QCADEsigner: a rapid design and simulation tool for quantum-dot cellular automata. QCADesigner is the product of an ongoing research effort by the Walus Lab at the University of British Columbia to create a design and simulation tool for Quantum Dot Cellular Automata (QCA). This tool is still under development and is provided free of cost to the research community “as is”. QCA is an emerging concept in computational nanotechnology for the realization of a computer using arrays of nano-scale QCA cells. These QCA cells are capable of performing all complex computational functions required for general-purpose computation (majority function, Inversion, and fan-out). The QCADesigner tool facilitates rapid design, layout and simulation of QCA circuits by providing powerful CAD features available in more complex circuit design tools.

References in zbMATH (referenced in 27 articles )

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  1. Khosroshahy, Milad Bagherian; Abdoli, Alireza; Rahmani, Amir Masoud: Design and power analysis of an ultra-high speed fault-tolerant full-adder cell in quantum-dot cellular automata (2022)
  2. Liu, Peng; Ni, Jianguo; Chu, Zhufei: Wire-crossings optimization based on majority-of-five and XOR-of-three primitives in QCA (2022)
  3. Fan, Shuyan; Khamesinia, Maryam Sadat: An efficient design of parallel and serial shift registers based on quantum-dot cellular automata (2021)
  4. Gao, Mingming; Wang, Jinling; Fang, Shaojun; Nan, Jingchang; Daming, Li: A new nano design for implementation of a digital comparator based on quantum-dot cellular automata (2021)
  5. Seyedi, Saeid; Navimipour, Nima Jafari: Designing a new 4:2 compressor using an efficient multi-layer full-adder based on nanoscale quantum-dot cellular automata (2021)
  6. Ronaghi, Niloofar; Faghih Mirzaee, Reza; Sayedsalehi, Samira: Triangular quantum-dot cellular automata wire for standard ternary logic (2020)
  7. Zhang, Yongqiang; Deng, Feifei; Cheng, Xin; Xie, Guangjun: A coplanar XOR using NAND-NOR-inverter and five-input majority voter in quantum-dot cellular automata technology (2020)
  8. Adelnia, Yaser; Rezai, Abdalhossein: A novel adder circuit design in quantum-dot cellular automata technology (2019)
  9. Khan, Angshuman; Mandal, Sikta: Robust multiplexer design and analysis using quantum dot cellular automata (2019)
  10. Li, Ting; Kornovich, Roy: An optimized design of serial-input-serial-output (SISO) and parallel-input-parallel-output (PIPO) shift registers based on quantum dot cellular automata nanotechnology (2019)
  11. Mosleh, Mohammad: A novel full adder/subtractor in quantum-dot cellular automata (2019)
  12. Pain, Puspak; Das, Kunal; Sadhu, Arindam; Kanjilal, Maitreyi Ray; De, Debashis: Novel true random number generator based hardware cryptographic architecture using quantum-dot cellular automata (2019)
  13. Prakash, G.; Darbandi, Mehdi; Gafar, N.; Jabarullah, Noor H.; Jalali, Mohammad Reza: Retracted: A new design of 2-bit universal shift register using rotated majority gate based on quantum-dot cellular automata technology (2019)
  14. Raj, Marshal; Gopalakrishnan, Lakshminarayanan; Ko, Seok-Bum: Fast quantum-dot cellular automata adder/subtractor using novel fault tolerant exclusive-or gate and full adder (2019)
  15. Wang, Lei; Xie, Guangjun: A power-efficient single layer full adder design in field-coupled QCA nanocomputing (2019)
  16. Yang, Binfeng; Afrooz, Sonia: A new coplanar design of multiplier based on nanoscale quantum-dot cellular automata (2019)
  17. Afrooz, Sonia; Navimipour, Nima Jafari: Fault-tolerant design of a shift register at the nanoscale based on quantum-dot cellular automata (2018)
  18. Bahadori, Golnaz; Houshmand, Monireh; Zomorodi-Moghadam, Mariam: Design of a fault-tolerant reversible control unit in molecular quantum-dot cellular automata (2018)
  19. Bahar, Ali Newaz; Laajimi, Radhouane; Abdullah-Al-Shafi, Md.; Ahmed, Kawsar: Toward efficient design of flip-flops in quantum-dot cellular automata with power dissipation analysis (2018)
  20. Gholamnia Roshan, Mojtaba; Gholami, Mohammad: Novel D latches and D flip-flops with set and reset ability in QCA nanotechnology using minimum cells and area (2018)

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