Professor! Today's topic is about contact analysis in Code_Aster, right? What is it?

It involves defining frictionless and Coulomb frictional contact using DEFI_CONTACT. It supports the discrete method (NODE_TO_SEGMENT) and the continuous method (MORTAR). The LAC method enables efficient solving of large-scale contact problems.

Next is 'Licensing and Terms of Use'! What does this cover?

Different open-source licenses (e.g., GPL, LGPL, Apache, BSD) impose varying obligations for publishing modified code and restrictions on commercial use. It is recommended to review the license terms before using it in a project and consult with your company's legal department beforehand. Also consider the handling of derivative works and the possibility of dual licensing.

Could you explain the concept behind this equation?

The displacement field $\mathbf{u}$ that makes the functional $\Pi$ stationary is the equilibrium solution. CalculiX and Code_Aster implement the Galerkin method based on this variational principle.

Um... what physical phenomenon does each term represent?

Applying this integral form to each control volume and numerically evaluating the flux across the surfaces yields the discrete equations.

Code_Aster接触解析

Category: 解析 | Integrated 2026-04-06

CAE visualization for code aster contact theory - technical simulation diagram

Code_Aster接触解析

Theory and Physics

(Theory and Physics Section)

Numerical Methods and Implementation

Details of Numerical Methods

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Specifically, what algorithm is used to solve the Code_Aster contact analysis?

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Let me explain the key points of the numerical methods and implementation for Code_Aster contact analysis.

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I see. So, if I understand the numerical methods for contact analysis, I'm basically good to go?

Compilation and Build

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I've heard of "compilation and build," but I might not fully understand it...

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Building from source code uses CMake or dedicated build systems (like wmake for OpenFOAM). Proper version management of dependency libraries (MPI, PETSc, BLAS/LAPACK, etc.) is crucial. A Linux environment is recommended, but it's also possible to set up on Windows using WSL2 or Docker containers.

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So, cutting corners during the build from source part will come back to bite me later. I'll keep that in mind!

Input File Structure

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Are there any points to watch out for when transferring data between different software?

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Understanding the case file structure and key parameter settings is the first step in implementation. The format of dictionary files (dict) or command files is specific to each software, and editing from official tutorial templates is efficient.

Script Automation

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I've heard of "script automation," but I might not fully understand it...

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Automating parameter studies with Python or Bash scripts is key to improving productivity. Also consider utilizing wrapper tools like PyFoam or cfMesh.

Debugging and Development Environment

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Memory leak detection and debugging with GDB, Valgrind, and AddressSanitizer are effective. Utilize the remote debugging features of IDEs (VSCode, CLion) to set up an efficient development environment. Introduce unit testing frameworks (Google Test, pytest) to automate regression tests.

Solver Settings and Algorithms

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I'd like to know a bit more about what's happening behind the scenes of the calculation!

OpenFOAM Solver Selection Guidelines

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What exactly do you mean by solver selection guidelines?

Solver	Application	Equation System
simpleFoam	Steady incompressible turbulence	SIMPLE
pimpleFoam	Unsteady incompressible	PIMPLE (PISO+SIMPLE)
interFoam	Two-phase flow (VOF)	MULES
rhoSimpleFoam	Steady compressible	SIMPLE
buoyantSimpleFoam	Natural convection	SIMPLE+Boussinesq
reactingFoam	Combustion	PIMPLE+Chemical reaction

CalculiX Input File Structure

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What exactly do you mean by input file structure?

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```

*NODE

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1, 0.0, 0.0, 0.0

...

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*ELEMENT, TYPE=C3D8

1, 1, 2, 3, 4, 5, 6, 7, 8

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...

*MATERIAL, NAME=STEEL

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*ELASTIC

210000., 0.3

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*DENSITY

7.85e-9

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*STEP

*STATIC

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*BOUNDARY

1, 1, 3

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*CLOAD

100, 2, 1000.

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*END STEP

```

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Ah, I see! So that's how the solver selection guidelines work.

Code_Aster Command File Structure

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Next is the topic of command file structure. What's it about?

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```

DEBUT()

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MAIL = LIRE_MAILLAGE()

MODELE = AFFE_MODELE(MAILLAGE=MAIL, ...)

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RESULT = MECA_STATIQUE(MODELE=MODELE, ...)

FIN()

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```

Discretization Scheme Selection

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Please tell me about "Discretization Scheme Selection"!

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OpenFOAM's discretization schemes are set in the fvSchemes file. The discretization of the convection term greatly influences accuracy and stability:

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After hearing this, I finally understand why solver selection guidelines are so important!

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upwind: 1st order accuracy, stable but high numerical diffusion
linearUpwind: 2nd order accuracy, limited
limitedLinear: 2nd order accuracy, with TVD limiter
LUST: blended scheme, recommended for LES

Error Evaluation and Accuracy Verification

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I've heard of "Error Evaluation and Accuracy Verification," but I might not fully understand it...

Discretization Error Evaluation

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What exactly do you mean by discretization error evaluation?

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Estimation of discretization error using Richardson extrapolation:

$$ f_{\text{exact}} \approx f_h + \frac{f_h - f_{2h}}{r^p - 1} $$

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Here, $f_h$ is the solution with mesh width $h$, $r$ is the mesh ratio, and $p$ is the order of discretization.

GCI (Grid Convergence Index)

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Please tell me about "GCI"!

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Quantitative evaluation of mesh convergence based on ASME V&V 20-2009:

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After hearing this, I finally understand why discretization error evaluation is so important!

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This can be expressed with this formula.

$$ GCI_{\text{fine}} = \frac{F_s |\varepsilon|}{r^p - 1} $$

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Hmm, just the formula doesn't click for me... What does it represent?

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Safety factor $F_s = 1.25$ (when comparing three or more mesh levels). GCI < 5% is a guideline for convergence.

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Now I understand what my senior meant when he said, "Make sure you properly evaluate discretization error."

Verification Benchmark Problems

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Please tell me about "Verification Benchmark Problems"!

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To ensure the reliability of analysis results, comparison with the following benchmark problems is recommended:

Code_Aster接触解析

Theory and Physics

Numerical Methods and Implementation

Details of Numerical Methods

Compilation and Build

Input File Structure

Script Automation

Debugging and Development Environment

Solver Settings and Algorithms

OpenFOAM Solver Selection Guidelines

CalculiX Input File Structure

Code_Aster Command File Structure

Discretization Scheme Selection

Error Evaluation and Accuracy Verification

Discretization Error Evaluation

GCI (Grid Convergence Index)

Verification Benchmark Problems

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