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Response analysis and optimization of the air spring with epistemic uncertainties

  • Feng Kong , Yu Bai , Xifeng Liang , Zhaijun Lu and Shengwen Yin EMAIL logo
Published/Copyright: March 3, 2022
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REVIEWS ON ADVANCED MATERIALS SCIENCE
From the journal REVIEWS ON ADVANCED MATERIALS SCIENCE Volume 61 Issue 1

Abstract

Traditional methods for the optimization design of the air spring are based on the deterministic assumption that the parameters are fixed. However, uncertainties widely exist during the manufacturing stage of the air spring. To model the uncertainties in air springs, evidence theory is introduced. For the response analysis of the air spring system under evidence theory, an evidence theory-based polynomial chaos method, called the sparse grid quadrature-based arbitrary orthogonal polynomial (SGQ-AOP) method, is proposed. In the SGQ-AOP method, the response of the air spring is approximated by AOP expansion, and the sparse grid quadrature is introduced to calculate the expansion coefficient. For optimization of the air spring, a reliability-based optimization model is established under evidence theory. To improve the efficiency of optimization, the SGQ-AOP method is used to establish the surrogate model for the response of the air spring. The proposed response analysis and the optimization method were employed to optimize an air spring with epistemic uncertainties, and its effectiveness has been demonstrated by comparing it with the traditional evidence theory-based AOP method.

Keywords: evidence theory; arbitrary orthogonal polynomial; sparse grid quadrature; optimization; air spring

1 Introduction

Air springs have a wide range of applications in suspension systems for railway vehicles, commercial, and personal cars [1,2,3]. Figure 1 shows an air spring of a railway locomotive. Compared to other suspension systems, the advantages of the air spring mainly include low natural frequency, excellent vibration isolation performance in high-frequency, and low rate of force transmission [4]. By the control of the intake valves, the working height and ride comfort under different ride conditions can be adjusted in an adaptable way, which makes the air spring attractive to luxurious vehicles.

Figure 1 Air spring of railway locomotive.
Figure 1

Air spring of railway locomotive.

In the application of an air spring for engineering, its optimal stiffness varies for different kinds of vehicles. In addition, the strain of the spring material should be minimized to improve the fatigue life of the air spring [5]. Thus, there is an increasing demand for the optimization design of the air spring. Traditional response analysis and optimization methods for the design of an air spring are deterministic approaches in which the parameters are considered to be fixed [6,7]. However, uncertainties due to manufacturing and other factors inevitably exist in practice. It is shown in ref. [8] that the change of material parameters has a great effect on the stiffness of the air spring system. Without considering these uncertainties, the optimal results obtained by using deterministic methods may be unreliable. Therefore, for the design of an air spring, it is desirable to develop the response and optimization methods considering the effect of uncertainties.

To model the uncertainty, different kinds of uncertainty quantification theories have been developed. The most widely used technique for uncertainty quantification is the probability theory [9,10,11]. When the probabilistic model is used to deal with uncertainties, the probability density function (PDF) of the uncertain parameter should be obtained. However, the data to determine the PDF are always unavailable in practice. To model the uncertain parameter without sufficient probabilistic information, some other uncertainty quantification techniques have been developed, such as evidence theory [12,13], fuzzy theory [14,15], P-box theory [16], interval analysis [17,18], etc. Evidence theory is treated as an appropriate complement to probability theory in uncertainty problem analysis when the distribution of the uncertain variables is roughly regarded as several finite intervals [19]. In evidence theory, the uncertain parameter is defined as several intervals and its associated basic probability assignments (BPA). Under different situations, evidence theory can be equivalent to special probability uncertain or interval uncertain problems. When the number of focal elements tends to infinity or 1, the evidence parameters can be equal to the probability or interval parameter. Furthermore, evidence theory can handle conflicting information from experts. In comparison to the other modeling techniques, the evidence theory is a more flexible framework. Due to these typical properties, evidence theory has been applied in structural uncertainty analysis extensively in recent years [20,21,22].

Compared to the optimization of an air spring with deterministic parameters, the evidence theory-based response analysis and optimization of the air spring is more challenging. Under evidence theory, the extreme value analysis should be implemented over each focal element, which is a time-consuming process. In recent years, lots of research has been dedicated to reduce the computational cost related to evidence theory-based uncertainty analysis. One typical method is to use the interval perturbation method to obtain the extreme value in each focal element [23,24,25]. Bai et al. employed the perturbation method to obtain the approximate response bounds for each focal element [23]. By using the perturbation method, the response of the structure under evidence theory can be efficiently obtained. Shengwen et al. proposed an evidence theory-based finite element-statistical energy analysis method for mid-frequency analysis of the structure–acoustic system, in which the second perturbation method is used to calculate the response in each focal element [24]. Chen et al. extended the evidence theory and the perturbation technique for the prediction of an exterior acoustic field with epistemic uncertainties [25]. Compared to Monte Carlo simulation, the interval perturbation method can greatly improve computational efficiency. However, the computational cost of the interval perturbation method still suffers from the large computational burden, as the perturbation analysis needs to be repeated for each focal element. Another popular method for evidence theory-based uncertainty analysis is the surrogate modeling method, such as the polynomial chaos method. Originally, global surrogate models have been introduced for evidence-theory-based uncertainty analysis [26,27]. Subsequently, the Jacobi polynomial expansion [28] and Gegenbauer series expansion [29] have been applied in evidence theory to deal with the structural–acoustic problems. Chong [30] proposed an evidence theory model that combined the Legendre-type polynomial with the Clenshaw–Curtis point to improve the optimization efficiency of complex mechanical problems. Recently, Shengwen et al. investigated the influence of polynomial basis types on the accuracy of the orthogonal polynomial expansion surrogate model. It is shown that the computational accuracy can be improved efficiently by appropriately selecting the type of the polynomial basis [31]. Based on the above research, the evidence-theory-based arbitrary orthogonal polynomial (AOP) method has been proposed and applied to the structure–acoustic systems for uncertainty analysis with epistemic uncertainties [31].

In an overview, there is an increasing demand in the optimization design of an air spring, but the development of numerical methods for the optimization of the air spring is still at the early stage, and some problems still remain unsolved. First, the response and optimization model for the air spring system with epistemic uncertainties have not been established. It is shown in ref. [3] that the response of the air spring system is very sensitive to some input parameters, such as the material properties of the cord, the cord angle. Without considering these uncertainties, the results obtained by using the deterministic optimization method may be unreliable. Thus, it is desirable to develop an optimization model for the air spring system considering epistemic uncertainties. Second, though the AOP method shows good convergence properties for evidence-theory-based uncertainty analysis, the computational burden of AOP by using Gauss quadrature will increase exponentially with the number of variables. The air spring system always involves many uncertain parameters, and the computational burden for finite element analysis of the air spring is relatively large. Thus, it is necessary to improve the computational efficiency of AOP for uncertainty quantification under evidence theory.

The aim of this article is to develop an efficient response analysis and optimization method for the air spring system with epistemic uncertainties. The evidence theory is introduced to model the uncertain parameters in an air spring. For response analysis of the air spring system with evidence variables, a sparse grid quadrature-based arbitrary orthogonal polynomial (SGQ-AOP) method is proposed by introducing the evidence theory-based AOP and the sparse quadrature technique. In particular, the evidence theory-based AOP expansion [31] is introduced to approximate the response of the air spring system, and the sparse quadrature is used to calculate the expansion coefficient of the AOP expansion. For optimization of the air spring system under evidence theory, the proposed sparse quadrature-based AOP expansion is used to establish the surrogate model for the response of the air spring system. Based on the surrogate model, the optimal result can be efficiently obtained by using the genetic algorithm. The response analysis and optimization of an air spring system with epistemic uncertainties have been introduced to investigate the proposed method.

2 Evidence theory-based uncertainty analysis by using polynomial expansion and sparse grid quadrature

In this section, the fundamental evidence theory is briefly introduced. To reduce the computational cost of the traditional evidence theory-based polynomial chaos method, a new method called the SGQ-AOP method is proposed. The main difference between the SGQ-AOP method and the traditional evidence theory-based polynomial chaos method is that the sparse grid quadrature is used to calculate the expansion coefficient of the polynomial chaos expansion, instead of Gaussian quadrature.

2.1 Fundamentals of evidence theory

In evidence theory, an event space can be defined by a mathematical triplet ( Ω , Θ , m ) where Ω denotes the universal set; Θ is a countable collection of subsets of Ω , which is also called as FD; and m is the BPA, which satisfied the following three axioms [10]:

(1) m ( A ) 0 , A Θ , m ( ) = 0 , A Θ m ( A ) = 1 ,

where m ( A ) is the BPA for the subset A of Θ , and the subset A satisfying m ( A ) > 0 is called as the focal element of the evidence space.

As the precise probability distribution in each focal element is not available, an interval that includes the Bel and Pl is employed to represent the uncertainty of probability as follows:

(2) Bel ( B ) = A B m ( A ) , Pl ( B ) = A B 0 m ( A ) .

In the above equation, the belief measure Bel ( B ) is the summation of BPA in the proposition, which is totally included in propositions, while the plausibility measure Pl( B ) is obtained by summing the BPA of events that are totally or partially included in event B. According to the evidence theory [29], each uncertain variable can be represented by more than one interval. For example, an uncertain variable U represented by evidence theory can be formulated as

(3) U = { ( U 1 I , m 1 ) , , ( U i I , m i ) , , ( U l I , m l ) } ,

where the interval U i I ( i = 1 , 2 , , l ) is the ith focal element of U, l is the total number of focal elements and m i is the BPA of U i I . These intervals can be overlapping, contiguous, or have gaps. The BPA is typically derived from the experimentation or expert opinion, indicating how likely the uncertain input falls within the specified interval U i I .

For multiple variables problem U = [ U 1 , U 2 , , U k ] , the formation of joint BPA is similar to the solution of joint PDF in probability theory. The joint FD of variables U can be formulated as the Cartesian product of each focal element of total uncertain variables, which can be expressed as

(4) U = { ( U 1 I , m 1 ) , , ( U i I , m i ) , , ( U l I , m l ) } ,

where

(5) U s k = [ U s k , 1 l , U s k , 2 l , , U s k , k l ] U 1 × U 2 × U k , s k = 1 , 2 , , N s .

Here, U s k is the joint focal element of each of the joint FD, with each of U s k , k l U i l meaning the focal element of U i , and N s is the total number of each focal element. The joint BPA of U s k can be calculated by

(6) m ( U s k ) = j = 1 k m ( U s k , i l ) , 0 , else .

According to the above definition, the specific distribution of each focal element is not required. Even if the data are not sufficient to construct the precise PDF of an uncertain variable, the uncertain model can still be established without assumption.

Considering a function y = f ( U ) , the belief and plausibility of y can be calculated as

(7) Bel ( y Y l ) = { u s k y s k l = f ( u s k l ) Y l } m ( U s k l ) ,

(8) P l ( y Y l ) = { u s k y s k l = f ( u s k l ) Y l } m ( U s k l ) .

In the above equations, y s k l can be calculated through

(9) y s k l = [ y S k ̲ , y S k ¯ ] = [ min g ( U ) U U S k l , max g ( U ) U U S k l ] .

The y S k ̲ and y S k ¯ are the minimum and maximum values of y s k l , respectively.

According to ref. [23], the mean value and variance of evidence variables can be defined as follows:

(10) μ ( y ) = S k = 1 N y S k l m ( U S k l ) ,

(11) var ( y ) = S k = 1 N ( y S k l μ ( y ) ) 2 m U S k l .

Therefore, by using the evidence theory model, the statistic property of y will be an interval rather than a fixed value.

2.2 The SGQ-AOP method for evidence theory-based uncertainty analysis

2.2.1 AOP expansion

The AOP expansion for the approximation of a function can be expressed as follows:

(12) Y ( x ) = i = 0 N y i φ i ( x ) ,

where N is the retained order, y i represents the expansion coefficient, and φ i ( ξ ) denotes the polynomial basis of order i, which satisfied the following orthogonality relation:

(13) φ i ( ξ ) , φ j ( ξ ) = h i δ i j ,

where h i = φ i 2 ( ξ ) and , denotes the inner product, which can be expressed as

(14) φ i ( ξ ) , φ j ( ξ ) = φ i ( ξ ) φ j ( ξ ) w ( ξ ) d ξ .

In the above equation, w ( ξ ) is the weight function, which can be an arbitrary continuous or discrete function, such as the piecewise function. The free choice of the weight function of polynomial basis is the main advantage of AOP expansion.

Suppose w ( ξ ) is a positive measure supported on an interval such that all moments μ k = ξ k w ( ξ ) d ξ exist and are finite. Then, there always exists a set of orthogonal polynomials that satisfy the following relations [32]:

(15) φ 1 ( ξ ) = 0 , φ 0 ( ξ ) = 1 , φ k + 1 ( ξ ) = ( ξ a k ) φ k ( ξ ) b k φ k 1 ( ξ ) , k = 0 , 1 , 2 , ,

where a k and b k ( k = 1 , 2 , ) of the AOP expansion can be determined by

(16) a k = ξ φ k ( ξ ) , φ k ( ξ ) φ k ( ξ ) , φ k ( ξ ) , k = 0 , 1 , 2 , ,

(17) b k = φ k ( ξ ) , φ k ( ξ ) φ k 1 ( ξ ) , φ k 1 ( ξ ) , k = 1 , 2 , .

In the above equations, the coefficient b 0 is arbitrary and set by convention such that b 0 = w ( x ) d x .

Based on the orthogonality of the polynomial basis, y i in equation (1) can be calculated as [32]

(18) y i = Y ( x ) , φ i ( x ) φ i ( x ) , φ i ( x ) = 1 h i Ω Y ( x ) φ i ( x ) ρ ( x ) d x .

The integral in the above equation can be calculated by the Gaussian quadrature as follows [32]:

(19) y i = 1 h i Ω Y ( x ) φ i ( x ) ρ ( x ) d x = 1 h i i = 1 m Y ( x ˆ i ) φ i ( ( x ˆ i ) w ˆ i ,

where x ˆ i and w ˆ i are the Gaussian nodes and the Gaussian weights, respectively; m is the total number of Gaussian nodes; and x ˆ i and w ˆ i can be obtained from the eigenvalue decomposition of the Jacobi matrix assembled with a i and b i . Particularly, the Jacobi matrix J n can be expressed as [32]

(20) J n = a 1 b 1 b 1 a 2 b 2 b 2 a n 1 b n 1 b n 1 a n .

In particular, if V T J n V = diag ( λ 1 , λ 2 , , λ n ) and V T V = I , where I is the n × n dimension identity matrix. Then, the desired x ˆ i and w ˆ i can be determined by

(21) x ˆ i = λ i , w ˆ i = b 0 v i , 1 2 , i = 1 , 2 , ,

where v i , 1 is the first component of the ith column vector of V .

For a function with multiple evidence variables, the AOP expansion can be expressed as

(22) y = f ( U ) = 0 i 1 + + i L 1 + + i L n f i 1 , , i L φ i 1 , , i L ( U ) ,

where

(23) φ i 1 , , i L ( U ) = φ i 1 ( U 1 ) × × φ i L ( U L ) .

In the above equations, n is the retained order of AOP expansion, f i 1 , , i L is the expansion coefficient to be estimated, and φ i k ( U k ) ( k = 1 , 2 , , L ) is the polynomial basis related to U k . Theoretically, an arbitrary polynomial basis can be used to construct the AOP expansion for the approximation of the response of the unified evidence uncertain model of three uncertain problems. However, the choice of the polynomial basis can have a great effect on the accuracy of the polynomial chaos method for random and epistemic uncertainty analysis [31]. According to ref. [31], the weight function of optimal polynomial basis can be determined according to the BPA of evidence variables as follows:

(24) f ξ ( ξ ) = j = 1 δ j ( ξ ) m ( B ˜ j ) / ( U j L j ) ,

where B j is the jth focal elements of ξ , and L j and U j are the lower and upper bounds of B j . By the above treatment, a transformed PDF for each evidence variable can be obtained.

In traditional AOP, the expansion coefficients in equation (22) are calculated by

(25) f i 1 , , i L = 1 h i 1 × × h i L j 1 = 1 M 1 × j L = 1 M L F ( U ˆ j 1 , , U ˆ j L ) φ i 1 , , i L ( U ˆ j 1 , , U ˆ j L ) w ˆ i 1 , , i L ,

where U ˆ j 1 , , U ˆ j L denote the Gaussian nodes of evidence variables, respectively; w ˆ j 1 , , j L = k = 1 L w ˆ j k denotes the Gaussian weight; M j ( j = 1 , 2 , , L ) denotes the number of Gaussian nodes related to the jth variable; and U ˆ j k and w ˆ j k denote the j k th Gaussian node and weight related to the kth variable, respectively. The detailed procedure to determine U ˆ j k and w ˆ j k can be found in ref. [31].

It can be found from equation (25) that the total number of Gaussian points to determine the coefficient is N = k = 1 L M k . Obviously, the total number of Gaussian points will increase exponentially with the increasing number of uncertain parameters, which may lead to tremendous computational costs. In order to improve the computational efficiency of the moment-based polynomial chaos expansion for interval and random analysis, the sparse grid quadrature will be introduced to calculate the expansion coefficient.

2.2.2 Sparse grid quadrature

The sparse quadrature is based on the Smolyak algorithm, which has been widely used in the fields of numerical integration and interpolation and image processing. In this section, the basic principles of sparse quadrature for calculating the expansion coefficient will be deduced.

A continuous function F ( x ) defined on x [ 1 , 1 ] can be approximated as Q l 1 ( F ) , l L . Similarly, the L-dimensional problem can be defined as ( Q l 1 1 Q l d 1 ) ( F ) by the tensor product. According to the nested hierarchical basis principle of the Smolyak algorithm, the difference format of the approximated function is [33]

(26) Δ k 1 ( F ) = ( Q k 1 Q k 1 1 ) ( F ) , Q 0 1 ( F ) = 0 .

Furthermore, for a L-dimension problem, the approximated function with the order- l of the Smolyak algorithm can be contrasted as

(27) Q 1 L ( F ) = k l + L 1 ( Δ k 1 1 Δ k L 1 ) ( F ) ,

where expresses the operation of the tensor product and k denotes the sum of the multidimensional indicators ( k = i = 1 d k i ). By the operation of the tensor product, equation (27) can be expressed as

(28) Q 1 d ( F ) = l + 1 k l + d ( 1 ) l + d k d 1 l + d k × ( Q k 1 1 Q k d 1 ) ( F ) .

Therefore, the integration points in the square grids can be defined as

(29) U 1 d = l + 1 k l + d ( U k 1 1 U k d 1 ) .

The number of the integration points based on the sparse grid method is estimated by

(30) U 1 d = l + 1 k l + d ( U k 1 1 U k d 1 ) .

The corresponding coefficient of the weights is

(31) w k 1 k L i 1 i L = ( 1 ) l + d k d 1 l + d k ( w k 1 i 1 w k L i L ) .

2.3 The procedure of the SGQ-AOP method for response analysis under evidence variables

The core idea of the SGQ-AOP method is to use the sparse quadrature to calculate the expansion coefficient of the evidence theory-based polynomial chaos expansion. The main steps of the SGQ-AOP method are as follows:

  1. Determine the weight function for each evidence variable according to equation (24).

  2. Construct the polynomial basis for each evidence variable by equations (15)–(17).

  3. Obtain the integration points of the sparse grid quadrature according to equation (29).

  4. Calculate the expansion coefficient.

3 Reliability-based optimization of the air spring under evidence theory

The strain of air spring has a great effect on the fatigue life of air spring. To improve the fatigue life of the air spring, the strain of the air spring should be optimized. Particularly, the purpose of the optimization of an air spring system is to reduce its potential strain. Therefore, the objective function of the air spring system with an evidence variable can be described as

(32) min d Exp ( u ( d , A ) ) ,

where d = [ d 1 , d 2 , , d R ] represents design variables, A is an evidence vector, and Exp(u(d, A)) denotes the mean value of the response. According to equations (10) and (11), the objective function is an interval. If the maximal potential value of Exp(u(d, A)) satisfies the engineering requirements, the other values will also satisfy the engineering requirements. Therefore, the maximal potential value of Exp(u(d, A)) can be selected as the objective function. Namely, the objective function shown in equation(33) can be expressed as

(33) min d Exp ( u ( d , A ) ) max .

The air spring system is a shock absorber in which the vibration performances (such as the stiffness) should be considered. These performances can be constrained by reliability conditions. The reliabilities are probabilities of performances satisfying design requirements. Therefore, the reliability constraint conditions can be expressed as

(34) Prob ( g h ( d , A ) 0 ) η h , h = 1 , 2 , , H ,

where g h (d, A) (h = 1,2,…,H) is the hth limit-state function that stands for the performance of a structural–acoustic system, and η h is the hth target reliability. When η h = 1, the reliability constraint conditions transformed to a deterministic constraint.

Based on equations (34) and (35), the reliability-based optimization model of the spring system under evidence theory can be expressed as

(35) min d Exp ( u ( d , A ) ) max , s .t . Prob ( g h ( d , A ) 0 ) η h , h = 1 , 2 , , H , d ̲ d d ¯ .

The objective function and the reliability constraint conditions can be efficiently evaluated by the SGQ-AOP method proposed in Section 2.

4 Numerical examples

4.1 Finite element model of an air spring

Figure 2 shows the finite element model of an air spring, and the calculation utilizes the Newton–Raphson method. The air spring action is divided into many load-increment steps. Then, an approximate equation is established at the end of each loaded-increment step. The acceptable solution of certain load-increment is reached after many rounds of iterations. This analysis is calculated in the ABAQUS/Explicit module. There are 24183 CAX4R elements and 1512 SFMAX1 elements in the whole FE model. By using ABAQUS, the stiffness of the air spring can be obtained. More details related to the calculation can be found in ref. [1]. The computational time to calculate the stiffness of the FE model is about 972 s. All computational results are obtained on a computer with 3.20 GHz Intel(R) Core (TM) CPU i9-10700K.

Figure 2 The FE model of an air spring.
Figure 2

The FE model of an air spring.

4.2 Response analysis of the air spring with epistemic uncertainties

To investigate the effectiveness of the SGQ-AOP model for response analysis of the air spring with epistemic uncertainties, Yang’s modulus E of the cord, the cross section S of cord, the cord angle θ, and the material parameters of rubber (including C01 and C10 of the Mooney–Rivlin model) are assumed as evidence variables. The BPA structures of E, S, θ, C01, and C10 are listed in Table 1.

Table 1

BPA structures of each uncertain parameter

E (MPa) S (mm2) θ (°) C01 C10
Focal element BPA Focal element BPA Focal element BPA Focal element BPA Focal element BPA
[1700, 1800] 0.1 [5.2, 5.6] 0.1 [28,33] 1 [0.2, 0.8] 1 [0.02, 0.08] 1
[1,800, 1,950] 0.5 [5.6, 6.0] 0.4
[1,950, 2,100] 0.3 [6.0, 6.4] 0.4
[2,100, 2,300] 0.2 [6.4, 6.8] 0.1

The proposed method is used to calculate the mean and variance of stiffness of the air spring. For comparison, the traditional AOP [29] is also introduced to calculate the response of the air spring. The retained order of the SGQ-AOP and the traditional AOP method is 4. The reference solution is obtained through the high-order Legendre polynomial expansion [29]. The results obtained by different methods are shown in Figures 3 and 4.

Figure 3 Bounds of the mean value of vertical stiffness of the air spring.
Figure 3

Bounds of the mean value of vertical stiffness of the air spring.

From Figures 3 and 4, it can be found that the results obtained by the SGQ-The AOP and the traditional AOP are very close to the reference results. It indicates that both SGQ-AOP and the traditional AOP method can achieve high accuracy for response analysis of the air spring with evidence variables. The relative error of the SGQ-AOP method is slightly higher than that of AOP, and the main reason is that a larger number of polynomial bases are retained in AOP. However, increasing the number of polynomial bases will lead to a larger computational burden. The computational times of the SGQ-AOP and AOP methods are 7.65 × 10 5 and 3.21 × 10 6 s . Therefore, compared with the traditional AOP, the proposed SGQ-AOP method can greatly improve computational efficiency.

Figure 4 Bounds of the standard deviation of vertical stiffness of the air spring.
Figure 4

Bounds of the standard deviation of vertical stiffness of the air spring.

4.3 An optimization model for an air spring with epistemic uncertainties

In practice, the cord angle θ and the cross section S of the cord are usually used as design variables to optimize the performance of the air spring system. This is mainly because θ and S have a great effect on the mechanical properties of the air spring. Therefore, θ and S will be used as design variables in this numerical example. The range of θ is 25–35°, while the range of S is 4–6 mm2. The objective of the optimization is the expectation of the strain. A vertical amplitude h = 10 mm is applied on the air spring. The initial pressure of the air spring is 0.6 MPa. The stiffness of the air spring is constrained. In particular, the vertical stiffness of the air spring should satisfy 90 kN mm 1 K v 110 kN mm 1 , while the lateral stiffness of the air spring should satisfy 135 kN mm 1 K v 150 kN mm 1 . Based on the above discussion, the optimization model can be described as

(36) Find θ , S , minimize Exp u θ , S , A max , subject to K ¯ v ( θ , S , A ) 110 ; K ¯ l ( θ , S , A ) 150 , K ̲ v ( θ , S , A ) 90 ; K ̲ l ( θ , S , A ) 135 , 25 θ 35 ; 4 S 6 .

The SGQ-AOP method is used to obtain the result of the optimization model shown in equation (37). The detailed procedure of optimization by using the SGQ-AOP method can be found in Section 3. The initial value of the design variable is θ = 35 and S = 6 mm2. Once the surrogate model is established by using SQ-IRMAPC, different kinds of optimization methods can be used to find the optimal solution, such as the gradient-based methods [34,35] and gradient-free optimization strategies (Genetic Algorithm, GA [36]). Generally, the gradient-based methods can achieve higher efficiency than GA, but are more complicated in the formulation. The surrogate model of the response of air spring is a simple function, thus the computational cost of optimization by using GA is relatively small. For simplicity, GA is employed to find the optimal solution in this paper. The cord angle and the cross section of the cord after optimization are θ = 31.2 and S = 6 mm2, respectively. Before optimization, the maximum strain of the rubber of the air spring is 0.83 MPA, while the maximum strain of the rubber of the air spring is only 0.56 MPa after optimization. Therefore, the maximum strain of the rubber can be effectively reduced by using the optimization method.

In order to compare the optimization results obtained without considering uncertainties, a deterministic optimization model is introduced as follows:

(37) Find θ , S , minimize u θ , S , subject to 90 K v ( θ , S ) 110 ; 135 K l ( θ , S ) 150 , 25 θ 35 ; 4 S 6 .

The SGQ-AOP method is used to construct the surrogate model of the response of air spring. The initial value of the design variable is also set as θ = 35 and S = 6 mm2. The Genetic Algorithm is introduced to the optimization of the air spring system. The cord angel and the cross section of the cord after optimization is θ = 29.5 and S = 6 mm2, respectively.

Assume that E, C01, and C10 are evidence variables; then, the maximum values of the stiffness of the air spring under different optimization results are obtained and listed in Table 2.

Table 2

Optimal results obtained by using different optimization methods

Type Optimal results Maximum of vertical stiffness (kN·mm−1)
Θ S (mm2)
Nondeterministic optimization (proposed) 31.2 6  109
Deterministic optimization (traditional) 29.5 6 114

It can be found in Table 2 that the maximum vertical stiffness is 114 kN·mm−1, which does not satisfy the constraints in equation (37). It indicates that the optimal results obtained without considering uncertainties may fail to satisfy the constraints. For comparison, after optimization by using the proposed method, the constraints are well satisfied. Therefore, the uncertainties should be considered for the optimization design of the air spring with epistemic uncertainties. Without considering these uncertainties, the optimal result obtained by using the deterministic optimization method may be unreliable.

5 Conclusion

In this article, the evidence theory is introduced to deal with the uncertainties in the air spring. To efficiently calculate the response of an air spring system with evidence variables, a new evidence theory-based polynomial chaos method, called the SGQ-AOP method, is proposed. In the SGQ-AOP method, the arbitrary orthogonal polynomial is used to approximate the response of interest, and the expansion coefficient of AOP is calculated by using the sparse grid quadrature. For optimization of the air spring system with uncertainties, a reliability-based optimization model under evidence theory is developed. The SGQ-AOP method is used to construct the surrogate model for the response of the air spring. Based on the surrogate model, the optimal results can be efficiently obtained by using the genetic algorithm. The proposed response analysis and the optimization method have been applied to the optimization design of an air spring with epistemic uncertainties. The main conclusions are the following:

  1. Compared to the traditional evidence theory-based arbitrary orthogonal polynomial method that is based on the Gaussian quadrature, the evidence theory-based arbitrary orthogonal polynomial method by using the sparse grid quadrature can greatly improve the computational efficiency.

  2. By using the reliability-based optimization method, the constraints can be well satisfied after optimization. However, without considering the uncertainties, the optimal results obtained by using the deterministic optimization method may not satisfy the constraints under uncertainties. Therefore, for optimization of the air spring with epistemic uncertainties, it is necessary to consider the uncertainties in the air spring system.

  1. Funding information: This work was supported by the Natural Science Foundation of Hunan Province, China (No. 2020JJ5686). The author would also like to thank the reviewers for their valuable suggestions.

  2. Authors contributions: Feng Kong: writing – original draft preparation,software, data curation. Yu Bai: experimental test, software, data curation. Xifeng Liang: writing – reviewing and editing. Zhaijun Lu: writing – reviewing and editing, formal analysis. Shengwen Yin: methodology, writing – reviewing and editing.

  3. Conflict of interest: Authors state no conflict of interest.

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Received: 2021-08-09
Revised: 2021-10-15
Accepted: 2021-11-07
Published Online: 2022-03-03

© 2022 Feng Kong et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/rams-2022-0008
Keywords for this article
evidence theory; arbitrary orthogonal polynomial; sparse grid quadrature; optimization; air spring
Creative Commons
BY 4.0

Articles in the same Issue

  1. Review Articles
  2. State of the art, challenges, and emerging trends: Geopolymer composite reinforced by dispersed steel fibers
  3. A review on the properties of concrete reinforced with recycled steel fiber from waste tires
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  17. Response analysis and optimization of the air spring with epistemic uncertainties
  18. Molecular dynamics of C–S–H production in graphene oxide environment
  19. Residual stress relief mechanisms of 2219 Al–Cu alloy by thermal stress relief method
  20. Characteristics and microstructures of the GFRP waste powder/GGBS-based geopolymer paste and concrete
  21. Development and performance evaluation of a novel environmentally friendly adsorbent for waste water-based drilling fluids
  22. Determination of shear stresses in the measurement area of a modified wood sample
  23. Influence of ettringite on the crack self-repairing of cement-based materials in a hydraulic environment
  24. Multiple load recognition and fatigue assessment on longitudinal stop of railway freight car
  25. Synthesis and characterization of nano-SiO2@octadecylbisimidazoline quaternary ammonium salt used as acidizing corrosion inhibitor
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  68. An experimental investigation and machine learning-based prediction for seismic performance of steel tubular column filled with recycled aggregate concrete
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  73. Displacement recovery and energy dissipation of crimped NiTi SMA fibers during cyclic pullout tests
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