NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014 Airborne Water Vapor Science, Radiometer Requirements, and Capabilities Professor Albin J. Gasiewski University of Colorado NOAA-CU Center for Environmental Technology (CET) [email protected]303-492-9688
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NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Airborne Water Vapor Science, Radiometer Requirements,
and Capabilities
Professor Albin J. GasiewskiUniversity of Colorado
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Key Points• Airborne radiometric profiling of water vapor requires:
– At least one (183 GHz) and up to four key direct-sensing H2Ovbands, and
– At least one (50-57 or 118 GHz) and up to three key O2 bands for temperature profiling
– At least one (90 GHz) and up to five window bands for cloud/precipitation sensing and correction
• Retrieval methods and achievable vertical resolutions in clear air are well established. – Improvements are yet possible using hyperspectral channel sets
and by improving stability and calibration precision.
• Systems for the above require moderately large apertures and correspondingly heavy aircraft or large bays. Such systems (e.g. PSR) are mature. – Lighter aircraft or w/o large bays would benefit from compact
integrated systems (e.g. PRACO).
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Clear-Air Opacity SpectrumKey tropospheric water vapor (H2Ov) and temperature (O2) bands
Klein & Gasiewski, JGR-ATM, July 2000
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Vertical Responses- Clear Air -
Klein & Gasiewski, JGR-ATM, July 2000
Clear-air incemental weighting functions
O2118.750 GHz424.763 GHz
H2O 183.310 GHz380.197/340
118.75-GHz Temperature Profiling
* Gasiewski and Johnson, TGARS, 1993
118.75±0.5 GHz
118.75±1.9 GHz
Some improvement possible in: - Use of hyperspectral channel sets- Receiver stability/calibration
MTS 7-channel airborne instrument
6
Nonlinear Iterative Humidity ProfilingNOAA 183 GHz MSU Data
*Kuo and Staelin, TGARS, 1994
A priori STDLinear D-matrixNonlinear Iterative
Pres
sure
(mB
)
Relative Humidity RMS Error (%)
Some improvement possible in: - Use of larger channelsets (7x 183 GHz channels)
- Receiver stability/calibration- Neural net algorithms
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Effects of Hydrometeors on Microwave Signatures
Scattering and absorption by hydrometeors need to beconsidered for radiometric water vapor or temperatureprofile measurements:
LiquidIce
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College Park, MDNovember 14, 2012JCSDA Seminar
Beijing, ChinaOctober 12, 2012National Space Science Center
52.6-53.0GHz
183.31 ± 1.8GHz
118.75 ± 2.05GHz
424.76 ± 3.25GHz
45 km 45 km 45 km 45 km 45 km
NAST-M Convective Cells Observed from 20 km altitude over ocean
V. Leslie
Aircraft data tells us:The 50-GHz band responds only to very strong convection in cell centers; partial beamfilling yields weak/no response.
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
55 GHz 89 GHz 183 GHz
CET spectrometer modules with internal fast-switched absolute calibration. Above spectrometers (plus two more underdevelopment) provide full AMSU-A/B andNPOESS CMIS and ATMS troposphericsounding compatibility.
CU CET Passive Microwave Vertical Sounder
Microwave sounders as installed in PSR/S airborne radiometer sensor head
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Airborne Imaging Radiometry
10.7 GHz37.0 GHz
89.0 GHz
18.7 GHz21.5 GHz
6.7 GHz10.7 GHz
Video10 m IR
PSR installs on NASA DC-8, P-3B, WB-57F, ER-2, Altair, Navy P-3C, NRL P-3.
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Topic…
Altair Integrated Package
First UAV-based passive microwave vertical sounding sensor
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Atmospheric River Sounding- Weak Atm River Penetrated on May 9, 2005 -
A
89 GHz
183 GHz
55 GHz
10 um IR
B
C
D
A B C D50 K
Julian dayComparison of Precipitable Water Vapor Retrievals from the ARM MWR, the CET GSR,
and Vaisala RS92 radiosondes launched during RHUBC on Julian Day 65, 2007.
GSR
MWR
RS92
PWV
(cm
)
RHUBC 2007 – Barrow, AK- PSR/S Ground Based -
(Westwater, et al.)
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
TRMM Calibration/Validation
10.7 & 37 GHz
18.7 &21.6 GHz
89 GHz
Video
10.7H GHz emission-basedrain rate retrieval algorithmData from CAMEX-3, DC-8 overflights of Hurricane Bonnie
TMI R
R (m
m/h
r…0-
16)
PSR RR (mm/hr…0-16)
ρ~0.91
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
High-Resolution MCS and Hurricane Rainband Imaging
PSR/A 10.7H GHz Rain Rate vs TRMM TMI (2A12)Front Look Back Look
RR
(mm
/hr…
0-16
)
CAMEX3 - Hurricane Bonnie near landfall, August 26, 1998
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Hurricane Bonnie at LandfallAirborne Microwave Imagery
PSR/A 10.7H GHz imagery from aircraft overpasses of hurricane Bonnie at 1400-1425 GMT(August 26, 1998).
High-resolution airborne imagery clearly reveals - over a limited region -many submesoscale details of rainband precipitation structure absent in satellite imagery.
during two crossings of a cold cyclone centered in the Labrador Sea.
Retrieved wind vectors are overlaid onto PSR
and SSM/I 37H GHz imagery. Blue arrows
are wind data from the NOAA/NCEP Eta
analysis, dropsondes are orange arrows.
Tight cyclonic rotation of the retrieved and model wind fields
about the center of rotation is revealed.
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014
Summary• Airborne radiometric profiling of water vapor requires:
– At least one (183 GHz) and up to four key direct-sensing H2Ovbands, and
– At least one (50-57 or 118 GHz) and up to three key O2 bands for temperature profiling
– At least one (90 GHz) and up to five window bands for cloud/precipitation sensing and correction
• Retrieval methods and achievable vertical resolutions in clear air are well established. – Improvements are yet possible using hyperspectral channel sets
and by improving stability and calibration precision.
• Systems for the above require moderately large apertures and correspondingly heavy aircraft or large bays. Such systems (e.g. PSR) are mature. – Lighter aircraft or w/o large bays would benefit from compact
integrated systems (e.g. PRACO).
NCAR Boulder CO Airborne Radiometry Workshop September 23-24, 2014