Design of quantum dot cellular automata based fault tolerant convolution encoders for secure nanocomputing
DOI10.1142/S021974992050032XzbMath1457.81023OpenAlexW3088391623MaRDI QIDQ5149403
Publication date: 11 February 2021
Published in: International Journal of Quantum Information (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1142/s021974992050032x
energy dissipationfault analysisquantum cellsquantum dot cellular automataconvolution encodernanocomputing
Network design and communication in computer systems (68M10) Quantum computation (81P68) Cellular automata (computational aspects) (68Q80) Reliability, testing and fault tolerance of networks and computer systems (68M15) Quantum dots, waveguides, ratchets, etc. (81Q37) Statistical mechanics of nanostructures and nanoparticles (82D80) Quantum coding (general) (81P70) Networks and circuits as models of computation; circuit complexity (68Q06)
Uses Software
Cites Work
- An optimized three-level design of decoder based on nanoscale quantum-dot cellular automata
- Conservative logic
- Modular adder designs using optimal reversible and fault tolerant gates in field-coupled QCA nanocomputing
- Designing nanoscale counter using reversible gate based on quantum-dot cellular automata
- Fault-tolerant design of a shift register at the nanoscale based on quantum-dot cellular automata
- Modular design of ultra-efficient reversible full adder-subtractor in QCA with power dissipation analysis
- Design of novel coplanar counter circuit in quantum dot cellular automata technology
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