Advancing Artificial Intelligence: The Potential of Brain-Inspired Architectures and Neuromorphic Computing for Adaptive, Efficient Systems
DOI:
https://doi.org/10.62802/tfme0736Keywords:
Machine Learning Integration, Biologically Plausible Models, Autonomous Systems, Neuromorphic Computing, Brain-Inspired AI, Robotics, Medical Diagnostics, Energy-Efficient Hardware, Artificial IntelligenceAbstract
Brain-inspired AI architecture, also known as neuromorphic computing, seeks to emulate the structure and functionality of the human brain to create more efficient, adaptive, and intelligent systems. Unlike traditional AI models that rely on conventional computing frameworks, brain-inspired architectures leverage neural networks and synapse-like connections to perform computations more similarly to biological brains. This approach offers significant advantages, including lower power consumption, improved learning capabilities, and enhanced problem-solving efficiency, particularly in tasks that require complex pattern recognition and cognitive processes. This paper explores the key components of brain-inspired AI architectures, such as spiking neural networks (SNNs) and neuromorphic hardware, and reviews the latest advancements in this field. We examine their applications across diverse domains, including robotics, autonomous systems, and medical diagnostics, where brain-like adaptability and real-time learning are critical. Additionally, we analyze the challenges associated with scaling these architectures, including hardware constraints and the complexity of accurately mimicking human brain functionality. The potential for combining brain-inspired AI with current machine learning models is also discussed, highlighting future directions for achieving more advanced, efficient, and human-like artificial intelligence systems. This research contributes to the growing body of knowledge on neuromorphic computing and its promise in shaping the future of AI technologies.
Moreover, brain-inspired AI architectures have the potential to surpass traditional AI systems in terms of real-time decision-making and learning efficiency, particularly in environments that require adaptive behavior. The use of spiking neural networks (SNNs) in these architectures allows for more biologically plausible models of neuron activity, which can lead to advancements in sensory processing and autonomous decision-making. As neuromorphic hardware continues to evolve, integrating it with existing AI frameworks could enhance both performance and scalability. However, replicating the brain's full complexity remains a significant challenge, particularly in terms of creating energy-efficient hardware capable of supporting large-scale neural networks. Despite these challenges, the development of brain-inspired AI promises to bridge the gap between artificial and human intelligence, offering transformative possibilities for various industries.
References
Hidalgo, I. (2023). Sustainable artificial intelligence systems: an energy efficiency approach.. https://doi.org/10.36227/techrxiv.24610899.v1
Yokoyama, A., Ferro, M., Paula, F., Vieira, V., & Schulze, B. (2023). Investigating hardware and software aspects in the energy consumption of machine learning: a green ai‐centric analysis. Concurrency and Computation Practice and Experience, 35(24). https://doi.org/10.1002/cpe.7825
Chen, Z. (2023). Hardware accelerated optimization of deep learning model on artificial intelligence chip. Frontiers in Computing and Intelligent Systems, 6(2), 11-14. https://doi.org/10.54097/fcis.v6i2.03