Abstract
This paper presents a WiFi-aided magnetic matching (MM) algorithm for indoor pedestrian navigation with consumer portable devices. This algorithm reduces both the mismatching rate (i.e., the rate of matching to an incorrect point that is more than 20 m away from the true value) and computational load of MM by using WiFi positioning solutions to limit the MM search space. Walking tests with Samsung Galaxy S3 and S4 smartphones in two different indoor environments (i.e., Environment #1 with abundant WiFi APs and significant magnetic features, and Environment #2 with less WiFi and magnetic information) were conducted to evaluate the proposed algorithm. It was found that WiFi fingerprinting accuracy is related to the signal distributions. MM provided results with small fluctuations but had a significant mismatch rate; when aided by WiFi, MM’s robustness was significantly improved. The outcome of this research indicates that WiFi and MM have complementary characteristics as the former is a point-by-point matching approach and the latter is based on profile-matching. Furthermore, performance improvement through integrating WiFi and MM depends on the environment (e.g., the signal distributions of magnetic intensity and WiFi RSS): In Environment #1 tests, WiFi-aided MM and WiFi provided similar results; in Environment #2 tests, the former was approximately 41.6% better. Our results supported that the WiFi-aided MM algorithm provided more reliable solutions than both WiFi and MM in the areas that have poor WiFi signal distribution or indistinctive magnetic-gradient features.
Highlights
While Global Navigation Satellite Systems (GNSS) based outdoor navigation has greatly advanced over the past few decades, positioning and navigation in indoor and deep urban areas are still open issues [1]
The training phase is conducted to build or update a “location, magnetic intensity” database (DB) that consists of a set of reference points (RPs) with known coordinates and the magnetic intensity on these RPs, while the positioning step is implemented to find the closest match between the features of the measured magnetic intensity and those stored in the DB
We found that magnetic matching (MM) results had small error fluctuations but had a significant mismatch rate
Summary
While Global Navigation Satellite Systems (GNSS) based outdoor navigation has greatly advanced over the past few decades, positioning and navigation in indoor and deep urban areas are still open issues [1]. The training phase is conducted to build or update a “location, magnetic intensity” database (DB) that consists of a set of reference points (RPs) with known coordinates and the magnetic intensity on these RPs, while the positioning step is implemented to find the closest match between the features of the measured magnetic intensity and. The paper is organized as follows: Section 2 outlines the architecture of the WiFi-aid magnetic matching algorithm and a detailed description of each component; Section 3 investigates the navigation performance of different technologies; and Section 4 draws the conclusions
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