3.1. KPCA

PCA is a powerful tool that can convert a set of data of possibly correlated variables into a set of linearly uncorrelated features called principal components (PCs) by adopting the orthogonal transformation. However, this statistical procedure is a linear technique, which is not suitable to discover and capture nonlinear features among the original dataset. KPCA [26] is an extension of PCA by using kernel methods, which makes the PCA perform in Hilbert space. The KPCA is illustrated as follows.

In high-dimension feature space ${\mathbf{R}}^n\to \mathbf{\Omega }$ , the matrix $X\left|\to \right.\Phi \left(x\right)$ is constructed by samples $x_i\left(i=\mathrm{1,2},\dots ,m\right)$ .

We assume that ${\sum }_{i=\mathrm{1}}^m\Phi \left(x\right)=\mathrm{0}$ , so the covariance matrix ${\mathbf{C}}^{\Omega }$ in the feature space $\mathbf{\Omega }$ can be expressed as follows: $$\begin{array}{}\text{(8)}& {\mathbf{C}}^{\Omega }=\frac{\mathrm{1}}{m}{\displaystyle \sum }_{j=\mathrm{1}}^m\Phi \left(x_j\right)\Phi {\left(x_j\right)}^T.\end{array}$$

The eigenvalue $\lambda$ and eigenvector $\mathbf{v}$ can be obtained by solving the following equation: $$\begin{array}{}\text{(9)}& \lambda \mathbf{v}={\mathbf{C}}^{\Omega }\mathbf{v}.\end{array}$$

Equation (9) is equivalent to the following equation: $$\begin{array}{}\text{(10)}& \lambda \left(\Phi \left(x_k\right)·\mathbf{v}\right)=\Phi \left(x_k\right)·{\mathbf{C}}^{\Omega }\mathbf{v},\hspace{1em}k=\mathrm{1,2},\dots ,m.\end{array}$$

The solutions $\mathbf{v}$ lie in the span of $\Phi \left(x_{\mathrm{1}}\right)$ , $\Phi \left(x_{\mathrm{2}}\right)$ ,…, $\Phi \left(x_m\right)$ , but ${\alpha }_i$ ( $i=\mathrm{1,2},\dots ,m$ ) must exist to satisfy the equation as follows: $$\begin{array}{}\text{(11)}& \mathbf{v}={\displaystyle \sum }_{i=\mathrm{1}}^m{\alpha }_i\Phi \left(x_i\right).\end{array}$$

Let $\mathbf{K}\left(x_i,x_j\right)=\Phi \left(x_i\right)\Phi \left(x_j\right)$ . By combining (8), (9), and (11), we can get $$\begin{array}{}\text{(12)}& m\lambda \mathit{\alpha }=\mathbf{K}\mathit{\alpha },\end{array}$$ where $\mathit{\alpha }$ denotes the column vector with ${\alpha }_i$ ( $i=\mathrm{1,2},\dots ,m$ ). By solving (12), we can obtain the vector ${\alpha }_i^k$ corresponding to ${\lambda }_k$ .

To normalize the eigenvectors $\mathit{\alpha }$ , we require that $$\begin{array}{}\text{(13)}& \mathrm{1}={\mathbf{v}}^k·{\mathbf{v}}^k={\displaystyle \sum }_{i=\mathrm{1}}^m{\alpha }_i{\alpha }_j\mathbf{K}={\lambda }_k\left({\mathit{\alpha }}^k·{\mathit{\alpha }}^k\right).\end{array}$$

The kernel PCs can be calculated as follows: $$\begin{array}{}\text{(14)}& x_k=\left({\mathbf{v}}^k·\Phi \left(x\right)\right)={\displaystyle \sum }_{i=\mathrm{1}}^m{\alpha }_i^k\mathbf{K}\left(x_i,x_j\right).\end{array}$$

The number of kernel PCs are determined by the following. $$\begin{array}{}\text{(15)}& \frac{{\sum }_{i=\mathrm{1}}^l{\lambda }_k}{{\sum }_{i=\mathrm{1}}^m{\lambda }_k}>\mathrm{90}\%\end{array}$$

The derivation above is performed on the basis of the assumption that ${\sum }_{i=\mathrm{1}}^m\Phi \left(x\right)=\mathrm{0}$ . In general, this assumption is difficult to establish, which indicates that $x$ is not guaranteed to be centered in the feature space $\mathbf{\Omega }$ and needs to be centralized. Let ${\mathbf{L}}_m$ be a square matrix of order $m$ and ${\left({\mathbf{L}}_m\right)}_{ij}=\mathrm{1}/m$ and $\mathbf{K}$ can be centralized and presented as follows: $$\begin{array}{}\text{(16)}& \overline{\mathbf{K}}=\mathbf{K}-\mathbf{K}{\mathbf{L}}_m-{\mathbf{L}}_m\mathbf{K}-\mathbf{K}{\mathbf{L}}_m\mathbf{K}\end{array}$$

3.2. Selecting of Kernel Function

The functions that satisfy the Mercer’s theorem are kernel functions [27]. Kernel functions are mainly divided into two categories, namely, local and global kernel functions. Interpolation and extrapolation abilities are the key indexes to determine the performance of KPCA, which is affected by the selection of kernel functions and its parameters. Local kernel function has better interpolation ability, whereas global kernel function shows better extrapolation capability. According to this feature, combining local and global kernel functions by using mixtures is a feasible solution to obtain kernels that have good interpolation and extrapolation capabilities.

Furthermore, radial basis function kernel is a typical local kernel. However, the exponential calculation of radial basis function kernel is computationally inefficient. The K-type kernel [28] has been proposed to be an alternative to radial basis function kernel due to its good performance on calculation and interpolation ability, which is expressed as follows: $$\begin{array}{}\text{(17)}& \overline{\mathbf{K}}\left(x_i,x_j\right)=\frac{m}{\left(\mathrm{1}+k^{\mathrm{2}}{‖x_i-x_j‖}^{\mathrm{2}}\right)},\end{array}$$ where $m>\mathrm{0}$ , $k>\mathrm{0}$ and can represent the width of the K-type kernel.

The polynomial kernel, a typical global kernel, is expressed as follows: $$\begin{array}{}\text{(18)}& \overline{\mathbf{K}}\left(x_i,x_j\right)={\left[a\left(x_i,x_j\right)+\mathrm{1}\right]}^d,\end{array}$$ where $a$ is the free parameter and $d$ is the order of the polynomial kernel.

Linear and multiplicative combinations are typical method of mixing kernels [29], which can be expressed as follows: $$\begin{array}{c}\text{(19)}& \overline{\mathbf{K}}\left(x_i,x_j\right)={\mathbf{K}}_{\mathrm{1}}\left(x_i,x_j\right)+{\mathbf{K}}_{\mathrm{2}}\left(x_i,x_j\right)\overline{\mathbf{K}}\left(x_i,x_j\right)=\alpha \mathbf{K}\left(x_i,x_j\right),\end{array}$$ where $\alpha >\mathrm{0}$ and $\overline{\mathbf{K}}$ and $\mathbf{K}$ denote the kernel functions. Thus, a hybrid kernel containing K-type kernel and polynomial kernel can be combined as follows: $$\begin{array}{c}\text{(20)}& \overline{\mathbf{K}}=\gamma {\mathbf{K}}_k+\left(\mathrm{1}-\gamma \right){\mathbf{K}}_{poly}\overline{\mathbf{K}}\left(x_i,x_j\right)=\gamma \left(\frac{m}{\left(\mathrm{1}+k^{\mathrm{2}}{‖x_i-x_j‖}^{\mathrm{2}}\right)}\right)+\left(\mathrm{1}-\gamma \right)\left({\left[a\left(x_i,x_j\right)+\mathrm{1}\right]}^d\right),\end{array}$$ where $k$ , $m$ , $a$ , $d$ , and $\gamma$ are the parameters of the kernel.

3.3. MAFSA

Artificial fish-swarm algorithm (AFSA) is an effective swarm intelligent optimization algorithm [30], which is on the basis of the four behaviors of a natural fish, namely, preying, swarming, following, and random behaviors. In AFSA, each artificial fish allows mutual information communications and independently performs the four behaviors proposed until the global optimal state is obtained. We suppose there are $N$ artificial fish and the position of any artificial fish is $X$ . The food consistence at position $X$ is denoted by $Y=f(X)$ (objective function), where $X$ is the vector in $n$ -dimensional space and $n$ is the number of parameters to be optimized on the basis of practical problems. Let $X_i=(x_{i\mathrm{1}},x_{i\mathrm{2}},\cdots ,x_{in})$ and $X_j=(x_{j\mathrm{1}},x_{j\mathrm{2}},\cdots ,x_{jn})$ , which are the current and next positions of an artificial fish, respectively. Hence, the straight distance between $X_i$ and $X_j$ can be expressed as $D_{ij}=‖X_i-X_j‖$ . $STEP$ and $VISUAL$ are defined as the moving step and perception range of each artificial fish, respectively. MAFSA is an improvement of AFSA, which modifies the moving step and perception range in basic AFSA. The basic idea of MAFSA will be described briefly as follows.

(1 ) Preying Behavior. In general, fish gather to the position with higher food concentration. If $Y_i<Y_j$ , then the artificial fish will move a $STEP$ from $X_i$ to $X_j$ , which can be expressed as follows: $$\begin{array}{}\text{(21)}& X_j=X_i+\mathit{\text{STEP}}·\frac{X_j-X_i}{D_{ij}}\times \mathit{\text{rand}}\left(\mathrm{0,1}\right).\end{array}$$

If $Y_i>Y_j$ , then the artificial fish will randomly select the next position $X_j$ and determine whether the forward condition is satisfied. $Num$ denotes the number of maximum iteration of the artificial fish. The reattempt times must be less than $TRY\_Num$ , or the artificial fish will execute a random behavior.

(2 ) Swarming Behavior. During the moving process of the fish swarm, each artificial fish moves toward the center position $X_c$ of its neighbor artificial fish $(D_{ic}<VISUAL)$ . The number of the neighbor artificial fish is $n_f$ . $\delta$ denotes the crowded degree of the artificial fish swamp. If $Y_c/n_f>\delta Y_i$ , then the artificial fish will move a $STEP$ from $X_i$ to $X_c$ , which can be expressed as follows: $$\begin{array}{}\text{(22)}& X_j=X_i+\mathit{\text{STEP}}·\frac{X_c-X_i}{D_{ic}}\times \mathit{\text{rand}}\left(\mathrm{0,1}\right).\end{array}$$

If $Y_c/n_f<\delta Y_i$ , which indicates that the food consistence at center position $X_c$ is low and swarm is relatively crowded, then the artificial fish will perform preying behavior.

(3 ) Following Behavior. In the fish swarm, when an artificial fish finds the area with high food consistence at position $X_b$ , it will quickly be followed by the neighbor artificial fish $\left(D_{ib}<VISUAL\right)$ . $n_f$ denotes the number of the neighbor artificial fish. If $Y_b/n_f>\delta Y_i$ , then the artificial fish will move a $STEP$ from $X_i$ to $X_b$ , which can be expressed as follows: $$\begin{array}{}\text{(23)}& X_j=X_i+STEP·\frac{X_b-X_i}{D_{ib}}\times \mathit{\text{rand}}\left(\mathrm{0,1}\right).\end{array}$$

If $Y_b/n_f<\delta Y_i$ , then the artificial fish will perform preying behavior.

(4 ) Random Behavior. A random behavior is the default of the preying behavior, which indicates that the artificial fish will opt a position randomly in its visual scope and move toward this position. The expression is determined as follows: $$\begin{array}{}\text{(24)}& X_j=X_i+VISUAL·\mathit{\text{rand}}\left(\mathrm{0,1}\right).\end{array}$$

(5 ) Improvement of the Step and Visual. In basic AFSA, the moving step and the perception range of the artificial fish are fixed. Relatively large values of $STEP$ and $VISUAL$ make most artificial fish gather to the global optimal solution quickly, but this may result in the premature convergence. On the contrary, the local search capability of the artificial fish can be enhanced by adopting relatively small values of $STEP$ and $VISUAL$ . Consequently, the artificial fish may fall into the local optimum and miss the global optimal solution. To achieve the faster convergence rate and keep the balance between the global and local searches, a variable parameter $\beta (t)$ is introduced to improve the values of the step and visual, which can be presented as follows: $$\begin{array}{c}\text{(25)}& \beta \left(t\right)=\exp \left(-\mathrm{23}\times {\left(\frac{t}{NUM}\right)}^k\right)VISUA{L}_t=\beta \left(t\right)\times VISUAL+VISUA{L}_{\mathrm{m}\mathrm{i}\mathrm{n}}\\ STE{P}_t=\beta \left(t\right)\times STEP+STE{P}_{\mathrm{m}\mathrm{i}\mathrm{n}},\end{array}$$ where $k$ denotes the attenuation parameters. If the value of $k$ is small, then $\beta (t)$ will significantly decrease at the initial iteration stage. $t$ is the current iteration number. $VISUA{L}_{\mathrm{m}\mathrm{i}\mathrm{n}}$ and $STE{P}_{\mathrm{m}\mathrm{i}\mathrm{n}}$ are the minimum of the perception range and step, respectively.

3.4. Parameter Optimization of Kernel Function on the Basis of MAFSA

The values of the kernel parameters directly affect the performance of KPCA. Therefore, we utilize MAFSA to search the optimal solution to the parameters of different kernels. Here, we consider the contribution rate of the first kernel PC $P{C}_1$ as objective function. The purpose is to represent the original temperature data using another set of uncorrelated variables with minimum numbers while simultaneously minimizing the loss of information. The basic procedures of these optimization problems are described as follows.

4.1. RBF Neural Network

RBF-NN is one of the most popular neural networks and extensively used in several fields, especially in classification and regression. The RBF-NN is a three-layer neural network [31], which includes input, hidden, and output layers. Similar to other feed-forward neural networks, RBF-NN is composed of large quantities of interconnected artificial neurons. Every neuron in the radial basis function network is completely connected with each neuron of the next layer. The topology of RBF-NN is shown in Figure 1. In comparison with the BP-NN, RBF-NN can approach the nonlinear continuous function with arbitrary precision and avoid falling into the local minimum point effectively.

RBF-NN contains the following important features.

(1) The input domain contains the center vector denoted by $C_{jp}$ which is also called cluster center. $C_{jp}$ is stored as a weight factor from the input layer to the hidden layer. Euclidean distance, typically represented as $E{D}_j=‖x_p-C_{jp}‖$ , is used to measure the distance of the input sample $x_p$ from the cluster center $C_{jp}$ , where $j=\mathrm{1,2},\dots ,M$ , $p=\mathrm{1,2},\dots ,P$ , $M$ is the total number of data centers, and $P$ is the total number of samples. The clustering center $C_{jp}$ is determined by K-means clustering algorithm.

(2) Gaussian function is typically selected as the hidden layer transfer function, which is expressed as follows: $$\begin{array}{}\text{(26)}& \phi {\left(r\right)}_j=\exp \left(-\frac{E{D}_j^{\mathrm{2}}}{\mathrm{2}{\sigma }^2}\right),\end{array}$$ where $\sigma$ is the spread constant of the radial basis function, which is denoted by $\sigma ={\left(E{D}_j\right)}_{\mathrm{m}\mathrm{a}\mathrm{x}}/\sqrt{M}$ . ${\left(E{D}_j\right)}_{\mathrm{m}\mathrm{a}\mathrm{x}}$ is the maximum Euclidean distance among selected centers.

(3) The output of the RBF-NN is represented by the following equation: $$\begin{array}{}\text{(27)}& y_i={\displaystyle \sum }_{j=\mathrm{1}}^N{w}_{ij}\phi {\left(r\right)}_j,\hspace{1em}i=\mathrm{1,2},\dots ,N,\end{array}$$ where $w_{ij}$ is the weight of the hidden layer to the output layer $w_{ij}$ , $w_{ij}$ is determined by gradient descent algorithm [32], and $N$ is the total number of hidden layer nodes.

4.2. Procedure of the Model

RBF-NN is adopted to construct the dam displacement prediction model. Hydrostatic pressure, time effect, and kernel PC of temperature are selected as the input variables of the RBF-NN model. The output of the model is the radial displacement of the single or multiple measuring points of the dam. In the structure of RBF-NN, two important tuning parameters are used, namely, the maximum number of hidden layers and the spread. The performance and the prediction accuracy of the developed model depend on the values of these two parameters. In this paper, trial and error is utilized to evaluate the optimum values of these two parameters to obtain a precise and reliable performance for the model. The developed model is implemented on the MATLAB platform, and the main steps are as follows.

The flowchart of the model is shown in Figure 2. The performance criteria in Step 5 include the decision coefficient ( $R^{\mathrm{2}}$ ), root mean square error ( $RMSE$ ), average absolute error ( $MAE$ ), and maximum absolute error ( $E$ ), which are expressed as follows: $$\begin{array}{}\text{(28)}& R^{\mathrm{2}}=\frac{{\left[{\sum }_{i=\mathrm{1}}^N\left(y_S\left(i\right)-{\stackrel{-}{y}}_S\right)\left(y\left(i\right)-\stackrel{-}{y}\right)\right]}^{\mathrm{2}}}{{\sum }_{i=\mathrm{1}}^N{\left(y_S\left(i\right)-{\stackrel{-}{y}}_S\right)}^{\mathrm{2}}{\sum }_{i=\mathrm{1}}^N{\left(y\left(i\right)-\stackrel{-}{y}\right)}^{\mathrm{2}}}\text{(29)}& RMSE=\sqrt{\frac{\mathrm{1}}{N}{\displaystyle \sum }_{i=\mathrm{1}}^N{\left(y_S\left(i\right)-y\left(i\right)\right)}^{\mathrm{2}}}\text{(30)}& MAE=\frac{\mathrm{1}}{N}{\displaystyle \sum }_{i=\mathrm{1}}^N\left|y_S\left(i\right)-y\left(i\right)\right|\text{(31)}& E=\max \left|y_S\left(i\right)-y\left(i\right)\right|\end{array}$$ where $y_S(i)$ and $y(i)$ represent the simulated and measured values of the model, respectively ( $i=\mathrm{1,2},\dots ,N$ ); ${\stackrel{-}{y}}_S$ and $\stackrel{-}{y}$ denote the simulated and measured average values, respectively; and $N$ denotes the number of observations. Larger $R^{\mathrm{2}}$ and smaller $RMSE$ , $MAE$ , and $E$ indicate that the model has better performance.

5.1. Project Profile

A double-curvature super-high concrete arch dam is located downstream on the Yalong River in Sichuan Province, China. The maximum dam height above ground level is 305 m and the elevation of the dam crest is 1885 m. The dam consists of 26 dam sections, with a dam crest length of 552 m. The width of the dam crest and bottom is 16 m and 63 m, respectively. The storage capacity of the reservoir is 7.76 billion m³. The normal reservoir level is about 1880 m above sea level. The dam construction began in 2005 and was completed in 2014, with its main purposes as hydroelectric power generation and flood control.

The dam automatic monitoring system is composed of several types of instruments, including water level gauges, pendulums, thermometers, strain gauges, piezometers, and osmometers. In this paper, radial displacement data acquired from the PL13-2 direct pendulum is studied. As is shown in Figure 3, the #13 dam section is located in the middle of the valley, and PL13-2 direct pendulum is equipped in the upper part of the #13 dam section where the radial displacement range is relatively large. Furthermore, the monitoring of data is continuous, which is helpful for modeling and analysis. The dataset for modeling is established from July 2013 to November 2016, which accumulated a total of 175 groups of data.

5.2. Temperature Variables

The thermometers installed in #13 dam section are approximately distributed within the range of 1620–1881 m in elevation. The temperature data collected from 45 thermometers, where the data are continuous, is studied and analyzed. To test the proposed KPCA’s performance on feature extraction and dimensionality reduction of input temperature dataset, the comparison with PCA is carried out.

5.3. Model Establishment

As described in Sections 2 and 3, the hydrostatic pressure, temperature, and time effect variables are determined as independent variables, whereas the measured radial displacements from 13-2 point are selected as dependent variables. Hydrostatic pressure variables contain four factors, namely, $H$ , $H^{\mathrm{2}}$ , $H^{\mathrm{3}}$ , and $H^{\mathrm{4}}$ . Meanwhile, the time effect variables have four factors, namely, $\theta$ , $\mathrm{1}-e^{-\theta }$ , $\ln \left(\theta +\mathrm{1}\right)$ , and $\theta /\left(\theta +\mathrm{1}\right)$ . Figures 8 and 9 show the measured upstream water level and measured radial displacements from 13-2 point, respectively. In Figure 9, negative values denote the radial displacements toward the upstream. The RBF-NN is used as a framework to build the model. Therefore, the dependent variables are selected as inputs, and independent variables are selected as output of the RBF-NN.

The first 160 groups are utilized for training, and the remaining 15 samples are adopted as testing set. Here, we establish four safety monitoring models on the basis of RBF-NN that involve the same hydrostatic pressure, time effect, and different temperature variables. Model 1 contains a total of thirteen input variables, of which the temperature variables are calculated using PCA and involve five factors. Models 2, 3, and 4 each contain nine input variables, and their temperature variables are calculated by utilizing K-type KPCA, Polynomial KPCA, and the proposed Hybrid-KPCA, respectively.

For these four safety monitoring models on the basis of RBF-NN, the training objective of the mean square error is set to $\mathrm{1}{\mathrm{0}}^{-\mathrm{4}}$ . The values of spread and hidden nodes are determined using trial and error. The value of spread is selected in the interval $[1,3]$ with a minimum step of 0.01, whereas the value of hidden layer nodes is selected in the interval $[10,40]$ with a minimum step of 1. Figure 10 shows the effects of the values of spread and hidden nodes on the performance of these four models, and the optimum values are summarized in Table 3. In Figure 10, the errors of models 3 and 4 are relatively smaller than the others. Moreover, the error variation range of model 4 is the smallest.

Table 3

Parameters of RBF-NN.

[figures omitted; refer to PDF]

5.4. Performance Evaluations and Discussions

To graphically and statistically evaluate the performance of the proposed models, comparisons among the measured, fitted, and predicted values are firstly carried out by plotting from Figures 11–14. Then, the values of performance criteria for the four models are listed in Table 4, and the best results are shown in boldface. The obtained evaluation conclusions can be summarized as follows.

Table 4

Comparison of prediction error for the models.

(1) These four models’ decision coefficients ( $R^{\mathrm{2}}$ ) are all larger than 0.99. In addition, the four models are all capable of fitting and predicting the trend of radial displacements accurately due to the good performance of RBF-NN.

(2) The predicted deviations of Polynomial KPCA-RBF-NN model and Hybrid-KPCA-RBF-NN model are relatively smaller than PCA-RBF-NN model and K-type KPCA-RBF-NN model. In Table 4, we can find that K-type KPCA-RBF model obtains the smallest absolute error ( $E$ ), average root mean square error ( $RMSE$ ), and average absolute error ( $MAE$ ). Although the fitting performance of K-type KPCA-RBF-NN model is not the best, its predictive performance is better than PCA-RBF-NN model.

(3) The prediction results of PCA-RBF-NN model are more unstable than the other models, which may be due to the loss of nonlinear feature in the temperature variables by using PCA.