Helmut Többen scite author profile

Abstract. Conventional monostatic wind lidar (light detection and ranging) systems are well-established wind speed remote sensing devices in the field of wind energy that provide reliable measurement results for flat terrain and homogeneous wind fields. These conventional wind lidar systems use a common transmitting and receiving unit and become unacceptably inaccurate as the wind fields become increasingly inhomogeneous due to their spatial and temporal averaging procedure (large measurement volume) that is inherent to the monostatic measurement principle. The new three-component fiber laser-based wind lidar sensor developed by the Physikalisch-Technische Bundesanstalt (PTB) uses one transmitting unit (fiber laser) and three receiving units to measure the velocity vector of single aerosols in a spatially highly resolved measurement volume (with diameter d and length l) in heights from 5 m (d=300 µm, l=2 mm) to 250 m (d=14 mm, l=4 m) with a resolution of about 0.1 m s−1. Detailed comparison measurements with a 135 m high wind met mast and a conventional lidar system have proven that the high spatial and temporal resolution of the new, so-called bistatic lidar leads to a reduced measurement uncertainty compared to conventional lidar systems. Furthermore, the comparison demonstrates that the deviation between the bistatic lidar and the wind met mast lies well within the measurement uncertainty of the cup anemometers of the wind met mast for both homogeneous and inhomogeneous wind fields. At PTB, the aim is to use the bistatic wind lidar as a traceable reference standard to calibrate other remote sensing devices, necessitating an in-depth validation of the bistatic lidar system and its measurement uncertainty. To this end, a new, specially designed wind tunnel with a laser Doppler anemometer (LDA) as flow velocity reference has been erected on a platform at a height of 8 m; this allows the new wind lidar to be positioned below the wind tunnel test section to be validated for wind vector measurements that are traceable to the SI units. A first validation measurement within the wind tunnel test section is presented, showing a deviation between the bistatic lidar system and the LDA clearly below 0.1 %.

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Helmut Többen

Optical properties of rare earth-doped ZBLAN glasses

Room temperature cw fibre laser at 3.5 μm in Er ³⁺ -doped ZBLAN glass

Room temperature CW fibre laser at 3.22 µm

Co-doping effects in erbium3+- and holmium3+-doped ZBLAN glasses

Validation of three-component wind lidar sensor for traceable highly resolved wind vector measurements

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Helmut Többen

Optical properties of rare earth-doped ZBLAN glasses

Room temperature cw fibre laser at 3.5 μm in Er 3+ -doped ZBLAN glass

Room temperature CW fibre laser at 3.22 µm

Co-doping effects in erbium3+- and holmium3+-doped ZBLAN glasses

Validation of three-component wind lidar sensor for traceable highly resolved wind vector measurements

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Resources

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Room temperature cw fibre laser at 3.5 μm in Er ³⁺ -doped ZBLAN glass