National Polar-orbiting Operational Satellite System (NPOESS) Microwave Imager/Sounder (MIS) Capabilities Pacific METSAT Working Group Apr 09 Rebecca Hamilton,

Slides:

Advertisements

Similar presentations

Environmental Application of Remote Sensing: CE 6900 Tennessee Technological University Department of Civil and Environmental Engineering Course Instructor:

Advertisements

1 CEOS/WGISS-20 JAXA Status Report September 16, 2005 Kyiv, Ukraine Satoko Horiyama MIURA / JAXA Hurricane KATRINA :23-03:27 (UTC) A Horizontal.

TRMM Tropical Rainfall Measurement (Mission). Why TRMM? n Tropical Rainfall Measuring Mission (TRMM) is a joint US-Japan study initiated in 1997 to study.

Maintaining and Improving the AMSR-E and WindSat Ocean Products Frank J. Wentz Remote Sensing Systems, Santa Rosa CA AMSR TIM Agenda 4-5 September 2013.

1 GOES Users’ Conference October 1, 2002 GOES Users’ Conference October 1, 2002 John (Jack) J. Kelly, Jr. National Weather Service Infusion of Satellite.

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

ATS 351 Lecture 8 Satellites

Remote Sensing of Mesoscale Vortices in Hurricane Eyewalls Presented by: Chris Castellano Brian Cerruti Stephen Garbarino.

NRL Tropical Cyclone Satellite Web Resource

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

MWR Algorithms (Wentz): Provide and validate wind, rain and sea ice [TBD] retrieval algorithms for MWR data Between now and launch (April 2011) 1. In-orbit.

Recent Progress on High Impact Weather Forecast with GOES ‐ R and Advanced IR Soundings Jun Li 1, Jinlong Li 1, Jing Zheng 1, Tim Schmit 2, and Hui Liu.

Recent activities on utilization of microwave imager data in the JMA NWP system - Preparation for AMSR2 data assimilation - Masahiro Kazumori Japan Meteorological.

ATMS 373C.C. Hennon, UNC Asheville Observing the Tropics.

_PCM. WindSat Mission Overview and Status Peter Gaiser Remote Sensing Division, Code 7220 Naval Research Laboratory Washington DC

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

SMOS STORM KO meeting 30/01/2012 ESRIN Ocean Surface Remote Sensing at High Winds with SMOS.

Current & Future Microwave Constellation

SMOS+ STORM Evolution Kick-off Meeting, 2 April 2014 SOLab work description Zabolotskikh E., Kudryavtsev V.

Current status of AMSR-E data utilization in JMA/NWP Masahiro KAZUMORI Numerical Prediction Division Japan Meteorological Agency July 2008 Joint.

Evaluation of Microwave Scatterometers and Radiometers as Satellite Anemometers Frank J. Wentz, Thomas Meissner, and Deborah Smith Presented at: NOAA/NASA.

Precipitation Retrievals Over Land Using SSMIS Nai-Yu Wang 1 and Ralph R. Ferraro 2 1 University of Maryland/ESSIC/CICS 2 NOAA/NESDIS/STAR.

Passive Microwave Remote Sensing

© Crown copyright Met Office Plans for Met Office contribution to SMOS+STORM Evolution James Cotton & Pete Francis, Satellite Applications, Met Office,

Also known as CMIS R. A. Brown 2005 LIDAR Sedona.

AN ENHANCED SST COMPOSITE FOR WEATHER FORECASTING AND REGIONAL CLIMATE STUDIES Gary Jedlovec 1, Jorge Vazquez 2, and Ed Armstrong 2 1NASA/MSFC Earth Science.

Weather Forecasting Chapter 9 Dr. Craig Clements SJSU Met 10.

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Image: MODIS Land Group, NASA GSFC March 2000 Improving Hurricane Intensity.

OC3522Summer 2001 OC Remote Sensing of the Atmosphere and Ocean - Summer 2001 Microwave Applications.

Starter 1.What are hurricanes in the Western Pacific called? 2.What are hurricanes in the Indian Ocean called?

05/06/2016 Juma Al-Maskari, 1 Tropical Cyclones.

NPOESS Conical Scanning Microwave Imager/ Sounder (CMIS) Overview

Evaluation of Passive Microwave Rainfall Estimates Using TRMM PR and Ground Measurements as References Xin Lin and Arthur Y. Hou NASA Goddard Space Flight.

SeaWiFS Views Hurricane Fabian Gathering Strength 970.2/Gene Feldman, Laboratory for Hydrospheric Processes, SeaWiFS SIMBIOS Project Office

High impact weather studies with advanced IR sounder data Jun Li Cooperative Institute for Meteorological Satellite Studies (CIMSS),

WindSat Vector Maps as Forecaster Products Naval Research Laboratory Monterey and Washington DC California Thomas F. Lee, Jeffrey D. Hawkins, Mike H. Bettenhausen.

Response of active and passive microwave sensors to precipitation at mid- and high altitudes Ralf Bennartz University of Wisconsin Atmospheric and Oceanic.

Science of the Aqua Mission By: Michael Banta ESS 5 th class Ms. Jakubowyc December 7, 2006.

Ocean Vector Wind Workshops and the Role of Cal/Val in Preparing for Future Satellite Wind Sensors Dudley Chelton Cooperative Institute for Oceanographic.

The Hyperspectral Environmental Suite (HES) and Advanced Baseline Imager (ABI) will be flown on the next generation of NOAA Geostationary Operational Environmental.

CRL’s Planned Contribution to GPM Harunobu Masuko and Toshio Iguchi Applied Research and Standards Division Communications Research Laboratory 4-2-1, Nukkui-kita-machi,

DIRECT READOUT APPLICATIONS USING ATOVS ANTHONY L. REALE NOAA/NESDIS OFFICE OF RESEARCH AND APPLICATIONS.

2015 HS3 Science Team Meeting Ames Research Center, Moffett Field, CA.

Doppler Lidar Winds & Tropical Cyclones Frank D. Marks AOML/Hurricane Research Division 7 February 2007.

Satellites Storm “Since the early 1960s, virtually all areas of the atmospheric sciences have been revolutionized by the development and application of.

Geophysical Ocean Products from AMSR-E & WindSAT Chelle L. Gentemann, Frank Wentz, Thomas Meissner, Kyle Hilburn, Deborah Smith, and Marty Brewer

An Overview of Satellite Rainfall Estimation for Flash Flood Monitoring Timothy Love NOAA Climate Prediction Center with USAID- FEWS-NET, MFEWS, AFN Presented.

COMPARING HRPP PRODUCTS OVER LARGE SPACE AND TIME SCALES Wesley Berg Department of Atmospheric Science Colorado State University.

The Potential Role of the GPM in Activities at the Naval Research Laboratory Joe Turk and Jeff Hawkins Naval Research Laboratory Marine Meteorology Division.

Infrared and Microwave Remote Sensing of Sea Surface Temperature Gary A. Wick NOAA Environmental Technology Laboratory January 14, 2004.

Apr 17, 2009F. Iturbide-Sanchez A Regressed Rainfall Rate Based on TRMM Microwave Imager Data and F16 Rainfall Rate Improvement F. Iturbide-Sanchez, K.

SMAP OSWV Product Potential for the OSWV Gap Augmentation SMAP Ocean Surface Wind Vector CalVal Team Simon Yueh and Alex Fore (JPL) Don Boucher and Josh.

SCM x330 Ocean Discovery through Technology Area F GE.

“CMORPH” is a method that creates spatially & temporally complete information using existing precipitation products that are derived from passive microwave.

Passive Microwave Remote Sensing

Applications of the NPOESS Imagers Thomas F. Lee, Jeffrey Hawkins, F. Joseph Turk, Peter Gaiser, Mike Bettenhausen Naval Research Laboratory Monterey CA.

Spaceborne Polarimetric Microwave Radiometer Brandon Ravenscroft

EXTREME WINDS AND PRECIPITATION FROM SPACE

Presented by Beth Caissie

Microwave Assimilation in Tropical Cyclones

SOLab work description

Plans for Met Office contribution to SMOS+STORM Evolution

GPM Microwave Radiometer Vicarious Cold Calibration

Passive Microwave Systems & Products

GOES visible (or “sun-lit”) image

Hui Liu, Jeff Anderson, and Bill Kuo

Satellite Foundational Course for JPSS (SatFC-J)

Satellite Foundational Course for JPSS (SatFC-J)

Current and future use of microwave imager radiances in NWP models

Presentation transcript:

National Polar-orbiting Operational Satellite System (NPOESS) Microwave Imager/Sounder (MIS) Capabilities Pacific METSAT Working Group Apr 09 Rebecca Hamilton, Capt, USAF MIS Deputy Program Manager, NPOESS David Kunkee, The Aerospace Corp MIS Chief Engineer, NPOESS

22 Agenda What is MIS? EDR Products Trade Space and Baseline MIS vs. Legacy Typhoon Warning-related EDRs –Sea Surface Winds –Sea Surface Temperature –Cloud Liquid Water, Precipitable Water –Precipitation Rate –Imagery Summary 2

3 What is MIS? MIS is a GFE sensor, developed by the Naval Research Laboratory MIS FM1 on NPOESS C2 –Launch date May 2016 (Current Best Estimate) –17:30 orbit, 828 km Conical scanning at 31.6 rpm Swath Width: ~1,700km 1.8m main reflector deployable structure 39 Channels; 12 feedhorns –Core Imaging Channels: 10 VH; 23 VH, 18 VH; 37 VH; 89 VH –Atmospheric Sounding: 50.3 – 60 GHz; 166 & GHz –Low Frequency: 6.8 VH –Polarimetric Channels: 10 PM or LR; 18 PMLR; 37 PM Upper Air Sounding: 60 – 63 GHz [FM2 on C3] on going trade study Upwelling Microwave energy from 6 GHz to 183 GHz is detected by the sensor and processed to form 17 Environmental Data Record (EDR) products Key EDRS: Soil Moisture [Key Performance Parameter (KPP)], Sea Surface Winds [KPP], Sea Surface Wind Direction, Sea Surface Temperature, Imagery Sensor System Requirements Design Review (SRDR) in May 2009

44 MIS EDRs (NPOESS C2)

5 MIS Trade Space W/R/T IORD-II A: 1.2 meter Antenna B: 1.8 meter Ant. + 6 GHz x1: Core Imaging + Polarimetry x2: Core + Polarimetry + Sounding B8: Upper Air Sounding

6 MIS System Spec Baseline W/R/T IORD-II A: 1.2 meter Antenna B: 1.8 meter Ant. + 6 GHz x1: Core Imaging + Polarimetry x2: Core + Polarimetry + Sounding B8: Upper Air Sounding B-2 Equals or Surpasses Legacy Performance (no UAS) A, A-1, A-2 Provides Inadequate Spatial Resolution for IORD-II

7 MIS vs. Legacy

8 Sea Surface Winds MIS expected to produce sea surface wind vectors similar to on-orbit capability of WindSat Wind direction capability has shown significant utility for improving typhoon forecasts UK Met office is now assimilating WindSat data into their Global Model –Demonstrated positive impact on Forecasting Tropical Cyclone tracks Wind direction retrievals using WindSat data in the Caribbean, 19 Aug 07

9 WindSat Data Comparison WindSat Data Comparison with NCEP Forecast Model Showing Detection (Analysis by R. Atlas, NOAA AMOL, Ocean Sciences Conference, February 2006). NCEP analysis January 6 NCEP analysis January 7 WindSat Surface Wind retrievals in the North Atlantic show the presence of paired cyclonic vortices not captured until the following day by the National Center for Environmental Prediction (NCEP) forecast analysis.

10 Sea Surface Temperature White dots: Hurricane Bonnie’s daily position as it moved northwest from 24 through 26 August. Gray dots: Hurricane Danielle as it moved northwest from 27 August through 1 September. Danielle crossed Bonnie’s cold wake on 29 August and its intensity dropped. Cloud cover prevented AVHRR from observing this sequence, however, TMI was able to measure characteristics of the surface. [LEFT] A cold wake (blue region near the white circles) was produced by Hurricane Bonnie on 24 to 26 August 1998, as seen by the TRMM Microwave Imager (TMI) [RIGHT] The cold wake was not seen by the visible/infrared AVHRR imager (right) due to areas of persistent rain and cloud cover (white patches) over the 3-day period.

11 Cloud Liquid Water and Precipitable Water Global maps of total Precipitable Water and Cloud Liquid Water are produced from AMSR-E data on the Aqua satellite and from SSM/I and SSMIS on DMSP. These datasets have value for weather forecasts and models of the energy and water cycles. Precipitable Water Vapor is considered critical for data continuity for GEOSS. Only microwave sensors can provide estimates of Cloud Liquid Water. MIS provides same performance as AMSR-E. AMSR-E Cloud Liquid Water: 3-days ending Atmospheric Water Vapor: 3-days ending Liquid Water: mm Water Vapor: mm

12 Precipitation Rate Rain Rate (mm/hour) Measurements of precipitation rate are valuable for tactical maneuvers, maritime navigation, and fisheries dynamics, and supports climate studies. MIS will provide global rain rate measurements. Rain rate (mm/h) at 2 km height from TMI. Squall line south of Japan. (From Aonashi and Liu, JAM, 2000).

13 Imagery WindSatAMSU SSM/I TRMM SSMIS AMSR-E MIS Imagery HCS will closely resemble SSMIS

14 Summary NPOESS MIS development continues to represent the latest most capable operational microwave radiometer –MIS is responsible for 17 EDRs (includes 2 NPOESS KPPs) –MIS offers improvements to nearly all legacy EDRs: DMSP SSMIS: Better horizontal spatial resolution NASA AMSR-E: RFI mitigation for 6 GHz NRL WindSat: Similar wind direction capability –Improvements to weather forecasts are expected from MIS atmospheric sounding, wind direction, and all weather sea surface temperature capabilities