My Account Log in

1 option

Multiple-valued computing in quantum molecular biology : arithmetic and combinational circuits / Hafiz Hasan Babu.

Taylor & Francis eBooks Complete Available online

View online
Format:
Book
Author/Creator:
Babu, Hafiz Hasan, author.
Contributor:
Taylor & Francis eBooks
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.

The Penn Libraries is committed to describing library materials using current, accurate, and responsible language. If you discover outdated or inaccurate language, please fill out this feedback form to report it and suggest alternative language.

Find

Home Release notes

My Account

Shelf Request an item Bookmarks Fines and fees Settings

Guides

Using the Find catalog Using Articles+ Using your account