Glaciares de Chile
- Glaciares del Volcán Melimoyu
- Glaciares del Nevado de Queulat
- Glaciares del Volcán Mentolat
- Glaciares del Volcán Cay
- Glaciares del Volcán Macá
- Glaciares del Volcán Hudson
- Glaciar Erasmo
- Glaciar San Rafael
- Glaciar San Quintín
- Campo de Hielo Norte
- Glaciar Nef
- Glaciar Colonia
- Lago Cachet II
- Glaciar Steffen
- Glaciares del Monte San Lorenzo
- Glaciar Jorge Montt
- Glaciar Lucía
- Glaciar Los Moscos
- Glaciar Bernardo
- Glaciar O’Higgins
- Glaciar Chico
- Campo de Hielo Sur
- Campo de Hielo Sur
- Glaciar Témpanos
- Glaciar Pío XI
- Glaciar Viedma
- Glaciar Perito Moreno
- Glaciar Dickson
- Glaciar Olvidado
- Glaciar Grey
- Glaciar Amalia
- Glaciar Pingo
- Glaciar Tyndall
- Glaciar Balmaceda
- Isla Desolación
- Glaciares de la Isla Santa Inés
- Seno Gabriel
- Glaciar Schiaparelli
- Glaciar Marinelli
- Fiordo Parry
- Cordillera Darwin
- Glaciar Garibaldi
- Glaciar Roncagli
- Glaciares Isla Hoste
Antártica
"Detecting Glacier Surface Motion by Optical Flow"
Lenzano M.G.; Lannutti E.; Toth C.; Rivera A. and Lenzano L. (2018) : “Detecting Glacier Surface Motion by Optical Flow” Photogrammetric Engineering & Remote Sensing, 84: 33-42, DOI: 10.14358/PERS.84.1.33.
Resumen / Abstract.
In this study, we assessed the feasibility of using optical flow, in particular, large displacement optical flow (LDOF) method as a possible solution to obtain surface movement data to derive ice flow velocities in a glacier. Tests were carried out at the Viedma Glacier, located at the South Patagonia Icefield, Argentina, where terrestrial monoscopic image sequences were acquired by a calibrated camera from April 2014 until April 2016. As for preprocessing, the Correlated Analysis method was implemented to avoid and minimize errors due to the measurable changes in lighting, shadows, clouds, and snow. The results show a flow field with a maximum surface velocity value of 3.5 m/d. The errors were minimized by averaging the image sequence results based on seasons, in which the Total Error Reconstruction yielded fairly good mean accuracy (0.36 m/d). In summary, it was demonstrated that LDOF can provide accurate and robust solution to detect daily changes in the glacier surface.