I'm an Associate Professor in the Department of Electrical and Mechanical Engineering at Applied Science University (ASU), Bahrain. I hold a Ph.D. in Electrical Engineering from the University of Technology Sydney, Australia (2018), an M.Sc. dual degree from the New York Institute of Technology and Jordan University of Science & Technology (2012), and a B.Eng. from Yarmouk University, Jordan (2008).

Over the years, I’ve taught at various universities in Jordan and Australia, and I’m passionate about research in fault detection for doubly fed induction generators (DFIGs), as well as the design and optimisation of renewable energy systems.

In addition to my academic roles, I’ve held several leadership and administrative positions, including:

- Head of the Electrical Engineering Department

- Director of the Academic Development and Quality Assurance Centre

- Director of International Relations Office

I’m always open to collaboration, knowledge exchange, and contributing to projects that advance higher education and sustainable technologies.

He has published numerous peer-reviewed articles, supervised postgraduate students, and contributed to national energy policy discussions, with particular emphasis on sustainable development and innovative solutions tailored for local communities.

Brief Introduction

Ahmad Salah is an Associate Professor in the Department of Electrical and Mechanical Engineering at Applied Science University (ASU), Bahrain. He is a distinguished scholar in renewable energy systems, fault detection in electrical machines, and sustainable energy solutions tailored for both global and regional contexts. He received his Ph.D. in Electrical Engineering from the University of Technology Sydney (UTS), Australia, in 2018. Prior to that, he earned a dual M.Sc. degree in Electrical Engineering from the New York Institute of Technology (NYIT) and Jordan University of Science & Technology (JUST) in 2012, as well as a B.Eng. in Electrical Engineering from Yarmouk University, Jordan, in 2008.

Dr. Salah’s academic and professional career reflects a commitment to both technical excellence and social responsibility. His expertise lies at the intersection of power systems engineering, renewable energy optimisation, and machine diagnostics, with a particular emphasis on doubly fed induction generators (DFIGs) in wind power applications. Over the past decade, he has combined rigorous research, teaching, and leadership roles to contribute meaningfully to higher education, renewable energy advancement, and international collaboration.

Story about Notable Contributions

Dr. Salah’s career has evolved through a combination of international education, cross-disciplinary research, and institutional leadership. Early in his career, he recognized the pressing need to address global challenges in sustainable energy. His doctoral studies at the University of Technology Sydney gave him a strong foundation in advanced power systems analysis, renewable energy technologies, and intelligent control methods. During this time, he developed a strong interest in renewable energy integration and the detection of operational faults in wind energy systems, which later became one of his signature research themes.

His work on DFIG fault detection and monitoring has been particularly impactful. DFIGs are a central component of many modern wind turbines, and ensuring their reliability is critical for the sustainability of wind power. Dr. Salah pioneered the application of intelligent monitoring techniques, including machine learning and artificial intelligence (AI), to improve fault detection accuracy and minimize downtime in wind energy systems. His contributions have helped reduce maintenance costs, enhance system efficiency, and extend the lifespan of critical renewable energy infrastructure.

In addition to his technical contributions, Dr. Salah has played an influential role in leadership and administration at ASU. He served as Head of the Electrical Engineering Department, where he restructured the academic program to align with international standards and accreditation requirements. As Director of the Academic Development and Quality Assurance Centre, he spearheaded initiatives to improve curriculum design, faculty development, and student learning outcomes. In his role as Director of the International Relations Office, Dr. Salah promoted cross-border collaborations, student exchange programs, and joint research projects, thereby positioning ASU as a hub for global academic engagement.

His teaching has also been widely recognized. Dr. Salah has taught across multiple universities in Jordan, Bahrain, and Australia, where he has mentored undergraduate and postgraduate students in electrical engineering, renewable energy, and smart grid technologies. Many of his students have gone on to pursue successful careers in academia, industry, and government, reflecting his influence as a dedicated educator and mentor.

Dr. Salah’s ability to link local energy challenges with global best practices has made him a sought-after contributor to national and regional discussions on renewable energy policy. In particular, he has focused on the adaptation of hybrid renewable energy systems for arid and semi-arid climates, where factors such as high solar irradiance, dust accumulation, and fluctuating demand patterns create unique challenges. By proposing context-sensitive solutions, he has contributed to the practical deployment of clean energy technologies in communities across the Middle East.

Principal Publications/Works

Dr. Ahmad Salah has authored and co-authored numerous peer-reviewed journal articles and conference papers. His publications cover a diverse set of topics, with a consistent emphasis on renewable energy, fault detection, and optimisation frameworks. Representative themes in his body of work include:

• Fault Detection and Condition Monitoring of Electrical Machines: Developing advanced diagnostic techniques for DFIGs and other machines used in wind and hybrid energy systems.

• Hybrid Renewable Energy Systems: Modelling, simulation, and optimisation of systems combining solar PV, wind, and storage technologies to meet the energy needs of remote or underserved areas.

• Artificial Intelligence in Renewable Energy: Employing AI and machine learning algorithms to improve system design, forecasting, and fault detection in renewable energy applications.

• Smart Grids and Energy Policy: Contributions to the integration of renewable energy into existing grids, including strategies for demand-side management and energy storage.

His research output not only advances theoretical knowledge but also bridges the gap between academic innovation and real-world application. Several of his works have been cited in policy reports and technical guidelines, further illustrating their relevance.

Dr. Salah has also supervised postgraduate students whose research covers emerging areas such as microgrid optimisation, smart grid resilience, and predictive maintenance of renewable energy assets. Through this mentorship, he has helped cultivate the next generation of renewable energy scholars and practitioners.

Implications for Sciences, Humanities, and Society

The implications of Dr. Salah’s work are both technical and societal. Scientifically, his contributions to fault detection and optimisation in renewable energy systems advance the reliability and efficiency of technologies that are central to the global clean energy transition. His integration of machine learning with traditional power system models exemplifies the growing importance of interdisciplinary approaches to engineering problems.

From a societal perspective, Dr. Salah’s emphasis on sustainable development aligns with global efforts to mitigate climate change and ensure energy equity. His research on hybrid systems and locally tailored renewable energy solutions contributes directly to energy security in developing regions, particularly in the Middle East and North Africa (MENA), where communities face unique climatic and infrastructural challenges.

In the humanities and education domains, his leadership in quality assurance and international relations has implications for the future of higher education. By raising standards, promoting global collaboration, and fostering inclusive academic environments, he has enhanced the role of universities as engines of both knowledge and social progress.

Moreover, his involvement in national energy policy discussions underscores the real-world impact of his research. Policymakers rely on evidence-based insights, and Dr. Salah’s expertise provides crucial guidance for developing strategies that balance economic, environmental, and social priorities. His contributions help shape a future where renewable energy is not just technologically viable but also socially equitable and widely accessible.

Conclusion

Dr. Ahmad Salah exemplifies the integration of academic scholarship, innovative research, and institutional leadership. His career journey reflects a deep commitment to advancing renewable energy technologies while fostering educational excellence and international cooperation. Through his pioneering work in DFIG fault detection, hybrid renewable energy systems, and AI-driven optimisation, he has made significant contributions to both science and society.

His leadership roles at Applied Science University have further strengthened his profile as an academic leader who bridges the gap between technical innovation and institutional development. By combining research excellence with administrative vision and a strong sense of social responsibility, Dr. Salah continues to play an important role in advancing both the scientific and human dimensions of renewable energy and higher education.