INCREASING THE PERFORMANCE OF COMMUNICATION SYSTEMS BASED ON SPIN DYNAMICS EQUATIONS

Abstract

The exponential growth of global data traffic, driven by cloud computing, artificial intelligence, and the Internet of Things, has placed unprecedented demands on communication systems and computational infrastructures. Traditional charge-based electronic technologies are increasingly constrained by physical limits such as Joule heating, signal delay, and energy inefficiency. This paper proposes an alternative approach based on the application of spintronics and the use of spin dynamics equations for modeling and optimizing communication processes [1,2]. By leveraging spin-based information encoding and transfer mechanisms, it is possible to significantly enhance system performance. The paper presents a theoretical framework, analyzes potential improvements in speed and efficiency, and discusses implementation challenges.

Keywords

spintronics, spin dynamics, communication systems, high-speed networks, computational efficiency, quantum-inspired computing, data transmission, network optimization.

References

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