CN111861906A - Pavement crack image virtual augmentation model establishment and image virtual augmentation method - Google Patents

Abstract

The invention belongs to the field of pavement crack image processing, and discloses a pavement crack image virtual augmentation model building and image virtual augmentation method. The model establishing method comprises the following steps: step 1: acquiring a pavement crack image, and sequentially performing data quality improvement and image segmentation on the pavement crack image to obtain a real pavement crack image set; step 2: establishing a DCGAN generation confrontation network model, wherein the DCGAN generation confrontation network model comprises a generator network and a discriminator network, and penalty terms are set behind loss functions of the generator network and the discriminator network; and step 3: and (3) acquiring random noise, inputting the random noise and the real pavement crack image set obtained in the step (1) into the DCGAN generation countermeasure network model obtained in the step (2) for training, wherein the trained model is the pavement crack image virtual augmentation model. The method effectively solves the problem of insufficient crack image data sets, and well realizes the increase of the number and the diversity of the crack image data sets.

Description

Pavement crack image virtual augmentation model establishment and image virtual augmentation method

Technical Field

The invention belongs to the field of pavement crack image processing, and particularly relates to a pavement crack image virtual augmentation model building and image virtual augmentation method.

Background

With the combination of the computer vision algorithm and the road image processing field, the artificial intelligence auxiliary pavement disease detection and maintenance become possible. In practical application, a crack detection model with good performance usually needs a large-scale and strong-diversity data set, but the acquisition of a crack image is a time-consuming and labor-consuming project, and the data requirement of the current deep learning network model is difficult to meet. Although the image data set is usually augmented by conventional methods such as turning, translation and the like at the present stage, the number of data set samples augmented by the method is limited and the diversity is poor, and if the data set is used for training models such as pavement crack detection, classification and segmentation, the trained network model lacks the generalization performance and is easy to generate the over-fitting phenomenon. Therefore, how to improve the phenomena of poor generalization capability of network models and model overfitting by improving the image augmentation method becomes a problem to be solved urgently.

Disclosure of Invention

The invention aims to provide a method for establishing a virtual augmentation model of a pavement crack image and a virtual augmentation method of the image, which are used for solving the problems that the augmentation technology in the prior art cannot augment the pavement crack in a large amount and high efficiency and the like.

In order to realize the task, the invention adopts the following technical scheme:

a method for establishing a virtual augmentation model of a pavement crack image comprises the following steps:

step 1: collecting a pavement crack image, and preprocessing the pavement crack image to obtain a real pavement crack image set, wherein the pavement crack is a transverse seam or a longitudinal seam;

step 2: establishing a DCGAN generation confrontation network model, wherein the DCGAN generation confrontation network model comprises a generator network and a discriminator network, and penalty terms are set behind loss functions of the generator network and the discriminator network;

and step 3: and (3) acquiring random noise, inputting the random noise and the real pavement crack image set acquired in the step (1) into the DCGAN generation countermeasure network model acquired in the step (2) for training, wherein the generator network model after training is the pavement crack image virtual augmentation model.

Furthermore, the generator network has 5 layers in total, the first layer is a full connection layer, the second layer to the fifth layer are convolution layers, and the convolution layers all adopt Relu as an activation function.

Furthermore, the discriminator network has 5 layers, the first to fourth layers are convolution layers, the fifth layer is a full connection layer, and the convolution layers all adopt leakyrelu as an activation function.

Further, the penalty function after adding the penalty term is

And is

Wherein X represents the input of the generator network and the discriminator network, y represents the output of the generator network and the discriminator network, w is a weight vector, alpha represents the value range of the regularization coefficient from 0 to 1, | | w | |₁Is the sum of the absolute values of the weights w in the model.

Further, the preprocessing in step 1 includes operations of color removal, noise removal, contrast enhancement, brightness enhancement and division into uniform sizes, which are performed in sequence.

An image virtual augmentation method comprising the steps of:

and acquiring random noise, and inputting the random noise into the pavement crack image virtual augmentation model acquired by any pavement crack image virtual augmentation model establishing method to acquire a pavement crack image augmentation data set.

Compared with the prior art, the invention has the following technical characteristics:

(1) the method uses the deep convolution generation type countermeasure network to generate the pavement crack image for the first time. The strategy of using the L1 regularization constraint is selected to reduce the test error in order to reduce the learning of the network to noise, enhance the generalization capability of the model, make the model smoother and prevent the over-fitting phenomenon.

(2) According to the method, the pavement crack image with more vividness and high quality is obtained by optimizing each hyper-parameter in the countermeasure network generated by adopting the deep convolution.

(3) The method provided by the invention effectively solves the problem of insufficient crack image data sets, and well realizes the expansion of the number and diversity of the crack image data sets.

Drawings

FIG. 1 is a general flow chart of the present invention;

FIG. 2 is a schematic diagram of a generative countermeasure network architecture;

FIG. 3 is a diagram of a generator network structure in a deep convolution generation countermeasure network;

FIG. 4 is a diagram of a discriminator network structure in a deep convolution generated countermeasure network;

FIG. 5 is a diagram showing the effect of generating transverse cracks in the crack growth model; wherein (a) is a 100epoch generated effect graph; (b) generating an effect graph for 200 epochs; (c) generating an effect map for 300 epoch; (d) generating an effect map for 400 epoch; (e) generating an effect map for 500 epochs; (f) generating an effect graph for 600 epoch;

FIG. 6 is a graph showing the effect of longitudinal seam formation in the crack growth model; wherein (a) is a 100epoch generated effect graph; (b) generating an effect graph for 200 epochs; (c) generating an effect map for 300 epoch; (d) generating an effect map for 400 epoch; (e) generating an effect map for 500 epochs; (f) generating an effect graph for 600 epoch;

FIG. 7 is a graph of the change in crack detection accuracy before and after data set expansion.

The details of the present invention are explained in further detail below with reference to the drawings and examples.

Detailed Description

The following embodiments of the present invention are provided, and it should be noted that the present invention is not limited to the following embodiments, and all equivalent changes based on the technical solutions of the present invention are within the protection scope of the present invention.

Example 1

The embodiment discloses a method for establishing a virtual augmentation model of a pavement crack image, which comprises the following steps:

step 1: collecting a pavement crack image, and preprocessing the pavement crack image to obtain a real pavement crack image set, wherein the pavement crack is a transverse seam or a longitudinal seam;

step 2: establishing a DCGAN generation confrontation network model, wherein the DCGAN generation confrontation network model comprises a generator network and a discriminator network, and penalty terms are set behind loss functions of the generator network and the discriminator network;

and step 3: and (3) acquiring random noise, inputting the random noise and the real pavement crack image set acquired in the step (1) into the DCGAN generation countermeasure network model acquired in the step (2) for training, wherein the generator network model after training is the pavement crack image virtual augmentation model.

The generator network is used for inputting random noise and outputting to generate a pavement crack image set, and the discriminator is used for inputting the generated pavement crack image set and the real pavement crack image set and outputting a real probability value.

Specifically, the random noise is generated by using TensorFlow.

Specifically, the preprocessing in step 1 includes operations of color removal, noise removal, contrast enhancement, brightness enhancement and division into uniform sizes, which are performed in sequence, and the quality of the preprocessed image data is improved.

Specifically, the real probability value in step 3 can represent the similarity between the picture generated by the generator and the real picture, and if the probability value is greater than 0.5, the input of the real probability value can be determined to be from the real data set; if the probability value is less than 0.5, the input is the newly generated data of the generation model;

specifically, the loss function of each training batch of the model is shown in formula (1),

is the true probability value, y, output by the jth training batch of the discriminator network_jThe model is a prediction probability value of the model, N is the total number of training batches, and the loss function value of the model is obtained by summing the loss function values of each batch and then averaging:

specifically, a gradient descent method is employed herein to update the values of the weight w and the offset b in each layer.

Specifically, the gradient is obtained through a back propagation algorithm, and in addition, in order to improve the training speed, the training data is divided into small batches (mini-batches). In each small batch, a small portion of the training samples is randomly selected at each step for gradient calculation. This has the advantage of increasing the speed of training.

Each cycle is defined as the process of a single full training of the training data, requiring multiple such cycles for the entire training process. At the end of each cycle, the penalty function used on the validation set is evaluated, and the network that minimizes the validation set penalty function is selected as the best choice. And training the generator according to the size of the loss function to guide the training direction of the model.

In the deep convolutional neural network, sample data is the basis of network training, and regularization constraints are guidelines for ensuring the network learning direction. In order to reduce the learning of noise by the network, reduce the test error, enhance the generalization capability of the model, make the model smoother and prevent the over-fitting phenomenon, the invention selects the strategy of using the L1 regularization constraint.

Specifically, the loss function after adding the penalty term is

And is

Wherein X represents the input of the generator network and the discriminator network, y represents the output of the generator network and the discriminator network, w is a weight vector, alpha represents the value range of the regularization coefficient from 0 to 1, | | w | | ₁Is the sum of the absolute values of the weights w in the model.

Graduating the above equation yields:

when w is positive, w becomes smaller after updating; when w is negative, updated w becomes larger. The distance is as close to 0 as possible, so that the complexity of the network is reduced, and the over-fitting phenomenon is prevented. When w is 0, | w | is not derivable, sign (0) is made 0, and the case where w is 0 is included in the regularization constraint.

The L1 regularization utilizes the sparse characteristic to carry out the feature selection, and selects the meaningful features from the feature subset, and the characteristic greatly simplifies the deep learning feature extraction problem, so that the generating effect of the generator is better.

Specifically, the generator network has 5 layers in total, wherein the convolutional layer is 4 layers, the fully-connected layer is 1 layer, and the specific operation is to use a random variable which is 100-dimensional and subject to (0,1) uniform distribution as the input of the generator. Firstly, the image is processed by a full connection layer to obtain a 4 x 1024 image, and then processed by 4 convolution kernels and a 5 x 5 transposition convolution layer to continuously enlarge the image, and finally, a crack image output by a generator is obtained. In the whole generator structure, the Relu activation function is used by other layers in the network except the first layer.

Specifically, the input of the discriminator is the generated crack image and the real crack image, and the output is a probability value for judging the authenticity, namely the value can judge the authenticity of the input image. The discriminator network used herein has a total of 5 layers, of which the convolutional layer is 4 layers and the fully connected layer is 1 layer. 64 × 64 × 3 images at the input of the discriminator. Firstly, the image is continuously downsampled for 4 times, the step length is 2, the size of a convolution kernel is 5 multiplied by 5, so that the image can be gradually reduced, and finally, a probability value representing the authenticity of the input image is obtained through a full connection layer. In the whole discriminator structure, the leakyrlelu function is adopted by other layers except the last layer without using the activation function.

Preferably, the optimizers of the generator and the arbiter are set to Adam optimizers, and the learning rates are set to 0.0002, and the convolution kernel sizes are 5 × 5.

Table 1 shows the network parameter settings for the deep convolution-generated countermeasure network constructed by the present invention;

table 1 DCGAN network parameter settings

FIG. 2 is a schematic diagram of a structure of a generative countermeasure network, which is mainly composed of two parts, including a generator and a discriminator

Fig. 3 is a diagram showing a structure of a generator network. The network structure is deconvolution (Decpmovavolvulsm), which is generally called Transposed Convolution (Transposed Convolution), that is, feature map size is gradually increased by means of learning. The input of the generated model in the training process is generally random noise Z, and new data G (Z) which is consistent with the real data distribution as much as possible is output directionally or non-directionally through a plurality of layers of transposition convolution calculation. Whether a generating network can produce high quality results depends on how the structure and parameters of the generating network are optimized.

Fig. 4 is a diagram showing the structure of the arbiter network. The network structure is similar to the traditional cyclic convolution neural network, and the features of the input image are extracted mainly through a plurality of convolutions, so that the size of the feature map of the hidden layer is generally reduced gradually. By inputting the real data set X and the new data G (z) generated by the generation model at the same time, obtaining an output probability value to judge whether the input of the input comes from the real data set, and if the probability value is more than 0.5, determining that the input comes from the real data set; if the probability value is less than 0.5, the input is the newly generated data of the generation model.

The method selects a Faster R-CNN detection model to evaluate the quality of the generated crack image and the reliability of the enhanced crack image data set.

Example 2

The embodiment discloses an image virtual augmentation method, which comprises the following steps:

and acquiring random noise, and inputting the random noise into the pavement crack image virtual augmentation model acquired by any pavement crack image virtual augmentation model establishing method to acquire a pavement crack image augmentation data set.

FIG. 5 is a cross-road joint effect diagram generated by the final optimized augmentation model. It can be seen from fig. 5 that the road surface transverse seam effect graph generated by the anti-network model generated by deep convolution becomes more and more vivid as the iteration number increases.

FIG. 6 is a road surface longitudinal seam effect diagram generated by the finally optimized augmentation model. From fig. 6, it can be seen that the pavement longitudinal seam effect graph generated by the anti-network model generated by deep convolution becomes more and more vivid as the iteration number increases.

FIG. 7 is a graph of the change in crack detection accuracy before and after data set expansion. The X axis represents a virtual crack image generated by a generation type countermeasure network, the Y axis represents the average accuracy of crack detection, and the orange curve represents a crack detection accuracy rate change curve of a Faster R-CNN detection model after 1000 real crack image data sets are expanded. It can be seen from the graph that as the number of virtual crack images gradually increases, the crack detection accuracy is also continuously improved. Tests show that under the condition that the number of real crack images is certain, when a generative confrontation network is used for amplifying an original training set, the crack detection accuracy of a crack detection model can be improved to a certain extent.

Claims (6)

1. A method for establishing a virtual augmentation model of a pavement crack image is characterized by comprising the following steps:

step 1: collecting a pavement crack image, and preprocessing the pavement crack image to obtain a real pavement crack image set, wherein the pavement crack is a transverse seam or a longitudinal seam;

Step 2: establishing a DCGAN generation confrontation network model, wherein the DCGAN generation confrontation network model comprises a generator network and a discriminator network, and penalty terms are set behind loss functions of the generator network and the discriminator network;

and step 3: and (3) acquiring random noise, inputting the random noise and the real pavement crack image set acquired in the step (1) into the DCGAN generation countermeasure network model acquired in the step (2) for training, wherein the generator network model after training is the pavement crack image virtual augmentation model.

2. The method for establishing the virtual augmented model of the pavement crack image as claimed in claim 1, wherein the generator network has 5 layers, the first layer is a full-connected layer, the second to fifth layers are convolutional layers, and the convolutional layers all adopt Relu as an activation function.

3. The method for building a virtual augmented model of a pavement crack image as claimed in claim 1, wherein the discriminator network has 5 layers, the first to fourth layers are convolutional layers, the fifth layer is a fully-connected layer, and the convolutional layers all adopt leakyrelu as an activation function.

4. The method for establishing a virtual augmented model of a pavement crack image according to claim 1, wherein the loss function after adding a penalty term is

And is

Wherein X represents the input of the generator network and the arbiter network and y represents the input of the generator network and the arbiter networkOutputting, wherein w is a weight vector, alpha represents that the value range of the regularization coefficient is 0 to 1, | w | | calculation₁Is the sum of the absolute values of the weights w in the model.

5. The method for establishing the virtual augmented model of the pavement crack image as claimed in claim 1, wherein the preprocessing in the step 1 comprises the operations of decoloring, denoising, contrast enhancement, brightness enhancement and segmentation into uniform size which are sequentially performed.

6. An image virtual augmentation method comprising the steps of:

acquiring random noise, inputting the random noise into the pavement crack image virtual augmentation model obtained by the pavement crack image virtual augmentation model establishing method according to any one of claims 1 to 5, and obtaining a pavement crack image augmentation data set.

Images