Uncertainty is ubiquitous in engineering systems due to inherent variability, limited knowledge, and modeling errors . To quantify stochastic structural safety under uncertainty, probability-based structural reliability commonly measures safety in terms of failure probability. The first-order reliability method (FORM) is widely adopted because it estimates small failure probabilities efficiently by linearizing the limit state function at the design point in a transformed standard normal space . When the limit state function is strongly nonlinear, the first-order approximation may lose accuracy, and higher-order approaches such as second- and even third-order reliability methods (SORM and TORM) can be used to improve accuracy at increased computational cost . Beyond these design-point-based approximations, methods for reliability analysis include cross-entropy-based adaptive importance sampling , Kriging-based active learning , sparse polynomial chaos expansions , and entropy-based measures . These developments are predominantly formulated for time-invariant reliability evaluation at fixed time instants. However, in time-dependent reliability problems, temporal dependence introduces strong correlation across the service period and increases the effective problem dimension. To address this challenge, numerous methods for time-dependent reliability analysis have been developed. These methods are commonly grouped into three classes: outcrossing-rate methods, sampling-based methods, and equivalent methods.

Outcrossing-rate methods, which are derived from the Rice formula , are widely used. However, their accuracy may deteriorate when multiple dependent upcrossings occur within the considered period. Among the outcrossing methods, a widely used refinement is the PHI2 method developed by and . By introducing bivariate correlation corrections for upcrossing events, PHI2 preserves the low computational cost of outcrossing-rate methods and typically reduces approximation error relative to classical formulations.

Sampling-based methods are conceptually straightforward. However, crude Monte Carlo simulation (MCS) requires very large sample sizes to accurately estimate small failure probabilities, especially with expensive limit state evaluations . As a result, the computational cost can be prohibitive. To alleviate this burden, mitigation strategies include an adaptive importance sampling approach , a first-order sampling approach , random field discretization , and a surrogate model approach . Within random field discretization, series expansion methods including the Karhunen–Loève (KL) expansion , expansion optimal linear estimation (EOLE) , and orthogonal series expansion (OSE) provide effective low-dimensional approximations. A comparative assessment of their accuracy and efficiency is provided by .

Equivalent methods are a key class in time-dependent reliability analysis. The main idea is to transform time-dependent problems into static ones. Equivalent methods include extreme-value methods and envelope function methods . In practice, efficient global optimization (EGO) and mixed EGO are often employed as search strategies to locate critical time instants on surrogate models and thereby predict time-dependent reliability . Envelope function methods estimate the time-dependent reliability by constructing response envelopes, which avoids per-instant analyses . Compared with outcrossing-rate methods, equivalent methods typically achieve higher accuracy when the response exhibits strongly correlated or multiple crossings while remaining far more efficient than direct sampling in many practical settings.

The equivalent-plane approach (EPA) was initially developed to assess the reliability of series and parallel systems . proposed a sequential compounding method and derived analytical expressions for combining series and parallel systems. Gong et al. transformed variables in the standard normal space into a high-dimensional space with the correlation of stochastic processes and obtained the time-dependent reliability by combining the reliability at each time instant.

This work develops a time-dependent reliability method that couples series expansion with the equivalent-plane approach. In Sect. , the problem formulation and notation for time-dependent reliability are reviewed. In Sect. , the reliability at each time instant is evaluated by FORM, EOLE provides a correlated representation of the stochastic process in the standard normal space, and EPA is then used to estimate the time-dependent failure probability. Numerical examples and the conclusions are presented in Sects.  and , respectively.

In the limit state function G(t,X,Y(t)), t denotes time, X=[X1,…,Xq] are time-invariant random variables, and Y(t) is the stochastic process. Failure occurs when G(⋅)≤0. The reliability of a structure with the limit state function is considered within the period of ts,te.

At a time instant ti∈ts,te, the failure event can be expressed as 1Ei=Gti,X,Y(ti)≤0, and the corresponding failure probability is 2pfti=Pr⁡Ei=Pr⁡Gti,X,Y(ti)≤0.

Over the period ts,te, the failure event is 3E=∃t∈ts,te:Gt,X,Y(t)≤0.

The failure probability over ts,te is 4pfts,te=Pr⁡E=Pr⁡∃t∈ts,te:Gt,X,Y(t)≤0.

When the stochastic process changes slowly or when resistance decays monotonically relative to the load, the failure probability over ts,te can be approximately expressed by pfte. However, when material properties or external loads of a structure are time-dependent, the structural reliability over the period requires a time-dependent reliability method.

At a discretized time instant ti, the limit state function is written as Gti,X,Y(ti). For reliability evaluation at the fixed time instant ti, the process value Y(ti) is treated as an equivalent random variable so that the problem involves (q+1) random variables (X,Y(ti)). By applying the Nataf transformation to (X,Y(ti)), an independent standard normal vector Vi=[V1(i),…,Vq+1(i)]⊤∈Rq+1 is obtained, and the transformed limit state function is denoted by GV(ti,Vi). The reliability at ti is quantified by the FORM reliability index 5βi=min⁡v∈Rq+1‖v‖:GV(ti,v)=0. The minimizer of Eq. (), denoted by Vi∗, is the most probable point (MPP) at ti, such that βi=‖Vi∗‖.

To account for the dependence of the stochastic process across different time instants, the stochastic process Y(t) can be approximately represented as an infinite linear combination of orthogonal functions . In this paper, Y(t) is approximated using EOLE, a truncated series expansion. Let m(t) and σ(t) denote the mean and standard deviation of Y(t). Select n time instants t1,…,tn in [ts,te], and define the correlation matrix C∈Rn×n with entries Cjk=ρY(tj,tk). Let ρY(t)=[ρY(t,t1),…,ρY(t,tn)]⊤. The truncated series expansion reads as 6Y(t)≈Y^(t)=m(t)+σ(t)∑k=1Mξkλkϕk⊤ρY(t), where ξk∼N(0,1) denotes independent standard normal variables, {(λk,ϕk)}k=1M denotes the M largest eigenvalues and the corresponding eigenvectors of C, and M is the truncation order. With n time instants fixed, the process Y(t) is parameterized by ξ=[ξ1,…,ξM]⊤.

In this work, the truncation order M is selected such that the maximum pointwise approximation error over [ts,te] does not exceed 1 %. The pointwise error is estimated by 7ε(t)=1-∑k=1Mϕk⊤ρY(t)2λk.

Based on Eq. (), we define the standardized process as 8η(t)=Y^(t)-m(t)σ(t)=∑k=1Mξkbk(t),bk(t)=ϕk⊤ρY(t)λk. At ti, η(ti)=b(ti)⊤ξ, with b(ti)=[b1(ti),…,bM(ti)]⊤. Here, the last component Vq+1(i) corresponds to the standardized process value at ti. Accordingly, the process-related standard normal variable in the above FORM analysis is linked to the EOLE variables by 9Vq+1(i)≈η(ti)=b(ti)⊤ξ.

With the EOLE relations in Eqs. ()–(), the process component at ti is represented in terms of the common EOLE variables ξ. Consequently, its contribution can be mapped onto the ξ subspace along b(ti) when constructing the (q+M)-dimensional direction vector. Therefore, the uncertainty at different time instants can be described in a unified (q+M)-dimensional independent standard normal space. Let U∼N(0,Iq+M) denote the corresponding standard normal vector. The equivalent design point associated with the FORM result at ti is defined as 10Ui∗=V1(i)∗,…,Vq(i)∗,Vq+1(i)∗b(ti)⊤⊤∈Rq+M, and the corresponding unit direction vector is defined as 11αi=Ui∗‖Ui∗‖∈Rq+M.

For notational convenience, define β=[β1,…,βn]⊤ and A=[α1,…,αn]∈R(q+M)×n. The first-order linearization of the limit state at ti is 12Zi=βi-αi⊤U,i=1,…,n, such that failure at ti corresponds to {Zi≤0}.

According to first-order reliability theory, the failure probability at ti is 13pf(ti)=1-Φ(βi), where Φ(⋅) denotes the standard normal cumulative distribution function.

For any two time instants ti and tj, the correlation coefficient between the linearized limit state function Zi and Zj is 14ρij=αi⊤αj.

From the definitions above, the correlation matrix of Z={Zi}i=1n is R: 15R=A⊤A.

Equation () implies that the diagonal entries equal 1 and that the off-diagonal entries coincide with the pairwise correlations. In particular, (R)ij=ρij for i,j=1,…,n.

The time-dependent failure over ts,te can be modeled as a series system across the discretized time instants. Accordingly, the linearized responses at the time instants form the components of a multivariate normal distribution. The system failure probability is then given by 16pfts,te=Pr⁡⋃i=1n{Zi≤0}=1-∫-∞βφn(w;R)dw, where φn(⋅;R) denotes the probability density function of the zero-mean multivariate normal distribution with correlation matrix R∈Rn×n, and the integration is with respect to w.

Multidimensional integrals in Eq. () suffer from the “curse of dimensionality” when the dimensionality increases. Some approximate methods, such as the Monte Carlo and quasi-Monte-Carlo methods, also have difficulty obtaining an acceptable accuracy in low-failure-probability problems. Thus, the EPA is adopted as an effective approximation of multidimensional integrals and is effective for series and parallel systems. As mentioned above, the time-dependent reliability problem is converted into a sequence of static reliability problems. The n linearized limit state responses Z={Zi}i=1n represent the failure events Ei={Zi≤0} at the n time instants. Selecting two instants ti and tj, the joint failure probability is 17pf,ij=Pr⁡Ei∪Ej=1-Φ2βi,βj;ρij, where Φ2(⋅,⋅;ρ) denotes the binormal cumulative distribution function with mean zero, unit variances, and correlation ρij.

The equivalent reliability index of the joint failure event Ei∪Ej is 18βij=-Φ-1pf,ij.

Then, the equivalent limit state function for the union event Ei∪Ej is defined as 19Zij=βij-αij⊤U, where αij∈Rq+M is the unit vector in the direction of ∇Uβij and is defined by 20αij=∂βij∂U/∂βij∂U.

The contribution of the kth component Uk of U (k=1,…,q+M) to βij is 21∂βij∂Uk=∂βij∂pf,ij∂pf,ij∂βi∂βi∂Uk+∂βij∂pf,ij∂pf,ij∂βj∂βj∂Uk.

Each factor in the first term on the right side of Eq. () reads as 22∂βij∂pf,ij=-∂Φ-1pf,ij∂pf,ij=-1φβij∂pf,ij∂βi=-φ(βi)Φβj-ρijβi1-ρij2∂βi∂Uk=αk(i).

The second term in Eq. () is obtained analogously from Eq. () by exchanging i and j.

Failure events are combined pairwise in sequence until the n failure events E1,…,En with Ei={Zi≤0} are reduced to a single equivalent limit state Zend, as shown in Fig. , with the associated failure event Eend={Zend≤0}. The time-dependent failure probability over [ts,te] is approximated by 23pf(ts,te)≈Pr⁡(Eend)=1-Φ(βend).

Since each compounding step introduces an approximation, the final time-dependent failure probability may depend on the compounding order, and the approximation error can accumulate through subsequent steps . To reduce this order sensitivity, we repeatedly select the remaining pair with the largest correlation ρij, compound the selected pair into a new equivalent event, update the correlations involving the new event, and continue until the final equivalent event Eend is obtained.

A new time-dependent reliability analysis method is presented in this work. This method employs FORM, EOLE, and EPA. FORM is used to analyze the reliability at each time instant. EOLE is used to represent the stochastic process by series expansion and to construct its correlated representation in the standard normal space, which supports the subsequent system aggregation over discretized time instants. EPA is employed to estimate the time-dependent failure probability of the series system over the considered period. Three numerical examples demonstrate the efficiency and accuracy of the proposed method. The results of the proposed method achieve close agreement with MCS benchmarks while requiring orders-of-magnitude fewer limit state evaluations. Compared with the PHI2 method, the proposed approach provides consistently improved accuracy in the studied examples.

Nevertheless, we also noted some limitations of the proposed method during this study. EPA inevitably introduces approximation errors when progressively compounding multiple failure events. When the stochastic process has a short correlation length and the response exhibits high-frequency fluctuations, a smaller time step is required to maintain adequate temporal resolution, which increases the number of compounding levels and may aggravate error accumulation and the sensitivity to the compounding order. For non-Gaussian stochastic processes, the dependence among time instants cannot be fully characterized by a correlation coefficient alone, and Gaussian approximations may lead to noticeable bias in tail probability estimates. Moreover, when the limit state function is strongly nonlinear, the first order linearization error of FORM may become non-negligible and can be further amplified through multi-aggregation. Future work will focus on mitigating these issues and improving the robustness of the method.