CN113159466A - Short-time photovoltaic power generation prediction system and method - Google Patents

Short-time photovoltaic power generation prediction system and method Download PDF

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CN113159466A
CN113159466A CN202110587166.8A CN202110587166A CN113159466A CN 113159466 A CN113159466 A CN 113159466A CN 202110587166 A CN202110587166 A CN 202110587166A CN 113159466 A CN113159466 A CN 113159466A
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卢小丁
江思伟
刘莉
袁宏亮
林栋�
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Abstract

A short-time photovoltaic power generation prediction system and method can more accurately track cloud layer movement by adopting an image processing technology; the photovoltaic power generation efficiency under multi-time and weather conditions is distinguished, and stronger adaptability is achieved; the change of the illumination intensity can be accurately predicted, so that a user can make optimization guidance of energy storage battery charging/grid connection planning on a photovoltaic system in advance, and the impact on a power grid is reduced. The system and the method have the advantages of high prediction precision, wide application range and strong interpretability.

Description

Short-time photovoltaic power generation prediction system and method
Technical Field
The invention relates to the field of power management, in particular to a short-time photovoltaic power generation power prediction system and method.
Background
According to traditional photovoltaic power generation power prediction, a ground anemometer is adopted to measure wind speed, and the moving speed and the wind direction of a high-altitude cloud layer cannot be accurately described. In the method for predicting by adopting the image, the image is mostly used for training and predicting, information in the image is not further extracted, and the influence of factors such as the temperature difference of the photovoltaic panel on the power generation efficiency is ignored. The method based on the number of cloud clusters and the area of the cloud clusters occupying the whole sky cannot distinguish cloud layers with different thicknesses, and cannot accurately predict the impact of the severe change of illumination intensity caused by cloud layer shielding on the whole power grid in the photovoltaic grid connection process.
Disclosure of Invention
Aiming at the problems, the invention provides a system and a method for predicting the short-time photovoltaic power generation power, and the adopted image processing technology can more accurately track the movement of cloud layers; the photovoltaic power generation efficiency under multi-time and weather conditions is distinguished, and stronger adaptability is achieved; the change of illumination intensity can be accurately predicted, and the impact is reduced by taking a response measure in advance; and (4) performing optimization guidance of energy storage battery charging/grid connection planning on the photovoltaic system.
A short-time photovoltaic power generation power prediction system comprises a data acquisition module, a local data processing module, a cloud data processing and storing module and an energy storage battery, wherein the local data processing module comprises a cloud layer moving speed estimation module, a sun position calculation module and a photovoltaic power generation efficiency calculation module;
the data acquisition module comprises a camera, a photovoltaic panel temperature sensor and an environment temperature sensor, the camera shoots a sky image, and meanwhile, the temperature sensors acquire and acquire the temperature of the photovoltaic panel and the environment;
the cloud layer moving speed estimation module and the sun position calculation module process and calculate the acquired sky image to obtain the cloud layer moving speed and the sun position, and the photovoltaic power generation efficiency calculation module inputs the calculated data, the real-time sky image and the temperature into a trained neural network of a multi-input data type to finally obtain the photovoltaic power generation efficiency;
and after the local data processing module processes the data, the data is stored in the cloud, and the energy storage battery is managed according to the calculation result.
A short-time photovoltaic power generation prediction method comprises the following steps:
step 1, acquiring images and temperature information by a camera and a temperature sensor, and preprocessing the acquired data; the temperature sensor collects the temperature of the photovoltaic panel and the environment, the camera shoots the sky image, and the preprocessing is to zoom the image through the characteristic pyramid after the image is subjected to distortion correction.
Step 2, estimating the motion of the cloud layer based on computer vision; carrying out feature point detection on the preprocessed image, and matching the feature point detection with the image at the previous moment; rejecting mismatching feature points, calculating the number of moving pixels of the corresponding feature points projected in the same picture as the moving distance of the cloud layer, and setting the angle formed by the connecting line of the two feature points as the moving direction of the cloud layer; after all the matched feature points are subjected to the operation, an average value is obtained;
step 3, carrying out self-adaptive adjustment on the sampling frequency of the cloud layer image; setting the basic sampling interval time as T, controlling the moving distance of cloud layers of two adjacent images to be l/10 image side length, and setting a target difference value e as l/10-d; the difference e is 0 when a PID control strategy is adopted;
step 4, calculating to obtain the position of the sun through local longitude and latitude and time information, and estimating the influence of cloud movement on the energy from solar radiation to the photovoltaic panel according to the calculated cloud movement speed and direction;
and 5, processing the image and the numerical data by adopting a neural network form of a multi-input data type for the collected data comprising the image data and the numerical data to obtain the final photovoltaic power generation efficiency, wherein the photovoltaic power generation efficiency is instantaneous power generation power/rated installed power.
The invention achieves the following beneficial effects: the invention provides a short-time photovoltaic power generation prediction system and a short-time photovoltaic power generation prediction method, which can more accurately track the movement of a cloud layer through an improved image processing technology, can better predict the shielding condition of the movement of the cloud layer on sunlight, and further obtain a better power generation prediction result; the photovoltaic power generation efficiency under the conditions of multiple times and weather is distinguished, the adaptability is stronger, the system can be directly established and directly put into use for prediction without being adjusted according to the actual position of the system when in use, and the operation is more convenient and easy; by analyzing the motion and the irradiation conditions of the cloud layer and the sun, the change of the illumination intensity can be accurately predicted, and the impact is reduced by taking a response measure in advance; and (4) performing optimization guidance of energy storage battery charging/grid connection planning on the photovoltaic system. The system and the method have the advantages of high prediction precision, wide application range, simple operation and strong interpretability.
Drawings
Fig. 1 is a schematic structural diagram of a photovoltaic power generation power prediction system in an embodiment of the present invention.
Fig. 2 is a schematic diagram of a scale space constructed in cloud layer motion estimation according to an embodiment of the present invention.
Fig. 3 is a schematic diagram illustrating feature point positioning in cloud motion estimation according to an embodiment of the present invention.
Fig. 4 is a schematic diagram illustrating distribution of principal directions of feature points in cloud motion estimation according to an embodiment of the present invention.
Fig. 5 is a schematic diagram illustrating cloud layer feature point matching in cloud layer motion estimation according to an embodiment of the present invention.
Fig. 6 is a diagram illustrating adjustment of sampling frequency of a cloud image by PID control according to an embodiment of the present invention.
FIG. 7 is a schematic diagram of the input and output of a BP neural network neuron in an embodiment of the present invention.
FIG. 8 is a schematic diagram of convolutional neural network pooling in an embodiment of the present invention.
FIG. 9 is an overall architecture diagram of the convolutional neural network layer and the BP neural network layer in an embodiment of the present invention.
Fig. 10 is a schematic diagram illustrating the principle of inserting numerical data into image data according to an embodiment of the present invention.
Fig. 11 is a diagram of a neural network architecture after numerical data is inserted into image data according to an embodiment of the present invention.
Fig. 12 is a flowchart illustrating a method for predicting photovoltaic power generation power according to an embodiment of the present invention.
Fig. 13 is a second flowchart of a method for predicting photovoltaic power generation power according to an embodiment of the present invention.
Detailed Description
The technical scheme of the invention is further explained in detail by combining the drawings in the specification.
A short-time photovoltaic power generation power prediction system is shown in figure 1 and comprises a data acquisition and collection module, a local data processing module, a cloud data processing and storing module and an energy storage battery, wherein the local data processing module comprises a cloud layer moving speed estimation module, a solar position calculation module and a photovoltaic power generation efficiency calculation module.
A data acquisition module: including image acquisition and temperature acquisition. The image acquisition comprises panoramic cameras such as fisheye cameras or a plurality of groups of cameras, for example, the fisheye cameras are used for shooting sky pictures by adopting fixed fisheye cameras, and after distortion correction is carried out, the pictures are zoomed by the characteristic pyramid, so that the calculated amount is reduced. The temperature acquisition is realized through a temperature sensor, and the photovoltaic panel and the ambient temperature are acquired.
The cloud layer moving speed estimation module performs feature point detection (not limited to Surf, Sift, ORB and the like) on the processed image, and matches the processed image with the image at the previous moment. And eliminating mismatching feature points, calculating the number of moving pixels of the corresponding feature points projected in the same picture as the moving distance of the cloud layer, and setting the angle formed by the connecting lines of the two feature points as the moving direction of the cloud layer. After the above operation is performed on all the matched feature points, an average value is obtained, and a calculation formula is as follows:
Figure BDA0003088151520000051
wherein (x)i,yi) As pixel coordinates of the current time,
Figure BDA0003088151520000052
The pixel coordinates at the previous time.
The sun position calculation module calculates the sun position according to the collected sky image.
In the horizon coordinate system, the position of the sun can be solved by the elevation angle α and the azimuth angle θ as follows:
Figure BDA0003088151520000053
Figure BDA0003088151520000054
wherein, delta is the declination angle of the sun;
Figure BDA0003088151520000055
the local latitude is; and omega is a time angle.
After the position of the sun is determined, the solar time angle is obtained from ω 15 × (ST-12) from the two image capturing times. The position of the sun on the projection frame at the next moment is calculated by the Gaussian-gram projection. And estimating the influence of the cloud layer motion on the energy from the solar radiation to the photovoltaic panel according to the calculated cloud layer motion speed and direction. Specifically, the sun projection movement at the next moment is equal to the cloud layer movement in size and opposite in direction, and the illumination intensity of the position is the estimated solar radiation intensity.
In the photovoltaic power generation efficiency calculation module, defining the photovoltaic power generation efficiency as instantaneous power generation power/rated installed power, inputting real-time image data and other acquired data into a trained neural network with multiple input data types, finally obtaining the photovoltaic power generation efficiency, and estimating the photovoltaic power generation amount of the actual installed equipment.
A short-time photovoltaic power generation power prediction method refers to flow charts of two modes of a reference graph 12 and a reference graph 13, only the last step of the two methods has difference, the photovoltaic power generation power prediction function can be achieved, and common parts such as cloud layer motion estimation, sampling, operation frequency calculation, sun position calculation and the like exist, so that the input variables are obtained. The generated power solving part of the two algorithms has different ideas and can be replaced mutually.
Specifically, the prediction method comprises the following steps:
step 1, acquiring images and temperature information by a camera and a temperature sensor, and preprocessing the acquired data; the temperature sensor collects the temperature of the photovoltaic panel and the environment, the camera shoots the sky image, and the preprocessing comprises the steps of carrying out distortion correction on the image and then zooming the image through the characteristic pyramid.
And 2, cloud layer motion estimation based on computer vision.
And (3) carrying out feature point detection (not limited to Surf, Sift, ORB and the like) on the processed image, and matching the processed image with the image at the previous moment. And eliminating mismatching feature points, calculating the number of moving pixels of the corresponding feature points projected in the same picture as the moving distance of the cloud layer, and setting the angle formed by the connecting lines of the two feature points as the moving direction of the cloud layer. And after the above operation is carried out on all the matched feature points, the average value is obtained.
Taking surf algorithm as an example, the brief description of cloud layer motion estimation algorithm comprises a-g processes with 7 steps, wherein feature point detection (process c) is a necessary operation for feature matching.
a. After the obtained cloud layer image is subjected to Gaussian filtering, a sea plug Matrix (Hessian Matrix) is constructed, a determinant of the sea plug Matrix is calculated to judge whether the sea plug Matrix is a local feature point of the image, and a box-shaped fuzzy filter is adopted to calculate a Gaussian approximate value for the determinant.
Figure BDA0003088151520000071
b. Constructing a scale space: the scale space of Surf, as shown in fig. 2, keeps the image size unchanged during its sampling, and a scale pyramid is constructed by changing the size of the box filter.
c. Positioning the characteristic points: as shown in fig. 3, each pixel point processed by the Hessian matrix is compared with 26 points in the neighborhood of the two-dimensional image space and the scale space, a key point is preliminarily located, and a final stable feature point is screened out by filtering out a key point with weak energy and an incorrectly located key point.
d. And (3) distributing the main directions of the characteristic points: haar wavelet characteristics are used. As shown in fig. 4, that is, in the circular neighborhood of the feature point, the sum of the horizontal and vertical haar wavelet features of all points in the 60-degree sector is counted, then after the sector is rotated at intervals of 0.2 radian and the haar wavelet feature values in the region are counted again, the direction of the sector with the largest value is finally taken as the main direction of the feature point.
e. Generating a characteristic point descriptor: a 4 × 4 rectangular region block is taken around the feature point, but the direction of the rectangular region taken is along the main direction of the feature point. Each subregion counts haar wavelet features of 25 pixels in both the horizontal and vertical directions, where both the horizontal and vertical directions are relative to the principal direction. The haar wavelet features are 4 directions of the sum of the horizontal direction value, the vertical direction value, the horizontal direction absolute value and the vertical direction absolute value.
f. Matching the characteristic points: as shown in fig. 5, the matching degree is determined by calculating the euclidean distance between two feature points, and the shorter the euclidean distance, the better the matching degree of the two feature points is represented. And judging the Hessian matrix trace, if the signs of the matrix traces of the two characteristic points are the same, representing that the two characteristics have contrast changes in the same direction, if the signs of the matrix traces are different, indicating that the contrast change directions of the two characteristic points are opposite, and directly excluding the characteristic points even if the Euclidean distance is 0.
The Euclidean distance is calculated as:
the key point descriptor in the image at the previous moment:
Ri=(ri1,ri2,…,ri128)
the current calculation uses the keypoint descriptors in the image:
Si=(si1,si2,…,si128)
any two descriptor similarity measures (euclidean distance):
Figure BDA0003088151520000081
g. after eliminating the mismatched points, n groups of corresponding points (x) are obtained11,y11),(x21,y21),(x12,y12),(x22,y22)...(x1n,y1n)(x2n,y2n) And calculating the moving distance d and the direction angle alpha of the cloud layer on the image.
Figure BDA0003088151520000082
Figure BDA0003088151520000083
Reference cloud layer moving speed v: and v is d/T.
In step 3, too high a calculation frequency increases the system load, and further increases the hardware cost and power consumption. In this way, the sampling frequency of the cloud layer image is adaptively adjusted. Assuming that the basic sampling interval time is T, (the moving distance of the cloud layers of two adjacent images is controlled to be l/10 image side length (rough value)), and the target difference e is l/10-d, the difference e is 0 by adopting a control strategy such as PID control and the like referring to fig. 6.
Step 4, in order to prevent cloud layer shielding, the position of the sun on the image cannot be identified by the convolutional network, the position of the sun is obtained through extra calculation according to local longitude and latitude and time information, and in the horizon coordinate system, the position of the sun can be obtained by solving an altitude angle alpha and an azimuth angle theta as follows:
Figure BDA0003088151520000091
Figure BDA0003088151520000092
wherein, delta is the declination angle of the sun;
Figure BDA0003088151520000093
the local latitude is; and omega is a time angle.
And after the position of the sun is determined, calculating the position change of the sun on the projection frame at the next moment according to the shooting time of the two images. And estimating the influence of the cloud layer motion on the energy from the solar radiation to the photovoltaic panel according to the calculated cloud layer motion speed and direction. Here, the estimation influence is only calculated in an initial way that the next moment will not be occluded by the cloud layer. And (3) establishing a flag bit covered _ flag, wherein if the cloud layer can block the sun at the next moment according to the current moment movement speed and direction, the flag bit value is 1, and if not, the flag bit value is 0. And finally, inputting the mark position and the position coordinate of the current sun as sun position information into a neural network for further calculation.
And step 5, the acquired data not only comprises image data, but also comprises numerical data. The embodiment of the invention adopts two modes, and adopts a neural network form of multiple input data types to process the image and numerical data to obtain the photovoltaic power generation efficiency, wherein the photovoltaic power generation efficiency is defined as instantaneous power generation power/rated installed power.
The first method is as follows: the method comprises the steps that a convolution neural network is used for inputting image data, a common BP neural network is used for inputting numerical data, after primary processing is conducted, all connection layers are combined together, and finally the value of the photovoltaic power generation efficiency coefficient is output.
The BP neural network comprises an input layer, a hidden layer and an output layer. The input characteristics include sun position information, photovoltaic panel and ambient temperature, cloud layer movement speed and direction, time of day, and the like. The neuron structure is shown in the following figure, wherein the inputs are x1, x2 and x3, the weights are multiplied by w1, w2 and w3, then the product is added with a bias term b, and the bias term b is substituted into an activation function to be output. The activation function adopts a sigmoid function, and the expression of the activation function is as follows:
Figure BDA0003088151520000101
the convolutional neural network comprises a convolutional layer, a pooling layer and a full-link layer. And (4) performing convolution on the three RGB channels of the original image, and pooling by adopting a maxporoling mode. Pooling is actually a scaling process. And selecting the pixel with the maximum pixel value in the pixel block range to represent the whole pixel block. Padding refers to a way of filling the head and the tail of an image in the pooling process so as to ensure that the image is an integer. Padding 0 around the original image, so that each pixel point can be scanned by the window. The pooling window moving step length stride is 1.
The keras layers conditioner function ties the two together. After the two models are combined, the two models are processed through a multilayer network, partial node data are randomly screened out through dropout, and finally a final output value is obtained through a sigmoid function. An Adam optimizer is adopted in the training process, and the loss function is MAE.
Referring to fig. 7-9, the fully-connected layer in fig. 9 is a shared layer, the connections after the convolution network pooling and the fully-connected of the BP network share hidden layer neurons, the shared layer in this layer is a literal meaning that the neurons share in such layer, and the fully-connected layer represents a connection mode, that is, each node of the layer is connected with all nodes of the previous layer, so as to integrate the extracted features.
The second method comprises the following steps: the method is characterized in that numerical data are normalized to be between (0, 255) and are forcedly converted into integers.
Figure BDA0003088151520000111
Simultaneously inserting the integer numerical data into three channels of RGB of the image data as a plurality of rows/columns, as shown in FIG. 10, the inserting position is determined according to the size of the pooled kernel; for example, a pooling kernel size of 2 x2, the feature values are filled in the top left corner of the 2 x2 pixel box, as shown in the following figure. For the case that the data amount is less than a whole row/column, 0 value filling is adopted, and the processed image is input into a convolutional neural network to predict the photovoltaic power generation efficiency, as shown in fig. 11.
In the embodiment of the invention, the BP neural network and the convolutional neural network both belong to the classical neural network, and can be expanded on the basis, such as adopting the cyclic neural network and generating a countermeasure network to replace the current neural network. The adjustment of parameters such as network structure can optimize the overall performance.
In the embodiment of the invention, the collected data can be processed and operated in a cloud computing mode.
In the embodiment of the present invention, the preprocessing in step 1 of the prediction method may further include a noise elimination step. And removing the outliers which are in error matching, and keeping the correct matching points. Common methods are KDTREE, BBF, Randac, GTM, etc.
In the embodiment of the present invention, the calculation cycle may be updated by using fuzzy control, neural network, and the like.
The above description is only a preferred embodiment of the present invention, and the scope of the present invention is not limited to the above embodiment, but equivalent modifications or changes made by those skilled in the art according to the present disclosure should be included in the scope of the present invention as set forth in the appended claims.

Claims (10)

1. A short-time photovoltaic power generation power prediction system is characterized in that:
the system comprises a data acquisition and collection module, a local data processing module, a cloud data processing and storing module and an energy storage battery, wherein the local data processing module comprises a cloud layer moving speed estimation module, a solar position calculation module and a photovoltaic power generation efficiency calculation module;
the data acquisition module comprises a camera, a photovoltaic panel temperature sensor and an environment temperature sensor, the camera shoots a sky image, and meanwhile, the temperature sensors acquire and acquire the temperature of the photovoltaic panel and the environment;
the cloud layer moving speed estimation module and the sun position calculation module process and calculate the cloud layer moving speed and the sun position according to the collected sky image, and the photovoltaic power generation efficiency calculation module inputs the calculated data, the real-time sky image and the temperature into a trained neural network of a multi-input data type to finally obtain the photovoltaic power generation efficiency;
and after the local data processing module processes the data, the data is stored in the cloud, and the energy storage battery is managed according to the calculation result.
2. The system according to claim 1, wherein the system comprises: the camera is a panoramic camera or a plurality of groups of cameras comprising fisheye cameras.
3. The system according to claim 1, wherein the system comprises: the cloud layer moving speed estimation module detects the characteristic points of the image and matches the image at the previous moment; rejecting mismatching feature points, calculating the number of moving pixels of the corresponding feature points projected in the same picture as the moving distance of the cloud layer, and setting the angle formed by the connecting line of the two feature points as the moving direction of the cloud layer; and after the above operation is carried out on all the matched feature points, the average value is obtained.
4. The system according to claim 1, wherein the system comprises: after the sun position calculation module determines the position of the sun, the position change of the sun on the projection frame at the next moment is calculated according to the shooting time of the two images; and estimating the influence of the cloud layer motion on the energy from the solar radiation to the photovoltaic panel according to the calculated cloud layer motion speed and direction.
5. A short-time photovoltaic power generation power prediction method is characterized by comprising the following steps: the method comprises the following steps:
step 1, acquiring images and temperature information by a camera and a temperature sensor, and preprocessing the acquired data; the temperature sensor collects the temperature of the photovoltaic panel and the environment, the camera shoots the sky image, and the preprocessing comprises the steps of carrying out distortion correction on the image and then zooming the image through the characteristic pyramid.
Step 2, estimating the motion of the cloud layer based on computer vision; carrying out feature point detection on the preprocessed image, and matching the feature point detection with the image at the previous moment; rejecting mismatching feature points, calculating the number of moving pixels of the corresponding feature points projected in the same picture as the moving distance of the cloud layer, and setting the angle formed by the connecting line of the two feature points as the moving direction of the cloud layer; after all the matched feature points are subjected to the operation, an average value is obtained;
step 3, carrying out self-adaptive adjustment on the sampling frequency of the cloud layer image; setting the basic sampling interval time as T, controlling the moving distance of cloud layers of two adjacent images to be l/10 image side length, and setting a target difference value e as l/10-d; the difference e is 0 when a PID control strategy is adopted;
step 4, calculating to obtain the position of the sun through local longitude and latitude and time information, and estimating the influence of cloud movement on the energy from solar radiation to the photovoltaic panel according to the calculated cloud movement speed and direction;
and 5, processing the image and the numerical data by adopting a neural network form of a multi-input data type for the collected data comprising the image data and the numerical data to obtain the final photovoltaic power generation efficiency, wherein the photovoltaic power generation efficiency is instantaneous power generation power/rated installed power.
6. The method according to claim 5, wherein the method comprises: in step 2, cloud layer motion estimation is carried out based on a surf algorithm, and the method comprises the following 6 characteristic matching processes of 2a-2 g:
step 2a, after the obtained cloud layer image is subjected to Gaussian filtering, constructing a Hessian Matrix, calculating a determinant thereof to judge whether the obtained cloud layer image is a local feature point of the image, and calculating a Gaussian approximate value by adopting a box-shaped fuzzy filter:
Figure FDA0003088151510000031
step 2b, constructing a scale space: in the scale space of the Surf, the size of an image is kept unchanged in the sampling process, and a scale pyramid is constructed by changing the size of a box-shaped filter;
step 2c, positioning the characteristic points: comparing each pixel point processed by the Hessian matrix with 26 points in the neighborhood of a two-dimensional image space and a scale space, preliminarily positioning a key point, and screening out a final stable characteristic point by filtering out the key point with weaker energy and the key point with wrong positioning;
step 2d, distribution of the main directions of the feature points: adopting haar wavelet characteristics, namely counting the sum of horizontal haar wavelet characteristics and vertical haar wavelet characteristics of all points in a sector of 60 degrees in a circular neighborhood of characteristic points, then rotating the sector at intervals of 0.2 radian, counting haar wavelet characteristic values in the sector again, and finally taking the direction of the sector with the maximum value as the main direction of the characteristic points;
step 2e, generating a feature point descriptor: taking a 4-by-4 rectangular area block around the feature point, and obtaining the direction of the rectangular area along the main direction of the feature point; counting haar wavelet characteristics of 25 pixels in the horizontal direction and the vertical direction of each subregion, wherein the horizontal direction and the vertical direction are relative to the main direction; the haar wavelet features are 4 directions of the sum of the horizontal direction value, the vertical direction value, the horizontal direction absolute value and the vertical direction absolute value;
step 2f, feature point matching: determining the matching degree by calculating the Euclidean distance between two feature points, wherein the shorter the Euclidean distance is, the better the matching degree of the two feature points is represented; judging the Hessian matrix trace, if the signs of the matrix traces of the two characteristic points are the same, representing that the two characteristics have contrast changes in the same direction, if the signs are different, indicating that the contrast change directions of the two characteristic points are opposite, and directly eliminating the characteristic points even if the Euclidean distance is 0;
in step 2f, the calculation of the euclidean distance specifically includes:
the key point descriptor in the image at the previous moment:
Ri=(ri1,ri2,…,ri128)
the current calculation uses the keypoint descriptors in the image:
Si=(si1,si2,…,si128)
any two descriptor similarity measures, euclidean distance:
Figure FDA0003088151510000041
step 2g, n groups of corresponding points (x) are obtained after the mismatching points are removed11,y11),(x21,y21),(x12,y12),(x22,y22)...(x1n,y1n),(x2n,y2n) Calculating the moving distance d and the direction angle alpha of the cloud layer on the image:
Figure FDA0003088151510000042
Figure FDA0003088151510000051
calculating the moving speed v of the cloud layer:
v=d/T。
7. the method according to claim 5, wherein the method comprises: in step 4, in the horizon coordinate system, the position of the sun is obtained by solving the altitude angle α and the azimuth angle θ, as follows:
Figure FDA0003088151510000052
Figure FDA0003088151510000053
wherein δ isDeclination angle of the sun;
Figure FDA0003088151510000054
the local latitude is; omega is a time angle;
and after the position of the sun is determined, calculating the position change of the sun on the projection frame at the next moment according to the shooting time of the two images.
8. The method according to claim 5, wherein the method comprises: in the step 4, the influence is estimated in a process of creating a flag bit covered _ flag, if the cloud layer can block the sun at the next moment according to the current moment motion speed and direction, the flag bit value is 1, and if not, the flag bit value is 0; and finally, inputting the mark position and the position coordinate of the current sun as sun position information into the neural network in the step 5 for further calculation.
9. The method according to claim 5, wherein the method comprises: in the step 5, a convolution neural network is used for inputting image data, a common BP neural network is used for inputting numerical data, after primary processing, the numerical data and the image data are combined together through a full connection layer, and finally, the photovoltaic power generation efficiency coefficient value is output;
the convolutional neural network comprises a convolutional layer, a pooling layer and a full-connection layer; convolving the RGB three channels of the original image, and pooling by adopting a maxporoling mode; pooling is a scaling process, and a pixel with the largest pixel value in a pixel block range is selected to represent the whole pixel block; padding refers to a way of filling the head and the tail of an image in the pooling process so as to ensure that the image is an integer. Filling 0 around the original image so that each pixel point is scanned by a window; the moving step length stride of the pooling window is 1;
the BP neural network comprises an input layer, a hidden layer and an output layer, and the input characteristics comprise sun position information, photovoltaic panel and environment temperature, cloud layer moving speed and direction and time; the neuron inputs are x1, x2 and x3, multiplied by weights w1, w2 and w3, and added with biasThe item b is substituted into the activation function for output; the activation function adopts a sigmoid function, and the expression of the activation function is as follows:
Figure FDA0003088151510000061
two neural networks are connected together by a keras. Combining two neural networks, then processing the neural networks through a multilayer network, randomly screening partial node data by using dropout in the process, and finally obtaining a final output value through a sigmoid function; an Adam optimizer is adopted in the training process, and the loss function is MAE.
10. The method according to claim 5, wherein the method comprises: in the step 5, normalizing the numerical data to be between (0, 255), and forcibly converting the numerical data into an integer;
Figure FDA0003088151510000062
simultaneously inserting the image data into RGB three channels of the image data as a plurality of rows/columns, wherein the inserting position is determined according to the size of the pooled kernel; and (3) for the condition that the data volume is less than a whole row/column, filling by adopting a 0 value, and inputting the processed image into a convolutional neural network to predict the photovoltaic power generation efficiency.
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