Abstract
In this work, the use of Machine Learning methods for robust Received Signal Strength (RSS)-based Visible Light Positioning (VLP) is experimentally evaluated. The performance of Multilayer Perceptron (MLP) models and Gaussian processes (GP) is investigated when using relative RSS input features. The experimental set-up for the RSS-based VLP technology uses light-emitting diodes (LEDs) transmitting intensity modulated light and a single photodiode (PD) as a receiver. The experiments focus on achieving robustness to cope with unknown received signal strength modifications over time. Therefore, several datasets were collected, where per dataset either the LEDs transmitting power is modified or the PD aperture is partly obfuscated by dust particles. Two relative RSS schemes are investigated. The first scheme uses the maximum received light intensity to normalize the received RSS vector, while the second approach obtains RSS ratios by combining all possible unique pairs of received intensities. The Machine Learning (ML) methods are compared to a relative multilateration implementation. It is demonstrated that the adopted MLP and GP models exhibit superior performance and higher robustness when compared to the multilateration strategies. Furthermore, when comparing the investigated ML models, the GP model is proven to be more robust than the MLP for the considered scenarios.
Highlights
Determining the location of oneself or mobile objects as accurately as possible has already been a problem of interest for ages
When the absolute Received Signal Strength (RSS) values are used as input features in the Multilayer Perceptron (MLP) and Gaussian processes (GP) models, the MLP results in a p50 localization error of 1.99 cm and a p95 localization error of 7.17 cm while the GP results in a p50 error of 1.92 cm and a p95 error of 6.41 cm
The MLP results in a p50 localization error of 2.36 cm and a p95 error of 7.41 cm, while the GP
Summary
Determining the location of oneself or mobile objects as accurately as possible has already been a problem of interest for ages. LEDs can be switched at a rate much higher than the bandwidth of the human observer allowing to perform wireless communication without compromising the illumination functionality [12] One such promising technology for indoor localization is Visible Light Positioning (VLP) [13]. The most prominent strategies to obtain a distance estimate in the context of VLP are based on the Received Signal Strength (RSS) or the Time Difference Of Arrival (TDOA). The localization accuracy of an indoor positioning system is not the sole important parameter that determines its practical applicability in industrial or other commercial use cases Another important characteristic is its robustness or reliability. ML methods featuring GPs and ANNs which use relative intensities are adopted to obtain a more robust RSS based 2D VLP solution.
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