Add to ORKGA hybrid automatic differentiation/incremental iterative method was implemented in the general purpose advanced computational fluid dynamics code (CFL3D Version 4.1) to yield a new code (CFL3D.ADII) that is capable of computing consistently discrete first order sensitivity derivatives for complex geometries. With the exception of unsteady problems, the new code retains all the useful features and capabilities of the original CFL3D flow analysis code. The superiority of the new code over a carefully applied method of finite-differences is demonstrated. A coarse grain, scalable, distributed-memory, parallel version of CFL3D.ADII was developed based on derivative stripmining . In this data-parallel approach, an identical copy of CFL3D.ADII is...
A versatile and efficient multi-block method is presented for the simulation of both steady and unst...
General problems of interest in computational fluid dynamics are investigated by means of optimizati...
This paper solves an 'incremental' form of the sensitivity equations derived by differentiating the ...
A hybrid automatic differentiation/incremental iterative method was implemented in the general purpo...
In this study which involves advanced fluid-flow codes, an incremental iterative formulation (also k...
Sensitivity derivative (SD) calculation via automatic differentiation typical of that required for t...
Sensitivity derivative (SD) calculation via automatic differentiation (AD) typical of that required ...
A gradient-based shape optimization methodology based on quasi-analytical sensitivities has been dev...
An aerodynamic shape optimization procedure based on discrete sensitivity analysis is extended to tr...
The straightforward automatic-differentiation and the hand-differentiated incremental iterative meth...
Sensitivity derivative (SD) calculation via automatic differentiation (AD) typical of that required ...
A new and efficient procedure for aerodynamic shape optimization is presented. The salient lineament...
In this preliminary study involving advanced computational fluid dynamic (CFD) codes, an incremental...
Automatic differentiation (AD) is a powerful computational method that provides for computing exact ...
An aerodynamic shape optimization procedure based on discrete sensitivity analysis is extended to tr...
A versatile and efficient multi-block method is presented for the simulation of both steady and unst...
General problems of interest in computational fluid dynamics are investigated by means of optimizati...
This paper solves an 'incremental' form of the sensitivity equations derived by differentiating the ...
A hybrid automatic differentiation/incremental iterative method was implemented in the general purpo...
In this study which involves advanced fluid-flow codes, an incremental iterative formulation (also k...
Sensitivity derivative (SD) calculation via automatic differentiation typical of that required for t...
Sensitivity derivative (SD) calculation via automatic differentiation (AD) typical of that required ...
A gradient-based shape optimization methodology based on quasi-analytical sensitivities has been dev...
An aerodynamic shape optimization procedure based on discrete sensitivity analysis is extended to tr...
The straightforward automatic-differentiation and the hand-differentiated incremental iterative meth...
Sensitivity derivative (SD) calculation via automatic differentiation (AD) typical of that required ...
A new and efficient procedure for aerodynamic shape optimization is presented. The salient lineament...
In this preliminary study involving advanced computational fluid dynamic (CFD) codes, an incremental...
Automatic differentiation (AD) is a powerful computational method that provides for computing exact ...
An aerodynamic shape optimization procedure based on discrete sensitivity analysis is extended to tr...
A versatile and efficient multi-block method is presented for the simulation of both steady and unst...
General problems of interest in computational fluid dynamics are investigated by means of optimizati...
This paper solves an 'incremental' form of the sensitivity equations derived by differentiating the ...
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