation depth of a measuring point by using a ratio measuring and calculating party, superposing the information and an electronic map to realize data visualization, realizing water accumulation depth prediction by using a time sequence model, facilitating the early warning of waterlogging forecast in a meteorological part and reducing waterlogging disasters.
The technical scheme is as follows: the invention provides an urban road ponding depth prediction and early warning method based on a visual identification technology, which comprises the following steps:
step 1: constructing a target detection model of the scale feature, wherein the detection model adopts a YOLO v3 deep learning model to construct the target detection model of the scale feature;
step 2: collecting traffic intersection monitoring videos, preprocessing video images, then carrying out target detection on the scale feature objects, and carrying out distortion correction and anti-perspective transformation on the detection result images to obtain the front view of the scale feature objects;
and step 3: carrying out binarization processing and pixel feature identification on the scale feature front view in the step 2, and calculating the depth of each position dot product water by using a proportional calculation method;
and 4, step 4: building a WebGIS-based accumulated water depth product analysis platform, and displaying the accumulated water depth of each position in the step 3 on the platform in a thermodynamic diagram mode;
and 5: and constructing a time series model according to the existing water accumulation depth data, and predicting the water accumulation depth of the next time period by using the collected multiple rainfall and water accumulation depth data.
Further, the method for constructing the target detection model in the step 1 comprises the following steps:
s1.1: collecting an object image with scale characteristics at an urban traffic intersection, classifying the object image into classes, and measuring the characteristic sizes of different scale characteristics, wherein the specific classes comprise warning post, traffic indicating rod and signal lamp post scale characteristics, and the characteristic sizes mainly comprise ribbon height and distance between a top ribbon and the ground;
s1.2: labeling the picture by using LabelImg to obtain a tagged file in txt format matched with the picture;
s1.3: the Python script file makes the collected pictures into a training data set file 'train.txt' and a test data set file 'test.txt';
s1.4: and (4) inputting the data set file in the S1.3 into a YOLO v3 deep learning model to finish the training and testing of the target detection model.
Further, the video image preprocessing in the step 2 includes converting the video image into a frame-by-frame picture data set, and performing rain removing processing on the picture data by using a rain removing algorithm based on a GAN network.
Further, the specific method for detecting the scale feature target in the step 2 is as follows:
s2.1: reading a picture data set, transmitting the picture data set into the target detection model trained in the step 1 for detection, performing frame selection on scale feature objects in the picture, and identifying the scale category;
s2.2: capturing a local area picture of the scale feature according to the target detection result in the S2.1;
s2.3: and performing distortion correction and inverse perspective transformation on the local area picture by adopting a project points function of OpenCV to obtain a front view of the scale feature.
Further, the specific method for calculating the depth of the dot product water at each position in step 3 is as follows:
s3.1: establishing local picture templates at the joint of color bands of different colors according to the front view of the scale feature in the step 2;
s3.2: reading a feature image acquired by target detection, and matching a first red-white or other color interval region position by using a cv2.matchtemplate function of OpenCv so as to determine the position of an interval line;
s3.3: carrying out binarization processing on the picture, and circularly finding the initial position of a red-white or other color alternate region by pixel points from a first red-white or other color alternate spacing line so as to determine the height c of a first color band on the picture;
s3.4: reading the height of the whole picture through OpenCv to obtain the position of the bottom edge of the picture, and subtracting the position of the top of the color band according to the position of the top of the color band obtained in S3.3 to obtain the height x from the top to the bottom of the color band on the picture;
s3.5: and calculating the depth of the accumulated water by proportional measurement in combination with the known size of the scale features of the specific category, wherein the specific calculation formula is as follows:
wherein D is the depth of accumulated water; h is the actual height from the top end of the captured scale feature to the ground; s is the width of a single color band of the scale feature; x is the height of the first ribbon from top to bottom in the figure; c is the height of the first color bar on the graph.
Further, the concrete method for displaying the ponding depth product analysis platform in a thermodynamic diagram mode comprises the following steps:
s4.1: ID marking is carried out on the scaly structure, site water depth data are matched with site IDs, and site water depth display is carried out on a WebGIS through java calling of sites and site attributes;
s4.2: based on the site water depth data, carrying out water accumulation amount simulation operation by utilizing a site fitting technology to realize grid point interpolation of any region and different levels, storing the grid point data in a JavaScript Object Notation data format, carrying out segmentation marking on the road, matching the road section with the attribute according to the road section ID, finally constructing a WebGIS frame by adopting technologies such as Leafflet, Canvas and the like, and uniformly displaying the water depth site data and the road grid point data in a superimposed geographic information manner.
Further, the method for performing station water depth display on the WebGIS in the step S4.1 includes: the dots with colors are used for representing accumulated water with different degrees, and the accumulated water is divided into different grades according to the depth of the accumulated water:
1) slightly accumulating water for 0-10 cm, and labeling with blue;
2) slightly accumulating water by 10-15 cm, and labeling with yellow;
3) moderate water accumulation is 15-30 cm, and orange labeling is carried out;
4) severe water accumulation >30cm, red color was used.
Has the advantages that:
1. the method disclosed by the invention is mainly used for carrying out urban accumulated water depth identification based on the existing urban monitoring image, and does not need to build hardware facilities such as a newly-added rainfall sensor, so that the cost can be greatly reduced, the large-area coverage of a monitoring system can be realized, and the method has the advantages of good applicability, easiness in popularization and the like.
2. The invention utilizes the scale feature identified in the monitoring system to carry out scale extraction and anti-perspective correction, determines the height c on the image of the first color band and the height x on the image from the top end to the bottom of the color band in the image through binarization and pixel feature extraction methods according to the image data of the scale feature, and measures and calculates the depth of the accumulated water at any time by utilizing ratio measurement, thereby having high real-time performance.
3. The forecasting precision is continuously improved along with the accumulation of basic data based on the time series model, the forecasting precision is gradually improved, and the practicability and the commercial value are gradually improved after the operation.
Drawings
FIG. 1 is a technical route chart of the method for predicting and warning depth of accumulated water according to the present invention;
FIG. 2 is a schematic view of target detection of a scale feature of the present invention;
FIG. 3 is a water depth marker plot of a scale feature of the present invention;
FIG. 4 is a thermodynamic diagram showing the road water depth electronic map of the present invention;
FIG. 5 is a water accumulation depth warning visualization display diagram according to the present invention;
FIG. 6 is a schematic diagram of an alarm in which the depth of the water accumulated on the electronic map exceeds a threshold value.
Detailed Description
The invention is further described below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.
The invention discloses an urban road ponding depth prediction and early warning method based on a visual identification technology, which comprises the following steps:
step 1: and constructing a target detection model of the scale feature, wherein the detection model adopts a YOLO v3 deep learning model to construct the target detection model of the scale feature.
S1.1: the method comprises the steps of collecting object images with scale characteristics at urban traffic intersections, classifying the object images, measuring the characteristic sizes of different scale characteristics, mainly comprising the height of a color band and the distance between a top color band and the ground, and referring to the attached drawing 2.
S1.2: labeling the picture by using LabelImg to obtain a tagged file in txt format matched with the picture;
s1.3: the Python script file makes the collected pictures into a training data set file 'train.txt' and a test data set file 'test.txt';
s1.4: and (4) inputting the data set file in the S1.3 into a YOLO v3 deep learning model to finish the training and testing of the target detection model.
Step 2: collecting traffic intersection monitoring videos, preprocessing video images, then carrying out target detection on the scale feature objects, and carrying out distortion correction and anti-perspective transformation on the detection result images to obtain the front view of the scale feature objects.
The pretreatment comprises the following steps: and converting the video image into a frame-by-frame picture data set, and carrying out rain removing treatment on the picture data by using a rain removing algorithm based on a GAN network.
S2.1: reading a picture data set, transmitting the picture data set into the target detection model trained in the step 1 for detection, performing frame selection on the scale feature objects in the picture, and identifying the scale types, referring to the attached figures 2 and 3.
S2.2: and (4) capturing a local area picture of the scale feature according to the target detection result in the S2.1, and referring to the attached figure 3.
S2.3: and performing distortion correction and inverse perspective transformation on the local area picture by adopting a project points function of OpenCV to obtain a front view of the scale feature.
And step 3: and (4) calculating the depth of the dot product water at each position by using a proportional measurement and calculation method according to the target detection result of the standard ruler feature object in the step (2).
The specific method for calculating the depth of the dot product water at each position in the step 3 comprises the following steps:
s3.1: and establishing local picture templates at the joints of the color bands with different colors according to the scale features.
S3.2: and reading a feature image acquired by target detection, and matching the region position (or other colors) of the first red and white interval by using a cv2.matchtemplate function of OpenCv, so as to determine the position of the interval line.
S3.3: the picture is subjected to binarization processing, and from a first interval line with red and white intervals (or other colors, in the figure, the warning rods with red and white intervals are taken as an example), the pixel points circularly find the initial position of the red and white area, so that the height c of the first color band on the picture is determined.
S3.4: and reading the height of the whole picture through OpenCv to obtain the position of the bottom edge of the picture, and subtracting the position of the top of the color band according to the position of the top of the color band obtained in S3.3 to obtain the height x from the top to the bottom of the color band on the picture.
S3.5: and calculating the depth of the accumulated water by proportional measurement in combination with the known size of the scale features of the specific category, wherein the specific calculation formula is as follows:
wherein D is the depth of accumulated water; h is the actual height from the top end of the captured scale feature to the ground; s is the width of a single color band of the scale feature; x is the height of the first ribbon from top to bottom in the figure; c is the height of the first color bar on the graph.
And 4, step 4: and (4) constructing a water accumulation depth product analysis platform based on the WebGIS, and displaying the water accumulation depth at each position in the step (3) on the platform in a thermodynamic diagram mode.
S4.1: and (4) carrying out ID marking on the scaly structure, matching the site water depth data with the site ID, and carrying out site water depth display on the WebGIS by calling the site and the site attributes through java.
The dots with colors are used for representing accumulated water with different degrees, and the accumulated water is divided into different grades according to the depth of the accumulated water:
1) slightly accumulating water for 0-10 cm, and labeling with blue;
2) slightly accumulating water by 10-15 cm, and labeling with yellow;
3) moderate water accumulation is 15-30 cm, and orange labeling is carried out;
4) severe water accumulation >30cm, red color was used.
Referring to fig. 5 and fig. 6, the water depth result is matched with the map point location, different water depths are classified and displayed on the map in different colors, and data between intersections are filled by difference calculation. And displaying a warning signal for the point position with the water accumulation depth exceeding 30 cm.
S4.2: based on the site water depth data, carrying out water accumulation amount simulation operation by utilizing a site fitting technology to realize grid point interpolation of any region and different levels, storing the grid point data in a JavaScript Object Notation data format, carrying out segmentation marking on the road, matching the road section with the attribute according to the road section ID, finally constructing a WebGIS frame by adopting technologies such as Leafflet, Canvas and the like, and uniformly displaying the water depth site data and the road grid point data in a superimposed geographic information manner.
And 5: and constructing a time series model according to the existing water accumulation depth data, and predicting the water accumulation depth of the next time period by using the collected multiple rainfall and water accumulation depth data.
The above embodiments are merely illustrative of the technical concepts and features of the present invention, and the purpose of the embodiments is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.
Claims (7)
1. A method for predicting and early warning urban road ponding depth based on a visual identification technology is characterized by comprising the following steps:
step 1: constructing a target detection model of the scale feature, wherein the detection model adopts a YOLO v3 deep learning model to construct the target detection model of the scale feature;
step 2: collecting traffic intersection monitoring videos, preprocessing video images, then carrying out target detection on the scale feature objects, and carrying out distortion correction and anti-perspective transformation on the detection result images to obtain the front view of the scale feature objects;
and step 3: carrying out binarization processing and pixel feature identification on the scale feature front view in the step 2, and calculating the depth of each position dot product water by using a proportional calculation method;
and 4, step 4: building a WebGIS-based accumulated water depth product analysis platform, and displaying the accumulated water depth of each position in the step 3 on the platform in a thermodynamic diagram mode;
and 5: and constructing a time series model according to the existing water accumulation depth data, and predicting the water accumulation depth of the next time period by using the collected multiple rainfall and water accumulation depth data.
2. The urban road ponding depth prediction and early warning method based on the visual recognition technology as claimed in claim 1, wherein the target detection model and the basic method established in step 1 are as follows:
s1.1: collecting an object image with scale characteristics at an urban traffic intersection, classifying the object image into classes, and measuring the characteristic sizes of different scale characteristics, wherein the specific classes comprise warning post, traffic indicating rod and signal lamp post scale characteristics, and the characteristic sizes mainly comprise ribbon height and distance between a top ribbon and the ground;
s1.2: labeling the picture by using LabelImg to obtain a tagged file in txt format matched with the picture;
s1.3: the Python script file makes the collected pictures into a training data set file 'train.txt' and a test data set file 'test.txt';
s1.4: and (4) inputting the data set file in the S1.3 into a YOLO v3 deep learning model to finish the training and testing of the target detection model.
3. The urban road ponding depth prediction and early warning method based on the visual recognition technology as claimed in claim 1, wherein the video image preprocessing in the step 2 comprises converting the video image into a frame-by-frame picture data set, and performing rain removing processing on the picture data by using a rain removing algorithm based on a GAN network.
4. The urban road ponding depth prediction and early warning method based on the visual recognition technology as claimed in claim 1, wherein the specific method for detecting the scale feature object in step 2 is as follows:
s2.1: reading a picture data set, transmitting the picture data set into the target detection model trained in the step 1 for detection, performing frame selection on scale feature objects in the picture, and identifying the scale category;
s2.2: capturing a local area picture of the scale feature according to the target detection result in the S2.1;
s2.3: and performing distortion correction and inverse perspective transformation on the local area picture by adopting a project points function of OpenCV to obtain a front view of the scale feature.
5. The urban road ponding depth prediction and early warning method based on the visual recognition technology as claimed in claim 1, wherein the specific method for calculating the ponding depth at each position in step 3 is as follows:
s3.1: establishing local picture templates at the joint of color bands of different colors according to the front view of the scale feature in the step 2;
s3.2: reading a feature image acquired by target detection, and matching a first red-white or other color interval region position by using a cv2.matchtemplate function of OpenCv so as to determine the position of an interval line;
s3.3: carrying out binarization processing on the picture, and circularly finding the initial position of a red-white or other color alternate region by pixel points from a first red-white or other color alternate spacing line so as to determine the height c of a first color band on the picture;
s3.4: reading the height of the whole picture through OpenCv to obtain the position of the bottom edge of the picture, and subtracting the position of the top of the color band according to the position of the top of the color band obtained in S3.3 to obtain the height x from the top to the bottom of the color band on the picture;
s3.5: and calculating the depth of the accumulated water by proportional measurement in combination with the known size of the scale features of the specific category, wherein the specific calculation formula is as follows:
wherein D is the depth of accumulated water; h is the actual height from the top end of the captured scale feature to the ground; s is the width of a single color band of the scale feature; x is the height of the first ribbon from top to bottom in the figure; c is the height of the first color bar on the graph.
6. The urban road ponding depth prediction and early warning method based on the visual recognition technology as claimed in any one of claims 1 to 5, wherein the concrete method for displaying the ponding depth product analysis platform in a thermodynamic diagram manner is as follows:
s4.1: ID marking is carried out on the scaly structure, site water depth data are matched with site IDs, and site water depth display is carried out on a WebGIS through java calling of sites and site attributes;
s4.2: based on the site water depth data, carrying out water accumulation amount simulation operation by utilizing a site fitting technology to realize grid point interpolation of any region and different levels, storing the grid point data in a JavaScript Object Notation data format, carrying out segmentation marking on the road, matching the road section with the attribute according to the road section ID, finally constructing a WebGIS frame by adopting technologies such as Leafflet, Canvas and the like, and uniformly displaying the water depth site data and the road grid point data in a superimposed geographic information manner.
7. The urban road ponding depth prediction and early warning method based on the visual recognition technology as claimed in claim 6, wherein the method for performing site water depth display on the WebGIS in the step S4.1 is as follows: the dots with colors are used for representing accumulated water with different degrees, and the accumulated water is divided into different grades according to the depth of the accumulated water:
1) slightly accumulating water for 0-10 cm, and labeling with blue;
2) slightly accumulating water by 10-15 cm, and labeling with yellow;
3) moderate water accumulation is 15-30 cm, and orange labeling is carried out;
4) severe water accumulation >30cm, red color was used.
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