Operational Management Systems for Resilient Microgrids in Remote and Islanded Communities Under Natural Disasters (TECH-IN: Microgrid Technologies for Remote and Island Communities under Natural Disasters)

Project Details


Microgrids effectively ease the integration of renewable energy sources (RES) and energy storage systems (ESS) at the consumption level, which generally aims to increase the efficiency of the electrical system and reduce the dependency on the electrical supply from fossil fuels. Microgrids intrinsically increase the efficiency of the electrical system by integrating the RES at the consumption level, which avoids most of the transmission losses. In addition, the use of dc distribution systems has the potential to further increase energy efficiency, and potentially reduce the cost of the system, especially when the penetration of RES and ESS is significant. On the other hand, the microgrids (MG) concept has been widely studied, which focuses on overcoming these issues in a reliable, efficient, cost-efficient, and sustainable way, but still, challenges exist. For instance, the severe power outages caused by natural disasters (ND), such as tsunamis, floods, earthquakes, etc. all of which affect industrial production, disturb business as well as home operations, and may endanger human lives. These possible natural disasters and incidents impose new challenges involving sophisticated control strategies, operation, and vulnerability to natural disasters. Most of these events directly affect the overall power system and as well communication between systems. After a disaster, the main grid may blackout, and gen- sets are shut down for security reasons. In this situation, low-power portable containerized MGs can provide an emergency solution so that for two or three days, electricity and/or potable water pumps can be provided to relieve the damaged area. However, resilience in front of extreme grid faults is still a technical challenge for MGs to deal with NDs. Therefore, the main concerns and current challenges for increasing renewable energy penetration and resiliency in power systems should be targeted to ensure high and unprecedented levels of system resiliency and recovery under NDs and grid faults. For this purpose, we need resilient energy systems that are robust against these events, moreover, it can keep the power system safe against overall collapse and complete power outages as much as possible. In order to verify the effectiveness of the abovementioned research, the simulation will be carried out by MATLAB/Simulink using simpower toolbox.For experimental verification, the project outcomes will also be implemented on a real-time control and monitoring platform (dSPACE) at CROM facilities. The Ph.D. project is aligned with the project `Microgrid Technologies for Remote Indonesian Islands- Tech-IN www.tech-in.et.aau.dk` which will cope with three main concerns 1) To increase sustainable microgrid solutions while reducing the fossil fuel (diesel, coal, etc) dependence. 2) Increase of electricity access to remote places and islands. 3) Provide high levels of resiliency and availability of electricity supply in front of natural disasters. For this, two case studies will be investigated - Lombok and Medang islands.
Funding: ChiefMinister Merit Scholarships (CMMS), The Punjab Educational Endowment Fund (PEEF), Pakistan.

Sponsored: Ministry of Foreign Affairs of Denmark, DANIDA Fellowship Centre (Project No. 20-M06-AAU) and supported byDANIDA Fellowship Centre and TECHIN Cerner of Research on Microgrids AAUEnergy, Aalborg University, Aalborg Denmark.

Layman's description

The project is entitled Microgrid Technologies for Remote Indonesian Islands – TECH-IN. My research focused on the Planning of Microgrids, Energy Management, and optimization for Resilient Microgrids.

Key findings

Planning of Microgrids, Energy Management, and optimization for Resilient Microgrids
Short titleResilient Microgrids
Effective start/end date01/01/202231/12/2024

UN Sustainable Development Goals

In 2015, UN member states agreed to 17 global Sustainable Development Goals (SDGs) to end poverty, protect the planet and ensure prosperity for all. This project contributes towards the following SDG(s):

  • SDG 7 - Affordable and Clean Energy
  • SDG 11 - Sustainable Cities and Communities
  • SDG 13 - Climate Action
  • SDG 17 - Partnerships for the Goals


  • Microgrids
  • Remote collaboration
  • Natural Disaster
  • Renewable energy sources
  • Resilient Control
  • Solar Energy
  • Wind Energy
  • Battery Energy storage Systems
  • Ad-Hoc Microgrids
  • Community Microgrids
  • Network Microgrids
  • Planning
  • Operation Management
  • Optimization
  • Energy management
  • Power Electronics
  • HOMER Pro
  • HOMER Grid
  • MATLAB Simulink
  • Games


Explore the research topics touched on by this project. These labels are generated based on the underlying awards/grants. Together they form a unique fingerprint.