Applied Shape Optimization for Fluids
Applied Shape Optimization for Fluids
Applied Shape Optimization for Fluids
Trending Bestseller

Applied Shape Optimization for Fluids

No reviews yet Write a Review
This new edition of Applied Shape Optimization for Fluids deals with shape optimization problems for fluids, with the equations needed for their understanding (Euler and Navier Strokes, but also those for microfluids) and with the numerical simulation of these problems.
Hardback
01-October-2009
RRP: $324.00
$217.00
In Stock: Ships in 4-6 Working Days
In Stock: Ships in 7-9 Days
Hurry up! Current stock:
icon Share icon Share
Description  
This new edition of Applied Shape Optimization for Fluids deals with shape optimization problems for fluids, with the equations needed for their understanding (Euler and Navier Strokes), and with the numerical simulation of these problems. It presents the state of the art in shape optimization for an expanded range of applications involving fluid flows. Automatic differentiation, approximate gradients, unstructured mesh adaptation, multi-model configurations, and time-dependent problems are introduced, and their implementation into the industrial environments of aerospace and automobile equipment industry explained and illustrated.
Customer reviews  

This product hasn't received any reviews yet. Be the first to review this product!

Write a Reviews
Flat Rate Shipping  
Easy Returns  
RRP: $324.00
$217.00
In Stock: Ships in 4-6 Working Days
In Stock: Ships in 7-9 Days
Hurry up! Current stock:
icon Share icon Share
Flat Rate Shipping  
Easy Returns  

Applied Shape Optimization for Fluids

RRP: $324.00
$217.00

Description

This new edition of Applied Shape Optimization for Fluids deals with shape optimization problems for fluids, with the equations needed for their understanding (Euler and Navier Strokes), and with the numerical simulation of these problems. It presents the state of the art in shape optimization for an expanded range of applications involving fluid flows. Automatic differentiation, approximate gradients, unstructured mesh adaptation, multi-model configurations, and time-dependent problems are introduced, and their implementation into the industrial environments of aerospace and automobile equipment industry explained and illustrated.

Customers Also Viewed