Abstract
Wireless systems already provide time delay and signal strength measurements and the future may see antenna arrays that provide directional information. All these may be used for positioning. Although the statistical accuracy of different positioning methods is well studied, the systematic error effects, which arise, for example, from errors in sensor (node) location, network synchronization, or the path loss model, are not. This study fills this gap providing a unified error-propagation-law-based tool to analyze measurement and systematic error effects. The considered positioning systems, which are compared based on the developed framework, are the hyperbolic (time-delay-based), direction finding (DF), received signal strength (RSS), and relative RSS (RRSS) location systems. The obtained analytical results verify our intuitive expectations; the hyperbolic methods are sensitive to errors in network synchronization, RRRS methods to channel modelling errors, whereas DF methods are rather insensitive to systematic errors. However, the bias of DF methods is at its largest if the sensor location error is perpendicular to the line joining the sensor and the source. If the methods are compared based on overall accuracy, hyperbolic methods may be preferred in large sized networks, whereas the DF and RRSS methods may provide better accuracy in small sized networks. However, RRSS systems require a dense network in order to provide reliable results.
Highlights
Not just are location-based services becoming more popular in wireless systems but location is needed in wireless sensing applications [1, 2]
We present some numerical examples related to time difference (TD), direction finding (DF), and relative RSS (RRSS) location systems with 2D positioning
The effects of systematic errors on the location accuracy have been studied in this paper
Summary
Not just are location-based services becoming more popular in wireless systems but location is needed in wireless sensing applications [1, 2]. A fundamental question in location is what is the attainable location accuracy and what is required to obtain it; whether some methods can offer sufficient accuracy with lower complexity and, possibly, with simpler installation than other ones. Positioning accuracy is affected by the measurement accuracy and systematic errors. A systematic error may be defined as an error that is not determined by chance but is introduced by an inaccuracy (as of observation or measurement) inherent in the system (MerriamWebster On-Line http://www.m-w.com/). Systematic errors, in contrast to random ones, are reproducible inaccuracies that are consistently in the same direction. In this work systematic errors include errors in wireless node positions, network synchronization, the propagation path loss model, and so forth
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