Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain
The monitoring of snow-covered surfaces on Earth is largely facilitated by the wealth of satellite data available, with increasing spatial resolution and temporal coverage over the last few years. Yet to date, retrievals of snow physical properties still remain complicated in mountainous areas, owin...
| Published in: | The Cryosphere |
|---|---|
| Main Authors: | , , , , , , |
| Format: | Article in Journal/Newspaper |
| Language: | English |
| Published: |
Copernicus Publications
2020
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| Subjects: | |
| Online Access: | https://doi.org/10.5194/tc-14-3995-2020 https://doaj.org/article/a1a4cb1adb08457d95ad99391e843b73 |
| _version_ | 1821727764544225280 |
|---|---|
| author | M. Lamare M. Dumont G. Picard F. Larue F. Tuzet C. Delcourt L. Arnaud |
| author_facet | M. Lamare M. Dumont G. Picard F. Larue F. Tuzet C. Delcourt L. Arnaud |
| author_sort | M. Lamare |
| collection | Directory of Open Access Journals: DOAJ Articles |
| container_issue | 11 |
| container_start_page | 3995 |
| container_title | The Cryosphere |
| container_volume | 14 |
| description | The monitoring of snow-covered surfaces on Earth is largely facilitated by the wealth of satellite data available, with increasing spatial resolution and temporal coverage over the last few years. Yet to date, retrievals of snow physical properties still remain complicated in mountainous areas, owing to the complex interactions of solar radiation with terrain features such as multiple scattering between slopes, exacerbated over bright surfaces. Existing physically based models of solar radiation across rough scenes are either too complex and resource-demanding for the implementation of systematic satellite image processing, not designed for highly reflective surfaces such as snow, or tied to a specific satellite sensor. This study proposes a new formulation, combining a forward model of solar radiation over rugged terrain with dedicated snow optics into a flexible multi-sensor tool that bridges a gap in the optical remote sensing of snow-covered surfaces in mountainous regions. The model presented here allows one to perform rapid calculations over large snow-covered areas. Good results are obtained even for extreme cases, such as steep shadowed slopes or, on the contrary, strongly illuminated sun-facing slopes. Simulations of Sentinel-3 OLCI (Ocean and Land Colour Instrument) scenes performed over a mountainous region in the French Alps allow us to reduce the bias by up to a factor of 6 in the visible wavelengths compared to methods that account for slope inclination only. Furthermore, the study underlines the contribution of the individual fluxes to the total top-of-atmosphere radiance, highlighting the importance of reflected radiation from surrounding slopes which, in midwinter after a recent snowfall (13 February 2018), accounts on average for 7 % of the signal at 400 nm and 16 % at 1020 nm (on 13 February 2018), as well as of coupled diffuse radiation scattered by the neighbourhood, which contributes to 18 % at 400 nm and 4 % at 1020 nm . Given the importance of these contributions, accounting for slopes ... |
| format | Article in Journal/Newspaper |
| genre | The Cryosphere |
| genre_facet | The Cryosphere |
| geographic | Midwinter |
| geographic_facet | Midwinter |
| id | ftdoajarticles:oai:doaj.org/article:a1a4cb1adb08457d95ad99391e843b73 |
| institution | Open Polar |
| language | English |
| long_lat | ENVELOPE(139.931,139.931,-66.690,-66.690) |
| op_collection_id | ftdoajarticles |
| op_container_end_page | 4020 |
| op_doi | https://doi.org/10.5194/tc-14-3995-2020 |
| op_relation | https://tc.copernicus.org/articles/14/3995/2020/tc-14-3995-2020.pdf https://doaj.org/toc/1994-0416 https://doaj.org/toc/1994-0424 doi:10.5194/tc-14-3995-2020 1994-0416 1994-0424 https://doaj.org/article/a1a4cb1adb08457d95ad99391e843b73 |
| op_source | The Cryosphere, Vol 14, Pp 3995-4020 (2020) |
| publishDate | 2020 |
| publisher | Copernicus Publications |
| record_format | openpolar |
| spelling | ftdoajarticles:oai:doaj.org/article:a1a4cb1adb08457d95ad99391e843b73 2025-01-17T01:05:58+00:00 Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain M. Lamare M. Dumont G. Picard F. Larue F. Tuzet C. Delcourt L. Arnaud 2020-11-01T00:00:00Z https://doi.org/10.5194/tc-14-3995-2020 https://doaj.org/article/a1a4cb1adb08457d95ad99391e843b73 EN eng Copernicus Publications https://tc.copernicus.org/articles/14/3995/2020/tc-14-3995-2020.pdf https://doaj.org/toc/1994-0416 https://doaj.org/toc/1994-0424 doi:10.5194/tc-14-3995-2020 1994-0416 1994-0424 https://doaj.org/article/a1a4cb1adb08457d95ad99391e843b73 The Cryosphere, Vol 14, Pp 3995-4020 (2020) Environmental sciences GE1-350 Geology QE1-996.5 article 2020 ftdoajarticles https://doi.org/10.5194/tc-14-3995-2020 2022-12-31T11:40:28Z The monitoring of snow-covered surfaces on Earth is largely facilitated by the wealth of satellite data available, with increasing spatial resolution and temporal coverage over the last few years. Yet to date, retrievals of snow physical properties still remain complicated in mountainous areas, owing to the complex interactions of solar radiation with terrain features such as multiple scattering between slopes, exacerbated over bright surfaces. Existing physically based models of solar radiation across rough scenes are either too complex and resource-demanding for the implementation of systematic satellite image processing, not designed for highly reflective surfaces such as snow, or tied to a specific satellite sensor. This study proposes a new formulation, combining a forward model of solar radiation over rugged terrain with dedicated snow optics into a flexible multi-sensor tool that bridges a gap in the optical remote sensing of snow-covered surfaces in mountainous regions. The model presented here allows one to perform rapid calculations over large snow-covered areas. Good results are obtained even for extreme cases, such as steep shadowed slopes or, on the contrary, strongly illuminated sun-facing slopes. Simulations of Sentinel-3 OLCI (Ocean and Land Colour Instrument) scenes performed over a mountainous region in the French Alps allow us to reduce the bias by up to a factor of 6 in the visible wavelengths compared to methods that account for slope inclination only. Furthermore, the study underlines the contribution of the individual fluxes to the total top-of-atmosphere radiance, highlighting the importance of reflected radiation from surrounding slopes which, in midwinter after a recent snowfall (13 February 2018), accounts on average for 7 % of the signal at 400 nm and 16 % at 1020 nm (on 13 February 2018), as well as of coupled diffuse radiation scattered by the neighbourhood, which contributes to 18 % at 400 nm and 4 % at 1020 nm . Given the importance of these contributions, accounting for slopes ... Article in Journal/Newspaper The Cryosphere Directory of Open Access Journals: DOAJ Articles Midwinter ENVELOPE(139.931,139.931,-66.690,-66.690) The Cryosphere 14 11 3995 4020 |
| spellingShingle | Environmental sciences GE1-350 Geology QE1-996.5 M. Lamare M. Dumont G. Picard F. Larue F. Tuzet C. Delcourt L. Arnaud Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| title | Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| title_full | Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| title_fullStr | Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| title_full_unstemmed | Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| title_short | Simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| title_sort | simulating optical top-of-atmosphere radiance satellite images over snow-covered rugged terrain |
| topic | Environmental sciences GE1-350 Geology QE1-996.5 |
| topic_facet | Environmental sciences GE1-350 Geology QE1-996.5 |
| url | https://doi.org/10.5194/tc-14-3995-2020 https://doaj.org/article/a1a4cb1adb08457d95ad99391e843b73 |