Related papers: Outer Approximation and Super-modular Cuts for Constrained Assortment Optimization under Mixed-Logit Model

Outer Approximation and Super-modular Cuts for Constrained Assortment Optimization under Mixed-Logit Model

URL: http://arxiv.org/abs/2407.18532v1
Date: Fri, 26 Jul 2024 06:27:11 GMT
Title: Outer Approximation and Super-modular Cuts for Constrained Assortment Optimization under Mixed-Logit Model
Authors: Hoang Giang Pham, Tien Mai,
Abstract summary: We study the assortment optimization problem under the mixed-logit customer choice model. Existing exact methods have primarily relied on mixed-integer linear programming (MILP) or second-order cone (CONIC) reformulations. Our work addresses the problem by focusing on components of the objective function that can be proven to be monotonically super-modular and convex.
Score: 6.123324869194196
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In this paper, we study the assortment optimization problem under the mixed-logit customer choice model. While assortment optimization has been a major topic in revenue management for decades, the mixed-logit model is considered one of the most general and flexible approaches for modeling and predicting customer purchasing behavior. Existing exact methods have primarily relied on mixed-integer linear programming (MILP) or second-order cone (CONIC) reformulations, which allow for exact problem solving using off-the-shelf solvers. However, these approaches often suffer from weak continuous relaxations and are slow when solving large instances. Our work addresses the problem by focusing on components of the objective function that can be proven to be monotonically super-modular and convex. This allows us to derive valid cuts to outer-approximate the nonlinear objective functions. We then demonstrate that these valid cuts can be incorporated into Cutting Plane or Branch-and-Cut methods to solve the problem exactly. Extensive experiments show that our approaches consistently outperform previous methods in terms of both solution quality and computation time.

Related papers

It's All in the Mix: Wasserstein Machine Learning with Mixed Features [5.739657897440173]
We present a practically efficient algorithm to solve mixed-feature problems. We demonstrate that our approach can significantly outperform existing methods that are to the presence of discrete features.
arXiv Detail & Related papers (2023-12-19T15:15:52Z)
Optimizing Solution-Samplers for Combinatorial Problems: The Landscape of Policy-Gradient Methods [52.0617030129699]
We introduce a novel theoretical framework for analyzing the effectiveness of DeepMatching Networks and Reinforcement Learning methods. Our main contribution holds for a broad class of problems including Max-and Min-Cut, Max-$k$-Bipartite-Bi, Maximum-Weight-Bipartite-Bi, and Traveling Salesman Problem. As a byproduct of our analysis we introduce a novel regularization process over vanilla descent and provide theoretical and experimental evidence that it helps address vanishing-gradient issues and escape bad stationary points.
arXiv Detail & Related papers (2023-10-08T23:39:38Z)
Backpropagation of Unrolled Solvers with Folded Optimization [55.04219793298687]
The integration of constrained optimization models as components in deep networks has led to promising advances on many specialized learning tasks. One typical strategy is algorithm unrolling, which relies on automatic differentiation through the operations of an iterative solver. This paper provides theoretical insights into the backward pass of unrolled optimization, leading to a system for generating efficiently solvable analytical models of backpropagation.
arXiv Detail & Related papers (2023-01-28T01:50:42Z)
Symmetric Tensor Networks for Generative Modeling and Constrained Combinatorial Optimization [72.41480594026815]
Constrained optimization problems abound in industry, from portfolio optimization to logistics. One of the major roadblocks in solving these problems is the presence of non-trivial hard constraints which limit the valid search space. In this work, we encode arbitrary integer-valued equality constraints of the form Ax=b, directly into U(1) symmetric networks (TNs) and leverage their applicability as quantum-inspired generative models.
arXiv Detail & Related papers (2022-11-16T18:59:54Z)
Learning Proximal Operators to Discover Multiple Optima [66.98045013486794]
We present an end-to-end method to learn the proximal operator across non-family problems. We show that for weakly-ized objectives and under mild conditions, the method converges globally.
arXiv Detail & Related papers (2022-01-28T05:53:28Z)
Divide and Learn: A Divide and Conquer Approach for Predict+Optimize [50.03608569227359]
The predict+optimize problem combines machine learning ofproblem coefficients with a optimization prob-lem that uses the predicted coefficients. We show how to directlyexpress the loss of the optimization problem in terms of thepredicted coefficients as a piece-wise linear function. We propose a novel divide and algorithm to tackle optimization problems without this restriction and predict itscoefficients using the optimization loss.
arXiv Detail & Related papers (2020-12-04T00:26:56Z)
Contrastive Losses and Solution Caching for Predict-and-Optimize [19.31153168397003]
We use a Noise Contrastive approach to motivate a family of surrogate loss functions. We address a major bottleneck of all predict-and-optimize approaches. We show that even a very slow growth rate is enough to match the quality of state-of-the-art methods.
arXiv Detail & Related papers (2020-11-10T19:09:12Z)
Memory Clustering using Persistent Homology for Multimodality- and Discontinuity-Sensitive Learning of Optimal Control Warm-starts [24.576214898129823]
Shooting methods are an efficient approach to solving nonlinear optimal control problems. Recent work has focused on providing an initial guess from a learned model trained on samples generated during an offline exploration of the problem space. In this work, we apply tools from algebraic topology to extract information on the underlying structure of the solution space.
arXiv Detail & Related papers (2020-10-02T14:24:59Z)
Extracting Optimal Solution Manifolds using Constrained Neural Optimization [6.800113407368289]
Constrained Optimization solution algorithms are restricted to point based solutions. We present an approach for extracting optimal sets as approximate, where unmodified non-informed constraints are defined.
arXiv Detail & Related papers (2020-09-13T15:37:44Z)
MINA: Convex Mixed-Integer Programming for Non-Rigid Shape Alignment [77.38594866794429]
convex mixed-integer programming formulation for non-rigid shape matching. We propose a novel shape deformation model based on an efficient low-dimensional discrete model.
arXiv Detail & Related papers (2020-02-28T09:54:06Z)

This list is automatically generated from the titles and abstracts of the papers in this site.