Overview of Quantum Computers and Reference Information/Reference Books

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What is a quantum computer?

A quantum computer is a form of computer that processes information using the principles of quantum mechanics as described in “Quantum Mechanics, Artificial Intelligence and Natural Language Processing“. The difference between a quantum computer and a conventional computer is that a quantum computer uses a unit of information with quantum mechanical properties called a “qubit” or “quantum bit,” whereas conventional computers process binary information called “bits.

Because these qubits can represent multiple states simultaneously based on the superposition principle of quantum mechanics, they can perform many calculations at once in parallel, which makes a quantum computer potentially faster than a conventional computer at solving certain problems.

Applications of Quantum Computers

Applications of quantum computers include the following

  • Cryptanalysis: Quantum computers can be used to solve prime factorization problems, which are very difficult to solve with current computers, and this has the potential to break some cryptographic schemes, such as the RSA cipher, and efficiently crack some cryptographic schemes.
  • Optimization problems: Quantum computers are expected to find faster solutions to combinatorial optimization problems involving huge data sets and optimization problems such as traffic route optimization and material design.
  • Molecular simulation: Quantum computers can accurately model quantum mechanical interactions, enabling more accurate prediction of complex chemical reactions and material properties, which is expected to find applications in the field of molecular and material simulation, such as drug design and energy conversion materials development. This is expected to find applications in the field of molecular and material simulation, such as drug design and the development of energy-conversion materials.
  • Machine learning: In a field called quantum machine learning, research is being conducted to take advantage of the characteristics of quantum computers to speed up and improve the accuracy of data analysis and pattern recognition, and the use of quantum computers is expected to significantly improve machine learning algorithms and pattern recognition.
Technical Elements of Quantum Computers

The technical elements of a quantum computer include the following

  • Quantum bit (qubit): The basic unit of information in a quantum computer. Unlike conventional bits, a qubit has quantum mechanical properties that allow it to represent multiple states simultaneously in a superposition.
  • Quantum gate: A quantum gate is a gate for performing operations on a qubit. A quantum gate changes the state of a qubit to perform a quantum computation. Common quantum gates include Adamar gates, phase shift gates, and CNOT gates.
  • Quantum error correction: Quantum bits are susceptible to environmental influences, which can introduce noise and errors. Therefore, quantum error correction techniques are important. Quantum error correction is a method for detecting and correcting noise and errors, which improves the reliability and stability of quantum bits.
  • Quantum Algorithms: Quantum computers require new algorithms called quantum algorithms. Quantum algorithms are algorithms that utilize the characteristics of qubits to efficiently solve problems that are difficult to solve with conventional computers. Typical quantum algorithms include Shore’s algorithm (prime factorization) and Grover’s algorithm (search problem).
  • Quantum bit implementation techniques: Quantum bits require physical implementation and are currently implemented in physical systems using various techniques such as superconducting circuits, ion traps, and photons. Each technique has its advantages and challenges, and reliability, scalability, and error rate are among the considerations.
Challenges of Quantum Computers

Currently, the following challenges exist in the realization of quantum computers

  • Improving quality and reliability: Quantum bits are sensitive to environmental influences and prone to noise and errors. The creation and retention of reliable qubits and the development of techniques to detect and correct errors are needed. Reliability of qubits and reduction of error rates are important factors in the performance of quantum computers and in the expansion of their applications.
  • Scalability: Current quantum computers can handle only a very small number of qubits, but practical quantum computers will require hundreds or thousands of qubits. To make them feasible, it will be necessary to develop large-scale quantum computers and advance the technology to deal with the control and communication challenges associated with them.
  • Stability of qubits: The state of a qubit is very delicate and can be easily affected by minute changes in the environment. Therefore, it is necessary to develop cooling and isolation techniques to keep qubits stable for long periods of time.
  • Design and optimization of quantum algorithms: In order to expand the range of applications of quantum computers, research is needed to design optimal algorithms and to find ways to apply existing computer algorithms to quantum computers.
  • Cost and resource challenges: Current quantum computers require advanced technology and equipment, and are expensive and require large resources, presenting challenges regarding cost reduction and efficient use of resources.
Reference Information and Reference Books on Quantum Computers

The National Institute of Informatics (NII) of the Research Organization of Information and Systems (RISO), an Inter-University Research Institute, has built a database of educational materials containing a variety of content related to quantum technology, including diagrams, graphs, exercises, and program codes, and has made it available as the Quantum Technology Education Center.

As a reference book, Gendai Shiso February 2020 Special Issue = Quantum Computers – A New Paradigm for Information Science and Technology” is available for general reading.

Quantum computers have been attracting renewed attention since the "demonstration of quantum transcendence" by a Google research team was reported. How could this change our world? This special issue provides an overview of the current state of quantum information science, from its history and theoretical foundations to its latest achievements, and considers the future of the quantum age from a variety of perspectives, including political economy, philosophy, and literature.

Discussion

Ecosystem of Quantum Technology / Arisa EMA + Keisuke FUJII

Introduction
How to turn the ecosystem around
Relationships outside the Ecosystem
Challenges of Quantum Computers
To increase the number of players
What is possible because of quantum

Introduction to Quantum Computers

Current Development and Potential Applications of Quantum Computers / Kae Nemoto

Principles and Advantages of Quantum Computers / Yuki Takeuchi

Introduction
Classical Computers and Quantum Computers
The Birth of Quantum Computers and Its Principles
What is special about quantum computers?
Quantum Error Correction
Quantum Computers and Quantum Entanglement
Various Models of Quantum Computers
How to Realize Quantum Bits---Toward the Realization of Quantum Computers
In the End

Philosophizing Quantum Computation / Akio Hosoya

1Introduction
2What is Computation?
3Bits and qbits
4Unitary Development
5Reading Results by Measuring q-Bits
6Entanglement
7Quantum Annealing
8Classification of quantum algorithms
9Musubi

The History of Quantum Computer Research from the Perspective of a Theoretical Computer Scientist / Harumichi Nishimura

Introduction
1The Beginning of Quantum Computing
2The Emergence of Quantum Computation Theory
3Simon and Shore
4Glover's Discovery
5The First Quantum Computer Boom
6Past the First Quantum Computer Boom
7The Second Quantum Computer Boom and Quantum Computational Theory Today
8Conclusion

Quantum Computers in History

Quantum Mechanics without H -- A World Made of Devices / Fumitaka Sato

Achievement of Quantum Transcendence
Back to Quantum Mechanics
Dwelling in the Dual Structure of Quantum Mechanics
The Great Exhibition as a Theory of Things
Popper, "Quantum Mechanics without Observers
External worlds and concepts
Mechanics and Statistics
Practice of "not seeing nature as it is
Textbook of Quantum Mechanics
Coherent and piecewise representations
Departure from the Schrödinger equation
Introduction in interactive experiments from the history of atomic discovery
Entangled States Overlap

Expanding Quantum Science

Quantum Mechanics from the Viewpoint of Information / Yuichiro Kitajima

1Introduction
2CBH Theorem
3PR Box
4Super Quantum Correlation
5Significance of the CBH Theorem
6Conclusion

Philosophy of Sphere, Quantum Information, and Big Data -- From Information Physics and Quantum Cognitive Science to Sphere Theoretic Metaphysics and Quantum AI Native / Yoshihiro Maruyama

1Von Neumann's Immoral Confession: From Interpretivism to Reconstructionism of Quantum Theory
2Informativity of Everything and Computability of Omnipresent Processes: Pancomputationalism as TheoryofEverything
3Sphere-theoretic structuralism and sphere-theoretic quantum theory, or the multi-process ontology of everything
4Quantum brain theory and quantum cognitive science--material quantum effects and structural quantum effects
5Native AI, Native Quantum, Native Sphere Theory

Quantum and Life / Shigenori Tanaka

1Introduction--Quantum Life Science
2Quantum Systems Biology
3Fermion Many-body Problem
4Rethinking--The Old and New Connection between Quantum and Life

Generalized Quantum Computing Toward "I" / Yukio Gunji Pegio

1Introduction
2Cognitive Fallacies and Quantum Mechanics
3Cognitive Nonlocality and the Quasi-Directive Structure of Boolean Algebra
4Cognitive Fallacies, Arguments, and Cognitive Nonlocality

Quantum opens up the panse

Quantum Mechanics and Contemporary Thought / Takuju Jeon

1Introduction--Quantum, Probability, and the Observer
2Quantum Mechanics as a Worldview
Introduction
2-1Non-Existential Metatheory of Quantum Mechanics
2-2Existential Metatheory of Quantum Mechanics as a Revised Supplement
2-3Many-Worlds Existential Metatheory of Quantum Mechanics
3The Interpretation of Quantum Mechanics and the Zeitgeist
4Final chapter

Starting from No Time, No Space / Soshichi Uchii

1Rovelli's Theory of Quantum Gravity
2Leibniz's Ultimate Theory
3The Power and Limits of Superposition
4The Emergence of Space
5The Emergence of Time
6Interpretation of Probability

Quantum Mechanics, Information Science, and Social Systems Theory -- Ideological Horizon of Quantum Information Science / Takehiko Ohguro

Introduction
The Commotion over "Quantum Transcendence
Stance toward Quantum Information Science
1
The Birth of Information Science and Cybernetics
Objects, Meanings, and Information
What is an "informational worldview?"
2
The breakdown of the "physical worldview" in physics
Vision of "Information" in Physics
The Conflict between "Things" and "Information" in Quantum Mechanics
3
Quantum Mechanics and Information Science
The Birth of Quantum Information Science
The Present State of Quantum Information Science
The Ideological Horizon of Quantum Information Science
4
Quantum Mechanics, Information Science and Social Systems Theory
Social Systems Theory and Quantum Information Science

AI, Cryptography, and Networks

Ethics of Future Technology / Shigeo Kawashima

Introduction
Heterogeneity of Man and Machine
Social-Technological Systems
First-person cognition
Computational/non-computational domain of future technology
Conclusion

Digital Signatures, Blockchains and Quantum Algorithms -- The Dawn of a New Cipherpunk / Kenji Saito

The Past is imbued with changeable properties
Quantum Algorithms and Cryptanalysis
Can Authenticity of Records be Preserved?
Digital Signatures and the Alibi Proof Problem, Proof over Time Problem
Blockchain and Authenticity of Records
Threats to the Blockchain
Crypto Agility and Digital Antiquities in the Blockchain
The Dawn of a New Cipherpunk

On the Emergence of Chyberspace -- Behind China's "Cyber Sovereignty" Theory / Jiro Hane

Introduction--The "Okinawa IT Charter" and Neoliberalism
1The United Nations Millennium Declaration
2The World Summit on the Information Society
3The Budding of Chaiberspace
4The Snowden Incident
Conclusion

Where does "information" come from and where is it going?

The Formation of the Concept of Information: The Approach of Physics and Engineering in the 1920s / Munema Kawanishi

Introduction
1 The History of the Term "Information
2The Formation of the Concept of Information in Communications Engineering
3Mechanization of the Devil: From the Introduction of the Szilard Engine
4Convergence

Home Automation Reconsidered: Japan in the 1980s Envisioned the Information Society of the 21st Century / Mana Suzuki

1IoT Technology and Home Automation (HA)
2Home Electronics in the 1980's (1) HA/HE in the Future Prospects
3Home Electronics in the 1980's (2) HA/HE in Books
4Home Communications Technology in the 1980's (1) Communications between Outside and Inside the Home
5Home Communications Technology in the 1980s (2) Communications within the Home

Quantum Imagination.

Coincidence, Parallel Worlds, and This I -- Issues Concerning Quantum Mechanics and Literature / Muuzo Kato

Introduction
1 Nakagawa Yoichi's Theory of Accidental Literature
2Invitation to Many-Worlds Interpretation
3Literary History of Quantum Computers
Conclusion

Demiurgeon's Demiurgeon's Demiurgeon

False Harmony (2) / Arata Isozaki

A Hundred Years of the Posthumanities: Part 2

Existence and Metaphysics: Jaspers / Mitsuki ASANUMA

1Introduction
2Jaspers
What is Existential Philosophy?
The Person and Character of Jaspers
Between Kierkegaard and Kant
3 "Schelling: Greatness and Fate
Establishment
Characteristics
Evaluation
4Jaspers and Heidegger.
Friendship and Feud
Habermas Book Reviews
The Mystery of Schelling
5Conclusion

Research Handbook

Cats are bilingual / Saho Takagi

“Machine Learning with Quantum Computers”

Quantum Computer Science: An Introduction”

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