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Ghaemi Peykani, Hamidreza, Dorrigiv, Morteza, Danaie, Mohamad. (1404). A Highly Efficient Nanoscale Demultiplexer Architecture based on Quantum-Dot Cellular Automata. هنرهای کاربردی, 5(4), 9-15. doi: 10.22075/mseee.2025.37506.1206
Hamidreza Ghaemi Peykani; Morteza Dorrigiv; Mohamad Danaie. "A Highly Efficient Nanoscale Demultiplexer Architecture based on Quantum-Dot Cellular Automata". هنرهای کاربردی, 5, 4, 1404, 9-15. doi: 10.22075/mseee.2025.37506.1206
Ghaemi Peykani, Hamidreza, Dorrigiv, Morteza, Danaie, Mohamad. (1404). 'A Highly Efficient Nanoscale Demultiplexer Architecture based on Quantum-Dot Cellular Automata', هنرهای کاربردی, 5(4), pp. 9-15. doi: 10.22075/mseee.2025.37506.1206
Ghaemi Peykani, Hamidreza, Dorrigiv, Morteza, Danaie, Mohamad. A Highly Efficient Nanoscale Demultiplexer Architecture based on Quantum-Dot Cellular Automata. هنرهای کاربردی, 1404; 5(4): 9-15. doi: 10.22075/mseee.2025.37506.1206

A Highly Efficient Nanoscale Demultiplexer Architecture based on Quantum-Dot Cellular Automata

Journal of Modeling and Simulation in Electrical and Electronics Engineering
دوره 5، شماره 4 - شماره پیاپی 22، اسفند 2025، صفحه 9-15    اصل مقاله (1.19 M)
نوع مقاله: Research Paper
شناسه دیجیتال (DOI): 10.22075/mseee.2025.37506.1206
نویسندگان
Hamidreza Ghaemi Peykani؛ Morteza Dorrigiv؛ Mohamad Danaie*
Faculty of Electrical and Computer Engineering, Semnan University, Semnan, Iran.
تاریخ دریافت: 03 اردیبهشت 1404،  تاریخ بازنگری: 04 مهر 1404،  تاریخ پذیرش: 22 مهر 1404 
چکیده
This paper presents the design of a demultiplexer (DMUX) structure using Quantum-dot Cellular Automata (QCA) technology. A demultiplexer is a fundamental circuit that receives information from a single input line and routes it to one of several output lines, with the selected output determined by the control inputs. Widely employed in communication systems, demultiplexers enable the transformation of serial data streams into parallel outputs. In this work, an optimized architecture for a 1:2 QCA demultiplexer is proposed, characterized by simplicity, efficiency, and reliability, with the added capability of implementing a wide range of logical functions. Furthermore, a novel 1:4 QCA demultiplexer is developed based on the proposed structure, eliminating the need for coplanar cells or crossover wires. Simulation results confirm the superior performance of the proposed architectures in terms of reduced cell count, area, and latency. Specifically, the 1:2 design requires only 17 QCA cells, occupies 0.01 μm², and exhibits a delay of 0.25 clock cycles, while the 1:4 demultiplexer requires 74 QCA cells, occupies 0.07 μm², and achieves a delay of 3 clock cycles.
کلیدواژه‌ها
Demultiplexer؛ Majority voter؛ Quantum-dot Cellular Automata؛ Crossover؛ Coplanar
مراجع
  1. DeHon, André, and Michael J. Wilson. "Nanowire-based sublithographic programmable logic arrays." Proceedings of the 2004 ACM/SIGDA 12th international symposium on Field programmable gate arrays. 2004.                        
  2. Ma, Xiaojun, Jing Huang, and Fabrizio Lombardi. "A model for computing and energy dissipation of molecular QCA devices and circuits." ACM Journal on Emerging Technologies in Computing Systems (JETC) 3.4 (2008): 1-30.                                                        
  3. Seminario, Jorge M., et al. "A molecular device operating at terahertz frequencies: theoretical simulations." IEEE Transactions on Nanotechnology 3.1 (2004): 215-218.                                                                                                                                         
  4. Sabbaghi-Nadooshan, Reza, and Moein Kianpour. "A novel QCA implementation of MUX-based universal shift register." Journal of Computational Electronics 13.1 (2014): 198-210.
  5. Rashidi, Hamid, Abdalhossein Rezai, and Sheema Soltany. "High-performance multiplexer architecture for quantum-dot cellular automata." Journal of Computational Electronics 15.3 (2016): 968-981.
  6. Ahmad, Firdous, Ghulam Mohiuddin Bhat, and Peer Zahoor Ahmad. "Novel adder circuits based on quantum-dot cellular automata (QCA)." Circuits and Systems 2014 (2014).                                                                      
  7. Beigh, Mohammad Rafiq, Mohammad Mustafa, and Firdous Ahmad. "Performance evaluation of efficient XOR structures in quantum-dot cellular automata (QCA)." (2013).                                                                                                                                                     
  8. Ajitha, D., K. Venkata Ramanaiah, and V. Sumalatha. "An efficient design of xor gate and its applications using qca." i-Manager's Journal on Electronics Engineering 5.3 (2015): 22.
  9. Singh, Gurmohan, R. K. Sarin, and Balwinder Raj. "A novel robust exclusive-OR function implementation in QCA nanotechnology with energy dissipation analysis." Journal of Computational Electronics 15.2 (2016): 455-465.                           
  10. Bahar, Ali Newaz, et al. "A novel 3-input XOR function implementation in quantum dot-cellular automata with energy dissipation analysis." Alexandria Engineering Journal 57.2 (2018): 729-738.                                                                                         
  11. Poorhosseini, Mehrdad, and Ali Reza Hejazi. "A fault-tolerant and efficient XOR structure for modular design of complex QCA circuits." Journal of Circuits, Systems and Computers 27.07 (2018): 1850115.
  12. Vankamamidi, Vamsi, Marco Ottavi, and Fabrizio Lombardi. "Clocking and cell placement for QCA." 2006 Sixth IEEE Conference on Nanotechnology. Vol. 1. IEEE, 2006.
  13. Asfestani, Mazaher Naji, and Saeed Rasouli Heikalabad. "A unique structure for the multiplexer in quantum-dot cellular automata to create a revolution in design of nanostructures." Physica B: Condensed Matter 512 (2017): 91-99.            
  14. Ahmad, Firdous. "An optimal design of QCA based 2n: 1/1: 2n multiplexer/demultiplexer and its efficient digital logic realization." Microprocessors and Microsystems 56 (2018): 64-75.                                                               
  15. Hashemi, Sara, Mostafa Rahimi Azghadi, and Ali Zakerolhosseini. "A novel QCA multiplexer design." 2008 International Symposium on Telecommunications. IEEE, 2008.                                                                                                                                               
  16. Sen, Bibhash, et al. "Modular design of testable reversible ALU by QCA multiplexer with increase in programmability." Microelectronics Journal 45.11 (2014): 1522-1532.
  17. Goswami, Mrinal, et al. "Efficient realization of digital logic circuit using QCA multiplexer." 2014 2nd International Conference on Business and Information Management (ICBIM). IEEE, 2014.                                       
  18. Sen, Bibhash, et al. "Multilayer design of QCA multiplexer." 2013 Annual IEEE India Conference (INDICON). IEEE, 2013.
  19. Seyedi, Saeid, Nima Jafari Navimipour, and Akira Otsuki. "Design and analysis of fault-tolerant 1: 2 demultiplexer using quantum-dot cellular automata nano-technology." Electronics 10.21 (2021): 2565.
  20. Khan, Angshuman, and Rajeev Arya. "Towards cost analysis and energy estimation of simple multiplexer and demultiplexer using quantum dot cellular automata." International Nano Letters 12.1 (2022): 67-77.
  21. Khan, Angshuman, and Rajeev Arya. "Towards the Design and Analysis of Multiplexer/Demultiplexer using Quantum dot Cellular Automata for Nano Systems." Journal of New Materials for Electrochemical Systems 25.1 (2022).
  22. Khan, Angshuman, and Rajeev Arya. "Optimal demultiplexer unit design and energy estimation using quantum dot cellular automata." Journal of Supercomputing 77.2 (2021).
  23. Sharma, Vijay Kumar, and Neeraj Kaushik. "Ultra-optimized demultiplexer unit design in quantum-dot cellular automata nanotechnology." e-Prime-Advances in Electrical Engineering, Electronics and Energy 7 (2024): 100445.
  24. Jeon, Jun-Cheol, and Changho Seo. "Quantum-dot cellular automata demultiplexer with minimum design costs with energy dissipation analysis and physical proof for reliable nano-communication systems." Heliyon 10.16 (2024).
  25. Aswathy, N., and NM Siva Mangai. "Optimising energy consumption in Nano‐cryptography: Quantum cellular automata‐based multiplexer/demultiplexer design." IET Quantum Communication 5.4 (2024): 632-640.
  26. Vaid, Nandan, Vijay Kumar Sharma, and Prashant Kumar. "Fundamental 1: 2 demultiplexer design in Quantum-Dot cellular automata Nanotechnology." e-Prime-Advances in Electrical Engineering, Electronics and Energy 8 (2024): 100600.
  27. Afrooz, Sonia, and Nima Jafari Navimipour. "An effective nano design of demultiplexer architecture based on coplanar quantum‐dot cellular automata." IET Circuits, Devices & Systems 15.2 (2021): 168-174.
  28. Abdullah-Al-Shafi, Mohammad. "RAM, DEMUX and ALU in nanoscale: a quantum-dot cellular automata-based architecture." Discover Electronics 2.1 (2025): 26.                                                                                              
  29. Vahabi, Mohsen, et al. "Design of an energy efficient approximate BinDCT module in quantum cellular automata." Scientific Reports 15.1 (2025): 19744.
  30. Reshi, Javeed Iqbal, Farooq A. Khanday, and M. Tariq Banday. "Optimized Nanoscale Adder-Subtractor Design Architectures Utilizing Quantum Dot Cellular Automata." Russian Microelectronics 54.4 (2025): 400-426.
  31. Ganesh, E. N., Lal Kishore, and M. J. S. Rangachar. "Implementation of quantum cellular automata combinational and sequential circuits using majority logic reduction method." International Journal of Nanotechnology and Applications 2.1 (2008): 89-106.                                                                                                                                                            
  32. Lent, Craig S., and P. Douglas Tougaw. "Lines of interacting quantum‐dot cells: A binary wire." Journal of applied Physics 74.10 (1993): 6227-6233.   
  33. Huang, Jing, et al. "Tile-based QCA design using majority-like logic primitives." ACM Journal on Emerging Technologies in Computing Systems (JETC) 1.3 (2005): 163-185.                                                                                       
  34. Prasanna, J. Lakshmi, et al. "Design of BCD Adder using Quantum Cellular Automata." International Journal of Advanced Trends in Computer Science and Engineering 9.1 (2020): 574-578.
  35. Vankamamidi, Vamsi, Marco Ottavi, and Fabrizio Lombardi. "Two-dimensional schemes for clocking/timing of QCA circuits." IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems 27.1 (2007): 34-44.                                                                                                                                       
  36. Afrooz, Sonia, and Nima Jafari Navimipour. "An effective nano design of demultiplexer architecture based on coplanar quantum‐dot cellular automata." IET Circuits, Devices & Systems 15.2 (2021): 168-174.
  37. Ahmad, Firdous. "An optimal design of QCA based 2n: 1/1: 2n multiplexer/demultiplexer and its efficient digital logic realization." Microprocessors and Microsystems 56 (2018): 64-75.
  38. Sardinha, Luiz HB, et al. "Nanorouter: a quantum-dot cellular automata design." IEEE Journal on Selected Areas in Communications 31.12 (2013): 825-834.
  39. Nanditha, V. M., et al. "Design and analysis of digital circuits using quantum cellular automata and verilog." 2020 7th International Conference on Computing for Sustainable Global Development (INDIACom). IEEE, 2020.                                                
  40. Iqbal, J., F. A. Khanday, and N. A. Shah. "Design of Quantum-dot Cellular Automata (QCA) based modular 2 n− 1− 2 n MUX-DEMUX." IMPACT-2013. IEEE, 2013.                                                                                                           
  41. Chakrabarty, Ratna, et al. "Nano-Calculator using Quantum Dot Cellular Automata (QCA)." 2017 1st International Conference on Electronics, Materials Engineering and Nano-Technology (IEMENTech). IEEE, 2017.
  42. Das, Badhan, et al. "An effective design of 2: 1 multiplexer and 1: 2 demultiplexer using 3-dot QCA architecture." 2019 International Conference on Robotics, Electrical and signal Processing Techniques (ICREST). IEEE, 2019.
  43. Ganesh, E. N., Lal Kishore, and M. J. S. Rangachar. "Implementation of Quantum cellular automata combinational and sequential circuits using Majority logic reduction method." International Journal of Nanotechnology and Applications 2.1 (2008): 89-106.                                                                                                                                                             
  44. Shah, N. A., et al. "Design of quantum-dot cellular automata (QCA) based modular 1 to 2n demultiplexers." Int. J. Nontechnology App 5.1 (2011): 47-58.
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