CN113100207A - Accurate formula pesticide application robot system based on wheat disease information and pesticide application method - Google Patents

Abstract

The invention provides a precise formula pesticide application robot system and a precise formula pesticide application method based on wheat disease information, which are used for solving the technical problems of pesticide waste and environmental pollution caused by poor accuracy of the conventional automatic pesticide spraying technology for crops. The system includes industry camera, microspur camera, PC, prescription pond, accurate controller and the shower nozzle of giving medicine to the poor free of charge, the PC is connected with industry camera, microspur camera, prescription pond and accurate controller of giving medicine to the poor free of charge respectively, and the prescription pond is connected with accurate controller of giving medicine to the poor free of charge, and accurate controller of giving medicine to the poor free of charge is connected with the shower nozzle of giving medicine to the poor free of charge. The invention has certain advantages in the aspects of disease type identification and formula preparation, has good effect in the aspect of identifying wheat disease types, has stronger advantages in the aspect of giving formulas based on disease severity, and has stronger adaptability and higher identification accuracy.

Description

Accurate formula pesticide application robot system based on wheat disease information and pesticide application method

Technical Field

The invention relates to the technical field of agricultural engineering, in particular to a precise formula pesticide application robot system and a pesticide application method based on wheat disease information.

Background

In recent years, with the development of computer technology, precise drug delivery robot systems have gained more and more attention. The realization of accurate pesticide application in agricultural production by using computer image processing and computer vision technology is also gradually developed. The digital image processing algorithm has great advantages in the aspects of automatic alignment and automatic identification, and is the basis and key technology of modern precision agriculture. According to the requirement of accurate pesticide application, the identification accuracy of the crop row center line can influence the alignment accuracy of a pesticide spraying nozzle, so that pesticide waste or environment pollution is easily caused; the accuracy of disease type identification and the disease severity can have great influence on the effect of accurate pesticide application, and the disease type can be applied according to the symptoms only by accurately judging the disease type, so that pesticide waste can be reduced by determining the disease severity, and the quantitative pesticide application is carried out. At present, no universal accurate pesticide application algorithm which has adaptability completely meeting the requirements exists at home and abroad, and no large-scale accurate pesticide application machine or accurate pesticide application robot which can realize the functions is available.

Disclosure of Invention

Aiming at the defects in the background technology, the invention provides a precise formula pesticide application robot system and a pesticide application method based on wheat disease information, and solves the technical problems of pesticide waste and environmental pollution caused by poor accuracy of the existing automatic pesticide spraying technology for crops.

The technical scheme of the invention is realized as follows:

the utility model provides an accurate prescription robot system that gives medicine to poor free of charge based on wheat disease information, includes industry camera, microspur camera, PC, prescription pond, accurate controller and the shower nozzle of giving medicine to poor free of charge, the PC is connected with industry camera, microspur camera, prescription pond and accurate controller of giving medicine to poor free of charge respectively, and the prescription pond is connected with accurate controller of giving medicine to poor free of charge, and accurate controller of giving medicine to poor free of charge is connected with the shower nozzle of giving medicine to poor free of charge.

Preferably, the PC comprises a disease recognition system, a crop row recognition system and a formula expert system, wherein the disease recognition system is respectively connected with the macro camera and the formula expert system, the formula expert system is connected with the formula pool, and the crop row recognition system is respectively connected with the industrial camera and the accurate pesticide application controller.

A pesticide application method of a precise formula pesticide application robot system based on wheat disease information comprises the following steps:

s1, acquiring an image of the wheat crop by using an industrial camera, and transmitting the image to a crop row recognition system of a PC (personal computer) to obtain deviation information of the pesticide application spray head and the crop row;

s2, acquiring a leaf disease image of the wheat crop by using a macro camera, and transmitting the leaf disease image to a disease identification system of a PC (personal computer) to obtain the disease type and the disease degree;

s3, transmitting the disease types and the disease degrees in the step S2 to a formula expert system, and preparing pesticide types and pesticide spraying amount in a formula pool through the formula expert system to obtain pesticide solution;

s4, transmitting deviation information of the pesticide applying spray head and the crop row in the step S1 to the accurate pesticide applying controller, and controlling the position of the pesticide applying spray head by the accurate pesticide applying controller to spray the pesticide solution in the step S3 to the ill-conditioned wheat crop to realize accurate pesticide applying of the wheat crop.

Preferably, in the step S1, the method of transmitting the image to the crop row recognition system of the PC to obtain the deviation information between the pesticide application nozzle and the crop row is as follows:

s11, preprocessing the image of the wheat crop by using an image processing method to obtain a binary image;

s12, removing pinhole noise between lines and on crop lines in the binary image by using a morphological algorithm to obtain a crop line skeleton;

s13, fitting the crop row skeleton by using a rapid Hough transformation algorithm based on directional processing to obtain the center line of the crop row;

s14, calculating the pixel deviation distance between the center line of the crop row and the center of the image according to the transformation relation between the world coordinate system and the image coordinate system to obtain the actual geographic deviation corresponding to the image pixel deviation, and combining the position information of the pesticide application nozzle and the industrial camera to obtain the deviation information of the pesticide application nozzle and the crop row.

Preferably, the method for preprocessing the image of the wheat crop by using the image processing method to obtain the binary image comprises the following steps:

s11.1, graying the image of the wheat crop by utilizing an improved over-green graying algorithm to obtain a grayscale image;

the grayscale image is:

wherein Gray represents a Gray value of the image, G represents a green component of the image, R represents a red component of the image, and B represents a blue component of the image;

s11.2, carrying out binary filtering processing on the gray level image, and removing noise in the gray level image to obtain a filtered image;

s11.3, carrying out binarization on the filtered image by adopting a maximum inter-class variance method to obtain a binary image.

Preferably, in step S2, the method for transmitting the leaf defect image to the defect identification system of the PC to obtain the type and degree of the defect includes:

s21, separating the leaves from the background of the leaf disease image by using an image processing method to obtain a leaf disease image;

s22, segmenting the leaf lesion image by adopting a green segmentation algorithm to obtain a lesion segmentation image, and carrying out image restoration on the lesion segmentation image to obtain a lesion image, wherein the image restoration refers to restoring the transformed gray level image into a color image according to image coordinate position information;

s23, respectively extracting features of the scab image by using a color histogram, a color moment, a contrast ratio, a moment of invariance and an eccentricity ratio calculation method to obtain initial standby features, and screening the initial standby features by a principal component analysis method to obtain core features for identifying the wheat leaf diseases, wherein the core features comprise a red moment, R-G, a circularity, a contrast ratio, an eccentricity ratio and a scab area number ratio;

and S24, recognizing the core characteristics by using an SVM algorithm based on the Fisher criterion, and outputting the types and severity of the diseases.

Preferably, the method for separating the leaf from the background of the leaf disease image by using the image processing method to obtain the leaf disease image comprises the following steps:

s21.1, converting the leaf disease image into a gray image, and processing the gray image by using an improved watershed algorithm to obtain a secondary gray image;

s21.2, segmenting the secondary gray image by using a self-adaptive threshold algorithm to obtain a binary image of the blade;

s21.3, cutting the two-value image of the blade subjected to the expansion corrosion filtering to obtain a target image;

and S21.4, converting the target image into a color image according to a spatial relationship according to the invariance principle of image spatial pixels to obtain a leaf disease image, wherein the spatial relationship refers to the correspondence of the coordinate positions of the binary image and the color image.

Preferably, the method for identifying the core features by using the SVM algorithm based on the fisher criterion and outputting the types and severity of the diseases comprises the following steps:

s24.1, constructing a disease category space M ═ V of wheat leaves₁∪V₂∪…∪V_i∪…∪V_NWherein V is_iIndicating disease of type i;

s24.2, dividing the disease category space M into two categories of subspaces, and constructing a linear discriminant function by adopting a Fisher criterion:

wherein X is (X)₁,x₂,…,x_p)^TFor the core features, i is 1,2, …, p, p represents the number of the core features, C is a constant vector, C_iRepresenting the contribution rate of different core features, U (X) representing a discriminant function;

s24.3, judging the types of the diseases according to the obtained core characteristics of the wheat leaf diseases by a multi-type recognition algorithm of a support vector machine decision tree based on Fisher criterion; and determining the severity grade of the disease according to the number of the core characteristics of the wheat leaf diseases.

The beneficial effect that this technical scheme can produce: the invention provides a realization method on the configuration of software and hardware, provides a method for automatic alignment of a spraying nozzle, automatic selection of pesticide types and control of spraying amount, has certain advantages in the aspects of disease type identification and formula preparation, has good effect on the aspect of identifying wheat disease types, has strong advantages in the aspect of giving formulas based on disease severity, and has strong adaptability and high identification accuracy.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a block diagram of the system of the present invention;

FIG. 2 is a flow chart of the present invention;

FIG. 3 is an original view of a wheat field according to the present invention;

FIG. 4 is a line center line extraction plot of a wheat crop of the present invention;

FIG. 5 is an original drawing of wheat stripe rust of the present invention;

FIG. 6 is a graph of wheat stripe rust treatment according to the present invention;

FIG. 7 is an original drawing of wheat leaf rust of the present invention;

FIG. 8 is an original drawing of wheat leaf rust with a complex background;

FIG. 9 is a graph showing the result of wheat powdery mildew identification according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive effort based on the embodiments of the present invention, are within the scope of the present invention.

Embodiment 1, as shown in fig. 1, a precise recipe pesticide application robot system based on wheat disease information includes an industrial camera, a macro camera, a PC, a recipe pool, a precise pesticide application controller, and a pesticide application nozzle, where the PC is connected to the industrial camera, the micro camera, the recipe pool, and the precise pesticide application controller, respectively, obtains a wheat crop row image from the industrial camera, obtains a disease image from the macro camera, is connected to the recipe pool mainly for transmitting information obtained by a recipe expert system to the recipe pool, and is connected to the precise pesticide application controller mainly for transmitting a control signal to the pesticide application controller; the dispensing pool is connected with the accurate dispensing controller, and the information of the dispensing pool is transmitted to the dispensing controller for supplying the amount of the dispensing medicine and mixing the liquid medicine; the accurate pesticide application controller is connected with the pesticide application spray head and controls the pesticide application spray head to perform pesticide application operation according to actual conditions. The PC machine comprises a disease identification system, a crop row identification system and a formula expert system, wherein the disease identification system is mainly used for identifying disease information of wheat, including disease categories, disease damage degree and the like; the crop row identification system is mainly used for identifying the crop rows of wheat, guiding the pesticide application robot to carry out pesticide spraying operation and ensuring that the pesticide is sprayed on diseased crops; the formula expert system mainly gives expert decisions according to information such as the category of crop diseases, the disease damage degree and the like to generate an application formula, the disease identification system is respectively connected with the macro camera and the formula expert system, the formula expert system is connected with the formula pool, and the crop row identification system is respectively connected with the industrial camera and the accurate application controller.

Embodiment 2, as shown in fig. 2, a method for applying a pesticide to a precise formulation pesticide application robot system based on wheat disease information includes the following specific steps:

s1, collecting an RGB color image of the wheat crop by using an industrial camera MV-VD030SC, wherein the image comprises a plurality of crop line information as shown in figure 3, and transmitting the image to a crop line identification system of a PC (personal computer) to obtain deviation information of the pesticide application spray head and the crop line; the method comprises the following steps:

s11, preprocessing the image of the wheat crop by using an image processing method to obtain a binary image; the specific method comprises the following steps:

s11.1, graying the image of the wheat crop by utilizing an improved over-green graying algorithm to obtain a grayscale image;

the grayscale image is:

wherein Gray represents a Gray value of the image, G represents a green component of the image, R represents a red component of the image, and B represents a blue component of the image;

s11.2, carrying out binary filtering processing on the gray level image, and removing noise in the gray level image to obtain a filtered image;

s11.3, carrying out binarization on the filtered image by adopting a maximum inter-class variance method to obtain a binary image. At the moment, only crop row information exists in the binary image, the background is removed, and background segmentation is achieved.

S12, removing pinhole noise between lines and on crop lines in the binary image by using a morphological algorithm, then refining the pinhole noise, and meanwhile, removing redundant lines in the image on the premise of considering information quantity and accuracy in order to reduce calculated quantity, and only reserving two lines closest to the center to represent a crop line skeleton, wherein the obtained crop line skeleton is shown in FIG. 4.

S13, in order to better reflect the trend of the crop row, fitting the crop row skeleton into a straight line by using a rapid Hough transformation algorithm based on directional processing, and taking the straight line as the center line of the crop row;

the principle of the fast Hough transformation algorithm based on directional processing is as follows:

the Hough transform fits crop rows into straight lines, and the basic idea is to convert the straight line detection problem in an image into the detection problem of the midpoint in a parameter space by utilizing duality of point lines, and to complete the straight line detection through the accumulation statistics of the midpoint in the parameter space. There are two methods for improving the speed of Hough transformation, namely reducing the number of participating points and reducing the calculation space. The Hough transform based on directional processing of the present invention is based on a combination of these two methods. In order to reduce the complexity of the calculation, the linear polar coordinate equation is expressed as follows:

ρ＝xcosθ+ysinθ；

where ρ is the distance from the origin to the line and θ is the angle between the x-axis and the line. When calculating, firstly, the whole image is quantized into several subregions, and two points (x) are randomly selected on the near-line segment in the thinned image_m,y_m)、(x_n,y_n) A straight line is determined, and the parameters are as follows:

ρ＝x_m cosθ+y_m sinθ；

and (3) forming all pixel points in each section of the near straight line into a set A, randomly taking two points in the set A to calculate the slope, and if the requirement of the near straight line is not met, reselecting. Because only the middle 2 lines of the crop line image are extracted, the value range of theta can be compressed to 30-150 degrees according to the method

The value of p is calculated, wherein,

and finally, accumulating the accumulated array according to the values of the rho and the theta to obtain the number of collinear points, and determining the size of the accumulator according to the value ranges of the rho and the theta and the resolution ratios of the rho and the theta so as to detect the straight line.

S14, according to the transformation relation between the world coordinate system and the image coordinate system, calculating the pixel deviation distance between the center line of the crop row and the center of the image to obtain the actual geographic deviation corresponding to the image pixel deviation, combining the position information of the pesticide application spray head and the industrial camera to obtain the deviation information of the pesticide application spray head and the crop row, and sending the deviation information to the accurate pesticide application controller by the PC.

S2, acquiring a leaf disease image of the wheat crop by using a macro camera (the model is a Nikon D80 type color digital camera), and transmitting the leaf disease image to a disease identification system of a PC (personal computer) to obtain the disease type and the disease degree; the method comprises the following steps:

s21, separating the blade from the background of the blade disease image by using an image processing method to obtain a blade disease image, as shown in FIGS. 5 and 7; the method comprises the following steps:

s21.1, when the diseased leaves are separated from the complex background, converting the leaf disease image into a gray image, and processing the gray image by using an improved watershed algorithm to obtain a secondary gray image;

s21.2, segmenting the secondary gray image by using a self-adaptive threshold algorithm to obtain a binary image of the blade;

s21.3, cutting the two-value image of the blade subjected to the expansion corrosion filtering to obtain a target image;

and S21.4, converting the target image into a color image according to a spatial relationship according to the invariance principle of image spatial pixels to obtain a leaf disease image, wherein the spatial relationship refers to the correspondence of the coordinate positions of the binary image and the color image.

S22, segmenting the leaf lesion image by adopting a green segmentation algorithm to obtain a lesion segmentation image, and performing image restoration on the lesion segmentation image to obtain a lesion segmentation image with white lesions and black background, as shown in FIGS. 6 and 8, wherein the image restoration refers to restoring the transformed gray level image into a color image according to the image coordinate position information;

s23, comprehensively considering different properties of different wheat diseases in various aspects of the image, defining appropriate characteristics, and obtaining a characteristic set capable of correctly classifying the wheat diseases in the research. And extracting initial standby characteristics for identifying various wheat leaf diseases. Obtaining core characteristics for identifying various wheat leaf diseases by a characteristic selection method. Respectively extracting features of the scab image by using calculation methods of a color histogram, a color moment, a contrast, a moment of invariance and an eccentricity ratio to obtain initial standby features, and screening the initial standby features by using a principal component analysis method to obtain core features for identifying wheat leaf diseases, wherein the core features comprise a red moment, R-G, a circularity, a contrast, an eccentricity ratio and a scab area number ratio;

s24, designing a multi-class recognition algorithm of a support vector machine decision tree based on Fisher criterion, and judging the class of the disease according to the obtained core characteristics of the wheat leaf disease; and determining the severity grade of the disease according to the number of the core characteristics of the wheat leaf diseases. And sending the information of the type and the severity degree to the precise pesticide application controller by the PC. The core features are identified by using an SVM algorithm based on the Fisher criterion, and the types and severity of diseases are output, as shown in FIG. 9. The SVM algorithm based on the Fisher discriminant method is as follows:

the system sets of core feature combination data can be expressed as:

L_N＝{X_i|i＝1,2,…,N}；

in the formula, L_NRepresenting the core feature composition space, vector X_iCombining vectors for the core features;

X_i＝(x₁,x₂,…,x_p)_i ^T；

wherein the component x_k(k ═ 1,2, …, p) represents different core features.

S24.1, dividing the actual disease category space M into N categories, and constructing the disease category space M of the wheat leaves as V₁∪V₂∪…∪V_i∪…∪V_NWherein V is_iIndicating disease of type i; the disease identification is to find that V is satisfied₁Vector X of_jCharacteristic value of (d):

s24.2, firstly, dividing the disease category space into subspaces which are only divided into two categories by adopting a decision tree method based on a support vector machine, and obtaining a plurality of subspaces combined by the two categories when identifying the categories. And identifying the subspace of the two types of spatial combinations by adopting the idea of fee pause criterion. Dividing the disease category space M into two categories of subspaces, and constructing a linear discriminant function by adopting a Fisher criterion:

wherein X is (X)₁,x₂,…,x_p)^TFor the core features, i is 1,2, …, p, p represents the number of the core features, C is a constant vector, C_iRepresenting the contribution rate of different core features, U (X) representing a discriminant function; under the specified conditions, a characteristic value U is determined₀When the value is a threshold value, the space is judged as a category 1 space when the value is smaller than the threshold value, and the space is judged as a category 2 space when the value is larger than the threshold value. The fisher discriminant method is a linear discriminant function obtained by only using knowledge of subset one and second moments under the optimal standard condition, and is more accurate than a method based on the euclidean distance and the mahalanobis distance.

S24.3, judging the types of the diseases according to the obtained core characteristics of the wheat leaf diseases by a multi-type recognition algorithm of a support vector machine decision tree based on Fisher criterion; and determining the severity grade of the disease according to the number of the core characteristics of the wheat leaf diseases.

And analogizing in sequence to obtain a category 1 space, a category 2 space, a category 3 space and the like respectively.

S3, transmitting the disease types and the disease degrees in the step S2 to a formula expert system, and preparing pesticide types and pesticide spraying amount in a formula pool through the formula expert system to obtain pesticide solution;

the formula expert system firstly acquires a related formula which comprises information such as required pesticide types and the dosage of each pesticide. And extracting a certain amount of pesticides from different pesticide containers in a formula pool respectively, and then mixing the pesticides by stirring to obtain a pesticide solution.

S4, transmitting deviation information of the pesticide applying spray head and the crop row in the step S1 to the accurate pesticide applying controller, and controlling the position of the pesticide applying spray head by the accurate pesticide applying controller to spray the pesticide solution in the step S3 to the ill-conditioned wheat crop, so that accurate pesticide applying of the wheat crop is realized, pesticide waste is reduced, and pesticide applying efficiency and accuracy are improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. The utility model provides an accurate prescription robot system that gives medicine to poor free of charge based on wheat disease information, its characterized in that, includes industry camera, microspur camera, PC, prescription pond, accurate controller and the shower nozzle of giving medicine to poor free of charge, the PC is connected with industry camera, microspur camera, prescription pond and accurate controller of giving medicine to poor free of charge respectively, and the prescription pond is connected with accurate controller of giving medicine to poor free of charge, and accurate controller of giving medicine to poor free of charge is connected with the shower nozzle of giving medicine to poor free of charge.

2. The wheat disease information-based precise formula pesticide application robot system according to claim 1, wherein the PC comprises a disease recognition system, a crop row recognition system and a formula expert system, the disease recognition system is respectively connected with the macro camera and the formula expert system, the formula expert system is connected with the formula pool, and the crop row recognition system is respectively connected with the industrial camera and the precise pesticide application controller.

3. The method for applying a precise formulation application robot system based on wheat disease information according to claim 1 or 2, characterized by comprising the steps of:

s1, acquiring an image of the wheat crop by using an industrial camera, and transmitting the image to a crop row recognition system of a PC (personal computer) to obtain deviation information of the pesticide application spray head and the crop row;

s2, acquiring a leaf disease image of the wheat crop by using a macro camera, and transmitting the leaf disease image to a disease identification system of a PC (personal computer) to obtain the disease type and the disease degree;

s3, transmitting the disease types and the disease degrees in the step S2 to a formula expert system, and preparing pesticide types and pesticide spraying amount in a formula pool through the formula expert system to obtain pesticide solution;

s4, transmitting deviation information of the pesticide applying spray head and the crop row in the step S1 to the accurate pesticide applying controller, and controlling the position of the pesticide applying spray head by the accurate pesticide applying controller to spray the pesticide solution in the step S3 to the ill-conditioned wheat crop to realize accurate pesticide applying of the wheat crop.

4. The method for pesticide application of the robot system for precise formula pesticide application based on wheat disease information according to claim 3, wherein the step S1 of transmitting the image to the crop row recognition system of the PC is that the method for obtaining the deviation information of the pesticide application spray head and the crop row is as follows:

s11, preprocessing the image of the wheat crop by using an image processing method to obtain a binary image;

s12, removing pinhole noise between lines and on crop lines in the binary image by using a morphological algorithm to obtain a crop line skeleton;

s13, fitting the crop row skeleton by using a rapid Hough transformation algorithm based on directional processing to obtain the center line of the crop row;

s14, calculating the pixel deviation distance between the center line of the crop row and the center of the image according to the transformation relation between the world coordinate system and the image coordinate system to obtain the actual geographic deviation corresponding to the image pixel deviation, and combining the position information of the pesticide application nozzle and the industrial camera to obtain the deviation information of the pesticide application nozzle and the crop row.

5. The pesticide application method of the precise formula pesticide application robot system based on the wheat disease information as claimed in claim 4, wherein the method for preprocessing the image of the wheat crop by using the image processing method to obtain the binary image comprises the following steps:

s11.1, graying the image of the wheat crop by utilizing an improved over-green graying algorithm to obtain a grayscale image;

the grayscale image is:

wherein Gray represents a Gray value of the image, G represents a green component of the image, R represents a red component of the image, and B represents a blue component of the image;

s11.2, carrying out binary filtering processing on the gray level image, and removing noise in the gray level image to obtain a filtered image;

s11.3, carrying out binarization on the filtered image by adopting a maximum inter-class variance method to obtain a binary image.

6. The method for applying a pesticide to a robot system with a precise formula based on wheat disease information according to claim 3, wherein the method for transmitting the leaf disease image to the disease identification system of the PC in step S2 comprises the following steps:

s21, separating the leaves from the background of the leaf disease image by using an image processing method to obtain a leaf disease image;

s22, segmenting the leaf lesion image by adopting a green segmentation algorithm to obtain a lesion segmentation image, and carrying out image restoration on the lesion segmentation image to obtain a lesion image, wherein the image restoration refers to restoring the transformed gray level image into a color image according to image coordinate position information;

s23, respectively extracting features of the scab image by using a color histogram, a color moment, a contrast ratio, a moment of invariance and an eccentricity ratio calculation method to obtain initial standby features, and screening the initial standby features by a principal component analysis method to obtain core features for identifying the wheat leaf diseases, wherein the core features comprise a red moment, R-G, a circularity, a contrast ratio, an eccentricity ratio and a scab area number ratio;

and S24, recognizing the core characteristics by using an SVM algorithm based on the Fisher criterion, and outputting the types and severity of the diseases.

7. The pesticide application method of the precise formula pesticide application robot system based on the wheat disease information as claimed in claim 6, wherein the method for separating the leaf from the background of the leaf disease image by using the image processing method comprises the following steps:

s21.1, converting the leaf disease image into a gray image, and processing the gray image by using an improved watershed algorithm to obtain a secondary gray image;

s21.2, segmenting the secondary gray image by using a self-adaptive threshold algorithm to obtain a binary image of the blade;

s21.3, cutting the two-value image of the blade subjected to the expansion corrosion filtering to obtain a target image;

and S21.4, converting the target image into a color image according to a spatial relationship according to the invariance principle of image spatial pixels to obtain a leaf disease image, wherein the spatial relationship refers to the correspondence of the coordinate positions of the binary image and the color image.

8. The pesticide application method of the precise formula pesticide application robot system based on the wheat disease information as claimed in claim 6, wherein the method for identifying the core characteristics and outputting the types and severity of diseases by using the SVM algorithm based on the Fisher criterion comprises the following steps:

s24.1, constructing a disease category space M ═ V of wheat leaves₁∪V₂∪…∪V_i∪…∪V_NWherein V is_iIndicating disease of type i;

s24.2, dividing the disease category space M into two categories of subspaces, and constructing a linear discriminant function by adopting a Fisher criterion:

wherein X is (X)₁,x₂,…,x_p)^TFor the core features, i is 1,2, …, p, p represents the number of the core features, C is a constant vector, C_iRepresenting the contribution rate of different core features, U (X) representing a discriminant function;

s24.3, judging the types of the diseases according to the obtained core characteristics of the wheat leaf diseases by a multi-type recognition algorithm of a support vector machine decision tree based on Fisher criterion; and determining the severity grade of the disease according to the number of the core characteristics of the wheat leaf diseases.

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