User:Felix Hoffmann/Sandbox

Stochastic Process

Given a probability space $(\Omega ,\Sigma ,P)$ and a measurable space $(E,{\mathcal {E}})$ , a stochastic process is a family of stochastic variables $(X_{t}:\Omega \to E)_{t\in I}$ , that is a map

X:\Omega \times I\to E,\;(\omega ,t)\mapsto X_{t}(\omega )\;

,

such that for all $t\in I$ the map $X_{t}:\;\omega \mapsto X_{t}(\omega )\;$ is $\Sigma$ - ${\mathcal {\mathcal {E}}}$ -measurable.

If $E$ is finite or countable, $(X_{t})_{t\in I}$ is called a point process.

Example: Poisson Process

Point Process

A poisson process is a counting process, that is a stochastic process {N(t), t ≥ 0} with values that are positive, integer, and increasing:

N(t) ≥ 0.
N(t) is an integer.
If s ≤ t then N(s) ≤ N(t).

Poisson Distribution

The poisson distribution of intensity $\lambda$ of a stochastic variable $X:\Omega \to \mathbb {N} _{0}$ , is a probability distribution given by the probability mass function

P_{\lambda }(k):=\operatorname {Pr} [X=k]={\frac {\lambda ^{k}e^{-\lambda }}{k!}}.

For the poisson distribution to be a well-defined distribution, we need to check that $\Pr[\mathbb {N} _{0}]=1$ . Indeed,

\Pr[\mathbb {N} _{0}]=\Pr[\bigcup _{k\in \mathbb {N} _{0}}\{k\}]=\sum _{k\in \mathbb {N} _{0}}\Pr[\{k\}]=\underbrace {\sum _{k\in \mathbb {N} _{0}}{\frac {\lambda ^{k}}{k!}}} _{=e^{\lambda }}e^{-\lambda }=1.

Then, also, $\Pr[S\subseteq \mathbb {N} _{0}]$ exists for every subset $S\subseteq \mathbb {N} _{0}$ , since $\Pr[S]$ is bounded by one and a monotonic growing function in $n$ , since $\Pr[\{k\}]$ is positive for all $k\in \mathbb {N} _{0}$ .

The expected value of a stochastic variable X following poisson distribution is computed as (link Expactation value of a discrete random variable) :

\operatorname {E} [X]=\sum _{k\in \mathbb {N} _{0}}k\operatorname {Pr} [X=k]=\sum _{k\in \mathbb {N} _{0}}k{\frac {\lambda ^{k}}{k!}}\,\mathrm {e} ^{-\lambda }=\lambda \,\mathrm {e} ^{-\lambda }\underbrace {\sum _{k=1}^{\infty }{\frac {\lambda ^{k-1}}{(k-1)!}}} _{=\mathrm {e} ^{\lambda }}=\lambda .

Expactation value of a discrete random variable

Let $X:\Omega \to \mathbb {R}$ be a discrete stochastic variable. Then the expected value of $X$ can be calculated as

\operatorname {E} [X]=\sum _{n\in \mathbb {N} }nP^{X}(n).

Proof:

It is $X^{-1}({r})=\emptyset$ for $r\notin \mathbb {N}$ , we have

X^{-1}(\mathbb {N} )=X^{-1}(\mathbb {R} )

.

Thus

{\begin{aligned}\operatorname {E} [X]&=\int _{\Omega }X\mathrm {d} P=\int _{\bigcup _{n\in \mathbb {N} }X^{-1}(\{n\})}X\mathrm {d} P=\sum _{n\in \mathbb {N} }\int _{X^{-1}(\{n\})}X\mathrm {d} P\\&=\sum _{n\in \mathbb {N} }\int _{X^{-1}(\{n\})}n\mathbf {1} _{X^{-1}(\{n\})}\mathrm {d} P\,\,{\stackrel {\mathrm {Def.} }{=}}\,\,\sum _{n\in \mathbb {N} }nP(X^{-1}(\{n\}))\,\,{\stackrel {\mathrm {Def.} }{=}}\,\,\sum _{n\in \mathbb {N} }nP^{X}(n).\end{aligned}}

Binomial Distribution

The binomial distribution with parameters n and p of a stochastic variable $X:\Omega \to \mathbb {N} _{0}$ , is a probability distribution of X given by the probability mass function

\operatorname {Pr} [X=k]={n \choose k}\,p^{k}\,(1-p)^{n-k}.

If X follows the binomial distribution with parameters n, the number of independent experiments, and p, the probability for one experiment to give the answer "yes", we write K ~ B(n, p).

We have

\Pr[\mathbb {N} _{0}]=\Pr[\bigcup _{k\in \mathbb {N} _{0}}\{k\}]=\sum _{k\in \mathbb {N} _{0}}\Pr[\{k\}]=\sum _{k\in \mathbb {N} _{0}}{\binom {n}{k}}p^{k}(1-p)^{n-k}\,\,{\stackrel {\mathrm {Binom.} }{=}}\,\,(p+(1-p))^{n}=1.

The expected value of a stochastic variable X following the binomial distribution is calculated as (link Expactation value of a discrete random variable) :

{\begin{aligned}\operatorname {E} [X]&=\sum _{k\in \mathbb {N} _{0}}k\operatorname {Pr} [X=k]\\&=\sum _{k=0}^{n}k{\binom {n}{k}}p^{k}(1-p)^{n-k}\\&=np\sum _{k=0}^{n}k{\frac {(n-1)!}{(n-k)!k!}}p^{k-1}(1-p)^{(n-1)-(k-1)}\\&=np\sum _{k=1}^{n}{\frac {(n-1)!}{(n-k)!(k-1)!}}p^{k-1}(1-p)^{(n-1)-(k-1)}\\&=np\sum _{k=1}^{n}{\binom {n-1}{k-1}}p^{k-1}(1-p)^{(n-1)-(k-1)}\\&=np\sum _{\ell =0}^{n-1}{\binom {n-1}{\ell }}p^{\ell }(1-p)^{(n-1)-\ell }\quad {\text{mit }}l:=k-1\\&=np\sum _{\ell =0}^{m}{\binom {m}{\ell }}p^{\ell }(1-p)^{m-\ell }\qquad {\text{mit }}m:=n-1\\&=np\left(p+\left(1-p\right)\right)^{m}=np1^{m}=np\end{aligned}}

Its variance is given by

\operatorname {Var} (X)=\sum _{k=0}^{n}k^{2}{\binom {n}{k}}p^{k}(1-p)^{n-k}-n^{2}p^{2}=np(1-p),

where we used the computational formula for the variance in $\operatorname {Var} (X)=\operatorname {E} \left(X^{2}\right)-\left(\operatorname {E} \left(X\right)\right)^{2}$ . (uncomplete proof!)

Spiketrains and instanteous firing rate (article)

Reference: Poisson Model of Spike Generation - David Heeger

A spike train of n spikes occuring at times $t_{i},i=1,..,n$ , is given as function

\rho (t)=\sum _{i=1}^{n}\delta (t-t_{i}),

which is more sophistically known as the neural response function.

The number of spikes N, occuring between two points in time $t_{1}<t_{2}$ , is computed as

N=\int _{t_{1}}^{t_{2}}\rho (t)\,\mathrm {d} t.

Because the sequence of action potentials generated by a given stimulus typically varies from trial to trial, neuronal responses are typically treated probabilistically. One (very simple) way to characterize the probabilitistic behaviour of the firing of a neuron is by the spike count rate r, which is given by

r={\frac {N}{T}}={\frac {1}{T}}\int _{0}^{T}\rho (t)\,\mathrm {d} t,

The spike count rate be determined vor a single trial period, or can be averaged over several trials. Another possible way of characterization