Central Limit theorem derived from Stochastic Processes

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Central Limit theorem derived from Stochastic Processes
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz, 2 Ch
Genre: eLearning | Language: English + srt | Duration: 21 lectures (4h 13m) | Size: 2.05 GB

It is well known that a plethora of natural stochastic processes often showcase a Gaussian probability distribution.


Mathematical intuition behind the (often) Gaussian behavior of nature

the mathematical reason why natural Stochastic Processes often have a Gaussian distribution

Calculation of the probability density from a signal in the domain (Stochastic Process)

concept of ergodicity of Stochastic Processes (why it is important)

useful mathematical reasoning while dealing with Stochastic processes

Mathematical derivation of the Central Limit theorem

Mathematical derivation of the distribution of a sinusoid

Fourier Transform and its Inverse

Fourier series

Calculus (integrals, derivatives)

Basic concepts of probability theory (what is a: random variable, probability density, etc)

This course aims to explain mathematically why such behavior is displayed.

The formulas that are derived in the course, will allow calculating the probability density function from the moments of the stochastic process.

The results presented are related to the well-known Central Limit Theorem (CLT). However, the latter is usually introduced when talking about random variables in Statistics, whereas it is definitely less obvious how the CLT affects Stochastic processes. The aim of this course is therefore to provide motivation as to how this happens mathematically.

This is an advanced course based on the instructor's PhD thesis, therefore the presentation and the formulas presented are original, despite the literature abounds with material relevant to this subject.

The prerequisites to the course are listed on this page and in the introductory video. It is worth mentioning that the most fundamental properties of the Fourier Transform and Fourier series, which are needed throughout the course's lectures, are revised in the in the first part of the course.

Note: at the moment (April 2021), I am editing the contents of this course to make my presentation delivery smoother (it will take some ).

Students who desire to know the mathematical details of Stochastic Processes

Students who desire to understand the deep significance of the Central Limit theorem, and how it beautifully arises when dealing with Stochastic Processes




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