Inversive Diversions and Diversive Inversions
Inhaltsverzeichnis
Referenz
Gregg Helt: Inversive Diversions and Diversive Inversions. In: Bridges 2017, Pages 467–470.
DOI
Abstract
In this paper, we first briefly review aspects of inversive geometry and inversive fractals. Motivated by a desire to expand our geometric and artistic toolkit, we then introduce mixed-restriction limit sets as a new technique for use with iterated function systems and groups of circle inversions to create previously undiscovered 2D inversive fractals. We also apply this technique to diverse shape-based inversions that are closely related to circle inversion. Finally, we explore extending mixed-restriction limit sets and shape-based inversions into 3D to generate 3D inversive fractals.
Extended Abstract
Bibtex
@inproceedings{bridges2017:467, author = {Gregg Helt}, title = {Inversive Diversions and Diversive Inversions}, pages = {467--470}, booktitle = {Proceedings of Bridges 2017: Mathematics, Art, Music, Architecture, Education, Culture}, year = {2017}, editor = {David Swart, Carlo H. S\'equin, and Krist\'of Fenyvesi}, isbn = {978-1-938664-22-9}, issn = {1099-6702}, publisher = {Tessellations Publishing}, address = {Phoenix, Arizona}, note = {Available online at \url{http://archive.bridgesmathart.org/2017/bridges2017-467.pdf}} }
Used References
[1] M. F. Barnsley and S. Demko, “Iterated Function Systems and the Global Construction of Fractals”, Proceedings of the Royal Society of London, vol. 399, no. 1817, pp. 243–275, 1985
[2] B. B. Mandelbrot, “Self-inverse Fractals, Apollonian Nets, and Soap”, The Fractal Geometry of Nature, Chapter 18, pp. 166-179, 1982
[3] V. Bulatov, “Inversive Kaleidoscopes and Their Visualization”, Proceedings of Bridges 2014: Mathematics, Music, Art, Architecture, Culture, pp. 329–332, 2014
[4] R. M. Baram and H. J. Herrmann, “Self-similar Space-filling Packings in Three Dimensions”, Fractals, vol. 12, no. 03, pp. 293–301, 2004
[5] C. Clancy and M. Frame, “Fractal Geometry of Restricted Sets of Circle Inversions”, Fractals, vol. 03, no. 04, pp. 689–699, 1995
[6] K. Gdawiec, “Star-shaped Set Inversion Fractals”, Fractals, vol. 22, no. 04, pp. 1450009.1-7, 2014
[7] J. L. Ramírez and G. N. Rubiano, “A Generalization of the Spherical Inversion”, International Journal of Mathematical Education in Science and Technology, vol. 48, no. 1, pp. 132–149, 2017
[8] J. Gielis, “A generic geometric transformation that unifies a wide range of natural and abstract shapes”, American Journal of Botany, vol. 90, no. 3, pp. 333–338, 2003
[9] G. Helt, “A Rose By Any Other Name...”, Proceedings of Bridges 2016: Mathematics, Music, Art, Architecture, Education, Culture, pp. 445–448, 2016
[10] A. Maschke, JWildfire software, 2011. Current release v3.10 (April 2017), http://jwildfire.org
Links
Full Text
http://archive.bridgesmathart.org/2017/bridges2017-467.pdf