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140 lines
4.8 KiB
TeX
140 lines
4.8 KiB
TeX
% vim: fdm=marker fmr=<<<,>>>
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\documentclass[../thesis.tex]{subfiles}
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\graphicspath{
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{.}
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{../../figures/}
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{../../../figures/}
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}
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\begin{document}
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\chapter{Random Phasor Sum Distribution}
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\label{sec:phasor_distributions}
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%\section{Random Phasor Distribution}
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This section gives a short derivation of \eqref{eq:random_phasor_sum:phase:sine} using two frequency-domain phasors.
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Further reading can be found in Ref.~\cite[Chapter 2.9]{goodman1985:2.9} under ``Constant Phasor plus Random Phasor Sum''.
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\\
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Write the noise phasor as $\vec{m} = a \, e^{i\pTrue}$ with phase $-\pi < \pTrue \leq \pi$ and amplitude $a \geq 0$,
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and the signal phasor as $\vec{s} = s \, e^{i\pTrue_s}$, but rotated such that its phase $\pTrue_s = 0$.
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\\
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% Noise phasor description
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The noise phasor is fully described by the joint probability density function
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\begin{equation}
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\label{eq:noise:pdf:joint}
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\phantom{,}
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p_{A\PTrue}(a, \pTrue; \sigma)
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=
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\frac{a}{2\pi\sigma^2} e^{-\frac{a^2}{2\sigma^2}}
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,
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\end{equation}
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for $-\pi < \pTrue \leq \pi$ and $a \geq 0$.
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\\
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Integrating \eqref{eq:noise:pdf:joint} over the amplitude $a$, it follows that the phase is uniformly distributed.
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\\
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Likewise, the amplitude follows a Rayleigh distribution
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\begin{equation}
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\label{eq:noise:pdf:amplitude}
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%\label{eq:pdf:rayleigh}
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\phantom{,}
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p_A(a; \sigma)
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%= p^{\mathrm{RICE}}_A(a; \nu = 0, \sigma)
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= \frac{a}{\sigma^2} e^{-\frac{a^2}{2\sigma^2}}
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,
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\end{equation}
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for which the mean is $\bar{a} = \sigma \sqrt{\frac{\pi}{2}}$ and the standard~deviation is given by $\sigma_{a} = \sigma \sqrt{ 2 - \tfrac{\pi}{2} }$.
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\\
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% Random phasor sum
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Adding the signal phasor, the mean in \eqref{eq:noise:pdf:joint} shifts
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from $\vec{a}^2 = a^2 {\left( \cos \pTrue + \sin \pTrue \right)}^2$
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to ${\left(\vec{a} - \vec{s}\right)}^2 = {\left( a \cos \pTrue -s \right)}^2 + {\left(\sin \pTrue \right)}^2$,
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resulting in a new joint distribution
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\begin{equation}
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\label{eq:phasor_sum:pdf:joint}
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\phantom{.}
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p_{A\PTrue}(a, \pTrue; s, \sigma)
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= \frac{a}{2\pi\sigma^2}
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\exp[ -
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\frac{
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{\left( a \cos \pTrue - s \right)}^2
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+ {\left( a \sin \pTrue \right)}^2
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}{
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2 \sigma^2
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}
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]
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.
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\end{equation}
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\\
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Integrating \eqref{eq:phasor_sum:pdf:joint} over $\pTrue$ one finds
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a Rice (or Rician) distribution for the amplitude,
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\begin{equation}
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\label{eq:phasor_sum:pdf:amplitude}
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%\label{eq:pdf:rice}
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\phantom{,}
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p_A(a; s, \sigma)
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= \frac{a}{\sigma^2}
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\exp[-\frac{a^2 + s^2}{2\sigma^2}]
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\;
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I_0\left( \frac{a s}{\sigma^2} \right)
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,
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\end{equation}
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where $I_0(z)$ is the modified Bessel function of the first kind with order zero.
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\\
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\begin{figure}
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\centering
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\includegraphics[width=0.5\textwidth]{beacon/phasor_sum/pdfs-amplitudes.pdf}
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\caption{
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A signal phasor's amplitude in the presence of noise will follow a Rician distribution~\eqref{eq:phasor_sum:pdf:amplitude}.
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For strong signals, this approximates a gaussian distribution, while for weak signals, this approaches a Rayleigh distribution.
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}
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\label{fig:phasor_sum:pdf:amplitude}
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\end{figure}
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For the Rician distribution, two extreme cases can be highlighted (as can be seen in Figure~\ref{fig:phasor_sum:pdf:amplitude}).
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In the case of a weak signal ($s \ll a$), \eqref{eq:phasor_sum:pdf:amplitude} behaves as a Rayleigh distribution~\eqref{eq:noise:pdf:amplitude}.
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Meanwhile, it approaches a gaussian distribution around $s$ when a strong signal ($s \gg a$) is presented.
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\begin{equation}
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\label{eq:strong_phasor_sum:pdf:amplitude}
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p_A(a; \sigma) = \frac{1}{\sqrt{2\pi}} \exp[-\frac{{\left(a - s\right)}^2}{2\sigma^2}]
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\end{equation}\\
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Like the amplitude distribution \eqref{eq:phasor_sum:pdf:amplitude}, the marginal phase distribution of \eqref{eq:phasor_sum:pdf:joint} results in two extreme cases;
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weak signals correspond to the uniform distribution for \eqref{eq:noise:pdf:joint}, while strong signals are well approximated by a gaussian distribution (see Figure~\ref{fig:random_phasor_sum:pdf:phase}).
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\\
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The analytic form takes the following complex expression,
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\begin{equation}
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\label{eq:phase_pdf:random_phasor_sum}
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p_\PTrue(\pTrue; s, \sigma) =
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\frac{ e^{-\left(\frac{s^2}{2\sigma^2}\right)} }{ 2 \pi }
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+
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\sqrt{\frac{1}{2\pi}}
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\frac{s}{\sigma}
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e^{-\left( \frac{s^2}{2\sigma^2}\sin^2{\pTrue} \right)}
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\frac{\left(
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1 + \erf{ \frac{s \cos{\pTrue}}{\sqrt{2} \sigma }}
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\right)}{2}
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\cos{\pTrue}
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\end{equation}
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where
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\begin{equation}
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\label{eq:erf}
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\phantom{,}
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\erf{\left(z\right)} = \frac{2}{\sqrt{\pi}} \int_0^z \dif{t} e^{-t^2}
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,
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\end{equation}
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is the error function.
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\begin{figure}
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\centering
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\includegraphics[width=0.5\textwidth]{beacon/phasor_sum/pdfs-phases.pdf}
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\caption{
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The Random Phasor Sum phase distribution \eqref{eq:phase_pdf:random_phasor_sum}.
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For strong signals, this approximates a gaussian distribution, while for weak signals, this approaches a uniform distribution.
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}
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\label{fig:random_phasor_sum:pdf:phase}
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\end{figure}
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\end{document}
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