Fast and reliable wireless connectivity is essential for businesses and industries in a broad range of sectors, from education and finance to healthcare, transport, utilities, logistics, mining, and manufacturing. As the demand of wireless coverage and services continues to rise, current wireless networks will fact new challenges, in terms of cost and resource efficiency, and reliability. The IPOSEE project, funded within the Horizon Europe Marie Skłodowska-Curie Actions programme, targets new concepts and solutions for automating and optimisation of service-oriented wireless networking, with delivering services as the focus, rather than just providing basic connectivity.
The objectives of research activities of the IPOSEE project are:
1) To devise and implement effective machine learning algorithms to extract, analyse, and interpret spatial-temporal the spatial-temporal patterns in mobile network data traffic. These algorithms are able to quantify uncertainty in service-demand prediction.
2) To identify and define representative subset(s) of services and their corresponding demand patterns for radio access network (RAN) deployment scenarios, by studying and analysing the correlation among the spatial-temporal patterns of service demand, to simplify the training for service demand forecasting.
3) To gain fundamental understanding of the achievable performance gains/limits, in particular capacity, via network densification (i.e. adding more network elements) and optimization of radio propagation environment optimisation with AI-aided traffic forecast, and to benchmark the performance for demanding scenarios such as requirement of low latency.
4) To develop AI-enabled RAN optimisation applications in conjunction with a probabilistic optimisation engine, based on AI predictions and RAN optimisation to cost-effectively meet service requirements. These optimization applications will be deployed as containerized microservices specifically designed for operation within the RAN Intelligent Controller (RIC) of the Open RAN (O-RAN) architecture.