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1.55µm Pulsed Fiber lidar for wake vortex detection (axial or transverse)
Jean-Pierre Cariou, Olivier Petilon, Julius Lawson-Daku
L. Bricteux , S. Brousmiche, S Lugan, B . Macq
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Advantages of 1.55 µm fiber systems
• Low electrical consumption :• Electrical to optical efficiency of the order of 10%
• Wavelength most favourable for eyesafe LIDAR designs• IR fiber technology reliability
• easy to adjust • mechanically reliable in a vibrating environment• 1.5 µm fiber coherent LIDARs have been successfully in flight operated
• Compactness• Flexibility in terms of onboard installation
• subsystems spatially far apart in the aircraft body• linked together using fiber optics
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Coherent Doppler LIDAR principle
LIDAR
Laser
Interferometer
f L
f S + f D
V R
V air Natural aerosols
Local oscillator
Detector
Laser beam focused on atmospheric aerosols , then :
• reflected by MIE diffusion•frequency shifted by Doppler effect due to relative motion between the aerosols and the Lidar•mixed in an optical interferometer with a reference beam called local oscillator•measured in radiofrequency domain
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Onboard Axial detection : FIDELIO project
Lidar
Lida scan
Lidar
Lida scan
• Feasibility demonstrated in MFLAME and IWAKE Program
•Fidelio purpose : “…developing a unique fibre laser technology (1.5 micron wavelength) geared for the aerospace industry requirements, enabling on-board realisation of a LIDAR atmospheric hazard detection system …”.
•Fidelio partners :•ELOP Industries (IL, coordinator, laser integration), •Thales Avionics (FR, aircraft integration specifications).•ONERA(FR, laser research, lidar development)•IPHT (DE, fiber research and design), •Thales Research and Technology (FR, laser research), •CeramOptec GmbH (DE, fiber packaging)•UCL ( BE, signal processing and display, wake-vortex modeling) ,•INESC Porto (PT, laser research)
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Axial detection FIDELIO modeling
The lidar model takes into account :
•the observation geometry,
•the wake vortex velocity field,
•the scanning pattern,
•the LIDAR instrument,
•the wind turbulence outside the vortex,
•the signal processing.
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FIDELIO modeling
• xx
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FIDELIO : modeling conclusions
• At medium range (>1 km), the vortex is easier to detect by measuring the spectrum broadening. These results confirm the IWAKE conclusions
• Longer pulse duration (800 ns) gives better results than the nominal value of 400ns and leads to a high velocity resolution
• The vortex is easier to detect at old ages than at young ones, since dissipation increases the velocity dispersion on the observation axis.
• Low PRF cannot be compensated by increasing the laser energy. Indeed a high PRF value enables incoherent summation, reducing speckle effect and therefore gives a better velocity resolution.
• For PRF=4 kHz, E=1 mJ, nominal atmospheric conditions: the theoretical LIDAR range is 2400 m.
• For PRF=10 kHz, E=0.1 mJ: the theoretical LIDAR range is 1200 m.
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FIDELIO : laser research results
•Lab result :
•750 µJ , 1 µs, 5 kHz with 4 amplification stages, and a special fiber developed by IPHT (not used in the lidar demonstrator), excellent beam quality ( M2=1.3), fully polarized
Wind velocity dispersion images computed after the passing of two successive aircrafts. Each box represents the 3°x12° field of view image acquired at different ranges (vertical axis) and at different time (horizontal axis).
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FIDELIO :Field tests
3D representation of wake vortex detection on two consecutive scans a few seconds after a B747 landing. Each rectangle corresponds to a range gate. The X axis represents the 12° horizontal field of view , Z axis the 3° vertical field of view and the Y axis the distance of the range gates.
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Axial detection FIDELIO: Conclusions
• FIDELIO project has generated important advances in research and development on fiber laser technology:
• An innovative high brightness pulsed 1.5µm laser source has been built, based on a MOPFA architecture with a large core fiber. The beam quality is excellent (M2=1.3). Achieved pulsed energy is 120µJ with a pulse repetition frequency of 12kHz and a pulse duration of 800ns. With a further amplification stage, 750µJ pulses were obtained in the lab at 5kHz and 1µs with excellent beam quality.
• A Doppler heterodyne LIDAR has been developed based on the 120µJ laser source with a high isolation free space circulator. The LIDAR includes a real time display of the wind field. Wind dispersion is post-processed.
• Field tests were carried out at Orly airport in April 2008. Axial aircraft wake vortex signatures have been successfully observed and acquired at a range of 1.2km with axial resolution of 75m for the first time with fiber laser source.
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Transverse detection
lidar
Scanning angle
lidar
Scanning angle
lidar
Scanning angle
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SWAN lidar set up for CREDOS campaign at Francfort (february –March 2007)
Field tests at Francfort airport CREDOS CAMPAIGN (february –March 2007)
ONERALIDAR
DLRLIDAR
VOLPELIDAR
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SWAN: lidar processing
• Real time signal processing and display:• longitudinal spatial resolution: 2.4 m• lateral spatial resolution: 35 cm@200m(0,1°)• Velocity resolution: < 1 m/s
• High level processing:• core position, velocity profiles, circulation vs time/span
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SWAN : wake vortex signal processing
Lidar heterodyne signal
Fourier transform
Velocity spectrum for a line of sight θi or a range gate
Vortex velocity profil along a diameter
Maximun or minimum velocity extraction for the all scan
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ONERALIDAR
SWAN : REAL TIME display of velocity map
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SWAN : wake vortex signal processing
Lidar heterodyne signal
Fourier transform
Velocity spectrum for a line of sight θi or a range gate
Vortex velocity profil along a diameter
Maximun or minimum velocity extraction for the all scan
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ONERALIDAR
40 50 60 70 80 90
-10
-5
0
5
10
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vite
sse
s (m
/s)
angle(°)
SWAN : Wake vortex spectra analysis
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CREDOS CAMPAIGN Orly/Francfort 2007B744
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Wake vortex transversal measurements (SWAN lidar) Conclusions
• Robust & reliable (trip to Frankfurt without adjustment)
• Real time display of velocity map
• Further works :• Automatic & real time wake vortex signal processing • Down sizing • Unattended operation
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Pulsed 1.5 µm LIDAR for Aircraft Wake-Vortex Detection and Monitoring :
conclusions • Important advances in Fiber laser research generated in FIDELIO
project
• Development and demonstration of a 1.5 µm fiber lidar for onboard axial wake vortex detection .
• Field test at Orly airport : 1.2 km detection with 120µJ ,12kHz , 800ns.
• 750µJ pulses were obtained in the lab at 5kHz and 1µs with excellent beam quality.
• Development and demonstration of a 1.5 µm fiber lidar for transverse wake vortex measurements (SWAN lidar).
• Measurement campaign in Frankfurt for CREDOS project.