Forskningssjef

Rune Solberg

Prosjekter

  • Jordobservasjon
  • Kartlegging og overvåking

AI for Arktis (AI4Arctic)

  • Jordobservasjon

Bedre snøkartlegging (Snowmodel4Sentinel)

Observasjoner av snømengde
  • Jordobservasjon
  • Klima og miljø

Snøobservasjoner (Snow CCI)

  • Jordobservasjon
  • Kartlegging og overvåking

Satellittbasert overvåkning av snø i Norge (Snøtjeneste)

Fyrtårn på en klippe i skumringen, med lyset som skinner ut over sjøen mot horisonten.
  • Jordobservasjon
  • Forklarbar kunstig intelligens
  • Digital sikkerhet og personvern

Pålitelig og grønn KI (ENFIELD)

Publikasjoner

  • 391 publikasjoner funnet
Dahl, Fredrik Andreas; Trier, Øivind Due og Solberg, Rune. (2026).
Analyse av avvikskarakteristikk for snødekningsgrad.
Norsk Regnesentral. BAMJO/21/25. 30. januar 2026. 46 S.
Vis sammendrag
I denne rapporten beskrives arbeidet og resultater fra en utvidelse av validering og evaluering av produkter for snødekningsgrad (FSC) fra 2024. Hensikten har vært å undersøke hvordan avvikene (feil) i FSC-verdier, relativt til «fasiter» fra bilder med høyere oppløsning, varierer i tid og rom med aggregeringsnivå, arealdekke og terreng. Analysene er gjort for Østlandet og tilsigsområder valgt ut av NVE med satellittdata over flere år. Referansedata («fasiter») er basert på Sentinel-2 MSIprodukter i 10 m oppløsning, mens FSC-produktene som ble analysert, er basert på 0,5 km data fra Sentinel-3 SLSTR. Resultatene viser at avvikene har tydelig romlig og tidsmessig struktur. Romlig aggregering reduserer MAE og RMSE, mens bias i hovedsak bevares. En betydelig del av feilen midles likevel ikke effektivt ut ved aggregering opp til de største testede skalaene, noe som tyder på systematiske avvik over større områder. I høydesoneanalysene fremkommer et robust mønster med økte avvik rundt 400-500 m. Når FSC aggregeres til sone-middelverdier per dato reduseres avvikene sammenliknet med pikselbasert stratifisering, men mønsteret i høyde avtar ikke fullt ut. Avvikene er generelt større i skog enn i områder med bart fjell og sparsom vegetasjon, med en negativ bias i skog, som er konsistent med utfordringer knyttet til snø under trekroner. Samlet viser analysen hvordan avvik endrer karakter ved aggregering til modelleringsrelevante enheter, og peker på forhold som bør tas hensyn til ved bruk av FSC som areal- og høydesoneaggregert modellinput
Rudjord, Øystein og Solberg, Rune. (2024).
SnowModel4Sentinel Phase 1 Report.
Norsk Regnesentral. BAMJO/23/24. 40 S.
Solberg, Rune; Gustafsson, David; Waldeland, Anders U.; Rudjord, Øystein; Reksten, Jarle Hamar og Salberg, Arnt Børre. (2024).
Final Report, AI4Arctic SnowMass Deliverable D6, version 1.
Norsk Regnesentral. BAMJO/31/24. 24 S.
Rudjord, Øystein; Waldeland, Anders U. og Solberg, Rune. (2024).
Prototype Product Report, AI4Arctic SnowMass Deliverable D3, version 3.
Norsk Regnesentral. BAMJO/26/24. 92 S.
Rudjord, Øystein; Waldeland, Anders U.; Reksten, Jarle Hamar og Solberg, Rune. (2024).
Software Description, AI4Arctic SnowMass Deliverable D4, version 3.
Norsk Regnesentral. BAMJO/27/24. 17 S.
Waldeland, Anders U.; Rudjord, Øystein; Reksten, Jarle Hamar; Salberg, Arnt Børre og Solberg, Rune. (2024).
Algorithm Report, AI4Arctic SnowMass Deliverable D2, version 3.1.
Norsk Regnesentral. BAMJO/25/24. 56 S.
Gustafsson, David; Clemenzi, Ilaria; Musuuza, Jude og Solberg, Rune. (2024).
Dataset Description, AI4Arctic SnowMass Deliverable D1, version 3.
Norwegian Computing Center. BAMJO/17/24. 26 S.
Gustafsson, David; Waldeland, Anders U.; Rudjord, Øystein og Solberg, Rune. (2024).
Validation Report, AI4Arctic SnowMass Deliverable D5, version 1.
Norsk Regnesentral. BAMJO/30/24. 22 S.
Rudjord, Øystein; Waldeland, Anders U.; Trier, Øivind Due og Solberg, Rune. (2024).
Isdekningsgrad på innsjøer fra SLSTR med dyp læring.
Norsk Regnesentral. BAMJO/06/24. 26 S.
Trier, Øivind Due; Reksten, Jarle Hamar og Solberg, Rune. (2024).
Validering og evaluering av FSC. Delprosjekt for snø og is i NVE Copernicus 2.
Norsk Regnesentral. BAMJO/07/24. 84 S.
Solberg, Rune og Rudjord, Øystein. (2024).
Retrieval of snow surface properties from optical satellite data by snow surface spectrum radiative transfer modelling. Oregon State University
Western Snow Conference. 22–25. april 2024. Corvallis. Oregon.
Stokholm, Andreas; Buus-Hinkler, Jørgen; Wulf, Tore; Korosov, Anton; Saldo, Roberto; Pedersen, Leif Toudal; Arthurs, David; Dragan, Ionut; Modica, Iacopo; Pedro, Juan; Debien, Annekatrien; Chen, Xinwei; Patel, Muhammed; Cantu, Fernando Jose Pena; Turnes, Javier Noa; Park, Jinman; Xu, Linlin; Scott, Katharine Andrea; Clausi, David Anthony; Fang, Yuan; Jiang, Mingzhe; Taleghanidoozdoozan, Saeid; Brubacher, Neil Curtis; Soleymani, Armina; Gousseau, Zacharie; Smaczny, Michał; Kowalski, Patryk; Komorowski, Jacek; Rijlaarsdam, David; Rijn, Jan Nicolaas Van; Jakobsen, Jens; Rogers, Martin Samuel James; Hughes, Nick; Zagon, Tom; Solberg, Rune; Longépé, Nicolas og Kreiner, Matilde Brandt. (2024).
The AutoICE Challenge.
The Cryosphere. ISSN 1994-0416 1994-0424. Vol. 18. Issue 8. S. 3471-3494.
Vis sammendrag
Mapping sea ice in the Arctic is essential for maritime navigation, and growing vessel traffic highlights the necessity of the timeliness and accuracy of sea ice charts. In addition, with the increased availability of satellite imagery, automation is becoming more important. The AutoICE Challenge investigates the possibility of creating deep learning models capable of mapping multiple sea ice parameters automatically from spaceborne synthetic aperture radar (SAR) imagery and assesses the current state of the automatic-seaice-mapping scientific field. This was achieved by providing the tools and encouraging participants to adopt the paradigm of retrieving multiple sea ice parameters rather than the current focus on single sea ice parameters, such as concentration. The paper documents the efforts and analyses, compares, and discusses the performance of the top-five participants’ submissions. Participants were tasked with the development of machine learning algorithms mapping the total sea ice concentration, stage of development, and floe size using a state-of-the-art sea ice dataset with dual-polarised Sentinel1 SAR images and 22 other relevant variables while using professionally labelled sea ice charts from multiple national ice services as reference data. The challenge had 129 teams representing a total of 179 participants, with 34 teams delivering 494 submissions, resulting in a participation rate of 26.4 %, and it was won by a team from the University of Waterloo. Participants were successful in training models capable of retrieving multiple sea ice parameters with convolutional neural networks and vision transformer models. The top participants scored best on the total sea ice concentration and stage of development, while the floe size was more difficult. Furthermore, participants offered intriguing approaches and ideas that could help propel future research within automatic sea ice mapping, such as applying high downsampling of SAR data to improve model efficiency and produce better results.
Gustafsson, David; Clemenzi, Ilaria; Musuuza, Jude og Solberg, Rune. (2023).
Dataset Description, AI4Arctic SnowMass Deliverable D1.
Norsk Regnesentral. BAMJO/04/23. 22 S.
Solberg, Rune; Reksten, Jarle Hamar; Craciunescu, Vasile og Irimescu, Anisoara. (2023).
Remote sensing of snow wetness, FPCUP WetSnow project report.
Norsk Regnesentral. BAMJO/17/23. 55 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Reksten, Jarle Hamar; Killie, Mari Anne; Eastwood, Steinar; Sørensen, Atle; Marin, Carlo og Premier, Valentina. (2023).
CryoClim Snow Products Documentation, CryoClim snow sub-service by MET Norway and NR.
Norsk Regnesentral. BAMJO/05/23. 37 S.
Solberg, Rune; Kreiner, Matilde Brandt; Buus-Hinkler, Jørgen; Wulf, Tore; Stokholm, Andreas; Saldo, Roberto; Arthurs, David og Korosov, Anton. (2023).
Final Report, AI4Arctic SeaIce Deliverable D4.1.
Norsk Regnesentral. BAMJO/10/23. 22 S.
Solberg, Rune; Rudjord, Øystein og Trier, Øivind Due. (2023).
Harmonised snow variable retrieval for hydrological applications by reconstruction of the snow surface spectrum using radiative transfer modelling. European Space Agency
Hydrospace 2023. 27. november – 1. desember 2023. Lisboa.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Killie, Mari Anne; Eastwood, Steinar; Sørensen, Atle; Marin, Carlo og Premier, Valentina. (2023).
New 38-Year Time Series of Daily, Global Fractional Snow Cover Maps. EARSeL
10th EARSeL Workshop on Land Ice and Snow. 6–8. februar 2023. Bern.
Trier, Øivind Due; Waldeland, Anders U. og Solberg, Rune. (2023).
Videreutvikling av skydeteksjon for SLSTR med dyp læring. Delprosjekt for snø og is i NVE Copernicus 2.
Norsk Regnesentral. BAMJO/15/23. 54 S.
Waldeland, Anders U.; Rudjord, Øystein; Trier, Øivind Due og Solberg, Rune. (2023).
Videreutvikling av snødekningsgrad for SLSTR med dyp læring. Delprosjekt for snø og is i NVE Copernicus 2.
Norsk Regnesentral. BAMJO/14/23. 36 S.
Rudjord, Øystein; Solberg, Rune; Spreen, Gunnar og Gerland, Sebastian. (2022).
Estimating thin ice thickness around Svalbard using MODIS satellite imagery.
Geografiska Annaler: Series A. Physical Geography. ISSN 0435-3676 1468-0459. Vol. 104. Issue 2. S. 127-149.
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Information about the state of the Arctic sea ice is becoming increasingly important. This paper describes an approach for automatic retrieval of daily thin sea ice thickness maps around Svalbard. The algorithm uses thermal satellite imagery from MODIS to estimate the surface temperature of the ice and further uses a thermal model of the ice surface to estimate the thickness of the sea ice. The approach is usable for thin sea ice, up to ca. 50 cm thick, during cold weather (freezing) conditions and without cloud cover present. The algorithm is compared with helicopter-borne electromagnetic ice thickness measurements. The comparison yields increasing root-mean-square deviation (RMSD) for thicker ice. The lowest RMSD found is 8.7 cm for ice thickness in the range 10 cm < hi ≤ 20 cm. The highest RMSD found is 25.2 cm for ice thickness in the range 30 cm < hi ≤ 40 cm. The bias shows no such trend, and the overall bias is found to be −5.5 cm. The results show that this is a promising approach, allowing monitoring of thin sea ice thickness at relatively higher spatial resolution.
Solberg, Rune og Trier, Øivind Due. (2022).
Sentinel for snow surface hoar mapping. Sentinel4SurfaceHoar project results.
Norsk Regnesentral. SAMBA/04/22. 72 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Killie, Mari Anne; Eastwood, Steinar og Sørensen, Atle. (2022).
A new 38-year time series of daily, global fractional snow cover maps. University of Alaska Fairbanks
16th International Circumpolar Remote Sensing Symposium. 16–20. mai 2022. Fairbanks.
Solberg, Rune; Reksten, Jarle Hamar; Craciunescu, Vasile og Irmescu, Anisoara. (2022).
WetSnow processing chain. WetSnow project report no. 1.
Norsk Regnesentral. SAMBA/06/22. 34 S.
Thorarinsdottir, Thordis Linda; Solberg, Rune; Lenkoski, Alex og Roksvåg, Thea. (2022).
Potensialet i data. -
NFR og KLD frokostmøte: Data og datadeling. 29. september 2022.
Solberg, Rune; Reksten, Jarle Hamar; Waldeland, Anders U. og Salberg, Arnt Børre. (2021).
Snow Product User Guide. AI4Arctic guide to snow products V1.
Norsk Regnesentral. SAMBA/15/21. 26 S.
Solberg, Rune; Reksten, Jarle Hamar; Trier, Øivind Due; Waldeland, Anders U.; Meldvold, Kjetil og Orthe, Nils Kristian. (2021).
Utvikling av operasjonell snøtjeneste ved NVE. Resultater fra prosjektfase 3.
Norsk Regnesentral. SAMBA/37/21. 62 S.
Solberg, Rune; Salberg, Arnt Børre; Waldeland, Anders U.; Reksten, Jarle Hamar; Trier, Øivind Due; Kreiner, Matilde Brandt; Wulf, Tore; Pedersen, Leif Toudal og Stokholm, Andreas. (2021).
Final report. AI4Arctic Deliverable 6.
Norsk Regnesentral. SAMBA/19/21. 78 S.
Solberg, Rune; Salberg, Arnt Børre og Reksten, Jarle Hamar. (2021).
A new climate snow cover record based on ATSR-2 and AATSR. EUMETSAT
EUMETSAT 2021 Conference. 20–24. september 2021.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Reksten, Jarle Hamar; Killie, Mari Anne; Eastwood, Steinar og Sørensen, Atle. (2021).
Development of a new 38-year time series of daily, global fractional snow cover products based on fusion of optical and passive microwave radiometer data. European Space Agency
From Science to Operations for Copernicus Imaging Microwave Radiometer (CIMR) Mission. 11–12. mai 2021.
Solberg, Rune; Salberg, Arnt Børre og Trier, Øyvind Due. (2021).
Bruker kunstig intelligens for å oppdage forurensning og naturforringelse.
29. desember 2021.
Trier, Øivind Due; Waldeland, Anders U. og Solberg, Rune. (2021).
Automatisk skydeteksjon i Sentinel-3 SLSTR satellittbilder med U-Net. Første resultater.
Norsk Regnesentral. SAMBA/26/21. 146 S.
Rudjord, Øystein; Trier, Øivind Due; Solberg, Rune og Hughes, Nick. (2020).
Sentinel4ThinIce Phase 2 WP8: Diagnosis and correction of possible underestimated ice thickness. Sentinel4ThinIce project report 2020.
Norsk Regnesentral. SAMBA/15/20. 24 S.
Melvold, Kjetil; Rudjord, Øystein og Solberg, Rune. (2020).
Utvikling av operasjonell Snøtjeneste og Innsjøistjeneste hos NVE. Norsk Romsenter
Ny Copernicus-periode. Infodag. 22. oktober 2020. webinar.
Salberg, Arnt Børre; Waldeland, Anders U.; Solberg, Rune; Malmgren-Hansen, David; Pedersen, Leif Toudal og Kreiner, Matilde Brandt. (2020).
Software package: AI4Arctic Deliverable 4.
Norsk Regnesentral. SAMBA/47/20. 26 S.
Schneider, Philipp; Hamer, Paul David; Vogt, Matthias; Trier, Øivind Due; Solberg, Rune; Skogesal, Hogne; Brobakk, Trond Einar og Ramfjord, Hallvard. (2020).
SEN4POL – Towards a Sentinel-based pollen information service. Norge digitalt
Faggruppe satellittdata workshop. 7. september 2020. Online.
Schneider, Philipp; Hamer, Paul David; Vogt, Matthias; Trier, Øivind Due; Solberg, Rune; Skogesal, Hogne; Brobakk, Trond Einar og Ramfjord, Hallvard. (2020).
SEN4POL – Towards a Sentinel-based pollen information service. Norwegian Space Agency
Copernicus Day of the Norwegian Space Agency. 22. oktober 2020. Online.
Solberg, Rune; Trier, Øivind Due og Rudjord, Øystein. (2020).
Remote Sensing of Snow Properties with Sentinel-3 versus MODIS. University of Bern
9th EARSeL workshop on Land Ice and Snow. 3–5. februar 2020. Bern.
Solberg, Rune. (2020).
Flomtjenesten. Norsk Romsenter
Ny Copernicus-periode. Infodag. 22. oktober 2020. Oslo.
Solberg, Rune; Salberg, Arnt Børre; Reksten, Jarle Hamar; Rasmussen, Gunnar; Kaljord, Andreas Hay og Jacobsen, Joakim. (2020).
Design and development toward a global flood monitoring product. GlobFlom report.
Norsk Regnesentral. SAMBA/49/20. 68 S.
Kreiner, Matilde Brandt; Pedersen, Leif Toudal; Solberg, Rune; Trier, Øivind Due; Reksten, Jarle Hamar; Rudjord, Øystein og Gustavsson, David. (2020).
Dataset and data policy. AI4Arctic Deliverable 3.
Norsk Regnesentral. SAMBA/32/20. 44 S.
Solberg, Rune. (2020).
Project management plan. AI4Arctic Deliverable 0.
Norsk Regnesentral. SAMBA/14/2020. 20 S.
Waldeland, Anders U.; Reksten, Jarle Hamar; Salberg, Arnt Børre; Solberg, Rune; Pedersen, Leif Toudal; Malmgren-Hansen, David og Kreiner, Matilde Brandt. (2020).
ICT requirements and API. AI4Arctic Deliverable 2.
Norsk Regnesentral. SAMBA/20/20. 24 S.
Solberg, Rune; Salberg, Arnt Børre; Waldeland, Anders U.; Kreiner, Matilde Brandt; Pedersen, Leif Toudal; Malmgren-Hansen, David; Korosov, Anton og Gustafsson, David. (2020).
Mid-term report. AI4Arctic Deliverable 5.
Norsk Regnesentral. SAMBA/39/20. 38 S.
Solberg, Rune; Waldeland, Anders U.; Salberg, Arnt Børre; Kreiner, Matilde Brandt; Pedersen, Leif Toudal og Malmgren-Hansen, David. (2020).
Problem statement and methodologies. AI4Arctic Deliverable 1.
Norsk Regnesentral. SAMBA/18/20. 46 S.
Solberg, Rune; Rudjord, Øystein; Reksten, Jarle Hamar og Trier, Øivind Due. (2020).
Multi-sensor multi-temporal FSC 2017-2020 dataset. S4S multi-FSC prototype products to EDI, Version 2.0.
Norsk Regnesentral. SAMBA/24/20. 30 S.
Schneider, Philipp; Hamer, Paul David; Trier, Øivind Due; Solberg, Rune; Ramfjord, Hallvard; Brobakk, Trond Einar og Skogesal, Hogne. (2019).
SEN4POL Phase-1: Final Scientific Report.
Norsk institutt for luftforskning. 40 S.
Solberg, Rune og Trier, Øivind Due. (2019).
Mapping snow surface hoar by optical remote sensing.
International Symposium on Mitigative Measures against Snow Avalanches and Other Rapid Gravity Mass Flows. 3–5. april 2019. Siglufjörður.
Rudjord, Øystein; Solberg, Rune; Reksten, Jarle Hamar og Trier, Øivind Due. (2019).
Monitoring lake ice cover with Sentinel-3.
ESA Living Planet Symposium. 13–17. mai 2019. Milano.
Reksten, Jarle Hamar; Salberg, Arnt Børre og Solberg, Rune. (2019).
System for deteksjon og kartlegging av flom basert på SAR.
Norsk Regnesentral. SAMBA/11/19. 20 S.
Rudjord, Øystein; Solberg, Rune; Trier, Øivind Due og Hughes, Nick. (2019).
Monitoring Thin Sea Ice Thickness with Sentinel-3.
IGS International Symposium on Sea Ice at the Interface. 19–23. august 2019. Winnipeg.
Solberg, Rune; Trier, Øivind Due og Rudjord, Øystein. (2019).
Remote sensing of snow properties with Sentinel-3.
Nordic Remote Sensing Conference. 17–19. september 2019. Århus.
Reksten, Jarle Hamar; Salberg, Arnt Børre og Solberg, Rune. (2019).
Flood detection in Norway based on Sentinel-1 SAR imagery.
International Archives of Photogrammetry. Remote Sensing and Spatial Information Sciences (ISPRS Archives). ISSN 1682-1750 2194-9034. Vol. XLII-3/W8. S. 349-355.
Vis sammendrag
After large flood incidents in Norway, The Norwegian Water Resources and Energy Directorate (NVE), has the responsibility for documenting the flooded areas. This has so far mainly been performed by utilising aerial images and visual interpretation. Satellite images are a valuable source of additional information as they are able to cover vast areas in each satellite pass. In this paper a fully automated system for detecting and delineating floods with the use of Synthetic Aperture Radar (SAR) images from the Sentinel-1 satellites is presented. In SAR images wet areas and water bodies usually show lower backscatter than dry areas. The flood detection system is thus based on comparing a reference image acquired before the flood with the flood event image. A Sentinel-1 training dataset has been obtained and manually annotated by NVE from three flood events in Norway. This training set has been used to train a random forest (RF) classifier, which outputs a score for each pixel in the SAR image. This score image is thresholded in order to obtain a crude flood detection. Unfortunately, changes in the backscatter may also be triggered by other events such as melting snow and harvested fields of crops. To mitigate such lookalikes, several techniques have been implemented and tested. This includes masking based on size, slope and height above nearest drainage (HAND). The experiments presented show that the system performance is very good. Of the 179 manually labelled flood objects, 168 are detected. The system is being applied operationally at NVE.
Rudjord, Øystein; Trier, Øivind Due; Solberg, Rune og Hughes, Nick. (2019).
Sentinel4ThinIce Phase 2. Thin ice thickness retrieval with Sentinel-3.
Norsk Regnesentral. SAMBA/53/19. 27 S.
Rudjord, Øystein; Reksten, Jarle Hamar; Solberg, Rune; Trier, Øivind Due og Melvold, Kjetil. (2019).
Utvikling av operasjonell innsjøistjeneste hos NVE: Resultater fra prosjektfase 2.
Norsk Regnesentral. SAMBA/45/19. 56 S.
Salberg, Arnt Børre; Luojus, Kari; Derksen, Chris; Marin, Carlo; Solberg, Rune; Schwaizer, Gabriele og Nagler, Thomas. (2019).
ESA CCI+ Snow ECV: End-to-End ECV Uncertainty Budget, verson 1.0.
European Space Agency. 26 S.
Salberg, Arnt Børre; Reksten, Jarle Hamar og Solberg, Rune. (2019).
Algorithms for flood detection and mapping by SAR. Algorithm Theoretical Basis Document, Flood Service System at NVE.
Norsk Regnesentral. SAMBA/10/19. 24 S.
Solberg, Rune; Reksten, Jarle Hamar; Trier, Øivind Due; Melvold, Kjetil og Orthe, Nils Kristian. (2019).
Utvikling av operasjonell snøtjeneste ved NVE. Resultater fra prosjektfase 2.
Norsk Regnesentral. SAMBA/52/2019. 50 S.
Solberg, Rune; Salberg, Arnt Børre; Reksten, Jarle Hamar; Kristensen, Søren Elkjær; Orthe, Nils Kristian og Sund, Monica. (2019).
Utvikling av operasjonell flomtjeneste ved NVE. Resultater fra prosjektfase 3.
Norsk Regnesentral. SAMBA/09/2019. 42 S.
Solberg, Rune og Salberg, Arnt Børre. (2019).
Landslide detection and mapping by remote sensing. Association of Chartered Engineers in Iceland (VFI)
International Symposium on Mitigative Measures against Snow Avalanches and Other Rapid Gravity Mass Flows. 3-5 April 2019,. 3–5. april 2019. Siglufjörður.
Solberg, Rune; Reksten, Jarle Hamar; Trier, Øivind Due; Melvold, Kjetil; Orthe, Nils Kristian og Nilsen, Sven-Erik. (2018).
Utvikling av operasjonell snøtjeneste hos NVE. Resultater fra prosjektfase 1.
Norsk Regnesentral. SAMBA/19/18. 46 S.
Solberg, Rune. (2018).
Snow products and services under development by the Norwegian Computing Center. European Environment Agency
Copernicus Snow and Ice Monitoring Workshop. 24–25. januar 2018. Købehavn.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Reksten, Jarle Hamar; Killie, Mari Anne; Eastwood, Steinar og Breivik, Lars-Anders. (2018).
Local and regional trends in snow cover from a 34-year time series of satellite observations. Alfred Wegener Institute
15th International Circumpolar Remote Sensing Symposium (ICRSS). 10–14. september 2018. Potsdam.
Solberg, Rune; Trier, Øivind Due; Rudjord, Øystein og Reksten, Jarle Hamar. (2018).
A portfolio of snow products based on Sentinel-3 for snow hydrology. Universität Heidelberg
SnowHydro – International Conference on Snow Hydrology. 12–15. februar 2018. Heidelberg.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Killie, Mari Anne; Reksten, Jarle Hamar; Steinar, Eastwood og Breivik, Lars-Anders. (2018).
Local and regional trends in snow cover from a 34-year time series of satellite observations. EUMETSAT
2018 EUMETSAT Meteorological Satellite Conference. 17–21. september 2018. Tallinn.
Rudjord, Øystein; Hamar, Jarle Bauck; Solberg, Rune; Trier, Øivind Due og Melvold, Kjetil. (2018).
Utvikling av operasjonell innsjøistjeneste hos NVE. Resultater fra prosjektfase 1.
Norsk Regnesentral. SAMBA/20/18. 37 S.
Solberg, Rune; Rudjord, Øystein og Trier, Øivind Due. (2018).
Single- and multi-sensor snow-cover mapping from Sentinel-3 and Sentinel-1.
Norsk Regnesentral. SAMBA/43/18. 60 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre og Reksten, Jarle Hamar. (2018).
Further advancement of global snow mapping in CryoClim. Sentinel4CryoClim Phase 2 - Deliverables 1, 3-7.
Norsk Regnesentral. SAMBA/44/18. 82 S.
Solberg, Rune; Salberg, Arnt Børre; Trier, Øivind Due; Rudjord, Øystein; Stancalie, Gheorghe; Diamandi, Andrei; Irimescu, Anisoara og Craciunescu, Vasile. (2017).
Remote sensing of snow wetness in Romania by Sentinel-1 and Terra MODIS data.
Romanian Journal of Physics. ISSN 1221-146X. Vol. 62. Issue 821.
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Snow monitoring is essential for prediction of flooding due to rapid snowmelt, to provide snow avalanche risk forecasts and for water resource management – including hydropower production, agriculture, groundwater and drinking water. Sentinel-1 C-band SAR is sensitive to presence of wet snow and can be used to binary snow-wetness classification. Wet-snow mapping into more categories has been demonstrated in the past by using MODIS data. The combination of surface temperature and the temporal development of the effective snow grain size are used to infer approximately how wet the snow is.
Solberg, Rune; Rudjord, Øystein og Trier, Øivind Due. (2017).
Developing an approach for satellite observations of black carbon in snow surfaces in the Arctic. University of Iceland
International Conference on High Latitude Dust 2017. 20–25. mai 2017. Reykjavik.
Mihailescu, Denis; Solberg, Rune; Stancalie, Gheorghe; Irimescu, Anisoara; Nertan, Argentina; Salberg, Arnt Børre; Trier, Øivind Due; Craciunescu, Vasile; Catana, Simona og Angearu, Claudiu. (2017).
Multi-sensor wet snow product (MWS) from Sentinel-1 and Sentinel-3 vs multi-sensor wet snow product (MWS) from Sentinel-1 and MODIS. West University of Timisoara
19th International Symposium on Symbolic and Numeric Algorithms for Scientific Computing. 21–24. september 2017. Timisoara.
Solberg, Rune; Salberg, Arnt Børre; Reksten, Jarle Hamar; Trier, Øivind Due; Sund, Monica; Colleuille, Hervé; Kristensen, Søren Elkjær; Orthe, Nils Kristian og Øydvin, Eli Katrina. (2017).
Utvikling av operasjonell flomtjeneste ved NVE. Resultater fra prosjektfase nr. 1.
Norsk Regnesentral. SAMBA/07/2017. 34 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Trier, Øivind Due; Stancalie, Gheorghe; Diamandi, Andrei og Irimescu, Anisoara. (2017).
A multi-sensor multi-temporal approach to retrieving snow surface wetness from a combination of Sentinel-1 and Sentinel-3 data. EARSeL
8th EARSeL workshop on Land Ice and Snow. 7–9. februar 2017. Bern.
Solberg, Rune. (2017).
Optical remote sensing of snow. Norwegian University of Science and Technology
Workshop on X-ray micro-tomography of porous ice media. 22–23. juni 2017. Trondheim.
Solberg, Rune; Trier, Øivind Due og Rudjord, Øystein. (2017).
Towards a portfolio of products for snow surface characterisation based on Sentinel-3. Geological Survey of Denmark and Greenland
Workshop on Modeling Meltwater in Snow and Firn: Processes. Validation. Intercomparison and Model Uses of Optical Remotely Sensed Data. 20–22. september 2017. Copenhagen.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Killie, Mari Anne; Eastwood, Steinar og Breivik, Lars-Anders. (2017).
Local and regional trends in snow cover from a 34-year time series of satellite observations. International Glaciological Society
IGS International Symposium on Polar Ice. Polar Climate. Polar Change. 14–19. august 2017. Boulder. CO.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Trier, Øivind Due; Nertan, Argentina; Irimescu, Anisoara; Mihailescu, Denis og Stancalie, Gheorghe. (2017).
Multi-sensor/multi-temporal prototype wet snow product – Version 3, SnowBall WP3, Deliverable D3.4, Sentinel-3 extension.
Norsk Regnesentral. SAMBA/16/2017. 112 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Killie, Mari Anne; Eastwood, Steinar og Breivik, Lars-Anders. (2017).
Advancement of global snow mapping in CryoClim, Sentinel4CryoClim Phase 1, Deliverables 1-6.
Norsk Regnesentral. SAMBA/10/2017. 80 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Trier, Øivind Due; Nertan, Argentina; Irimescu, Anisoara; Mihailescu, Denis og Stancalie, Gheorghe. (2017).
Multi-sensor/multi-temporal prototype wet snow product – Version 2, SnowBall WP3, Deliverable D3.4.
Norsk Regnesentral. SAMBA/15/2017. 34 S.
Solberg, Rune; Salberg, Arnt Børre; Reksten, Jarle Hamar; Trier, Øivind Due; Kristensen, Søren Elkjær; Orthe, Nils Kristian; Colleuille, Hervé og Sund, Monica. (2017).
Utvikling av operasjonell flomtjeneste ved NVE, Resultater fra prosjektfase 2.
Norsk Regnesentral. SAMBA/37/2017. 28 S.
Rudjord, Øystein; Solberg, Rune; Trier, Øivind Due; Salberg, Arnt Børre; Stăncălie, Gheorghe; Diamandi, Andrei; Irimescu, Anişoara og Craciunescu, Vasile. (2017).
Remote sensing of snow wetness using Sentinel: a multisensor approach. IGS
IGS International Symposium on Polar Ice. Polar Climate. Polar Change. 14–19. august 2017. Boulder. CO.
Rudjord, Øystein; Trier, Øivind Due; Solberg, Rune og Hughes, Nick. (2017).
Sentinel4ThinIce Phase 1: Algorithm improvements, validation and intercomparison.
Norsk Regnesentral. SAMBA/34/2017. 30 S.
Melsheimer, Christian; Mäkynen, Marko; Rasmussen, Till Andreas Soya; Rudjord, Øystein; Similä, Markku H.; Solberg, Rune og Walker, Nick P.. (2016).
Comparison and validation of four Arctic Sea ice thickness products of the EC POLAR ICE project.
ESA SP. ISSN 0379-6566 1609-0438. Vol. SP-740.
Vis sammendrag
Sea ice thickness (SIT) is an important parameter for monitoring Arctic change, modelling and predicting weather and climate, and for navigation and offshore op- erations. However, SIT is still not very well monitored operationally. In the European Commission (EC) FP7 project “POLAR ICE”, three novel SIT products based on different satellite data as well as SIT from a state-of-the- art ocean and sea ice model are fed into a common data handling and distribution system for end users. Each SIT product has different scopes and limitations as to, e.g., spatial and temporal resolution, ice thickness range and geographical domain. The aim of this study is to com- pare the four different SIT products with each other and with SIT in-situ measurements in order to better under- stand the differences and limitations, and possibly give recommendations on how to best profit from the synergy of the different data.
Box, Jason E.; Kokhanovsky, Alexander A.; Heygster, Georg; Istomina, Larysa; Høyer, Jacob; Riihelä, Aku; Dumont, Marie; Picard, Ghislain; Solberg, Rune; Paul, Frank; Hubbard, Alun; Perovich, Don; Aoki, Teruo og Key, Jeffrey R.. (2016).
Cryospheric albedo from Sentinel-3 and -2. European Space Agency
ESA Living Planet Symposium. 9–13. mai 2016. Prague.
Salberg, Arnt Børre; Zortea, Maciel; Hamar, Jarle Bauck; Solberg, Rune; Sund, Monica og Colleuille, Hervé. (2016).
Preparing for a national service for flood monitoring using Sentinel-1.
ESA Living Planet Symposium. 9. mai 2016.
Solberg, Rune. (2016).
Vakre men livsfarlige iskrystaller.
22. mars 2016.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Trier, Øivind Due; Stancalie, Gheorghe; Diamandi, Andrei og Irimescu, Anisoara. (2016).
Single- and multi-sensor snow wetness mapping by Sentinel-1 and MODIS data. The Ohio State University
73rd Eastern Snow Conference. 14–16. juni 2016. Columbus. Ohio.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre og Killie, Mari Anne. (2016).
Status and further development of CryoClim global Snow Cover Extent product. WMO
WMO GCW 2nd Snow Watch Team Meeting. 13–14. juni 2016. Columbus. Ohio.
Solberg, Rune. (2016).
Bedre prognoser ved bruk av satellittdata i kombinasjon med data fra andre kilder. Energi Norge
FlomQ – Workshop om flomestimering. 23–25. mai 2016. Trondheim.
Solberg, Rune; Killie, Mari Anne; Andreassen, Liss Marie og König, Max. (2016).
Algorithms for monitoring of snow, sea ice and glaciers – the CryoClim project. European Space Agency
ESA PRODEX 30 Year Anniversary Workshop. 5–6. september 2016. Noordwijk.
Stancalie, Gheorghe; Craciunescu, Vasile; Diamandi, Andrei; Irimescu, Anisoara; Dumitrache, Catalin; Solberg, Rune; Rudjord, Øystein og Trier, Øivind Due. (2016).
Current achievements towards developing downstream services for snow monitoring in Romania. Romanian Space Agency
5th COPERNICUS Conference for the Eastern European Copernicus users and service providers. 5–6. oktober 2016. Bucuresti.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Trier, Øivind Due; Stancalie, Gheorghe; Diamandi, Andrei og Irimescu, Anisoara. (2016).
Single and multi-sensor snow wetness mapping by Sentinel-1 and Sentinel-3 data. West University of Timișoara
The 18th International Symposium on Symbolic and Numerical Algorithms for Scientific Computing. Geoinformatics Workshop. 24–27. september 2016. Timisoara.
Walker, Nick; Fleming, Andrew; Cziferszky, Andreas; Pedersen, Leif Toudal; Rasmussen, Till; Mäkynen, Marko; Berglund, Robin; Seitsonen, Lauri; Rudjord, Øystein; Solberg, Rune; Tangen, Helge; Axell, Lars; Saldo, Roberto; Melsheimer, Christian; Larsen, Hans Eilif; Puestow, Thomas; Arthurs, David og Flach, Dominic. (2016).
Polar ice: Integrating, distributing and visualising ice information products for operators in polar waters.
ESA SP. ISSN 0379-6566 1609-0438. Vol. SP-740.
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The POLAR ICE project has developed a system for integrating and delivering satellite derived ice information products to operators working in the economically and environmentally important Arctic and Antarctic regions. POLAR ICE has been supported by the European Commission's FP7 programme and undertaken by European and Canadian companies and institutes, who are all partners in the Polar View Earth Observation Limited (PVEO) company. It is the aim of PVEO to commercialise the service that has been developed and demonstrated as a part of POLAR ICE.Access to sea ice information derived from satellite earth observation data is critical to support the increasing numbers of Arctic and Antarctic shipping and off-shore operations and to protect the rapidly changing polar environment.To-date the development of sea ice information capabilities has addressed separate elements of complete service chains. In contrast POLAR ICE has linked these separate elements together, filled in known gaps and built a robust integrated service chain.
Solberg, Rune; Rudjord, Øystein og Trier, Øivind Due. (2016).
Remote sensing of black carbon in the Arctic. BlackCarbon main project, Phase 1, Deliverables 1, 2 and 3.
Norsk Regnesentral. SAMBA/56/16. 122 S.
Solberg, Rune; Salberg, Arnt Børre; Rudjord, Øystein; Trier, Øivind Due; Stancalie, Gheorghe; Diamandi, Andrei og Irimescu, Anisoara. (2016).
Single and multi-sensor snow wetness mapping by Sentinel-1 and Sentinel-3 data. European Space Agency
ESA Living Planet Symposium. 9–13. mai 2016. Prague.
Solberg, Rune; Rudjord, Øystein; Trier, Øivind Due; Malnes, Eirik og Hindberg, Heidi. (2016).
Multi-sensor fractional snow cover mapping by fusion of Sentinel-1 and Sentinel-3 data. European Space Agency
ESA Living Planet Symposium. 9–13. mai 2016. Prague.
Malnes, Eirik; Buanes, Arild; Nagler, Thomas; Bippus, Gabriele; Gustafsson, David; Schiller, Christian; Metsämäki, Sari; Pulliainen, Jouni; Luojus, Kari; Larsen, Hans Eilif; Solberg, Rune; Diamandi, Andrei og Wiesmann, Andreas. (2015).
User requirements for the snow and land ice services - CryoLand.
The Cryosphere. ISSN 1994-0416 1994-0424. Vol. 9. Issue 3. S. 1191-1202.
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CryoLand (2011–2015) is a project carried out within the 7th Framework of the European Commission aimed at developing downstream services for monitoring seasonal snow, glaciers and lake/river ice primarily based on satellite remote sensing. The services target private and public users from a wide variety of application areas, and aim to develop sustainable services after the project is completed. The project has performed a thorough user requirement survey in order to derive targeted requirements for the service and provide recommendations for the design and priorities of the service. In this paper we describe the methods used, the major findings in this user survey, and how we used the results to design and specify the CryoLand snow and land ice service. The user requirement analysis shows that a European operational snow and land ice service is required and that there exists developed cryosphere products that can meet the specific needs. The majority of the users were mainly interested not only in the snow services, but also the lake/river ice products and the glacier products were desired.
Solberg, Rune; Diamandi, Andrei og Irimescu, Anisoara. (2015).
Validation plan for remote sensing of snow wetness.
Norsk Regnesentral. SAMBA/50/15. 42 S.
Solberg, Rune; Rudjord, Øystein; Salberg, Arnt Børre; Trier, Øivind Due; Nertan, Argentina; Irimescu, Anisoara; Dumitrescu, Alexandru og Stăncălie, Gheorghe. (2015).
Multi-sensor/multi-temporal prototype wet snow product – Version 1.
Norsk Regnesentral. SAMBA/48/15. 48 S.
Solberg, Rune; Salberg, Arnt Børre; Rudjord, Øystein; Trier, Øivind Due; Irimescu, Anişoara; Catană, Simona; Mihăilescu, Denis; Dumitrescu, Alexandru og Stăncălie, Gheorghe. (2015).
Validated wet snow retrieval algorithms.
Norsk Regnesentral. SAMBA/47/15. 92 S.