Algebraic Multigrid and the Future of Computer Science
Autour(s)
- Chidi Yun, Miki Shun, Keypi Jackson, Ladson Newiduom, Ibrina Browndi
Abstract
Algebraic Multigrid (AMG) is a powerful computational technique used in computer science to solve linear systems of equations quickly and efficiently. This article provides an in-depth review of AMG, including its history, principles, and current state-of-the-art techniques. Additionally, the article explores the future of computer science, particularly with respect to the continued evolution of AMG and its impact on the field. The literature review reveals that AMG is still a popular and actively researched topic in computer science. Recent research has focused on improving the performance and scalability of AMG by developing new algorithms and parallel computing techniques. Algebraic Multigrid (AMG) is a powerful computational technique used in computer science to solve linear systems of equations quickly and efficiently. This article provides an in-depth review of AMG, including its history, principles, and current state-of-the-art techniques. Additionally, the article explores the future of computer science, particularly with respect to the continued evolution of AMG and its impact on the field. The literature review reveals that AMG is still a popular and actively researched topic in computer science. Recent research has focused on improving the performance and scalability of AMG by developing new algorithms and parallel computing techniques. Algebraic Multigrid (AMG) is a powerful and efficient method for solving linear systems of equations that arise in many scientific and engineering applications. This article explores the potential of AMG as a tool for addressing the increasingly complex and large-scale problems that are emerging in the field of computer science. Through a literature review and analysis of recent developments in AMG research, this article highlights the potential of AMG to enable breakthroughs in areas such as machine learning, big data analytics, and high-performance computing. The research methodology involves benchmarking, performance analysis, and simulation to evaluate the performance of AMG in a variety of computational settings. The results demonstrate the significant potential of AMG as a key technology for driving the future of computer science.