HAMSTER healthy, mobility and security-based data communication architecture for unmanned systems

Advances in communicat ions have been unarguably essent ial to enablemodern systems and applicat ions as we know them. Ubiquity has turned into reality, allowing specialised embedded systems to eminent ly grow and spread. That is notably the case of unmanned vehicles which have been creat ively explored on applications that were not as efficient as they currently are, neither as innovative as recent ly accomplished. Therefore, towards the efficient operat ion of either unmanned vehicles and systems they integrate, in addition to communicat ion improvements, it is highly desired that we carefully observe relevant , co-related necessit ies that may lead to the full insert ion of unmanned vehicles to our everyday lives. Moreover, by addressing these demands on integrated solut ions, better resultswill likely be produced. This thesis presentsHAMSTER, theHeAlthy, Mobility and Security based data communication archiTEctuRe for unmanned vehicles, which addresses threemain types of communicat ions: machine-to-machine, machine-to-infrast ructure and internal machine communications. Four addit ional elements on co-related requirements are provided alongside with HAMSTER for more accurate approaches regarding security and safety aspects (SPHERE platform), crit icality analysis (NCI index), energy efficiency (NP plat form) and mobility-oriented ad hoc and infrast ructured communicat ions (NIMBLE platform). Furthermore, three specialised versions are provided: unmanned aerial vehicles (Flying HAMSTER), unmanned ground vehicles (Running HAMSTER) and unmanned surface/ underwater vehicles (Swimming HAMSTER). The architecture validat ion is achieved by case studies on each feature addressed, leading to guidelines on the development of vehicles more likely to meet certificat ion requirements, more efficient and secure communicat ions, assert ive approaches regarding crit icality and green approaches on internal communicat ions. Indeed, results prove the efficiency and effectiveness of HAMSTER architecture and its elements, as well as its flexibility in carrying out different experiments focused on various aspects of communication, which helps researchers and developers to achieve safe and secure communicat ions in unmanned vehicles. (AU)