ABAQUS
The Abaqus Unified FEA product suite offers powerful and complete solutions for both routine and sophisticated engineering problems covering a vast spectrum of industrial applications. In the automotive industry engineering work groups are able to consider full vehicle loads, dynamic vibration, multibody systems, impact/crash, nonlinear static, thermal coupling, and acoustic-structural coupling using a common model data structure and integrated solver technology. Best-in-class companies are taking advantage of Abaqus Unified FEA to consolidate their processes and tools, reduce costs and inefficiencies, and gain a competitive advantage.
Keywords for this software
References in zbMATH (referenced in 1424 articles , 3 standard articles )
Showing results 1 to 20 of 1424.
Sorted by year (citations)
- Adamiec-Wójcik, Iwona; Brzozowska, Lucyna; Wojciech, Stanisław: Effectiveness of the segment method in absolute and joint coordinates when modelling risers (2020)
- Boulbes, Raphael Jean: Troubleshooting finite-element modeling with Abaqus. With application in structural engineering analysis (2020)
- Cazacu, Oana; Chandola, Nitin; Revil-Baudard, Benoit; Frodal, Bjørn Håkon; Børvik, Tore; Hopperstad, Odd Sture: Modeling the effect of notch geometry on the deformation of a strongly anisotropic aluminum alloy (2020)
- Cheng, Jiahao; Tu, Xiaohui; Ghosh, Somnath: Wavelet-enriched adaptive hierarchical FE model for coupled crystal plasticity-phase field modeling of crack propagation in polycrystalline microstructures (2020)
- Chen, S.; Osovski, S.: Damage evolution around shear loaded intervoid ligaments in plane strain and plane stress (2020)
- Costas, Miguel; Morin, David; de Lucio, Mario; Langseth, Magnus: Testing and simulation of additively manufactured AlSi10Mg components under quasi-static loading (2020)
- Cui, X.; Han, X.; Duan, S. Y.; Liu, G. R.: An ABAQUS implementation of the cell-based smoothed finite element method (CS-FEM) (2020)
- Deng, Hao; Cheng, Lin; Liang, Xuan; Hayduke, Devlin; To, Albert C.: Topology optimization for energy dissipation design of lattice structures through snap-through behavior (2020)
- dos Santos, T.; Brezolin, A.; Rossi, R.; Rodríguez-Martínez, J. A.: Modeling dynamic spherical cavity expansion in elasto-viscoplastic media (2020)
- Go, Myeong-Seok; Lim, Jae Hyuk; Kim, Jin-Gyun; Hwang, Ki-Ryoung: A family of Craig-Bampton methods considering residual mode compensation (2020)
- Grytz, Rafael; Krishnan, Kapil; Whitley, Ryan; Libertiaux, Vincent; Sigal, Ian A.; Girkin, Christopher A.; Downs, J. Crawford: A mesh-free approach to incorporate complex anisotropic and heterogeneous material properties into eye-specific finite element models (2020)
- Jabareen, Mahmood; Pestes, Yehonatan: The Cosserat point element as an accurate and robust finite element formulation for implicit dynamic simulations (2020)
- Jafaripour, Mostafa; Taheri-Behrooz, Fathollah: Creep behavior modeling of polymeric composites using Schapery model based on micro-macromechanical approaches (2020)
- Jalili, M.; Soltani, B.: Investigation the micromechanisms of strain localization formation in AZ31 Mg alloy: a mesoscale 3D full-field crystal plasticity computational homogenization study (2020)
- Jiménez Rios, Alejandro; O’Dwyer, Dermot: Numerical modeling of cob’s nonlinear monotonic structural behavior (2020)
- Kapitaniak, Marcin; Vaziri, Vahid; Wiercigroch, Marian: Bifurcation scenarios in helical buckling of slender rods using new FE (2020)
- Kildashti, Kamyar; Dong, Kejun; Samali, Bijan: An accurate geometric contact force model for super-quadric particles (2020)
- Klinkel, Sven; Chasapi, Margarita: Isogeometric analysis of solids in boundary representation (2020)
- Kumbhar, Pramod Y.; Francis, A.; Swaminathan, N.; Annabattula, R. K.; Natarajan, S.: Development of user element routine (UEL) for cell-based smoothed finite element method (CSFEM) in Abaqus (2020)
- Liu, Z. Q.; Chen, Z. Y.: Seismic control strategy of a multi-story subway station based on probability density evolution method (2020)