Abstract
In this paper, we propose 4 theoretical models to deal with the wild hornet crisis. First, we use ORIGIN to visualize the distribution of wild wasps. Using the least square method and the grey system GM (1, 1), we establish a theoretical model to predict the propagation of wild wasps over time and analyze the accuracy of the model. However, the accuracy of our model is not very high, which results from the influence of many factors such as climate and human. Secondly, we use convolution neural network to recognize the images. With the increase of network depth, the accuracy rate reaches a bottleneck, which can help predict mistaken classification. We also use the SIR infectious disease model based on the dataset file provided. In the model, we mark the confirmed giant hornet as the infected state I (infected), mark the nonwild wasp as the removed state R (removed, refractory, or recovered), and mark the unclassified and unverified wild wasp as the susceptible state S (susceptible). A model to predict the possibility of misclassification was established by considering the normal death of wild wasp. Thirdly, by analogy with the SIR model, when the epidemic occurs, people pay more attention to the infected person. Thus, the SIR model will lead to the most likely positive sightings. Then, in order to ensure the timeliness and accuracy, the model must be updated once a year by changing or adding parameter according to local conditions. Finally, by establishing an optimized SIR infectious disease model, we added the factor of the Washington state’s control of wild wasps. The analysis shows that the number of infected I (i.e., wild wasps) has tended to zero after 250 days, so it can be proved that the Washington state has eliminated the pest.
Highlights
Experimental simulation proves that the proposed method has high measurement accuracy and greatly improves the accuracy of predicting the number of wild wasps
We use the SIR infectious disease model based on the dataset file provided and regard the identified wild wasps as infected state I (I), excluded as removed state R (R as susceptible state (S)), a model to predict the possibility of misclassification was established by considering the normal death of wild wasp
Backpropagation algorithm is the most commonly used algorithm with minimum error for training convolutional neural network. e main principles are as follows: the DataTrain data is input into the convolution layer of the CNN, it passes through the neuron, and it reaches the convolution kernel and outputs the result. e
Summary
En, we establish a model to predict the propagation of wild wasps over time based on least square method and grey system GM (1, 1). We use the SIR infectious disease model based on the dataset file provided and regard the identified wild wasps as infected state I (I), excluded as removed state R (R as susceptible state (S)), a model to predict the possibility of misclassification was established by considering the normal death of wild wasp. Erefore, we use least squares, grey systems, convolutional neural networks, and SIR infectious disease models to focus on the distribution and prediction of wild wasps based on the given data. E following is the number of wild wasps found in 2019 and 2020, and we will use the 2019 data to predict the 2020 data and compare the 2020 data with the 2020 real data to verify the feasibility of the model as shown in Tables 1 and 2. We used t-test to detect the significance of regression coefficient
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