Anas N. Al-Rabadi
Department of Computer Engineering, The University of Jordan, Amman – Jordan & Department of Renewable Energy Engineering, Isra University – Jordan
ABSTRACT
Novel realizations of concurrent computations utilizing three-dimensional lattice networks and their corresponding carbon-based field emission controlled switching is introduced in this article. The formalistic ternary nano-based implementation utilizes recent findings in field emission and nano applications which include carbon-based nanotubes and nanotips for three-valued lattice computing via field-emission methods. The presented work implements multi-valued Galois functions by utilizing concurrent nano-based lattice systems, which use two-to-one controlled switching via carbon-based field emission devices by using nano-apex carbon fibers and carbon nanotubes that were presented in the first part of the article. The introduced computational extension utilizing many-to-one carbon field-emission devices will be further utilized in implementing congestion-free architectures within the third part of the article. The emerging nano-based technologies form important directions in low-power compact-size regular lattice realizations, in which carbon-based devices switch less-costly and more-reliably using much less power than silicon-based devices. Applications include low-power design of VLSI circuits for signal processing and control of autonomous robots.
KEYWORDS
Carbon nano-apex emission, Concurrent computing, Formal symmetrization, Lattice networks, Regularity
ORIGINAL SOURCE URL: https://aircconline.com/vlsics/V11N6/11620vlsi01.pdf
http://airccse.org/journal/vlsi/vol11.html
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