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Multiple-valued computing in quantum molecular biology : arithmetic and combinational circuits / Hafiz Hasan Babu.
- Format:
- Book
- Author/Creator:
- Babu, Hafiz Hasan, author.
- Series:
- MULTIPLE-VALUED COMPUTING IN QUANTUM MOLECULAR BIOLOGY.1
- Language:
- English
- Subjects (All):
- Quantum theory.
- Mathematical physics.
- Quantum statistics.
- Physical Description:
- 1 online resource (531 pages)
- Edition:
- 1st ed.
- Place of Publication:
- Boca Raton, FL : CRC Press, [2024]
- Contents:
- Cover
- Half Title
- Title Page
- Copyright Page
- Dedication
- Contents
- Author
- Preface
- Acknowledgments
- Acronyms
- Introduction
- I. Multiple-Valued Quantum and DNA Computing
- Overview
- 1. Multiple-Valued Quantum Computing
- 1.1. Introduction
- 1.2. Quantum Physics and Quantum Computing
- 1.2.1. Applications of Quantum Physics
- 1.3. What is Quantum Computing?
- 1.3.1. Quantum Computing Properties
- 1.3.2. How Does Quantum Computer Work?
- 1.4. Multiple-Valued Logic
- 1.4.1. History of Multiple-Valued Logic
- 1.4.2. Advantages of Multiple-Valued Quantum Computing over Binary Logic
- 1.5. Ternary Logic in Quantum Computing
- 1.5.1. Quantum Ternary Fundamental Logic Operations
- 1.6. Applications of Multiple-Valued Quantum Computing
- 1.7. Demerits of Multiple-Valued Quantum Computing
- 1.7.1. Challenges in Multiple-Valued Quantum Computing
- 1.8. Summary
- Bibliography
- 2. Multiple-Valued DNA Computing
- 2.1. Introduction
- 2.2. What is DNA Computing?
- 2.2.1. History of DNA Computing
- 2.3. Some Related Terminologies
- 2.3.1. Molecular Biology
- 2.3.2. DNase Enzyme
- 2.3.3. Fluorescence Detection
- 2.4. How Does a DNA Computing Work?
- 2.4.1. DNA Computing for Binary Logic System
- 2.5. Multiple-Valued DNA Computing
- 2.5.1. How Can Multiple-Valued Operations Be Performed in DNA Computing?
- 2.6. Advantages of Multiple-Valued DNA Computing
- 2.7. Limitations of Multiple-Valued DNA Computing
- 2.8. Applications of Multiple-Valued DNA Computing
- 2.9. Challenges in Multiple-Valued DNA Computing
- 2.10. Motivations toward Multiple-Valued DNA Computing
- 2.11. Summary
- 3. Multiple-Valued Quantum-DNA Computing
- 3.1. Introduction
- 3.2. Quantum Mechanics and Quantum Molecular Biology
- 3.2.1. Why Quantum Molecular Biology Is an Important Field?.
- 3.3. Relationship between Multi-Valued and Two-Valued Quantum and DNA Computing
- 3.3.1. Multiple-Valued Quantum-DNA Computing: A New Computing Approach
- 3.3.2. Data Conversion Circuits to Convert Qutrits to DNA Base Sequences
- 3.3.3. Intermediatory System to Control Quantum-DNA Data Flow
- 3.3.4. Heat Transfer Circuit
- 3.4. Advantages of Multiple-Valued Quantum-DNA Computing
- 3.5. Disadvantages of Multiple-Valued Quantum-DNA Computing
- 3.6. Summary
- 4. Multiple-Valued DNA-Quantum Computing
- 4.1. Introduction
- 4.2. Relationship between Multi-Valued DNA Computing and Multi-Valued Quantum Computing with Two-Valued DNA Computing and Quantum Computing
- 4.3. Multiple-Valued DNA-Quantum Computing
- 4.3.1. General Organization of Multiple-Valued DNA-Quantum Computing
- 4.4. Difference between Multiple-Valued Quantum-DNA and DNA-Quantum Computing
- 4.5. Advantages of Multiple-Valued DNA-Quantum Computing
- 4.6. Summary
- II. Heat Measurement, Heat Transfer, Speed Calculation, Data Conversion, and Data Management in Multiple-Valued Quantum and DNA Computing
- 5. Heat Calculation
- 5.1. Introduction
- 5.2. Basic Definitions for Heat Calculation in Quantum Circuit
- 5.3. Heat Calculation in Multiple-Valued Quantum Circuit
- 5.3.1. Quantum Multi-Valued Half Adder
- 5.3.2. Quantum Multi-Valued Half Subtractor
- 5.3.3. Quantum Multi-Valued 3-to-1 Multiplexer
- 5.4. Basic Definitions for Heat Calculation in DNA Circuit
- 5.5. Heat Calculation in Multi-Valued DNA Circuit
- 5.5.1. DNA Multi-Valued Decoder
- 5.5.2. DNA Multi-Valued 3-to-1 Multiplexer
- 5.6. Heat Calculation in Multi-Valued Quantum-DNA Circuit
- 5.6.1. Multi-Valued Quantum-DNA Half Adder
- 5.7. Heat Calculation in Multi-Valued DNA-Quantum Circuit
- 5.7.1. Multi-Valued DNA-Quantum Half Subtractor
- 5.8. Summary.
- 10. Multiple-Valued Logic Operations in Quantum Computing
- 10.1. Introduction
- 10.2. Quantum Ternary Logic
- 10.2.1. Why Ternary Logic in Quantum Computing?
- 10.3. Quantum Fundamental Gates in Multi-Valued Logic
- 10.3.1. Quantum Ternary Shift Gates
- 10.3.2. Quantum Ternary C2 NOT Gate
- 10.4. Quantum Multi-Valued Basic Logic Operations
- 10.4.1. Ternary Quantum-AND Operation
- 10.4.2. Ternary Quantum-NAND Operation
- 10.4.3. Ternary Quantum-OR Operation
- 10.4.4. Ternary Quantum-NOR Operation
- 10.4.5. Ternary Quantum XOR Operation
- 10.4.6. Ternary Quantum XNOR Operation
- 10.5. Summary
- 11. Multiple-Valued Quantum Arithmetic Operations
- 11.1. Introduction
- 11.2. Multiple-Valued Quantum Half-Adder
- 11.2.1. The Architecture of Quantum Ternary Half-Adder Operation
- 11.2.2. Working Principles of Quantum Ternary Half-Adder Operation
- 11.3. Multiple-Valued Quantum Full-Adder
- 11.3.1. The Circuit Architecture of Quantum Ternary Full-Adder Operation
- 11.3.2. Working Principles of Quantum Ternary Full-Adder Operation
- 11.4. Multiple-Valued Quantum Half-Subtractor
- 11.4.1. The Circuit Architecture of Quantum Ternary Half-Subtractor Operation
- 11.4.2. Working Principles of Quantum Ternary Half-Subtractor Operation
- 11.5. Multiple-Valued Quantum Full-Subtractor Operation
- 11.5.1. The Circuit Architecture of Quantum Ternary Full-Subtractor Operation
- 11.5.2. Working Principles of Quantum Ternary Full-Subtractor Operation
- 11.6. Multiple-Valued Quantum Parallel Adder
- 11.6.1. General Organizations of Multiple-Valued Quantum Parallel Adder
- 11.6.2. Circuit Architecture of Quantum Multiple-Valued Parallel Adder
- 11.6.3. The Working Principles of Quantum Multiple-Valued Parallel Adder
- 11.7. Multiple-Valued Quantum Carry-Lookahead Adder.
- 11.7.1. General Organizations of Quantum Ternary Carry-Lookahead Adder
- 11.7.2. The Architecture of Quantum Ternary Carry-Lookahead Adder
- 11.7.3. The Working Principles of Quantum Ternary Carry-Lookahead Adder
- 11.8. Multiple-Valued Quantum Carry-Skip Adder
- 11.8.1. How Does Quantum Ternary Carry-Skip Adder Work?
- 11.8.2. The General Architecture of Quantum Ternary Carry-Skip Adder
- 11.8.3. The Working Principles of Quantum Ternary Carry-Skip Adder
- 11.9. Multiple-Valued Quantum Multiplier
- 11.9.1. How Does the Quantum Ternary Multiplier Work?
- 11.9.2. The Architecture of the Quantum Ternary 2 x 2 Multiplier
- 11.9.3. The Working Procedure of the Quantum Ternary 2 x 2 Multiplier
- 11.10. Multiple-Valued Quantum Divider
- 11.10.1. How Does the Quantum Ternary Divider Work?
- 11.10.2. Circuit Architecture of the Quantum Ternary Divider
- 11.10.3. The Working Procedures of the Quantum Ternary Divider
- 11.11. Multiple-Valued Quantum Comparator
- 11.11.1. Circuit Architecture of Multiple-Valued Quantum Comparator
- 11.11.2. Working Principle Multiple-Valued Quantum Comparator
- 11.12. Summary
- 12. Multiple-Valued Logic Operations in DNA Computing
- 12.1. Introduction
- 12.2. How Can Multiple-Valued Operations be Performed in DNA Computing?
- 12.3. Performing Fundamental Operations in Ternary Logic in DNA Computing
- 12.3.1. Ternary DNA-NOT Operation
- 12.3.2. Ternary DNA-AND Operation
- 12.3.3. Ternary DNA NAND Operation
- 12.3.4. Ternary DNA-OR Operation
- 12.3.5. Ternary DNA-NOR Operation
- 12.3.6. Ternary DNA-XOR Operation
- 12.3.7. Ternary DNA XNOR Operation
- 12.4. Summary
- 13. Multiple-Valued Arithmetic Operations in DNA Computing
- 13.1. Introduction
- 13.2. Multi-Valued DNA Half-Adder
- 13.2.1. The Circuit Architecture of DNA Ternary Half-Adder Operation.
- Notes:
- 13.2.2. Working Principles of Quantum Ternary Half-Adder Operation.
- Includes bibliographical references and index.
- Bibliography -- 6. Speed Calculation -- 6.1. Introduction -- 6.2. Speed Calculation for a Quantum Operation -- 6.3. Speed Calculation in Multi-Valued Quantum Circuit -- 6.3.1. Quantum Multi-Valued 3-to-1 Multiplexer -- 6.3.2. Quantum Multi-Valued Half Adder -- 6.3.3. Quantum Multi-Valued Half Subtractor -- 6.4. Speed Calculation for DNA Operation -- 6.5. Speed Calculation in Multi-Valued DNA Circuit -- 6.5.1. DNA Multi-Valued Decoder -- 6.5.2. DNA Multi-Valued 3-to-1 Multiplexer -- 6.6. Speed Calculation in Multi-Valued Quantum-DNA Circuit -- 6.6.1. Multi-Valued Half Adder at 0-Kelvin -- 6.6.2. Multi-Valued Half Subtractor at 0-Kelvin -- 6.6.3. Multi-Valued Multiplexer at 0-Kelvin -- 6.7. Speed Calculation in Multi-Valued DNA-Quantum Circuit -- 6.7.1. Multi-Valued Half Subtractor at room temperature -- 6.8. Summary -- Bibliography -- 7. Heat Transfer -- 7.1. Introduction -- 7.2. Heat Transfer in Multiple-Valued Quantum-DNA Circuits -- 7.2.1. Heat Transfer in Multi-Valued Quantum-DNA Full Subtractor (Difference) -- 7.2.2. Heat Transfer in Multi-Valued Quantum-DNA Half Adder -- 7.3. Summary -- Bibliography -- 8. Data Conversion -- 8.1. Introduction -- 8.2. Data Conversion in Multiple-Valued Quantum-DNA Circuits -- 8.2.1. NMR Relaxation at Room Temperature -- 8.3. Data Conversion in Multiple-Valued DNA-Quantum Circuits -- 8.3.1. Quadrupole Ion Trap -- 8.4. Summary -- Bibliography -- 9. Data Management -- 9.1. Introduction -- 9.2. Data Management in Quantum-DNA Circuits -- 9.2.1. Construction of an Intermediary System to Control Quantum-DNA Data Flow -- 9.2.2. Multiple-Valued Quantum-DNA Half Adder -- 9.3. Data Management in DNA-Quantum Circuits -- 9.3.1. Construction of an Intermediary System to Control DNA-Quantum Data Flow -- 9.4. Summary -- Bibliography -- III. Multiple-Valued Arithmetic Circuits in Quantum Molecular Biology -- Overview.
- Electronic reproduction. London Available via World Wide Web.
- Description based on print version record
- Other Format:
- Print version Babu, Hafiz Hasan Multiple-Valued Computing in Quantum Molecular Biology
- ISBN:
- 1000900983
- 9781000900989
- 9781003381938
- Publisher Number:
- 90100618093
- Access Restriction:
- Restricted for use by site license.
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