Your search keyword '"Kelsey Scharnhorst"' showing total 4 results

1. Atomic switch networks as complex adaptive systems

Author

Masakazu Aono, James K. Gimzewski, Renato J. Aguilera, Eric J. Sandouk, Kelsey Scharnhorst, Juan Pablo Carbajal, and Adam Z. Stieg

Subjects

010302 applied physics, Physics and Astronomy (miscellaneous), Computer science, Distributed computing, General Engineering, General Physics and Astronomy, Ranging, 02 engineering and technology, Feedback loop, 021001 nanoscience & nanotechnology, 01 natural sciences, Power law, Overcurrent, 0103 physical sciences, Key (cryptography), Distributed memory, 0210 nano-technology, Complex adaptive system, Voltage

Abstract

Complexity is an increasingly crucial aspect of societal, environmental and biological phenomena. Using a dense unorganized network of synthetic synapses it is shown that a complex adaptive system can be physically created on a microchip built especially for complex problems. These neuro-inspired atomic switch networks (ASNs) are a dynamic system with inherent and distributed memory, recurrent pathways, and up to a billion interacting elements. We demonstrate key parameters describing self-organized behavior such as non-linearity, power law dynamics, and multistate switching regimes. Device dynamics are then investigated using a feedback loop which provides control over current and voltage power-law behavior. Wide ranging prospective applications include understanding and eventually predicting future events that display complex emergent behavior in the critical regime.

Published

2018

2. Nanoarchitectonic atomic switch networks for unconventional computing

Author

James K. Gimzewski, Adam Z. Stieg, Kelsey Scharnhorst, Renato J. Aguilera, Eleanor Demis, and Masakazu Aono

Subjects

010302 applied physics, business.product_category, Computer science, General Engineering, Reservoir computing, Complex system, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, CMOS, Neuromorphic engineering, 0103 physical sciences, Electronic engineering, Waveform, Network switch, 0210 nano-technology, Unconventional computing, business, Efficient energy use

Abstract

Developments in computing hardware are constrained by the operating principles of complementary metal oxide semiconductor (CMOS) technology, fabrication limits of nanometer scaled features, and difficulties in effective utilization of high density interconnects. This set of obstacles has promulgated a search for alternative, energy efficient approaches to computing inspired by natural systems including the mammalian brain. Atomic switch network (ASN) devices are a unique platform specifically developed to overcome these current barriers to realize adaptive neuromorphic technology. ASNs are composed of a massively interconnected network of atomic switches with a density of ∼109 units/cm2 and are structurally reminiscent of the neocortex of the brain. ASNs possess both the intrinsic capabilities of individual memristive switches, such as memory capacity and multi-state switching, and the characteristics of large-scale complex systems, such as power-law dynamics and non-linear transformations of input signals. Here we describe the successful nanoarchitectonic fabrication of next-generation ASN devices using combined top-down and bottom-up processing and experimentally demonstrate their utility as reservoir computing hardware. Leveraging their intrinsic dynamics and transformative input/output (I/O) behavior enabled waveform regression of periodic signals in the absence of embedded algorithms, further supporting the potential utility of ASN technology as a platform for unconventional approaches to computing.

Published

2016

3. Atomic switch networks—nanoarchitectonic design of a complex system for natural computing

Author

Adam Z. Stieg, Renato J. Aguilera, Eric J. Sandouk, James K. Gimzewski, Henry O. Sillin, Masakazu Aono, Eleanor Demis, and Kelsey Scharnhorst

Subjects

Network architecture, business.product_category, Materials science, Natural computing, Mechanical Engineering, Distributed computing, Complex system, Reservoir computing, Bioengineering, Nanotechnology, General Chemistry, Field (computer science), Structural complexity, Nonlinear system, Mechanics of Materials, General Materials Science, Network switch, Electrical and Electronic Engineering, business

Abstract

Self-organized complex systems are ubiquitous in nature, and the structural complexity of these natural systems can be used as a model to design new classes of functional nanotechnology based on highly interconnected networks of interacting units. Conventional fabrication methods for electronic computing devices are subject to known scaling limits, confining the diversity of possible architectures. This work explores methods of fabricating a self-organized complex device known as an atomic switch network and discusses its potential utility in computing. Through a merger of top-down and bottom-up techniques guided by mathematical and nanoarchitectonic design principles, we have produced functional devices comprising nanoscale elements whose intrinsic nonlinear dynamics and memorization capabilities produce robust patterns of distributed activity and a capacity for nonlinear transformation of input signals when configured in the appropriate network architecture. Their operational characteristics represent a unique potential for hardware implementation of natural computation, specifically in the area of reservoir computing-a burgeoning field that investigates the computational aptitude of complex biologically inspired systems.

Published

2015

4. Nanoarchitectonic atomic switch networks for unconventional computing.

Author

Eleanor C. Demis, Renato Aguilera, Kelsey Scharnhorst, Masakazu Aono, Adam Z. Stieg, and James K. Gimzewski

Abstract

Developments in computing hardware are constrained by the operating principles of complementary metal oxide semiconductor (CMOS) technology, fabrication limits of nanometer scaled features, and difficulties in effective utilization of high density interconnects. This set of obstacles has promulgated a search for alternative, energy efficient approaches to computing inspired by natural systems including the mammalian brain. Atomic switch network (ASN) devices are a unique platform specifically developed to overcome these current barriers to realize adaptive neuromorphic technology. ASNs are composed of a massively interconnected network of atomic switches with a density of ∼109 units/cm2 and are structurally reminiscent of the neocortex of the brain. ASNs possess both the intrinsic capabilities of individual memristive switches, such as memory capacity and multi-state switching, and the characteristics of large-scale complex systems, such as power-law dynamics and non-linear transformations of input signals. Here we describe the successful nanoarchitectonic fabrication of next-generation ASN devices using combined top-down and bottom-up processing and experimentally demonstrate their utility as reservoir computing hardware. Leveraging their intrinsic dynamics and transformative input/output (I/O) behavior enabled waveform regression of periodic signals in the absence of embedded algorithms, further supporting the potential utility of ASN technology as a platform for unconventional approaches to computing. [ABSTRACT FROM AUTHOR]

Published

2016