Web page of Charles Dapogny

Syllabus:

The course is divided into 7 lectures, with unequal lengths. In each case below, you will find the slides of the lectures, as well as sample codes written in FreeFem++. These personal implementations are designed from the sole knowledge of the authors, and for pedagogical purposes mainly, rather than computational efficiency. All conclusions drawn from their use should be mitigated with these points in mind!

Here is also a link to a series of videos (in French) corresponding to the lectures (course taught for the University of Tripoli, Lebanon).

Part I: Introduction

Download the slides of the lecture.
See the record of the lecture.

Part II: Optimal control

Download the slides of the lecture.
See the records of the lectures: Lecture 1, Lecture 2.

The FreeFem codes associated to the examples of the lectures:

Tartar's radiator without Hilbertian regularization.	Tartar's radiator using Hilbertian regularization.	Optimization of the design of a heat lens.

Download the code.	Download the code.	Download the code.

Part III: Geometric shape optimization

Download the slides of the lecture.
See the records of the lectures: Lecture 1, Lecture 2.

Be sure to give a try to the codes for the examples from the lectures:

Optimization of a cantilever beam with a geometric optimization algorithm.	Optimization of the shape of wheel-shaped bridge using the level set method.

Download the code.	Download the code.

Part IV: Homogenization

Download the slides of the lectures: Part 1, Part 2 and Part 3.
Here is another set of slides, covering more or less the same topics.

Part V: Density methods

Download the slides of the lecture.

Be sure to give a try to the codes for the examples from the lectures:

Optimization of a cantilever beam with density-based topology optimization algorithm.	Optimization of the shape of pipe containing a Newtonian fluid with a density-based method.

Download the code.	Download the code.

Part VI: Topological derivatives

Download the slides of the lecture.

Try it yourself!

Optimization of the shape of an electric mast using the fixed-point algorithm based on topological derivatives.	Optimization of the shape of an electric mast using the fixed-point algorithm based on topological derivatives.

Download the code.	Download the code.

Part VII: Perspectives

Download the slides of the lecture.

Evaluation:

Each attendant is expected to select one of the following themes, in close connection with the lectures, and to contact both instructors by email to give a list of three themes (sorted by rank of preference). Themes will then be attributed on a first come first served basis, and the corresponding articles will be sent to you.

Additive manufacturing and shape and topology optimization

G. Allaire and L. Jakabcin, Taking into account thermal residual stresses in topology optimization of structures built by additive manufacturing
M. Langelaar, Topology optimization of 3D self-supporting structures for additive manufacturing
J. Liu et al, Current and future trends in topology optimization for additive manufacturing

The fixed point method based on topological derivatives for shape and topology optimization

S. Amstutz, Analysis of a level set method for topology optimization
S. Amstutz and H. Andra, A new algorithm for topology optimization using a level-set method
S. Amstutz, Sensitivity analysis with respect to a local perturbation of the material property

Existence and non existence of optimal designs

F. Murat, Contre-exemples pour divers problèmes où le contrôle intervient dans les coefficients
A. Henrot and M. Pierre, Variation et optimisation de formes (Chap. 4)

Shape optimization via the level set method

G. Allaire, F. Jouve and A.-M. Toader, Structural optimization using sensitivity analysis and a level-set method
G. Allaire and F. Jouve, A level-set method for vibration and multiple loads structural optimization

Variants of the level set method for shape optimization

G. Pingen, M. Waidmann, A. Evgrafov and K. Maute, A parametric level-set approach for topology optimization of flow domains
T. Yamada, K. Izui, S. Nishiwaki and A. Takezawa, A topology optimization method based on the level set method incorporating a fictitious interface energy

The Moving Morphable Components (MMC) method for shape optimization

X. Guo, W. Zhang and W. Zhong, Doing Topology Optimization Explicitly and Geometrically – A New Moving Morphable Components Based Framework
W. Zhang, J. Yuan, J. Zhang and X. Guo A new topology optimization approach based on Moving Morphable Components (MMC) and the ersatz material model

About the homogenization theory

A. Cherkaev and R.V. Kohn (Eds), Topics in the Mathematical Modelling of Composite Materials (Chaps. 1 and 3)

Bloch-wave homogenization

C. Conca and M. Vanninathan, Homogenization of periodic structures via Bloch decomposition
C. Conca and M. Vanninathan, Fourier approach to homogenization problems

Mesh update strategies for shape optimization

G. Allaire and O. Pantz, Structural optimization with FreeFem++
A. N. Christiansen, M. Nobel-Jorgensen, N. Aage, O. Sigmund and J. A. Baerentzen Topology optimization using an explicit interface representation
G. Allaire, C. Dapogny and P. Frey, Shape optimization with a level set based mesh evolution method

Applications of homogenization to numerical shape and topology optimization

M. P. Bendsoe and N. Kikuchi, Generating optimal topologies in structural design using a homogenization method
G. Allaire, E. Bonnetier, G. Francfort and F. Jouve, Shape optimization by the homogenization method

Multi-phase shape and topology optimization

G. Allaire, C. Dapogny, G. Delgado and G. Michailidis, Multi-phase structural optimization using a level set method
O. Pantz, Sensibilité de l’équation de la chaleur aux sauts de conductivité
M. Wang and X. Wang, ‘‘Color’’ level sets: a multi-phase method for structural topology optimization with multiple materials

The Solid Isotropic Material with Penalization (SIMP) method

M. P. Bendsoe and O. Sigmund, Material interpolation schemes in topology optimization
O. Sigmund and J. Petersson, Numerical instabilities in topology optimization: A survey on procedures dealing with checkerboards, mesh-dependencies and local minima
O. Sigmund, A 99 line topology optimization code written in Matlab

Applications of shape optimization in computer graphics

H. Zhao, S. Osher and R. Fedkiw, Fast Surface Reconstruction Using the Level Set Method
G. Peyre, J. Fadili and J. Rabin, Wasserstein Active Contours

Each theme contains two or three research articles (depending on the length and difficulty), and the attendants are required to make a synthesis out of them, resulting in

A two-page report, to be sent to both instructors before Sunday, January 28th, 11.59pm;
An oral presentation of 12 minutes (followed by 3 minutes of questions), taking place live on January, 29th, 2024, 2 pm in Room H103 (Ensimag).

Here is the schedule for the presentations:

2.00 pm. M. Benedetti: Mesh update strategies for shape optimization
2.15 pm. K. Killias: Applications of shape optimization in computer graphics
2.30 pm. Y. Liu: About the homogenization theory
2 45 pm. H. Mazloum: The fixed point method based on topological derivatives for shape and topology optimization
3.00 pm. M. Renard: Shape optimisation via the level set method
3.15 pm. L. Vandame: Variants of the level set method for shape optimization

References and resources:

G. Allaire, Optimal design of structures: webpage of the course taught by G. Allaire at Ecole Polytechnique.
G. Allaire, C. Dapogny and F. Jouve, Shape and topology optimization: a comprehensive book chapter, accounting for most of the material in the course.
G. Allaire and O. Pantz, Structural Optimization with FreeFem++: an educational article describing a user-friendly implementation of geometric shape optimization.
C. Dapogny, An introduction to shape and topology optimization: webpage of a previous version of the course, containing a set of programming exercises (including a primer about FreeFem++).
C. Dapogny, P. Frey, F. Omnès and Y. Privat, Geometrical shape optimization in Fluid Mechanics using FreeFem++: an educational article describing a similar framework in the context of fluid mechanics.
E. Andreassen, A. Clausen, M. Schevenels, B. S. Lazarov and O. Sigmund, Efficient topology optimization in MATLAB using 88 lines of code: an educational article associated to a Matlab implementation of the SIMP method.
P. Frey and Y. Privat, Aspects théoriques et numériques pour les fluides incompressibles: webpage of a similar course, given at Sorbonne Universités.

Instructors:

Syllabus:

Evaluation:

References and resources: