- E-postStephan.Kral@uib.no
- BesøksadresseAllégaten 705007 Bergen
- PostadressePostboks 78035020 Bergen
Utvalgte publikasjoner
- 2016. Proof of concept for turbulence measurements with the RPAS SUMO during the BLLAST campaign. Atmospheric Measurement Techniques. 9: 4901-4913. Publisert 2016-10-06. doi: 10.5194/amt-9-4901-2016
- 2016. Proof of concept for turbulence measurements with the RPAS SUMO during the BLLAST campaign.
- 2016. The ISOBAR project (2016–2018) – Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
- 2016. The ISOBAR project (2016-2018) - Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
- 2016. Similarity analysis of turbulent transport and dissipation for momentum, temperature, moisture and CO2 during BLLAST. Atmospheric Chemistry and Physics Discussions (ACPD). Publisert 2016-02-01. doi: 10.5194/acp-2015-1061
- 2016. Exploring the potential of the RPA system SUMO for multipurpose boundary-layer missions during the BLLAST campaign. Atmospheric Measurement Techniques. 9: 2675-2688. doi: 10.5194/amt-9-2675-2016
- 2016. Boundary-Layer Study at FINO1.
- 2016. OBLO instrumentation at FINO1.
- 2016. Proof of concept for wind turbine wake investigations with the RPAS SUMO.
- 2015. Turbulence measurements from the RPAS SUMO during BLLAST.
- 2015. Wind turbine wake measurements with the RPAS SUMO.
- 2015. Yaw angle estimation for the measurement of turbulent fluxes from the Small Unmanned Meteorological Observer (SUMO).
- 2014. Observations of summer turbulent surface fluxes in a High Arctic fjord. Quarterly Journal of the Royal Meteorological Society. 140: 666-675. doi: 10.1002/qj.2167
- (2022). Gradient-Based Turbulence Estimates from Multicopter Profiles in the Arctic Stable Boundary Layer. Boundary-Layer Meteorology.
- (2021). UAS based Atmospheric Research in Polar Regions — Experiences and Perspectives from Sea-ice and Ship-based Operations.
- (2021). The Innovative Strategies for Observations in the Arctic Atmospheric Boundary Layer Project (ISOBAR) — Unique fine-scale observations under stable and very stable conditions . Bulletin of The American Meteorological Society - (BAMS). 218-243.
- (2021). Ship-based UAS and Remote Sensing Observations of the Lower Arctic Atmosphere.
- (2021). SUMO and SAMURAI – GFI/UiB drones for wind energy reserach.
- (2021). PC-2 Winter Process Cruise (WPC). .
- (2021). Atmospheric Processes (T1-2-3).
- (2020). Unmanned Aircraft Get Together: The LAPSE-RATE Campaign . Bulletin of The American Meteorological Society - (BAMS). 590-596.
- (2020). Observations and simulations from an arctic fjord and valley environment in Svalbard.
- (2020). Innovative Strategies for Observations in the Arctic Atmospheric Boundary Layer.
- (2020). Analysis of Arctic Stable Boundary Layers during the ISOBAR Field Campaign.
- (2019). Wind- und Turbulenzmessung in stabiler Grenzschicht mit kleinen unbemannten Luftfahrzeugen während zweier ISOBAR Kampagnen im nördlichen Finnland.
- (2019). The Multi-Purpose Airborne Sensor Carrier MASC-3 for Wind and Turbulence Measurements in the Atmospheric Boundary Layer. Sensors. 32 sider.
- (2019). The ISOBAR Project on stable boundary layers - Current status on data analysis and results.
- (2019). Synthesis and validation of meteorological parameters from different RPAS during the ISOBAR campaigns at Hailuoto.
- (2019). Intercomparison of small unmanned aircraft system (sUAS) measurements for atmospheric science during the LAPSE-RATE campaign. Sensors. 1-32.
- (2019). Development of community, capabilities and understanding through unmanned aircraft-based atmospheric research: The LAPSE-RATE campaign. Bulletin of The American Meteorological Society - (BAMS).
- (2018). Wind and Turbulence Measurements with RPA during the ISOBAR Campaign 2017.
- (2018). Wind and Turbulence Measurements with RPA during the ISOBAR Campaign 2017.
- (2018). Wind and Turbulence Measurements with RPA during the ISOBAR Campaign.
- (2018). The two ISOBAR Stable Boundary Layer Field Campains at Hailuoto, Finland in 2017 and 2018: Experimental Setup and First Results.
- (2018). The two ISOBAR Stable Boundary Layer Field Campaigns at Hailuoto, Finland in 2017 and 2018: Experimental Setup and First Results.
- (2018). The Two ISOBAR Stable Boundary Layer Field Campains at Hailuoto, Finland in 2017 and 2018: Experimental Setup and First Results.
- (2018). The Innovative Strategies for Observations in the Arctic Atmospheric Boundary LAyeR (ISOBAR) Field Campaign: Perspectives from the University of Oklahoma.
- (2018). The ISOBAR project on stable boundary layers – The two campaigns on Hailuoto 2017 and 2018.
- (2018). RPAS observation on the structure and evolution of the Atmospheric Boundary Layer during the two ISOBAR field campaigns on Hailuoto, 2017 and 2018.
- (2018). Innovative strategies for observations in the Arctic atmospheric boundary layer (ISOBAR)—The Hailuoto 2017 Campaign. Atmosphere. 29 sider.
- (2018). BASIC:-Boundary Layers in the Arctic Atmosphere, Seas and Ice Dynamics - SKD Strategic Project January 2015 – December 2017. 388. 388. .
- (2018). Advances in the Measurements of the Structure Function Parameter for Temperature Using a Small Unmanned Aircraft System.
- (2018). Advances in the Estimation of the Structure Function Parameter for Temperature Using a Small Unmanned Aircraft System.
- (2017). Two new RPAS for atmospheric boundary layer research based on an off-the-shelf model aircraft and the Paparazzi autopilot .
- (2017). RPAS based observation on the Arctic Boundary Layer during the ISOBAR campaigns on Andøya and Hailuoto.
- (2017). N-ICE2015 sodar wind data.
- (2017). A surface-layer study of the transport and dissipation of turbulent kinetic energy and the variances of temperature, humidity and CO2. Boundary-Layer Meteorology. 211-231.
- (2016). UAVs in the Iceland Sea Project.
- (2016). The ISOBAR project (2016–2018) – Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
- (2016). The ISOBAR project (2016–2018) – Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
- (2016). The ISOBAR project (2016-2018) - Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
- (2016). Similarity analysis of turbulent transport and dissipation for momentum, temperature, moisture and CO2 during BLLAST. Atmospheric Chemistry and Physics Discussions (ACPD).
- (2016). SUMO operations in harsh environments.
- (2016). SUMO operation during the BLLAST campaign - Experiences and results.
- (2016). Proof of concept for wind turbine wake investigations with the RPAS SUMO. Energy Procedia. 452-461.
- (2016). Proof of concept for wind turbine wake investigations with the RPAS SUMO.
- (2016). Proof of concept for turbulence measurements with the RPAS SUMO during the BLLAST campaign. Atmospheric Measurement Techniques. 4901-4913.
- (2016). Proof of concept for turbulence measurements with the RPAS SUMO during the BLLAST campaign.
- (2016). Observations on the Arctic Boundary Layer using the Small Unmanned Meteorological Observer (SUMO) during polar night .
- (2016). OBLO instrumentation at FINO1.
- (2016). Exploring the potential of the RPA system SUMO for multipurpose boundary-layer missions during the BLLAST campaign. Atmospheric Measurement Techniques. 2675-2688.
- (2015). Yaw angle estimation for the measurement of turbulent fluxes from the Small Unmanned Meteorological Observer (SUMO).
- (2015). Wind turbine wake measurements with the RPAS SUMO.
- (2015). Turbulence measurements from the RPAS SUMO during BLLAST.
- (2015). Experimental Meteorology Group at the Geophysical Institute Bergen.
- (2014). Turbulent flux measurements in the Arctic Boundary Layer using the Small Unmanned Meteorological Observer (SUMO).
- (2014). Overview of Best Practices in Mitigating the Impact of Natural Disasters and Extreme Weather Phenomena on European Aviation – The MOWE-IT Project .
- (2014). Observations of summer turbulent surface fluxes in a High Arctic fjord. Quarterly Journal of the Royal Meteorological Society. 666-675.
- (2014). Guidebook for Enhancing Resilience of European Road Transport in Extreme Weather Events . .
- (2014). Guidebook for Enhancing Resilience of European Air Traffic in Extreme Weather Events . .
- (2013). The impact of thunderstorm activity on the European air traffic system .