Alternating DC algorithm for partial DC programming problems

This letter proposes a novel approach using the [Formula: see text]-norm regularization for the sparse covariance matrix estimation (SCME) problem. The objective function of SCME problem is composed of a nonconvex part and the [Formula: see text] term, which is discontinuous and difficult to tackle. Appropriate DC (difference of convex functions) approximations of [Formula: see text]-norm are used that result in approximation SCME problems that are still nonconvex. DC programming and DCA (DC algorithm), powerful tools in nonconvex programming framework, are investigated. Two DC formulations are proposed and corresponding DCA schemes developed. Two applications of the SCME problem that are considered are classification via sparse quadratic discriminant analysis and portfolio optimization. A careful empirical experiment is performed through simulated and real data sets to study the performance of the proposed algorithms. Numerical results showed their efficiency and their superiority compared with seven state-of-the-art methods.

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A novel approach for solving stochastic problems with multiple objective functions

RAIRO - Operations Research ◽

10.1051/ro/2021112 ◽

2021 ◽

Author(s):

ramzi kasri ◽

fatima bellahcene

Keyword(s):

Solution Method ◽

Dc Programming ◽

Decision Makers ◽

Stochastic Linear Programming ◽

Multivariate Distributions ◽

Quadratic Problem ◽

Weighting Method ◽

Dc Algorithm ◽

Novel Approach ◽

Multiobjective Approach

In this paper we suggest an approach for solving a multiobjective stochastic linear programming problem with normal multivariate distributions. Our solution method is a combination between the multiobjective approach and a nonconvex technique. The problem is first transformed into a deterministic multiobjective problem introducing the expected value criterion and an utility function that represents the decision makers’ preferences. The obtained problem is reduced to a mono-objective quadratic problem using a weighting method. This last problem is solved by DC programming and DC algorithm. A numerical example is included for illustration.

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A Branch-and-Bound Algorithm Embedded with DCA for DC Programming

Mathematical Problems in Engineering ◽

10.1155/2012/364607 ◽

2012 ◽

Vol 2012 ◽

pp. 1-16 ◽

Cited By ~ 2

Author(s):

Meihua Wang ◽

Fengmin Xu ◽

Chengxian Xu

Keyword(s):

Branch And Bound ◽

Large Scale ◽

Optimization Problems ◽

Optimal Solution ◽

Dc Programming ◽

Computational Time ◽

Special Importance ◽

Branch Number ◽

Dc Algorithm ◽

Computational Performance

The special importance of Difference of Convex (DC) functions programming has been recognized in recent studies on nonconvex optimization problems. In this work, a class of DC programming derived from the portfolio selection problems is studied. The most popular method applied to solve the problem is the Branch-and-Bound (B&B) algorithm. However, “the curse of dimensionality” will affect the performance of the B&B algorithm. DC Algorithm (DCA) is an efficient method to get a local optimal solution. It has been applied to many practical problems, especially for large-scale problems. A B&B-DCA algorithm is proposed by embedding DCA into the B&B algorithms, the new algorithm improves the computational performance and obtains a global optimal solution. Computational results show that the proposed B&B-DCA algorithm has the superiority of the branch number and computational time than general B&B. The nice features of DCA (inexpensiveness, reliability, robustness, globality of computed solutions, etc.) provide crucial support to the combined B&B-DCA for accelerating the convergence of B&B.

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Efficient Nonnegative Matrix Factorization by DC Programming and DCA

Neural Computation ◽

10.1162/neco_a_00836 ◽

2016 ◽

Vol 28 (6) ◽

pp. 1163-1216 ◽

Cited By ~ 5

Author(s):

Hoai An Le Thi ◽

Xuan Thanh Vo ◽

Tao Pham Dinh

Keyword(s):

Least Squares ◽

Matrix Factorization ◽

Nonnegative Matrix Factorization ◽

Synthetic Data ◽

Nonnegative Matrix ◽

Dc Programming ◽

Selection Strategy ◽

Sparse Regularization ◽

Dc Algorithm ◽

Difference Of Convex Functions

In this letter, we consider the nonnegative matrix factorization (NMF) problem and several NMF variants. Two approaches based on DC (difference of convex functions) programming and DCA (DC algorithm) are developed. The first approach follows the alternating framework that requires solving, at each iteration, two nonnegativity-constrained least squares subproblems for which DCA-based schemes are investigated. The convergence property of the proposed algorithm is carefully studied. We show that with suitable DC decompositions, our algorithm generates most of the standard methods for the NMF problem. The second approach directly applies DCA on the whole NMF problem. Two algorithms—one computing all variables and one deploying a variable selection strategy—are proposed. The proposed methods are then adapted to solve various NMF variants, including the nonnegative factorization, the smooth regularization NMF, the sparse regularization NMF, the multilayer NMF, the convex/convex-hull NMF, and the symmetric NMF. We also show that our algorithms include several existing methods for these NMF variants as special versions. The efficiency of the proposed approaches is empirically demonstrated on both real-world and synthetic data sets. It turns out that our algorithms compete favorably with five state-of-the-art alternating nonnegative least squares algorithms.

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Block Clustering Based on Difference of Convex Functions (DC) Programming and DC Algorithms

Neural Computation ◽

10.1162/neco_a_00490 ◽

2013 ◽

Vol 25 (10) ◽

pp. 2776-2807 ◽

Cited By ~ 8

Author(s):

Hoai Minh Le ◽

Hoai An Le Thi ◽

Tao Pham Dinh ◽

Van Ngai Huynh

Keyword(s):

Convex Functions ◽

Optimization Problem ◽

Dc Programming ◽

Clustering Problem ◽

Block Classification ◽

Dc Algorithm ◽

Difference Of Convex Functions ◽

Dc Program ◽

Difference Of Convex ◽

Block Clustering

We investigate difference of convex functions (DC) programming and the DC algorithm (DCA) to solve the block clustering problem in the continuous framework, which traditionally requires solving a hard combinatorial optimization problem. DC reformulation techniques and exact penalty in DC programming are developed to build an appropriate equivalent DC program of the block clustering problem. They lead to an elegant and explicit DCA scheme for the resulting DC program. Computational experiments show the robustness and efficiency of the proposed algorithm and its superiority over standard algorithms such as two-mode K-means, two-mode fuzzy clustering, and block classification EM.

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An Efficient Method for Convex Constrained Rank Minimization Problems Based on DC Programming

Mathematical Problems in Engineering ◽

10.1155/2016/7473041 ◽

2016 ◽

Vol 2016 ◽

pp. 1-13

Author(s):

Wanping Yang ◽

Jinkai Zhao ◽

Fengmin Xu

Keyword(s):

Objective Function ◽

Minimization Problem ◽

Dc Programming ◽

Rank Minimization ◽

Closed Form Solutions ◽

Minimization Problems ◽

Difference Of Convex Functions ◽

Convex Objective Function ◽

Difference Of Convex ◽

Cut Problems

The constrained rank minimization problem has various applications in many fields including machine learning, control, and signal processing. In this paper, we consider the convex constrained rank minimization problem. By introducing a new variable and penalizing an equality constraint to objective function, we reformulate the convex objective function with a rank constraint as a difference of convex functions based on the closed-form solutions, which can be reformulated as DC programming. A stepwise linear approximative algorithm is provided for solving the reformulated model. The performance of our method is tested by applying it to affine rank minimization problems and max-cut problems. Numerical results demonstrate that the method is effective and of high recoverability and results on max-cut show that the method is feasible, which provides better lower bounds and lower rank solutions compared with improved approximation algorithm using semidefinite programming, and they are close to the results of the latest researches.

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