CN113111573A - Landslide displacement prediction method based on GRU - Google Patents
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Abstract
The invention discloses a landslide displacement prediction method based on GRU, which monitors landslide earth surface displacement deformation, and calculates a replacement value of an abnormal value in obtained landslide displacement data by utilizing a constructed polynomial model; carrying out mean normalization processing on all the landslide displacement data after being replaced by the replacement values, and constructing a GRU model, a training set, a verification set and a test set; performing loop iteration on the GRU model by using the training set, and performing parameter adjustment on the trained GRU model by using the verification set; and testing the GRU model after the parameters are adjusted by using the test set, and performing inverse mean normalization processing on the obtained model prediction result to complete landslide displacement prediction and improve prediction precision.
Description
Technical Field
The invention relates to the technical field of geological disaster monitoring and prediction, in particular to a landslide displacement prediction method based on GRUs.
Background
Landslide is one of the most devastating geological disasters in many areas of the world, causing a large number of casualties and very important property losses each year. A reliable landslide prediction early warning method is a reasonable approach for reducing landslide risk. If the method capable of accurately predicting the landslide displacement can be successfully implemented, the method has great social value and important economic benefit.
Landslide prediction models can be divided into two broad categories, physical models and data-driven models. Compared with a physical model, the data-driven model is more popular because of simple process, accurate prediction and lower cost, but abnormal values are usually ignored blindly in the prediction process, and the prediction precision is not high due to the complicated structure of the currently commonly used RNN and LSTM models.
Disclosure of Invention
The invention aims to provide a landslide displacement prediction method based on GRU, and the prediction precision is improved.
In order to achieve the above object, the present invention provides a landslide displacement prediction method based on GRU, comprising the following steps:
monitoring landslide surface displacement deformation, and calculating a replacement value of an abnormal value in the obtained landslide displacement data by utilizing a constructed polynomial model;
carrying out mean normalization processing on all the landslide displacement data after being replaced by the replacement values, and constructing a GRU model, a training set, a verification set and a test set;
performing loop iteration on the GRU model by using the training set, and performing parameter adjustment on the trained GRU model by using the verification set;
and testing the GRU model after the parameters are adjusted by using the test set, and performing anti-mean normalization processing on the obtained model prediction result to finish landslide displacement prediction.
The method comprises the following steps of monitoring landslide surface displacement deformation, and calculating a replacement value of an abnormal value in obtained landslide displacement data by utilizing a constructed polynomial model, wherein the replacement value comprises the following steps:
monitoring landslide ground surface displacement deformation to obtain a plurality of landslide displacement data, wherein the plurality of landslide displacement data comprise a plurality of normal values and a plurality of abnormal values;
and taking a plurality of normal value serial numbers except the abnormal values as independent variables, taking a plurality of normal values as dependent variables to construct a polynomial model, inputting the abnormal value serial numbers into the polynomial model, and obtaining an output value of the polynomial model, namely a replacement value of the abnormal values.
Wherein, using the training set to perform loop iteration on the GRU model, and using the validation set to perform parameter adjustment on the trained GRU model comprises:
calculating values of an update gate, a reset gate, a hidden state and a current candidate state in the GRU model by using the landslide displacement data in the training set;
calculating the difference value between the landslide displacement data and the corresponding hidden state, and summing all the difference values to obtain a corresponding error term;
adjusting the corresponding weight value based on the error term until the iteration termination condition is reached, and finishing the training of the GRU model;
and verifying the trained GRU model by using the verification set, and adjusting the model learning rate and the number of corresponding model nodes.
Adjusting a corresponding weight value based on the error term until an iteration termination condition is reached, and completing training of the GRU model, wherein the training comprises the following steps:
respectively deriving the reset gate weight, the updated gate weight and the candidate state weight by using the error term to obtain corresponding derivatives;
subtracting the product of the corresponding derivative and a model learning rate from the reset gate weight, the updated gate weight and the candidate state weight to obtain a new reset gate weight, an updated gate weight and a candidate state weight;
and finishing the training of the GRU model until the current iteration times reach a set iteration threshold or the sum of the error terms is less than a set value.
The method comprises the following steps of testing the GRU model after parameters are adjusted by using the test set, and carrying out anti-mean normalization processing on an obtained model prediction result to complete landslide displacement prediction, wherein the method comprises the following steps:
inputting the test set into the GRU model after parameters are adjusted to obtain a corresponding model prediction result;
and carrying out anti-mean normalization processing on the model prediction result to obtain final measurement data, and completing landslide displacement prediction.
The landslide displacement prediction method based on GRU monitors landslide surface displacement deformation, and calculates a replacement value of an abnormal value in obtained landslide displacement data by utilizing a constructed polynomial model; carrying out mean normalization processing on all the landslide displacement data after being replaced by the replacement values, and constructing a GRU model, a training set, a verification set and a test set; performing loop iteration on the GRU model by using the training set, and performing parameter adjustment on the trained GRU model by using the verification set; and testing the GRU model after the parameters are adjusted by using the test set, and performing inverse mean normalization processing on the obtained model prediction result to complete landslide displacement prediction and improve prediction precision.
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 schematic step diagram of a method for predicting landslide displacement based on GRU according to the present invention.
Fig. 2 is a schematic flow chart of a method for predicting landslide displacement based on a GRU according to the present invention.
Fig. 3 is a diagram of a GRU model structure provided by the present invention.
FIG. 4 is a graph of actual raw data for a GRU model prediction provided by the present invention.
FIG. 5 is a schematic diagram of a polynomial model provided by the present invention.
FIG. 6 is a graph of normalized actual raw data for GRU model prediction provided by the present invention.
FIG. 7 is a diagram of a GRU model prediction result provided by the present invention.
Detailed Description
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.
In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.
Referring to fig. 1 and 2, the present invention provides a method for predicting landslide displacement based on GRU, comprising the following steps:
s101, monitoring displacement deformation of the landslide surface, and calculating a replacement value of an abnormal value in the obtained landslide displacement data by using the constructed polynomial model.
Specifically, a high-precision GPS receiver or a landslide displacement sensor or a remote sensing satellite or manual measurement is used for monitoring the displacement and deformation of the landslide earth surface. And carrying out abnormal value replacement processing on the obtained landslide displacement data, and constructing a polynomial model to calculate a replacement value of the abnormal value.
The process is as follows: let the polynomial model be y ═ anxn+an-1xn-1+...+a1x+a0X is an independent variable, aiConstant but unknown, y is the dependent variable and n is the highest power of the polynomial. Suppose there are m data, x1,x2,x3,...xmLet x be3If the abnormal value is found, the independent variables are numbers 1, 2 and 4 … m, x1,x2,x4,...xmConstructing a polynomial model as a dependent variable to obtain y ═ anxn+an-1xn-1+...+a1x+a0At this time aiThe value of y is calculated by substituting the number 3 into the polynomial model for the known constant, where the value of y is x3The replacement value of (a). All abnormal values are replaced by analogy, and the problem that the prediction precision is low due to the fact that the abnormal values in the landslide displacement data are not processed or directly eliminated is solved.
S102, performing mean normalization processing on all the landslide displacement data after replacement by using the replacement values, and constructing a GRU model, a training set, a verification set and a test set.
Specifically, the mean normalization processing is performed on all the landslide displacement data after the abnormal value is replaced by the replacement value, so that the data is stable. Mean normalization procedure: y isi=(xi-μ)/σ,xiFor the ith raw data, μ is the mean of the x data set and σ is the standard deviation of the x data set.
The GRU model is built as shown in fig. 3.
The GRU is a typical neural network model and comprises an input layer, a hidden layer and an output layer, wherein the input layer is connected with the hidden layer, the hidden layer is connected with the output layer, n nodes are arranged in the hidden layer and are also connected with each other, and each connection has the weight; the landslide displacement data are divided into a training set, a verification set and a test set according to the proportion of 0.6, 0.2 and 0.2 (the proportion can be other proportions, and is not necessarily limited to the three proportions), the training set is input from an input layer and is used for training a GRU (generalized regression unit) model, the model is better, the verification set is used for performing cross verification after the model is trained, the model is optimal, a prediction result is output by an output layer and is compared with the test set to obtain the estimation accuracy of the model, and the problem that the prediction accuracy is not high because a machine learning algorithm only divides the data into the training set and the test set is solved.
S103, performing loop iteration on the GRU model by using the training set, and performing parameter adjustment on the trained GRU model by using the verification set.
Specifically, the landslide displacement data in the training set is used for calculating values of an update gate, a reset gate, a hidden state and a current candidate state in the GRU model, calculating differences between the landslide displacement data and the corresponding hidden state, summing all the differences to obtain corresponding error terms, deriving a reset gate weight, an update gate weight and a candidate state weight respectively by using the error terms to obtain corresponding derivatives, and subtracting a product of the corresponding derivatives and a model learning rate from the reset gate weight, the update gate weight and the candidate state weight to obtain new reset gate weight, the update gate weight and the candidate state weight; and completing the training of the GRU model until the current iteration times reach a set iteration threshold or the sum of the error terms is less than a set value, adjusting part of parameters of the model in each iteration, and comprising the following detailed procedures:
xtdenotes the t-th data, ztUpdate gate, r, indicating time ttReset gate, h, indicating time ttShowing a hidden state at time t,Represents the current candidate state at time t, WrWeight, W, representing reset gatezA weight representing an update gate,Weight representing candidate state, sigma representing sigmoid function, tanh representing tanh function,Representing the model learning rate. Wherein]Representing the concatenation of two vectors, representing the product of the matrices.
rt=σ(Wr·[ht-1,xt])
zt=σ(Wz·[ht-1,xt])
For each iteration, the GRU has two directions of computation propagation, forward propagation and backward propagation, respectively. Forward propagation: calculating rt、zt、ht、The value of (c), back propagation: calculating xtAnd htAre summed to obtain error terms, which are respectively coupled to Wr、Wz、Derivation to obtain the derivative of the error term to each weight, Wr、Wz、Subtract the product of the derivative and the learning rate to obtain the new Wr、Wz、And (5) circularly iterating until the set times or the sum of the error terms is less than the set value, and finishing the model training.
Validating the GRU model using the validation set data after training is complete, and adjusting includesParameters including (adjustment learning rate)And node number n), last W of the usage modelr、Wz、And keeping the same, the learning rate is increased from small to 1 (after the learning rate is changed every time, the number of nodes is from 2 to n2Increasing), the error term and the learning rate (and the number of nodes) at each time are recorded, and the learning rate at the time with the minimum error term is adopted as the final learning rate (and the number of final nodes n).
And S104, testing the GRU model after the parameters are adjusted by using the test set, and performing anti-mean normalization processing on the obtained model prediction result to finish landslide displacement prediction.
Specifically, after verification is completed, the test set is used for testing the GRU model to obtain a model prediction result, the model prediction result is subjected to inverse mean normalization processing to obtain final landslide prediction displacement data, namely final test data, of the GRU model, and the inverse mean normalization process comprises the following steps: y isi=xiσ + μ, μ is the mean of the original x data set, σ is the standard deviation in the original x data set, yiFor final prediction of data, xiIs the ith data calculated in the model.
Referring to fig. 4 to 7, fig. 4 is a graph of actual raw data of GRU model prediction provided by the present invention, which is a monthly displacement data value from 12 months of 06 to 12 months of 12 of the monitoring point of the white water river landslide ZG 118.
Fig. 5 is a schematic diagram of a polynomial model constructed using 72 normal values, where the polynomial model of the power of 5 is used in the current model.
Fig. 6 is a data diagram of normalized actual original data predicted by the GRU model provided by the present invention, and the original data is normalized by 73 landslide displacement data after replacing an abnormal value.
FIG. 7 is a diagram of a GRU model prediction result provided by the present invention. And selecting the last 12 data of the data as a test set, wherein the curve part in the graph is actual landslide displacement data, and the x part in the graph is predicted displacement predicted by the model. As can be seen from the figure, the prediction accuracy of the GRU is very high.
Advantageous effects
1. The statistical characteristic and the development regularity of the time sequence data are considered, and the accuracy of landslide displacement prediction is improved.
2. The landslide displacement prediction method can predict landslide displacement under the conditions of less actual landslide displacement data and less kinds of influence factor data, and reduces the prediction difficulty.
3. Compared with the traditional static landslide displacement prediction algorithm, the GRU model is a dynamic model prediction algorithm and is more suitable for practical needs.
4. The method solves the problems of gradient explosion and gradient disappearance which can occur in a neural network algorithm.
5. The data are divided into a training set, a verification set and a test set, so that the landslide displacement prediction model is more accurate.
6. The problem of low efficiency due to complex structure in a neural network algorithm is solved.
7. And considering the continuity of the landslide data, and solving the problem of abnormal values by constructing a polynomial model.
The landslide displacement prediction method based on GRU monitors landslide surface displacement deformation, and calculates a replacement value of an abnormal value in obtained landslide displacement data by utilizing a constructed polynomial model; carrying out mean normalization processing on all the landslide displacement data after being replaced by the replacement values, and constructing a GRU model, a training set, a verification set and a test set; performing loop iteration on the GRU model by using the training set, and performing parameter adjustment on the trained GRU model by using the verification set; and testing the GRU model after the parameters are adjusted by using the test set, and performing inverse mean normalization processing on the obtained model prediction result to complete landslide displacement prediction and improve prediction precision.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
Claims (5)
1. A landslide displacement prediction method based on GRU is characterized by comprising the following steps:
monitoring landslide surface displacement deformation, and calculating a replacement value of an abnormal value in the obtained landslide displacement data by utilizing a constructed polynomial model;
carrying out mean normalization processing on all the landslide displacement data after being replaced by the replacement values, and constructing a GRU model, a training set, a verification set and a test set;
performing loop iteration on the GRU model by using the training set, and performing parameter adjustment on the trained GRU model by using the verification set;
and testing the GRU model after the parameters are adjusted by using the test set, and performing anti-mean normalization processing on the obtained model prediction result to finish landslide displacement prediction.
2. The GRU-based landslide displacement prediction method of claim 1 wherein monitoring landslide surface displacement deformation and using a constructed polynomial model to calculate a replacement value for the outlier in the resulting landslide displacement data comprises:
monitoring landslide ground surface displacement deformation to obtain a plurality of landslide displacement data, wherein the plurality of landslide displacement data comprise a plurality of normal values and a plurality of abnormal values;
and taking a plurality of normal value serial numbers except the abnormal values as independent variables, taking a plurality of normal values as dependent variables to construct a polynomial model, inputting the abnormal value serial numbers into the polynomial model, and obtaining an output value of the polynomial model, namely a replacement value of the abnormal values.
3. The GRU-based landslide displacement prediction method of claim 1 wherein performing a loop iteration on the GRU model using the training set and performing a parameter adjustment on the trained GRU model using the validation set comprises:
calculating values of an update gate, a reset gate, a hidden state and a current candidate state in the GRU model by using the landslide displacement data in the training set;
calculating the difference value between the landslide displacement data and the corresponding hidden state, and summing all the difference values to obtain a corresponding error term;
adjusting the corresponding weight value based on the error term until the iteration termination condition is reached, and finishing the training of the GRU model;
and verifying the trained GRU model by using the verification set, and adjusting the model learning rate and the number of corresponding model nodes.
4. The GRU-based landslide displacement prediction method of claim 3 wherein adjusting the corresponding weight value based on the error term until completion of training of the GRU model after reaching an iteration termination condition comprises:
respectively deriving the reset gate weight, the updated gate weight and the candidate state weight by using the error term to obtain corresponding derivatives;
subtracting the product of the corresponding derivative and a model learning rate from the reset gate weight, the updated gate weight and the candidate state weight to obtain a new reset gate weight, an updated gate weight and a candidate state weight;
and finishing the training of the GRU model until the current iteration times reach a set iteration threshold or the sum of the error terms is less than a set value.
5. The GRU-based landslide displacement prediction method of claim 1 wherein testing the GRU model after adjusting parameters using the test set and performing an inverse mean normalization of the obtained model prediction results to complete landslide displacement prediction comprises:
inputting the test set into the GRU model after parameters are adjusted to obtain a corresponding model prediction result;
and carrying out anti-mean normalization processing on the model prediction result to obtain final measurement data, and completing landslide displacement prediction.
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CN115511191A (en) * | 2022-09-30 | 2022-12-23 | 固远晨通科技发展有限公司 | High and steep slope displacement point prediction method |
CN117629122A (en) * | 2023-11-24 | 2024-03-01 | 江苏欧普瑞信息科技有限公司 | Dam displacement monitoring and early warning method and system |
CN117629122B (en) * | 2023-11-24 | 2024-06-07 | 江苏欧普瑞信息科技有限公司 | Dam displacement monitoring and early warning method and system |
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