| Preface |
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v | (2) |
| Introduction |
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vii | |
| Part I. Geometry and Nature |
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1 | (46) |
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Chaos game visualization of sequences |
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5 | (10) |
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15 | (4) |
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Computer simulation of the morphology and development of several species of seaweed using Lindenmayer systems |
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19 | (4) |
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Generating fractals from Voronoi diagrams |
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23 | (4) |
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Circles which kiss: a note on osculatory packing |
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27 | (6) |
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Graphical identification of spatio-temporal chaos |
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33 | (2) |
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Manifolds and control of chaotic systems |
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35 | (6) |
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A vacation on Mars-an artist's journey in a computer graphics world |
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41 | (6) |
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| Part II. Attractors |
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47 | (96) |
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Automatic generation of strange attractors |
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53 | (8) |
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Attractors with dueling symmetry |
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61 | (8) |
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A new feature in Henon's map |
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69 | (4) |
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Lyapunov exponents of the logistic map with periodic forcing |
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73 | (6) |
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Toward a better understanding of fractality in nature |
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79 | (14) |
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On the dynamics of real polynomials on the plane |
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93 | (10) |
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Phase portraits parametrically excited pendula: an exercise in multidimensional data visualisation |
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103 | (8) |
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Self-reference and paradox in two and three dimensions |
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111 | (4) |
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Visualizing the effects of filtering chaotic signals |
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115 | (6) |
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Oscillating iteration paths in neural networks learning |
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121 | (6) |
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The crying of fractal batrachion 1,489 |
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127 | (6) |
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Evaluating pseudo-random number generators |
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133 | (10) |
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| Part III. Cellular Automata, Gaskets, and Koch Curves |
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143 | (76) |
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Sensitivity in cellular automata: some examples |
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149 | (6) |
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One tub, eight blocks, twelve blinkers and other views of life |
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155 | (6) |
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161 | (8) |
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Sierpinski fractals and GCDs |
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169 | (8) |
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Complex patterns generated by next nearest neighbors cellular automata |
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177 | (8) |
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On the congruence of binary patterns generated by modular arithmetic on a parent array |
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185 | (6) |
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A simple gasket derived from prime numbers |
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191 | (2) |
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Discrete approximation of the Koch curve |
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193 | (8) |
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Visualizing Cantor cheese construction |
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201 | (6) |
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Notes on Pascal's pyramid for personal computer users |
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207 | (10) |
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Patterns generated by logical operators |
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217 | (2) |
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| Part IV. Mandelbrot, Julia and Other Complex Maps |
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219 | (128) |
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A tutorial on efficient computer graphic representations of the Mandelbrot set |
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225 | (10) |
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Julia sets in the quaternions |
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235 | (12) |
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Self-similar sequences and chaos from Gauss sums |
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247 | (4) |
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Color maps generated by "trigonometric iteration loops" |
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251 | (2) |
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A note on Halley's method |
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253 | (2) |
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A note on some internal structures of the Mandelbrot set |
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255 | (4) |
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259 | (4) |
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A generalized Mandelbrot set and the role of critical points |
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263 | (6) |
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A new scaling along the spike of the Mandelbrot set |
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269 | (12) |
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Further insights into Halley's method |
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281 | (2) |
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Visualizing the dynamics of the Rayleigh quotient iteration |
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283 | (4) |
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The "burning ship" and its quasi-Julia sets |
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287 | (4) |
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Field lines in the Mandelbrot set |
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291 | (6) |
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A tutorial on the visualization of forward orbits associated with Siegel disks in the quadratic Julia sets |
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297 | (4) |
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Image generation by Blaschke products in the unit disk |
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301 | (6) |
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An investigation of fractals generated by z xxx 1/z (-n)+c |
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307 | (6) |
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Infinite-corner-point fractal image generation by Newton's method for solving exp[-Alpha(xxx+z)(xxx-z)]-1=0 |
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313 | (8) |
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Chaos and elliptic curves |
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321 | (6) |
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Newton's method for multiple roots |
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327 | (4) |
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Warped midgets in the Mandelbrot set |
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331 | (10) |
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Automatic generation of general quadratic map basins |
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341 | (6) |
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| Part V. Iterated Function Systems |
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347 | (64) |
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Some nonlinear iterated function systems |
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353 | (8) |
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Balancing order and chaos in image generation |
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361 | (22) |
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Estimating the spatial extent of attractors of iterated function systems |
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383 | (8) |
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Automatic generation of iterated function systems |
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391 | (10) |
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Modeling and rendering of nonlinear iterated function systems |
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401 | (10) |
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| Part VI. Computer Art |
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411 | (36) |
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Automatic parallel generation of aeolian fractals on the IBM power visualization system |
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415 | (10) |
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Julia set art and fractals in the complex plane |
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425 | (4) |
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Methods of displaying the behaviour of the mapping z xxx z(2) + xxx |
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429 | (4) |
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AUTUMN - a recipe for artistic fractal images |
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433 | (2) |
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435 | (2) |
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Computer art representing the behavior of the Newton-Raphson method |
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437 | (2) |
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Systemised serendipity for producing computer art |
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439 | (2) |
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Computer art from Newton's, Secant, and Richardson's methods |
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441 | (6) |
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| Author Index |
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447 | (2) |
| Subject index |
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449 | (2) |
| About the Editor |
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451 | |
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