Quantum computing :a pathway to quantum logic design /

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Quantum computing :a pathway to quantum logic design /

Babu, Hafiz Md. Hasan, - Personal Name; Institute of Physics (Great Britain), - Personal Name;

"Version: 202306"--Title page verso.Includes bibliographical references.part II. Quantum fault tolerance. 19. Quantum fault-tolerant circuits -- 19.1. The need for quantum fault-tolerant circuits -- 19.2. The fault-tolerant quantum adder -- 19.3. The fault-tolerant multiplier -- 19.4. The quantum fault-tolerant integer divider -- 19.5. Summarypart III. Quantum-dot cellular automata. 20. Quantum-dot cellular automata -- 20.1. Fundamentals of QCA circuits -- 20.2. The QCA cell -- 20.3. Information and data propagation -- 20.4. Basic QCA elements and gates -- 20.5. The QCA clock -- 20.6. Summary21. The QCA adder and subtractor -- 21.1. The Ex-OR gate -- 21.2. The QCA half-adder and -subtractor -- 21.3. The QCA full-adder and full-subtractor -- 21.4. Summary22. The QCA multiplier and divider -- 22.1. The QCA multiplier -- 22.2. The QCA divider -- 22.3. Summary23. QCA asynchronous and synchronous counters -- 23.1. The asynchronous counter -- 23.2. The synchronous counter -- 23.3. Summary24. The QCA decoder and encoder -- 24.1. The QCA decoder -- 24.2. The QCA encoder -- 24.3. Summary25. The QCA multiplexer and demultiplexer -- 25.1. The QCA 2-to-1 multiplexer -- 25.2. The QCA 4-to-1 multiplexer -- 25.3. The QCA 1-to-2 demultiplexer -- 25.4. The QCA 1-to-4 demultiplexer -- 25.5. Multiplexing/demultiplexing using QCA -- 25.6. Summary26. QCA flip-flops -- 26.1. QCA D flip-flops -- 26.2. QCA J-K flip-flops -- 26.3. QCA SR flip-flops -- 26.4. QCA T flip-flops -- 26.5. Applications -- 26.6. Summary27. QCA programmable logic devices -- 27.1. The QCA programmable array logic -- 27.2. The QCA programmable logic array -- 27.3. The QCA field-programmable gate array -- 27.4. The importance and applications of QCA programmable logic devices -- 27.5. Summary28. QCA RAM, ROM, and cache memory -- 28.1. The RAM cell -- 28.2. The QCA ROM -- 28.3. The QCA cache memory -- 28.4. Summary29. The QCA processor circuit -- 29.1. Introduction -- 29.2. Basic definitions -- 29.3. The block diagram of a QCA processor -- 29.4. The basic components of a QCA processor -- 29.5. Summary30. Applications of QCA technology -- 30.1. High performance -- 30.2. Small size -- 30.3. Low power consumption -- 30.4. Encryption and authentication -- 30.5. Higher data speed -- 30.6. Image processing -- 30.7. Summarypart IV. QCA fault tolerance. 31. QCA fault-tolerant circuits -- 31.1. The necessity of QCA fault-tolerant circuits -- 31.2. The fault-tolerant QCA majority gate -- 31.3. The fault-tolerant QCA 1-to-2 demultiplexer -- 31.4. The fault-tolerant QCA full-adder -- 31.5. The fault-tolerant QCA SRAM cell -- 31.6. The fault-tolerant QCA subtractor -- 31.7. The fault-tolerant QCA multiplier -- 31.8. Summary.part I. Quantum logic. 1. Quantum logic -- 1.1. Overview -- 1.2. Motivations towards quantum computing -- 1.3. The relationship between reversible and quantum logic -- 1.4. Quantum computers -- 1.5. The working principles of quantum computers -- 1.6. The evolution of quantum computers -- 1.7. Why pursue quantum computing? -- 1.8. Summary2. Basic definitions of quantum logic -- 2.1. The quantum qubit -- 2.2. The quantum gate -- 2.3. Garbage outputs -- 2.4. Constant inputs -- 2.5. Area -- 2.6. Power -- 2.7. Delay -- 2.8. Depth -- 2.9. Quantum cost -- 2.10. Quantum gate calculation complexity -- 2.11. Summary3. The quantum qubit string comparator -- 3.1. Characteristics of a quantum comparator -- 3.2. The quantum magnitude comparator -- 3.3. The design of a quantum comparator -- 3.4. Summary4. The quantum full-adder and subtractor -- 4.1. The quantum adder -- 4.2. The quantum subtractor -- 4.3. Summary5. The quantum multiplexer and demultiplexer -- 5.1. The quantum multiplexer -- 5.2. The quantum demultiplexer -- 5.3. Summary6. The quantum adder circuits -- 6.1. The quantum carry skip adder -- 6.2. The quantum comparison circuit -- 6.3. The quantum2-to-1 multiplier circuit -- 6.4. The design of a quantum carry skip adder -- 6.5. The quantum BCD adder -- 6.6. Summary7. The quantum multiplier-accumulator -- 7.1. The importance of a quantum multiplier-accumulator -- 7.2. The quantum multiplication technique -- 7.3. Reduction of the garbage outputs and ancillary inputs of quantum circuits -- 7.4. The design of a quantum multiplier circuit -- 7.5. Accumulator -- 7.6. Summary8. The quantum divider -- 8.1. Division algorithms -- 8.2. The importance of the quantum divider -- 8.3. The tree-based quantum division technique -- 8.4. The design of a quantum divider circuit -- 8.5. Summary9. The quantum BCD priority encoder -- 9.1. The properties of a quantum encoder -- 9.2. The design of a quantum BCD priority encoder circuit -- 9.3. Summary10. The quantum decoder -- 10.1. The characteristics of a quantum decoder -- 10.2. The design of a quantum decoder -- 10.3. Summary11. The quantum square root circuit -- 11.1. The properties of a quantum square root function -- 11.2. The design of a quantum square root circuit -- 11.3. Summary12. Quantum latches and counter circuits -- 12.1. The properties of quantum latches -- 12.2. The design of quantum latches -- 12.3. The properties of quantum counter circuits -- 12.4. The design of quantum counters -- 12.5. Summary13. The quantum controlled ternary barrel shifter -- 13.1. Ternary quantum gates -- 13.2. The properties of ternary quantum circuits -- 13.3. The quantum barrel shifter -- 13.4. The design of a quantum ternary barrel shifter -- 13.5. Summary14. Quantum RAM, quantum ROM, and quantum cache memory -- 14.1. The quantum n-to-2n decoder -- 14.2. The quantum memory unit -- 14.3. The construction procedure of QRAM -- 14.4. Quantum ROM -- 14.5. Quantum cache memory -- 14.6. Summary15. The quantum arithmetic logic unit -- 15.1. The design of a quantum ALU -- 15.2. Summary16. Quantum programmable logic devices -- 16.1. The quantum programmable array logic -- 16.2. The quantum programmable logic array -- 16.3. The quantum complex programmable logic device -- 16.4. The quantum field-programmable gate array -- 16.5. Summary17. The quantum processor circuit -- 17.1. Introduction -- 17.2. Basic definitions -- 17.3. The block diagram of a quantum processor -- 17.4. The basic components of a quantum processor -- 17.5. Applications -- 17.6. Summary18. Applications of quantum computing technology -- 18.1. Optimization -- 18.2. Machine learning -- 18.3. Biomedical simulations -- 18.4. Financial services -- 18.5. Computational chemistry -- 18.6. Logistics and scheduling -- 18.7. Cyber security -- 18.8. Circuit, software, and system fault simulation -- 18.9. Weather forecasting -- 18.10. SummaryQuantum computing is an emerging technology with the potential to have a significant impact on science and technology. Organised into four parts, this comprehensive second edition covers topics such as the basic concepts of quantum computing alongside quantum implementation of different circuits; the fault tolerant concepts of quantum computing; the concept of QCA alongside the design processes of different QCA circuits; and an overview of QCA fault-tolerant circuits and their design procedures. In addition to updates to first edition chapters to reflect developments in recent years, this new edition sees the inclusion of problems to every chapter and eight new chapters. This book will be a great help for quantum computing researchers, faculty members and students who can develop a working understanding of circuit-based quantum computing.Professional and scholarly.Also available in print.Mode of access: World Wide Web.System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.Dr. Hafiz Md. Hasan Babu is a Professor in the Department of Computer Science & Engineering and a Dean in the Faculty of Engineering and Technology at the University of Dhaka, Bangladesh. In recognition of his valuable contributions in the field of computer science and engineering, he received the Bangladesh Academy of Sciences Dr. M. O. Ghani Memorial Gold Medal Award in 2015 and University Grants Commission of Bangladesh Gold Medal Award in 2017, which are the most prestigious research awards in Bangladesh. He has written more than one hundred research articles published in reputed journals and is a regular reviewer of reputed international journals and conferences.Title from PDF title page (viewed on July 6, 2023).

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Series Title: -
Call Number: -
Publisher: : .,
Collation: 1 online resource (various pagings) :illustrations (some color).
Language: English
ISBN/ISSN: 9780750356831
Classification: 006.3/843
Content Type: -
Media Type: -
Carrier Type: -
Edition: Second edition.
Subject(s): SCIENCE / Physics / Quantum Theory.
Quantum computers.
Quantum computing.
Quantum logic.
Specific Detail Info: -
Statement of Responsibility: Hafiz Md. Hasan Babu.

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