Cellular Nanoscale Sensory Wave Computing

This fresh perspective of sensory computing successfully bridges the gap between nanoscale devices and CMOS integrated circuits. Practical and complex algorithms are also discussed, in addition to new developments like the nanoscale antenna.

This book is loosely based on a Multidisciplinary University Research Initiative (MURI) project and a few supplemental projects sponsored by the Of?ce of Naval Research (ONR) during the time frame of 20042009. The initial technical scope and vision of the MURI project was formulated by Drs. Larry Cooper and Joel Davis, both program of?cers at ONR at the time. The unifying theme of this MURI project and its companionefforts is the concept of cellular nonlinear/neuralnetwork (CNN) technology and its various extensions and chip implementations, including nanoscale sensors and the broadening ?eld of cellular wave computing. In recent years, CNN-based vision system drew much attention from vision scientists to device technologists and computer architects. Due to its early - plementation in a two-dimensional (2D) topography, it found success in early vision technologyapplications, such as focal-plane arrays, locally adaptable sensor/ processor integration, resulting in extremely high frame rates of 10,000 frames per second. More recently it drew increasing attention from computer architects, due to its intrinsic local interconnect architecture and parallel processing paradigm. As a result, a few spin-off companies have already been successful in bringing cel- lar wave computing and CNN technology to the market. This book aims to capture some of the recent advances in the ?eld of CNN research and a few select areas of applications.

Discusses the combination of sensing and computation on a single chip, particularly an entire vision system on a chip Addresses the cellular wave computing concept and architecture in regards to emerging post-CMOS nanoelectronics architecture as well as the many thousand core chips Describes many new developments, such as the nanoscale antenna and 3D monolithic integration of sensing and computing Presents the practical and complex algorithms for mission critical applications running on the new cellular visual microprocessors as well as on the 1024 core FPGA Covers a new kind of computer science and algorithmic base that is emerging for million processor systems with several thousand processor chips Includes a special aspect on biological relevance which explains the multichannel processing in a mammalian retina in connection to the cellular wave computing paradigm

Klappentext

In this book the emerging and converging architecture of morphic cellular wave computers based on the concept of Cellular Neural/Nonlinear Network (CNN) is introduced in a practical way. The authors include descriptions of hardware architectures, software algorithms, as well as a possible new CNN cell based on memristor. The first single chip cellular wave computer- a vision system on a chip (VSoC) is also discussed.

Cellular Nanoscale Sensory Wave Computing is a result of a Multidisciplinary University Research Initiative (MURI) project that has been funded by the Office of Naval Research and completed recently. The results manifest a new way of thinking about sensory computing, as well as it is one of the first successful attempts to bridge the gap between nanoscale (smaller than 100 nm) devices and CMOS integrated circuits with stored programmable algorithms and software on the system level.

Inhalt
A Brief History of CNN and ONR.- Cellular Wave Computing in Nanoscale via Million Processor Chips.- Nanoantenna Infrared Detectors.- Memristors: A New Nanoscale CNN Cell.- Circuit Models of Nanoscale Devices.- A CMOS Vision System On-Chip with Multi-Core, Cellular Sensory-Processing Front-End.- Cellular Multi-core Processor Carrier Chip for Nanoantenna Integration and Experiments.- Circuitry Underlying Visual Processing in the Retina.- Elastic Grid-Based Multi-Fovea Algorithm for Real-Time Object-Motion Detection in Airborne Surveillance.- Low-Power Processor Array Design Strategy for Solving Computationally Intensive 2D Topographic Problems.