Abstract
The IEEE 802.11mc WiFi standard provides a protocol for a cellphone to measure its distance from WiFi access points (APs). The position of the cellphone can then be estimated from the reported distances using known positions of the APs. There are several “multilateration” methods that work in relatively open environments. The problem is harder in a typical residence where signals pass through walls and floors. There, Bayesian cell update has shown particular promise. The Bayesian grid update method requires an “observation model” which gives the conditional probability of observing a reported distance given a known actual distance. The parameters of an observation model may be fitted using scattergrams of reported distances versus actual distance. We show here that the problem of fitting an observation model can be reduced from two dimensions to one. We further show that, perhaps surprisingly, a “double exponential” observation model fits real data well. Generating the test data involves knowing not only the positions of the APs but also that of the cellphone. Manual determination of positions can limit the scale of test data collection. We show here that “boot strapping,” using results of a Bayesian grid update method as a proxy for the actual position, can provide an accurate observation model, and a good observation model can nearly double the accuracy of indoor positioning. Finally, indoors, reported distance measurements are biased to be mostly longer than the actual distances. An attempt is made here to detect this bias and compensate for it.
Highlights
There has been considerable interest in developing the ability to accurately localize position indoors where GPS can not be used [1,2,3,4,5,6,7,8,9,10,11]
Bayesian cell update has proven to be a promising method for estimating indoor position using
We have shown that scattergrams of real data indicate that the observation model fitting problem can be reduced from two dimensions to one
Summary
There has been considerable interest in developing the ability to accurately localize position indoors where GPS can not be used [1,2,3,4,5,6,7,8,9,10,11]. What is reported is half of the round-trip time (RTT) of an RF signal, multiplied by the speed of light This would be the distance if the signal travelled in vacuum or air in a straight line (and ignoring noise). In some cases, the direct line of sight is blocked by metallic objects or thick layers of absorbing material In this case the round-trip-time estimate may be based on a signal that has reflected off some surface away from the direct path. We show here that a parameterized “double exponential” model fits real data well Results of using this observation model in Bayesian cell updates are shown in Figure 1 (screen shots from the video [29]). We explore the question of the observation model first in a “2-D” setting (single level of a large house), and in a “3-D” setting (three levels in another house)
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