Abstract
Evolving power systems with increasing renewables penetration, along with the development of the smart grid, calls for improved communication networks to support these distributed generation sources. Automatic and optimal placement of communication resources within the advanced metering infrastructure is critical to provide a high-performing, reliable, and resilient power system. Three network design formulations based on mixed-integer linear and non-linear programming approaches are proposed to minimise network congestion by optimising residual buffer capacity through the placement of data concentrators and network routeing. Results on a case study show that the proposed models improve network connectivity and robustness, and increase average residual buffer capacity. Maximising average residual capacity alone, however, results in both oversaturated and underutilised nodes, while maximising either minimum residual capacity or total reciprocal residual capacity can yield much-improved network load allocation. Consideration of connection redundancy improves network reliability further by ensuring quality-of-service in the event of an outage. Analysis of multi-period network expansion shows that the models do not deviate significantly from optimal when used progressively (within 5% deviation), and are effective for utility planners to use for smart grid expansion.
Highlights
The adoption of new renewable standards and accelerated cost reductions are driving sharp growth in renewable energy technologies
We focus on optimal handling of aperiodic data traffic by optimising the residual buffer capacity of data concentrators (DCs) as an analogue to optimise QoS factors such as bandwidth, throughput, packet loss, and delay requirements in the network
The general framework of the smart grid communication network (SGCN) consists of a multi-tier system: (i) a home area network (HAN) consisting of smart appliances, Internet-of-things (IoT) devices, and distributed energy sources communicating to a nearby smart meters (SMs), (ii) a neighbourhood area network (NAN) consisting of DCs that receive the information from nearby SMs, process and relay the information onto, (iii) the edge router (ER) or a control centre of the energy provider within the wide area network (WAN) [10, 15, 16]
Summary
The adoption of new renewable standards and accelerated cost reductions are driving sharp growth in renewable energy technologies. The development of the smart grid, as a natural evolution of the electric power grid, seeks to incorporate new technologies to support these distributed generation sources. Automatic placement and optimisation of network topology are critical to provide a cost-effective, high-performing, reliable, and secure communication network in support of the expanding smart grid. We develop a procedure to optimally place communication hardware and route communication within AMI networks in a way that best maximises QoS performance for utility customers, provide redundant network connectivity in the event of a security threat or outage, and provide for effective expansion of the network.
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