INTERNATIONAL JOURNAL OF ADVANCE RESEARCH
IN MULTIDISCIPLINARY

Quantum computing is at the very edge of technological progress, promising to revolutionize several disciplines, including microprocessor performance. This research paper explores the transition from classical to quantum computing paradigms, emphasizing the capabilities of quantum computing to enhance microprocessor efficiency and speed. This research intends to clarify the transformational influence of quantum computing on microprocessor design and overall processing performance by incorporating quantum concepts such as superposition, entanglement, and quantum interference. The study analyses the possible obstacles and constraints associated with incorporating quantum computing into microprocessor architecture. It also emphasizes the need for more research and development to properly exploit the potential of quantum computing in revolutionizing microprocessor technology. The study explores how quantum computing can potentially address current limitations in traditional microprocessor design, such as scalability and energy efficiency. Overall, this research sheds light on the promising future of quantum computing in enhancing computational capabilities and advancing technology. By overcoming these challenges, quantum computing has the potential to significantly improve processing speeds and efficiency in microprocessor design. Continued advancements in this field could lead to groundbreaking innovations in various industries that rely on high-performance computing. Quantum computing has the potential to transform industries including encryption, drug discovery, and artificial intelligence. As researchers continue to push the frontiers of quantum computing, we may anticipate even more significant applications in the near future.