intro component description

competition/tex/chapters/components.tex

@@ -1,6 +1,26 @@
 \section{Component Description}
 	
-	Our indoor localisation solely uses the sensors provided by almost each commodity smartphone.
+	As described above, our indoor localisation solely uses the sensors provided by almost each commodity smartphone. 
+By assuming statistical independence of all sensors, the probability density of the state evaluation of eq. \eqref{eq:recursiveDensity} is given by 
+	%
+	\begin{equation}
+		%\begin{split}
+			p(\vec{o}_t \mid \vec{q}_t) = 
+			p(\vec{o}_t \mid \vec{q}_t)_\text{baro} 
+			\,p(\vec{o}_t \mid \vec{q}_t)_\text{ib}
+			\,p(\vec{o}_t \mid \vec{q}_t)_\text{wifi}
+			\enspace.
+		%\end{split}
+		\label{eq:evalBayes}
+	\end{equation}
+	%
+	Here, every single component refers to a probabilistic sensor model. 
+	The barometer information is evaluated using $p(\vec{o}_t \mid \vec{q}_t)_\text{baro}$,
+	whereby absolute position information is given by $p(\vec{o}_t \mid \vec{q}_t)_\text{ib}$ for
+	\docIBeacon{}s and by $p(\vec{o}_t \mid \vec{q}_t)_\text{wifi}$ for \docWIFI{}. 
+	
+  Compared to other state-of-the-art system, the step- and turn-detection is not incorporated into the evaluation step. 
+  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}. 
 
 	
 	\input{chapters/barometer.tex}