Solutions for implementing a Multihop Topology for Bluetooth Low Energy

Abstract

While the Bluetooth Low Energy standard is able to provide unmatched accessibility and power consumption, it lacks proper support for multihop topologies, which severely limits its applicability in scenarios where the network is expected to cover distances beyond the reach of a single device's radio range. This thesis addresses the topology-shortcoming in the Bluetooth Low Energy standard by analyzing challenges related to the design of a mesh network topology extension for the existing standard, and presents solutions for an implementation. During the design process, a wireless network simulator is designed and implemented, in order to provide the candidate with an additional tool for development. The simulator is published as an open source project on the repository hosting website GitHub, in hopes of future usage in other similar design processes. The simulator becomes a central part of the design process during development, as it provides fast feedback to the candidate regarding the quality of the various solutions attempted. At the end of the design phase of the project, the simulator features a full- edged implementation of the design, which is published along with the simulator. As part of the work conducted to qualify various approaches to network structure, a network backbone formation algorithm is designed and compared to existing solutions for the subject. The algorithm performs well compared to its competitors, but fails to provide consistent network wide backbone connectivity. Towards the end of the thesis work, the solution design is implemented for the nRF51 series microcontroller by Nordic Semiconductor. The nRF51 implementation is focused on providing a solid basis for future development, and is expected to be extended upon during the candidate's future cooperation with Nordic Semiconductor. While the nal design presented in the thesis paper fails to meet the initial expectations to functionality, which were proven far too ambitious for the time allocated for the project, the candidate is condent that the solutions that are implemented provides all the performance and functionality that can be expect from the solution, and will be able to act as a basis for a design that could compete with all existing solutions for the intended application areas. This thesis work is conducted in cooperation with Nordic Semiconductor ASA, represented by David Edwin, and builds upon the candidate's prestudy on the topic.