perturbation technique - определение. Что такое perturbation technique
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Что (кто) такое perturbation technique - определение

Singular Perturbation; Singular perturbation theory

Perturbation theory         
MATHEMATICAL METHODS USED TO FIND AN APPROXIMATE SOLUTION TO A PROBLEM WHICH CANNOT BE SOLVED EXACTLY
Perturbation methods; Pertubation Theory; Perturbation analysis; Perturbation (mathematics); Perturbation Theory; First-order non-singular perturbation theory; Higher order terms; Higher-order terms; Perturbation series; Perturbation theory (mathematics); Small perturbations
In mathematics and applied mathematics, perturbation theory comprises methods for finding an approximate solution to a problem, by starting from the exact solution of a related, simpler problem. A critical feature of the technique is a middle step that breaks the problem into "solvable" and "perturbative" parts.
Musical technique         
GROUP OF TECHNIQUES RELATING TO THE COMPOSING, PRODUCTION OR PERFORMANCE OF MUSIC
Technique (music); General Instrumental technique; Performance technique; Instrumental technique; Brass technique; String instrument technique; String technique; Brass instrument technique; Stringed instrument technique; Woodwind technique; Woodwind instrument technique; Percussion technique; Percussion instrument technique; Percussion instrumental technique; Woodwind instrumental technique; Brass instrumental technique; String instrumental technique; Stringed instrumental technique
Musical technique is the ability of instrumental and vocal musicians to exert optimal control of their instruments or vocal cords in order to produce the precise musical effects they desire. Improving one's technique generally entails practicing exercises that improve one's muscular sensitivity and agility.
Perturbation (astronomy)         
  • Cowell's method. Forces from all perturbing bodies (black and gray) are summed to form the total force on body ''i'' (red), and this is numerically integrated starting from the initial position (the ''epoch of osculation'').
  • Mercury]], [[Venus]], [[Earth]], and [[Mars]] over the next 50,000 years. The 0 point on this plot is the year 2007.
  • Encke's method. Greatly exaggerated here, the small difference  δ'''r''' (blue) between the osculating, unperturbed orbit (black) and the perturbed orbit (red), is numerically integrated starting from the initial position (the ''epoch of osculation'').
  • Mercury]]'s orbital longitude and latitude, as perturbed by [[Venus]], [[Jupiter]] and all of the planets of the [[Solar System]], at intervals of 2.5 days. Mercury would remain centered on the crosshairs if there were no perturbations.
COMPLEX MOTION OF A MASSIVE ASTRONOMICAL BODY
Orbital Perturbation; Gravitational perturbation; Gravitational perturbations; Orbital perturbation analysis; Perturbations (astronomy); Orbital perturbation analysis (spacecraft)
In astronomy, perturbation is the complex motion of a massive body subjected to forces other than the gravitational attraction of a single other massive body.Bate, Mueller, White (1971): ch.

Википедия

Singular perturbation

In mathematics, a singular perturbation problem is a problem containing a small parameter that cannot be approximated by setting the parameter value to zero. More precisely, the solution cannot be uniformly approximated by an asymptotic expansion

φ ( x ) n = 0 N δ n ( ε ) ψ n ( x ) {\displaystyle \varphi (x)\approx \sum _{n=0}^{N}\delta _{n}(\varepsilon )\psi _{n}(x)\,}

as ε 0 {\displaystyle \varepsilon \to 0} . Here ε {\displaystyle \varepsilon } is the small parameter of the problem and δ n ( ε ) {\displaystyle \delta _{n}(\varepsilon )} are a sequence of functions of ε {\displaystyle \varepsilon } of increasing order, such as δ n ( ε ) = ε n {\displaystyle \delta _{n}(\varepsilon )=\varepsilon ^{n}} . This is in contrast to regular perturbation problems, for which a uniform approximation of this form can be obtained. Singularly perturbed problems are generally characterized by dynamics operating on multiple scales. Several classes of singular perturbations are outlined below.

The term "singular perturbation" was coined in the 1940s by Kurt Otto Friedrichs and Wolfgang R. Wasow.