Abstract
Indoor positioning methods based on fingerprinting and radio signals rely on the quality of the radio map. For example, for room-level classification purposes, it is required that the signal observations related to each room exhibit significant differences in their RSSI values. However, it is difficult to verify and visualize that separability since radio maps are constituted by multi-dimensional observations whose dimension is directly related to the number of access points or monitors being employed for localization purposes. In this paper, we propose a refinement cycle for passive indoor positioning systems, which is based on dimensionality reduction techniques, to evaluate the quality of a radio map. By means of these techniques and our own data representation, we have defined two different visualization methods to obtain graphical information about the quality of a particular radio map in terms of overlapping areas and outliers. That information will be useful to determine whether new monitors are required or some existing ones should be moved. We have performed an exhaustive experimental analysis based on a variety of different scenarios, some deployed by our own research group and others corresponding to a well-known existing dataset widely analyzed by the community, in order to validate our proposal. As we will show, among the different combinations of data representation methods and dimensionality reduction techniques that we discuss, we have found that there are some specific configurations that are more useful in order to perform the refinement process.
Highlights
Indoor positioning services provide specific locations of mobile devices, and they are an important building block for ubiquitous computing services
As we showed in the previous subsection, the exponential growing of the input space can be a problem for PCA, the impact on LDA of this price to pay for using the training to perform passive localization is, perhaps surprisingly, somehow positive
We have shown that dimensionality reduction can be an exceptional tool to aid in the deployment cycle of indoor positioning systems based on radio fingerprinting
Summary
Indoor positioning services provide specific locations of mobile devices, and they are an important building block for ubiquitous computing services. Some active approaches assume that a specific software component is running on the mobile devices in order to collect the radio signals. Others perform passive localization, which makes use only of monitors collecting the radio signals generated by mobile devices in their usual operation. Our recent work [2] is more focused on the latter type of positioning systems, since they do not require the explicit collaboration of the users nor the installation of special purpose applications on their mobile devices. Users are reluctant to install apps that are battery consuming, and there are serious limitations to obtain RSSI (Received Signal Strength Indicator) information from some operating systems. The proliferation of smartphones and tablets is Sensors 2017, 17, 871; doi:10.3390/s17040871 www.mdpi.com/journal/sensors
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