Page 290 - Mechanics of Asphalt Microstructure and Micromechanics

P. 290

282 Ch a p t e r E i gh t

Marques, J.M.M.C. and Owen, D.R. (1983). Strain hardening representation for implicit quasi-
static elasto-viscoplastic algorithms. Computers and Structures, Vol.17, pp.301–304.
Miller, A.K. (1976). An inelastic constitutive model for monotonic, cyclic and creep deformation.
Journal of Engineering Materials, Vol.98, pp.97–113.

Moës, N., Dolbow, J. and Belytschko, T. (1999). A ﬁnite element method for crack growth
without remeshing. International Journal for Numerical Methods in Engineering, Vol.46, No.1,
pp.131–150.
Mohammadi, S. (2008). Extended Finite Element Method: for Fracture Analysis of Structures.
Blackwell Publishing, Oxford.
Ortiz, M. and Popov, E.P. (1985). Accuracy and stability of integration algorithms for elastoplas-
tic constitutive relations. International Journal for Numerical Methods in Engineering, Vol.21,
pp.1561–1567.
Ottosen, N.S. and Gunneskov, O. (1985). Nonlinear subincremental method for determination
of elastic-plastic creep behavior. International Journal for Numerical Methods in Engineering,
Vol.21, pp.2237–2256.
Pande, G.N. and Shama, K.G. (1979). On joint/interface elements and associated problems of
numerical ill-conditioning. International Journal for Numerical and Analytical Methods in Geo-
mechanics, Vol.3, pp.293–300.
Paris, F. and Canas, J. (1997). Boundary Element Method. Oxford University Press, Oxford.
Peirce, A.P. and Napier, J.A.L. (1995). A spectral multipole method for efﬁcient solution of large-

scale boundary element models in elastostatics. International Journal for Numerical Methods in
Engineering, Vol.38, No.23, pp.4009–4034.
Sangpetngam, B. (2003). Development and Evaluation of a Viscoelastic Boundary Element
Method to Predict Asphalt Pavement Cracking. Ph.D. Thesis, University of Florida.
Sangpetngam, B., Birgisson, B. and Roque, R. (2003).Development of an efﬁcient crack growth

simulator based on hot mix asphalt fracture mechanics. Transportation Research Record,
No.1832, pp.105–112.
Sangpetngam, B., Birgisson, B. and Roque, R. (2004). Multilayer boundary-element method for
evaluating top-down cracking in hot-mix asphalt pavements. Transportation Research Record,
No.1896, pp.129–137.
Scarpas, T. (2004). A Mechanics based Computational Platform for Pavement Engineering. Delft
University of Technology, The Netherland.
Sharma, K.G. and Desai, C.S. (1992). Analysis and implementation of thin-layer element for
interfaces and joints. Journal of Engineering Mechanics, Vol.118, pp.2442–2462.
Shin, C.F., Delorenzi, H.G. and Miller, A.K. (1977). A stable computational scheme for stiff time
dependent constitutive equations. Proceedings of the 4 International Conference on Structural
th
Mechanics in Reactor Technology, paper L2/2.
SHRP-A-415 (1994). Permanent deformation response of asphalt aggregate mixes. Strategic High-
way Research Program, National Research Council, Washington, D.C.
Simo, J.C. and Taylor, R.L. (1985). Consistent tangent operators for rate-independent elastoplas-
ticity. Computer Methods in Applied Mechanics and Engineering, Vol.48, pp.101–118.
Simo, J.C. and Hughes, T.J.R. (1998). Computational Inelasticity (Interdisciplinary Applied Math-
ematics), Vol.7, Springer, New York.
Snyder, M.D. and Bathe, K.J. (1981). A solution procedure for thermo-elastic and creep problems.
Nuclear Engineering Design, Vol.64, pp.49–80.
Steen, B.V.D., Vervoort, A. and Napier, J.A.L. (2001). Numerical modeling of fracture initiation
and propagation in biaxial tests on rock samples. International Journal of Fracture, Vol.108,
pp.165–191.

285 286 287 288 289 290 291 292 293 294 295