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Quantum computing  Markus Kiili Opinnäytetyö
Quantum computing Markus Kiili Opinnäytetyö

Approaches to Quantum Error Correction
Approaches to Quantum Error Correction

Quantum Computing and Communications
Quantum Computing and Communications

quantum transition-state theory. II. Recovery of the exact quantum
quantum transition-state theory. II. Recovery of the exact quantum

Toward a scalable, silicon-based quantum computing architecture
Toward a scalable, silicon-based quantum computing architecture

Application of Quantum Computing principles to Natural Language Processing
Application of Quantum Computing principles to Natural Language Processing

Unconditionally Secure Quantum Signatures
Unconditionally Secure Quantum Signatures

Quantum Lambda Calculus - Department of Mathematics and
Quantum Lambda Calculus - Department of Mathematics and

Quantum Computing
Quantum Computing

Chapter 15. - Portland State University
Chapter 15. - Portland State University

Quantum Proofs for Classical Theorems
Quantum Proofs for Classical Theorems

QBism, the Perimeter of Quantum Bayesianism
QBism, the Perimeter of Quantum Bayesianism

Analysis of Literature: Quantum Computer Programming
Analysis of Literature: Quantum Computer Programming

Polynomial-Time Algorithms for Prime Factorization and Discrete
Polynomial-Time Algorithms for Prime Factorization and Discrete

A proof that measured data and equations of quantum mechanics
A proof that measured data and equations of quantum mechanics

... sketched, leading to the first of many needs for concurrently operating CPC’s. Section 4 describes some examples in which guessing, quantum mechanics and CPC structures must interact in the building of a quantum computer as a laboratory instrument specified by equations of quantum mechanics. We show ...
How Quantum Theory Helps us Explain - u.arizona.edu
How Quantum Theory Helps us Explain - u.arizona.edu

Exact quantum query complexity
Exact quantum query complexity

The Quantum Mechanical Frame of  Reference Andrew Soltau
The Quantum Mechanical Frame of  Reference Andrew Soltau

QUANTUM STATES, ENTANGLEMENT and CLOSED TIMELIKE
QUANTUM STATES, ENTANGLEMENT and CLOSED TIMELIKE

... system, then similar arguments will go through and we will get a contradiction • Thus, there is no universal ‘Church of the larger Hilbert space’ (either in CR or CTC world) where a CTC mixed state can be purified if it has to undergo arbitrary interaction with arbitrary CR system in a non-trivial w ...
Experimental one-way quantum computing
Experimental one-way quantum computing

... * Permanent address: Ecole normale supérieure, 45, rue d’Ulm, 75005 Paris, France ...
Quantum distributed computing - Technion
Quantum distributed computing - Technion

Quantum technology: the second quantum revolution
Quantum technology: the second quantum revolution

... theoretical attempts to explain experiments on blackbody radiation. From that theory arose the fundamental idea of wave{particle duality: in particular the idea that matter particles sometimes behaved like waves, and that light waves sometimes acted like particles. This simple idea underlies nearly ...
Modernizing Quantum Annealing using Local Searches
Modernizing Quantum Annealing using Local Searches

Program and Booklet - Fakultät für Mathematik
Program and Booklet - Fakultät für Mathematik

Precisely Timing Dissipative Quantum Information
Precisely Timing Dissipative Quantum Information

< 1 2 3 4 5 6 7 8 9 10 ... 44 >

Quantum cognition

Quantum cognition is an emerging field which applies the mathematical formalism of quantum theory to model cognitive phenomena such as information processing by the human brain, decision making, human memory, concepts and conceptual reasoning, human judgment, and perception. The field clearly distinguishes itself from the quantum mind as it is not reliant on the hypothesis that there is something micro-physical quantum mechanical about the brain. Quantum cognition is based on the quantum-like paradigm or generalized quantum paradigm or quantum structure paradigm that information processing by complex systems such as the brain, taking into account contextual dependence of information and probabilistic reasoning, can be mathematically described in the framework of quantum information and quantum probability theory.Quantum cognition uses the mathematical formalism of quantum theory to inspire and formalize models of cognition that aim to be an advance over models based on traditional classical probability theory. The field focuses on modeling phenomena in cognitive science that have resisted traditional techniques or where traditional models seem to have reached a barrier (e.g., human memory ), and modeling preferences in decision theory that seem paradoxical from a traditional rational point of view (e.g., preference reversals ). Since the use of a quantum-theoretic framework is for modeling purposes, the identification of quantum structures in cognitive phenomena does not presuppose the existence of microscopic quantum processes in the human brain.
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