intro component description
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Toni
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\section{Component Description}
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\section{Component Description}
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Our indoor localisation solely uses the sensors provided by almost each commodity smartphone.
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As described above, our indoor localisation solely uses the sensors provided by almost each commodity smartphone.
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By assuming statistical independence of all sensors, the probability density of the state evaluation of eq. \eqref{eq:recursiveDensity} is given by
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\begin{equation}
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%\begin{split}
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p(\vec{o}_t \mid \vec{q}_t) =
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p(\vec{o}_t \mid \vec{q}_t)_\text{baro}
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\,p(\vec{o}_t \mid \vec{q}_t)_\text{ib}
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\,p(\vec{o}_t \mid \vec{q}_t)_\text{wifi}
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\enspace.
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%\end{split}
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\label{eq:evalBayes}
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\end{equation}
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Here, every single component refers to a probabilistic sensor model.
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The barometer information is evaluated using $p(\vec{o}_t \mid \vec{q}_t)_\text{baro}$,
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whereby absolute position information is given by $p(\vec{o}_t \mid \vec{q}_t)_\text{ib}$ for
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\docIBeacon{}s and by $p(\vec{o}_t \mid \vec{q}_t)_\text{wifi}$ for \docWIFI{}.
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Compared to other state-of-the-art system, the step- and turn-detection is not incorporated into the evaluation step.
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In our approach it stabilizes and improves the sampling of states $\vec{q}$ into moving more realistically. The transition step is the carried out using random walks on a graph, which is built offline, and uses the building's floorplan \cite{ebner-16}.
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\input{chapters/barometer.tex}
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\input{chapters/barometer.tex}
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@@ -32,8 +32,7 @@ where $\mObsVec_{1:t} = \mObsVec_{1}, \mObsVec_{1}, ..., \mObsVec_{t}$ is a seri
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where $x, y, z$ represent the position in 3D space, $\mStateHeading$ the user's heading and $\mStatePressure$ the relative atmospheric pressure prediction in hectopascal (hPa).
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where $x, y, z$ represent the position in 3D space, $\mStateHeading$ the user's heading and $\mStatePressure$ the relative atmospheric pressure prediction in hectopascal (hPa).
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The recursive part of the density estimation contains all information up to time $t-1$.
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The recursive part of the density estimation contains all information up to time $t-1$.
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Furthermore, the state transition $p(\mStateVec_{t} \mid \mStateVec_{t-1}, \mObsVec_{t-1})$ models the pedestrian's movement and is carried out using random walks on a graph, which is built offline, and uses the building's floorplan \cite{ebner-16}.
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Furthermore, the state transition $p(\mStateVec_{t} \mid \mStateVec_{t-1}, \mObsVec_{t-1})$ models the pedestrian's movement, whereby the evaluation provides a likelihood for every sensor.
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Containing all relevant sensor measurements to evaluate the current state, the observation vector is defined as follows:
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Containing all relevant sensor measurements to evaluate the current state, the observation vector is defined as follows:
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\begin{equation}
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\begin{equation}
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