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117 results on '"Caflisch, Russel"'

1. Adjoint Monte Carlo Method

Author

Caflisch, Russel and Yang, Yunan

Subjects
Mathematics - Numerical Analysis, Physics - Computational Physics
Abstract

This survey explores the development of adjoint Monte Carlo methods for solving optimization problems governed by kinetic equations, a common challenge in areas such as plasma control and device design. These optimization problems are particularly demanding due to the high dimensionality of the phase space and the randomness in evaluating the objective functional, a consequence of using a forward Monte Carlo solver. To overcome these difficulties, a range of ``adjoint Monte Carlo methods'' have been devised. These methods skillfully combine Monte Carlo gradient estimators with PDE-constrained optimization, introducing innovative solutions tailored for kinetic applications. In this review, we begin by examining three primary strategies for Monte Carlo gradient estimation: the score function approach, the reparameterization trick, and the coupling method. We also delve into the adjoint-state method, an essential element in PDE-constrained optimization. Focusing on applications in the radiative transfer equation and the nonlinear Boltzmann equation, we provide a comprehensive guide on how to integrate Monte Carlo gradient techniques within both the optimize-then-discretize and the discretize-then-optimize frameworks from PDE-constrained optimization. This approach leads to the formulation of effective adjoint Monte Carlo methods, enabling efficient gradient estimation in complex, high-dimensional optimization problems., Comment: 39 pages, 7 figures

Published
2024

2. Gradient-based Monte Carlo methods for relaxation approximations of hyperbolic conservation laws

Author

Bertaglia, Giulia, Pareschi, Lorenzo, and Caflisch, Russel E.

Subjects
Mathematics - Numerical Analysis, Physics - Computational Physics, 65C05, 65C35, 35L65, 35L04, 82B40
Abstract

Particle methods based on evolving the spatial derivatives of the solution were originally introduced to simulate reaction-diffusion processes, inspired by vortex methods for the Navier--Stokes equations. Such methods, referred to as gradient random walk methods, were extensively studied in the '90s and have several interesting features, such as being grid free, automatically adapting to the solution by concentrating elements where the gradient is large and significantly reducing the variance of the standard random walk approach. In this work, we revive these ideas by showing how to generalize the approach to a larger class of partial differential equations, including hyperbolic systems of conservation laws. To achieve this goal, we first extend the classical Monte Carlo method to relaxation approximation of systems of conservation laws, and subsequently consider a novel particle dynamics based on the spatial derivatives of the solution. The methodology, combined with asymptotic-preserving splitting discretization, yields a way to construct a new class of gradient-based Monte Carlo methods for hyperbolic systems of conservation laws. Several results in one spatial dimension for scalar equations and systems of conservation laws show that the new methods are very promising and yield remarkable improvements compared to standard Monte Carlo approaches, either in terms of variance reduction as well as in describing the shock structure.

Published
2023

3. Adjoint DSMC for Nonlinear Spatially-Homogeneous Boltzmann Equation With a General Collision Model

Author

Yang, Yunan, Silantyev, Denis, and Caflisch, Russel

Subjects
Mathematics - Numerical Analysis, 76P05, 82C80, 65C05, 65K10, 82B40, 65M32
Abstract

We derive an adjoint method for the Direct Simulation Monte Carlo (DSMC) method for the spatially homogeneous Boltzmann equation with a general collision law. This generalizes our previous results in [Caflisch, R., Silantyev, D. and Yang, Y., 2021. Journal of Computational Physics, 439, p.110404], which was restricted to the case of Maxwell molecules, for which the collision rate is constant. The main difficulty in generalizing the previous results is that a rejection sampling step is required in the DSMC algorithm in order to handle the variable collision rate. We find a new term corresponding to the so-called score function in the adjoint equation and a new adjoint Jacobian matrix capturing the dependence of the collision parameter on the velocities. The new formula works for a much more general class of collision models., Comment: 28 pages, 5 figures

Published
2022
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4. Adjoint DSMC for nonlinear Boltzmann equation constrained optimization

Author

Caflisch, Russel, Silantyev, Denis, and Yang, Yunan

Subjects
Mathematics - Numerical Analysis, Mathematical Physics, Mathematics - Optimization and Control, 76P05, 82C80, 65C05, 65K10, 82B40, 65M32
Abstract

Applications for kinetic equations such as optimal design and inverse problems often involve finding unknown parameters through gradient-based optimization algorithms. Based on the adjoint-state method, we derive two different frameworks for approximating the gradient of an objective functional constrained by the nonlinear Boltzmann equation. While the forward problem can be solved by the DSMC method, it is difficult to efficiently solve the high-dimensional continuous adjoint equation obtained by the "optimize-then-discretize" approach. This challenge motivates us to propose an adjoint DSMC method following the "discretize-then-optimize" approach for Boltzmann-constrained optimization. We also analyze the properties of the two frameworks and their connections. Several numerical examples are presented to demonstrate their accuracy and efficiency., Comment: 32 pages. 8 figures

Published
2020
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5. Compressed Wannier modes found from an $L_1$ regularized energy functional

Author

Barekat, Farzin, Yin, Ke, Caflisch, Russel E., Osher, Stanley J., Lai, Rongjie, and Ozolins, Vidvuds

Subjects
Condensed Matter - Materials Science, Mathematical Physics, Quantum Physics
Abstract

We propose a method for calculating Wannier functions of periodic solids directly from a modified variational principle for the energy, subject to the requirement that the Wannier functions are orthogonal to all their translations ("shift-orthogonality"). Localization is achieved by adding an $L_1$ regularization term to the energy functional. This approach results in "compressed" Wannier modes with compact support, where one parameter $\mu$ controls the trade-off between the accuracy of the total energy and the size of the support of the Wannier modes. Efficient algorithms for shift-orthogonalization and solution of the variational minimization problem are demonstrated., Comment: 5 pages, 3 figures

Published
2014

6. Projection to the Set of Shift Orthogonal Functions

Author

Barekat, Farzin, Lai, Rongjie, Yin, Ke, Osher, Stanley, Caflisch, Russel, and Ozolins, Vidvuds

Subjects
Mathematics - Numerical Analysis, Mathematical Physics, Mathematics - Optimization and Control
Abstract

This paper presents a fast algorithm for projecting a given function to the set of shift orthogonal functions (i.e. set containing functions with unit $L^2$ norm that are orthogonal to their prescribed shifts). The algorithm can be parallelized easily and its computational complexity is bounded by $O(M\log(M))$, where $M$ is the number of coefficients used for storing the input. To derive the algorithm, a particular class of basis called Shift Orthogonal Basis Functions are introduced and some theory regarding them is developed., Comment: 32 pages, 2 figures

Published
2014

7. PDEs with Compressed Solutions

Author

Caflisch, Russel E., Osher, Stanley J., Schaeffer, Hayden, and Tran, Giang

Subjects
Mathematics - Analysis of PDEs
Abstract

Sparsity plays a central role in recent developments in signal processing, linear algebra, statistics, optimization, and other fields. In these developments, sparsity is promoted through the addition of an $L^1$ norm (or related quantity) as a constraint or penalty in a variational principle. We apply this approach to partial differential equations that come from a variational quantity, either by minimization (to obtain an elliptic PDE) or by gradient flow (to obtain a parabolic PDE). Also, we show that some PDEs can be rewritten in an $L^1$ form, such as the divisible sandpile problem and signum-Gordon. Addition of an $L^1$ term in the variational principle leads to a modified PDE where a subgradient term appears. It is known that modified PDEs of this form will often have solutions with compact support, which corresponds to the discrete solution being sparse. We show that this is advantageous numerically through the use of efficient algorithms for solving $L^1$ based problems., Comment: 21 pages, 15 figures

Published
2013

8. Simulation with Fluctuating and Singular Rates

Author

Barekat, Farzin and Caflisch, Russel

Subjects
Mathematics - Numerical Analysis
Abstract

In this paper we present a method to generate independent samples for a general random variable, either continuous or discrete. The algorithm is an extension of the acceptance-rejection method, and it is particularly useful for kinetic simulation in which the rates are fluctuating in time and have singular limits, as occurs for example in simulation of recombination interactions in a plasma. Although it depends on some additional requirements, the new method is easy to implement and rejects less samples than the acceptance-rejection method., Comment: 22 pages, 6 figures

Published
2013
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9. Compressed Modes for Variational Problems in Mathematics and Physics

Author

Ozoliņš, Vidvuds, Lai, Rongjie, Caflisch, Russel, and Osher, Stanley

Subjects
Mathematics - Numerical Analysis, Physics - Computational Physics
Abstract

This paper describes a general formalism for obtaining localized solutions to a class of problems in mathematical physics, which can be recast as variational optimization problems. This class includes the important cases of Schr\"odinger's equation in quantum mechanics and electromagnetic equations for light propagation in photonic crystals. These ideas can also be applied to develop a spatially localized basis that spans the eigenspace of a differential operator, for instance, the Laplace operator, generalizing the concept of plane waves to an orthogonal real-space basis with multi-resolution capabilities., Comment: 18 pages

Published
2013
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10. Sparse Dynamics for Partial Differential Equations

Author

Schaeffer, Hayden, Osher, Stanley, Caflisch, Russel, and Hauck, Cory

Subjects
Mathematics - Numerical Analysis
Abstract

We investigate the approximate dynamics of several differential equations when the solutions are restricted to a sparse subset of a given basis. The restriction is enforced at every time step by simply applying soft thresholding to the coefficients of the basis approximation. By reducing or compressing the information needed to represent the solution at every step, only the essential dynamics are represented. In many cases, there are natural bases derived from the differential equations which promote sparsity. We find that our method successfully reduces the dynamics of convection equations, diffusion equations, weak shocks, and vorticity equations with high frequency source terms.

Published
2012
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11. Anisotropic step stiffness from a kinetic model of epitaxial growth

Author

Margetis, Dionisios and Caflisch, Russel E.

Subjects
Condensed Matter - Materials Science
Abstract

Starting from a detailed model for the kinetics of a step edge or island boundary, we derive a Gibbs-Thomson type formula and the associated step stiffness as a function of the step edge orientation angle, $theta$. Basic ingredients of the model are: (i) the diffusion of point defects (``adatoms'') on terraces and along step edges; (ii) the convection of kinks along step edges; and (iii) constitutive laws that relate adatom fluxes, sources for kinks, and the kink velocity with densities via a mean-field approach. This model has a kinetic (nonequilibrium) steady-state solution that corresponds to epitaxial growth through step flow. The step stiffness, $\tbe(\theta)$, is determined via perturbations of the kinetic steady state for small edge Peclet number, P, which is the ratio of the deposition to the diffusive flux along a step edge. In particular, $\tbe$ is found to satisfy $\tbe =O(\theta^{-1})$ for $O(P^{1/3}) <\theta \ll 1$, which is in agreement with independent, equilibrium-based calculations., Comment: 32 pages, 1 figure; submitted to Multiscale Modeling and Simulation

Published
2007

12. Adjoint DSMC for nonlinear spatially-homogeneous Boltzmann equation with a general collision model

Author

Yang, Yunan, Silantyev, Denis, and Caflisch, Russel

Subjects
Optimization, History, Polymers and Plastics, Adjoint-state method, Direct simulation Monte Carlo methods, Numerical Analysis (math.NA), Industrial and Manufacturing Engineering, Boltzmann equation, 76P05, 82C80, 65C05, 65K10, 82B40, 65M32, FOS: Mathematics, DSMC, Mathematics - Numerical Analysis, Business and International Management
Abstract

We derive an adjoint method for the Direct Simulation Monte Carlo (DSMC) method for the spatially homogeneous Boltzmann equation with a general collision law. This generalizes our previous results in Caflisch et al. (2021) [9], which was restricted to the case of Maxwell molecules, for which the collision rate is constant. The main difficulty in generalizing the previous results is that a rejection sampling step is required in the DSMC algorithm in order to handle the variable collision rate. We find a new term corresponding to the so-called score function in the adjoint equation and a new adjoint Jacobian matrix capturing the dependence of the collision parameter on the velocities. The new formula works for a much more general class of collision models., Journal of Computational Physics, 488, ISSN:0021-9991, ISSN:1090-2716

Published
2023

15. Analysis of island dynamics in epitaxial growth of thin films

Author

Caflisch, Russel E and Li, B

Subjects
epitaxial growth, island dynamics, step edges, normal velocity, adatom diffusion, linear stability, step-edge kinetics, line tension, surface diffusion
Abstract

This work is concerned with analysis and refinement for a class of island dynamics models for epitaxial growth of crystalline thin films. An island dynamics model consists of evolution equations for step edges (or island boundaries), coupled with a diffusion equation for the adatom density, on an epitaxial surface. The island dynamics model with irreversible aggregation is confirmed to be mathematically ill-posed, with a growth rate that is approximately linear for large wavenumbers. By including a kinetic model for the structure and evolution of step edges, the island dynamics model is made mathematically well-posed. In the limit of small edge Peclet number, the edge kinetics model reduces to a set of boundary conditions, involving line tension and one-dimensional surface diffusion, for the adatom density. Finally, in the infinitely fast terrace diffusion limit, a simplified model of one-dimensional surface diffusion and kink convection is derived and found to be linearly stable.

Published
2003

25. Optimization of Signal Segmentation, Signal Recovery, and Limited Current

Author

Chou, Hung-Hsu, Caflisch, Russel E1, Bandeira, Afonso S, Chou, Hung-Hsu, Chou, Hung-Hsu, Caflisch, Russel E1, Bandeira, Afonso S, and Chou, Hung-Hsu

Abstract

The first chapter is based on applying the Poisson summation formula to a constrained optimization problem. Motivated by Shannon sampling theorem and results on shift-invariant subspaces, we establish a compatible framework for the two key factors: the accuracy constraint, which is described in the frequency space, and the efficiency function, which is expressed in the regular space. We derive the optimal wavelet, denoted as the double-sinc function, that obtains the smallest support while remaining first order accuracy. Based on this wavelet, we further improve its accuracy by loosen up the constraint in support and manage to achieve nearly optimal efficiency.The goal of the second chapter is to recover the underlying signal from its superposed randomly-shifted noisy measurement, motivated by multi-reference alignment and Cryo-EM problem. The general setting is that we observe samples from noisy signal that is acted by a random group action, and we would like eliminate those noises, one type at a time. In our particular setting, rational Fourier monomials and total Fourier product are invariants under the group action and hence partially remove the effect of the noise from the group action. We then apply central limit theorem to eliminate the Gaussian noise. Finally, we apply the split Bregman algorithm in compressed sensing to obtain an explicit solution assuming that the signal is compactly supported. The third chapter is dedicated to applying a variation principle to the Euler-Poisson equation for periodic flow in a diode to optimize the flux difference, which could potentially exceed the Child-Langmuir limit. We derive a set of dual equations and boundary conditions and use upwind method to solve both the forward and backward equations. In our numerical experiment we derive a periodic solution whose flux goes above the CL limit before the physical setting or the method of characteristics breaks down.

Published
2019

26. Vortex Dynamics

Author

Caflisch, Russel E.

Subjects
Vortex Dynamics (Book) -- Book reviews, Books -- Book reviews, Mathematics
Published
1994

27. Accelerated First-Order Optimization with Orthogonality Constraints

Author

Siegel, Jonathan, Caflisch, Russel E1, Siegel, Jonathan, Siegel, Jonathan, Caflisch, Russel E1, and Siegel, Jonathan

Abstract

Optimization problems with orthogonality constraints have many applications in science and engineering.In these applications, one often deals with large-scale problems which are ill-conditioned near the optimum.Consequently, there is a need for first-order optimization methods which deal with orthogonality constraints,converge rapidly even when the objective is not well-conditioned, and are robust.In this dissertation we develop a generalization of Nesterov's accelerated gradient descent algorithm for optimization on the manifold of orthonormal matrices. The performance of the algorithm scales with the square root of the condition number.As a result, our method outperforms existing state-of-the-art algorithms on large, ill-conditioned problems. We discuss applications of the method to electronic structure calculations and to the calculation of compressed modes.

Published
2018

28. Two Phase Flows and Waves

Author

Caflisch, Russel

Subjects
Two Phase Flows and Waves (Book) -- Book reviews, Books -- Book reviews, Mathematics
Published
1992

35. Direct simulation Monte Carlo schemes for Coulomb interactions in plasmas

Author

Dimarco, Giacomo, Caflisch, Russel, Pareschi, Lorenzo, Institut de Mathématiques de Toulouse UMR5219 (IMT), Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Université Toulouse 1 Capitole (UT1), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Université Toulouse - Jean Jaurès (UT2J)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS), Department of Mathematics [UCLA], University of California [Los Angeles] (UCLA), University of California-University of California, Department of Mathematics and Informatics, Università degli Studi di Ferrara (UniFE), Université Toulouse Capitole (UT Capitole), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Université de Toulouse (UT)-Institut National des Sciences Appliquées (INSA)-Université Toulouse - Jean Jaurès (UT2J), Université de Toulouse (UT)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Centre National de la Recherche Scientifique (CNRS), University of California (UC)-University of California (UC), and Università degli Studi di Ferrara = University of Ferrara (UniFE)

Subjects
Plasma Physics (physics.plasm-ph), 82D10 (65C05 82D05), FOS: Mathematics, FOS: Physical sciences, Numerical Analysis (math.NA), Mathematics - Numerical Analysis, Computational Physics (physics.comp-ph), Physics - Computational Physics, Physics - Plasma Physics, ComputingMilieux_MISCELLANEOUS, 65M99, 65L06, 82D05
Abstract

We consider the development of Monte Carlo schemes for molecules with Coulomb interactions. We generalize the classic algorithms of Bird and Nanbu-Babovsky for rarefied gas dynamics to the Coulomb case thanks to the approximation introduced by Bobylev and Nanbu (Theory of collision algorithms for gases and plasmas based on the Boltzmann equation and the Landau-Fokker-Planck equation, Physical Review E, Vol. 61, 2000). Thus, instead of considering the original Boltzmann collision operator, the schemes are constructed through the use of an approximated Boltzmann operator. With the above choice larger time steps are possible in simulations; moreover the expensive acceptance-rejection procedure for collisions is avoided and every particle collides. Error analysis and comparisons with the original Bobylev-Nanbu (BN) scheme are performed. The numerical results show agreement with the theoretical convergence rate of the approximated Boltzmann operator and the better performance of Bird-type schemes with respect to the original scheme.

Published
2010

36. Two Approaches to Accelerated Monte Carlo Simulation of Coulomb Collisions

Author

Ricketson, Lee, Caflisch, Russel E1, Ricketson, Lee, Ricketson, Lee, Caflisch, Russel E1, and Ricketson, Lee

Abstract

In plasma physics, the direct simulation of inter-particle Coulomb collisions is often necessary to capture the relevant physics, but presents a computational bottleneck because of the complexity of the process. In this thesis, we derive, test and discuss two methods for accelerating the simulation of collisions in plasmas in certain scenarios. The first is a hybrid fluid-Monte Carlo scheme that reduces the number of collisions that must be simulated. Coupling between the fluid and particle components of the scheme is accomplished by assigning to each particle a passive scalar approximating the relative entropy between its distribution of velocities and the fluid distribution. When this quantity is sufficiently small, the particle is moved into the fluid so its associated collisions need not be simulated. The second method is an adaptation of the multilevel Monte Carlo method. Instead of a single time step, this method introduces a hierarchy of time steps - i.e. levels - and uses the interplay between adjacent levels for variance reduction. We present new applications to plasmas, a method for eliminating the cost of the coarsest level calculation, and an alternative method for achieving the optimal overall computational complexity.Throughout, we discuss applications beyond plasma physics, including rarefied gases and chemical reaction networks.

Published
2014

38. A multiscale method for epitaxial growth

Author

Sun, Yi, Caflisch, Russel, Engquist, Björn, Sun, Yi, Caflisch, Russel, and Engquist, Björn

Abstract

In this paper we investigate a heterogeneous multiscale method (HMM) for interface tracking and apply the technique to the simulation of epitaxial growth. HMM relies on an efficient coupling between macroscale and microscale models. When the macroscale model is not fully known explicitly or not accurate enough, HMM provides a procedure for supplementing the missing data from a microscale model. Here we design a multiscale method that couples kinetic Monte-Carlo (KMC) simulations on the microscale with the island dynamics model based on the level set method and a diffusion equation. We perform the numerical simulations for submonolayer island growth and step edge evolutions on the macroscale domain while keeping the KMC modeling of the internal boundary conditions. Our goal is to get comparably accurate solutions at potentially lower computational cost than for the full KMC simulations, especially for the step flow problem without nucleation., QC 20120102

Published
2011
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43. Modeling and Numerical Methods for Material Growth and Convection

Author

CALIFORNIA UNIV LOS ANGELES DEPT OF MATHEMATICS, Caflisch, Russel E., CALIFORNIA UNIV LOS ANGELES DEPT OF MATHEMATICS, and Caflisch, Russel E.

Abstract

Under support from this grant, substantial progress was made on a number of research projects, including the level set methods, modeling and simulation for material growth, Monte Carlo methods for rarefied gas dynamics, boundary value problem for Prandtl equations and image processing.

Published
2001

46. Rarefied Gas Dynamics and Monte Carlo Methods.

Author

CALIFORNIA UNIV LOS ANGELES DEPT OF MATHEMATICS, Caflisch, Russel E., CALIFORNIA UNIV LOS ANGELES DEPT OF MATHEMATICS, and Caflisch, Russel E.

Abstract

The research supported by this grant was primarily on quasi-random sequences, which are a deterministic alternative to random or pseudo-random sequences', and their use in Monte Carlo methods, These methods are vastly superior to standard Monte Carlo, at least in principle, because the errors are of size O(N-1) rather than the usual O(N-1/).On the other hand, this gain in accuracy can be lost if the domain of integration is of high dimension or the function to be integrated is not smooth. In joint work with Bradley Moskowitz, we succeeded in overcoming these limitations for a number of Monte Carlo methods, including the acceptance-rejection method, Feynman-Kac integrals and diffusion Monte Carlo.

Published
1995

47. Analysis and Computation for Vortex Dynamics and Rarefied Gases

Author

YALE UNIV NEW HAVEN CT DEPT OF MATHEMATICS, Caflisch, Russel, YALE UNIV NEW HAVEN CT DEPT OF MATHEMATICS, and Caflisch, Russel

Abstract

The researchers have developed a variety of adapted orthogonal transforms for signal compression and analysis. These methods have been used successfully in sound and high resolution image compression and are currently being tested for their technological value. In parallel, the best basis algorithm has been used by K. Sreenivasan for analysis of experimental turbulence data, and by M. Farge and V. Wickerhauser for the analysis of simulated two dimensional vorticity fields. This analysis permits a more careful comparison between simulation and experiment by detecting subtle differences in structures. By extracting coherent structures in the flows it promises to permit efficient tracking of these structures. In particular, as a result of testing by the FBI and Scotland Yard, a variant of these algorithms has been chosen for as a. standard for fingerprint image compression with an estimated initial saving to the FBI in storage hardware alone of $25,000,000. These methods are also being tested, in collaboration with Martin Marietta, for automatic target recognition.

Published
1992

49. MODELING, SIMULATION, AND DESIGN FOR A CUSTOMIZABLE ELECTRODEPOSITION PROCESS.

Author

THIYANARATNAM, PRADEEP, CAFLISCH, RUSSEL, MOTTA, PAULO S., and JUDY, JACK W.

Subjects
*ELECTROFORMING, *SIMULATION methods & models, *METAL ions, *MATHEMATICAL models, *NUMERICAL analysis, *INVERSE problems, *DIFFERENTIAL equations, *MATHEMATICAL analysis, *MATHEMATICS
Abstract

Judy and Motta developed a customizable electrodeposition process for fabrication of very small metal structures on a substrate. In this process, layers of metal of various shapes are placed on the substrate, then the substrate is inserted in an electroplating solution. Some of the metal layers have power applied to them, while the rest of the metal layers are not connected to the power initially. Metal ions in the plating solution start depositing on the powered layers and a surface grows from the powered layers. As the surface grows, it will touch metal layers that were initially unpowered, causing them to become powered and to start growing with the rest of the surface. The metal layers on the substrate are known as seed layer patterns, and different seed layer patterns can produce different shapes. This paper presents a mathematical model, a forward simulation method, and an inverse problem solution for the growth of a surface from a seed layer pattern. The model describes the surface evolution as uniform growth in the direction normal to the surface. This growth is simulated in two and three dimensions using the level set method. The inverse problem is to design a seed layer pattern that produces a desired surface shape. Some surface shapes are not attainable by any seed layer pattern. For smooth attainable shapes, we present a computational method that solves this inverse problem. [ABSTRACT FROM AUTHOR]

Published
2008
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