A Simple and Empirical Refraction Correction Method for UAV-Based Shallow-Water Photogrammetry
Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33122
A Simple and Empirical Refraction Correction Method for UAV-Based Shallow-Water Photogrammetry

Authors: I GD Yudha Partama, A. Kanno, Y. Akamatsu, R. Inui, M. Goto, M. Sekine

Abstract:

The aerial photogrammetry of shallow water bottoms has the potential to be an efficient high-resolution survey technique for shallow water topography, thanks to the advent of convenient UAV and automatic image processing techniques Structure-from-Motion (SfM) and Multi-View Stereo (MVS)). However, it suffers from the systematic overestimation of the bottom elevation, due to the light refraction at the air-water interface. In this study, we present an empirical method to correct for the effect of refraction after the usual SfM-MVS processing, using common software. The presented method utilizes the empirical relation between the measured true depth and the estimated apparent depth to generate an empirical correction factor. Furthermore, this correction factor was utilized to convert the apparent water depth into a refraction-corrected (real-scale) water depth. To examine its effectiveness, we applied the method to two river sites, and compared the RMS errors in the corrected bottom elevations with those obtained by three existing methods. The result shows that the presented method is more effective than the two existing methods: The method without applying correction factor and the method utilizes the refractive index of water (1.34) as correction factor. In comparison with the remaining existing method, which used the additive terms (offset) after calculating correction factor, the presented method performs well in Site 2 and worse in Site 1. However, we found this linear regression method to be unstable when the training data used for calibration are limited. It also suffers from a large negative bias in the correction factor when the apparent water depth estimated is affected by noise, according to our numerical experiment. Overall, the good accuracy of refraction correction method depends on various factors such as the locations, image acquisition, and GPS measurement conditions. The most effective method can be selected by using statistical selection (e.g. leave-one-out cross validation).

Keywords: Bottom elevation, multi-view stereo, river, structure-from-motion.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1129718

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1583

References:


[1] R.V. Monica, B.G. Rocio, K. Thomas, and V. Amanda, “Automated Identification of River Hydromorphological Features Using UAV High Resolution Aerial Imagery,” Sensors, vol.15, pp. 27969-27989, Nov. 2015.
[2] N. Nagata, T. Hosoda, and Y. Muramoto, “Numerical analysis of river channel processes with bank erosion,” Journal of Hydraulic Engineering, vol.126, no.4, pp.243-252, Apr. 2000.
[3] K. Ulrich, B. Rainer, and H. Konrad, “Assessment of river habitat in Brandenburg, Germany,” Limnologica, vol.34, pp.176-186, Jun. 2004.
[4] C.J. Legleiter, and P.C. Kyriakidis, “Spatial prediction of river channel topography by kriging,” Earth Surf. Processes Landform, vol.33, no.6, pp. 841-867, 2008.
[5] A.S. Woodget, P.E. Carbonneau, F. Visser, and I.P. Maddock, “Quantifying submerged fluvial topography using hyperspatial resolution UAS imagery and structure from motion photogrammetry,” Earth Surface Processes and Landforms, vol.40, pp.47-64, Aug. 2015.
[6] J.B. Butler, S.N. Lane, and J.H. Chandler, “Through-water close range digital photogrammetry in flume and field environments,” Photogrammetric Record, vol.17, no.99, pp. 419-439, Apr. 2002.
[7] J.G. Fryer, and H.T. Kniest, “Error in depth determination caused by waves in through-water photogrammetry,” Photogrammetric Record, vol.11, no.66, pp.745-753, Oct. 1985.
[8] R.M Westway, S.N. Lane, and D.M. Hicks, “The development of an automated correction procedure for digital photogrammetry for the study of wide, shallow, gravel-bed rivers,” Earth Surface Processes and Landforms, vol. 25, pp. 209-226, Nov. 1999.
[9] T. Murase, M. Tanaka, T. Tani, Y. Miyashita, N. Ohkawa, S. Ishiguro, Y. Suzuki, H. Kayanne, and H. Yamano, “A photogrammetric correction procedure for light refraction effects at a two-medium boundary,” Photogrammetric Engineering & Remote Sensing, vol.74, no. 9, pp. 1129-1136, Sep. 2008.
[10] O. Bagheri, M. Ghodsian, and M. Saadatseresht, “Reach scale application of UAV+SfM method in shallow rivers hyperspatial bathymetry,” International Conference on Sensors & Models in Remote, vol.40, 23-25 Nov. 2015.