Speeding Up GDL-Based Message Passing Algorithms for Large-Scale DCOPs

Khan, Md. Mosaddek; Tran-Thanh, Long; Ramchurn, Sarvapali D.; Jennings, Nicholas R.

doi:10.1093/comjnl/bxy021

Cited by 8 publications

(6 citation statements)

References 17 publications

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“…Some of them, including the methods proposed by (Macarthur et al, 2011;Pujol-Gonzalez, Cerquides, Meseguer, Rodriguez-Aguilar, & Tambe, 2013), were implemented in the Max-sum version that was proposed for solving DCOP_MST in (Yedidsion, Zivan, & Farinelli, 2014). Others, which were proposed recently, make an immense reduction of the computational cost in such scenarios (Khan, Tran-Thanh, Ramchurn, & Jennings, 2018;Chen, Jiang, Deng, Chen, & He, 2019). In our work, we prove that such exponential computation is not required, and therefore these methods, which are most useful in standard scenarios, are less relevant.…”

Section: Related Workmentioning

confidence: 73%

Collision Avoiding Max-Sum for Mobile Sensor Teams

Pertzovsky,

Zivan,

Agmon

2024

jair

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Recent advances in technology have large teams of robots with limited computation skills work together in order to achieve a common goal. Their personal actions need to contribute to the joint effort, however, they also must assure that they do not harm the efforts of the other members of the team, e.g., as a result of collisions. We focus on the distributed target coverage problem, in which the team must cooperate in order to maximize utility from sensed targets, while avoiding collisions with other agents. State of the art solutions focus on the distributed optimization of the coverage task in the team level, while neglecting to consider collision avoidance, which could have far reaching consequences on the overall performance. Therefore, we propose CAMS: a collision-avoiding version of the Max-sum algorithm, for solving problems including mobile sensors. In CAMS, a factor-graph that includes two types of constraints (represented by function-nodes) is being iteratively generated and solved. The first type represents the task-related requirements, and the second represents collision avoidance constraints. We prove that consistent beliefs are sent by target representing function-nodes during the run of the algorithm, and identify factor-graph structures on which CAMS is guaranteed to converge to an optimal (collision-free) solution. We present an experimental evaluation in extensive simulations, showing that CAMS produces high quality collision-free coverage also in large and complex scenarios. We further present evidence from experiments in a real multi-robot system that CAMS outperforms the state of the art in terms of convergence time.

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Section: Related Workmentioning

confidence: 73%

Collision Avoiding Max-Sum for Mobile Sensor Teams

Pertzovsky,

Zivan,

Agmon

2024

jair

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“…T = [0. 1, 11.1, 22.2, 33.3, 44.4, 55.5, 66.6, 77.7, 88.8, 100] Let the feedback from each point be (using the modified ALS as described Algorithm 3: line 12): 40,30,25,32,42,57,70,95,130] The selected sample points (top G = 3 points) will be (Algorithm 3: lines 15-16):…”

Section: Proposed Methodsmentioning

confidence: 99%

“…As a consequence, diverse classes of incomplete algorithms have been developed to deal with large-scale DCOPs. Until recently, these incomplete algorithms could be classified into three classes: local search-based algorithms [20,21,22,23], inference-based algorithms [24,25,26,27,28] and sample-based algorithms [29,30].…”

Section: Introductionmentioning

confidence: 99%

On Population-Based Algorithms for Distributed Constraint Optimization Problems

Mahmud¹,

Khan²,

Jennings³

2020

Preprint

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Distributed Constraint Optimization Problems (DCOPs) are a widely studied class of optimization problems in which interaction between a set of cooperative agents are modeled as a set of constraints. DCOPs are NP-hard and significant effort has been devoted to developing methods for finding incomplete solutions. In this paper, we study an emerging class of such incomplete algorithms that are broadly termed as population-based algorithms. The main characteristic of these algorithms is that they maintain a population of candidate solutions of a given problem and use this population to cover a large area of the search space and to avoid localoptima. In recent years, this class of algorithms has gained significant attention due to their ability to produce high-quality incomplete solutions. With the primary goal of further improving the quality of solutions compared to the state-of-the-art incomplete DCOP algorithms, we present two new population-based algorithms in this paper. Our first approach, Anytime Evolutionary DCOP or AED, exploits evolutionary optimization meta-heuristics to solve DCOPs. We also present a novel anytime update mechanism that gives AED its anytime property. While in our second contribution, we show that population-based approaches can be combined with local search approaches. Specifically, we develop an algorithm called DPSA based on the Simulated Annealing meta-heuristic. We empirically evaluate these two algorithms to illustrate their respective effectiveness in different settings against the state-of-the-art incomplete DCOP algorithms including all existing population-based algorithms in a wide variety of benchmarks. Our evaluation shows AED and DPSA markedly outperform the state-of-the-art and produce up to 75% improved solutions.

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“…The Max-Product algorithm has received particular attention amongst all of the existing message passing algorithms. Similar to other such algorithms, Max-Product performs inference on a graphical model by either following a synchronous or an asynchronous message update protocol [6,13]. The messages here are generated using the GDL framework that has an axiomatic tendency of computational savings [12].…”

Section: Introductionmentioning

confidence: 99%

GDPx: An Application Independent Pruning Technique to Reduce Computation Cost of Max-Product Belief Propagation Algorithm

Khan

Trung

2023

Dhaka Uni. J. of Applied Sci. and Eng.

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The Max-Product belief propagation algorithm has been widely used to process constraints associated with optimization problems in a broad range of application domains such as information theory, multi-agent systems, image processing, etc. The constraint optimization of a given problem is typically accomplished by performing inference with the use of a message passing process. During the process, the Max-Product algorithm performs repetitive maximization operation, which has been considered as one of the main reasons the algorithm can be computationally expensive. In more detail, scalability becomes a challenge when Max-Product has to deal with constraint functions with high arity and/or variables with a large domain size. In either case, the ensuing exponential growth of search space can make the maximization operator of the algorithm computationally infeasible in practice. In effect, it is frequently observed that the output of an algorithm becomes obsolete or unusable as the optimization process takes too long. Speciﬁcally, the issue of an algorithm taking too long to complete its internal inference process becomes more severe and prevalent as the size of the problem increases. As a result, the practical scalability of such algorithms is constrained. However, it is challenging to maintain the solution quality while reducing the computation cost of the algorithm. This is important because success in doing so will eventually reduce the algorithm’s overall completion time without compromising on the quality of its solution. To address this issue, we develop a generic pruning technique that enables the maximization operator of the Max-Product algorithm to operate on a signiﬁcantly reduced search space of at least around 85% or more (i.e. empirical observation). Additionally, we demonstrate theoretically that the pruned search space obtained through our approach has no negative impact on the algorithm’s outcome. Finally, further empirical evidence notably suggests that our proposed approach brings down 50% to around 99% of the time required to complete a single maximization operation. DUJASE Vol. 7(1) 45-57, 2022 (January)

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Speeding Up GDL-Based Message Passing Algorithms for Large-Scale DCOPs

Cited by 8 publications

References 17 publications

Collision Avoiding Max-Sum for Mobile Sensor Teams

Collision Avoiding Max-Sum for Mobile Sensor Teams

On Population-Based Algorithms for Distributed Constraint Optimization Problems

GDPx: An Application Independent Pruning Technique to Reduce Computation Cost of Max-Product Belief Propagation Algorithm

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