Abstract

While the theoretical foundation of the optimal camera placement problem has been studied for decades, its practical implementation has recently attracted significant research interest due to the increasing popularity of visual sensor networks. The most flexible formulation of finding the optimal camera placement is based on a binary integer programming (BIP) problem. Despite the flexibility, most of the resulting BIP problems are NP-hard and any such formulations of reasonable size are not amenable to exact solutions. There exists a myriad of approximate algorithms for BIP problems, but their applications, efficiency, and scalability in solving camera placement are poorly understood. Thus, we develop a comprehensive framework in comparing the merits of a wide variety of approximate algorithms in solving the optimal camera placement problems. We first present a general approach of adapting these problems into BIP formulations. Then, we demonstrate how they can be solved using different approximate algorithms including greedy heuristics, Markov-chain Monte Carlo, simulated annealing, and linear and semidefinite programming relaxations. The accuracy, efficiency, and scalability of each technique are analyzed and compared in depth. Extensive experimental results are provided to illustrate the strength and weakness of each method.

Highlights

  • Due to the significant progress in visual sensor technology, wireless communication, and pattern recognition algorithms, the deployment of wide-area visual sensor networks has become practical and cost-effective

  • We show the effectiveness of using semidefinite programming relaxations (SDP) on relaxation on a simple and a moderate complex environment

  • We have presented and compared strengths and weaknesses of various well-known optimization frameworks to solve the generic camera placement problem including a greedy approach, Markov-Chain Monte Carlo (MCMC) methods, and linear programming (LP) and SDP relaxations

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Summary

Introduction

Due to the significant progress in visual sensor technology, wireless communication, and pattern recognition algorithms, the deployment of wide-area visual sensor networks has become practical and cost-effective. Application-specific constraints and objective functions can be defined based on these variables to formulate a binary integer programming (BIP) optimization problem. A myriad of approximate algorithms have been applied in solving BIP-based camera placement problem. Many of the proposed approaches [1,2,3,4,5,6,7,8] are customized for specific applications and a fair evaluation of different approximate algorithms on solving the general camera placement problem remains elusive. We present the BIP formulation for a wide variety of camera placement problems and provide a comprehensive framework to study various approximation algorithms in solving them.

Related Work
Camera Placement in General
Common Constraints Used in Camera Planning
Approximate Solutions to BIP Camera Placement Problems
Objective
Discussion

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