Approximation algorithms for the single robot line coverage problem. (English) Zbl 1469.68119
Lavalle, Steven M. (ed.) et al., Algorithmic foundations of robotics XIV. Proceedings of the fourteenth workshop on the algorithmic foundations of robotics. Cham: Springer. Springer Proc. Adv. Robot. 17, 534-550 (2021).
Summary: The line coverage problem is the task of servicing a given set of one-dimensional features in an environment. Its applications include the inspection of road networks, power lines, and oil and gas lines. The line coverage problem is a generalization of the standard arc routing problems, and is NP-hard in general. We address the single robot line coverage problem where the service and deadhead costs are distinct and asymmetric. We model the problem as an optimization problem that minimizes the total cost of travel on a given graph. We present approximation algorithms to obtain bounded solutions efficiently, using the minimum cost flow problem. We build the main algorithm in stages by considering three simpler subproblems. The subproblems are based on the structure of the required graph, i.e., the graph induced by the features that require servicing. We first present an optimal algorithm for the case of Eulerian graphs with only required edges. Next we consider general graphs, not necessarily Eulerian, with only required edges and present a 2-approximation algorithm. Finally, we consider the general case with both required and non-required edges. The approximation algorithm is dependent on the Asymmetric Traveling Salesperson Problem (ATSP), and is bounded by \(\alpha (C) + 2\), where \(\alpha (C)\) is the approximation factor of the ATSP algorithm with \(C\) connected components. Our upper bound is also an improvement over the existing results for the asymmetric rural postman problem.
For the entire collection see [Zbl 1464.68013].
For the entire collection see [Zbl 1464.68013].
MSC:
| 68T40 | Artificial intelligence for robotics |
| 68R10 | Graph theory (including graph drawing) in computer science |
| 68W25 | Approximation algorithms |
| 90C35 | Programming involving graphs or networks |
| 90C59 | Approximation methods and heuristics in mathematical programming |
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