https://orcid.org/0000-0001-9851-5771
References
- Bush MB. The interaction between a crack and a particle cluster. Int J Frac. 1997;88:215–232.
- Huang J, Rapoff AJ, Haftka RT. Attracting cracks for arrestment in bonelike composites. Mater Design. 2006;27:461–469.
- Mantic V. Interfacial crack onset at a circular cylindrical inclusion under a remote transverse tension, application of a coupled stress and energy criterion. Int J Solids Struct. 2009;46:1287–1304.
- Barsoum RS. On the use of isoparametric finite elements in linear fracture mechanics. Int J Num Methods Eng. 1976;10:25–37.
- Atluri SN. Computational Methods in Mechanics of Fracture, Vol 2. Amsterdam: North-Holland; 1986.
- Daux C, Moes N, Dolbow J, et al. Arbitrary branched and intersecting cracks with the extended finite element method. Int J Num Methods Eng. 2000;48:1741–1760.
- Cruse TA. BIE fracture mechanics analysis: 25 years of developments. Comp Mech. 1996;18:1–11.
- Aliabadi MH, Rooke DP. Numerical fracture mechanics (Solid mechanics and its applications; Vol 8). Dordrecht: Kluwer Academic Pub; 1991.
- Silveira NPP, Guimaraes S, Telles JCF. A numerical green’s function BEM formulation for crack growth initiation. Eng Anal Bound Elem. 2005;29:978–985.
- Mews H, Kuhn G. An effective numerical stress intensity factor calculation with no crack discretization. Int J Frac. 1988;38:61–76.
- Ma J, Chen W, Zhang C, et al. Meshless simulation of anti-plane crack problems by the method of fundamental solutions using the crack Green’s function. Comput Math Appl. 2020;79:1543–1560.
- Lin J, Feng W, Reutskiy S, et al. A new semi-analytical method for solving a class of time fractional partial differential equations with variable coefficients. Appl Math Lett. 2021;112(106712.
- Kitey R, Phan A-V, Tippur HV, et al. Modeling of crack growth through particulate clusters in brittle matrix by symmetric-Galerkin boundary element method. Int J Frac. 2006;141:11–25.
- Wang J, Crouch SL, Mogilevskaya SG. A fast and accurate algorithm for a Galerkin boundary integral method. Comput Mech. 2005;37:96–109.
- Han X, Wang T. Elastic fields of interacting elliptic inhomogeneities. Int J Solids Struct. 1999;36:4523–4541.
- Tamate O. The effect of a circular inclusion on the stresses around a line crack in a sheet under tension. Int J Frac Mech. 1968;4:257–266.
- Atkinson C. The interaction between and crack and an inclusion. Int J Eng Sci. 1972;10:127–136.
- Erdogan F, Gupta GD, Ratwani M. Interaction between a circular inclusion and an arbitrarily oriented crack. ASME J Appl Mech. 1974; Dec: 1007-1013.
- Patton EM, Santare MH. Crack path prediction near an elliptic inclusion. Eng Frac Mech. 1993;44:195–205.
- Arai M. Application of distributed dislocation method to curved crack moving near a press-fitted inclusion in a two-dimensional infinite plate. Eng Frac Mech. 2019;218:106609.
- Wang R. A new method for calculating the stress intensity factors of a crack with a circular inclusion. Acta Mech. 1995;108:77–85.
- Li Z, Chen Q. Crack-inclusion interaction for mode I crack analyzed by Eshelby equivalent inclusion method. Int J Frac. 2002;118:29–40.
- Shodja HM, Rad IZ, Soheilifard R. Interacting cracks and ellipsoidal inhomogeneities by the equivalent inclusion method. J Mech Phy Solids. 2003;51:945–960.
- Moschovidis ZA, Mura T. Two-ellipsoidal inhomogeneities by the equivalent inclusion method. ASME J Appl Mech. 1975;42:847–852.
- Eshelby JD. Ealstic Inclusions and Inhomogeneities. In: Sneddon IN, Hill R, editors. Progresses in Solid Mechanics Vol II. Amsterdam: North-Holland Pub; 1961. p. 89–140.
- Eshelby JD. The determination of the elastic field of an ellipsoidal inclusion and related problems. R Soc Lond A. 1957;214:376–396.
- Mura T. Micromechanics of defects in solids. 2nd ed. Dordrecht: Martinus Nijhoff Pub; 1987.
- Lubarda VA, Markenscoff X. On absence of esehlby property for non-ellipsoidal inclusions. Int J Solids Struct. 1998;35:3405–3411.
- Asaro RJ, Barnett DM. The non-uniform transformation strain problem for an anisotropic ellipsoidal inclusion. J Mech Phys Solids. 1975;23:77–83.
- Jun T-S, Korsunsky AM. Evaluation of residual stresses and strains using eigenstrain reconstruction method. Int J Solids Struct. 2010;47:1678–1686.
- Chen YZ. Solution for Eshelby’s elliptic inclusion with polynomials distribution of the eigenstrains in plane elasticity. Appl Math Model. 2014;38:4872–4884.
- Lee Y-G, Zuo W-N, Pan E. Eshelby’s problem of polygonal inclusions with polynomial eigenstrains in an anisotropic megneto-electro-elastic full plane. Proc R Soc A. 2015;471:1–20.
- Rahman M. The isotropic ellipsoidal inclusion with polynomial distribution of eigenstrains. ASME J Appl Mech. 2002;69:593–601.
- Kabaanikhin SI. Definitions and examples of inverse and ill-posed problems. J Inv Ill-Posed Probl. 2008;16:317–357.
- Bonnet M, Constantinescu A. Inverse problems in elasticity. Inverse Prob. 2005;21:R1–R50.
- Cao YP, Hu N, Lu J, et al. An inverse approach for constructing the residual stress field induced by wielding. J Strain Anal Eng Des. 2002;37:345–359.
- Hill MR. Determination of residual stress based on the estimation of eigenstrain [PhD thesis]. Stanford: Stanford University; 1996.
- Korsunsky AM, Regino GM, Nowell D. Variational eigenstrain analysis of residual stresses in a welded plate. Int J Solids and Str. 2007;44:4574–4591.
- Agrawal A. Eigenstrain reconstruction from contaminated data using inverse-EIM. 4th Int Conf Struct Integrity, Madeira; Aug-Sept 2021.
- Bilby BA, Eshelby JD. Dislocations and the theory of fracture. In; Liebowitz S, editor. Fracture, microscopic and macroscopic fundamentals. Vol. 1, Academic Press; 1969. p. 99–182.
- Hills DA, Kelly PA, Dai DN, Korsunsky AM. Solution of crack problem: the distributed dislocation technique. In Gladwell GML, editor, Solid mechanics and its applications. Dordrecht: Springer; 1996.
- Krenk S. On the Use of the interpolation polynomials for solutions of singular integral equations. Quant Appl Math. 1975;32:479–484.
- Mausavi MS, Lazar M. Distributed dislocation technique for cracks based on non-singular dislocations in nonlocal elasticity of Helmholtz type. Eng Fract Mech. 2015;136:79–95.
- Jin X, Lyu D, Zhang X, et al. Explicit analytical solutions for a complete set of Eshelby tensors of an ellipsoidal inclusion. ASME J Appl Mech. 2016;83:1–12.
- Song G, Wang L, Deng L, et al. Mechanical characterization and inclusion based boundary element modeling of lightweight concrete containing foam particles. Mech Mater. 2015;91:208–225.
- Agrawal A, Venkitanarayanan P. Polynomial selection for induced eigenstrain inside a stiff inclusion interacting strongly with a mode I crack. MCM Conference; Sept 2017; Petersburg, Russia.
- Gladwell GML. Contact problems in the classical theory of elasticity. Sijthoff Noordhoff. 1980.
- Jen E, Srivastava RP. Solving singular integral equations using Gaussian quadrature and over-determined systems. Comput Math Appl. 1983;9:625–632.
- Mushkhelishvili NI. Some basic problems of the mathematical theory of elasticity. Springer-Science; 1953.
- Chen YZ. Integral equations methods for multiple crack problems and related topics. ASME J Appl Mech. 2007;60:172–194.
- Newman JC. An improved method of collocation for stress analysis of cracked plates with various shaped boundaries. NASATN D-6376. 1971; NASA.
- Wang YH. Stress intensity factor for a crack in a tube by boundary collocation method. Int J Press Vessels Pip. 1989;38:167–176.
- MATLAB. Mathworks Inc, Natick, Massachusetts, 2014.
- Lin J, Zhang Y, Reutskiy S, et al. A novel meshless space-time backward substitution method and its application to nonhomogeneous advection-diffusion problems. Appl Math Comput. 2021;398:125964.
- Rooke DP, Cartwright DJ. 1975. Compendium of stress intensity factors. London: Her Majesty’s Stationary Office.