Your search keyword '"Mazumder, Rahul"' showing total 38 results

1. Linear programming using diagonal linear networks

Author

Wang, Haoyue, Ghosal, Promit, and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control

Abstract

Linear programming has played a crucial role in shaping decision-making, resource allocation, and cost reduction in various domains. In this paper, we investigate the application of overparametrized neural networks and their implicit bias in solving linear programming problems. Specifically, our findings reveal that training diagonal linear networks with gradient descent, while optimizing the squared $L_2$-norm of the slack variable, leads to solutions for entropically regularized linear programming problems. Remarkably, the strength of this regularization depends on the initialization used in the gradient descent process. We analyze the convergence of both discrete-time and continuous-time dynamics and demonstrate that both exhibit a linear rate of convergence, requiring only mild assumptions on the constraint matrix. For the first time, we introduce a comprehensive framework for solving linear programming problems using diagonal neural networks. We underscore the significance of our discoveries by applying them to address challenges in basis pursuit and optimal transport problems.

Published

2023

2. A Cyclic Coordinate Descent Method for Convex Optimization on Polytopes

Author

Mazumder, Rahul and Wang, Haoyue

Subjects

Mathematics - Optimization and Control

Abstract

Coordinate descent algorithms are popular for huge-scale optimization problems due to their low cost per-iteration. Coordinate descent methods apply to problems where the constraint set is separable across coordinates. In this paper, we propose a new variant of the cyclic coordinate descent method that can handle polyhedral constraints provided that the polyhedral set does not have too many extreme points such as L1-ball and the standard simplex. Loosely speaking, our proposed algorithm PolyCD, can be viewed as a hybrid of cyclic coordinate descent and the Frank-Wolfe algorithms. We prove that PolyCD has a O(1/k) convergence rate for smooth convex objectives. Inspired by the away-step variant of Frank-Wolfe, we propose PolyCDwA, a variant of PolyCD with away steps which has a linear convergence rate when the loss function is smooth and strongly convex. Empirical studies demonstrate that PolyCDwA achieves strong computational performance for large-scale benchmark problems including L1-constrained linear regression, L1-constrained logistic regression and kernel density estimation.

Published

2023

3. Fast as CHITA: Neural Network Pruning with Combinatorial Optimization

Author

Benbaki, Riade, Chen, Wenyu, Meng, Xiang, Hazimeh, Hussein, Ponomareva, Natalia, Zhao, Zhe, and Mazumder, Rahul

Subjects

Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition, Mathematics - Optimization and Control

Abstract

The sheer size of modern neural networks makes model serving a serious computational challenge. A popular class of compression techniques overcomes this challenge by pruning or sparsifying the weights of pretrained networks. While useful, these techniques often face serious tradeoffs between computational requirements and compression quality. In this work, we propose a novel optimization-based pruning framework that considers the combined effect of pruning (and updating) multiple weights subject to a sparsity constraint. Our approach, CHITA, extends the classical Optimal Brain Surgeon framework and results in significant improvements in speed, memory, and performance over existing optimization-based approaches for network pruning. CHITA's main workhorse performs combinatorial optimization updates on a memory-friendly representation of local quadratic approximation(s) of the loss function. On a standard benchmark of pretrained models and datasets, CHITA leads to significantly better sparsity-accuracy tradeoffs than competing methods. For example, for MLPNet with only 2% of the weights retained, our approach improves the accuracy by 63% relative to the state of the art. Furthermore, when used in conjunction with fine-tuning SGD steps, our method achieves significant accuracy gains over the state-of-the-art approaches.

Published

2023

4. Improved Deep Neural Network Generalization Using m-Sharpness-Aware Minimization

Author

Behdin, Kayhan, Song, Qingquan, Gupta, Aman, Durfee, David, Acharya, Ayan, Keerthi, Sathiya, and Mazumder, Rahul

Subjects

Computer Science - Machine Learning, Mathematics - Optimization and Control

Abstract

Modern deep learning models are over-parameterized, where the optimization setup strongly affects the generalization performance. A key element of reliable optimization for these systems is the modification of the loss function. Sharpness-Aware Minimization (SAM) modifies the underlying loss function to guide descent methods towards flatter minima, which arguably have better generalization abilities. In this paper, we focus on a variant of SAM known as mSAM, which, during training, averages the updates generated by adversarial perturbations across several disjoint shards of a mini-batch. Recent work suggests that mSAM can outperform SAM in terms of test accuracy. However, a comprehensive empirical study of mSAM is missing from the literature -- previous results have mostly been limited to specific architectures and datasets. To that end, this paper presents a thorough empirical evaluation of mSAM on various tasks and datasets. We provide a flexible implementation of mSAM and compare the generalization performance of mSAM to the performance of SAM and vanilla training on different image classification and natural language processing tasks. We also conduct careful experiments to understand the computational cost of training with mSAM, its sensitivity to hyperparameters and its correlation with the flatness of the loss landscape. Our analysis reveals that mSAM yields superior generalization performance and flatter minima, compared to SAM, across a wide range of tasks without significantly increasing computational costs.

Published

2022

5. A Light-speed Linear Program Solver for Personalized Recommendation with Diversity Constraints

Author

Wang, Haoyue, Cheng, Miao, Basu, Kinjal, Gupta, Aman, Selvaraj, Keerthi, and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control

Abstract

We study a structured linear program (LP) that emerges in the need of ranking candidates or items in personalized recommender systems. Since the candidate set is only known in real time, the LP also needs to be formed and solved in real time. Latency and user experience are major considerations, requiring the LP to be solved within just a few milliseconds. Although typical instances of the problem are not very large in size, this stringent time limit appears to be beyond the capability of most existing (commercial) LP solvers, which can take $20$ milliseconds or more to find a solution. Thus, reliable methods that address the real-world complication of latency become necessary. In this paper, we propose a fast specialized LP solver for a structured problem with diversity constraints. Our method solves the dual problem, making use of the piece-wise affine structure of the dual objective function, with an additional screening technique that helps reduce the dimensionality of the problem as the algorithm progresses. Experiments reveal that our method can solve the problem within roughly 1 millisecond, yielding a 20x improvement in speed over efficient off-the-shelf LP solvers. This speed-up can help improve the quality of recommendations without affecting user experience, highlighting how optimization can provide solid orthogonal value to machine-learned recommender systems.

Published

2022

6. Nonparametric Finite Mixture Models with Possible Shape Constraints: A Cubic Newton Approach

Author

Wang, Haoyue, Ibrahim, Shibal, and Mazumder, Rahul

Subjects

Statistics - Computation, Mathematics - Optimization and Control, 90C06, 90C25, 90C90, 62G07

Abstract

We explore computational aspects of maximum likelihood estimation of the mixture proportions of a nonparametric finite mixture model -- a convex optimization problem with old roots in statistics and a key member of the modern data analysis toolkit. Motivated by problems in shape constrained inference, we consider structured variants of this problem with additional convex polyhedral constraints. We propose a new cubic regularized Newton method for this problem and present novel worst-case and local computational guarantees for our algorithm. We extend earlier work by Nesterov and Polyak to the case of a self-concordant objective with polyhedral constraints, such as the ones considered herein. We propose a Frank-Wolfe method to solve the cubic regularized Newton subproblem; and derive efficient solutions for the linear optimization oracles that may be of independent interest. In the particular case of Gaussian mixtures without shape constraints, we derive bounds on how well the finite mixture problem approximates the infinite-dimensional Kiefer-Wolfowitz maximum likelihood estimator. Experiments on synthetic and real datasets suggest that our proposed algorithms exhibit improved runtimes and scalability features over existing benchmarks., Comment: 31 pages, 6 figures

Published

2021

7. DSelect-k: Differentiable Selection in the Mixture of Experts with Applications to Multi-Task Learning

Author

Hazimeh, Hussein, Zhao, Zhe, Chowdhery, Aakanksha, Sathiamoorthy, Maheswaran, Chen, Yihua, Mazumder, Rahul, Hong, Lichan, and Chi, Ed H.

Subjects

Computer Science - Machine Learning, Mathematics - Optimization and Control, Statistics - Machine Learning

Abstract

The Mixture-of-Experts (MoE) architecture is showing promising results in improving parameter sharing in multi-task learning (MTL) and in scaling high-capacity neural networks. State-of-the-art MoE models use a trainable sparse gate to select a subset of the experts for each input example. While conceptually appealing, existing sparse gates, such as Top-k, are not smooth. The lack of smoothness can lead to convergence and statistical performance issues when training with gradient-based methods. In this paper, we develop DSelect-k: a continuously differentiable and sparse gate for MoE, based on a novel binary encoding formulation. The gate can be trained using first-order methods, such as stochastic gradient descent, and offers explicit control over the number of experts to select. We demonstrate the effectiveness of DSelect-k on both synthetic and real MTL datasets with up to $128$ tasks. Our experiments indicate that DSelect-k can achieve statistically significant improvements in prediction and expert selection over popular MoE gates. Notably, on a real-world, large-scale recommender system, DSelect-k achieves over $22\%$ improvement in predictive performance compared to Top-k. We provide an open-source implementation of DSelect-k., Comment: Appeared in NeurIPS 2021

Published

2021

8. Linear regression with partially mismatched data: local search with theoretical guarantees

Author

Mazumder, Rahul and Wang, Haoyue

Subjects

Mathematics - Optimization and Control, Statistics - Computation, Statistics - Methodology, Statistics - Machine Learning

Abstract

Linear regression is a fundamental modeling tool in statistics and related fields. In this paper, we study an important variant of linear regression in which the predictor-response pairs are partially mismatched. We use an optimization formulation to simultaneously learn the underlying regression coefficients and the permutation corresponding to the mismatches. The combinatorial structure of the problem leads to computational challenges. We propose and study a simple greedy local search algorithm for this optimization problem that enjoys strong theoretical guarantees and appealing computational performance. We prove that under a suitable scaling of the number of mismatched pairs compared to the number of samples and features, and certain assumptions on problem data; our local search algorithm converges to a nearly-optimal solution at a linear rate. In particular, in the noiseless case, our algorithm converges to the global optimal solution with a linear convergence rate. Based on this result, we prove an upper bound for the estimation error of the parameter. We also propose an approximate local search step that allows us to scale our approach to much larger instances. We conduct numerical experiments to gather further insights into our theoretical results, and show promising performance gains compared to existing approaches.

Published

2021

9. A new computational framework for log-concave density estimation

Author

Chen, Wenyu, Mazumder, Rahul, and Samworth, Richard J.

Subjects

Statistics - Computation, Mathematics - Optimization and Control, Statistics - Methodology

Abstract

In Statistics, log-concave density estimation is a central problem within the field of nonparametric inference under shape constraints. Despite great progress in recent years on the statistical theory of the canonical estimator, namely the log-concave maximum likelihood estimator, adoption of this method has been hampered by the complexities of the non-smooth convex optimization problem that underpins its computation. We provide enhanced understanding of the structural properties of this optimization problem, which motivates the proposal of new algorithms, based on both randomized and Nesterov smoothing, combined with an appropriate integral discretization of increasing accuracy. We prove that these methods enjoy, both with high probability and in expectation, a convergence rate of order $1/T$ up to logarithmic factors on the objective function scale, where $T$ denotes the number of iterations. The benefits of our new computational framework are demonstrated on both synthetic and real data, and our implementation is available in a github repository \texttt{LogConcComp} (Log-Concave Computation).

Published

2021

10. Grouped Variable Selection with Discrete Optimization: Computational and Statistical Perspectives

Author

Hazimeh, Hussein, Mazumder, Rahul, and Radchenko, Peter

Subjects

Statistics - Methodology, Computer Science - Machine Learning, Mathematics - Optimization and Control, Statistics - Computation, Statistics - Machine Learning

Abstract

We present a new algorithmic framework for grouped variable selection that is based on discrete mathematical optimization. While there exist several appealing approaches based on convex relaxations and nonconvex heuristics, we focus on optimal solutions for the $\ell_0$-regularized formulation, a problem that is relatively unexplored due to computational challenges. Our methodology covers both high-dimensional linear regression and nonparametric sparse additive modeling with smooth components. Our algorithmic framework consists of approximate and exact algorithms. The approximate algorithms are based on coordinate descent and local search, with runtimes comparable to popular sparse learning algorithms. Our exact algorithm is based on a standalone branch-and-bound (BnB) framework, which can solve the associated mixed integer programming (MIP) problem to certified optimality. By exploiting the problem structure, our custom BnB algorithm can solve to optimality problem instances with $5 \times 10^6$ features and $10^3$ observations in minutes to hours -- over $1000$ times larger than what is currently possible using state-of-the-art commercial MIP solvers. We also explore statistical properties of the $\ell_0$-based estimators. We demonstrate, theoretically and empirically, that our proposed estimators have an edge over popular group-sparse estimators in terms of statistical performance in various regimes. We provide an open-source implementation of our proposed framework.

Published

2021

11. Frank-Wolfe Methods with an Unbounded Feasible Region and Applications to Structured Learning

Author

Wang, Haoyue, Lu, Haihao, and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control, 90C25, 90C06, 90C90

Abstract

The Frank-Wolfe (FW) method is a popular algorithm for solving large-scale convex optimization problems appearing in structured statistical learning. However, the traditional Frank-Wolfe method can only be applied when the feasible region is bounded, which limits its applicability in practice. Motivated by two applications in statistical learning, the $\ell_1$ trend filtering problem and matrix optimization problems with generalized nuclear norm constraints, we study a family of convex optimization problems where the unbounded feasible region is the direct sum of an unbounded linear subspace and a bounded constraint set. We propose two new Frank-Wolfe methods: unbounded Frank-Wolfe method (uFW) and unbounded Away-Step Frank-Wolfe method (uAFW), for solving a family of convex optimization problems with this class of unbounded feasible regions. We show that under proper regularity conditions, the unbounded Frank-Wolfe method has a $O(1/k)$ sublinear convergence rate, and unbounded Away-Step Frank-Wolfe method has a linear convergence rate, matching the best-known results for the Frank-Wolfe method when the feasible region is bounded. Furthermore, computational experiments indicate that our proposed methods appear to outperform alternative solvers., Comment: 31 pages, 6 figures

Published

2020

12. Subgradient Regularized Multivariate Convex Regression at Scale

Author

Chen, Wenyu and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control, Statistics - Computation, Statistics - Machine Learning

Abstract

We present new large-scale algorithms for fitting a subgradient regularized multivariate convex regression function to $n$ samples in $d$ dimensions -- a key problem in shape constrained nonparametric regression with applications in statistics, engineering and the applied sciences. The infinite-dimensional learning task can be expressed via a convex quadratic program (QP) with $O(nd)$ decision variables and $O(n^2)$ constraints. While instances with $n$ in the lower thousands can be addressed with current algorithms within reasonable runtimes, solving larger problems (e.g., $n\approx 10^4$ or $10^5$) is computationally challenging. To this end, we present an active set type algorithm on the dual QP. For computational scalability, we allow for approximate optimization of the reduced sub-problems; and propose randomized augmentation rules for expanding the active set. We derive novel computational guarantees for our algorithms. We demonstrate that our framework can approximately solve instances of the subgradient regularized convex regression problem with $n=10^5$ and $d=10$ within minutes; and shows strong computational performance compared to earlier approaches.

Published

2020

13. Sparse Regression at Scale: Branch-and-Bound rooted in First-Order Optimization

Author

Hazimeh, Hussein, Mazumder, Rahul, and Saab, Ali

Subjects

Statistics - Computation, Computer Science - Machine Learning, Mathematics - Optimization and Control, Statistics - Machine Learning

Abstract

We consider the least squares regression problem, penalized with a combination of the $\ell_{0}$ and squared $\ell_{2}$ penalty functions (a.k.a. $\ell_0 \ell_2$ regularization). Recent work shows that the resulting estimators are of key importance in many high-dimensional statistical settings. However, exact computation of these estimators remains a major challenge. Indeed, modern exact methods, based on mixed integer programming (MIP), face difficulties when the number of features $p \sim 10^4$. In this work, we present a new exact MIP framework for $\ell_0\ell_2$-regularized regression that can scale to $p \sim 10^7$, achieving speedups of at least $5000$x, compared to state-of-the-art exact methods. Unlike recent work, which relies on modern commercial MIP solvers, we design a specialized nonlinear branch-and-bound (BnB) framework, by critically exploiting the problem structure. A key distinguishing component in our framework lies in efficiently solving the node relaxations using a specialized first-order method, based on coordinate descent (CD). Our CD-based method effectively leverages information across the BnB nodes, through using warm starts, active sets, and gradient screening. In addition, we design a novel method for obtaining dual bounds from primal CD solutions, which certifiably works in high dimensions. Experiments on synthetic and real high-dimensional datasets demonstrate that our framework is not only significantly faster than the state of the art, but can also deliver certifiably optimal solutions to statistically challenging instances that cannot be handled with existing methods. We open source the implementation through our toolkit L0BnB.

Published

2020

14. Learning Sparse Classifiers: Continuous and Mixed Integer Optimization Perspectives

Author

Dedieu, Antoine, Hazimeh, Hussein, and Mazumder, Rahul

Subjects

Statistics - Machine Learning, Computer Science - Machine Learning, Mathematics - Optimization and Control, Statistics - Computation

Abstract

We consider a discrete optimization formulation for learning sparse classifiers, where the outcome depends upon a linear combination of a small subset of features. Recent work has shown that mixed integer programming (MIP) can be used to solve (to optimality) $\ell_0$-regularized regression problems at scales much larger than what was conventionally considered possible. Despite their usefulness, MIP-based global optimization approaches are significantly slower compared to the relatively mature algorithms for $\ell_1$-regularization and heuristics for nonconvex regularized problems. We aim to bridge this gap in computation times by developing new MIP-based algorithms for $\ell_0$-regularized classification. We propose two classes of scalable algorithms: an exact algorithm that can handle $p\approx 50,000$ features in a few minutes, and approximate algorithms that can address instances with $p\approx 10^6$ in times comparable to the fast $\ell_1$-based algorithms. Our exact algorithm is based on the novel idea of \textsl{integrality generation}, which solves the original problem (with $p$ binary variables) via a sequence of mixed integer programs that involve a small number of binary variables. Our approximate algorithms are based on coordinate descent and local combinatorial search. In addition, we present new estimation error bounds for a class of $\ell_0$-regularized estimators. Experiments on real and synthetic data demonstrate that our approach leads to models with considerably improved statistical performance (especially, variable selection) when compared to competing methods., Comment: To appear in JMLR

Published

2020

15. Computing Estimators of Dantzig Selector type via Column and Constraint Generation

Author

Mazumder, Rahul, Wright, Stephen, and Zheng, Andrew

Subjects

Statistics - Computation, Mathematics - Optimization and Control, Statistics - Machine Learning

Abstract

We consider a class of linear-programming based estimators in reconstructing a sparse signal from linear measurements. Specific formulations of the reconstruction problem considered here include Dantzig selector, basis pursuit (for the case in which the measurements contain no errors), and the fused Dantzig selector (for the case in which the underlying signal is piecewise constant). In spite of being estimators central to sparse signal processing and machine learning, solving these linear programming problems for large scale instances remains a challenging task, thereby limiting their usage in practice. We show that classic constraint- and column-generation techniques from large scale linear programming, when used in conjunction with a commercial implementation of the simplex method, and initialized with the solution from a closely-related Lasso formulation, yields solutions with high efficiency in many settings.

Published

2019

16. Learning Hierarchical Interactions at Scale: A Convex Optimization Approach

Author

Hazimeh, Hussein and Mazumder, Rahul

Subjects

Statistics - Machine Learning, Computer Science - Machine Learning, Mathematics - Optimization and Control, Statistics - Computation

Abstract

In many learning settings, it is beneficial to augment the main features with pairwise interactions. Such interaction models can be often enhanced by performing variable selection under the so-called strong hierarchy constraint: an interaction is non-zero only if its associated main features are non-zero. Existing convex optimization based algorithms face difficulties in handling problems where the number of main features $p \sim 10^3$ (with total number of features $\sim p^2$). In this paper, we study a convex relaxation which enforces strong hierarchy and develop a highly scalable algorithm based on proximal gradient descent. We introduce novel screening rules that allow for solving the complicated proximal problem in parallel. In addition, we introduce a specialized active-set strategy with gradient screening for avoiding costly gradient computations. The framework can handle problems having dense design matrices, with $p = 50,000$ ($\sim 10^9$ interactions)---instances that are much larger than current state of the art. Experiments on real and synthetic data suggest that our toolkit hierScale outperforms the state of the art in terms of prediction and variable selection and can achieve over a 4900x speed-up., Comment: AISTATS 2020

Published

2019

17. Randomized Gradient Boosting Machine

Author

Lu, Haihao and Mazumder, Rahul

Subjects

Computer Science - Machine Learning, Mathematics - Optimization and Control, Statistics - Machine Learning

Abstract

Gradient Boosting Machine (GBM) introduced by Friedman is a powerful supervised learning algorithm that is very widely used in practice---it routinely features as a leading algorithm in machine learning competitions such as Kaggle and the KDDCup. In spite of the usefulness of GBM in practice, our current theoretical understanding of this method is rather limited. In this work, we propose Randomized Gradient Boosting Machine (RGBM) which leads to substantial computational gains compared to GBM, by using a randomization scheme to reduce search in the space of weak-learners. We derive novel computational guarantees for RGBM. We also provide a principled guideline towards better step-size selection in RGBM that does not require a line search. Our proposed framework is inspired by a special variant of coordinate descent that combines the benefits of randomized coordinate descent and greedy coordinate descent; and may be of independent interest as an optimization algorithm. As a special case, our results for RGBM lead to superior computational guarantees for GBM. Our computational guarantees depend upon a curious geometric quantity that we call Minimal Cosine Angle, which relates to the density of weak-learners in the prediction space. On a series of numerical experiments on real datasets, we demonstrate the effectiveness of RGBM over GBM in terms of obtaining a model with good training and/or testing data fidelity with a fraction of the computational cost.

Published

2018

18. Using L1-relaxation and integer programming to obtain dual bounds for sparse PCA

Author

Dey, Santanu S., Mazumder, Rahul, and Wang, Guanyi

Subjects

Mathematics - Optimization and Control

Abstract

Principal component analysis (PCA) is one of the most widely used dimensionality reduction tools in data analysis. The PCA direction is a linear combination of all features with nonzero loadings -- this impedes interpretability. Sparse PCA (SPCA) is a framework that enhances interpretability by incorporating an additional sparsity requirement in the feature weights. However, unlike PCA, the SPCA problem is NP-hard. Most conventional methods for solving SPCA are heuristics with no guarantees, such as certificates of optimality on the solution-quality via associated dual bounds. Dual bounds are available via standard semidefinite programming (SDP) based relaxations, which may not be tight, and the SDPs are difficult to scale by off-the-shelf solvers. In this paper, we present a convex integer programming (IP) framework to derive dual bounds. At the heart of our approach is the so-called $\ell_1$-relaxation of SPCA. While the $\ell_1$-relaxation leads to convex optimization problems for $\ell_0$-sparse linear regression and relatives, it results in a non-convex optimization problem for the PCA problem. We first show that the $\ell_1$-relaxation gives a tight multiplicative bound on SPCA. Then we show how to use standard integer programming techniques to further relax the $\ell_1$-relaxation into a convex IP. We present worst-case results on the quality of the dual bound from the convex IP. We observe that the dual bounds are significantly better than worst-case performance and are superior to the SDP bounds in some real-life instances. Moreover, solving the convex IP model using commercial IP solvers appears to scale much better than solving the SDP-relaxation using commercial solvers. To the best of our knowledge, we obtain the best dual bounds for real and artificial instances for SPCA problems involving covariance matrices of size up to $2000\times 2000$.

Published

2018

19. Condition Number Analysis of Logistic Regression, and its Implications for Standard First-Order Solution Methods

Author

Freund, Robert M., Grigas, Paul, and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control, Computer Science - Machine Learning, Statistics - Computation, Statistics - Machine Learning

Abstract

Logistic regression is one of the most popular methods in binary classification, wherein estimation of model parameters is carried out by solving the maximum likelihood (ML) optimization problem, and the ML estimator is defined to be the optimal solution of this problem. It is well known that the ML estimator exists when the data is non-separable, but fails to exist when the data is separable. First-order methods are the algorithms of choice for solving large-scale instances of the logistic regression problem. In this paper, we introduce a pair of condition numbers that measure the degree of non-separability or separability of a given dataset in the setting of binary classification, and we study how these condition numbers relate to and inform the properties and the convergence guarantees of first-order methods. When the training data is non-separable, we show that the degree of non-separability naturally enters the analysis and informs the properties and convergence guarantees of two standard first-order methods: steepest descent (for any given norm) and stochastic gradient descent. Expanding on the work of Bach, we also show how the degree of non-separability enters into the analysis of linear convergence of steepest descent (without needing strong convexity), as well as the adaptive convergence of stochastic gradient descent. When the training data is separable, first-order methods rather curiously have good empirical success, which is not well understood in theory. In the case of separable data, we demonstrate how the degree of separability enters into the analysis of $\ell_2$ steepest descent and stochastic gradient descent for delivering approximate-maximum-margin solutions with associated computational guarantees as well. This suggests that first-order methods can lead to statistically meaningful solutions in the separable case, even though the ML solution does not exist., Comment: 38 pages

Published

2018

20. Fast Best Subset Selection: Coordinate Descent and Local Combinatorial Optimization Algorithms

Author

Hazimeh, Hussein and Mazumder, Rahul

Subjects

Statistics - Computation, Mathematics - Optimization and Control, Statistics - Machine Learning

Abstract

The $L_0$-regularized least squares problem (a.k.a. best subsets) is central to sparse statistical learning and has attracted significant attention across the wider statistics, machine learning, and optimization communities. Recent work has shown that modern mixed integer optimization (MIO) solvers can be used to address small to moderate instances of this problem. In spite of the usefulness of $L_0$-based estimators and generic MIO solvers, there is a steep computational price to pay when compared to popular sparse learning algorithms (e.g., based on $L_1$ regularization). In this paper, we aim to push the frontiers of computation for a family of $L_0$-regularized problems with additional convex penalties. We propose a new hierarchy of necessary optimality conditions for these problems. We develop fast algorithms, based on coordinate descent and local combinatorial optimization, that are guaranteed to converge to solutions satisfying these optimality conditions. From a statistical viewpoint, an interesting story emerges. When the signal strength is high, our combinatorial optimization algorithms have an edge in challenging statistical settings. When the signal is lower, pure $L_0$ benefits from additional convex regularization. We empirically demonstrate that our family of $L_0$-based estimators can outperform the state-of-the-art sparse learning algorithms in terms of a combination of prediction, estimation, and variable selection metrics under various regimes (e.g., different signal strengths, feature correlations, number of samples and features). Our new open-source sparse learning toolkit L0Learn (available on CRAN and Github) reaches up to a three-fold speedup (with $p$ up to $10^6$) when compared to competing toolkits such as glmnet and ncvreg., Comment: To appear in Operations Research

Published

2018

21. Computation of the Maximum Likelihood estimator in low-rank Factor Analysis

Author

Khamaru, Koulik and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control, Statistics - Computation, Statistics - Machine Learning

Abstract

Factor analysis, a classical multivariate statistical technique is popularly used as a fundamental tool for dimensionality reduction in statistics, econometrics and data science. Estimation is often carried out via the Maximum Likelihood (ML) principle, which seeks to maximize the likelihood under the assumption that the positive definite covariance matrix can be decomposed as the sum of a low rank positive semidefinite matrix and a diagonal matrix with nonnegative entries. This leads to a challenging rank constrained nonconvex optimization problem. We reformulate the low rank ML Factor Analysis problem as a nonlinear nonsmooth semidefinite optimization problem, study various structural properties of this reformulation and propose fast and scalable algorithms based on difference of convex (DC) optimization. Our approach has computational guarantees, gracefully scales to large problems, is applicable to situations where the sample covariance matrix is rank deficient and adapts to variants of the ML problem with additional constraints on the problem parameters. Our numerical experiments demonstrate the significant usefulness of our approach over existing state-of-the-art approaches., Comment: 22 pages, 4 figures

Published

2018

22. Sparse principal component analysis and its $l_1$-relaxation

Author

Dey, Santanu S., Mazumder, Rahul, Molinaro, Marco, and Wang, Guanyi

Subjects

Mathematics - Optimization and Control

Abstract

Principal component analysis (PCA) is one of the most widely used dimensionality reduction methods in scientific data analysis. In many applications, for additional interpretability, it is desirable for the factor loadings to be sparse, that is, we solve PCA with an additional cardinality (l0) constraint. The resulting optimization problem is called the sparse principal component analysis (SPCA). One popular approach to achieve sparsity is to replace the l0 constraint by an l1 constraint. In this paper, we prove that, independent of the data, the optimal objective function value of the problem with l0 constraint is within a constant factor of the the optimal objective function value of the problem with l1 constraint. To the best of our knowledge, this is the first formal relationship established between the l0 and the l1 constraint version of the problem.

Published

2017

23. The Trimmed Lasso: Sparsity and Robustness

Author

Bertsimas, Dimitris, Copenhaver, Martin S., and Mazumder, Rahul

Subjects

Statistics - Methodology, Mathematics - Optimization and Control, Mathematics - Statistics Theory, Statistics - Computation, Statistics - Machine Learning

Abstract

Nonconvex penalty methods for sparse modeling in linear regression have been a topic of fervent interest in recent years. Herein, we study a family of nonconvex penalty functions that we call the trimmed Lasso and that offers exact control over the desired level of sparsity of estimators. We analyze its structural properties and in doing so show the following: 1) Drawing parallels between robust statistics and robust optimization, we show that the trimmed-Lasso-regularized least squares problem can be viewed as a generalized form of total least squares under a specific model of uncertainty. In contrast, this same model of uncertainty, viewed instead through a robust optimization lens, leads to the convex SLOPE (or OWL) penalty. 2) Further, in relating the trimmed Lasso to commonly used sparsity-inducing penalty functions, we provide a succinct characterization of the connection between trimmed-Lasso- like approaches and penalty functions that are coordinate-wise separable, showing that the trimmed penalties subsume existing coordinate-wise separable penalties, with strict containment in general. 3) Finally, we describe a variety of exact and heuristic algorithms, both existing and new, for trimmed Lasso regularized estimation problems. We include a comparison between the different approaches and an accompanying implementation of the algorithms., Comment: 32 pages (excluding appendix); 4 figures

Published

2017

24. Subset Selection with Shrinkage: Sparse Linear Modeling when the SNR is low

Author

Mazumder, Rahul, Radchenko, Peter, and Dedieu, Antoine

Subjects

Statistics - Methodology, Mathematics - Optimization and Control, Mathematics - Statistics Theory, Statistics - Computation, Statistics - Machine Learning

Abstract

We study a seemingly unexpected and relatively less understood overfitting aspect of a fundamental tool in sparse linear modeling - best subset selection, which minimizes the residual sum of squares subject to a constraint on the number of nonzero coefficients. While the best subset selection procedure is often perceived as the "gold standard" in sparse learning when the signal to noise ratio (SNR) is high, its predictive performance deteriorates when the SNR is low. In particular, it is outperformed by continuous shrinkage methods, such as ridge regression and the Lasso. We investigate the behavior of best subset selection in the high-noise regimes and propose an alternative approach based on a regularized version of the least-squares criterion. Our proposed estimators (a) mitigate, to a large extent, the poor predictive performance of best subset selection in the high-noise regimes; and (b) perform favorably, while generally delivering substantially sparser models, relative to the best predictive models available via ridge regression and the Lasso. We conduct an extensive theoretical analysis of the predictive properties of the proposed approach and provide justification for its superior predictive performance relative to best subset selection when the noise-level is high. Our estimators can be expressed as solutions to mixed integer second order conic optimization problems and, hence, are amenable to modern computational tools from mathematical optimization.

Published

2017

25. Certifiably Optimal Low Rank Factor Analysis

Author

Bertsimas, Dimitris, Copenhaver, Martin S., and Mazumder, Rahul

Subjects

Statistics - Methodology, Mathematics - Optimization and Control, Statistics - Computation

Abstract

Factor Analysis (FA) is a technique of fundamental importance that is widely used in classical and modern multivariate statistics, psychometrics and econometrics. In this paper, we revisit the classical rank-constrained FA problem, which seeks to approximate an observed covariance matrix ($\boldsymbol\Sigma$), by the sum of a Positive Semidefinite (PSD) low-rank component ($\boldsymbol\Theta$) and a diagonal matrix ($\boldsymbol\Phi$) (with nonnegative entries) subject to $\boldsymbol\Sigma - \boldsymbol\Phi$ being PSD. We propose a flexible family of rank-constrained, nonlinear Semidefinite Optimization based formulations for this task. We introduce a reformulation of the problem as a smooth optimization problem with convex compact constraints and propose a unified algorithmic framework, utilizing state of the art techniques in nonlinear optimization to obtain high-quality feasible solutions for our proposed formulation. At the same time, by using a variety of techniques from discrete and global optimization, we show that these solutions are certifiably optimal in many cases, even for problems with thousands of variables. Our techniques are general and make no assumption on the underlying problem data. The estimator proposed herein, aids statistical interpretability, provides computational scalability and significantly improved accuracy when compared to current, publicly available popular methods for rank-constrained FA. We demonstrate the effectiveness of our proposal on an array of synthetic and real-life datasets. To our knowledge, this is the first paper that demonstrates how a previously intractable rank-constrained optimization problem can be solved to provable optimality by coupling developments in convex analysis and in discrete optimization.

Published

2016

26. An Extended Frank-Wolfe Method with 'In-Face' Directions, and its Application to Low-Rank Matrix Completion

Author

Freund, Robert M., Grigas, Paul, and Mazumder, Rahul

Subjects

Mathematics - Optimization and Control, Statistics - Computation, Statistics - Machine Learning, 90C25, G.1.6

Abstract

Motivated principally by the low-rank matrix completion problem, we present an extension of the Frank-Wolfe method that is designed to induce near-optimal solutions on low-dimensional faces of the feasible region. This is accomplished by a new approach to generating ``in-face" directions at each iteration, as well as through new choice rules for selecting between in-face and ``regular" Frank-Wolfe steps. Our framework for generating in-face directions generalizes the notion of away-steps introduced by Wolfe. In particular, the in-face directions always keep the next iterate within the minimal face containing the current iterate. We present computational guarantees for the new method that trade off efficiency in computing near-optimal solutions with upper bounds on the dimension of minimal faces of iterates. We apply the new method to the matrix completion problem, where low-dimensional faces correspond to low-rank matrices. We present computational results that demonstrate the effectiveness of our methodological approach at producing nearly-optimal solutions of very low rank. On both artificial and real datasets, we demonstrate significant speed-ups in computing very low-rank nearly-optimal solutions as compared to either the Frank-Wolfe method or its traditional away-step variant., Comment: 25 pages, 3 tables and 2 figues

Published

2015

27. A Computational Framework for Multivariate Convex Regression and its Variants

Author

Mazumder, Rahul, Choudhury, Arkopal, Iyengar, Garud, and Sen, Bodhisattva

Subjects

Statistics - Computation, Mathematics - Optimization and Control, Statistics - Methodology

Abstract

We study the nonparametric least squares estimator (LSE) of a multivariate convex regression function. The LSE, given as the solution to a quadratic program with $O(n^2)$ linear constraints ($n$ being the sample size), is difficult to compute for large problems. Exploiting problem specific structure, we propose a scalable algorithmic framework based on the augmented Lagrangian method to compute the LSE. We develop a novel approach to obtain smooth convex approximations to the fitted (piecewise affine) convex LSE and provide formal bounds on the quality of approximation. When the number of samples is not too large compared to the dimension of the predictor, we propose a regularization scheme --- Lipschitz convex regression --- where we constrain the norm of the subgradients, and study the rates of convergence of the obtained LSE. Our algorithmic framework is simple and flexible and can be easily adapted to handle variants: estimation of a non-decreasing/non-increasing convex/concave (with or without a Lipschitz bound) function. We perform numerical studies illustrating the scalability of the proposed algorithm.

Published

2015

28. Scalable Computation of Regularized Precision Matrices via Stochastic Optimization

Author

Atchadé, Yves F., Mazumder, Rahul, and Chen, Jie

Subjects

Mathematics - Statistics Theory, Mathematics - Optimization and Control

Abstract

We consider the problem of computing a positive definite $p \times p$ inverse covariance matrix aka precision matrix $\theta=(\theta_{ij})$ which optimizes a regularized Gaussian maximum likelihood problem, with the elastic-net regularizer $\sum_{i,j=1}^{p} \lambda (\alpha|\theta_{ij}| + \frac{1}{2}(1- \alpha) \theta_{ij}^2),$ with regularization parameters $\alpha \in [0,1]$ and $\lambda>0$. The associated convex semidefinite optimization problem is notoriously difficult to scale to large problems and has demanded significant attention over the past several years. We propose a new algorithmic framework based on stochastic proximal optimization (on the primal problem) that can be used to obtain near optimal solutions with substantial computational savings over deterministic algorithms. A key challenge of our work stems from the fact that the optimization problem being investigated does not satisfy the usual assumptions required by stochastic gradient methods. Our proposal has (a) computational guarantees and (b) scales well to large problems, even if the solution is not too sparse; thereby, enhancing the scope of regularized maximum likelihood problems to many large-scale problems of contemporary interest. An important aspect of our proposal is to bypass the \emph{deterministic} computation of a matrix inverse by drawing random samples from a suitable multivariate Gaussian distribution., Comment: 42 pages

Published

2015

29. The Discrete Dantzig Selector: Estimating Sparse Linear Models via Mixed Integer Linear Optimization

Author

Mazumder, Rahul and Radchenko, Peter

Subjects

Statistics - Methodology, Mathematics - Optimization and Control, Mathematics - Statistics Theory, Statistics - Computation, Statistics - Machine Learning

Abstract

We propose a novel high-dimensional linear regression estimator: the Discrete Dantzig Selector, which minimizes the number of nonzero regression coefficients subject to a budget on the maximal absolute correlation between the features and residuals. Motivated by the significant advances in integer optimization over the past 10-15 years, we present a Mixed Integer Linear Optimization (MILO) approach to obtain certifiably optimal global solutions to this nonconvex optimization problem. The current state of algorithmics in integer optimization makes our proposal substantially more computationally attractive than the least squares subset selection framework based on integer quadratic optimization, recently proposed in [8] and the continuous nonconvex quadratic optimization framework of [33]. We propose new discrete first-order methods, which when paired with state-of-the-art MILO solvers, lead to good solutions for the Discrete Dantzig Selector problem for a given computational budget. We illustrate that our integrated approach provides globally optimal solutions in significantly shorter computation times, when compared to off-the-shelf MILO solvers. We demonstrate both theoretically and empirically that in a wide range of regimes the statistical properties of the Discrete Dantzig Selector are superior to those of popular $\ell_{1}$-based approaches. We illustrate that our approach can handle problem instances with p = 10,000 features with certifiable optimality making it a highly scalable combinatorial variable selection approach in sparse linear modeling.

Published

2015

30. Best Subset Selection via a Modern Optimization Lens

Author

Bertsimas, Dimitris, King, Angela, and Mazumder, Rahul

Subjects

Statistics - Methodology, Mathematics - Optimization and Control, Statistics - Computation, Statistics - Machine Learning

Abstract

In the last twenty-five years (1990-2014), algorithmic advances in integer optimization combined with hardware improvements have resulted in an astonishing 200 billion factor speedup in solving Mixed Integer Optimization (MIO) problems. We present a MIO approach for solving the classical best subset selection problem of choosing $k$ out of $p$ features in linear regression given $n$ observations. We develop a discrete extension of modern first order continuous optimization methods to find high quality feasible solutions that we use as warm starts to a MIO solver that finds provably optimal solutions. The resulting algorithm (a) provides a solution with a guarantee on its suboptimality even if we terminate the algorithm early, (b) can accommodate side constraints on the coefficients of the linear regression and (c) extends to finding best subset solutions for the least absolute deviation loss function. Using a wide variety of synthetic and real datasets, we demonstrate that our approach solves problems with $n$ in the 1000s and $p$ in the 100s in minutes to provable optimality, and finds near optimal solutions for $n$ in the 100s and $p$ in the 1000s in minutes. We also establish via numerical experiments that the MIO approach performs better than {\texttt {Lasso}} and other popularly used sparse learning procedures, in terms of achieving sparse solutions with good predictive power., Comment: This is a revised version (May, 2015) of the first submission in June 2014

Published

2015

31. A New Perspective on Boosting in Linear Regression via Subgradient Optimization and Relatives

Author

Freund, Robert M., Grigas, Paul, and Mazumder, Rahul

Subjects

Mathematics - Statistics Theory, Computer Science - Learning, Mathematics - Optimization and Control, Statistics - Machine Learning, 62J05, 62J07, 90C25

Abstract

In this paper we analyze boosting algorithms in linear regression from a new perspective: that of modern first-order methods in convex optimization. We show that classic boosting algorithms in linear regression, namely the incremental forward stagewise algorithm (FS$_\varepsilon$) and least squares boosting (LS-Boost($\varepsilon$)), can be viewed as subgradient descent to minimize the loss function defined as the maximum absolute correlation between the features and residuals. We also propose a modification of FS$_\varepsilon$ that yields an algorithm for the Lasso, and that may be easily extended to an algorithm that computes the Lasso path for different values of the regularization parameter. Furthermore, we show that these new algorithms for the Lasso may also be interpreted as the same master algorithm (subgradient descent), applied to a regularized version of the maximum absolute correlation loss function. We derive novel, comprehensive computational guarantees for several boosting algorithms in linear regression (including LS-Boost($\varepsilon$) and FS$_\varepsilon$) by using techniques of modern first-order methods in convex optimization. Our computational guarantees inform us about the statistical properties of boosting algorithms. In particular they provide, for the first time, a precise theoretical description of the amount of data-fidelity and regularization imparted by running a boosting algorithm with a prespecified learning rate for a fixed but arbitrary number of iterations, for any dataset.

Published

2015

32. AdaBoost and Forward Stagewise Regression are First-Order Convex Optimization Methods

Author

Freund, Robert M., Grigas, Paul, and Mazumder, Rahul

Subjects

Statistics - Machine Learning, Computer Science - Learning, Mathematics - Optimization and Control, 68Q32, 68T05, 62J05, 90C25, I.2.6, I.5.1, G.3, G.1.6

Abstract

Boosting methods are highly popular and effective supervised learning methods which combine weak learners into a single accurate model with good statistical performance. In this paper, we analyze two well-known boosting methods, AdaBoost and Incremental Forward Stagewise Regression (FS$_\varepsilon$), by establishing their precise connections to the Mirror Descent algorithm, which is a first-order method in convex optimization. As a consequence of these connections we obtain novel computational guarantees for these boosting methods. In particular, we characterize convergence bounds of AdaBoost, related to both the margin and log-exponential loss function, for any step-size sequence. Furthermore, this paper presents, for the first time, precise computational complexity results for FS$_\varepsilon$.

Published

2013

33. A new computational framework for log-concave density estimation

Author

Chen, Wenyu, Mazumder, Rahul, Samworth, Richard J., Samworth, Richard [0000-0003-2426-4679], and Apollo - University of Cambridge Repository

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, stat.CO, math.OC, Optimization and Control (math.OC), stat.ME, FOS: Mathematics, Statistics - Computation, Mathematics - Optimization and Control, Computation (stat.CO), Statistics - Methodology

Abstract

In Statistics, log-concave density estimation is a central problem within the field of nonparametric inference under shape constraints. Despite great progress in recent years on the statistical theory of the canonical estimator, namely the log-concave maximum likelihood estimator, adoption of this method has been hampered by the complexities of the non-smooth convex optimization problem that underpins its computation. We provide enhanced understanding of the structural properties of this optimization problem, which motivates the proposal of new algorithms, based on both randomized and Nesterov smoothing, combined with an appropriate integral discretization of increasing accuracy. We prove that these methods enjoy, both with high probability and in expectation, a convergence rate of order $1/T$ up to logarithmic factors on the objective function scale, where $T$ denotes the number of iterations. The benefits of our new computational framework are demonstrated on both synthetic and real data, and our implementation is available in a github repository \texttt{LogConcComp} (Log-Concave Computation).

Published

2023

34. Multivariate Convex Regression at Scale

Author

Chen, Wenyu and Mazumder, Rahul

Subjects

FOS: Computer and information sciences, Statistics - Machine Learning, Optimization and Control (math.OC), FOS: Mathematics, Machine Learning (stat.ML), Mathematics - Optimization and Control, Statistics - Computation, Computation (stat.CO)

Abstract

We present new large-scale algorithms for fitting a subgradient regularized multivariate convex regression function to $n$ samples in $d$ dimensions -- a key problem in shape constrained nonparametric regression with widespread applications in statistics, engineering and the applied sciences. The infinite-dimensional learning task can be expressed via a convex quadratic program (QP) with $O(nd)$ decision variables and $O(n^2)$ constraints. While instances with $n$ in the lower thousands can be addressed with current algorithms within reasonable runtimes, solving larger problems (e.g., $n\approx 10^4$ or $10^5$) is computationally challenging. To this end, we present an active set type algorithm on the dual QP. For computational scalability, we perform approximate optimization of the reduced sub-problems; and propose randomized augmentation rules for expanding the active set. Although the dual is not strongly convex, we present a novel linear convergence rate of our algorithm on the dual. We demonstrate that our framework can approximately solve instances of the convex regression problem with $n=10^5$ and $d=10$ within minutes; and offers significant computational gains compared to earlier approaches.

Published

2020

35. Scalable Computation of Regularized Precision Matrices via Stochastic Optimization

Author

Atchad��, Yves F., Mazumder, Rahul, and Chen, Jie

Subjects

Optimization and Control (math.OC), FOS: Mathematics, Mathematics - Statistics Theory, Statistics Theory (math.ST), Mathematics - Optimization and Control

Abstract

We consider the problem of computing a positive definite $p \times p$ inverse covariance matrix aka precision matrix $\theta=(\theta_{ij})$ which optimizes a regularized Gaussian maximum likelihood problem, with the elastic-net regularizer $\sum_{i,j=1}^{p} \lambda (\alpha|\theta_{ij}| + \frac{1}{2}(1- \alpha) \theta_{ij}^2),$ with regularization parameters $\alpha \in [0,1]$ and $\lambda>0$. The associated convex semidefinite optimization problem is notoriously difficult to scale to large problems and has demanded significant attention over the past several years. We propose a new algorithmic framework based on stochastic proximal optimization (on the primal problem) that can be used to obtain near optimal solutions with substantial computational savings over deterministic algorithms. A key challenge of our work stems from the fact that the optimization problem being investigated does not satisfy the usual assumptions required by stochastic gradient methods. Our proposal has (a) computational guarantees and (b) scales well to large problems, even if the solution is not too sparse; thereby, enhancing the scope of regularized maximum likelihood problems to many large-scale problems of contemporary interest. An important aspect of our proposal is to bypass the \emph{deterministic} computation of a matrix inverse by drawing random samples from a suitable multivariate Gaussian distribution., Comment: 42 pages

Published

2015

36. A Computational Framework for Multivariate Convex Regression and Its Variants

Author

Bodhisattva Sen, Rahul Mazumder, Arkopal Choudhury, Garud Iyengar, Sloan School of Management, and Mazumder, Rahul

Subjects

Statistics and Probability, FOS: Computer and information sciences, Multivariate statistics, Statistics::Theory, Regression function, MathematicsofComputing_NUMERICALANALYSIS, 01 natural sciences, Statistics - Computation, Methodology (stat.ME), Statistics::Machine Learning, 010104 statistics & probability, Computer Science::Systems and Control, 0502 economics and business, FOS: Mathematics, Statistics::Methodology, Applied mathematics, Quadratic programming, 0101 mathematics, Mathematics - Optimization and Control, Computation (stat.CO), Statistics - Methodology, 050205 econometrics, Mathematics, Augmented Lagrangian method, 05 social sciences, Regular polygon, Nonparametric statistics, Regression, Optimization and Control (math.OC), Statistics, Probability and Uncertainty

Abstract

We study the nonparametric least squares estimator (LSE) of a multivariate convex regression function. The LSE, given as the solution to a quadratic program with O(n²) linear constraints (n being the sample size), is difficult to compute for large problems. Exploiting problem specific structure, we propose a scalable algorithmic framework based on the augmented Lagrangian method to compute the LSE. We develop a novel approach to obtain smooth convex approximations to the fitted (piecewise affine) convex LSE and provide formal bounds on the quality of approximation. When the number of samples is not too large compared to the dimension of the predictor, we propose a regularization scheme—Lipschitz convex regression—where we constrain the norm of the subgradients, and study the rates of convergence of the obtained LSE. Our algorithmic framework is simple and flexible and can be easily adapted to handle variants: estimation of a nondecreasing/nonincreasing convex/concave (with or without a Lipschitz bound) function. We perform numerical studies illustrating the scalability of the proposed algorithm—on some instances our proposal leads to more than a 10,000-fold improvement in runtime when compared to off-the-shelf interior point solvers for problems with n = 500. Keywords: Augmented Lagrangian method; Lipschitz convex regression; Non parametric least squares estimator; Scalable quadratic programming; Smooth convex regression, United States. Office of Naval Research (Grant N00014-15-1-2342)

Published

2019

37. Best subset selection via a modern optimization lens

Author

Angela King, Dimitris Bertsimas, Rahul Mazumder, Massachusetts Institute of Technology. Operations Research Center, Sloan School of Management, Bertsimas, Dimitris J, King, Angela, and Mazumder, Rahul

Subjects

FOS: Computer and information sciences, Statistics and Probability, 90C27, Mathematical optimization, least absolute deviation, 0211 other engineering and technologies, Machine Learning (stat.ML), 02 engineering and technology, algorithms, 01 natural sciences, Statistics - Computation, mixed integer programming, 90C26, Methodology (stat.ME), 010104 statistics & probability, 62J07, Lasso (statistics), 62J05, Statistics - Machine Learning, Discrete optimization, FOS: Mathematics, 0101 mathematics, lasso, Integer programming, Global optimization, Mathematics - Optimization and Control, Computation (stat.CO), Statistics - Methodology, Mathematics, Continuous optimization, 021103 operations research, global optimization, Solver, 90C11, $\ell_{0}$-constrained minimization, Optimization and Control (math.OC), Least absolute deviations, discrete optimization, 62G35, Statistics, Probability and Uncertainty, Sparse linear regression, best subset selection, Integer (computer science)

Abstract

In the last twenty-five years (1990-2014), algorithmic advances in integer optimization combined with hardware improvements have resulted in an astonishing 200 billion factor speedup in solving Mixed Integer Optimization (MIO) problems. We present a MIO approach for solving the classical best subset selection problem of choosing $k$ out of $p$ features in linear regression given $n$ observations. We develop a discrete extension of modern first order continuous optimization methods to find high quality feasible solutions that we use as warm starts to a MIO solver that finds provably optimal solutions. The resulting algorithm (a) provides a solution with a guarantee on its suboptimality even if we terminate the algorithm early, (b) can accommodate side constraints on the coefficients of the linear regression and (c) extends to finding best subset solutions for the least absolute deviation loss function. Using a wide variety of synthetic and real datasets, we demonstrate that our approach solves problems with $n$ in the 1000s and $p$ in the 100s in minutes to provable optimality, and finds near optimal solutions for $n$ in the 100s and $p$ in the 1000s in minutes. We also establish via numerical experiments that the MIO approach performs better than {\texttt {Lasso}} and other popularly used sparse learning procedures, in terms of achieving sparse solutions with good predictive power., This is a revised version (May, 2015) of the first submission in June 2014

Published

2015

38. The Discrete Dantzig Selector: Estimating Sparse Linear Models via Mixed Integer Linear Optimization

Author

Rahul Mazumder, Peter Radchenko, Sloan School of Management, and Mazumder, Rahul

Subjects

FOS: Computer and information sciences, Optimization problem, Linear programming, 0211 other engineering and technologies, Machine Learning (stat.ML), Mathematics - Statistics Theory, Statistics Theory (math.ST), 02 engineering and technology, Library and Information Sciences, Statistics - Computation, 01 natural sciences, Least squares, Methodology (stat.ME), 010104 statistics & probability, Statistics - Machine Learning, Algorithmics, Linear regression, FOS: Mathematics, Applied mathematics, Quadratic programming, 0101 mathematics, Mathematics - Optimization and Control, Computation (stat.CO), Statistics - Methodology, Mathematics, 021103 operations research, Linear model, Computer Science Applications, Optimization and Control (math.OC), Information Systems, Integer (computer science)

Abstract

We propose a novel high-dimensional linear regression estimator: the Discrete Dantzig Selector , which minimizes the number of nonzero regression coefficients subject to a budget on the maximal absolute correlation between the features and residuals. Motivated by the significant advances in integer optimization over the past 10–15 years, we present a mixed integer linear optimization ( MILO ) approach to obtain certifiably optimal global solutions to this nonconvex optimization problem. The current state of algorithmics in integer optimization makes our proposal substantially more computationally attractive than the least squares subset selection framework based on integer quadratic optimization, recently proposed by Bertsimas et al. and the continuous nonconvex quadratic optimization framework of Liu et al. . We propose new discrete first-order methods, which when paired with the state-of-the-art MILO solvers, lead to good solutions for the Discrete Dantzig Selector problem for a given computational budget. We illustrate that our integrated approach provides globally optimal solutions in significantly shorter computation times, when compared to off-the-shelf MILO solvers. We demonstrate both theoretically and empirically that in a wide range of regimes the statistical properties of the Discrete Dantzig Selector are superior to those of popular $\ell _{1}$ -based approaches. We illustrate that our approach can handle problem instances with $p =10,\!000$ features with certifiable optimality making it a highly scalable combinatorial variable selection approach in sparse linear modeling.

Published

2017