An application of toroidal functions in electrostatics

Selvaggi, Jerry P.; Salon, S.J.; Chari, M.V.K.

doi:10.1119/1.2737473

Cited by 19 publications

(18 citation statements)

References 14 publications

(10 reference statements)

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“…In connection to our interests here, the sketch of the electric field in the [xz] plane implicitly showed that the field, and thus the force on a point charge is not central. Selvaggi et al employed 22 a different approach and demonstrated -without detailed introduction of the toroidal functions-that the electric potential can be expressed in a compact form using the Fourier cosine expansion of the r − ξ −1 , in which expansion the toroidal functions appear as coefficients of the cos(mϕ) functions. This approach has some numerically attractive features: any non-uniform charge distribution can be systematically analyzed after calculating the Fourier expansion of the charge distribution on the ring, and for each term in this expansion there is a single corresponding toroidal function.…”

Section: General Formalism In a Nutshellmentioning

confidence: 99%

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Peculiarities in the gravitational field of a filamentary ring

Schumayer

Hutchinson

2019

American Journal of Physics

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The gravitational field of a massive, filamentary ring is considered. We provide an analytic expression for the gravitational potential and demonstrate that the exact gravitational potential and its gradient, thus the gravitational force-field, is not central. Hence it is a good candidate to discuss the difference between the concepts of center of mass and center of gravity. We focus on other consequences of reduced symmetry, e.g., only the z-component of the angular momentum is conserved. However, the remnant high symmetry of this system also ensures that there are special classes of motions which are restricted to invariant subspaces, thus, depending on the initial condition, the dynamics of a point particle is integrable. We also show that periodic orbits in the equatorial plane external to the ring are possible, but only if the angular momentum is above a threshold value. In this case the orbits are stable.a Parsec, abbreviated as pc, is an astronomical unit of length and it is equal to about 3.261 light-years.arXiv:1902.03344v1 [cond-mat.soft]

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Section: General Formalism In a Nutshellmentioning

confidence: 99%

“…However, the choice of toroidal functions of first or second kind may require further thoughts. In Selvaggi et al 22 only the second kind is used, while in the mathematical literature it is used predominantly for the interior problem, r ⊥ < R.…”

Section: General Formalism In a Nutshellmentioning

confidence: 99%

Peculiarities in the gravitational field of a filamentary ring

Schumayer

Hutchinson

2019

American Journal of Physics

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“…It should be noted that restricted to (−1, 1), the functions P µ ν , 2Q µ ν are Hilbert transforms of each other (via 'Neumann's integral') when µ = 0, and are related by more complicated integral transforms when µ = 0 [35]. This relationship, which is suggested by (9), is why Q µ ν , Q µ ν and Q µ ν should really be defined to be twice as large. But to maintain compatibility with the past, the factor 1 2 implicit in their definitions will be kept.…”

Section: Normalizations and Asymptoticsmentioning

confidence: 99%

“…By (1b), it can be expressed in terms of the Legendre functions P ±m −s , and thus in terms of complete elliptic integrals. Legendre (rather than Ferrers) functions with ν a half-odd-integer and µ an integer are commonly called toroidal or 'anchor ring' functions, since harmonics including factors of the form P m n−1/2 (cosh ξ), Q m n−1/2 (cosh ξ) appear when solving boundary value problems in toroidal domains, upon separating variables in toroidal coordinates [9,10]. The efficient calculation of values of toroidal functions, employing recurrences or other numerical schemes, is well understood [11,12].…”

Section: Introductionmentioning

confidence: 99%

Legendre functions of fractional degree: transformations and evaluations

Maier

2016

Proc. R. Soc. A.

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Associated Legendre functions of fractional degree appear in the solution of boundary value problems in wedges or in toroidal geometries, and elsewhere in applied mathematics. In the classical case when the degree is half an odd integer, they can be expressed using complete elliptic integrals. In this study, many transformations are derived, which reduce the case when the degree differs from an integer by one-third, one-fourth or one-sixth to the classical case. These transformations, or identities, facilitate the symbolic manipulation and evaluation of Legendre and Ferrers functions. They generalize both Ramanujan's transformations of elliptic integrals and Whipple's formula, which relates Legendre functions of the first and second kinds. The proofs employ algebraic coordinate transformations, specified by algebraic curves. *

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“…The right hand side of Eq. 8is the zeroth order toroidal harmonic expansion for the inverse distance function in circular cylindrical coordinates [21][22][23][24][25][26][27] and can be derived directly from the free-space Green's function in circular cylindrical coordinates [28][29][30]. Figures 2 and 3 are plots which illustrate a comparison between Eqs.…”

Section: The Yukawa-potential Kernel Of a Circular Cylindrical Sourcementioning

confidence: 99%

A Toroidal Harmonic Representation of the Yukawa-potential Kernel for a Circular Cylindrical Source

Selvaggi¹,

Salon²,

Chari³

2008

PIERS Online

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A true cylindrical series expansion of the Yukawa-or screened Coulomb-potential kernel is developed for a finite circular cylindrical source through the application of a toroidal harmonic expansion. The Yukawa kernel is separated into a singular and nonsingular part. The singular part is expanded in terms of the associated toroidal harmonics and the nonsingular part is expanded in terms of an elementary binomial expansion.

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An application of toroidal functions in electrostatics

Cited by 19 publications

References 14 publications

Peculiarities in the gravitational field of a filamentary ring

Peculiarities in the gravitational field of a filamentary ring

Legendre functions of fractional degree: transformations and evaluations

A Toroidal Harmonic Representation of the Yukawa-potential Kernel for a Circular Cylindrical Source

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