![From Quantum Gates to Quantum Learning: recent research and](http://s1.studyres.com/store/data/004590824_1-90b5a4fd673dbd01dba641ca42fb0700-300x300.png)
From Quantum Gates to Quantum Learning: recent research and
... • Put all 7-bits into a superposition state • superposition allows quantum computer to make calculations on all 128 possible numbers (27) in ONE iteration i.e. finishes in 1 second. • Tremendous possibilities… imagine doing computations on even larger sample spaces all at the same time!!! ...
... • Put all 7-bits into a superposition state • superposition allows quantum computer to make calculations on all 128 possible numbers (27) in ONE iteration i.e. finishes in 1 second. • Tremendous possibilities… imagine doing computations on even larger sample spaces all at the same time!!! ...
Maximally entangling tripartite protocols for Josephson phase qubits *
... form the basis for many important information-processing algorithms $15%. In this paper, we develop several single-step entangling protocols suitable for generating maximally entangled quantum states in tripartite systems with pairwise coupling g!XX + YY" + g̃ZZ. We base our approach on the idea tha ...
... form the basis for many important information-processing algorithms $15%. In this paper, we develop several single-step entangling protocols suitable for generating maximally entangled quantum states in tripartite systems with pairwise coupling g!XX + YY" + g̃ZZ. We base our approach on the idea tha ...
Quantum Money from Hidden Subspaces
... A second contribution is to construct the first private-key quantum money schemes that remain unconditionally secure, even if the counterfeiter can interact adaptively with the bank. This gives the first solution to the “online attack problem,” a major security hole in the Wiesner [39] and BBBW [14] ...
... A second contribution is to construct the first private-key quantum money schemes that remain unconditionally secure, even if the counterfeiter can interact adaptively with the bank. This gives the first solution to the “online attack problem,” a major security hole in the Wiesner [39] and BBBW [14] ...
Classical/Quantum Dynamics of a Particle in Free Fall
... at a very early point in his/her education, and with the first & last of those systems we are never done: they are—for reasons having little to do with their physical importance—workhorses of theoretical mechanics, traditionally employed to illustrated formal developments as they emerge, one after an ...
... at a very early point in his/her education, and with the first & last of those systems we are never done: they are—for reasons having little to do with their physical importance—workhorses of theoretical mechanics, traditionally employed to illustrated formal developments as they emerge, one after an ...
One-dimensional theory of the quantum Hall system
... of the (abelian) Haldane-Halperin hierarchy construction [34,35] is manifest, and the stability of a given TT state is monotonously decreasing with increasing denominator q at filling ν = p/q [24,25]. Albeit being calculated in an extreme limit, this simple result is in surprisingly good agreement w ...
... of the (abelian) Haldane-Halperin hierarchy construction [34,35] is manifest, and the stability of a given TT state is monotonously decreasing with increasing denominator q at filling ν = p/q [24,25]. Albeit being calculated in an extreme limit, this simple result is in surprisingly good agreement w ...
Quantum Reflection at Strong Magnetic Fields
... to modify the propagation of (real) light fields through vacuum. In 1936, W. Heisenberg and his PhD student H. Euler published a generalization of the Maxwell Lagrangian which is now known as the Heisenberg-Euler Lagrangian [3]. It describes the nonlinear dynamics of slowly varying electromagnetic f ...
... to modify the propagation of (real) light fields through vacuum. In 1936, W. Heisenberg and his PhD student H. Euler published a generalization of the Maxwell Lagrangian which is now known as the Heisenberg-Euler Lagrangian [3]. It describes the nonlinear dynamics of slowly varying electromagnetic f ...
Relativistic quantum mechanics and the S matrix
... construction of a set of unitary operators that represent the elements of the Poincaré group. This group is the set of all inhomogeneous Lorentz transformations (a,b) that map the space-time variables of one inertial frame to those of another inertial frame according to x ⬘ ⫽ax⫹b. Unitary operators ...
... construction of a set of unitary operators that represent the elements of the Poincaré group. This group is the set of all inhomogeneous Lorentz transformations (a,b) that map the space-time variables of one inertial frame to those of another inertial frame according to x ⬘ ⫽ax⫹b. Unitary operators ...
PHYSICS 673 Nonlinear and Quantum Optics
... Problem 1.12 Calculate the susceptibility χ(ω) of a gas of electrons shown in Fig.√1.3. Each electron has charge e, mass m, is mounted on a spring with spring constant κ such that κ/m = ω0 gives the resonant frequency of the oscillators. The damping constant is Γ, meaning that the friction force exp ...
... Problem 1.12 Calculate the susceptibility χ(ω) of a gas of electrons shown in Fig.√1.3. Each electron has charge e, mass m, is mounted on a spring with spring constant κ such that κ/m = ω0 gives the resonant frequency of the oscillators. The damping constant is Γ, meaning that the friction force exp ...
Complete Lecture Notes
... By the turn of the 19th century, classical physics had reached its summit. The nature and motion of particles and matter was properly accounted for. Newtonian mechanics was put in a solid mathematical framework (Lagrange, Hamilton) and the properties of radiation was covered by Maxwell’s equations. ...
... By the turn of the 19th century, classical physics had reached its summit. The nature and motion of particles and matter was properly accounted for. Newtonian mechanics was put in a solid mathematical framework (Lagrange, Hamilton) and the properties of radiation was covered by Maxwell’s equations. ...
superconducting qubits solid state qubits
... electron in a potential well (such as a quantum dot or an impurity ion) or by the spin states of the electron (or the nucleus). The former are examples of charge qubits. The charge qubits have high energy splitting, and can be manipulated by applying potentials to control electrodes. However, charge ...
... electron in a potential well (such as a quantum dot or an impurity ion) or by the spin states of the electron (or the nucleus). The former are examples of charge qubits. The charge qubits have high energy splitting, and can be manipulated by applying potentials to control electrodes. However, charge ...
Quantum electrodynamics
![](https://commons.wikimedia.org/wiki/Special:FilePath/Dirac_3.jpg?width=300)
In particle physics, quantum electrodynamics (QED) is the relativistic quantum field theory of electrodynamics. In essence, it describes how light and matter interact and is the first theory where full agreement between quantum mechanics and special relativity is achieved. QED mathematically describes all phenomena involving electrically charged particles interacting by means of exchange of photons and represents the quantum counterpart of classical electromagnetism giving a complete account of matter and light interaction.In technical terms, QED can be described as a perturbation theory of the electromagnetic quantum vacuum. Richard Feynman called it ""the jewel of physics"" for its extremely accurate predictions of quantities like the anomalous magnetic moment of the electron and the Lamb shift of the energy levels of hydrogen.