CN113257000A - Intelligent detection early warning system and method for road black ice - Google Patents

Abstract

The invention discloses an intelligent detection and early warning system and method for black ice on a road, which comprises a front-end system and an Internet of things platform in signal connection with the front-end system, wherein the front-end system comprises: the main body structure comprises a base arranged on an anti-collision fence of a highway, a vertical rod vertically arranged on the base and an electric box, wherein the bottom of the electric box is communicated with the external environment; the power supply system comprises a solar panel arranged at the top end of the upright rod and a storage battery which is arranged in the electric box and is electrically connected with the solar panel; the sensor system comprises a plurality of redundant temperature sensors, a humidity sensor and a condensation ice sensor which are arranged in an electric box; the intelligent gunlock recognition system comprises an AI camera with edge computing capability and an RS-485 communication line; the sensor system and the intelligent bolt system identification system are electrically connected with the storage battery.

Description

Intelligent detection early warning system and method for road black ice

Technical Field

The invention relates to the field of road traffic, in particular to an intelligent detection and early warning system and method for road black ice.

Background

Black Ice, known by the english name Black Ice, refers to a very thin layer of Ice that covers roads and is difficult to find. Because the thickness of the road is very thin, the asphalt color of the road can be transmitted out of the road, so that the visibility of the ice surface is very low, and the road is integrated with the road and is very difficult to find. Since the temperature of the thin black ice is not particularly low, a layer of melted water is present on the surface of the ice, allowing the ice to slide more than a thick ice having a low temperature. The black ice can cause the vehicle to slip, spin and brake for a significantly longer distance.

Disclosure of Invention

In order to solve the technical problems, the invention provides an intelligent detection and early warning system and method for road black ice.

In order to solve the technical problems, the invention adopts the following technical scheme:

the utility model provides a road black ice intelligent detection early warning system, includes front end system and the thing networking platform of being connected with front end system signal, front end system includes:

the main body structure comprises a base arranged on an anti-collision fence of a highway, a vertical rod vertically arranged on the base and an electric box, wherein the bottom of the electric box is communicated with the external environment;

the power supply system comprises a solar panel arranged at the top end of the upright rod and a storage battery which is arranged in the electric box and is electrically connected with the solar panel;

the sensor system comprises a plurality of redundant temperature sensors, a humidity sensor and a condensation ice sensor which are arranged in an electric box;

the intelligent gunlock recognition system comprises an AI camera with edge computing capability and an RS-485 communication line;

the sensor system and the intelligent bolt system identification system are electrically connected with the storage battery.

A detection and early warning method of an intelligent detection and early warning system for road black ice comprises the following steps:

step A: the sensor system periodically detects and judges the occurrence condition of the black ice on the road through a pre-constructed decision tree model;

and B: training a convolutional neural network through a road black ice image with textural features, activating an AI camera and acquiring a road image within the working time period of a sensor system, and inputting the road image into the convolutional neural network to judge whether the road has black ice;

and C: if the sensor system and the intelligent gunlock recognition system both judge that black ice appears on the road, an early warning is sent out through an early warning unit; if only one of the sensor system and the intelligent gunlock recognition system judges that the road is black ice, prompting is carried out through the monitoring terminal;

wherein, step A includes:

step A1: collecting multiple groups of historical road characteristic data and corresponding black ice occurrence conditions to form multiple characteristic data, and calculating the entropy of each characteristic data;

step A2: selecting feature data with the maximum entropy as current splitting features, and constructing a decision tree model by calculating the information gain rate of each feature data;

step A3: and inputting real-time road characteristic data into the decision tree model, and judging the occurrence condition of the black ice.

In particular, the road characteristic data includes an atmospheric temperature, a ground humidity, and an air humidity of the road region.

Specifically, in step a1, three-quarters of the feature data are used as the training data set, one-quarter of the feature data are used as the test data set, and the entropy of each feature data in the training data set is calculated

p_iIndicating the probability of the occurrence of black ice on the road.

Specifically, in step a1, a C4.5 decision tree algorithm model is introduced, the feature data with the maximum entropy is selected as the current splitting feature, the information gain rate of each feature data is calculated, the feature data with the highest information gain rate is used as the root node of the decision tree model, the feature data with the information gain rate higher than the average level is used as the upper node of the decision tree model, and the feature data with the information gain rate lower than the average level is used as the leaf node of the decision tree model.

Specifically, before road characteristic data are input into a decision tree model, pruning operation and evaluation are carried out on the decision tree model; calculating GINI coefficient when pruning the decision tree model

p_kRepresenting the probability value of the occurrence of black ice on the road; calculating loss

C_α(T)＝C(T)+α|T_leaf|；

Wherein, c (t) ═ gini (p) × n_L]，n_LIs the number of samples in the leaf node, | T_leafI is the leaf node number, and alpha is a regularization term;

and when the decision tree model is evaluated, importing the test data set into the decision tree model, and verifying the prediction precision of the decision tree model on the black ice generation condition.

Specifically, in the step B, a road image with black ice is collected in advance, graying processing, binarization processing and texture extraction are sequentially carried out, and the obtained road black ice image with texture features is led into a convolutional neural network for training; and the AI camera inputs the acquired road image into the convolutional neural network to judge whether black ice appears on the road.

Specifically, when the road image is subjected to the graying processing, a weighted average algorithm is adopted, and the grayscale value Gray (i, j) of any pixel (i, j) is 0.299R (i, j) +0.578G (i, j) +0.114B (i, j); where R (i, j) is the red channel value of the pixel, G (i, j) is the green channel value of the pixel, and B (i, j) is the blue channel value of the pixel.

Specifically, when the road image is subjected to binarization processing, an adaptive threshold segmentation method is adopted.

Specifically, when texture extraction is carried out on a road image, a gray level co-occurrence matrix of the road image is extracted, wherein the gray level is 0-1, and the method comprises the following steps:

selecting any point T (x, y) on the road image and a deviation point T '(x + a, y + b) thereof to form a point pair (T, T'), wherein the corresponding gray value is (i, j), the values of (a, n) are respectively (0,1), (1,0), (1,1) and (-1,1), and four gray level co-occurrence matrixes G1, G2, G3 and G4 are obtained;

and respectively calculating the contrast, energy and entropy of the texture features of the road image for the four gray level co-occurrence matrixes.

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

the sensor system and the intelligent gunlock recognition system are used for detecting the occurrence condition of black ice on a road, and the sensor system and the intelligent gunlock recognition system are high in power consumption, so that the sensor system and the intelligent gunlock recognition system can work at a certain time interval, and the time interval can be set manually; during the operation of the sensor system and the intelligent gunlock recognition system, the occurrence condition of the black ice on the road is detected and judged simultaneously, and the occurrence condition of the black ice on the road is comprehensively judged according to the detection results of the two systems, so that the accuracy of black ice detection is improved.

Drawings

FIG. 1 is a diagram of a detection and warning system according to the present invention;

FIG. 2 is a flow chart of a detection and early warning method of the present invention;

FIG. 3 is the code of the API interface of the adaptive threshold partitioning method of the present invention;

FIG. 4 is a parameter description of the API interface of the adaptive threshold partitioning method of the present invention.

Detailed Description

A preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings.

The main body structure is used for carrying a power supply system, an intelligent bolt face recognition system and a sensor system; the base is arranged on an anti-collision fence of a road; the electric box is arranged on the base and is 0.4-0.5 m away from the ground; the upright pole is fixed with the electric box; the storage battery is arranged in the electric box. Solar panel installs on the pole setting top, and solar energy supplies power for intelligent rifle bolt identification system, sensor system.

The AI camera is installed in the pole setting, and the AI camera has marginal computing power, can embed black ice, ordinary ice surface, snow surface, surface of water and normal road surface image recognition algorithm, has 4G communication ability, can regularly take a candid photograph analysis, remote control candid photograph, long-range real-time video of watching.

And the RS485 communication line is connected with the AI camera and is used for signal transmission.

The sensor system is arranged in the electric box and is provided with a plurality of paths of redundant temperature sensors, humidity sensors and condensation ice sensors, and the redundant sensors are additionally arranged outside the normal working sensors for improving the reliability of the system.

The bottom of the electrical appliance box is designed into a micro weather station mode, and the electrical appliance box is ventilated, can reach the same weather conditions as the road surface, and can be dustproof and waterproof.

The Internet of things platform is located at a far end and comprises a monitoring server, a monitoring terminal and an early warning unit, wherein the monitoring server, the monitoring terminal and the early warning unit are used for receiving data results of road surface detection and providing road surface conditions for workers.

The detection early warning system transmits a real-time video and an analysis result back to the Internet of things platform through the 4G signal.

A detection and early warning method of an intelligent detection and early warning system for road black ice comprises the following steps:

step A: the sensor system periodically detects and judges the occurrence condition of the black ice on the road through a pre-constructed decision tree model;

and B: training a convolutional neural network through a road black ice image with textural features, activating an AI camera and acquiring a road image within the working time period of a sensor system, and inputting the road image into the convolutional neural network to judge whether the road has black ice;

and C: and comprehensively judging the occurrence condition of the black ice on the road through the detection results of the sensor system and the gun-shooter identification system.

Specifically, step C is classified into two cases, C1 and C2.

Where case C1 is: and if the sensor system and the intelligent bolt face recognition system both judge that black ice appears on the road, an early warning is sent out through the early warning unit.

Case C2 is: in order to prevent the sensor system or the intelligent gun bolt recognition system from generating false alarm, if only one of the sensor system and the intelligent gun bolt recognition system judges that black ice appears on a road, the situation is only prompted through the monitoring terminal, and a worker is required to verify whether the situation is false alarm or not.

The case C2 is classified into two cases, C21 and C22.

Where case C21 is: if the sensor system judges that the black ice appears on the road, the worker can call the monitoring picture of the AI camera to continuously observe for a period of time so as to judge whether the black ice appears.

Case C22 is: if the intelligent gunlock recognition system judges that black ice appears on the road, the worker resets the sensor system, the sensor system works again, and numerical value changes of the multiple paths of redundant temperature sensors, the humidity sensor and the condensation ice sensor are continuously observed to judge whether the black ice appears.

Wherein, step A includes:

step A1: and collecting multiple groups of historical road characteristic data and corresponding black ice occurrence conditions to form multiple characteristic data, and calculating the entropy of each characteristic data.

In particular, the road characteristic data includes an atmospheric temperature, a ground humidity, and an air humidity of the road region.

In this embodiment, three-quarters of the feature data are used as the training data set, and one-quarter of the feature data are used as the test data set.

Constructing a sample corpus H { (M) from a training dataset₁,N₁),(M₂,N₂),…(M_i,N_i) In which M is_iMeasured values representing road characteristic data, N_iAnd i represents the actual condition of the road with black ice, namely whether the road has the black ice or not, and the reference numeral of the training data.

Computing entropy for each feature data in a training dataset

p_iIndicating the probability of the occurrence of black ice on the road.

Step A2: and selecting the feature data with the maximum entropy as the current splitting feature, and constructing a decision tree model by calculating the information gain rate of each feature data.

Specifically, in step a2, a C4.5 decision tree algorithm model is introduced, the feature data with the maximum entropy is selected as the current splitting feature, the information gain rate of each feature data is calculated, the feature data with the highest information gain rate is used as the root node of the decision tree model, the feature data with the information gain rate higher than the average level is used as the upper node of the decision tree model, and the feature data with the information gain rate lower than the average level is used as the leaf node of the decision tree model, so as to construct the decision tree model and design the output value.

Specifically, before road characteristic data are input into a decision tree model, pruning operation and evaluation are carried out on the decision tree model; the criteria for carrying out the pruning operation are: the more leaf nodes, the larger the penalty C function.

When the decision tree model is pruned, the GINI coefficient is calculated firstly

p_kRepresenting the probability value of the occurrence of black ice on the road; recalculating loss

C_α(T)＝C(T)+α|T_leaf|；

Wherein, c (t) ═ gini (p) × n_L]，n_LIs the number of samples in the leaf node, | T_leafAnd | is the number of leaf nodes and α is a regularization term.

The parameter alpha controls the degree of influence between the two, a larger alpha facilitates the selection of a simpler decision tree model, and a smaller alpha facilitates the selection of a more complex decision tree model.

And when the decision tree model is evaluated, importing the test data set into the decision tree model, and verifying the prediction precision of the decision tree model on the black ice generation condition.

Step A3: and inputting real-time road characteristic data into the decision tree model, and judging the occurrence condition of the black ice.

The method comprises the steps that an AI camera collects road images, in consideration of the problem of power consumption, a sensor system collects data once every 5-10 minutes, the sensor system is in a sleep working mode at other times, and the AI camera is awakened to capture road images while the sensor system operates; the AI camera may also be set to capture video at intervals, such as capturing a 15-second video stream every 3 minutes after 8 pm to 6 am, where the video stream is processed into a sequence of images by the AI camera to form an image group.

Before recognition, image processing needs to be performed on the acquired single image or image group.

Specifically, in the step B, a road image with black ice is collected in advance, graying processing, binarization processing and texture extraction are sequentially carried out, and the obtained road black ice image with texture features is led into a convolutional neural network for training; and the AI camera inputs the acquired road image into the convolutional neural network to judge whether black ice appears on the road.

Specifically, when the road image is subjected to the graying processing, a weighted average algorithm is adopted, and the grayscale value Gray (i, j) of any pixel (i, j) is 0.299R (i, j) +0.578G (i, j) +0.114B (i, j); where R (i, j) is the red channel value of the pixel, G (i, j) is the green channel value of the pixel, and B (i, j) is the blue channel value of the pixel.

Specifically, when the road image is subjected to binarization processing, a self-adaptive threshold segmentation method is adopted; specifically, a corresponding API interface in the Opencv software library is called, as shown in fig. 3 to 4, where:

InputArray src denotes an input image;

OutputArray dst represents an output image, which is in accordance with the input image size;

int ADAPTIVE method represents an algorithm adopted for calculating the threshold in a neighborhood, and has two values, namely ADAPTIVE _ threshold _ MEAN _ C and ADAPTIVE _ threshold _ GAUSSIAN _ C;

the calculation method of ADAPTIVE _ THRESH _ MEAN _ C is to calculate the average value of the neighborhood and then subtract the value of the parameter double C;

the calculation method of ADAPTIVE _ THRESH _ GAUSSIAN _ C is to calculate the GAUSSIAN mean value of the field and then subtract the value of the parameter double C;

int threshold type is a threshold type, and only two values are provided, namely threshold _ BINARY and threshold _ BINARY _ INV;

the calculation unit of adaptiveThreshold is a neighborhood block of image pixels, int blockSize is the size of a local neighborhood, 3, 5, 7 and the like;

double C is the offset adjustment amount;

the final threshold value is obtained by subtracting the offset value adjustment quantity from the mean value and Gaussian calculation threshold value, so that the binary road image is obtained, the analysis of the black ice condition of the road is facilitated, and the influence of uneven illumination distribution on image processing is reduced.

Specifically, when texture extraction is carried out on a road image, a gray level co-occurrence matrix of the road image is extracted, wherein the gray level is 0-1, and the method comprises the following steps:

selecting any point T (x, y) on the road image and a deviation point T '(x + a, y + b) thereof to form a point pair (T, T'), wherein the corresponding gray value is (i, j), the values of (a, b) are respectively (0,1), (1,0), (1,1) and (-1,1), and four gray level co-occurrence matrixes G1, G2, G3 and G4 are obtained;

and respectively calculating the contrast, energy and entropy of the texture features of the road image for the four gray level co-occurrence matrixes.

Contrast con ═ Σ (i-j)²p (x, y); if the contrast is high, the characteristic texture is obvious, and if the contrast is low, the characteristic texture is fuzzy;

energy Asm ═ sigma-p (x, y)²(ii) a The energy is small, which indicates that the characteristic texture is fine; high energy, indicating coarse texture;

entropy Ent ═ Σ p (i, j) log₂p (i, j), wherein (i, j) represents the gray value of a pair of points (T, T') in the image; p (i, j) is the probability of the occurrence of the point pair (T, T').

And then, guiding the road black ice image with the texture features into a convolutional neural network for training, wherein the convolutional neural network in the embodiment is a VGG-16 network.

And the AI camera compares the acquired single image or image group with the road black ice image with the texture characteristics to judge whether the road generates black ice.

The detection results of the two systems are used for comprehensively judging the occurrence condition of the black ice on the road, so that the accuracy of black ice detection is improved; the intelligent gunlock recognition system, the sensor system feedback and the historical experience can be simultaneously integrated, for example, information such as the time interval of road black ice generation, the time period of black ice generation, the road section prone to black ice generation and the like in the past year is obtained, a comprehensive early warning result is obtained, then related data are returned to the Internet of things platform through the 4G communication system, the monitoring server responds, the monitoring terminal displays the road condition, and the early warning unit starts a corresponding warning process.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein, and any reference signs in the claims are not intended to be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The utility model provides a road black ice intelligent detection early warning system which characterized in that, including front end system and with front end system signal connection's thing networking platform, front end system includes:

the main body structure comprises a base arranged on an anti-collision fence of a highway, a vertical rod vertically arranged on the base and an electric box, wherein the bottom of the electric box is communicated with the external environment;

the power supply system comprises a solar panel arranged at the top end of the upright rod and a storage battery which is arranged in the electric box and is electrically connected with the solar panel;

the sensor system comprises a plurality of redundant temperature sensors, a humidity sensor and a condensation ice sensor which are arranged in an electric box;

the intelligent gunlock recognition system comprises an AI camera with edge computing capability and an RS-485 communication line;

the sensor system and the intelligent bolt face recognition system are electrically connected with the storage battery;

the Internet of things platform is located at a far end and comprises a monitoring server, a monitoring terminal and an early warning unit.

2. A detection and early-warning method of the intelligent detection and early-warning system for the black ice on the road as claimed in claim 1, comprising the following steps:

step A: the sensor system periodically detects and judges the occurrence condition of the black ice on the road through a pre-constructed decision tree model;

and B: training a convolutional neural network through a road black ice image with textural features, activating an AI camera and acquiring a road image within the working time period of a sensor system, inputting the road image into the convolutional neural network for comparison, and judging whether the road has black ice or not;

and C: if the sensor system and the intelligent gunlock recognition system both judge that black ice appears on the road, an early warning is sent out through an early warning unit; if only one of the sensor system and the intelligent gunlock recognition system judges that the road is black ice, prompting is carried out through the monitoring terminal;

wherein, step A includes:

step A1: collecting multiple groups of historical road characteristic data and corresponding black ice occurrence conditions to form multiple characteristic data, and calculating the entropy of each characteristic data;

step A2: selecting feature data with the maximum entropy as current splitting features, and constructing a decision tree model by calculating the information gain rate of each feature data;

step A3: and inputting real-time road characteristic data into the decision tree model, and judging the occurrence condition of the black ice.

3. The detection and early-warning method of the intelligent detection and early-warning system for the black ice on the road as claimed in claim 2, wherein the road characteristic data comprises the atmospheric temperature, the ground humidity and the air humidity of the road area.

4. The method as claimed in claim 2, wherein in step a1, three quarters of the feature data are used as training data set, one quarter of the feature data are used as test data set, and entropy of each feature data in the training data set is calculated

p_iIndicating the probability of the occurrence of black ice on the road.

5. The detection and early-warning method of the intelligent detection and early-warning system for the road black ice according to claim 4, wherein in the step A2, a C4.5 decision tree algorithm model is introduced, the feature data with the maximum entropy is selected as the current splitting feature, the information gain rate of each feature data is calculated, the feature data with the highest information gain rate is used as the root node of the decision tree model, the feature data with the information gain rate higher than the average level is used as the upper node of the decision tree model, and the feature data with the information gain rate lower than the average level is used as the leaf node of the decision tree model.

6. The detection and early-warning method of the intelligent detection and early-warning system for the black ice on the road according to claim 5, wherein the method comprises the following steps: before inputting the road characteristic data into the decision tree model, pruning and evaluating the decision tree model; calculating GINI coefficient when pruning the decision tree model

p_kRepresenting the probability value of the occurrence of black ice on the road; calculating loss

C_α(T)＝C(T)+α|T_leaf|；

Wherein, c (t) ═ gini (p) × n_L]，n_LIs the number of samples in the leaf node, | T_leafI is the leaf node number, and alpha is a regularization term;

and when the decision tree model is evaluated, importing the test data set into the decision tree model, and verifying the prediction precision of the decision tree model on the black ice generation condition.

7. The detection and early-warning method of the intelligent detection and early-warning system for the road black ice according to claim 2, wherein in the step B, a road image with the black ice is collected in advance, graying processing, binarization processing and texture extraction are sequentially carried out, and the obtained road black ice image with the texture features is led into a convolutional neural network for training; and the AI camera inputs the acquired road image into the convolutional neural network to judge whether black ice appears on the road.

8. The detection and early-warning method of the intelligent detection and early-warning system for the black ice on the road according to claim 7, wherein when graying the road image, a weighted average algorithm is adopted, and the Gray value Gray (i, j) of any one pixel (i, j) is 0.299R (i, j) +0.578G (i, j) +0.114B (i, j); where R (i, j) is the red channel value of the pixel, G (i, j) is the green channel value of the pixel, and B (i, j) is the blue channel value of the pixel.

9. The detection and early-warning method of the intelligent detection and early-warning system for the black ice on the road as claimed in claim 7, wherein an adaptive threshold segmentation method is adopted when the road image is subjected to binarization processing.

10. The detection and early-warning method of the intelligent detection and early-warning system for the black ice on the road according to claim 7, wherein when texture extraction is performed on the road image, a gray level co-occurrence matrix of the road image is extracted, and the gray level is 0-1, and the method comprises the following steps:

selecting any point T (x, y) on the road image and a deviation point T '(x + a, y + b) thereof to form a point pair (T, T'), wherein the corresponding gray value is (i, j), the values of (a, b) are respectively (0,1), (1,0), (1,1) and (-1,1), and four gray level co-occurrence matrixes G1, G2, G3 and G4 are obtained;

and respectively calculating the contrast, energy and entropy of the texture features of the road image for the four gray level co-occurrence matrixes.

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