BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION
This study follows the implementation of a balanced inverse-direct design of airfoil via multi-objective optimization. The aim of such case is to minimize the mean absolute error (MAE) of the pressure distribution compared to a given target along with a second objective of minimizing coecient of...
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id-itb.:423932019-09-19T11:25:31ZBALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION Rahmad, Yodefia Indonesia Final Project airfoil, multi-objective optimization, inverse design, genetic algorithm, Kriging surrogate model INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/42393 This study follows the implementation of a balanced inverse-direct design of airfoil via multi-objective optimization. The aim of such case is to minimize the mean absolute error (MAE) of the pressure distribution compared to a given target along with a second objective of minimizing coecient of drag (Cd). The term balanced comes from the pursue of a set of non-dominated solutions where each member proposes dierent trade-o for each objective. Two dierent gradient-free optimization methods are applied: genetic algorithm (GA) and Bayesian optimiza- tion. GA mimics genetic inheritance and natural selection in nding an optimized solution through population regenerations. Bayesian optimization utilizes a Krig- ing surrogate function in modeling the objective function probabilistically based on a set of initial samples. From a total of three cases, the rst one examines the validity of the framework by optimizing NACA 0012 airfoil with a known target airfoil of NACA 2412. The second uses NLF(1)-0115 as baseline airfoil and sets the target to maintain a laminar ow over the upper surface region. The last case prescribes a reduced shock pressure distribution as the target for a transonic airfoil RAE 2822. All of the problems conducted result in a solution set which includes new airfoil congurations with acceptable quantity of error in pressure distribution compared to the target assigned and notably lower drag. text |
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This study follows the implementation of a balanced inverse-direct design of airfoil
via multi-objective optimization. The aim of such case is to minimize the mean
absolute error (MAE) of the pressure distribution compared to a given target
along with a second objective of minimizing coecient of drag (Cd). The term
balanced comes from the pursue of a set of non-dominated solutions where each
member proposes dierent trade-o for each objective. Two dierent gradient-free
optimization methods are applied: genetic algorithm (GA) and Bayesian optimiza-
tion. GA mimics genetic inheritance and natural selection in nding an optimized
solution through population regenerations. Bayesian optimization utilizes a Krig-
ing surrogate function in modeling the objective function probabilistically based
on a set of initial samples. From a total of three cases, the rst one examines the
validity of the framework by optimizing NACA 0012 airfoil with a known target
airfoil of NACA 2412. The second uses NLF(1)-0115 as baseline airfoil and sets
the target to maintain a laminar ow over the upper surface region. The last
case prescribes a reduced shock pressure distribution as the target for a transonic
airfoil RAE 2822. All of the problems conducted result in a solution set which
includes new airfoil congurations with acceptable quantity of error in pressure
distribution compared to the target assigned and notably lower drag.
|
| format |
Final Project |
| author |
Rahmad, Yodefia |
| spellingShingle |
Rahmad, Yodefia BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION |
| author_facet |
Rahmad, Yodefia |
| author_sort |
Rahmad, Yodefia |
| title |
BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION |
| title_short |
BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION |
| title_full |
BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION |
| title_fullStr |
BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION |
| title_full_unstemmed |
BALANCED INVERSE-DIRECT DESIGN OF AIRFOIL VIA MULTI-OBJECTIVE OPTIMIZATION |
| title_sort |
balanced inverse-direct design of airfoil via multi-objective optimization |
| url |
https://digilib.itb.ac.id/gdl/view/42393 |
| _version_ |
1822926255950921728 |