Effects of Differential Single-and Dual-Frequency GPS and GLONASS Observations on Point Accuracy under Forest Canopies

A 20-channel, dual-frequency receiver observing dual-fiequency pseudorange and carrier phase of both GPS and GLONASS was used to determine the positional accuracy of 29 points under tree canopies. The mean positional accuracy based on differential postprocessing of GPS+GLONASS singlefrequency observations ranged from 0.16 m to 1 .I 6 m for 2.5 min to 20 min of observation at points with basal area ranging from <20 m2/ha to 230 m2/ha. The mean positional accuracy of differential postprocessing of dual-frequency GPS+GLONASS observations ranged from 0.08 m to 1.35 m. Using the dualfrequency carrier phase as main observable and fixing the initial integer phase ambiguities, i.e., a fixed solution, gave the best accuracy. However, searching for fixed solutions increased the risk of large individual positional errors due to "false" fixed solutions. The accuracy increased with decreasing density of forest, increasing length of observation period, and decreasing a priori standard error as reported by the postprocessing software.