SDN is an architecture that aims to make networks agile and flexible. We have currently partnering with East Carolina University to implement an IoT-based dashboard that uses BeagleBone black and raspberry pi to monitor network response, throughput, the speed of website loading with more network analysis.

Spectrum sharing (Dynamic Spectrum Access – DSA) presents a model that solves the spectrum scarcity problem in this new era of explosive growth of smartphones, Internet of Things (IoT) and other numerous bandwidth-hungry applications. Studies across various regimes have shown that many RF spectrum bands are often underutilised even in densely populated urban areas. Hence, DSA introduces a technique that opportunistically allows unlicensed devices (or license-exempt devices) to share the RF spectrum with other licensed services. Specifically, the license-exempt devices can access the white space spectrum, which refers to those spectrums that are unused in a particular location at a particular time with a key consideration that they do not interfere with the licensed devices.  @iLabAfrica’s Internet of Things/Telecommunications Research Group began its DSA work through a collaborative research project made up of the following institutions: University of Strathclyde from Glasgow, UK (Lead institution), University of Malawi, Malawi,  Copperbelt University, Zambia  and University of Ghana, Ghana. The title of the project was: Enabling Affordable Internet Access with Dynamic Spectrum Management and Software Defined Radio and the Engineering and Physical Sciences Research Council (EPSRC). Since then, the Research Group has actively led DSA activities in collaboration with the Foreign Commonwealth and Development Office (FCDO) and the Communications Authority of Kenya – which culminated in the development of TVWS regulations in Kenya, the Dynamic Spectrum Alliance on Gap Studies for DSA as well as the opportunity of spectrum sharing in the 6 GHz band. Presently, the team is working on Coexistence Simulation in the 6 GHz band as well as leading an ITU Research Competition Study on Connect2Recover – Rebuilding Digital Inclusion through Spectrum Sharing.

To read more on our Dynamic Spectrum Access (DSA) projects Click Here

LPWAN Technology offers a very compelling mix of long range, low power consumption and secure data transmission. LPWAN is mainly targeted for Machine to Machine Communication (M2M) and IoT networks. We, so far implemented LoRaWAN infrastructure to leapfrog IoT adoption. We are currently collaborating in the Horizon 2020 project titled: WAZIHUB to develop capacity in implementation of LoRaWAN and enable startups leverage this technology for sustainable business models. The project is in partnership with universities and innovation hubs from Italy, France, Tanzania, Senegal, Zambia, Ghana, Uganda and South Africa. We have also partnered with Liquid telecom to advance research on Sigfox network and collaboratively drive its adoption for commercial activity in Kenya.

Industry 4.0, a name given to the current trend of automation and data exchange in manufacturing technologies is one of the major blocks of our research. We are keen to help drive innovation in the Industrial ecosystem through the combination of cyber-physical systems, the Internet of Things and cognitive computing.