Reservoir Computing : Theory, Physical Implementations, and Applications / edited by Kohei Nakajima, Ingo Fischer.

Format:

Book

Contributor:

Nakajima, Kohei., Editor.

Fischer, Ingo, Editor.

SpringerLink (Online service)

Series:

Computer Science (SpringerNature-11645)

Natural computing series

Natural Computing Series

Language:

English

Subjects (All):

Artificial intelligence.

Automatic control.

Robotics.

Automation.

Machine learning.

Neural networks (Computer science).

Spintronics.

Artificial Intelligence.

Control, Robotics, Automation.

Machine Learning.

Mathematical Models of Cognitive Processes and Neural Networks.

Local Subjects:

Artificial Intelligence.

Control, Robotics, Automation.

Machine Learning.

Robotics.

Mathematical Models of Cognitive Processes and Neural Networks.

Spintronics.

Physical Description:

1 online resource (XIX, 458 pages) : 161 illustrations, 127 illustrations in color.

Edition:

1st ed. 2021.

Contained In:

Springer Nature eBook

Place of Publication:

Singapore : Springer Nature Singapore : Imprint: Springer, 2021.

System Details:

text file PDF

Summary:

This book is the first comprehensive book about reservoir computing (RC). RC is a powerful and broadly applicable computational framework based on recurrent neural networks. Its advantages lie in small training data set requirements, fast training, inherent memory and high flexibility for various hardware implementations. It originated from computational neuroscience and machine learning but has, in recent years, spread dramatically, and has been introduced into a wide variety of fields, including complex systems science, physics, material science, biological science, quantum machine learning, optical communication systems, and robotics. Reviewing the current state of the art and providing a concise guide to the field, this book introduces readers to its basic concepts, theory, techniques, physical implementations and applications. The book is sub-structured into two major parts: theory and physical implementations. Both parts consist of a compilation of chapters, authored by leading experts in their respective fields. The first part is devoted to theoretical developments of RC, extending the framework from the conventional recurrent neural network context to a more general dynamical systems context. With this broadened perspective, RC is not restricted to the area of machine learning but is being connected to a much wider class of systems. The second part of the book focuses on the utilization of physical dynamical systems as reservoirs, a framework referred to as physical reservoir computing. A variety of physical systems and substrates have already been suggested and used for the implementation of reservoir computing. Among these physical systems which cover a wide range of spatial and temporal scales, are mechanical and optical systems, nanomaterials, spintronics, and quantum many body systems. This book offers a valuable resource for researchers (Ph.D. students and experts alike) and practitioners working in the field of machine learning, artificial intelligence, robotics, neuromorphic computing, complex systems, and physics.

Contents:

Chapter 1: The cerebral cortex: A delay coupled recurrent oscillator network?

Chapter 2: Cortico-Striatal Origins of Reservoir Computing, Mixed Selectivity and Higher Cognitive Function

Chapter 3: Reservoirs learn to learn

Chapter 4: Deep Reservoir Computing

Chapter 5: On the characteristics and structures of dynamical systems suitable for reservoir computing

Chapter 6: Reservoir Computing for Forecasting Large Spatiotemporal Dynamical Systems

Chapter 7: Reservoir Computing in Material Substrates

Chapter 8: Physical Reservoir Computing in Robotics

Chapter 9: Reservoir Computing in MEMS

Chapter 10: Neuromorphic Electronic Systems for Reservoir Computing

Chapter 11: Reservoir Computing using Autonomous Boolean Networks Realized on Field-Programmable Gate Arrays

Chapter 12: Programmable Fading Memory in Atomic Switch Systems for Error Checking Applications

Chapter 13: Reservoir computing leveraging the transient non-linear dynamics of spin-torque nano-oscillators

Chapter 14: Reservoir computing based on spintronics technology

Chapter 15: Reservoir computing with dipole-coupled nanomagnets

Chapter 16: Performance improvement of delay-based photonic reservoir computing

Chapter 17: Computing with integrated photonic reservoirs

Chapter 18: Quantum reservoir computing

Chapter 19: Towards NMR Quantum Reservoir Computing.

Other Format:

Printed edition:

ISBN:

978-981-13-1687-6

9789811316876

Access Restriction:

Restricted for use by site license.