Boundary layer meteorology: 

• Characterization of the coherence of turbulence above the sea and in Norwegian fjords.
• Influence of the topography on the mean and turbulent flow characteristics.
• Synthetic turbulence generation in the atmospheric surface layer.
• Influence of the blocking by the surface on the spectral characteristics of turbulence.

Wind engineering: 

•  Turbulent wind load modelling on long-span bridges.
• Data-driven modelling for structural dynamics.
• Full-scale vibration analysis.

Lidar remote sensing of wind: 

• Can scanning Doppler wind lidars measure turbulence?.
• Study of the flow around bridges with short-range and long-range wind lidar instruments.

Courses

• SDG310: Introduction: Interdisciplinary Approaches to Sustainable Development (2022-present)
• ENERGI322 Offshore wind energy - part 2 (2022-present)
• ENERGI321 Offshore wind energy - part 1 (2023-present)
• ENERGI210 Wind turbine aerodynamics (2022-2023)
• ENERGI230 Miljø og energi (2023-present)
• ENERGI101: Introduksjon til energikjelder og forbruk (2020)

2025

• Etienne Cheynet (2025). Introduction to turbulence modelling for wind loading on structure. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Etienne Cheynet et al. (2025). Surface pressure measurement system for investigating bridge aerodynamics. (external link)
• Shokoufeh Malekmohammadi; Etienne Cheynet; Joachim Reuder (2025). High-resolution wind lidar observation of Kelvin-Helmholtz billows above an offshore wind farm. (external link)
• Lennart Vogt; Jasna Bogunovic Jakobsen; Etienne Cheynet et al. (2025). Stable boundary layer wind profiles – A comparison of analytical models and lidar observations. (external link)
• Shokoufeh Malekmohammadi; Etienne Cheynet; Joachim Reuder (2025). Observation of Kelvin–Helmholtz billows in the marine atmospheric boundary layer by a ship-borne Doppler wind lidar. (external link)
• Etienne Cheynet (2025). ERA5 for wind ressource assessment: an introduction. (external link)
• Etienne Cheynet (2025). Hva er veien videre for Norsk Havvind? Strømproduksjon fra havvind parker utenfor Vestlandet. (external link)
• Bendik Voldseth; Etienne Cheynet; Joachim Reuder (2025). Science to Insurance: Improved Extreme Wind Estimates for Offshore Wind Assets. (external link)
• Mauro Ghirardelli; Stephan Thomas Kral; Etienne Cheynet et al. (2025). SAMURAI-S: Sonic Anemometer on a MUlti-Rotor drone for Atmospheric turbulence Investigation in a Sling load configuration. (external link)
• Etienne Cheynet; Jan Markus Diezel; Hilde Haakenstad et al. (2025). Tall wind profile validation of ERA5, NORA3, and NEWA datasets using lidar observations. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2025). Wind turbulence around a bridge deck in full scale. (external link)
• Ghirardelli Mauro; Stephan Thomas Kral; Etienne Cheynet et al. (2025). SAMURAI-S: Sonic Anemometer on a MUlti-Rotor drone for Atmospheric turbulence Investigation in a Sling load configuration. (external link)
• Huize Chen; Xiaomo Jiang; Huaiyu Hui et al. (2025). Enhancing probabilistic wind speed forecasting by integrating self-adaptive Bayesian wavelet denoising with deep Gaussian process regression under uncertainties. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2025). Field Observations of Buffeting Loads on a Suspension Bridge Girder. (external link)
• Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson; Etienne Cheynet et al. (2025). Field observations of bridge deck aerodynamics. (external link)
• Lennart Vogt; Jasna Bogunovic Jakobsen; Etienne Cheynet et al. (2025). Stable boundary layer wind profiles – A comparison of analytical models and lidar observations. (external link)
• Rebeca Marini; Konstantinos Vratsinis; Pieter-Jan Daems et al. (2025). An assessment of the metocean conditions in the Belgian offshore zone. (external link)
• Yuanchen Wan; Etienne Cheynet; Yan Li et al. (2025). Wind conditions monitoring for solar collector array design: the case of Nevada Solar One. (external link)

2021

• Etienne Cheynet; Martin Flügge; Joachim Reuder et al. (2021). The COTUR project: Remote sensing of offshore turbulence for wind energy application. (external link)
• Etienne Cheynet; Martin Flügge; Joachim Reuder et al. (2021). Preliminary results of the COTUR project. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2021). Full-scale observations of bridge stay cable vibrations in a wet state. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2021). Observations of the turbulent near wake of a bridge deck. (external link)
• Mohammad Nafisifard; Jasna Bogunovic Jakobsen; Etienne Cheynet et al. (2021). Dual lidar wind measurements along an upstream horizontal line perpendicular to a suspension bridge. (external link)
• Joachim Reuder; Mauro Ghirardelli; Stephan Thomas Kral et al. (2021). SUMO and SAMURAI – GFI/UiB drones for wind energy reserach. (external link)
• Etienne Cheynet (2021). Wind-induced response of a 5 MW offshore wind turbine. (external link)
• Etienne Cheynet (2021). Structural monitoring of a 5MW offshore wind turbine. (external link)
• Mohammad Nafisifard; Jasna Bogunovic Jakobsen; Etienne Cheynet et al. (2021). Observations of incoming turbulent flow by dual wind lidar mounted on a bridge deck. (external link)
• Aoudou Midjiyawa Zakari; Etienne Cheynet; Joachim Reuder et al. (2021). Potential and challenges of wind measurements using met-masts in complex topography for bridge design: Part II – Spectral flow characteristics. (external link)
• Joachim Reuder; Etienne Cheynet; Andrew Clifton et al. (2021). Recommendation on use of wind lidars. (external link)
• Aoudou Midjiyawa Zakari; Etienne Cheynet; Heinrich Joachim Reuder et al. (2021). Potential and challenges of wind measurements using met-masts in complex topography for bridge design: Part I - Integral flow characteristics. (external link)
• Etienne Cheynet (2021). Structural monitoring of OWTs for predictive maintenance. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjørnsson et al. (2021). Observations of bridge stay cable vibrations in dry and wet conditions: A case study. (external link)
• Ibuki Kusano; Etienne Cheynet; Jasna Bogunovic Jakobsen et al. (2021). Aerodynamic study of a suspension bridge deck by CFD simulations, wind tunnel tests and full-scale observations. (external link)

2017

• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2017). Assessing the potential of a commercial pulsed lidar for wind characterisation at a bridge site. (external link)
• Jungao Wang; Jonas Thor Snæbjörnsson; Jasna Bogunovic Jakobsen et al. (2017). Coupled Aerodynamic and Hydrodynamic Response of a Long Span Bridge Suspended from Floating Towers. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2017). Full-scale observation of the flow downstream of a suspension bridge deck. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2017). Measurements of Surface-Layer Turbulence in a Wide Norwegian Fjord Using Synchronized Long-Range Doppler Wind Lidars. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2017). Damping estimation of large wind-sensitive structures. (external link)
• Jungao Wang; Etienne Cheynet; Jasna Bogunovic Jakobsen et al. (2017). Time-Domain Analysis of Wind-Induced Response of a Suspension Bridge in Comparison With the Full-Scale Measurements. (external link)
• Jonas Thor Snæbjörnsson; Jasna Bogunovic Jakobsen; Etienne Cheynet et al. (2017). Full-scale monitoring of wind and suspension bridge response. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2017). Wind turbulence measurements above the sea in an open fjord inlet using long-range synchronized lidars. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Charlotte Obhrai (2017). Spectral characteristics of surface-layer turbulence in the North Sea. (external link)
• Etienne Cheynet (2017). Spectral characteristics of offshore wind turbulence. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2017). Measurement of the wind coherence with synchronized long-range Doppler wind lidars. (external link)
• Etienne Cheynet; Jonas Thor Snæbjörnsson; Jasna Bogunovic Jakobsen (2017). Temperature effects on the modal properties of a suspension bridge. (external link)

2024

• Nicolo Daniotti; Jonas Thor Snæbjörnsson; Jasna Bogunovic Jakobsen et al. (2024). Vortex shedding in the wake of a fullscale bridge deck. (external link)
• Eirik Finserås; Ignacio Herrera Anchustegui; Etienne Cheynet et al. (2024). Gone with the wind? Wind farm-induced wakes and regulatory gaps. (external link)
• Hedda Wallestad; Etienne Cheynet; Astrid Nybø et al. (2024). Wind farm layout assessment in Sørlige Nordsjø II using the FLORIS framework and NORA3 dataset,. (external link)
• Etienne Cheynet (2024). Energy variability: the case of wind energy. (external link)
• Etienne Cheynet; Lin Li; Zhiyu Jiang (2024). Metocean conditions at two Norwegian sites for development of offshore wind farms. (external link)
• Elias Villamil Fernandez; Etienne Cheynet; Ida Marie Solbrekke (2024). Evaluating the Offshore Wind Areas Suitability for Sustainable Energy Development in Norway: A Comparative Analysis. (external link)
• Alexander Arvid Flem; Mauro Ghirardelli; Stephan Thomas Kral et al. (2024). Experimental Characterization of Propeller-Induced Flow (PIF) below a Multi-Rotor UAV. (external link)
• Mali Ones; Etienne Cheynet; Joachim Reuder (2024). Extending Turbulence Measurements to 300m: Aiming to Retrieve All Wind Components from Vertical Velocity. (external link)
• Etienne Cheynet (2024). Wind turbines and wind farms wakes. (external link)
• Etienne Cheynet (2024). Wind Resource Assessment: Case Study. (external link)
• Shauna Creane; Pedro Santos; Konstanze Kölle et al. (2024). IEA Wind Task 49: Reference Site Conditions for Floating Wind Arrays. (external link)

2015

• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2015). Full scale monitoring of wind and traffic induced response of a suspension bridge. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2015). Buffeting response of a bridge at the inlet of a fjord. (external link)
• Jasna Bogunovic Jakobsen; Etienne Cheynet; Jonas Thor Snæbjörnsson et al. (2015). Assessment of wind conditions at a fjord inlet by complementary use of sonic anemometers and lidars. (external link)
• Jasna Bogunovic Jakobsen; Etienne Cheynet; Jonas Thor Snæbjørnsson et al. (2015). Application of lidars for assessment of wind conditions on a bridge site. (external link)
• Jasna Bogunovic Jakobsen; Etienne Cheynet; Jonas Thor Snæbjörnsson et al. (2015). Assessment of wind conditions at a fjord inlet by complementary use of sonic anemometers and lidars. (external link)
• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2015). Buffeting response of a bridge at the inlet of a fjord. (external link)
• Jasna Bogunovic Jakobsen; Etienne Cheynet; Jonas Thor Snæbjørnsson et al. (2015). Application of lidars for assessment of wind conditions on a bridge site. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2015). Full scale monitoring of wind and traffic induced response of a suspension bridge. (external link)

2020

• Etienne Cheynet; Martin Flügge; Joachim Reuder et al. (2020). Preliminary results of the COTUR project. (external link)
• Etienne Cheynet; Nicolo Daniotti; Jasna Bogunovic Jakobsen et al. (2020). Improved long-span bridge modeling using data-driven identification of vehicle-induced vibrations. (external link)
• Etienne Cheynet; Shengnan Liu; Muk Chen Ong et al. (2020). The influence of terrain on the mean wind flow characteristics in a fjord. (external link)
• Etienne Cheynet (2020). Offshore wind potential in Norway and the North Sea. (external link)
• Etienne Cheynet (2020). Panel discussion: “New Challenges in Wind-Structure interaction”. (external link)
• Martin Flügge; Etienne Cheynet; Yngve Heggelund et al. (2020). The COTUR project: Remote sensing of offshore turbulence for wind energy application. (external link)

2016

• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2016). Wind-induced vibrations monitoring with satellite navigation. (external link)
• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2016). Full-scale observation of the flow downstream of a suspension bridge deck. (external link)
• Jonas Thor Snæbjörnsson; Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen (2016). Performance evaluation of a suspension bridge excited by wind and traffic induced action. (external link)
• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2016). Buffeting response of a suspension bridge in complex terrain. (external link)
• Etienne Cheynet; Jasna Bounovic Jakobsen (2016). Wind-induced vibrations of a suspension bridge: A case study in full-scale. (external link)
• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2016). Application of short-range dual-Doppler lidars to evaluate the coherence of turbulence. (external link)
• Etienne Francois Cyprien Cheynet; Jasna Bogunovic Jakobsen; Benny Svardal et al. (2016). Wind Coherence Measurement by a Single Pulsed Doppler Wind Lidar. (external link)

2019

• Joachim Reuder; Martin Flügge; Yngve Heggelund et al. (2019). The COTUR campaign - measuring offshore turbulence and coherence With lidars. (external link)
• Etienne Cheynet (2019). Influence of the Measurement Height on the Vertical Coherence of Natural Wind. (external link)
• Nicolo Daniotti; Etienne Cheynet; Jasna Bogunovic Jakobsen et al. (2019). Analysing wind-induced vibrations of a suspension bridge using GNSS data. (external link)
• Etienne Cheynet; Jonas Thor Snæbjörnsson; Jasna Bogunovic Jakobsen (2019). Identifying Traffic-Induced Vibrations of a Suspension Bridge: A Modelling Approach Based on Full-Scale Data. (external link)
• Nicolo Daniotti; Etienne Cheynet; Jasna Bogunovic Jakobsen et al. (2019). Damping Estimation from Full-Scale Traffic-Induced Vibrations of a Suspension Bridge. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2019). Flow Distortion Recorded by Sonic Anemometers on a Long-Span Bridge. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2019). Flow distortion recorded by sonic anemometers on a long-span bridge: Towards a better modelling of the dynamic wind load in full-scale. (external link)
• Etienne Cheynet; Shengnan Liu; Muk Chen Ong et al. (2019). Influence of the local terrain on the mean flow characteristics in a fjord. (external link)
• Martin Flügge; Yngve Heggelund; Joachim Reuder et al. (2019). COTUR - Estimating coherence and turbulence with LIDARs. (external link)
• Joachim Reuder; Martin Flügge; Etienne Cheynet et al. (2019). The COTUR campaign - measuring offshore turbulence and coherence with lidars. (external link)

2023

• Etienne Cheynet (2023). Wind turbines and wind farm characteristics. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2023). A study of bridge deck aerodynamics through full-scale surface pressure measurements. (external link)
• Ignacio Herrera Anchustegui; Etienne Cheynet (2023). Gone with the wind? Wind farm-induced wakes and regulatory gaps. (external link)
• Mauro Ghirardelli; Stephan Thomas Kral; Nicolas Carlo Müller et al. (2023). Flow Structure around a Multicopter Drone: A Computational Fluid Dynamics Analysis for Sensor Placement Considerations. (external link)

2018

• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2018). Complementary use of wind lidars and land-based met-masts for wind measurements in a wide fjord. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Joachim Reuder (2018). Velocity spectra and coherence estimates in the marine atmospheric boundary layer. (external link)
• Jungao Wang; Etienne Cheynet; Jonas Thor Snæbjörnsson et al. (2018). Coupled aerodynamic and hydrodynamic response of a long span bridge suspended from floating towers. (external link)
• Yngve Heggelund; Martin Flügge; Jasna Bogunovic Jacobsen et al. (2018). COTUR Measuring coherence and turbulence with lidars. (external link)
• Etienne Cheynet; Hálfdán Ágústsson; Knut Harstveit (2018). Complementary use of wind lidars and land-based met-masts for wind characterization in a wide fjord. (external link)
• Etienne Cheynet (2018). Hvordan kan vi se vinden i en fjord?. (external link)

2014

• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2014). Wind characteristics on a suspension bridge at the inlet of a fjord. (external link)
• Etienne Cheynet; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson (2014). Wind-induced response of a bridge at the inlet of a fjord. (external link)

2022

• Rieska Mawarni Putri; Etienne Cheynet; Charlotte Obhrai et al. (2022). Turbulence in a coastal environment: the case of Vindeby. (external link)
• Etienne Cheynet (2022). Non-neutral Coherence of turbulence during the COTUR campaign. (external link)
• Nicolo Daniotti; Jasna Bogunovic Jakobsen; Jonas Thor Snæbjörnsson et al. (2022). Full-scale measurements of wind-induced surface pressures on a bridge deck. (external link)
• Etienne Cheynet; Ida Marie Solbrekke; Jan Markus Diezel et al. (2022). A one-year comparison of new wind atlases over the North Sea. (external link)
• Joachim Reuder; Etienne Cheynet (2022). Offshore Wind Ressources. (external link)
• Etienne Cheynet; Ida Marie Solbrekke; Jan Markus Diezel et al. (2022). A one-year comparison of new wind atlases over the North Sea. (external link)
• Etienne Cheynet; Lin Li; Zhiyu Jiang (2022). Metocean Conditions at Two Norwegian Sites for Development of Offshore Wind Farms. (external link)
• Etienne Cheynet (2022). COTUR workshop: Non-neutral Coherence of turbulence during the COTUR campaign. (external link)
• Etienne Cheynet; Nicolo Daniotti; Jasna Bogunovic Jakobsen et al. (2022). Unfrozen skewed turbulence for wind loading on structures. (external link)

2012

• Bernd Schmid; Etienne Cheynet (2012). Wear properties of coatings for wind turbine blades. (external link)

See a complete overview of publications in Cristin.

BEL-FLOAT (2023-2026): The BEL-Float project focuses on developing Belgium's expertise in floating wind technology through academic innovation. The project aims to prepare new researchers with the necessary skills for floating wind energy and to strengthen the Belgian-Norwegian partnership in offshore wind.

ImpactWind SouthWest (2022-2027): ImpactWind SouthWest is a project led by NORCE, aiming to transform offshore wind development through collaboration, an open database, a research program, and educational initiatives. It aims to make the licensing process for Norwegian offshore wind faster, contributing to sustainable energy and job creation in Norway

 

LOWT (2021-2025): Large Offshore Wind Turbines (LOWT):structural design accounting for non-neutral wind conditions

This project will develop new knowledge and models to improve the design basis for large floating wind turbines (LOWT)(>12MW) in freewind and wake conditions. Observations from Hywind Scotland have shown the thermal stratification of the atmosphere can substantially affect the structural response of a wind turbine to the incoming turbulent flow. The first objective is to use wind data from several offshore sites to characterise the wind field in non-neutral atmospheric conditions. The project will use high-frequency wind data combined with a brand new remote sensing dataset (COTUR). In the COTUR campaign the incoming flow over the ocean was recorded, both within and above the surface layer, thus providing new insight on the applicability surface-layer scaling to model the turbulent wind loads on LOWT. This unique dataset will be analysed for the first time to the to indicate whether the turbulence models used in the standards, which mainly relies on surface-layer scaling, are appropriate or not. The final output will be to recommend suitable wind and coherence model for in non-neutral conditions as input to free wind aeroelastic simulations and DWM models offshore. The second objective is to validate the simulated wind turbine response using full scale data from offshore wind farms (Alpha Ventus, Sheringham Shoal, and Zefyros/Hywind Demo). The validated simulation tools will then be used to quantify the effect of non-neutral atmospheric conditions on future LOWT (>12MW) to ensure safe and cost-effective design in the next generation of offshore wind farms in Norway and beyond. The final focus of the project is wake simulations of LOWT in non-neutral conditions using DWM model. High-fidelity CFD simulations will be used to include variable velocity shear in the DWM method and validate the wake meandering in non-neutral conditions. The non-neutral wind spectra and coherence from the data analysis work will be used as input for the DWM simulations.

 

COTUR (2018-2020): Measuring coherence and turbulence with lidars (COTUR)

The size of offshore wind turbines has increased significantly since the installation of the world’s first commercial offshore wind turbine at Vindeby in 1991. The average offshore wind turbine capacity has increased from 500 kW in the 1990s to 3 MW by the end of 2010. Today, the largest offshore wind turbines have a rated power of 9 MW and a rotor diameter of 164 meters. Large, floating wind turbines pose new challenges compared to bottom-fixed turbines. In particular, the Hywind Scotland wind farm posed new challenges with respect to turbulence and coherence. There is a need for a better understanding of the horizontal coherence over large rotors offshore, but few measurements are available for such analyses. The main objective of the project is to improve the understanding of offshore wind coherence through measurements with lidars. The measurements will form a new, unique and highly relevant dataset for future offshore wind research. The collected data and corresponding meta-data will be stored in a database for later analysis.