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This update provides information on the proposed observing platforms for the T-PARC winter phase, including NOAA and NASA satellites, aircrafts, and enhanced Siberian network.
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Winter T-PARC Update Yucheng Song IMSG at EMC/NCEP/NOAA Zoltan Toth EMC/NCEP/NWS/NOAA http://www.emc.ncep.noaa.gov/gmb/tparc Updated on July 7, 2008
WITH CONTRIBUTIONS FROM • Dave Emmitt Simpson Weather Assoc. • Chris Doyle Meteorological Service of Canada • Alexander Kats Roshydromet, Russia • Gary Wick ESRL/NOAA, CO • David Richardson ECMWF
Overview • Platforms planned • Decision making process • Real time parallel at NCEP
PROPOSED OBSERVING PLATFORMS • NOAA and NASA satellites • G-lV out of Japan (Yokota AFB), ~150 hrs in Jan 10- Feb 28 • G-IV 45,000 feet high, centering around 00z • C-130 – covering the mid Pacific over the same time period (USAF) • C-130 30,000 feet high, centering around 00z • P3 (or other asset) • East Pacific or western US (contributions by NRL and SMA) • Enhanced Siberian network • Roshydromet / NOAA and/or NRL contribution • Japanese contribution • Other possible platforms (see T-PARC plan) • Rapid scan satellite data (Nakazawa-San) • Contributions from Japan • Tibetan Plateau • Asian THORPEX community contribution
PROPOSED OBSERVING PLATFORMS Extensive observational platforms during T-PARC winter phase allow us to track the potential storms and take additional observations as the perturbation propagate downstream into Arctic and US continents Day 3-4 RAWIN Russia Arctic VR Day 5-6 RAWIN Tibet CONUS VR D 2-3 G-IV D 1-2 C-130 G-IV D-1 P-3 WHEN?JAN – MARCH 2009 !!
Platforms planned • G-IV Stationed in Japan (likely Yokota AFB) (Japan contacts: YoshioAsuma and Tetsuo Nakazawa) Stage 1: Jan 10-Feb 28 • Can reach 45,000 feet high, centered on 00Z UTC • Maximum range:3800 nm • Maximum duration: 8 hrs 45 mins • Contribution from NWS WSR program • Backbone of the whole program • Requested 150 flight hours 360 dropsondes • Six of the missions will recover at other stations such as Guam, Okinawa Stage 2: March 1-March 31 • Base out of Honolulu approximately 110hrs • ISSUES: • Air traffic control: (resolved) • 00Z or 12Z (local time in Japan would be 3:30AM for 00Z) • Yokota AFB, Japan: (resolved) (AOC contacts: Jack Parrish and Michele Finn)
C-130 C-130 out of Anchorage (USAF) • Can reach 35,000 feet high, centered on 00Z UTC • Maximum range: 1800nmi • Maximum duration: 10 hrs • Part of NCEP WSR program
Russia Roshydromet • Alexander Kats • Nina Zaitseva • Dr. Ivanov (Director of CAO) • Dr. Mikhail D. Tsyroulnikov ISSUES: Roshydromet could not pay for the extra sondes ($130K est.) 1. Proposal forWMO Voluntary Cooperation Program (VCP) funding (proved) about 25-30K 2. $50K from Canada (contact Chris Doyle, contribution from EC and DND) 3. Pending proposal with Steve Swadley/Rolf Langland from NRL 4. Possible contributions from Japan (Contact: Yoshio Asuma)
Enhanced Siberian network • Additional 06 and 18 UTC observations from the subset of about 40 designated operational stations about 6 weeks • - Space and time distribution (and may be amount of additional observations on each station) will be uneven depending from the weather conditions. - They will be carried out during 10-15 24-h intensive observing periods (IOPs) with 6-hrs soundings in some sensitive areas to be determined during the campaign depending from the weather conditions - Depending on geographical location of sensitive area, during each IOP about 20 of the available 40 stations will be requested (in 18-24 hrs prior to the IOP beginning).
Continued • Expected maximum total amount of additional soundings during the campaign is 15 (IOP) x 20 (sites) x 2 (extra soundings) ~ 600 soundings. • Taking into account possible uneven distribution of sounding it is necessary to have on each stations consumables for some 25 additional soundings to avoid running out of consumables at any of the stations before the end of the campaign. • This gives us maximum amount of additional consumables to be distributed for as many as 25 (soundings) x 40 (sites) ~ 1000 soundings. Remaining consumables will be used for the regular soundings after the end of the campaign.
Stations requested by winter T-PARC – 35 stations 31369 31538 31736 30554 23955 29612 29698 32389 32540 25913 23330 28275 28698 31873 31977 32150 20674 29572 29862 28661 25428 21824 21946 24125 24266 24343 24641 24688 24726 24944 24959 25123 25400 30054 31004
ONR P-3 • Use DWL on P3 to profile winds below & at flight level Contacts: Dave Emmitt Simpson Weather Associates The ELDORA radar is provided by NCAR. The P3DWL is provided by ONR. The two possible locations for the P3DWL are noted as (1) or (2).
P3DWL data Description • Nominal vertical domain:0 – 6 km (assumes flight level ~ 6.5 km)Line-of-sight products • Nominal spacing between profiles: 2 km (500m with 90 deg sector processing) • Vertical resolution:~ 50 meters • Accuracy U and V components:.05 m/s (assuming homogeneous wind field) • Accuracy W component:.1 m/s • Additional data collection capabilities: All angles within ±30 degrees of nadir All angles within ±30 degrees of flight path • DWL wind profiles:Buffer format, real time processing, single profile file size about 10 KB
Decision Making Communication setup (webpage and emails) • Identify High impact weather (HIW) events • Inputs from US field offices, research interest groups, Canada, Mexico in advance • Sensitive Area Calculations (SACs) • Run NCEP ETKF targeting software • DTS (ECMWF/UK MET OFFICE/METER FRANCE) • NRL targeting and others? • Select tracks and stations • Fixed tracks for easier air traffic control? • Flexible tracks (UAV)? • Siberia/Tibet Plateau stations • Decisions sent out • 18-36 hours ahead of time • Flexibility of change with 24 hours notification
DTS targeting system – an example Shaded area shows Sensitive Area Box is the forecast area (verification area)
PREVIEW T-PARC DTS targeting system • Multiple Data Targeting Display – convenient for technique comparison • Easier to select area of interests
Plans for real time parallel at NCEP • Data denial experiment • T126L64 control and operational experiments • Impact: • Conventional metrological fields, differences display alongside the operational forecast and analysis • Verification: • Post field program period • Legacy programs (Fit to obs, fit to analysis, scores) KEY ISSUE: T-PARC identity BUFR headers
Contribution from Mexico • Extra-Rawinsondes (if expendable material is provided) • Ensemble evaluation for the Mexican region • At least one meteorologist volunteering in operational activities
Canada and Mexico Contacts: • Chris Doyle (Canada) • Ricardo Prieto González (Mexico) <rprieto@tlaloc.imta.mx> • Juan M. Caballero (Mexico) jmcaballero@semar.gob.mx
Background Info • Upcoming Winter T-PARC meeting on October 8-10, 2008 • Other potential platforms – Not totally committed yet
P3DWL The MLX-16 coherent Doppler lidar built by LMCT for the US Army (ARL).
Cylindrical scanner Shown here is the scanner as mounted in the CIRPAS Twin Otter. The white fairing is used to reduce aerodynamic drag Scanner
Two Types of NOAA Satellite Programs Polar-orbiting Operational Environmental Satellites(POES) Geostationary Operational Environmental Satellites (GOES) Polar Orbiting Satellites Geostationary Satellites N Fairbanks, Data Acquisition Site Wallops, Virginia Wallops, Virginia Fairbanks, Alaska Wallops, Virginia N Data Acquisition Sites Subsatellite Point 540 Mi Equator Equator 22,240 Mi S Orbit Path S Continuously monitors the Western Hemisphere Each satellite covers the entire Earth twice per day • Same geographic image over time • Full image every 30 minutes • Northern Hemisphere imaged every 15 minutes • Usable images between 60°N and 60°S • Information is used for short-term weather forecasting and severe storm warning/tracking • Each orbit is 102 minutes • Global coverage every 12 hours with 1 satellite • Images are global and include the poles • Information is used for long-term weather forecasting and climate monitoring
Chinese participation • CMA contact person: Dehui Chen chendh@cma.gov.cn • Jing Chen chenj@cma.gov.cn CAMS – Chinese Academy for Meter. Sci.
TIBET OBSERVATION NETWORK • IMPORTANCE OF TIBET PLATEAU • Origin of many storm systems in the Northern Hemisphere • Well known important diabatic heating and dynamic forcing effects • Strong influence on East Asia jet stream and downstream weather • HOW THE DATA WILL CONTRIBUTE • Look for possible ways to take adaptive RAOB observations a. Fixed intensive observation periods (Jan 09 – Mar 09) b. Adaptive observing (ETKF or other methods) • Optimize Chinese observational network • Fill data gap in the network • Assimilate data into different DA systems • PROGRESS • GPS sondes, profilers and an array of surface mesoscale networks • Which are expected to leave in place after the field phase of T-PARC
NOAA THORPEX POTENTIAL OBSERVATION SYSTEM ENHANCEMENT FOR WINTER T-PARC (JAN 09 – MAR 09)
Global Hawk Contacts: NOAA • Gary Wick PSD/ESRL/NOAA • Todd Jacobs NOAA NASA • David Fratello DFRC Systems engineer • Chris Naftel DFRC Project Manager • Phillip Hall OMAO/NASA ISSUES: • Air traffic control • Lidar and dropsonde capability?
Potential for High Altitude UAS Availability • NOAA UAS program actively pursuing a joint demonstration in March 2009 • Would utilize NASA Global Hawk with operations from NASA Dryden • Plans for completion of a dropsonde system by March 1 • Potential for flights joint with studies of “atmospheric rivers” • Schedule is very challenging but not impossible • Primary hurdles • NOAA UAS program not yet funded • No formal commitment of aircraft availability from NASA • Potential FAA limitations on release of dropsondes from unmanned aircraft
Global Hawk Endurance From NASA Dryden 20 hr 15 hr 25 hr