Evaluation of the Energy Consumption of a Mobile Robotic Platform for Sustainable 6G Networks

The emerging 6G paradigm and the proliferation of wireless devices require flexible network infrastructures capable of meeting the increasing Quality of Service (QoS) requirements. Mobile Robotic Platforms (MRPs) acting as mobile communications cells are a promising solution to provide on-demand wireless connectivity in dynamic networking scenarios. However, the energy consumption of MRPs is a challenge that must be considered, in order to maximize the availability of the wireless networks created. The main contribution of this paper is the experimental evaluation of the energy consumption of an MRP acting as a mobile communications cell. The evaluation considers different actions performed by a real MRP, showing that the energy consumption varies significantly with the type of action performed. The obtained results pave the way for optimizing the MRP movement in dynamic networking scenarios so that the wireless network's availability is maximized while minimizing the MRP's energy consumption.