Assist. Prof. Dr. Ahmad Mousavi | Bilevel Optimization | Best Researcher Award

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Assist. Prof. Dr. Ahmad Mousavi | Bilevel Optimization | Best Researcher Award

Assistant Professor, American University, United States

Assist. Prof. Dr. Ahmad Mousavi is an Assistant Professor in the Department of Mathematics and Statistics at American University with a Ph.D. in Applied Mathematics from the University of Maryland, Baltimore County, and postdoctoral training at the University of Florida and the University of Minnesota Institute for Mathematics and its Applications. Over the last decade, Assist. Prof. Dr. Ahmad Mousavi has combined deep expertise in large-scale optimization, sparse recovery, and data science with leadership in machine learning, natural language processing, and quantum computing to advance both theoretical and applied research. His professional experience includes directing online master’s programs in data science, serving as a reviewer for leading journals such as Neural Networks and Journal of Optimization Theory and Applications, and mentoring graduate students on fairness, pruning, and multimodal misinformation detection.  Research skills include algorithm development, programming in Python/R/Matlab, statistical modelling, deep learning frameworks, and high-performance computing. Assist. Prof. Dr. Ahmad Mousavi has earned recognition through travel grants, competitive fellowships, and teaching awards and has built an international collaboration network with researchers in North America, Europe, and Asia. He has published extensively in journals such as Journal of Industrial and Management Optimization, Soft Computing, and ESAIM: Control, Optimisation and Calculus of Variations, Over 9 publications, 49 citations, and an h-index of 4 in scopus.

Profile: GOOGLE SCHOLAR | SCOPUS | ORCID

Featured Publications

Mousavi, A. (2022). Multi-objective enhanced interval optimization problem. Journal of Optimization, 45(3), 215-230. Citations: 19.

Mousavi, A. (2023). Prediction-based mean-value-at-risk portfolio optimization using machine learning regression algorithms for multi-national stock markets. Applied Soft Computing, 124, 109832. Citations: 9.

Mousavi, A. (2024). Implementation of machine learning in ℓ∞-based sparse Sharpe ratio portfolio optimization: A case study on Indian stock market. Expert Systems with Applications, 246, 123566. Citations: 1.

Mousavi, A. (2023). Parametric approach for multi-objective enhanced interval linear fractional programming problem. Annals of Operations Research, 321(1), 245-262. Citations: 1.

Xinyu Zhu | Heterogeneous Computing | Best Researcher Award

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Dr. Xinyu Zhu | Heterogeneous Computing | Best Researcher Award

PhD at Beihang University, China

Xinyu Zhu is a Ph.D. candidate at Beihang University, Beijing, China, specializing in heterogeneous computing, system-on-chip (SoC) design, and low-power systems. He earned his Master’s degree in Circuits and Systems from Hefei University of Technology in 2020. His research focuses on optimizing hardware architectures, particularly in the context of efficient computing systems that balance performance and energy consumption. His work, which includes innovative designs for both accurate and approximate computing, aims to advance the field of embedded systems, especially in applications requiring high performance and low power, such as artificial intelligence (AI) reasoning accelerators.

Profile

Scopus

Education

Xinyu Zhu’s educational background is grounded in electronics and computer systems. He received his M.S. degree in Circuits and Systems from Hefei University of Technology in 2020. His current doctoral studies at Beihang University delve into heterogeneous computing and system-on-chip design. His academic journey is driven by a desire to contribute significantly to the development of efficient, low-power computing solutions, particularly for embedded systems and AI applications. His work bridges theory and practical implementation, emphasizing both high performance and reduced hardware resource consumption.

Experience

Throughout his academic career, Xinyu Zhu has contributed to several high-impact projects in the field of system-on-chip design and low-power computing. His research has focused on enhancing computing efficiency while minimizing power and hardware resource consumption. He has been involved in both consultancy and industry-sponsored projects, working on cutting-edge solutions for energy-efficient computing. These collaborations have shaped his expertise in designing multipliers for both accurate and approximate computations, aiming to cater to the growing demands of embedded systems and AI accelerators. Zhu’s ability to collaborate across academia and industry has allowed him to translate theoretical advancements into practical applications.

Research Interest

Xinyu Zhu’s primary research interests lie in the intersection of heterogeneous computing, system-on-chip (SoC) design, and approximate computing. His work investigates how to optimize computing architectures to balance performance, accuracy, and energy consumption, a critical concern for modern embedded systems and AI accelerators. Zhu has focused particularly on the design of radix-4 encoded multipliers and zero-skipping multipliers, which have significant implications for both high-precision and approximate computing. His research aims to create efficient computing systems that can be applied to real-world scenarios, particularly in AI-driven technologies where power efficiency is crucial.

Award

Xinyu Zhu has been nominated for the AI Data Scientist Award in the Best Researcher category, recognizing his contributions to the field of low-power, high-performance computing. His innovative designs for radix-4 encoded and zero-skipping multipliers have not only advanced traditional computing but also provided significant applications in approximate computing, an area of growing importance in AI and embedded systems. His work has demonstrated deep optimization of computing structures, leading to lower power consumption and reduced hardware resource requirements, positioning him as a promising researcher in the field of system-on-chip design and AI accelerators.

Publication

Xinyu Zhu has contributed to various scholarly articles and journals. His research has been published in prominent journals, reflecting the significance of his work in heterogeneous computing and low-power system design. Some of his notable publications include:

Xinyu Zhu et al., “Design of Radix-4 Encoded Multipliers for Efficient Computing,” Journal of Low Power Electronics, 2023.

Xinyu Zhu et al., “Optimization of Zero-Skipping Multipliers for AI Accelerators,” IEEE Transactions on Circuits and Systems, 2022.

His work has been cited in various related fields, underlining the influence of his research in advancing system design for AI and embedded systems. His articles are often referenced for their innovative approach to power-efficient computing, especially in the context of approximate computing methods.

Conclusion

Zhu’s work represents a significant contribution to the field of heterogeneous computing and low-power design, with a particular emphasis on system-on-chip and approximate computing. His innovative designs for radix-4 encoded and zero-skipping multipliers have the potential to revolutionize how computing systems handle performance and energy efficiency, especially in the context of artificial intelligence accelerators. Through his dedication to research and collaboration with industry, Zhu continues to push the boundaries of what is possible in energy-efficient computing. His contributions provide critical support for the development of high-performance embedded systems and AI-driven technologies, marking him as a leading figure in his field.