Abstract
This study investigates the potential of Android-based smartwatch real-time kinematic (RTK) positioning using single-frequency, multi Global Navigation Satellite Systems (GNSSs) observations, including the L1 GPS, E1 Galileo, B1 BDS and L1 QZSS signals. We evaluate the instantaneous (single-epoch), single-frequency, single-baseline RTK performance under three conditions: (1) zero-baseline with external antenna, (2) short-baseline with external antennas, and (3) short-baseline with internal antennas, all under a stationary setup configuration. The benefit of using the instantaneous RTK model is that it is insensitive to cycle slips. We analyze the smartwatch-to-smartwatch single baseline RTK performance in Dunedin, New Zealand using 4 h of data with a one second measurement interval. No geodetic station is involved in this study, as one of the smartwatches serves as the base station. The tested smartwatches include the Google Pixel Watch 1 (GW1) and the Samsung Galaxy Watch 6 (SW6) that can only collect single-frequency data, and we compare the RTK performance to that of Google Pixel 5 (GP5) smartphones. While using external Trimble Zephyr 2 antennas for the GW1 and SW6 smartwatches, we achieved centimeter-level positioning precisions, with instantaneous integer least squares (ILS) success rates (SR) exceeding 99% for both the zero- and short-baseline data. We found that the RTK performance of both smartwatches is competitive with that of the GP5 smartphones. We also demonstrate that using the internal antennas of the smartwatches results in higher sensitivity to potential multipath effects and poorer GNSS signal quality, thereby reducing the RTK positioning performance. Most importantly, we have shown, for the first time, that one of the smartwatch models can achieve cm-level RTK positioning with a remarkable instantaneous ILS SR exceeding 99% over 4 h of data using the internal smartwatch antennas.