Week 8.3: Relation to the infinitely divisible distributions

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En provenance du cours de National Research University Higher School of Economics

Stochastic processes

39 notes

National Research University Higher School of Economics

Stochastic processes

39 notes

The purpose of this course is to equip students with theoretical knowledge and practical skills, which are necessary for the analysis of stochastic dynamical systems in economics, engineering and other fields. More precisely, the objectives are 1. study of the basic concepts of the theory of stochastic processes; 2. introduction of the most important types of stochastic processes; 3. study of various properties and characteristics of processes; 4. study of the methods for describing and analyzing complex stochastic models. Practical skills, acquired during the study process: 1. understanding the most important types of stochastic processes (Poisson, Markov, Gaussian, Wiener processes and others) and ability of finding the most appropriate process for modelling in particular situations arising in economics, engineering and other fields; 2. understanding the notions of ergodicity, stationarity, stochastic integration; application of these terms in context of financial mathematics; It is assumed that the students are familiar with the basics of probability theory. Knowledge of the basics of mathematical statistics is not required, but it simplifies the understanding of this course. The course provides a necessary theoretical basis for studying other courses in stochastics, such as financial mathematics, quantitative finance, stochastic modeling and the theory of jump - type processes.

À partir de la leçon

Week 8: Lévy processes

Upon completing this week, the learner will be able to understand the main properties of Lévy processes; construct a Lévy process from an infinitely-divisible distribution; characterize the activity of jumps of a given Lévy process; apply the Lévy-Khintchine representation for a particular Lévy process and understand the time change techniques, stochastic volatility approach are other ideas for construction of Lévy-based models.

Week 8.1: Definition of a Lévy process. Stochastic continuity and càdlàg paths.12:36

Week 8.2: Examples of Lévy processes. Calculation of the characteristic function in particular cases17:37

Week 8.3: Relation to the infinitely divisible distributions7:24

Week 8.4: Characteristic exponent8:45

Week 8.5: Properties of a Lévy process, which directly follow from the existence of characteristic exponent7:45

Week 8.6: Lévy-Khintchine representation and Lévy-Khintchine triplet-17:03

Week 8.7: Lévy-Khintchine representation and Lévy-Khintchine triplet-27:33

Week 8.8: Lévy-Khintchine representation and Lévy-Khintchine triplet-38:20

Week 8.9: Modelling of jump-type dynamics. Lévy-based models7:28

Week 8.10: Time-changed stochastic processes. Monroe theorem9:07

Rencontrer les enseignants

Vladimir Panov
Assistant Professor
Faculty of economic sciences, HSE

In this subsection, I would like to show a couple of

properties of the infinitely divisible distributions and to prove that

the Bernoulli distribution and the uniform distribution are not infinitely divisible.

Let me formulate a couple of properties of an infinitely divisible distribution.

The first property says,

the characteristic function of

any infinitely divisible distribution is not equal to zero for any real U.

In other words, this equation a phi of U is equal to zero,

does not have any real solutions.

This fact is rather interesting because you know that phi is a complex-valued function,

and if phi is a polynomial of order N,

then it should have a root,

the equation should have a root.

And here, from this fact,

it follows that all of these roots are complex, not real.

Why this fact helps to show that a uniform distribution is not infinitely divisible?

Well, let me calculate the characteristic function of uniform distribution.

Let me assume that xi is uniform on the interval a_b.

And in this case,

the characteristic function of xi is equal to the integral from a to b,

exponent in the power iux

multiplied by 1 divided by b minus a, dx.

And this integral is equal to 1 divided by b minus a,

exponent in the power complex unit ua divided by iu,

and multiply it by exponent is the power iu, b minus a minus 1.

Here, I assume that u is not equal to zero.

Otherwise, the characteristic function is simply equal to 1.

Now, I would like to show that the equation

that phi xi of U is equal to zero has some roots.

Okay, this expression is equal to zero,

if and only if,

exponent is the power iu b minus a minus 1 is equal to zero.

And this means that U is equal to 2 pi K divided by b minus a,

where K is an integer number and does not equal to zero,

because the case U equal to zero we have considered separately.

So, we conclude that the equation that phi of U is equal to zero,

has some roots and therefore,

uniform distribution cannot be infinitely divisible.

Okay, the second property,

which is also very interesting and which holds for any infinitely divisible distribution,

is that the support of

a random variable have an infinitely divisible distribution is unbounded.

What does it mean? So, support of a random variable is

by definition a support of its probability distribution.

Probability distribution of Borel subset B

is a probability that this random variable is from B.

And support of any measure, by definition,

is a set of all X's such that for

any open set G containing X,

the measure of this G is strongly positive.

Let me consider the support of Bernoulli random variable.

You know that Bernoulli random variable xi is equal to 1 with

some probability P and is equal to zero with probability 1 minus P. Therefore,

we have the following pictures.

There are two points, zero and one,

and both of these points are definitely in the support of xi.

Just look at this definition.

If we take any set containing zero one,

for instance, a set containing one,

the probability is that xi is in this set is stronger,

larger than zero, because the probability that xi is equal to zero is equal to 1 minus B.

The same situation is with all sets containing 1.

So definitely, zero and one,

these two points, are in the support of the probability measure of xi.

Otherwise, it would take any point which is not equal to zero and 1,

this point is not in the support because if you consider some

namely any small set containing this point,

the probability that xi is the support is equal to zero.

So, we conclude that the support of xi is equal to two points,

zero and one, and if xi will be an infinitely divisible distribution,

the support of xi should be unbounded.

And therefore, we conclude that the distribution of xi is not infinitely divisible.

So, now we'll have a couple of concrete examples of infinitely divisible distributions

and we have a couple of interesting properties of any infinitely divisible distribution.

As end, let me mention that most distributions are infinitely divisible and actually,

these two examples are the only examples of

not infinitely divisible distribution which are widely used in the probability theory.

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