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Synaptic AI: Bridging Neural Dynamics and Deep Learning for Next- Generation Computation.

 Authors:

Gaurang Kumbhar¹, Srushti Shelke², Priti Totawad³

¹Department of Artificial Intelligence and Data Science, ISBM College of Engineering

²Department of Artificial Intelligence and Data Science, ISBM College of Engineering

³Department of Artificial Intelligence and Data Science, ISBM College of Engineering

ABSTRACT: The escalating computational and power demands of deep learning algorithms challenge traditional von Neumann architectures, which separate memory and processing units. This structural bottleneck, often referred to as the "von Neumann bottleneck," hampers data throughput and energy efficiency—especially in real-time, data-intensive AI applications. Neuromorphic computing, inspired by the human brain's architecture and function, offers a promising alternative. Unlike conventional systems, neuromorphic models integrate processing and memory, enabling highly parallel, event-driven computation. This design drastically reduces latency and power consumption. The brain's remarkable ability to process complex patterns using minimal energy motivates the development of neuromorphic hardware. Such systems emulate neural dynamics through spiking neural networks (SNNs), asynchronous data handling, and adaptive learning mechanisms. Deep learning excels at extracting rich features from massive datasets but suffers from high training costs and scalability concerns. Neuromorphic systems, with their real- time responsiveness and efficiency, can serve as ideal platforms to deploy and potentially train these models at the edge.The fusion of deep learning's representational power with neuromorphic computing's efficiency could pave the way for the next generation of intelligent systems. These hybrid models hold potential for real-time, adaptive learning in resource- constrained environments—enabling smarter edge devices, autonomous systems, and brain-inspired AI. Together, they could overcome existing hardware bottlenecks, offering transformative advancements in AI's reach, performance, and sustainability.

Keywords: Deep Learning, Neuromorphic Computing, Artificial Intelligence, Machine Learning, Efficient Computing, Edge Computing.