Research Interests（ResearchID，Google scholar）

－Bayesian modeling and computation

－Stochastic computations and uncertainty quantification

－Inverse and ill-posed problems

－Scientific machine learning

Submitted:

3.   L. Yan, T. Zhou, Doubly stochastic Stein Variational Newton method, 2020

2.   C. Qian, L. Yan, Conditional deep surrogate models for Hierarchical Bayesian inverse problems, 2020.

1.   L. Yan, T. Cui, T. Zhou,  Optimization-based sampling for Bayesian inverse problems using surrogate modeling, 2020.

Journal Papers:

32. L. Yan, T. Zhou, Stein variational gradient descent with local approximations,Computer Methods in Applied Mechanics and Engineering,386:114087,2021.

31. L. Yan, X. Zou, Gradient-free Stein variational gradient descent with kernel approximation, Applied Mathematics Letters, 121: 107465, 2021.

30.  L. Yan, T. Zhou, An acceleration strategy for randomize-then-optimize sampling via deep neural networks, to appear in J. Comput. Math., 2021.

29.  A. Narayan, L. Yan, T. Zhou. Optimal design for the kernel interpolation: applications to uncertainty quantification.J.  Comput. Phys., 430:110094,2021.

28.  L. Yan, T. Zhou,An adaptive surrogate modeling based on deep neural networks  for large-scale Bayesian inverse  problems,Commu. Comput. Phys.,28:2180-2205,2020.(A special issue on Machine Learning for Scientific Computing)

27.  F.L. Yang, L. Yan,A non-intrusive reduced basis EKI for time-fractional diffusion inverse problems, Acta Math. Appl.Sinica-English Serier, 36(1):183-202, 2020.(A special issue for IP)

26.  L. Yan, T. Zhou.Adaptive multi-fidelity polynomial chaos approach to Bayesian inference in inverse  problems,J.  Comput. Phys.,2019, 381: 110-128.

25.  L.Yan, T. Zhou. An adaptive multi-fidelity PC-based ensemble Kalman inversion for inverse problems,Int. J.  Uncertainty Quantification, 2019, 9(3):205-220.

24.Y.X. Zhang, J.X. Jian, L. Yan,Bayesian approach to a nonlinear inverse problem for time-space fractional diffusion equation.Inverse Problems, 2018, 34:125002(19pp).

23.   F.L. Yang, L. Yan, L. Ling.Doubly stochastic radial basis function methods.J. Comput. Phys.,2018, 363: 87-97.

22.   L. Guo, A. Narayan,L. Yan, T. Zhou.Weighted approximate Fekete points: sampling for least-squares polynomial approximation,SIAM J.  Sci. Comput., 2018, 40 (1), A366-A387.

21.  L. Yan,Y. X. Zhang.Convergence analysis of surrogate-based methods for Bayesian inverse problems,Inverse Problems,2017, 33:125001(20pp).

20.  L. Guo, Y. Liu, L. Yan,Sparse recovery via lq-minimization for polynomial chaos expansions, Numer.   Math. Theor.  Meth. Appl., 2017,10(4):775-797.

19.   L. Yan, Y. Shin, D. Xiu.Sparse approximation using L1-L2 minimization and its application to stochastic collocation.SIAM J.  Sci. Comput., 2017, 39 (1): A229–A254.

18.   Y.X.Zhang, L. Yan.The general a posteriori truncation method and its application to radiogenic source identification for the Helium production-diffusion equation, Appl. Math. Model.,2017, 43 :126-138.

17.   J.J. Liu, M. Yamamoto, L. Yan.On the reconstruction of unknown boundary sources for time fractional diffusion process by nonlocal measurement.Inverse Problems, 2016,32(1): 015009.

16.  L. Yan, L. Guo.Stochastic collocation algorithms using l1-minimization for Bayesian solution of inverse problems. SIAM J.  Sci. Comput., 2015,37(3), A1410–A1435.

15.   L. Yan, F. L. Yang. The method of approximate particular solutions for the time-fractional diffusion equation with a non-local boundary condition.Comput.  Math. Appl.,2015,70:254-264.

14.   J.J.Liu, M. Yamamoto, L. Yan.On the uniqueness and reconstruction for an inverse problem of the fractional diffusion process.Appl. Numer.  Math., 2015, 87:1-19.

13.   L. Yan, F.L Yang.Efficient Kansa-type MFS algorithm for time-fractional inverse diffusion problems.Comput.  Math. Appl.,2014, 67:1507-1520.

12.  L. Yan, F.L. Yang. A Kansa-type MFS scheme for two-dimensional time fractional diffusion equations. Eng. Anal. Bound.  Eleme.,2013, 37 (11): 1426–1435.

11.   H. F. Zhao, L. Yan, J. J. Liu. On the interface identification of free boundary problem by method of fundamental solution. Numer.  Linear Algebra  Appl., 2013, 20(2)：385-396.

10.   L. Yan, L. Guo, D.Xiu.Stochastic collocation algorithms using L1-minimization.Int. J. Uncertainty Quantification,  2012, 2(3): 279–293.

9.    L. Yan, F. L. Yang, C. L. Fu. A new numerical method for the inverse source problems from a Bayesian statistical perspective.Int. J. Numer. Meth. Eng., 2011, 85:1460-1474 

8.     Y.X. Zhang, C. L. Fu, L. Yan.Approximate inverse method for stable analytic continuation in a strip domain. J.  Comput. Appl.  Math., 2011, 235: 1979-1992 

7.    L. Yan, C. L. Fu, F. F. Dou. A computational method for identifying a spacewise-dependent heat source.Int.  J. Numer.  Meth. Biomedical Eng., 2010,26: 597-608

6.    L. Yan,F. L.Yang, C.L.Fu. A meshless method for solving an inverse spacewise-dependent heat source problem.J. Comput.  Phys., 2009, 228(1):123-136

5.     F. L. Yang,L. Yan, T. Wei. The identification of a Robin coefficient by a conjugate gradient method. Int. J.  Numer. Meth. Eng.,2009,78:800-816

4.     L. Yan, F. L. Yang, C. L. Fu. A Bayesian inference approach to identify a Robin coefficient in one-dimensional parabolic problems. J.  Comput. Appl.  Math., 2009, 231(2):840-850

3.     F. L. Yang, L. Yan, T. Wei. Reconstruction of part of a boundary for the Laplace equation by using a regularized method of fundamental solution. Inverse Problems  Sci. Eng.,2009,17(8):1113-1128.

2.     F. L. Yang,L. Yan, T. Wei. Reconstruction of the corrosion boundary for the Laplace equation by using a boundary collocation method. Math. Comput.  Simu., 2009,79(7):2148-2156 

1.     L. Yan, C. L. Fu, F. L. Yang. The method of fundamental solutions for the inverse heat source problem.Eng. Anal. Bound. Elem., 2008, 32(3) :216-222.