Six-qubit permutation-based decoherence-free orthogonal basis

Abstract We discuss new ideas for consideration of loop diagrams and angular integrals in D-dimensions in QCD. In case of loop diagrams, we propose the covariant formalism of expansion of tensorial loop integrals into the orthogonal basis of linear combinations of external momenta. It gives a very simple representation for the final results and is more convenient for calculations on computer algebra systems. In case of angular integrals we demonstrate how to simplify the integration of differential cross sections over polar angles. Also we derive the recursion relations, which allow to reduce all occurring angular integrals to a short set of basic scalar integrals. All order ε-expansion is given for all angular integrals with up to two denominators based on the expansion of the basic integrals and using recursion relations. A geometric picture for partial fractioning is developed which provides a new rotational invariant algorithm to reduce the number of denominators.

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The Influence of Stochastic Imperfection Field on the Bearing Capacity of Hyperbolic Cooling Towers

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.374-377.2297 ◽

2011 ◽

Vol 374-377 ◽

pp. 2297-2300

Author(s):

Hai Zhao ◽

Ya Zhou Xu ◽

Guo Liang Bai

Keyword(s):

Bearing Capacity ◽

Large Scale ◽

Initial Imperfection ◽

Orthogonal Basis ◽

Imperfection Sensitivity ◽

Stochastic Field ◽

Buckling Mode ◽

Material Inhomogeneity ◽

Initial Imperfections ◽

Distribution Form

The uncontrollable factors such as construction errors, material inhomogeneity, etc. will inevitably lead to a certain initial imperfections. It is generally known that the stochastic initial imperfection of the structure is an important factor for affecting structural stability and bearing capacity. Since these imperfections are random in nature, this paper proposes the method mainly based on the standard orthogonal basis to expand the stochastic field, taking into account the decomposition of the stochastic initial imperfections related to structures, which is projected in the buckling mode orthogonal basis. In the end, the article by the stability analysis example shows that this method can use less random variables effectively describing the original stochastic imperfection field, and efficiently search for the most unfavorable initial imperfection distribution form in order to ensure the imperfection sensitivity structures have a higher reliability, so it can be applied to large-scale engineering structure stochastic imperfection analysis.

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Two-phase flow analysis based on a phase-field model using orthogonal basis bubble function finite element method

International Journal of Computational Fluid Dynamics ◽

10.1080/10618560802238226 ◽

2008 ◽

Vol 22 (8) ◽

pp. 555-568 ◽

Cited By ~ 8

Author(s):

Junichi Matsumoto ◽

Naoki Takada

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Phase Field ◽

Field Model ◽

Flow Analysis ◽

Phase Field Model ◽

Orthogonal Basis ◽

Phase Flow ◽

Two Phase ◽

Bubble Function

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MATRIX THEORY, HILBERT SCHEME AND INTEGRABLE SYSTEM

Modern Physics Letters A ◽

10.1142/s0217732398002904 ◽

1998 ◽

Vol 13 (34) ◽

pp. 2731-2742 ◽

Cited By ~ 1

Author(s):

YUTAKA MATSUO

Keyword(s):

Hilbert Scheme ◽

Matrix Theory ◽

Fock Space ◽

Homology Class ◽

Orthogonal Basis ◽

Inner Product ◽

Virasoro Symmetry ◽

Hilbert Scheme Of Points ◽

The Matrix ◽

Boson Fock Space

We give a reinterpretation of the matrix theory discussed by Moore, Nekrasov and Shatashivili (MNS) in terms of the second quantized operators which describes the homology class of the Hilbert scheme of points on surfaces. It naturally relates the contribution from each pole to the inner product of orthogonal basis of free boson Fock space. These bases can be related to the eigenfunctions of Calogero–Sutherland (CS) equation and the deformation parameter of MNS is identified with coupling of CS system. We discuss the structure of Virasoro symmetry in this model.

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Divergence-Taylor-orthogonal basis functions for the discretization of second-kind surface integral equations in the method of moments

CEM'11 Computational Electromagnetics International Workshop ◽

10.1109/cem.2011.6047318 ◽

2011 ◽

Author(s):

Eduard Ubeda ◽

Jose M. Tamayo ◽

Juan M. Rius

Keyword(s):

Integral Equations ◽

Method Of Moments ◽

Orthogonal Basis ◽

Basis Functions ◽

Surface Integral ◽

Surface Integral Equations

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Orthogonal basis with a conicoid first mode for shape specification of optical surfaces

Optics Express ◽

10.1364/oe.24.005448 ◽

2016 ◽

Vol 24 (5) ◽

pp. 5448 ◽

Cited By ~ 6

Author(s):

Chelo Ferreira ◽

José L. López ◽

Rafael Navarro ◽

Ester Pérez Sinusía

Keyword(s):

Orthogonal Basis ◽

Optical Surfaces

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Orthogonal Functions Solving Linear functional Differential EquationsUsing Chebyshev Polynomial

Baghdad Science Journal ◽

10.21123/bsj.5.1.143-148 ◽

2008 ◽

Vol 5 (1) ◽

pp. 143-148 ◽

Cited By ~ 3

Author(s):

Baghdad Science Journal

Keyword(s):

Function Approximation ◽

Linear Functional ◽

Functional Differential Equations ◽

Orthogonal Basis ◽

Basis Functions ◽

Least Square ◽

Orthogonal Functions ◽

Functional Differential ◽

Approximated Evaluation ◽

Chebyshev Functions

A method for Approximated evaluation of linear functional differential equations is described. where a function approximation as a linear combination of a set of orthogonal basis functions which are chebyshev functions .The coefficients of the approximation are determined by (least square and Galerkin’s) methods. The property of chebyshev polynomials leads to good results , which are demonstrated with examples.

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Caracterización en línea de la dinámica temporal de señales para el monitoreo del sistema eléctrico de potencia

Revista de Energía Química y Física ◽

10.35429/jcpe.2020.22.7.26.34 ◽

2020 ◽

pp. 26-34

Author(s):

Francisco Román Lezama-Zárraga ◽

Jorge de Jesús Chan-González ◽

Meng Yen Shih ◽

Roberto Carlos Canto-Canul

Keyword(s):

Nonlinear Oscillations ◽

Electrical Power ◽

Orthogonal Basis ◽

Basis Functions ◽

Electrical Power System ◽

Transient Phenomena ◽

On Line ◽

Measurement Units ◽

Dynamic Phenomena

The characterization of dynamic phenomena is essential for monitoring the Electrical Power System subject to disturbances. This article proposes an On-line time systematic approach to analyze and characterize the temporal evolution of transient and nonlinear oscillations in these systems. Two methods are used; the first method is based on a local decomposition of the signal under study into orthogonal basis functions to obtain the dynamics of transient oscillations. Next, a second method is applied to those orthogonal basis functions to obtain analytical signals and characterize the instantaneous amplitude, phase and frequency attributes of the oscillations and determine a physical interpretation of the system’s behavior. The proposed methodology is a time-frequencyenergy analysis which can be applied to the timesynchronized Phasor Measurement Units measurements. The results demonstrate that the proposed methodology provide an accurate characterization of transient phenomena with non-stationary effects.

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