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YangQuan Chen, Ph.D., Director, MESA (Mechatronics, Embedded Systems and Automation) Lab

Fractional Order Mechanics: Motivations Final Front : Fractional Order Stochasticity Power Law, Scale-Free, Heavy- Tailedness , Long Range Dependence, Long Memory, and Complexity due to Fractional Dynamics. YangQuan Chen, Ph.D., Director,

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YangQuan Chen, Ph.D., Director, MESA (Mechatronics, Embedded Systems and Automation) Lab

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  1. Fractional Order Mechanics: MotivationsFinal Front: Fractional Order StochasticityPower Law, Scale-Free, Heavy-Tailedness, Long Range Dependence, Long Memory, and Complexity due to Fractional Dynamics YangQuan Chen, Ph.D., Director, MESA (Mechatronics, Embedded Systems and Automation)Lab MEAM/EECS, School of Engineering, University of California, Merced E: yqchen@ieee.org; or, yangquan.chen@ucmerced.edu T: (209)228-4672; O: SE1-254; Lab: Castle #22 (T: 228-4398) 9/12/2013. Thursday 09:00-11:15, KL217

  2. All Connected via Fractional Calculus: Power Law, Scale-Free, Heavy-Tailedness, Long Range Dependence, Long Memory, and Complexity due to Fractional Dynamics YangQuan Chen, Ph.D., Director, MESA (Mechatronics, Embedded Systems and Automation)Lab MEAM/EECS, School of Engineering, University of California, Merced E: yqchen@ieee.org; or, yangquan.chen@ucmerced.edu T: (209)228-4672; O: SE1-254; Lab: Castle Eng 820 (T: 228-4398) http://mechatronics.ucmerced.edu/research/applied-fractional-calculus February 25, 2012. Monday 3:00PM-4:30PM MTS (Mind, Technology and Society) Seminar Series @ UCMerced COB 110

  3. Almost All Connected via Fractional Calculus: Power Law, Scale-Free, Heavy-Tailedness, Long Range Dependence, Long Memory, and Complexity due to Fractional Dynamics YangQuan Chen, Ph.D., Director, MESA (Mechatronics, Embedded Systems and Automation)Lab MEAM/EECS, School of Engineering, University of California, Merced E: yqchen@ieee.org; or, yangquan.chen@ucmerced.edu T: (209)228-4672; O: SE1-254; Lab: Castle Eng 820 (T: 228-4398) http://mechatronics.ucmerced.edu/research/applied-fractional-calculus February 25, 2012. Monday 3:00PM-4:30PM MTS (Mind, Technology and Society) Seminar Series @ UCMerced COB 110

  4. “Fractional Order Thinking” or, “In Between Thinking” • For example • Between integers there are non-integers; • Between logic 0 and logic 1, there is the “fuzzy logic”; • Between integer order splines, there are “fractional order splines” • Between integer high order moments, there are noninteger order moments (e.g. FLOS) • Between “integer dimensions”, there are fractal dimensions • Fractional Fourier transform (FrFT) – in-between time-n-freq. • Non-Integer order calculus (fractional order calculus – abuse of terminology.) (FOC) ME280 Fractional Order Mechanics

  5. 0 1 ME280 Fractional Order Mechanics

  6. Outline • Connectedness • Power Law, Scale-Free, • Heavy-Tailedness, • Long Range Dependence, Long Memory • Take home messages • When to use Fractional Calculus • Complexity due to Fractional Dynamics ME280 Fractional Order Mechanics

  7. Power Law • “Scaling laws in cognitive sciences” by CT Kello, GDA Brown, R Ferrer-i-Cancho, JG Holden, K Linkenkaer-Hansen, T. Trends in Cognitive Sciences 14 (5), 223-232, 2010 When k is negative: Inverse power law Scale-free Scale invariance ME280 Fractional Order Mechanics

  8. http://www.cafepress.com/thepowerlawshop ME280 Fractional Order Mechanics

  9. In Different Contexts • Scale-free networks (degree distributions) • Pink noise (power spectrum) • Probability density function (PDF) • Autocorelation function (ACF) • Allometry(Y=a Xb) • Anomalous relaxation (evolving over time) • Anomalous diffusion (MSD versus time) • Self-similar ME280 Fractional Order Mechanics

  10. Other connectedness to FC? (hidden) • Fractal, irregular, anomalous, rough, Hurst • Multifractal, multi-scale, scale-rich • Renormalization (?), Universality • Extreme events– spikiness, bursty, intermittence • Fluctuation in fluctuations; Variability, • Emergence, Surprise • Nonlocality, Long term memory • Complex (behavior, processes, network, fluid, dynamics, systems …) ME280 Fractional Order Mechanics

  11. Integer Order CalculusExponential Law ME280 Fractional Order Mechanics

  12. Fractional Order CalculusPower Law ME280 Fractional Order Mechanics

  13. Fractional Order CalculusPower Law Mittag-Leffler function in two parameters: E1,1(x)=ex ME280 Fractional Order Mechanics

  14. G. M. Mittag-Leffler(1846-1927) Professor Donald E. Knuth, creator of TEX: “As far as the spacing in mathematics is concerned...I took ActaMathematica, from 1910 approximately; this was a journal in Sweden ... Mittag-Leffler was the editor, and his wife was very rich, and they had the highest budget for making quality mathematics printing. So the typography was especially good in ActaMathematica.” (Questions and Answers with Prof. Donald E. Knuth, Charles University, Prague, March 1996) ME280 Fractional Order Mechanics

  15. The Mittag-Leffler function ME280 Fractional Order Mechanics

  16. Root of long (algebraic) tail, or inverse power law Tail MATTERS! ME280 Fractional Order Mechanics

  17. Complex relaxation in NMR http://en.wikipedia.org/wiki/Metastasis http://www.ispub.com/journal/the-internet-journal-of-radiology/volume-13-number-1/in-vivo-mr-measurement-of-refractive-index-relative-water-content-and-t2-relaxation-time-of-various-brain-lesions-with-clinical-application-to-discriminate-brain-lesions.article-g08.fs.jpg ME280 Fractional Order Mechanics

  18. T2 relaxation in NMR http://hs.doversherborn.org/hs/bridgerj/DSHS/apphysics/NMR/T2.htm ME280 Fractional Order Mechanics

  19. T2 relaxation in NMR Carr–Purcell–Meiboom–Gill (CPMG) pulse sequence, as shown in Fig. 1, is widely used to measure spin–spin relaxation time T2 magnetization decay data M(t) with poor SNR ME280 Fractional Order Mechanics

  20. Complex relaxation: How to characterize or model it? • Debye relaxation • Distributed-parameter (infinite # of time constants) (H. Fröhlich, 1949) ME280 Fractional Order Mechanics

  21. Complex relaxation: How to better characterize or model it? • Cole-Cole (1941) • Distributed-parameter (infinite # time constants) (Hu, Li and Chen, IEEE CDC 2010) ME280 Fractional Order Mechanics

  22. More complex relaxation models • Havriliak-Negami • Cole-Davidson • Distributed-order case? Sure! ME280 Fractional Order Mechanics

  23. An illustration • a = 0.75, T=1 sec. • Distributed-parameter (infinite time constants) ME280 Fractional Order Mechanics

  24. Scanning the “order” and fitting The order information might be important in diagnosis of cancer, trauma etc. for treatment responses … ME280 Fractional Order Mechanics

  25. Fractional noises / fluctuations Brownian motion, or Weiner process anti-persistent persistent fBm fGn Normal Gaussian noise http://www.frontiersin.org/Fractal_Physiology/10.3389/fphys.2012.00208/full ME280 Fractional Order Mechanics

  26. Spikiness/Burstiness Poisson PDF Inverse power law PDF A.-L. Barabási. The origin of bursts and heavy tails in human dynamics. Nature 435207–211 (2005). http://seeingcomplexity.wordpress.com/2011/03/07/global-android-activations-and-the-power-law/ ME280 Fractional Order Mechanics

  27. Examples of the power law slope in a) a patient with cardiac disease; and b) a healthy person. Phyllis K. Stein, Ph.D., Anand Reddy, M.D. “Non-Linear Heart Rate Variability and Risk Stratification in Cardiovascular Disease” Indian Pacing and Electrophysiology Journal (ISSN 0972-6292), 5(3): 210-220 (2005) ME280 Fractional Order Mechanics

  28. HRV – fractional dynamics? Usefulness w/ an iPhone App? http://www.londonintegratedhealth.co.uk/stress_health_and_performance.html ME280 Fractional Order Mechanics

  29. Stable Distributions a=2: Gaussian a=1, b=0: Cauchy a=1.5,b=1: Levy http://academic2.american.edu/~jpnolan/stable/stable.html ME280 Fractional Order Mechanics

  30. Connection to FC via PDF • “Fractional Calculus and Stable Probability Distributions” (1998) by byRudolf Gorenflo , Francesco Mainardi http://arxiv.org/pdf/0704.0320.pdf ME280 Fractional Order Mechanics

  31. Heavy tail, fat tail ME280 Fractional Order Mechanics

  32. Long jumps, intermittence Levy flights Brownian motion ME280 Fractional Order Mechanics

  33. Spikiness/Burstiness

  34. Long-range • dependence • Hurst • parameter • Self-similar • ARFIMA • -stable • distributions • NETWORK • TRAFFIC • Fractional Gaussian • noise (FGn) • “Spikiness” • “Heavy tails” • Fractional Brownian motion (FBm)

  35. Random delay dynamics ????? • Self-similarity => Hurstparameter • “Spikiness”.

  36. Long-range dependence History: The first model for long range dependence was introduced by Mandelbrot and Van Ness (1968) Value: financial data communications networks data video traffic biocorrosion data ME280 Fractional Order Mechanics

  37. Long-range dependence (LRD) Consider a second order stationary time series Y = {Y (k)} with mean zero. The time series Y is said to be long-range dependentif ME280 Fractional Order Mechanics

  38. Motivations: Long Memory or LRD Concept of persistency – shot responses short memory long memory DOI 10.1007/s00477-005-0029-y ME280 Fractional Order Mechanics

  39. SRD vs LRD • Short-range dependent (SRD) processes are characterized by an autocorrelation function which decays exponentially fast; • Long-range dependence (LRD) processes exhibit a much slower decay of the correlations - their autocorrelation functions typically obey some inverse power law. http://en.wikipedia.org/wiki/Long-range_dependency ME280 Fractional Order Mechanics

  40. Mathematically, • A stationary process is said to have long-range correlations if its covariance function C(n) (assume that the process has finite second-order statistics) decays slowly as n→∞, i.e. for 0 < α < 1, where c is a finite, positive constant. • The weakly-stationary time-series X(t) is said to be long range dependent if its spectral density obeys f(λ) ∼ Cf|λ|−βas λ → 0, for some Cf > 0 and some real parameter β ∈ (0, 1). ME280 Fractional Order Mechanics

  41. Heavy tailedness and Long tailedness • The distribution of a random variable X with distribution function F is said to have a heavy right tail if • The distribution of a random variable X with distribution function F is said to have a long right tail if for all t > 0, NOTE: long-tailed distributions are heavy-tailed, but the converse is false if you know the situation is bad, it is probably worse than you think. http://en.wikipedia.org/wiki/Heavy-tailed_distribution ME280 Fractional Order Mechanics

  42. 100+ years of LRD/HT research • Distribution of wealth, income of individuals • City sizes vs. ranks - given the population, what is the city rank? • Graphs of gene regulatory & protein-protein networks are scale free • Long neuron inter-spike intervals in depressed mice • Internet and WWW - scale free network (graph): fault tolerant, hubs are both the strength and Achilles’ heels • Scene lengths in VBR and MPEG video are heavy-tailed • Computer files, Web documents, frequency of access are heavy-tailed • Stock price fluctuations and company sizes • Inter occurrence of catastrophic events, earthquakes - applications to reinsurance • Frequency of words in natural languages (often called Zipf’s law) Ubiquity of Power Laws, Jankovic, 2007 ME280 Fractional Order Mechanics

  43. Fractional Calculus, LRD, Power Law, u(t) y(t) White Noise y(t) is a Brownian motion when a=1, i.e., process. noise (signal) generation via fractional dynamic system • Power laws in • Signal/Systems • Probability distribution • Random processes (correlation functions) ME280 Fractional Order Mechanics

  44. chemotaxis behavior quantification • Soil remediation • Genetically engineered bacterium • Targeted chemotractant ME280 Fractional Order Mechanics

  45. Video microscopy ME280 Fractional Order Mechanics

  46. Sample trajectory of one bacterium ME280 Fractional Order Mechanics

  47. Sample variances ME280 Fractional Order Mechanics

  48. Good news: NOT second order processes! • Research opportunities related to FOSP • Find the most sensitive index to quantify the chemotaxis behavior (Hurst parameter?) • Most robust to bacteria population size, temporal sample size • Complex Hurst parameter for complex (2D) motion? • 2-D LRD (Long range dependent) processes? • On-going efforts. ME280 Fractional Order Mechanics

  49. Running variance estimate is not convergent! ME280 Fractional Order Mechanics

  50. Noise - 1 Normal distribution N(0,1) Sample Variance ME280 Fractional Order Mechanics

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