Robust Indoor Location Identification for Smartphones Using Echoes From Dominant Reflectors

The indoor location awareness has drawn increasing attention as the mobile apps are used extensively in our daily lives. Existing indoor localization solutions either require a pre-installed infrastructure or can only achieve room-level accuracy, which could not provide a function-location service for mobile devices. In this work, we propose a new active sensing system that enables smartphones to identify some pre-defined indoor locations robustly without requiring any additional sensors or pre-installed infrastructure. The main idea behind our system is to utilize the acoustic signatures, which are derived from the mobile device by emitting a beep signal and selecting its echoes created by dominant reflectors, as the robust fingerprint for location identification. Given the microphone samplings, our system designs a correlation based technique to accurately detect the beginning points of echoes from the received beep signal. To achieve a robust location identification, we develop a new echo selection scheme to select echoes created by dominant reflectors by exploiting the relationships between propagation delays of different orders of echoes. To deal with the variable number of selected echoes, our location identification component then derives histograms from selected echoes and uses the one-against-all SVM classifiers to determine the current location. Our experimental results show that our proposed system is accurate and robust for location identification under various real-world scenarios.