Snow Depth Retrieval with UAS Using Photogrammetric Techniques

Alpine areas pose challenges for many existing remote sensing methods for snow depth retrieval, thus leading to uncertainty in water forecasting and budgeting. Herein, we present the results of a field campaign conducted in Tasmania, Australia in 2013 from which estimates of snow depth were derived using a low-cost photogrammetric approach on-board a micro unmanned aircraft system (UAS). Using commercial off-the-shelf (COTS) sensors mounted on a multi-rotor UAS and photogrammetric image processing techniques, the results demonstrate that snow depth can be accurately retrieved by differencing two surface models corresponding to the snow-free and snow-covered scenes, respectively. In addition to accurate snow depth retrieval, we show that high-resolution (50 cm) spatially continuous snow depth maps can be created using this methodology. Two types of photogrammetric bundle adjustment (BA) routines are implemented in this study to determine the optimal estimates of sensor position and orientation, in addition to 3D scene information; conventional BA (which relies on measured ground control points) and direct BA (which does not require ground control points). Error sources that affect the accuracy of the BA and subsequent snow depth reconstruction are discussed. The results indicate the UAS is capable of providing high-resolution and high-accuracy (<10 cm) estimates of snow depth over a small alpine area (~0.7 ha) with significant snow accumulation (depths greater than one meter) at a fraction of the cost of full-size aerial survey approaches. The RMSE of estimated snow depths using the conventional BA approach is 9.6 cm, whereas the direct BA is characterized by larger error, with an RMSE of 18.4 cm. If a simple affine transformation is applied to the point cloud derived from the direct BA, the overall RMSE is reduced to 8.8 cm RMSE.

[1]  Duane C. Brown,et al.  Close-Range Camera Calibration , 1971 .

[2]  E. L. Peck Snow measurement predicament , 1972 .

[3]  B. Efron,et al.  A Leisurely Look at the Bootstrap, the Jackknife, and , 1983 .

[4]  Albert Rango,et al.  An Overview of Passive Microwave Snow Research and Results (Paper 4R0095) , 1984 .

[5]  Dorothy K. Hall,et al.  Nimbus-7 SMMR derived global snow cover parameters , 1987 .

[6]  Dorothy K. Hall,et al.  Passive microwave remote and in situ measurements of artic and subarctic snow covers in Alaska , 1991 .

[7]  R. Bindschadler,et al.  Application of image cross-correlation to the measurement of glacier velocity using satellite image data , 1992 .

[8]  Thomas S. Huang,et al.  Motion and structure from feature correspondences: a review , 1994, Proc. IEEE.

[9]  H. Ebadi,et al.  A comprehensive study on gps-assisted aerial triangulation , 1997 .

[10]  Dorothy K. Hall,et al.  Comparison of snow mass estimates from a prototype passive microwave snow algorithm, a revised algorithm and a snow depth climatology , 1997 .

[11]  George P. Gerdan,et al.  The Influence of the Number of Satellites on the Accuracy of RTK GPS Positions , 1999 .

[12]  Andrew W. Fitzgibbon,et al.  Bundle Adjustment - A Modern Synthesis , 1999, Workshop on Vision Algorithms.

[13]  David G. Lowe,et al.  Object recognition from local scale-invariant features , 1999, Proceedings of the Seventh IEEE International Conference on Computer Vision.

[14]  N. Haala,et al.  DIRECT GEOREFERENCING USING GPS/INERTIAL EXTERIOR ORIENTATIONS FOR PHOTOGRAMMETRIC APPLICATIONS , 2000 .

[15]  K. P. Schwarz,et al.  Digital image georeferencing from a multiple camera system by GPS/INS , 2001 .

[16]  B. Lundén,et al.  Digital photogrammetry for air-photo-based construction of a digital elevation model over snow-covered areas ‐ Blamannsisen, Norway , 2001 .

[17]  Kelly Elder,et al.  Comparison of spatial interpolation methods for estimating snow distribution in the Colorado Rocky Mountains , 2002 .

[18]  Rudolph van der Merwe,et al.  Sigma-Point Kalman Filters for Integrated Navigation , 2004 .

[19]  T. Barnett,et al.  Potential impacts of a warming climate on water availability in snow-dominated regions , 2005, Nature.

[20]  David Nistér,et al.  Preemptive RANSAC for live structure and motion estimation , 2005, Machine Vision and Applications.

[21]  Richard Szeliski,et al.  A Comparison and Evaluation of Multi-View Stereo Reconstruction Algorithms , 2006, 2006 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (CVPR'06).

[22]  Li Zhang,et al.  Multi-image matching for DSM generation from IKONOS imagery , 2006 .

[23]  Li Zhang,et al.  Comparison of DSMs generated from mini UAV imagery and terrestrial laser scanner in a cultural heritage application , 2006 .

[24]  Steven M. Seitz,et al.  Photo tourism: exploring photo collections in 3D , 2006, ACM Trans. Graph..

[25]  Andrew Thomas Hudak,et al.  A Multiscale Curvature Algorithm for Classifying Discrete Return LiDAR in Forested Environments , 2007, IEEE Transactions on Geoscience and Remote Sensing.

[26]  S. D. Jones,et al.  DEM CREATION OF A SNOW COVERED SURFACE USING DIGITAL AERIAL PHOTOGRAPHY , 2008 .

[27]  B. Smith,et al.  Rates of southeast Greenland ice volume loss from combined ICESat and ASTER observations , 2008 .

[28]  I. Daho,et al.  Snow Cover Measurement , 2008 .

[29]  Edward J. Kim,et al.  Radiance assimilation shows promise for snowpack characterization , 2009 .

[30]  Jean Ponce,et al.  Accurate, Dense, and Robust Multiview Stereopsis , 2010, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[31]  Richard Szeliski,et al.  Bundle Adjustment in the Large , 2010, ECCV.

[32]  Chris Derksen,et al.  Estimating Snow Water Equivalent Using Snow Depth Data and Climate Classes , 2010 .

[33]  R. Monson,et al.  Longer growing seasons lead to less carbon sequestration by a subalpine forest , 2010 .

[34]  Yi Lin,et al.  A low-cost multi-sensoral mobile mapping system and its feasibility for tree measurements , 2010 .

[35]  Chris Derksen,et al.  Estimating northern hemisphere snow water equivalent for climate research through assimilation of space-borne radiometer data and ground-based measurements , 2011 .

[36]  Wang Tao,et al.  Dense point cloud extraction from UAV captured images in forest area , 2011, Proceedings 2011 IEEE International Conference on Spatial Data Mining and Geographical Knowledge Services.

[37]  Arko Lucieer,et al.  Assessing the Accuracy of Georeferenced Point Clouds Produced via Multi-View Stereopsis from Unmanned Aerial Vehicle (UAV) Imagery , 2012, Remote. Sens..

[38]  Arko Lucieer,et al.  Development of a UAV-LiDAR System with Application to Forest Inventory , 2012, Remote. Sens..

[39]  T. Painter,et al.  Lidar measurement of snow depth: a review , 2013, Journal of Glaciology.

[40]  Edward J. Kim,et al.  The effect of spatial variability on the sensitivity of passive microwave measurements to snow water equivalent , 2013 .

[41]  I. Colomina,et al.  Unmanned aerial systems for photogrammetry and remote sensing: A review , 2014 .

[42]  Arko Lucieer,et al.  Direct Georeferencing of Ultrahigh-Resolution UAV Imagery , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[43]  J. Ryan,et al.  Repeat UAV photogrammetry to assess calving front dynamics at a large outlet glacier draining the Greenland Ice Sheet , 2014 .

[44]  S. M. Jong,et al.  Mapping landslide displacements using Structure from Motion (SfM) and image correlation of multi-temporal UAV photography , 2014 .

[45]  M. Nolan,et al.  Mapping snow depth from manned aircraft on landscape scales at centimeter resolution using structure-from-motion photogrammetry , 2015 .

[46]  Andrea Faber,et al.  Introduction To Modern Photogrammetry , 2016 .