Your search keyword '"Mathematics - Optimization and Control"' showing total 62 results

1. A stochastic variance-reduced accelerated primal-dual method for finite-sum saddle-point problems

Author

Erfan Yazdandoost Hamedani and Afrooz Jalilzadeh

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, Applied Mathematics, MathematicsofComputing_NUMERICALANALYSIS, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

In this paper, we propose a variance-reduced primal-dual algorithm with Bregman distance for solving convex-concave saddle-point problems with finite-sum structure and nonbilinear coupling function. This type of problems typically arises in machine learning and game theory. Based on some standard assumptions, the algorithm is proved to converge with oracle complexity of $O\left(\frac{\sqrt n}{\epsilon}\right)$ and $O\left(\frac{n}{\sqrt \epsilon}+\frac{1}{\epsilon^{1.5}}\right)$ using constant and non-constant parameters, respectively where $n$ is the number of function components. Compared with existing methods, our framework yields a significant improvement over the number of required primal-dual gradient samples to achieve $\epsilon$-accuracy of the primal-dual gap. We tested our method for solving a distributionally robust optimization problem to show the effectiveness of the algorithm.

Published

2023

2. An accelerated inexact dampened augmented Lagrangian method for linearly-constrained nonconvex composite optimization problems

Author

Weiwei Kong and Renato D. C. Monteiro

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

This paper proposes and analyzes an accelerated inexact dampened augmented Lagrangian (AIDAL) method for solving linearly-constrained nonconvex composite optimization problems. Each iteration of the AIDAL method consists of: (i) inexactly solving a dampened proximal augmented Lagrangian (AL) subproblem by calling an accelerated composite gradient (ACG) subroutine; (ii) applying a dampened and under-relaxed Lagrange multiplier update; and (iii) using a novel test to check whether the penalty parameter of the AL function should be increased. Under several mild assumptions involving the dampening factor and the under-relaxation constant, it is shown that the AIDAL method generates an approximate stationary point of the constrained problem in ${\cal O}(\varepsilon^{-5/2}\log\varepsilon^{-1})$ iterations of the ACG subroutine, for a given tolerance $\varepsilon>0$. Numerical experiments are also given to show the computational efficiency of the proposed method.

Published

2023

3. An efficient implementable inexact entropic proximal point algorithm for a class of linear programming problems

Author

Hong T. M. Chu, Ling Liang, Kim-Chuan Toh, and Lei Yang

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

We introduce a class of specially structured linear programming (LP) problems, which has favorable modeling capability for important application problems in different areas such as optimal transport, discrete tomography and economics. To solve these generally large-scale LP problems efficiently, we design an implementable inexact entropic proximal point algorithm (iEPPA) combined with an easy-to-implement dual block coordinate descent method as a subsolver. Unlike existing entropy-type proximal point algorithms, our iEPPA employs a more practically checkable stopping condition for solving the associated subproblems while achieving provable convergence. Moreover, when solving the capacity constrained multi-marginal optimal transport (CMOT) problem (a special case of our LP problem), our iEPPA is able to bypass the underlying numerical instability issues that often appear in the popular entropic regularization approach, since our algorithm does not require the proximal parameter to be very small in order to obtain an accurate approximate solution. Numerous numerical experiments show that our iEPPA is efficient and robust for solving large-scale CMOT problems. The experiments on the discrete tomography problem also highlight the potential modeling power of our model., 28 pages, 6 figures

Published

2023

4. Integer set reduction for stochastic mixed-integer programming

Author

Saravanan Venkatachalam and Lewis Ntaimo

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

Two-stage stochastic mixed-integer programming (SMIP) problems with general integer variables in the second-stage are generally difficult to solve. This paper develops the theory of integer set reduction for characterizing the subset of the convex hull of feasible integer points of the second-stage subproblem which can be used for solving the SMIP. The basic idea is to consider a small enough subset of feasible integer points that is necessary for generating a valid inequality for the integer subproblem. An algorithm for obtaining such a subset based on the solution of the subproblem LP-relaxation is then devised and incorporated into the Fenchel decomposition method for SMIP. To demonstrate the performance of the new integer set reduction methodology, a computational study based on randomly generated test instances was performed. The results of the study show that integer set reduction provides significant gains in terms of generating cuts faster leading to better bounds in solving SMIPs than using a direct solver., Comment: 28 pages, 5 figures

Published

2023

5. Lifted stationary points of sparse optimization with complementarity constraints

Author

Shisen Liu and Xiaojun Chen

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

We aim to compute lifted stationary points of a sparse optimization problem (P0) with complementarity constraints. We define a continuous relaxation problem (Rv) that has the same global minimizers and optimal value with problem (P0). Problem (Rv) is a mathematical program with complementarity constraints (MPCC) and a difference-of-convex (DC) objective function. We define MPCC lifted-stationarity of (Rv) and show that it is weaker than directional stationarity, but stronger than Clarke stationarity for local optimality. Moreover, we propose an approximation method to solve (Rv) and an augmented Lagrangian method to solve its subproblem, which relaxes the equality constraint in (Rv) with a tolerance. We prove the convergence of our algorithm to an MPCC lifted-stationary point of problem (Rv) and use a sparse optimization problem with vertical linear complementarity constraints to demonstrate the efficiency of our algorithm on finding sparse solutions in practice., Comment: 29 pages, 3 figures

Published

2022

6. General-purpose preconditioning for regularized interior point methods

Author

Jacek Gondzio, Spyridon Pougkakiotis, and John W. Pearson

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Computer Science::Mathematical Software, Numerical Analysis (math.NA), Mathematics - Numerical Analysis, Computer Science::Numerical Analysis, Mathematics - Optimization and Control, Mathematics::Numerical Analysis

Abstract

In this paper we present general-purpose preconditioners for regularized augmented systems, and their corresponding normal equations, arising from optimization problems. We discuss positive definite preconditioners, suitable for CG and MINRES. We consider “sparsifications" which avoid situations in which eigenvalues of the preconditioned matrix may become complex. Special attention is given to systems arising from the application of regularized interior point methods to linear or nonlinear convex programming problems.

Published

2022

7. A stochastic first-order trust-region method with inexact restoration for finite-sum minimization

Author

Stefania Bellavia, Nataša Krejić, Benedetta Morini, and Simone Rebegoldi

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Numerical Analysis (math.NA), Mathematics - Numerical Analysis, 65K05, 90C26, 68T05, Mathematics - Optimization and Control

Abstract

We propose a stochastic first-order trust-region method with inexact function and gradient evaluations for solving finite-sum minimization problems. Using a suitable reformulation of the given problem, our method combines the inexact restoration approach for constrained optimization with the trust-region procedure and random models. Differently from other recent stochastic trust-region schemes, our proposed algorithm improves feasibility and optimality in a modular way. We provide the expected number of iterations for reaching a near-stationary point by imposing some probability accuracy requirements on random functions and gradients which are, in general, less stringent than the corresponding ones in literature. We validate the proposed algorithm on some nonconvex optimization problems arising in binary classification and regression, showing that it performs well in terms of cost and accuracy, and allows to reduce the burdensome tuning of the hyper-parameters involved.

Published

2022

8. Stochastic relaxed inertial forward-backward-forward splitting for monotone inclusions in Hilbert spaces

Author

Shisheng Cui, Uday Shanbhag, Mathias Staudigl, Phan Vuong, RS: FSE DACS, and Dept. of Advanced Computing Sciences

Subjects

FIXED-POINT ITERATIONS, Control and Optimization, Variance reduction, EQUILIBRIA, Stochastic approximation, Applied Mathematics, SCHEMES, Complexity, 37H10, 49M37, 65C40, 65K15, MODEL, Computational Mathematics, Dynamic sampling, Optimization and Control (math.OC), VARIATIONAL-INEQUALITIES, FOS: Mathematics, ALGORITHM, OPTIMIZATION, EQUATIONS, Mathematics - Optimization and Control, Monotone operator splitting, EXTRAGRADIENT METHOD

Abstract

We consider monotone inclusions defined on a Hilbert space where the operator is given by the sum of a maximal monotone operator $T$ and a single-valued monotone, Lipschitz continuous, and expectation-valued operator $V$. We draw motivation from the seminal work by Attouch and Cabot on relaxed inertial methods for monotone inclusions and present a stochastic extension of the relaxed inertial forward-backward-forward (RISFBF) method. Facilitated by an online variance reduction strategy via a mini-batch approach, we show that (RISFBF) produces a sequence that weakly converges to the solution set. Moreover, it is possible to estimate the rate at which the discrete velocity of the stochastic process vanishes. Under strong monotonicity, we demonstrate strong convergence, and give a detailed assessment of the iteration and oracle complexity of the scheme. When the mini-batch is raised at a geometric (polynomial) rate, the rate statement can be strengthened to a linear (suitable polynomial) rate while the oracle complexity of computing an $\epsilon$-solution improves to $O(1/\epsilon)$. Importantly, the latter claim allows for possibly biased oracles, a key theoretical advancement allowing for far broader applicability. By defining a restricted gap function based on the Fitzpatrick function, we prove that the expected gap of an averaged sequence diminishes at a sublinear rate of $O(1/k)$ while the oracle complexity of computing a suitably defined $\epsilon$-solution is $O(1/\epsilon^{1+a})$ where $a>1$. Numerical results on two-stage games and an overlapping group Lasso problem illustrate the advantages of our method compared to stochastic forward-backward-forward (SFBF) and SA schemes., Comment: Small clarifications in Section 4.2

Published

2022

9. A product space reformulation with reduced dimension for splitting algorithms

Author

Rubén Campoy

Subjects

Control and Optimization, Applied Mathematics, douglas – rachford algorithm, 47H05, 47J25, 49M27, 65K10, 90C30, UNESCO::CIENCIAS TECNOLÓGICAS, Computational Mathematics, Optimization and Control (math.OC), splitting algorithm, projection methods, FOS: Mathematics, pierra’s product space reformulation, monotone inclusions, Mathematics - Optimization and Control, feasibility problem

Abstract

In this paper we propose a product space reformulation to transform monotone inclusions described by finitely many operators on a Hilbert space into equivalent two-operator problems. Our approach relies on Pierra’s classical reformulation with a different decomposition, which results in a reduction of the dimension of the outcoming product Hilbert space. We discuss the case of not necessarily convex feasibility and best approximation problems. By applying existing splitting methods to the proposed reformulation we obtain new parallel variants of them with a reduction in the number of variables. The convergence of the new algorithms is straightforwardly derived with no further assumptions. The computational advantage is illustrated through some numerical experiments.

Published

2022

10. Quantifying uncertainty with ensembles of surrogates for blackbox optimization

Author

Charles Audet, Sébastien Le Digabel, and Renaud Saltet

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), G.1.6, Applied Mathematics, FOS: Mathematics, 90C56: Derivative-free methods, Mathematics - Optimization and Control

Abstract

This work is in the context of blackbox optimization where the functions defining the problem are expensive to evaluate and where no derivatives are available. A tried and tested technique is to build surrogates of the objective and the constraints in order to conduct the optimization at a cheaper computational cost. This work proposes different uncertainty measures when using ensembles of surrogates. The resulting combination of an ensemble of surrogates with our measures behaves as a stochastic model and allows the use of efficient Bayesian optimization tools. The method is incorporated in the search step of the mesh adaptive direct search (MADS) algorithm to improve the exploration of the search space. Computational experiments are conducted on seven analytical problems, two multi-disciplinary optimization problems and two simulation problems. The results show that the proposed approach solves expensive simulation-based problems at a greater precision and with a lower computational effort than stochastic models., Comment: 36 pages, 11 figures, submitted

Published

2022

11. On proximal augmented Lagrangian based decomposition methods for dual block-angular convex composite programming problems

Author

Kuang-Yu Ding, Xin-Yee Lam, and Kim-Chuan Toh

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

We design inexact proximal augmented Lagrangian based decomposition methods for convex composite programming problems with dual block-angular structures. Our methods are particularly well suited for convex quadratic programming problems arising from stochastic programming models. The algorithmic framework is based on the application of the abstract inexact proximal ADMM framework developed in [Chen, Sun, Toh, Math. Prog. 161:237--270] to the dual of the target problem, as well as the application of the recently developed symmetric Gauss-Seidel decomposition theorem for solving a proximal multi-block convex composite quadratic programming problem. The key issues in our algorithmic design are firstly in designing appropriate proximal terms to decompose the computation of the dual variable blocks of the target problem to make the subproblems in each iteration easier to solve, and secondly to develop novel numerical schemes to solve the decomposed subproblems efficiently. Our inexact augmented Lagrangian based decomposition methods have guaranteed convergence. We present an application of the proposed algorithms to the doubly nonnegative relaxations of uncapacitated facility location problems, as well as to two-stage stochastic optimization problems. We conduct numerous numerical experiments to evaluate the performance of our method against state-of-the-art solvers such as Gurobi and MOSEK. Moreover, our proposed algorithms also compare favourably to the well-known progressive hedging algorithm of Rockafellar and Wets.

Published

2023

12. Convergence of an asynchronous block-coordinate forward-backward algorithm for convex composite optimization

Author

Cheik Traoré, Saverio Salzo, and Silvia Villa

Subjects

FOS: Computer and information sciences, Computational Mathematics, Control and Optimization, Computer Science - Distributed, Parallel, and Cluster Computing, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Distributed, Parallel, and Cluster Computing (cs.DC), Mathematics - Optimization and Control

Abstract

In this paper, we study the convergence properties of a randomized block-coordinate descent algorithm for the minimization of a composite convex objective function, where the block-coordinates are updated asynchronously and randomly according to an arbitrary probability distribution. We prove that the iterates generated by the algorithm form a stochastic quasi-Fejér sequence and thus converge almost surely to a minimizer of the objective function. Moreover, we prove a general sublinear rate of convergence in expectation for the function values and a linear rate of convergence in expectation under an error bound condition of Tseng type. Under the same condition strong convergence of the iterates is provided as well as their linear convergence rate.

Published

2023

13. A communication-efficient and privacy-aware distributed algorithm for sparse PCA

Author

Lei Wang, Xin Liu, and Yin Zhang

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

Sparse principal component analysis (PCA) improves interpretability of the classic PCA by introducing sparsity into the dimension-reduction process. Optimization models for sparse PCA, however, are generally non-convex, non-smooth and more difficult to solve, especially on large-scale datasets requiring distributed computation over a wide network. In this paper, we develop a distributed and centralized algorithm called DSSAL1 for sparse PCA that aims to achieve low communication overheads by adapting a newly proposed subspace-splitting strategy to accelerate convergence. Theoretically, convergence to stationary points is established for DSSAL1. Extensive numerical results show that DSSAL1 requires far fewer rounds of communication than state-of-the-art peer methods. In addition, we make the case that since messages exchanged in DSSAL1 are well-masked, the possibility of private-data leakage in DSSAL1 is much lower than in some other distributed algorithms.

Published

2023

14. Accelerated inexact composite gradient methods for nonconvex spectral optimization problems

Author

Weiwei Kong and Renato D. C. Monteiro

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

This paper presents two inexact composite gradient methods, one inner accelerated and another doubly accelerated, for solving a class of nonconvex spectral composite optimization problems. More specifically, the objective function for these problems is of the form $f_1 + f_2 + h$ where $f_1$ and $f_2$ are differentiable nonconvex matrix functions with Lipschitz continuous gradients, $h$ is a proper closed convex matrix function, and both $f_2$ and $h$ can be expressed as functions that operate on the singular values of their inputs. The methods essentially use an accelerated composite gradient method to solve a sequence of proximal subproblems involving the linear approximation of $f_1$ and the singular value functions underlying $f_2$ and $h$. Unlike other composite gradient-based methods, the proposed methods take advantage of both the composite and spectral structure underlying the objective function in order to efficiently generate their solutions. Numerical experiments are presented to demonstrate the practicality of these methods on a set of real-world and randomly generated spectral optimization problems.

Published

2022

15. Derivative-free methods for mixed-integer nonsmooth constrained optimization

Author

Tommaso Giovannelli, Giampaolo Liuzzi, Stefano Lucidi, and Francesco Rinaldi

Subjects

Computational Mathematics, Control and Optimization, Derivative-free optimization, Mixed-integer nonlinear programming, Nonsmooth optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, 90C11, 90C56, 65K05, Mathematics - Optimization and Control

Abstract

In this paper, mixed-integer nonsmooth constrained optimization problems are considered, where objective/constraint functions are available only as the output of a black-box zeroth-order oracle that does not provide derivative information. A new derivative-free linesearch-based algorithmic framework is proposed to suitably handle those problems. First, a scheme for bound constrained problems that combines a dense sequence of directions to handle the nonsmoothness of the objective function with primitive directions to handle discrete variables is described. Then, an exact penalty approach is embedded in the scheme to suitably manage nonlinear (possibly nonsmooth) constraints. Global convergence properties of the proposed algorithms toward stationary points are analyzed and results of an extensive numerical experience on a set of mixed-integer test problems are reported.

Published

2022

16. Radius theorems for subregularity in infinite dimensions

Author

Helmut Gfrerer and Alexander Kruger

Subjects

Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, Mathematics::Optimization and Control, FOS: Mathematics, Mathematics - Optimization and Control

Abstract

The paper continues our previous work [7] on the radius of subregularity that was initiated by Asen Dontchev. We extend the results of [7] to general Banach/Asplund spaces and to other classes of perturbations, and sharpen the coderivative tools used in the analysis of the robustness of well-posedness of mathematical problems and related regularity properties of mappings involved in the statements. We also expand the selection of classes of perturbations, for which the formula for the radius of strong subregularity is valid., Comment: 31 pages

Published

2023

17. Method for solving bang-bang and singular optimal control problems using adaptive Radau collocation

Author

Elisha R. Pager and Anil V. Rao

Subjects

0209 industrial biotechnology, Computational Mathematics, 020901 industrial engineering & automation, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, 010103 numerical & computational mathematics, 02 engineering and technology, 0101 mathematics, Mathematics - Optimization and Control, 01 natural sciences

Abstract

A method is developed for solving bang-bang and singular optimal control problems using adaptive Legendre-Gauss-Radau (LGR) collocation. The method is divided into several parts. First, a structure detection method is developed that identifies switch times in the control and analyzes the corresponding switching function for segments where the solution is either bang-bang or singular. Second, after the structure has been detected, the domain is decomposed into multiple domains such that the multiple-domain formulation includes additional decision variables that represent the switch times in the optimal control. In domains classified as bang-bang, the control is set to either its upper or lower limit. In domains identified as singular, the objective function is augmented with a regularization term to avoid the singular arc. An iterative procedure is then developed for singular domains to obtain a control that lies in close proximity to the singular control. The method is demonstrated on four examples, three of which have either a bang-bang and/or singular optimal control while the fourth has a smooth and nonsingular optimal control. The results demonstrate that the method of this paper provides accurate solutions to problems whose solutions are either bang-bang or singular when compared against previously developed mesh refinement methods that are not tailored for solving nonsmooth and/or singular optimal control problems, and produces results that are equivalent to those obtained using previously developed mesh refinement methods for optimal control problems whose solutions are smooth., 37 pages, 6 figures, 5 tables To Appear in Computational Optimization and Applications

Published

2022

18. $$\rho$$-regularization subproblems: strong duality and an eigensolver-based algorithm

Author

Liaoyuan Zeng and Ting Kei Pong

Subjects

Computational Mathematics, Control and Optimization, Applied Mathematics, Mathematics - Optimization and Control

Abstract

Trust-region (TR) type method, based on a quadratic model such as the trust-region subproblem (TRS) and $ p $-regularization subproblem ($p$RS), is arguably one of the most successful methods for unconstrained minimization. In this paper, we study a general regularized subproblem (named $ \rho $RS), which covers TRS and $p$RS as special cases. We derive a strong duality theorem for $ \rho $RS, and also its necessary and sufficient optimality condition under general assumptions on the regularization term. We then define the Rendl-Wolkowicz (RW) dual problem of $ \rho $RS, which is a maximization problem whose objective function is concave, and differentiable except possibly at two points. It is worth pointing out that our definition is based on an alternative derivation of the RW-dual problem for TRS. Then we propose an eigensolver-based algorithm for solving the RW-dual problem of $ \rho $RS. The algorithm is carried out by finding the smallest eigenvalue and its unit eigenvector of a certain matrix in each iteration. Finally, we present numerical results on randomly generated $p$RS's, and on a new class of regularized problem that combines TRS and $p$RS, to illustrate our algorithm.

Published

2022

19. On the inexact scaled gradient projection method

Author

Max V. Lemes, L. F. Prudente, and Orizon P. Ferreira

Subjects

Control and Optimization, Line search, Applied Mathematics, Feasible region, MathematicsofComputing_GENERAL, Convex set, Computational Mathematics, Monotone polygon, Optimization and Control (math.OC), Approximation error, Convergence (routing), Line (geometry), FOS: Mathematics, Applied mathematics, Projection (set theory), Mathematics - Optimization and Control, 49J52, 49M15, 65H10, 90C30, Mathematics

Abstract

The purpose of this paper is to present an inexact version of the scaled gradient projection method on a convex set, which is inexact in two sense. First, an inexact projection on the feasible set is computed, allowing for an appropriate relative error tolerance. Second, an inexact non-monotone line search scheme is employed to compute a step size which defines the next iteration. It is shown that the proposed method has similar asymptotic convergence properties and iteration-complexity bounds as the usual scaled gradient projection method employing monotone line searches., Comment: 30 pages, 14 figures

Published

2021

20. Finding best approximation pairs for two intersections of closed convex sets

Author

Shambhavi Singh, Xianfu Wang, and Heinz H. Bauschke

Subjects

021103 operations research, Control and Optimization, Applied Mathematics, 0211 other engineering and technologies, Regular polygon, 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, 65K05 (Primary) 47H09, 90C25 (Secondary), Computational Mathematics, Optimization and Control (math.OC), FOS: Mathematics, 0101 mathematics, Projection (set theory), Mathematics - Optimization and Control, Algorithm, Mathematics

Abstract

The problem of finding a best approximation pair of two sets, which in turn generalizes the well known convex feasibility problem, has a long history that dates back to work by Cheney and Goldstein in 1959. In 2018, Aharoni, Censor, and Jiang revisited this problem and proposed an algorithm that can be used when the two sets are finite intersections of halfspaces. Motivated by their work, we present alternative algorithms that utilize projection and proximity operators. Our modeling framework is able to accommodate even convex sets. Numerical experiments indicate that these methods are competitive and sometimes superior to the one proposed by Aharoni et al.

Published

2021

21. Strengthened splitting methods for computing resolvents

Author

Francisco J. Aragón Artacho, Rubén Campoy, Matthew K. Tam, Universidad de Alicante. Departamento de Matemáticas, and Laboratorio de Optimización (LOPT)

Subjects

Splitting algorithm, Control and Optimization, 0211 other engineering and technologies, 47H05, 90C30, 65K05, Elliptic pdes, Monotonic function, 02 engineering and technology, 01 natural sciences, Monotone operator, Operator (computer programming), Development (topology), Estadística e Investigación Operativa, FOS: Mathematics, 0101 mathematics, Image denoising, Resolvent, Mathematics - Optimization and Control, Mathematics, 021103 operations research, Applied Mathematics, 010102 general mathematics, Algebra, Computational Mathematics, Monotone polygon, Optimization and Control (math.OC), Strengthening, Key (cryptography)

Abstract

In this work, we develop a systematic framework for computing the resolvent of the sum of two or more monotone operators which only activates each operator in the sum individually. The key tool in the development of this framework is the notion of the “strengthening” of a set-valued operator, which can be viewed as a type of regularisation that preserves computational tractability. After deriving a number of iterative schemes through this framework, we demonstrate their application to best approximation problems, image denoising and elliptic PDEs. FJAA and RC were partially supported by the Ministry of Science, Innovation and Universities of Spain and the European Regional Development Fund (ERDF) of the European Commission, Grant PGC2018-097960-B-C22. MKT is supported in part by ARC grant DE200100063.

Published

2021

22. Differentiability results and sensitivity calculation for optimal control of incompressible two-phase Navier-Stokes equations with surface tension

Author

Elisabeth Diehl, Johannes Haubner, Michael Ulbrich, and Stefan Ulbrich

Subjects

Computational Mathematics, Mathematics - Analysis of PDEs, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, Mathematics - Optimization and Control, 49K20, 49J50, 35R35, Analysis of PDEs (math.AP)

Abstract

We analyze optimal control problems for two-phase Navier-Stokes equations with surface tension. Based on $$L_p$$ L p -maximal regularity of the underlying linear problem and recent well-posedness results of the problem for sufficiently small data we show the differentiability of the solution with respect to initial and distributed controls for appropriate spaces resulting from the $$L_p$$ L p -maximal regularity setting. We consider first a formulation where the interface is transformed to a hyperplane. Then we deduce differentiability results for the solution in the physical coordinates. Finally, we state an equivalent Volume-of-Fluid type formulation and use the obtained differentiability results to derive rigorosly the corresponding sensitivity equations of the Volume-of-Fluid type formulation. For objective functionals involving the velocity field or the discontinuous pressure or phase indciator field we derive differentiability results with respect to controls and state formulas for the derivative. The results of the paper form an analytical foundation for stating optimality conditions, justifying the application of derivative based optimization methods and for studying the convergence of discrete sensitivity schemes based on Volume-of-Fluid discretizations for optimal control of two-phase Navier-Stokes equations.

Published

2022

23. Distributed forward-backward methods for ring networks

Author

Francisco J. Aragón-Artacho, Yura Malitsky, Matthew K. Tam, David Torregrosa-Belén, Universidad de Alicante. Departamento de Matemáticas, and Laboratorio de Optimización (LOPT)

Subjects

FOS: Computer and information sciences, Splitting algorithm, Control and Optimization, Computer Sciences, Applied Mathematics, Monotone operator, Monotone inclusion, Forward-backward algorithm, Distributed optimisation, Computational Mathematics, Datavetenskap (datalogi), Computer Science - Distributed, Parallel, and Cluster Computing, Optimization and Control (math.OC), FOS: Mathematics, Distributed, Parallel, and Cluster Computing (cs.DC), Mathematics - Optimization and Control

Abstract

In this work, we propose and analyse forward-backward-type algorithms for finding a zero of the sum of finitely many monotone operators, which are not based on reduction to a two operator inclusion in the product space. Each iteration of the studied algorithms requires one resolvent evaluation per set-valued operator, one forward evaluation per cocoercive operator, and two forward evaluations per monotone operator. Unlike existing methods, the structure of the proposed algorithms are suitable for distributed, decentralised implementation in ring networks without needing global summation to enforce consensus between nodes., Comment: 19 pages

Published

2022

24. Computing mixed strategies equilibria in presence of switching costs by the solution of nonconvex QP problems

Author

Giampaolo Liuzzi, Veronica Piccialli, Stefan Rass, and Marco Locatelli

Subjects

Mathematical optimization, Control and Optimization, 0211 other engineering and technologies, Polytope, Context (language use), [object Object], 02 engineering and technology, Bound-tightening, Branch-and-bound, Game theory, Nonconvex quadratic programming problems, Game Theory, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Mathematics - Optimization and Control, Mathematics, 021103 operations research, Bound-Tightening, Applied Mathematics, Node (networking), Branch-and-Bound, Stochastic game, Nonconvex Quadratic Programming Problems, Computational Mathematics, Tree (data structure), Optimization and Control (math.OC), Benchmark (computing), 020201 artificial intelligence & image processing, Minification

Abstract

In this paper we address game theory problems arising in the context of network security. In traditional game theory problems, given a defender and an attacker, one searches for mixed strategies which minimize a linear payoff functional. In the problems addressed in this paper an additional quadratic term is added to the minimization problem. Such term represents switching costs, i.e., the costs for the defender of switching from a given strategy to another one at successive rounds of a Nash game. The resulting problems are nonconvex QP ones with linear constraints and turn out to be very challenging. We will show that the most recent approaches for the minimization of nonconvex QP functions over polytopes, including commercial solvers such as and , are unable to solve to optimality even test instances with $$n=50$$ n = 50 variables. For this reason, we propose to extend with them the current benchmark set of test instances for QP problems. We also present a spatial branch-and-bound approach for the solution of these problems, where a predominant role is played by an optimality-based domain reduction, with multiple solutions of LP problems at each node of the branch-and-bound tree. Of course, domain reductions are standard tools in spatial branch-and-bound approaches. However, our contribution lies in the observation that, from the computational point of view, a rather aggressive application of these tools appears to be the best way to tackle the proposed instances. Indeed, according to our experiments, while they make the computational cost per node high, this is largely compensated by the rather slow growth of the number of nodes in the branch-and-bound tree, so that the proposed approach strongly outperforms the existing solvers for QP problems.

Published

2021

25. Exact linesearch limited-memory quasi-Newton methods for minimizing a quadratic function

Author

Anders Forsgren and David Ek

Subjects

Hessian matrix, 021103 operations research, Control and Optimization, Applied Mathematics, MathematicsofComputing_NUMERICALANALYSIS, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Positive-definite matrix, Quadratic function, System of linear equations, 01 natural sciences, Computational Mathematics, symbols.namesake, Optimization and Control (math.OC), Broyden–Fletcher–Goldfarb–Shanno algorithm, FOS: Mathematics, symbols, Applied mathematics, Quadratic programming, 0101 mathematics, Focus (optics), Representation (mathematics), Mathematics - Optimization and Control, Mathematics

Abstract

The main focus in this paper is exact linesearch methods for minimizing a quadratic function whose Hessian is positive definite. We give a class of limited-memory quasi-Newton Hessian approximations which generate search directions parallel to those of the BFGS method, or equivalently, to those of the method of preconditioned conjugate gradients. In the setting of reduced Hessians, the class provides a dynamical framework for the construction of limited-memory quasi-Newton methods. These methods attain finite termination on quadratic optimization problems in exact arithmetic. We show performance of the methods within this framework in finite precision arithmetic by numerical simulations on sequences of related systems of linear equations, which originate from the CUTEst test collection. In addition, we give a compact representation of the Hessian approximations in the full Broyden class for the general unconstrained optimization problem. This representation consists of explicit matrices and gradients only as vector components.

Published

2021

26. A Laplacian approach to $$\ell _1$$-norm minimization

Author

Vincenzo Bonifaci and Bonifaci, Vincenzo

Subjects

FOS: Computer and information sciences, Control and Optimization, Basis pursuit, 010103 numerical & computational mathematics, 02 engineering and technology, Type (model theory), 01 natural sciences, 90C25, Iteratively reweighted least squares, Computer Science - Data Structures and Algorithms, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Applied mathematics, Data Structures and Algorithms (cs.DS), Differentiable function, 0101 mathematics, Mathematics - Optimization and Control, Mathematics, Applied Mathematics, Multiplicative function, 020206 networking & telecommunications, ℓ1 regression, basis pursuit, iteratively reweighted least squares, multiplicative weights, laplacian paradigm, convex optimization, Computational Mathematics, Optimization and Control (math.OC), Convex optimization, Minification, Laplace operator

Abstract

We propose a novel differentiable reformulation of the linearly-constrained $$\ell _1$$ ℓ 1 minimization problem, also known as the basis pursuit problem. The reformulation is inspired by the Laplacian paradigm of network theory and leads to a new family of gradient-based methods for the solution of $$\ell _1$$ ℓ 1 minimization problems. We analyze the iteration complexity of a natural solution approach to the reformulation, based on a multiplicative weights update scheme, as well as the iteration complexity of an accelerated gradient scheme. The results can be seen as bounds on the complexity of iteratively reweighted least squares (IRLS) type methods of basis pursuit.

Published

2021

27. Approximate solution of system of equations arising in interior-point methods for bound-constrained optimization

Author

Anders Forsgren and David Ek

Subjects

Control and Optimization, Applied Mathematics, Constrained optimization, System of linear equations, Nonlinear programming, Computational Mathematics, Nonlinear system, Quality (physics), Optimization and Control (math.OC), FOS: Mathematics, Applied mathematics, Focus (optics), Heuristics, Mathematics - Optimization and Control, Interior point method, Mathematics

Abstract

The focus in this paper is interior-point methods for bound-constrained nonlinear optimization, where the system of nonlinear equations that arise are solved with Newton’s method. There is a trade-off between solving Newton systems directly, which give high quality solutions, and solving many approximate Newton systems which are computationally less expensive but give lower quality solutions. We propose partial and full approximate solutions to the Newton systems. The specific approximate solution depends on estimates of the active and inactive constraints at the solution. These sets are at each iteration estimated by basic heuristics. The partial approximate solutions are computationally inexpensive, whereas a system of linear equations needs to be solved for the full approximate solution. The size of the system is determined by the estimate of the inactive constraints at the solution. In addition, we motivate and suggest two Newton-like approaches which are based on an intermediate step that consists of the partial approximate solutions. The theoretical setting is introduced and asymptotic error bounds are given. We also give numerical results to investigate the performance of the approximate solutions within and beyond the theoretical framework.

Published

2021

28. Theoretical and numerical comparison of the Karush–Kuhn–Tucker and value function reformulations in bilevel optimization

Author

Shenglong Zhou and Alain B. Zemkoho

Subjects

Mathematical optimization, Class (set theory), 021103 operations research, Control and Optimization, Optimization problem, Karush–Kuhn–Tucker conditions, Applied Mathematics, Mathematics::Optimization and Control, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Bilevel optimization, Computational Mathematics, symbols.namesake, Optimization and Control (math.OC), Bellman equation, FOS: Mathematics, symbols, Point (geometry), 0101 mathematics, Mathematics - Optimization and Control, Newton's method, Mathematics

Abstract

The Karush-Kuhn-Tucker and value function (lower-level value function, to be precise) reformulations are the most common single-level transformations of the bilevel optimization problem. So far, these reformulations have either been studied independently or as a joint optimization problem in an attempt to take advantage of the best properties from each model. To the best of our knowledge, these reformulations have not yet been compared in the existing literature. This paper is a first attempt towards establishing whether one of these reformulations is best at solving a given class of the optimistic bilevel optimization problem. We design a comparison framework, which seems fair, considering the theoretical properties of these reformulations. This work reveals that although none of the models seems to particularly dominate the other from the theoretical point of view, the value function reformulation seems to numerically outperform the Karush-Kuhn-Tucker reformulation on a Newton-type algorithm. The computational experiments here are mostly based on test problems from the Bilevel Optimization LIBrary (BOLIB)., 33 pages, 4 figures

Published

2021

29. Tractable ADMM schemes for computing KKT points and local minimizers for $$\ell _0$$-minimization problems

Author

Uday V. Shanbhag and Yue Xie

Subjects

Subsequential limit, Control and Optimization, Karush–Kuhn–Tucker conditions, G.1.6, Computation, Mathematics::Optimization and Control, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Convexity, Statistics::Machine Learning, 90C26, 90C30, 90C33, 90C46, FOS: Mathematics, 0101 mathematics, Mathematics - Optimization and Control, Mathematics, Discrete mathematics, 021103 operations research, Statistical learning, Applied Mathematics, Regular polygon, Computational Mathematics, Optimization and Control (math.OC), Computer Science::Computer Vision and Pattern Recognition, Norm (mathematics), F.2.1, Minification

Abstract

We consider an $\ell_0$-minimization problem where $f(x) + \gamma \|x\|_0$ is minimized over a polyhedral set and the $\ell_0$-norm regularizer implicitly emphasizes sparsity of the solution. Such a setting captures a range of problems in image processing and statistical learning. Given the nonconvex and discontinuous nature of this norm, convex regularizers are often employed as substitutes. Therefore, far less is known about directly solving the $\ell_0$-minimization problem. Inspired by [19], we consider resolving an equivalent formulation of the $\ell_0$-minimization problem as a mathematical program with complementarity constraints (MPCC) and make the following contributions towards the characterization and computation of its KKT points: (i) First, we show that feasible points of this formulation satisfy the relatively weak Guignard constraint qualification. Furthermore, under the suitable convexity assumption on $f(x)$, an equivalence is derived between first-order KKT points and local minimizers of the MPCC formulation. (ii) Next, we apply two alternating direction method of multiplier (ADMM) algorithms to exploit special structure of the MPCC formulation: (ADMM$_{\rm cf}^{\mu, \alpha, \rho}$) and (ADMM$_{\rm cf}$). These two ADMM schemes both have tractable subproblems. Specifically, in spite of the overall nonconvexity, we show that the first of the ADMM updates can be effectively reduced to a closed-form expression by recognizing a hidden convexity property while the second necessitates solving a convex program. In (ADMM$_{\rm cf}^{\mu, \alpha, \rho}$), we prove subsequential convergence to a perturbed KKT point under mild assumptions. Our preliminary numerical experiments suggest that the tractable ADMM schemes are more scalable than their standard counterpart and ADMM$_{\rm cf}$ compares well with its competitors to solve the $\ell_0$-minimization problem., Comment: 47 pages, 3 tables

Published

2020

30. Hybrid Riemannian conjugate gradient methods with global convergence properties

Author

Hiroyuki Sakai and Hideaki Iiduka

Subjects

Riemannian optimization, 021103 operations research, Control and Optimization, Euclidean space, Applied Mathematics, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Wolfe conditions, Python (programming language), 01 natural sciences, 65K05, 90C26, 57R35, Computational Mathematics, Optimization and Control (math.OC), Conjugate gradient method, FOS: Mathematics, Applied mathematics, 0101 mathematics, Mathematics - Optimization and Control, computer, Mathematics, computer.programming_language

Abstract

This paper presents new Riemannian conjugate gradient methods and global convergence analyses under the strong Wolfe conditions. The main idea of the new methods is to combine the good global convergence properties of the Dai-Yuan method with the efficient numerical performance of the Hestenes-Stiefel method. The proposed methods compare well numerically with the existing methods for the Rayleigh quotient minimization problem on the unit sphere. Numerical comparisons show that they perform better than the existing ones., Comment: 17 pages, 2 figures and 2 tables

Published

2020

31. Inverse point source location with the Helmholtz equation on a bounded domain

Author

Konstantin Pieper, Philip Trautmann, Bao Quoc Tang, and Daniel Walter

Subjects

021103 operations research, Control and Optimization, Optimization problem, Discretization, Helmholtz equation, Applied Mathematics, Mathematical analysis, 0211 other engineering and technologies, Inverse, 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Finite element method, Computational Mathematics, Frank–Wolfe algorithm, Optimization and Control (math.OC), Bounded function, Norm (mathematics), FOS: Mathematics, 35R30 (Primary) 35Q93, 49J20, 90C46 (Secondary), 0101 mathematics, Mathematics - Optimization and Control, Mathematics

Abstract

The problem of recovering acoustic sources, more specifically monopoles, from point-wise measurements of the corresponding acoustic pressure at a limited number of frequencies is addressed. To this purpose, a family of sparse optimization problems in measure space in combination with the Helmholtz equation on a bounded domain is considered. A weighted norm with unbounded weight near the observation points is incorporated into the formulation. Optimality conditions and conditions for recovery in the small noise case are discussed, which motivates concrete choices of the weight. The numerical realization is based on an accelerated conditional gradient method in measure space and a finite element discretization.

Published

2020

32. Feasibility and a fast algorithm for Euclidean distance matrix optimization with ordinal constraints

Author

Si-Tong Lu, Qingna Li, and Miao Zhang

Subjects

Mathematical optimization, 021103 operations research, Control and Optimization, Rank (linear algebra), Applied Mathematics, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Positive-definite matrix, Euclidean distance matrix, 01 natural sciences, Constraint (information theory), Computational Mathematics, Matrix (mathematics), Optimization and Control (math.OC), FOS: Mathematics, Isotonic regression, Multidimensional scaling, 0101 mathematics, Majorization, Mathematics - Optimization and Control, Mathematics

Abstract

Euclidean distance matrix optimization with ordinal constraints (EDMOC) has found important applications in sensor network localization and molecular conformation. It can also be viewed as a matrix formulation of multidimensional scaling, which is to embed n points in a $r$-dimensional space such that the resulting distances follow the ordinal constraints. The ordinal constraints, though proved to be quite useful, may result in only zero solution when too many are added, leaving the feasibility of EDMOC as a question. In this paper, we first study the feasibility of EDMOC systematically. We show that if $r\ge n-2$, EDMOC always admits a nontrivial solution. Otherwise, it may have only zero solution. The latter interprets the numerical observations of 'crowding phenomenon'. Next we overcome two obstacles in designing fast algorithms for EDMOC, i.e., the low-rankness and the potential huge number of ordinal constraints. We apply the technique developed to take the low rank constraint as the conditional positive semidefinite cone with rank cut. This leads to a majorization penalty approach. The ordinal constraints are left to the subproblem, which is exactly the weighted isotonic regression, and can be solved by the enhanced implementation of Pool Adjacent Violators Algorithm (PAVA). Extensive numerical results demonstrate {the} superior performance of the proposed approach over some state-of-the-art solvers., 32 pages, 23 figures

Published

2020

33. A derivative-free optimization algorithm for the efficient minimization of functions obtained via statistical averaging

Author

Pooriya Beyhaghi, Thomas Bewley, and Ryan Alimo

Subjects

021103 operations research, Control and Optimization, Delaunay triangulation, Applied Mathematics, 0211 other engineering and technologies, Sampling (statistics), 010103 numerical & computational mathematics, 02 engineering and technology, Function (mathematics), Stationary ergodic process, 01 natural sciences, Computational Mathematics, Alpha (programming language), Optimization and Control (math.OC), Convergence (routing), Derivative-free optimization, FOS: Mathematics, Minification, 0101 mathematics, Mathematics - Optimization and Control, Algorithm, Mathematics

Abstract

This paper considers the efficient minimization of the infinite time average of a stationary ergodic process in the space of a handful of design parameters which affect it. Problems of this class, derived from physical or numerical experiments which are sometimes expensive to perform, are ubiquitous in engineering applications. In such problems, any given function evaluation, determined with finite sampling, is associated with a quantifiable amount of uncertainty, which may be reduced via additional sampling. The present paper proposes a new optimization algorithm to adjust the amount of sampling associated with each function evaluation, making function evaluations more accurate (and, thus, more expensive), as required, as convergence is approached. The work builds on our algorithm for Delaunay-based Derivative-free Optimization via Global Surrogates ($\Delta$-DOGS). The new algorithm, dubbed $\alpha$-DOGS, substantially reduces the overall cost of the optimization process for problems of this important class. Further, under certain well-defined conditions, rigorous proof of convergence to the global minimum of the problem considered is established., Comment: Submitted to Journal of Computational Optimization and Applications

Published

2020

34. Markov chain block coordinate descent

Author

Yuejiao Sun, Wotao Yin, Yangyang Xu, and Tao Sun

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Mathematical optimization, Control and Optimization, 0211 other engineering and technologies, Machine Learning (stat.ML), 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Machine Learning (cs.LG), symbols.namesake, Statistics - Machine Learning, FOS: Mathematics, 0101 mathematics, Coordinate descent, Mathematics - Optimization and Control, Mathematics, 021103 operations research, Markov chain, Applied Mathematics, Markov chain Monte Carlo, Lipschitz continuity, Computational Mathematics, Rate of convergence, Optimization and Control (math.OC), symbols, Markov decision process, Gradient descent, Convex function

Abstract

The method of block coordinate gradient descent (BCD) has been a powerful method for large-scale optimization. This paper considers the BCD method that successively updates a series of blocks selected according to a Markov chain. This kind of block selection is neither i.i.d. random nor cyclic. On the other hand, it is a natural choice for some applications in distributed optimization and Markov decision process, where i.i.d. random and cyclic selections are either infeasible or very expensive. By applying mixing-time properties of a Markov chain, we prove convergence of Markov chain BCD for minimizing Lipschitz differentiable functions, which can be nonconvex. When the functions are convex and strongly convex, we establish both sublinear and linear convergence rates, respectively. We also present a method of Markov chain inertial BCD. Finally, we discuss potential applications.

Published

2019

35. A conjugate gradient-based algorithm for large-scale quadratic programming problem with one quadratic constraint

Author

Akram Taati and Maziar Salahi

Subjects

Quadratic growth, 021103 operations research, Control and Optimization, Applied Mathematics, MathematicsofComputing_NUMERICALANALYSIS, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Positive-definite matrix, 90C20, 90C26, System of linear equations, 01 natural sciences, Constraint (information theory), Computational Mathematics, Quadratic equation, Optimization and Control (math.OC), Conjugate gradient method, FOS: Mathematics, Quadratic programming, 0101 mathematics, Mathematics - Optimization and Control, Algorithm, Eigenvalues and eigenvectors, Mathematics

Abstract

In this paper, we consider the nonconvex quadratically constrained quadratic programming (QCQP) with one quadratic constraint. By employing the conjugate gradient method, an efficient algorithm is proposed to solve QCQP that exploits the sparsity of the involved matrices and solves the problem via solving a sequence of positive definite system of linear equations after identifying suitable generalized eigenvalues. Specifically, we analyze how to recognize hard case (case 2) in a preprocessing step, fixing an error in Sect. 2.2.2 of Pong and Wolkowicz (Comput Optim Appl 58(2):273–322, 2014) which studies the same problem with the two-sided constraint. Some numerical experiments are given to show the effectiveness of the proposed method and to compare it with some recent algorithms in the literature.

Published

2019

36. A family of spectral gradient methods for optimization

Author

Yakui Huang, Xin-Wei Liu, and Yu-Hong Dai

Subjects

021103 operations research, Control and Optimization, Property (philosophy), Applied Mathematics, Spectral gradient method, Mathematics::Optimization and Control, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Unconstrained optimization, 01 natural sciences, Least squares, 90C20, 90C25, 90C30, Computational Mathematics, Optimization and Control (math.OC), FOS: Mathematics, Method of steepest descent, Applied mathematics, Convex combination, 0101 mathematics, Convex function, Mathematics - Optimization and Control, Mathematics

Abstract

We propose a family of spectral gradient methods, whose stepsize is determined by a convex combination of the long Barzilai-Borwein (BB) stepsize and the short BB stepsize. Each member of the family is shown to share certain quasi-Newton property in the sense of least squares. The family also includes some other gradient methods as its special cases. We prove that the family of methods is $R$-superlinearly convergent for two-dimensional strictly convex quadratics. Moreover, the family is $R$-linearly convergent in the any-dimensional case. Numerical results of the family with different settings are presented, which demonstrate that the proposed family is promising., 22 pages, 2figures

Published

2019

37. Iterative regularization for constrained minimization formulations of nonlinear inverse problems

Author

Barbara Kaltenbacher and Kha Van Huynh

Subjects

010101 applied mathematics, Computational Mathematics, Control and Optimization, Optimization and Control (math.OC), Applied Mathematics, FOS: Mathematics, 010103 numerical & computational mathematics, Numerical Analysis (math.NA), Mathematics - Numerical Analysis, 0101 mathematics, 01 natural sciences, Mathematics - Optimization and Control

Abstract

In this paper we study the formulation of inverse problems as constrained minimization problems and their iterative solution by gradient or Newton type methods. We carry out a convergence analysis in the sense of regularization methods and discuss applicability to the problem of identifying the spatially varying diffusivity in an elliptic PDE from different sets of observations. Among these is a novel hybrid imaging technology known as impedance acoustic tomography, for which we provide numerical experiments.

Published

2021

38. Multi-block Bregman proximal alternating linearized minimization and its application to orthogonal nonnegative matrix factorization

Author

Nicolas Gillis, Masoud Ahookhosh, Panagiotis Patrinos, and Le Thi Khanh Hien

Subjects

021103 operations research, Control and Optimization, Economics, Applied Mathematics, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Numerical Analysis (math.NA), Bregman divergence, 01 natural sciences, Non-negative matrix factorization, Separable space, Computational Mathematics, Rate of convergence, Optimization and Control (math.OC), FOS: Mathematics, Applied mathematics, Mathematics - Numerical Analysis, Minification, 0101 mathematics, Mathematics - Optimization and Control, Mathematics, Block (data storage)

Abstract

We introduce and analyze BPALM and A-BPALM, two multi-block proximal alternating linearized minimization algorithms using Bregman distances for solving structured nonconvex problems. The objective function is the sum of a multi-block relatively smooth function (i.e., relatively smooth by fixing all the blocks except one) and block separable (nonsmooth) nonconvex functions. It turns out that the sequences generated by our algorithms are subsequentially convergent to critical points of the objective function, while they are globally convergent under KL inequality assumption. Further, the rate of convergence is further analyzed for functions satisfying the {\L}ojasiewicz's gradient inequality. We apply this framework to orthogonal nonnegative matrix factorization (ONMF) that satisfies all of our assumptions and the related subproblems are solved in closed forms, where some preliminary numerical results is reported.

Published

2021

39. Asynchronous parallel primal–dual block coordinate update methods for affinely constrained convex programs

Author

Yangyang Xu

Subjects

FOS: Computer and information sciences, Mathematical optimization, Control and Optimization, Computer science, 0211 other engineering and technologies, Machine Learning (stat.ML), 90C06, 90C25, 68W40, 49M27, 010103 numerical & computational mathematics, 02 engineering and technology, Adaptive stepsize, Residual, 01 natural sciences, Convexity, Statistics - Machine Learning, FOS: Mathematics, Mathematics - Numerical Analysis, 0101 mathematics, Mathematics - Optimization and Control, Block (data storage), Sequence, 021103 operations research, Applied Mathematics, Regular polygon, Numerical Analysis (math.NA), Constraint (information theory), Computational Mathematics, Computer Science - Distributed, Parallel, and Cluster Computing, Optimization and Control (math.OC), Asynchronous communication, Distributed, Parallel, and Cluster Computing (cs.DC)

Abstract

Recent several years have witnessed the surge of asynchronous (async-) parallel computing methods due to the extremely big data involved in many modern applications and also the advancement of multi-core machines and computer clusters. In optimization, most works about async-parallel methods are on unconstrained problems or those with block separable constraints. In this paper, we propose an async-parallel method based on block coordinate update (BCU) for solving convex problems with nonseparable linear constraint. Running on a single node, the method becomes a novel randomized primal-dual BCU with adaptive stepsize for multi-block affinely constrained problems. For these problems, Gauss-Seidel cyclic primal-dual BCU needs strong convexity to have convergence. On the contrary, merely assuming convexity, we show that the objective value sequence generated by the proposed algorithm converges in probability to the optimal value and also the constraint residual to zero. In addition, we establish an ergodic $O(1/k)$ convergence result, where $k$ is the number of iterations. Numerical experiments are performed to demonstrate the efficiency of the proposed method and significantly better speed-up performance than its sync-parallel counterpart.

Published

2018

40. Duality of nonconvex optimization with positively homogeneous functions

Author

Nobuo Yamashita and Shota Yamanaka

Subjects

021103 operations research, Control and Optimization, Optimization problem, Applied Mathematics, 0211 other engineering and technologies, Regular polygon, Homogeneous function, Duality (optimization), 020206 networking & telecommunications, Absolute value, 02 engineering and technology, Computational Mathematics, symbols.namesake, Optimization and Control (math.OC), Homogeneous, Constraint functions, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, symbols, Applied mathematics, Mathematics - Optimization and Control, Mathematics, Real number

Abstract

We consider an optimization problem with positively homogeneous functions in its objective and constraint functions. Examples of such positively homogeneous functions include the absolute value function and the $p$-norm function, where $p$ is a positive real number. The problem, which is not necessarily convex, extends the absolute value optimization proposed in [O. L. Mangasarian, Absolute value programming, Computational Optimization and Applications 36 (2007) pp. 43-53]. In this work, we propose a dual formulation that, differently from the Lagrangian dual approach, has a closed-form and some interesting properties. In particular, we discuss the relation between the Lagrangian duality and the one proposed here, and give some sufficient conditions under which these dual problems coincide. Finally, we show that some well-known problems, e.g., sum of norms optimization and the group Lasso-type optimization problems, can be reformulated as positively homogeneous optimization problems., 21 pages

Published

2018

41. Robust truss topology optimization via semidefinite programming with complementarity constraints: a difference-of-convex programming approach

Author

Yoshihiro Kanno

Subjects

Semidefinite programming, Mathematical optimization, 021103 operations research, Control and Optimization, Computer science, Applied Mathematics, 0211 other engineering and technologies, Truss, 02 engineering and technology, 01 natural sciences, Complementarity (physics), Global optimal, 010101 applied mathematics, Computational Mathematics, Optimization and Control (math.OC), Convex optimization, FOS: Mathematics, 0101 mathematics, Mathematics - Optimization and Control, Truss topology optimization

Abstract

The robust truss topology optimization against the uncertain static external load can be formulated as mixed-integer semidefinite programming. Although a global optimal solution can be computed with a branch-and-bound method, it is very time-consuming. This paper presents an alternative formulation, semidefinite programming with complementarity constraints, and proposes an efficient heuristic. The proposed method is based upon the convex-concave procedure for DC (difference-of-convex) programming. It is shown that the method can often find a practically reasonable truss design within the computational cost of solving some dozen of convex optimization subproblems.

Published

2018

42. A penalty method for rank minimization problems in symmetric matrices

Author

John E. Mitchell and Xin Shen

Subjects

Mathematical optimization, 021103 operations research, Control and Optimization, Karush–Kuhn–Tucker conditions, Rank (linear algebra), Applied Mathematics, Mathematics::Optimization and Control, 0211 other engineering and technologies, 010103 numerical & computational mathematics, 02 engineering and technology, Positive-definite matrix, 90C33, 90C53, 01 natural sciences, Computational Mathematics, Optimization and Control (math.OC), FOS: Mathematics, Symmetric matrix, Point (geometry), Penalty method, Minification, 0101 mathematics, Mathematics - Optimization and Control, Calmness, Mathematics

Abstract

The problem of minimizing the rank of a symmetric positive semidefinite matrix subject to constraints can be cast equivalently as a semidefinite program with complementarity constraints (SDCMPCC). The formulation requires two positive semidefinite matrices to be complementary. This is a continuous and nonconvex reformulation of the rank minimization problem. We investigate calmness of locally optimal solutions to the SDCMPCC formulation and hence show that any locally optimal solution is a KKT point. We develop a penalty formulation of the problem. We present calmness results for locally optimal solutions to the penalty formulation. We also develop a proximal alternating linearized minimization (PALM) scheme for the penalty formulation, and investigate the incorporation of a momentum term into the algorithm. Computational results are presented.

Published

2018

43. A flexible coordinate descent method

Author

Kimon Fountoulakis and Rachael Tappenden

Subjects

021103 operations research, Control and Optimization, Line search, Applied Mathematics, 0211 other engineering and technologies, Regular polygon, Monotonic function, 010103 numerical & computational mathematics, 02 engineering and technology, Curvature, 01 natural sciences, Computational Mathematics, Optimization and Control (math.OC), Convergence (routing), FOS: Mathematics, Minification, 0101 mathematics, Coordinate descent, Mathematics - Optimization and Control, Algorithm, Mathematics, Block (data storage)

Abstract

We present a novel randomized block coordinate descent method for the minimization of a convex composite objective function. The method uses (approximate) partial second-order (curvature) information, so that the algorithm performance is more robust when applied to highly nonseparable or ill conditioned problems. We call the method Flexible Coordinate Descent (FCD). At each iteration of FCD, a block of coordinates is sampled randomly, a quadratic model is formed about that block and the model is minimized \emph{approximately/inexactly} to determine the search direction. An inexpensive line search is then employed to ensure a monotonic decrease in the objective function and acceptance of large step sizes. We present several high probability iteration complexity results to show that convergence of FCD is guaranteed theoretically. Finally, we present numerical results on large-scale problems to demonstrate the practical performance of the method., Comment: 31 pages, 24 figures

Published

2018

44. Convergence of a Scholtes-type regularization method for cardinality-constrained optimization problems with an application in sparse robust portfolio optimization

Author

Michal Červinka, Max Bucher, Martin Branda, and Alexandra Schwartz

Subjects

Continuous optimization, Mathematical optimization, 021103 operations research, Control and Optimization, Karush–Kuhn–Tucker conditions, Optimization problem, Applied Mathematics, 0211 other engineering and technologies, Robust optimization, 010103 numerical & computational mathematics, 02 engineering and technology, Solver, 01 natural sciences, Nonlinear programming, Computational Mathematics, Vector optimization, Optimization and Control (math.OC), FOS: Mathematics, 0101 mathematics, Portfolio optimization, Mathematics - Optimization and Control, Mathematics

Abstract

We consider general nonlinear programming problems with cardinality constraints. By relaxing the binary variables which appear in the natural mixed-integer programming formulation, we obtain an almost equivalent nonlinear programming problem, which is thus still difficult to solve. Therefore, we apply a Scholtes-type regularization method to obtain a sequence of easier to solve problems and investigate the convergence of the obtained KKT points. We show that such a sequence converges to an S-stationary point, which corresponds to a local minimizer of the original problem under the assumption of convexity. Additionally, we consider portfolio optimization problems where we minimize a risk measure under a cardinality constraint on the portfolio. Various risk measures are considered, in particular Value-at-Risk and Conditional Value-at-Risk under normal distribution of returns and their robust counterparts under moment conditions. For these investment problems formulated as nonlinear programming problems with cardinality constraints we perform a numerical study on a large number of simulated instances taken from the literature and illuminate the computational performance of the Scholtes-type regularization method in comparison to other considered solution approaches: a mixed-integer solver, a direct continuous reformulation solver and the Kanzow-Schwartz regularization method, which has already been applied to Markowitz portfolio problems., 23 pages, 4 figures

Published

2018

45. A copositive approach for two-stage adjustable robust optimization with uncertain right-hand sides

Author

Guanglin Xu and Samuel Burer

Subjects

Semidefinite programming, 0209 industrial biotechnology, 021103 operations research, Control and Optimization, Optimization problem, Linear programming, Applied Mathematics, 0211 other engineering and technologies, Regular polygon, Robust optimization, 02 engineering and technology, Computational Mathematics, Arbitrarily large, 020901 industrial engineering & automation, Optimization and Control (math.OC), FOS: Mathematics, Applied mathematics, Affine transformation, Mathematics - Optimization and Control, Time complexity, Mathematics

Abstract

We study two-stage adjustable robust linear programming in which the right-hand sides are uncertain and belong to a convex, compact uncertainty set. This problem is NP-hard, and the affine policy is a popular, tractable approximation. We prove that under standard and simple conditions, the two-stage problem can be reformulated as a copositive optimization problem, which in turn leads to a class of tractable, semidefinite-based approximations that are at least as strong as the affine policy. We investigate several examples from the literature demonstrating that our tractable approximations significantly improve the affine policy. In particular, our approach solves exactly in polynomial time a class of instances of increasing size for which the affine policy admits an arbitrarily large gap., Comment: 30 pages and 2 tables

Published

2017

46. Accelerated primal–dual proximal block coordinate updating methods for constrained convex optimization

Author

Yangyang Xu and Shuzhong Zhang

Subjects

FOS: Computer and information sciences, Mathematical optimization, Control and Optimization, Computational complexity theory, 0211 other engineering and technologies, Machine Learning (stat.ML), 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Convexity, 90C25, 95C06, 68W20, Statistics - Machine Learning, Convergence (routing), FOS: Mathematics, 0101 mathematics, Mathematics - Optimization and Control, Mathematics, Variable (mathematics), Block (data storage), 021103 operations research, Applied Mathematics, Computer Science - Numerical Analysis, Numerical Analysis (math.NA), Computational Mathematics, Rate of convergence, Optimization and Control (math.OC), Convex optimization, Convex function

Abstract

Block Coordinate Update (BCU) methods enjoy low per-update computational complexity because every time only one or a few block variables would need to be updated among possibly a large number of blocks. They are also easily parallelized and thus have been particularly popular for solving problems involving large-scale dataset and/or variables. In this paper, we propose a primal-dual BCU method for solving linearly constrained convex program in multi-block variables. The method is an accelerated version of a primal-dual algorithm proposed by the authors, which applies randomization in selecting block variables to update and establishes an $O(1/t)$ convergence rate under weak convexity assumption. We show that the rate can be accelerated to $O(1/t^2)$ if the objective is strongly convex. In addition, if one block variable is independent of the others in the objective, we then show that the algorithm can be modified to achieve a linear rate of convergence. The numerical experiments show that the accelerated method performs stably with a single set of parameters while the original method needs to tune the parameters for different datasets in order to achieve a comparable level of performance., Accepted to Computational Optimization and Applications

Published

2017

47. Proximal quasi-Newton methods for regularized convex optimization with linear and accelerated sublinear convergence rates

Author

Hiva Ghanbari and Katya Scheinberg

Subjects

FOS: Computer and information sciences, Hessian matrix, Control and Optimization, Sublinear function, 0211 other engineering and technologies, Machine Learning (stat.ML), Acceleration (differential geometry), 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Machine Learning (cs.LG), symbols.namesake, Statistics - Machine Learning, Simple (abstract algebra), Convergence (routing), FOS: Mathematics, Applied mathematics, 0101 mathematics, Mathematics - Optimization and Control, Mathematics, 021103 operations research, Applied Mathematics, Computer Science - Numerical Analysis, Numerical Analysis (math.NA), Computer Science - Learning, Computational Mathematics, Rate of convergence, Optimization and Control (math.OC), Convex optimization, symbols, Convex function

Abstract

A general, inexact, efficient proximal quasi-Newton algorithm for composite optimization problems has been proposed by Scheinberg and Tang (Math Program 160:495–529, 2016) and a sublinear global convergence rate has been established. In this paper, we analyze the global convergence rate of this method, in the both exact and inexact settings, in the case when the objective function is strongly convex. We also investigate a practical variant of this method by establishing a simple stopping criterion for the subproblem optimization. Furthermore, we consider an accelerated variant, based on FISTA of Beck and Teboulle (SIAM 2:183–202, 2009), to the proximal quasi-Newton algorithm. Jiang et al. (SIAM 22:1042–1064, 2012) considered a similar accelerated method, where the convergence rate analysis relies on very strong impractical assumptions on Hessian estimates. We present a modified analysis while relaxing these assumptions and perform a numerical comparison of the accelerated proximal quasi-Newton algorithm and the regular one. Our analysis and computational results show that acceleration may not bring any benefit in the quasi-Newton setting.

Published

2017

48. A study of the Bienstock–Zuckerberg algorithm: applications in mining and resource constrained project scheduling

Author

Eduardo Moreno, Gonzalo Muñoz, Daniel Espinoza, Marcos Goycoolea, Orlando Rivera Letelier, and Maurice Queyranne

Subjects

050210 logistics & transportation, 021103 operations research, Control and Optimization, Correctness, Applied Mathematics, 05 social sciences, Resource constrained, Significant difference, 0211 other engineering and technologies, 02 engineering and technology, Scheduling (computing), Linear programming relaxation, Project scheduling problem, Computational Mathematics, Optimization and Control (math.OC), 0502 economics and business, FOS: Mathematics, Batch processing, Column generation, Mathematics - Optimization and Control, Algorithm, Mathematics

Abstract

We study a Lagrangian decomposition algorithm recently proposed by Dan Bienstock and Mark Zuckerberg for solving the LP relaxation of a class of open pit mine project scheduling problems. In this study we show that the Bienstock---Zuckerberg (BZ) algorithm can be used to solve LP relaxations corresponding to a much broader class of scheduling problems, including the well-known Resource Constrained Project Scheduling Problem (RCPSP), and multi-modal variants of the RCPSP that consider batch processing of jobs. We present a new, intuitive proof of correctness for the BZ algorithm that works by casting the BZ algorithm as a column generation algorithm. This analysis allows us to draw parallels with the well-known Dantzig---Wolfe decomposition (DW) algorithm. We discuss practical computational techniques for speeding up the performance of the BZ and DW algorithms on project scheduling problems. Finally, we present computational experiments independently testing the effectiveness of the BZ and DW algorithms on different sets of publicly available test instances. Our computational experiments confirm that the BZ algorithm significantly outperforms the DW algorithm for the problems considered. Our computational experiments also show that the proposed speed-up techniques can have a significant impact on the solve time. We provide some insights on what might be explaining this significant difference in performance.

Published

2017

49. A new projection method for finding the closest point in the intersection of convex sets

Author

Francisco J. Aragón Artacho, Rubén Campoy, Universidad de Alicante. Departamento de Matemáticas, and Laboratorio de Optimización (LOPT)

Subjects

Control and Optimization, Nonexpansive mapping, Point of interest, 0211 other engineering and technologies, Convex set, Reflection, Feasibility problem, 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, symbols.namesake, Douglas–Rachford algorithm, Intersection, Projection (mathematics), 47H09, 47N10, 90C25, Estadística e Investigación Operativa, FOS: Mathematics, Projection method, Applied mathematics, Point (geometry), Projection, 0101 mathematics, Mathematics - Optimization and Control, Mathematics, 021103 operations research, Applied Mathematics, Hilbert space, Linear subspace, Computational Mathematics, Optimization and Control (math.OC), symbols, Best approximation problem

Abstract

In this paper we present a new iterative projection method for finding the closest point in the intersection of convex sets to any arbitrary point in a Hilbert space. This method, termed AAMR for averaged alternating modified reflections, can be viewed as an adequate modification of the Douglas–Rachford method that yields a solution to the best approximation problem. Under a constraint qualification at the point of interest, we show strong convergence of the method. In fact, the so-called strong CHIP fully characterizes the convergence of the AAMR method for every point in the space. We report some promising numerical experiments where we compare the performance of AAMR against other projection methods for finding the closest point in the intersection of pairs of finite dimensional subspaces. This work was partially supported by MINECO of Spain and ERDF of EU, Grant MTM2014-59179-C2-1-P. F.J. Aragón Artacho was supported by the Ramón y Cajal program by MINECO of Spain and ERDF of EU (RYC-2013-13327) and R. Campoy was supported by MINECO of Spain and ESF of EU (BES-2015-073360) under the program “Ayudas para contratos predoctorales para la formación de doctores 2015”.

Published

2017

50. Visualization of the $$\varepsilon $$ ε -subdifferential of piecewise linear–quadratic functions

Author

Yves Lucet, Anuj Bajaj, and Warren Hare

Subjects

Discrete mathematics, Linear function (calculus), 021103 operations research, Control and Optimization, G.1.6, Applied Mathematics, 010102 general mathematics, MathematicsofComputing_NUMERICALANALYSIS, Mathematics::Optimization and Control, 0211 other engineering and technologies, Regular polygon, 52A41 (Primary), 02 engineering and technology, Quadratic function, Subderivative, 01 natural sciences, Piecewise linear function, Computational Mathematics, Level set, Piecewise, Applied mathematics, 0101 mathematics, Convex function, Mathematics - Optimization and Control, Mathematics

Abstract

Computing explicitly the $$\varepsilon $$ź-subdifferential of a proper function amounts to computing the level set of a convex function namely the conjugate minus a linear function. The resulting theoretical algorithm is applied to the the class of (convex univariate) piecewise linear---quadratic functions for which existing numerical libraries allow practical computations. We visualize the results in a primal, dual, and subdifferential views through several numerical examples. We also provide a visualization of the BrOndsted---Rockafellar theorem.

Published

2017