minor tex changes
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@@ -6,7 +6,7 @@
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Evaluation took place within all floors (0 to 3) of the
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faculty building, each of which about \SI{77}{\meter} x \SI{55}{\meter} in size.
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We conducted 4 distinct walks, to test short distances, long distances, critical sections
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We conducted 4 distinct walks, to test short and long distances, critical sections
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and ignoring the shortest-path suggested by the system.
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Due to an in-house exhibition during that time, many places were crowded and \docWIFI{} signals
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are attenuated.
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@@ -15,15 +15,19 @@
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While walking, the pedestrian clicked a button on the smartphone application
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when passing a marker. Between two consecutive points, a constant movement speed is assumed.
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Thus, the ground truth might not be \SI{100}{\percent} accurate, but fair enough for error measurements.
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All walks were performed using a Motorola Nexus 6 and a Samsung Galaxy S5.
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As the Samsung Galaxy S5's \docWIFI{} can not be limited to the \SI{2.4}{\giga\hertz} band only,
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its scans take much longer than those of the Motorola Nexus 6:
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All walks were performed using a Motorola Nexus 6 and a Samsung Galaxy S5.
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As the Galaxy's \docWIFI{} can not be limited to the \SI{2.4}{\giga\hertz} band only,
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its scans take much longer than those of the Nexus:
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\SI{3500}{\milli\second} vs. \SI{600}{\milli\second}.
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Also, the Nexus' barometer sensor provides readings both more frequent and far more accurate than
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the Galaxy does. This results in a better localisation using the Nexus smartphone.
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Despite being fast enough to run in realtime on the smartphone itself, computation was done offline using
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the \mbox{CONDENSATION} particle filter with \SI{7500}{} particles as realization.
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Despite being fast enough to run on the smartphone itself
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($ \approx \SI{100}{\milli\second} $ per transition, single-core Intel\textsuperscript{\textregistered} Atom{\texttrademark} C2750),
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computation was done offline using
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the \mbox{CONDENSATION} algorithm with \SI{7500}{} particles as realization.
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The weighted arithmetic mean of the particles was used as state estimation.
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As mentioned earlier, the position of all \docAP{}s (about 5 per floor) is known beforehand.
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@@ -104,15 +108,15 @@ All walks were performed using a Motorola Nexus 6 and a Samsung Galaxy S5.
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segment \refSeg{1} of fig. \ref{fig:errorTimedNexus}.
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Starting instead with both, known position and heading, reduced the error by about \SI{15}{\percent} when using prior knowledge and
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by \SI{25}{\percent} when omitting prior knowledge. As prior knowledge directs the density towards a known target,
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it is able to compensate unknown initial headings which explains the \SI{10}{\percent} difference.
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by \SI{25}{\percent} when omitting prior knowledge. As prior knowledge directs the density towards the known target,
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it is able to compensate initially unknown headings which explains the \SI{10}{\percent} difference.
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%
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However, as soon as the pedestrian starts moving down the hallway \refSeg{2} the error is reduced dramatically.
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As soon as the pedestrian starts moving down the hallway \refSeg{2} the error is reduced dramatically.
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Adding prior knowledge centres the density in the middle of the floor, ensures that the heading is directed towards
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the shortest path and thus produces even better localisation results.
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Directly hereafter, we ignore the shortest path \refSeg{3'} determined by the system and walk along \refSeg{3}
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instead. Of course, this leads to a temporally increasing error, as the system needs to detect this path change
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instead. Of course, this leads to a temporarily increasing error, as the system needs to detect this path change
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and takes some time to recover (see fig. \ref{fig:errorTimedNexus} \refSeg{3}). The new path to the desired destination
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is \refSeg{3''} which is also ignored. Instead, we took a much longer route down the stairwell \refSeg{4}.
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After this change is detected by the system, prior knowledge is again able to reduce the error for segment \refSeg{5}.
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@@ -130,9 +134,9 @@ as seen in fig. \ref{fig:nexusPathDetails} \refSeg{6}.
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errors in segment \refSeg{7}.
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It follows a critical area with high errors and multimodalities.
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Due to an in-house exhibition during the time of recording, we had to leave the ground truth by a few meters.
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Furthermore, the overcrowded areas lead to attenuated \docWIFI{} signals. Both reasons move the
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Furthermore, the overcrowded areas lead to attenuated \docWIFI{} signals. This moves the
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density into another stairwell (see fig. \ref{fig:nexusPathDetails}, red lines in the lower right).
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The resulting multimodality (two staircases possible) leads to a rising error
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The resulting multimodality (two staircases possible) leads to a rising error in
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\refSeg{8}, \refSeg{9}. At the end of the walk \refSeg{10} the system is able to recover, again.
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