Quantifying the computational efficacy of nanocomputing channels

“…CMOS interconnects have not grown to Work as fast as the device them 3. Power consumption due to leakage current is significant in the CMOS technology and has no cent percent solution till date [10][11][12][13][14]. Optimistic assumptions indicate that the technology has the potential to break the terahertz barrier.It has low power consumption.Electrons are the main elements in QCA to perform operations and to propagate informations.Dr.Craig Lent at Notre Dame titled Quantum-dot cellular automata, which is a new form of logic gates using quantum dots.The logic unit in QCA is the QCA cell.It is composed of four quantum dots [15][16][17].…”

Design of Coplanar Circuit Switching Network in Quantum Dot Cellular Automata

“…CMOS interconnects have not grown to Work as fast as the device them 3. Power consumption due to leakage current is significant in the CMOS technology and has no cent percent solution till date [10][11][12][13][14]. Optimistic assumptions indicate that the technology has the potential to break the terahertz barrier.It has low power consumption.Electrons are the main elements in QCA to perform operations and to propagate informations.Dr.Craig Lent at Notre Dame titled Quantum-dot cellular automata, which is a new form of logic gates using quantum dots.The logic unit in QCA is the QCA cell.It is composed of four quantum dots [15][16][17].…”

Design of Coplanar Circuit Switching Network in Quantum Dot Cellular Automata

Nanocomputing channel fidelity of QCA code converter circuits under thermal randomness

Design of a loop-based random access memory based on the nanoscale quantum dot cellular automata