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Doppler Wind Lidar

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Title: Doppler Wind Lidar


1
Doppler Wind Lidar Measurement Principles
Bruce Gentry NASA / Goddard Space Flight
Center based on a presentation made to the
Global Tropospheric Wind Sounder
Workshop Greenbelt, MD February 26, 2001
2
Doppler Lidar Measurement Concept
  • DOPPLER RECEIVER - Multiple possibilities
  • Coherent heterodyne (e.g.
    SPARCLE/MSFC)
  • Direct detection Double Edge (e.g.
    Zephyr/GSFC)
  • Direct detection Fringe Imaging (e.g. Michigan
    Aerospace Corp.)

3
Doppler Lidar Profiling Geometry
z0 Orbital altitude (km) z Sample altitude
(km) ?zVertical resolution (km)
R Range to sample volume (km) c speed of light
(km/s) t time of flight of pulse (s) ?RRange
resolution (km) ?t integration interval (s) ?
Nadir angle (deg)
vs Spacecraft velocity (km/s) LRLaser rep
rate(Hz) ?xLaser spot separation (km)
4
A Satellite DWL Coverage Scheme with 4 Lines-of
Sight (2 fore, 2 aft)
Fore Aft
283 km
400 km
Swath width 566 km
5
Doppler Lidar Receivers
  • Coherent or heterodyne detection
  • Proposed for eyesafe operation at 9.6 microns
    and
  • and 2 microns using aerosol backscattered signal
  • Direct or non-coherent detection
  • Proposed for eyesafe operation at 355 nm using
    molecular
  • or aerosol backscattered signal
  • Fringe imaging approach
  • Edge filter technique

6
What Is Coherent Lidar?
  • Coherent (heterodyne) detection of weak signal
    with a strong, stable reference laser (local
    oscillator) increases SNR to approach theoretical
    best performance and rejects background light
  • Frequency of beat signal is proportional to the
    target velocity - truly a direct measurement of
    velocity
  • Translation of optical frequency to radio
    frequency allows signal processing with mature
    and flexible electronics and software, and
    reduces 1/f noise
  • Extremely narrow bandpass filter using
    electronics or software rejects even more noise

Courtesy M. Kavaya, MSFC
7
Coherent Doppler Lidar
  • High photon efficiency
  • Insensitive to solar background light
  • Measured signal is RF beat frequency of
    atmospheric signal and local oscillator
  • Requires aerosol backscatter (no molecular
    version)

? Simplified heterodyne receiver. The incoming
signal is mixed with a very stable local
oscillator (LO) ...
? to produce a beat frequency proportional
to Doppler shift
8
Examples of Coherent Doppler Wind Lidar Data
NASA/MSFC
NOAA/ETL
9
Direct Detection Doppler Lidar
  • Measured signal is proportional to intensity
  • High resolution optical filter used to measure
    Doppler shift
  • Draws on technology used with other space lidars
    (MOLA, GLAS, VCL, Picasso)
  • Well developed solid state lasers
  • Large aperture light bucket telescopes
  • Photon counting detectors
  • Shot averaging to increase S/N
  • Utilizes aerosol or molecular backscatter
  • Molecular provides clear air winds in free
    troposphere/over oceans
  • 2 primary implementations Double Edge and
    Fringe Imaging

10
Fringe Imaging Doppler Receiver Concept
1. Incoming light is imaged through the FP
etalon onto a CCD array 2. Doppler frequency
shift is proportional to the change in the
radius of the etalon fringe
??Dop ?out-?return
Several methods have been proposed to map the
circular fringes to the rectangular CCD
11
Double Edge Measurement Concept
1. Incoming light is collimated, split into 2
channels and sent through the FP etalon.
The light in each channel is focussed to a photon
counting detector giving signals I1 and I2.
2. The Doppler frequency shift is proportional
to the change in the ratio of the measured
signals I1/I2 which varies as the laser
wavelength moves up and down on the steep
edge of the filters.
?
?out ? ( I1/I2)out
?return ? ( I1/I2)return
Incoming signal
??Dop ?out-?return
Aerosol Channel at 1064 nm
Molecular Channel at 355 nm
12
GLOW- Goddard Lidar Observatory for Winds
  • Demonstrates system level performance for
    validation of
  • instrument models and verification of
    algorithms
  • Field testbed for demonstration of new component
    technologies
  • Provides unique capability to profile
    tropospheric winds
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