Title:Memristive Nanowire Network for Energy Efficient Audio Classification: Pre-Processing-Free Reservoir Computing with Reduced Latency

Abstract:Speech recognition is a key challenge in natural language processing, requiring low latency, efficient computation, and strong generalization for real-time applications. While software-based artificial neural networks (ANNs) excel at this task, they are computationally intensive and depend heavily on data pre-processing. Neuromorphic computing, with its low-latency and energy-efficient advantages, holds promise for audio classification. Memristive nanowire networks, combined with pre-processing techniques like Mel-Frequency Cepstrum Coefficient extraction, have been widely used for associative learning, but such pre-processing can be power-intensive, undermining latency benefits. This study pioneers the use of memristive and spatio-temporal properties of nanowire networks for audio signal classification without pre-processing. A nanowire network simulation is paired with three linear classifiers for 10-class MNIST audio classification and binary speaker generalization tests. The hybrid system achieves significant benefits: excellent data compression with only 3% of nanowire output utilized, a 10-fold reduction in computational latency, and up to 28.5% improved classification accuracy (using a logistic regression classifier). Precision and recall improve by 10% and 17% for multispeaker datasets, and by 24% and 17% for individual speaker datasets, compared to raw data classifiers. This work provides a foundational proof of concept for utilizing memristive nanowire networks (NWN) in edge-computing devices, showcasing their potential for efficient, real-time audio signal processing with reduced computational overhead and power consumption, and enabling the development of advanced neuromorphic computing solutions.