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Author(s)
Lena JT Strömberg, previously Department of Solid Mechanics, Royal Institute of Technology, KTH, Sweden
Abstract
Propagation and static distribution of light on noncircular orbits are modelled. The space where light embodies is determined with kinematics, such that the perpendicular velocity of the 'material'space described as a noncircular orbit, is harmonic with amplitude fwre. Light propagation to discrete orbits may occur with arbitrary velocity. The modeling serves to describe light when distributed on an arch e.g. rainbow or cloud bow, and when located into more discrete spots. The latter is assumed being present at singularities of the electric field. The assumption of convolution gives propagation of light onto a new noncircular orbit, with solutions of discrete multiple singularities. This is compared with biSolars of a Halo. A fine structure will be outlined assuming bibiSolars implied as fractals.
Keywords
noncircular orbit, halo, singularities, electromagnetism, discrete solutions, rainbow, convolution, harmonics, fractal, cycle for f
Cite this paper
Lena JT Strömberg,
Halo Phenomena modeled with Distributed and Quantum Optics given by Electrodynamic Singularities on a Noncircular Orbit, SCIREA Journal of Physics. Vol.
1
, No.
1
,
2016
, pp.
33

40
.
References
[1]  Arnold V.I (1978). Mathematical Methods of Classical Mechanics (Graduate Texts in Mathematics, Vol. 60), Springer, 2nd Edition 1989. 
[2]  Correia A, Laskar J (2004). Mercury's capture into the 3/2 spinorbit resonance as a result of its chaotic dynamics. Nature 429, 848850. 
[3]  Gurtin ME, PodioGuidugli P (1996). Configurational forces and the intrinsic laws for crack propagation. J. Mech. Phys. Solids, 44(6): 905927. 
[4]  Helsing J, Karlsson A. (2016). Determination of normalized electric eigenfields in microwave cavities with sharp edges. Journal of Computational Physics 304 465–486. 
[5]  Runesson K, Larsson F, Steinman P. (2009). On energetic changes due to configurational motion of standard continua, Int. J. of Solids and Structures, 46(6), 14641475. 
[6]  Strömberg L (2014). A model for noncircular orbits derived from a twostep linearisation of the Kepler laws. Journal of Physics and Astronomy Research 1(2): 013014. 
[7]  Strömberg L (2015). Models for locations in the solar system. J. Physics and Astronomy. Res. 1(2): 054058. 
[8]  Strömberg L (2015). Hypergravity derived from the Ledensity and applied to a model for explosion. Analysis of universal constants of gravity and light in conjunction with the Jspace. J of Scientific Research and Essays 1(2) 
[9]  Strömberg L (2015). Observations for Lateral Light at a Hole Adjacent To Lines of Different Colours Comparison with the Eye in Terms of Iris and Blue Make Up Analysis of Monochromatic Light. Journal of Scientific Research and Essays 1(2) 
[10]  Strömberg L (2016). Results for noncircular orbits, LAP Lambert Academic publishing Germany. ISBN13 9783659852183). 
[11]  Strömberg L (2016)2. Noncircular orbits at MC vehicle wobbling, in whirls and for light, LAP Lambert Academic publishing, Germany. ISBN13 9783659856648. 