Design and Development of a Fly-by-Wireless UAV Platform

Abstract

The development of unmanned aerial vehicles (UAVs) has become an active area of research in recent years, and very interesting devices have been developed. UAVs are important instruments for numerous applications, such as forest surveillance and fire detection, coastal and economic exclusive zone surveillance, detection of watershed pollution and military missions. The work described in this chapter is part of a larger project, named AIVA, which involves the design and development of an aerial platform, as well as the instrumentation, communications, flight control and artificial vision systems, in order to provide autonomous takeoff, flight mission and landing maneuvers. The focus of the chapter is on one of the main innovative aspects of the project: the onboard wireless distributed data acquisition and control system. Traditionally, UAVs present an architecture consisting of one centralized and complex unit, with one or more CPUs, to which the instrumentation devices are connected by wires. At the same time, they have bulky mechanical connections. In the approach presented here, dubbed “fly-by-wireless”, the traditional monolithic processing unit is replaced by several less complex units (wireless nodes), spread out over the aircraft. In that way, the nodes are placed near the sensors and controlled surfaces, creating a network of nodes with the capacity of data acquisition, processing and actuation. This proposed fly-by-wireless platform provides several advantages over conventional systems, such as higher flexibility and modularity, as well as easier installation procedures, due to the elimination of connecting cables. However, it also introduces several challenges. The wireless network that supports the onboard distributed data acquisition and control system needs to satisfy demanding requirements in terms of quality of service (QoS), such as sustainable throughput, bounded delay and reliable packet delivery. At the same time, it is necessary to guarantee that the power consumption of the battery powered wireless nodes is small, in order to increase the autonomy of the system. Currently there are many different wireless network technologies available in the market. Section 2 presents an overview of the most relevant technologies and discusses their suitability to meet the above requirements. Based on this analysis, we chose the Bluetooth wireless network technology as the basis for the design and development of a prototype of the fly-by-wireless system. The system was implemented using commercial off-the-shelf components, in order to provide a good trade-