Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 17. Long Term Trends and Hurst Phenomena From ancient times the Nile river region has been known for its peculiar long-term behavior: long periods of.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "1 17. Long Term Trends and Hurst Phenomena From ancient times the Nile river region has been known for its peculiar long-term behavior: long periods of."— Presentation transcript:

1 1 17. Long Term Trends and Hurst Phenomena From ancient times the Nile river region has been known for its peculiar long-term behavior: long periods of dryness followed by long periods of yearly floods. It seems historical records that go back as far as 622 AD also seem to support this trend. There were long periods where the high levels tended to stay high and other periods where low levels remained low 1. An interesting question for hydrologists in this context is how to devise methods to regularize the flow of a river through reservoir so that the outflow is uniform, there is no overflow at any time, and in particular the capacity of the reservoir is ideally as full at time as at t. Let denote the annual inflows, and 1 A reference in the Bible says “seven years of great abundance are coming throughout the land of Egypt, but seven years of famine will follow them” (Genesis). (17-1) PILLAI

2 2 their cumulative inflow up to time n so that represents the overall average over a period N. Note that may as well represent the internet traffic at some specific local area network and the average system load in some suitable time frame. To study the long term behavior in such systems, define the “extermal” parameters as well as the sample variance In this case (17-3) (17-4) (17-5) (17-6) (17-2) PILLAI

3 3 defines the adjusted range statistic over the period N, and the dimen- sionless quantity that represents the readjusted range statistic has been used extensively by hydrologists to investigate a variety of natural phenomena. To understand the long term behavior of where are independent identically distributed random variables with common mean and variance note that for large N by the strong law of large numbers and (17-7) (17-8) (17-9) (17-10) PILLAI

4 4 with probability 1. Further with where 0 < t < 1, we have where is the standard Brownian process with auto-correlation function given by min To make further progress note that so that Hence by the functional central limit theorem, using (17-3) and (17-4) we get (17-11) (17-12) (17-13) PILLAI

5 5 where Q is a strictly positive random variable with finite variance. Together with (17-10) this gives a result due to Feller. Thus in the case of i.i.d. random variables the rescaled range statistic is of the order of It follows that the plot of versus log N should be linear with slope H = 0.5 for independent and identically distributed observations. (17-14) (17-15) Slope=0.5 PILLAI

6 6 The hydrologist Harold Erwin Hurst (1951) generated tremendous interest when he published results based on water level data that he analyzed for regions of the Nile river which showed that Plots of versus log N are linear with slope According to Feller’s analysis this must be an anomaly if the flows are i.i.d. with finite second moment. The basic problem raised by Hurst was to identify circumstances under which one may obtain an exponent for N in (17-15). The first positive result in this context was obtained by Mandelbrot and Van Ness (1968) who obtained under a strongly dependent stationary Gaussian model. The Hurst effect appears for independent and non-stationary flows with finite second moment also. In particular, when an appropriate slow-trend is superimposed on a sequence of i.i.d. random variables the Hurst phenomenon reappears. To see this, we define the Hurst exponent fora data set to be H if PILLAI

7 7 where Q is a nonzero real valued random variable. IID with slow Trend Let be a sequence of i.i.d. random variables with common mean and variance and be an arbitrary real valued function on the set of positive integers setting a deterministic trend, so that represents the actual observations. Then the partial sum in (17-1) becomes where represents the running mean of the slow trend. From (17-5) and (17-17), we obtain (17-16) (17-17) (17-18) PILLAI

8 8 Since are i.i.d. random variables, from (17-10) we get Further suppose that the deterministic sequence converges to a finite limit c. Then their Caesaro means also converges to c. Since applying the above argument to the sequence and we get (17-20) converges to zero. Similarly, since (17-19) (17-20) PILLAI

9 9 by Schwarz inequality, the first term becomes But and the Caesaro means Hence the first term (17-21) tends to zero as and so does the second term there. Using these results in (17-19), we get To make further progress, observe that (17-21) (17-22) (17-23) (17-24) PILLAI

10 10 and Consequently, if we let for the i.i.d. random variables, then from (17-6),(17-24) and (17-25) (17-26), we obtain where From (17-24) – (17-25), we also obtain (17-25) (17-26) (17-27) (17-28) PILLAI

11 11 From (17-27) and (17-31) we get the useful estimates and Since are i.i.d. random variables, using (17-15) in (17-26) we get a positive random variable, so that (17-29) (17-30) (17-31) (17-32) (17-33) (17-34) (17-35) PILLAI

12 12 Consequently for the sequence in (17-17) using (17-23) in (17-32)-(17-34) we get if H > 1/2. To summarize, if the slow trend converges to a finite limit, then for the observed sequence for every H > 1/2 in probability as In particular it follows from (17-16) and (17-36)-(17-37) that the Hurst exponent H > 1/2 holds for a sequence if and only if the slow trend sequence satisfies (17-36) (17-37) (17-38) PILLAI

13 13 In that case from (17-37), for that H > 1/2 we obtain where is a positive number. Thus if the slow trend satisfies (17-38) for some H > 1/2, then from (17-39) Example: Consider the observations where are i.i.d. random variables. Here and the sequence converges to a for so that the above result applies. Let (17-39) (17-40) (17-41) (17-42) PILLAI

14 14 To obtain its max and min, notice that if and negative otherwise. Thus max is achieved at and the minimum of is attained at N=0. Hence from (17-28) and (17-42)-(17-43) Now using the Reimann sum approximation, we may write (17-44) (17-43) PILLAI

15 15 so that and using (17-45)-(17-46) repeatedly in (17-44) we obtain (17-46) (17-45) PILLAI

16 16 where are positive constants independent of N. From (17-47), notice that if then where and hence (17-38) is satisfied. In that case (17-47) PILLAI

17 17 and the Hurst exponent Next consider In that case from the entries in (17-47) we get and diving both sides of (17-33) with so that where the last step follows from (17-15) that is valid for i.i.d. observations. Hence using a limiting argument the Hurst exponent (17-48) (17-49) PILLAI

18 18 H = 1/2 if Notice that gives rise to i.i.d. observations, and the Hurst exponent in that case is 1/2. Finally for the slow trend sequence does not converge and (17-36)-(17-40) does not apply. However direct calculation shows that in (17-19) is dominated by the second term which for large N can be approximated as so that From (17-32) where the last step follows from (17-34)-(17-35). Hence for from (17-47) and (17-50) (17-50) PILLAI

19 19 as Hence the Hurst exponent is 1 if In summary, (17-51) (17-52) Fig.1 Hurst exponent for a process with superimposed slow trend 1/2 1 -1/2 0 Hurst phenomenon PILLAI

Download ppt "1 17. Long Term Trends and Hurst Phenomena From ancient times the Nile river region has been known for its peculiar long-term behavior: long periods of."

Similar presentations

Random Processes Introduction (2)

Random Processes Introduction (2)
9. Two Functions of Two Random Variables

9. Two Functions of Two Random Variables
1 12. Principles of Parameter Estimation The purpose of this lecture is to illustrate the usefulness of the various concepts introduced and studied in.

1 12. Principles of Parameter Estimation The purpose of this lecture is to illustrate the usefulness of the various concepts introduced and studied in.
10 Further Time Series OLS Issues Chapter 10 covered OLS properties for finite (small) sample time series data -If our Chapter 10 assumptions fail, we.

10 Further Time Series OLS Issues Chapter 10 covered OLS properties for finite (small) sample time series data -If our Chapter 10 assumptions fail, we.
STAT 497 APPLIED TIME SERIES ANALYSIS

STAT 497 APPLIED TIME SERIES ANALYSIS
Model Fitting Jean-Yves Le Boudec 0. Contents 1 Virus Infection Data We would like to capture the growth of infected hosts (explanatory model) An exponential.

Model Fitting Jean-Yves Le Boudec 0. Contents 1 Virus Infection Data We would like to capture the growth of infected hosts (explanatory model) An exponential.
1 Chap 5 Sums of Random Variables and Long-Term Averages Many problems involve the counting of number of occurrences of events, computation of arithmetic.

1 Chap 5 Sums of Random Variables and Long-Term Averages Many problems involve the counting of number of occurrences of events, computation of arithmetic.
A gentle introduction to fluid and diffusion limits for queues Presented by: Varun Gupta April 12, 2006.

A gentle introduction to fluid and diffusion limits for queues Presented by: Varun Gupta April 12, 2006.
SUMS OF RANDOM VARIABLES Changfei Chen. Sums of Random Variables Let be a sequence of random variables, and let be their sum:

SUMS OF RANDOM VARIABLES Changfei Chen. Sums of Random Variables Let be a sequence of random variables, and let be their sum:
Descriptive statistics Experiment  Data  Sample Statistics Experiment  Data  Sample Statistics Sample mean Sample mean Sample variance Sample variance.

Descriptive statistics Experiment  Data  Sample Statistics Experiment  Data  Sample Statistics Sample mean Sample mean Sample variance Sample variance.
Evaluating Hypotheses

Evaluating Hypotheses
13. The Weak Law and the Strong Law of Large Numbers

13. The Weak Law and the Strong Law of Large Numbers
1 Simple Linear Regression Chapter 16. 2 Introduction In this chapter we examine the relationship among interval variables via a mathematical equation.

1 Simple Linear Regression Chapter Introduction In this chapter we examine the relationship among interval variables via a mathematical equation.
19. Series Representation of Stochastic Processes

19. Series Representation of Stochastic Processes
The moment generating function of random variable X is given by Moment generating function.

The moment generating function of random variable X is given by Moment generating function.
12 INFINITE SEQUENCES AND SERIES. 12.4 The Comparison Tests In this section, we will learn: How to find the value of a series by comparing it with a known.

12 INFINITE SEQUENCES AND SERIES The Comparison Tests In this section, we will learn: How to find the value of a series by comparing it with a known.
1 10. Joint Moments and Joint Characteristic Functions Following section 6, in this section we shall introduce various parameters to compactly represent.

1 10. Joint Moments and Joint Characteristic Functions Following section 6, in this section we shall introduce various parameters to compactly represent.
Standard error of estimate & Confidence interval.

Standard error of estimate & Confidence interval.
Review of Probability.

Review of Probability.
Introduction to AEP In information theory, the asymptotic equipartition property (AEP) is the analog of the law of large numbers. This law states that.

Introduction to AEP In information theory, the asymptotic equipartition property (AEP) is the analog of the law of large numbers. This law states that.

Similar presentations

Ads by Google