Presentation is loading. Please wait.

Presentation is loading. Please wait.

Passive Microwave Rain Rate Remote Sensing Christopher D. Elvidge, Ph.D. NOAA-NESDIS National Geophysical Data Center E/GC2 325 Broadway, Boulder, Colorado.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Passive Microwave Rain Rate Remote Sensing Christopher D. Elvidge, Ph.D. NOAA-NESDIS National Geophysical Data Center E/GC2 325 Broadway, Boulder, Colorado."— Presentation transcript:

1 Passive Microwave Rain Rate Remote Sensing Christopher D. Elvidge, Ph.D. NOAA-NESDIS National Geophysical Data Center E/GC2 325 Broadway, Boulder, Colorado 80305 USA Tel. 1-303-497-6121 Fax. 1-303-497-6513 Email: chris.elvidge@noaa.gov http://dmsp.ngdc.noaa.gov/ http://sabr.ngdc.noaa.gov/ chris.elvidge@noaa.gov http://dmsp.ngdc.noaa.gov/ http://sabr.ngdc.noaa.gov/chris.elvidge@noaa.gov http://dmsp.ngdc.noaa.gov/ http://sabr.ngdc.noaa.gov/

2 Outline Why do we need microwave sensors? Why do we need microwave sensors? Evolution of passive microwave sensor Evolution of passive microwave sensor –History –Future Rain rate retrieval Rain rate retrieval –Physical bases –Algorithm performance Examples Examples Application to disaster warning Application to disaster warning

3 Microwave Remote Sensing from Space Penetration through non- precipitating clouds. Penetration through non- precipitating clouds. Highly stable instrument calibration. Highly stable instrument calibration. Radiance is linearly related to temperature (i.e. the retrieval is nearly linear). Radiance is linearly related to temperature (i.e. the retrieval is nearly linear). O 2 is uniformly mixed gas throughout the atmosphere. O 2 is uniformly mixed gas throughout the atmosphere. Larger field of views (10-50 km) compared to vis/IR. Larger field of views (10-50 km) compared to vis/IR. Variable emissivity over land. Variable emissivity over land. Polar orbiting satellites provide discontinuous temporal coverage. Polar orbiting satellites provide discontinuous temporal coverage. AdvantagesDisadvantages

4 Why do We Need Observations in Lower Troposphere? Convective events in well mixed layer during daytime heating The planetary boundary layer contains the Fog and low clouds under nocturnal inversion Layer of air containing the roots of summertime convection Depth of cold air in winter to tops of stratocumulus Low-level jet for weather

5 History and Future of Passive Microwave Earth Observation NASA 1970-1987 Nimbus satellite ESMR-1, ESMR-2, SMMR NASA 1970-1987 Nimbus satellite ESMR-1, ESMR-2, SMMR NOAA 1978-1999 POES MSU, 1999-present POES AMSU NOAA 1978-1999 POES MSU, 1999-present POES AMSU DMSP 1982-present SSM/T 1987-present SSM/I, 1991- present SSM/T2, 2004-2015? SSMIS DMSP 1982-present SSM/T 1987-present SSM/I, 1991- present SSM/T2, 2004-2015? SSMIS NASDA 1997-present TRMM TMI & PR, 2002-present Aqua AMSR, 2003-present ADEOS-2 AMSR NASDA 1997-present TRMM TMI & PR, 2002-present Aqua AMSR, 2003-present ADEOS-2 AMSR NPOESS 2007-2030? CMIS NPOESS 2007-2030? CMIS

6 DMSP SSM/I Sensor Flown on DMSP F8 - F15 It is a conical scan sensor. Abbreviation Frequency (GHz) Resolution (km) 19V19.3570x45 19H19.3570x45 22V22.23560x40 37V37.038x30 37H37.038x30 85V85.516x14 85H85.516x14

7 NOAA AMSU Sensor Flown on NOAA-15 (May 1998) and NOAA-16 (Sept. 2000) satellites Contains 20 channels: AMSU-A 15 channels 23 – 89 GHz AMSU-B 5 channels 89 – 183 GHz 6-hour temporal sampling: 130, 730, 1330, 1930 LST

8 AMSU-A and –B Scan Pattern Cross-track scan geometry AMSU-A (30 FOV/scan; 48 km @ nadir) AMSU-B (90 FOV/scan; 16 km @ nadir) 2200 km swath width

9 Precipitation Monitoring Tornadic Storm on Sept 24 2001 AMSU NEXTRAD

10

11 AMSR image of Typhoon 6 June 17, 2003

12

13 Conclusion Passive microwave remote sensing has a unique capability to detect rain and estimate rain rates from orbit. Passive microwave remote sensing has a unique capability to detect rain and estimate rain rates from orbit. This complements ground based weather radar and precipitation measurements. This complements ground based weather radar and precipitation measurements. Algorithms work over water, may extend to land with more advanced sensors. Algorithms work over water, may extend to land with more advanced sensors. Satellite data from multiple systems can be used to get greater integration time, provide a more complete depiction of rain rate through the day and prediction of severe rain events. Satellite data from multiple systems can be used to get greater integration time, provide a more complete depiction of rain rate through the day and prediction of severe rain events.

Download ppt "Passive Microwave Rain Rate Remote Sensing Christopher D. Elvidge, Ph.D. NOAA-NESDIS National Geophysical Data Center E/GC2 325 Broadway, Boulder, Colorado."

Similar presentations

A Microwave Retrieval Algorithm of Above-Cloud Electric Fields Michael J. Peterson The University of Utah Chuntao Liu Texas A & M University – Corpus Christi.

A Microwave Retrieval Algorithm of Above-Cloud Electric Fields Michael J. Peterson The University of Utah Chuntao Liu Texas A & M University – Corpus Christi.
TRMM Tropical Rainfall Measurement (Mission). Why TRMM? n Tropical Rainfall Measuring Mission (TRMM) is a joint US-Japan study initiated in 1997 to study.

TRMM Tropical Rainfall Measurement (Mission). Why TRMM? n Tropical Rainfall Measuring Mission (TRMM) is a joint US-Japan study initiated in 1997 to study.
The Global Precipitation Climatology Project – Accomplishments and future outlook Arnold Gruber Director of the GPCP NOAA NESDIS IPWG 23-27 September 2002,

The Global Precipitation Climatology Project – Accomplishments and future outlook Arnold Gruber Director of the GPCP NOAA NESDIS IPWG September 2002,
REMOTE SENSİNG APLICATIONS IN RAİN REMOTE SENSİNG APLICATIONS IN RAİN MEHMET SUR 110020219 MEHMET SUR 110020219.

REMOTE SENSİNG APLICATIONS IN RAİN REMOTE SENSİNG APLICATIONS IN RAİN MEHMET SUR MEHMET SUR
TRMM/TMI Michael Blecha EECS 823.  TMI : TRMM Microwave Imager  PR: Precipitation Radar  VIRS: Visible and Infrared Sensor  CERES: Cloud and Earth.

TRMM/TMI Michael Blecha EECS 823.  TMI : TRMM Microwave Imager  PR: Precipitation Radar  VIRS: Visible and Infrared Sensor  CERES: Cloud and Earth.
ATS 351 Lecture 8 Satellites

ATS 351 Lecture 8 Satellites
Using Scatterometers and Radiometers to Estimate Ocean Wind Speeds and Latent Heat Flux Presented by: Brad Matichak April 30, 2008 Based on an article.

Using Scatterometers and Radiometers to Estimate Ocean Wind Speeds and Latent Heat Flux Presented by: Brad Matichak April 30, 2008 Based on an article.
CIRA & NOAA/NESDIS/RAMM GOES/POES Status, Orbits, and Products Dr. Bernie Connell CIRA/NOAA-RAMMT March 2005.

CIRA & NOAA/NESDIS/RAMM GOES/POES Status, Orbits, and Products Dr. Bernie Connell CIRA/NOAA-RAMMT March 2005.
Monitoring the Arctic and Antarctic By: Amanda Kamenitz.

Monitoring the Arctic and Antarctic By: Amanda Kamenitz.
March 24, 2010San Jose State University Measuring Precipitation from Space  Past, Present, and Future Jian-Jian Wang University of Maryland Baltimore.

March 24, 2010San Jose State University Measuring Precipitation from Space  Past, Present, and Future Jian-Jian Wang University of Maryland Baltimore.
Applications of Remote Sensing: The Cryosphere (Snow & Ice) Menglin Jin, San Jose Stte University Outline  Physical principles  International satellite.

Applications of Remote Sensing: The Cryosphere (Snow & Ice) Menglin Jin, San Jose Stte University Outline  Physical principles  International satellite.
CIRA & NOAA/NESDIS/RAMM Meteorological Sounders Dr. Bernie Connell CIRA/NOAA-RAMMT March 2005.

CIRA & NOAA/NESDIS/RAMM Meteorological Sounders Dr. Bernie Connell CIRA/NOAA-RAMMT March 2005.
Use of TRMM for Analysis of Extreme Precipitation Events Largest Land Daily Rainfall (mm/day)

Use of TRMM for Analysis of Extreme Precipitation Events Largest Land Daily Rainfall (mm/day)
Spaceborne Weather Radar

Spaceborne Weather Radar
Data assimilation of polar orbiting satellites at ECMWF

Data assimilation of polar orbiting satellites at ECMWF
Recent activities on utilization of microwave imager data in the JMA NWP system - Preparation for AMSR2 data assimilation - Masahiro Kazumori Japan Meteorological.

Recent activities on utilization of microwave imager data in the JMA NWP system - Preparation for AMSR2 data assimilation - Masahiro Kazumori Japan Meteorological.
Estimation of poverty rates based on satellite observed nighttime lights Chris Elvidge, NOAA National Geophysical Data Center (NGDC) Boulder, Colorado.

Estimation of poverty rates based on satellite observed nighttime lights Chris Elvidge, NOAA National Geophysical Data Center (NGDC) Boulder, Colorado.
J. S. Parihar Agricultural Resources Group Space Applications Centre (ISRO) Ahmedabad, India Land applications from Megha.

J. S. Parihar Agricultural Resources Group Space Applications Centre (ISRO) Ahmedabad, India Land applications from Megha.
ATMS 373C.C. Hennon, UNC Asheville Observing the Tropics.

ATMS 373C.C. Hennon, UNC Asheville Observing the Tropics.
EECS 823 MACHARIA.  Four-frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave.

EECS 823 MACHARIA.  Four-frequency, linearly-polarized, passive microwave radiometric system which measures atmospheric, ocean and terrain microwave.

Similar presentations

Ads by Google