The field of robotics has received significant attention in our society due to the extensive use of robotic manipulators; however, recent advances in the research on autonomous vehicles have demonstrated a broader range of applications, such as exploration, surveillance, and environmental monitoring. In this sense, the problem of efficiently building a model of the environment using cooperative mobile robots is critical. Finding routes that are either length or time-optimized is essential for real-world applications of small autonomous robots. This paper addresses the problem of multi-robot area coverage path planning for geophysical surveys. Such surveys have many applications in mineral exploration, geology, archeology, and oceanography, among other fields. We propose a methodology that segments the environment into hexagonal cells and allocates groups of robots to different clusters of non-obstructed cells to acquire data. Cells can be covered by lawnmower, square or centroid patterns with specific configurations to address the constraints of magneto-metric surveys. Several trials were executed in a simulated environment, and a statistical investigation of the results is provided. We also report the results of experiments that were performed with real Unmanned Aerial Vehicles in an outdoor setting.

This paper presents the results of a series of geophysical surveys of Roman forts and their environs carried out by the Gwynedd Archaeological Trust. An almost complete plan of the early wooden fort at Llanfor has been produced. Its densely-packed interior demonstrates heavy garrisoning, probably during very early Flavian campaigning. The small square auxiliary fort of Caer Llugwy has been shown to be a contraction of a larger rectangular fort. Surveys at Pennal, Caer Gai, and Canovium revealed a wide range of extramural development including vici in the form of ribbon development.