Learning in Energy-Efficient Neuromorphic Computing: Algorithm and Architecture Co-Design (IEEE Press) - Hardcover

Über die Autorin bzw. den Autor

NAN ZHENG, PhD, received a B. S. degree in Information Engineering from Shanghai Jiao Tong University, China, in 2011, and an M. S. and PhD in Electrical Engineering from the University of Michigan, Ann Arbor, USA, in 2014 and 2018, respectively. His research interests include low-power hardware architectures, algorithms and circuit techniques with an emphasis on machine-learning applications.

PINAKI MAZUMDER, PhD, is a professor in the Department of Electrical Engineering and Computer Science at The University of Michigan, USA. His research interests include CMOS VLSI design, semiconductor memory systems, CAD tools and circuit designs for emerging technologies including quantum MOS, spintronics, spoof plasmonics, and resonant tunneling devices.

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Explains current co-design and co-optimization methodologies for building hardware neural networks and algorithms for machine learning applications

This book focuses on how to build energy-efficient hardware for neural networks with learning capabilities???and provides co-design and co-optimization methodologies for building hardware neural networks that can learn. Presenting a complete picture from high-level algorithm to low-level implementation details, Learning in Energy-Efficient Neuromorphic Computing: Algorithm and Architecture Co-Design also covers many fundamentals and essentials in neural networks (e.g. deep learning), as well as hardware implementation of neural networks.

The book begins with an overview of neural networks followed by a discussion of algorithms for utilizing and training rate-based artificial neural networks. Next comes an introduction to various options for executing neural networks, ranging from general-purpose processors to specialized hardware, from digital accelerator to analog accelerator. A design example on building energy- efficient accelerator for adaptive dynamic programming with neural networks is also presented. An examination of fundamental concepts and popular learning algorithms for spiking neural networks follows, along with a look at the hardware for spiking neural networks. Then comes a chapter offering readers three design examples (two of which are based on conventional CMOS, and one on emerging nanotechnology) to implement the learning algorithm found in the previous chapter. The book concludes with an outlook on the future of neural network hardware.

• Includes a cross-layer survey of hardware accelerators for neuromorphic algorithms
• Covers the co-design of architecture and algorithms with emerging devices for much-improved computing efficiency
• Focuses on the co-design of algorithms and hardware, which is especially critical for using emerging devices such as traditional memristors or diffusive memristors, for neuromorphic computing

Learning in Energy-Efficient Neuromorphic Computing: Algorithm and Architecture Co-Design is an ideal resource for researchers, scientists, software engineers, and hardware engineers dealing with the ever-increasing demands on power consumption and response time. It is also excellent for teaching and training undergraduate and graduate students about the latest generation of neural networks with powerful learning capabilities.