3 research outputs found
Minimizing Turns in Watchman Robot Navigation: Strategies and Solutions
The Orthogonal Watchman Route Problem (OWRP) entails the search for the
shortest path, known as the watchman route, that a robot must follow within a
polygonal environment. The primary objective is to ensure that every point in
the environment remains visible from at least one point on the route, allowing
the robot to survey the entire area in a single, continuous sweep. This
research places particular emphasis on reducing the number of turns in the
route, as it is crucial for optimizing navigation in watchman routes within the
field of robotics. The cost associated with changing direction is of
significant importance, especially for specific types of robots. This paper
introduces an efficient linear-time algorithm for solving the OWRP under the
assumption that the environment is monotone. The findings of this study
contribute to the progress of robotic systems by enabling the design of more
streamlined patrol robots. These robots are capable of efficiently navigating
complex environments while minimizing the number of turns. This advancement
enhances their coverage and surveillance capabilities, making them highly
effective in various real-world applications.Comment: 6 pages, 3 figure
Securing Pathways with Orthogonal Robots
The protection of pathways holds immense significance across various domains,
including urban planning, transportation, surveillance, and security. This
article introduces a groundbreaking approach to safeguarding pathways by
employing orthogonal robots. The study specifically addresses the challenge of
efficiently guarding orthogonal areas with the minimum number of orthogonal
robots. The primary focus is on orthogonal pathways, characterized by a
path-like dual graph of vertical decomposition. It is demonstrated that
determining the minimum number of orthogonal robots for pathways can be
achieved in linear time. However, it is essential to note that the general
problem of finding the minimum number of robots for simple polygons with
general visibility, even in the orthogonal case, is known to be NP-hard.
Emphasis is placed on the flexibility of placing robots anywhere within the
polygon, whether on the boundary or in the interior.Comment: 8 pages, 5 figure