Your search keyword '"Andrew Senogles"' showing total 3 results

1. SlideSim: 3D Landslide Displacement Monitoring through a Physics-Based Simulation Approach to Self-Supervised Learning

Author

Andrew Senogles, Michael J. Olsen, and Ben Leshchinsky

Subjects

landslide, monitoring, deep learning, lidar, UAS, optical flow, Science

Abstract

Displacement monitoring is a critical step to understand, manage, and mitigate potential landside hazard and risk. Remote sensing technology is increasingly used in landslide monitoring. While significant advances in data collection and processing have occurred, much of the analysis of remotely-sensed data applied to landslides is still relatively simplistic, particularly for landslides that are slow moving and have not yet “failed”. To this end, this work presents a novel approach, SlideSim, which trains an optical flow predictor for the purpose of mapping 3D landslide displacement using sequential DEM rasters. SlideSim is capable of automated, self-supervised learning by building a synthetic dataset of displacement landslide DEM rasters and accompanying label data in the form of u/v pixel offset flow grids. The effectiveness, applicability, and reliability of SlideSim for landslide displacement monitoring is demonstrated with real-world data collected at a landslide on the Southern Oregon Coast, U.S.A. Results are compared with a detailed ground truth dataset with an End Point Error RMSE = 0.026 m. The sensitivity of SlideSim to the input DEM cell size, representation (hillshade, slope map, etc.), and data sources (e.g., TLS vs. UAS SfM) are rigorously evaluated. SlideSim is also compared to diverse methodologies from the literature to highlight the gap that SlideSim fills amongst current state-of-the-art approaches.

Published

2022

2. LADI: Landslide displacement interpolation through a spatial-temporal Kalman filter.

Author

Andrew Senogles, Michael J. Olsen, and Ben A. Leshchinsky

Published

2023

3. The Hooskanaden Landslide: historic and recent surge behavior of an active earthflow on the Oregon Coast

Author

Adam M. Booth, Curran Mohney, Andrew Senogles, S. Alberti, Ben Leshchinsky, Pete Castro, Jill DeKoekkoek, Kara Kingen, Michael J. Olsen, and Kira Glover-Cutter

Subjects

021110 strategic, defence & security studies, Earthflow, Baseline (sea), 0211 other engineering and technologies, Landslide, 02 engineering and technology, Geotechnical Engineering and Engineering Geology, Pacific ocean, Natural hazard, Surge, Maximum displacement, Seismology, Geology, 021101 geological & geomatics engineering

Abstract

This paper presents an analysis of the Hooskanaden Landslide, an earthflow, which experienced a dramatic surge event beginning on February 24, 2019, closing US Highway 101 near mile point 343.5 for nearly 2 weeks. This ~ 1 km long surge event resulted in horizontal displacements of up to 45 m and uplift of 6 m at the toe located on a gravel beach adjacent to the Pacific Ocean. The Hooskanaden Landslide, likely active since the eighteenth century, exhibits regular activity with a recurrence interval of major surge events of approximately every 20 years, transitioning from slow to relatively rapid velocities. During the 2019 event, maximum displacement rates of approximately 60 cm/h were observed, slowly decreasing to 15 cm/h for a sustained period of approximately 2 weeks before the eventual return to baseline conditions (

Published

2020