PTEN Expression and KRAS Mutations on Primary Tumors and Metastases in the Prediction of Benefit From Cetuximab Plus Irinotecan for Patients With Metastatic Colorectal Cancer

We consider the energy minimization problem for undirected graphical models, also known as MAP-inference problem for Markov random fields which is NP-hard in general. We propose a novel polynomial time algorithm to obtain a part of its optimal non-relaxed integral solution. Our algorithm is initialized with variables taking integral values in the solution of a convex relaxation of the MAP-inference problem and iteratively prunes those, which do not satisfy our criterion for partial optimality. We show that our pruning strategy is in a certain sense theoretically optimal. Also empirically our method outperforms previous approaches in terms of the number of persistently labelled variables. The method is very general, as it is applicable to models with arbitrary factors of an arbitrary order and can employ any solver for the considered relaxed problem. Our method's runtime is determined by the runtime of the convex relaxation solver for the MAP-inference problem.

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A Study of Lagrangean Decompositions and Dual Ascent Solvers for Graph Matching

Swoboda

Rother

Alhaija

et al. 2017

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We study the quadratic assignment problem, in computer vision also known as graph matching. Two leading solvers for this problem optimize the Lagrange decomposition duals with sub-gradient and dual ascent (also known as message passing) updates. We explore this direction further and propose several additional Lagrangean relaxations of the graph matching problem along with corresponding algorithms, which are all based on a common dual ascent framework. Our extensive empirical evaluation gives several theoretical insights and suggests a new state-of-the-art anytime solver for the considered problem. Our improvement over state-of-the-art is particularly visible on a new dataset with large-scale sparse problem instances containing more than 500 graph nodes each.

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A Dual Ascent Framework for Lagrangean Decomposition of Combinatorial Problems

Swoboda

Kuske

Savchynskyy

2017

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We propose a general dual ascent framework for Lagrangean decomposition of combinatorial problems. Although methods of this type have shown their efficiency for a number of problems, so far there was no general algorithm applicable to multiple problem types. In this work, we propose such a general algorithm. It depends on several parameters, which can be used to optimize its performance in each particular setting. We demonstrate efficacy of our method on graph matching and multicut problems, where it outperforms state-of-the-art solvers including those based on subgradient optimization and off-the-shelf linear programming solvers.

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World Wide Web — Course tool: An environment for building WWW-based courses

Goldberg

Salari

Swoboda

1996

Computer Networks and ISDN Systems

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FastDOG: Fast Discrete Optimization on GPU

Abbas¹,

Swoboda²

2022

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Making Higher Order MOT Scalable: An Efficient Approximate Solver for Lifted Disjoint Paths

Horňáková

Kaiser

Swoboda

et al. 2021

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Paul Swoboda

Deep Graph Matching via Blackbox Differentiation of Combinatorial Solvers

Partial Optimality by Pruning for MAP-Inference with General Graphical Models

Partial Optimality by Pruning for MAP-Inference with General Graphical Models

A Study of Lagrangean Decompositions and Dual Ascent Solvers for Graph Matching

A Dual Ascent Framework for Lagrangean Decomposition of Combinatorial Problems

World Wide Web — Course tool: An environment for building WWW-based courses

FastDOG: Fast Discrete Optimization on GPU

Making Higher Order MOT Scalable: An Efficient Approximate Solver for Lifted Disjoint Paths

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