Model new materials using powerful symbolic and numeric computational abilities, visualize crystal structures interactively, and measure performance by analyzing deformation and failure data with sophisticated statistics—all in one integrated workflow.
Underlying the Mathematica materials science solution is the most automated and reliable computation, development, and deployment environment available.
Designing new materials and processes using powerful computational abilities
Sample models of an anisotropically elastic solid; a diffusion-limited aggregation process; and a folded structure, such as a core for a lightweight panel
Characterizing materials or analyzing performance with original algorithms
Simple, interactive curve-fitting tools that can be easily created and shared
Using built-in connectivity, integration, and interactivity
A notebook instantly converted to an interactive slide show that can be modified during a presentation
Functions for automatically computing probabilities and expectations of any event, for any uni- or multivariate distribution, allowing quick calculations for many problems
Symbolic calculations improve the accuracy and flexibility of structural or performance models Competitor note: Matlab's built-in routines only handle numeric calculations
Calculate the expected stresses and strains a material will feel as it is deformed and analyze deformation data to determine its stiffness and strength
Post-process derived equations to convert them to code that will control machining equipment
![[ja]](/common/images2003/lang_bottom_ja.gif)
![[es]](/common/images2003/lang_bottom_es.gif)
![[zh]](/common/images2003/lang_bottom_zh.gif)