NSPO’s Microsatellite Program Y. S. Chen and Bill Wu National Space Organization, Taiwan UNIVERSAT-2006, Moscow State University, Russia 26~30 June 2006.

Slides:



Advertisements
Similar presentations
2World Best World Best 365 Organization Direct general of National Meteorological Satellite Center (1) Satellite Development and Planning Division.
Advertisements

Ionosphere Climate Studied by F3 / COSMIC Constellation C. H. Liu Academia Sinica In Collaboration with Tulasi Ram, C.H. Lin and S.Y. Su.
Extended observations of decameter scatter associated with the mid-latitude ionospheric trough E. R. Talaat 1, E. S. Miller 1, R. J. Barnes 1, J. M. Ruohoniemi.
1 Program:ROSA Mission Event:1° ASI-EUM ASI-meeting Date:4-5 February, 2009 ROSA Future developments and possible ASI / EUMETSAT cooperation.
Mesoscale ionospheric tomography over Finland Juha-Pekka Luntama Finnish Meteorological Institute Cathryn Mitchell, Paul Spencer University of Bath 4th.
GTECH 201 Session 08 GPS.
Ben Kravitz November 12, 2009 Limb Scanning and Occultation.
UNDERSTANDING TYPHOONS
Spaceborne Weather Radar
Radio Occultation Atmospheric Profiling with Global Navigation Satellite Systems (GNSS)
0 The FORMOSAT3/COSMIC Mission Space Weather Application AMS San Diego Jan. 11, 2005 Christian Rocken
The Impact of GPS Radio Occultation Data on the Analysis and Prediction of Tropical Cyclones Bill Kuo UCAR.
GPS / RO for atmospheric studies Dept. of Physics and Astronomy GPS / RO for atmospheric studies Panagiotis Vergados Dept. of Physics and Astronomy.
COSMIC / FormoSat 3 Overview, Status, First results, Data distribution.
GCOS Meeting Seattle, May 06 Using GPS for Climate Monitoring Christian Rocken UCAR/COSMIC Program Office.
Radio Occultation From GPS/MET to COSMIC.
SVY 207: Lecture 4 GPS Description and Signal Structure
New Satellite Capabilities and Existing Opportunities Bill Kuo 1 and Chris Velden 2 1 National Center for Atmospheric Research 2 University of Wisconsin.
Use of GPS RO in Operations at NCEP
An Introduction to ROSA-ROSSA structure G. Perona
CGMS-40, November 2012, Lugano, Switzerland Coordination Group for Meteorological Satellites - CGMS IROWG - Overview of and Plans for the Newest CGMS Working.
Different options for the assimilation of GPS Radio Occultation data within GSI Lidia Cucurull NOAA/NWS/NCEP/EMC GSI workshop, Boulder CO, 28 June 2011.
Ground Support Network operations for the GRAS Radio Occultation Mission R. Zandbergen, the GRAS GSN team (ESOC) and the Metop GRAS team (EUMETSAT) 09/09/2011.
Space Geodesy (1/3) Geodesy provides a foundation for all Earth observations Space geodesy is the use of precise measurements between space objects (e.g.,
GPS Radio Occultation Sounding Zhen Zeng (HAO&COSMIC)
GPS derived TEC Measurements for Plasmaspheric Studies: A Tutorial and Recent Results Mark Moldwin LD Zhang, G. Hajj, I. Harris, T. Mannucci, X. PI.
TECO-2006 Geneva, Dec. 3-5, Improvements in the Upper-Air Observation Systems in Japan M. Ishihara, M. Chiba, Y. Izumikawa, N. Kinoshita, and N.
June, 2003EUMETSAT GRAS SAF 2nd User Workshop. 2 The EPS/METOP Satellite.
Lecture 6 Observational network Direct measurements (in situ= in place) Indirect measurements, remote sensing Application of satellite observations to.
Slide 1 Impact of GPS-Based Water Vapor Fields on Mesoscale Model Forecasts (5th Symposium on Integrated Observing Systems, Albuquerque, NM) Jonathan L.
Ground-based ionospheric networks in Europe Ljiljana R. Cander.
Status of the assimilation of GPS RO observations: the COSMIC Mission L. Cucurull JCSDA/UCAR J.C. Derber, R. Treadon, and R.J. Purser.
BoM/GNSS RO ACTIVITIES and PLANS John Le Marshall Director, JCSDA CAWCR
Joint International GRACE Science Team Meeting and DFG SPP 1257 Symposium, Oct. 2007, GFZ Potsdam Folie 1 Retrieval of electron density profiles.
ROSA – ROSSA Validation results R. Notarpietro, G. Perona, M. Cucca
Recent developments for a forward operator for GPS RO Lidia Cucurull NOAA GPS RO Program Scientist NOAA/NWS/NCEP/EMC NCU, Taiwan, 16 August
GPS: Everything you wanted to know, but were afraid to ask Andria Bilich National Geodetic Survey.
Programa de Satélites Científicos e Experimentos do INPE MCE Equatorial Atmosphere Research Satellite Monitor e Imageador de Raios-X Missão Clima Espacial.
The Impact of FORMOSAT-3/COSMIC GPS RO Data on Typhoon Prediction
Use of GPS Radio Occultation Data for Climate Monitoring Y.-H. Kuo, C. Rocken, and R. A. Anthes University Corporation for Atmospheric Research.
Impact of FORMOSAT-3 GPS Data Assimilation on WRF model during 2007 Mei-yu season in Taiwan Shyuan-Ru Miaw, Pay-Liam Lin Department of Atmospheric Sciences.
Key RO Advances Observation –Lower tropospheric penetration (open loop / demodulation) –Larger number of profiles (rising & setting) –Detailed precision.
FORMOSAT-3/COSMIC Science Highlights Bill Kuo UCAR COSMIC NCAR ESSL/MMM Division.
AGU Fall MeetingDec 11-15, 2006San Francisco, CA Estimates of the precision of GPS radio occultations from the FORMOSAT-3/COSMIC mission Bill Schreiner,
Preliminary results from assimilation of GPS radio occultation data in WRF using an ensemble filter H. Liu, J. Anderson, B. Kuo, C. Snyder, A. Caya IMAGe.
Improved Radio Occultation Observations for a COSMIC Follow-on Mission C. Rocken, S. Sokolovskiy, B. Schreiner UCAR / COSMIC D. Ector NOAA.
COSMIC Update and Highlights 8 November
C H A M P International Laser Ranging Service - General Assembly, October 2005 Eastbourne, UK L. Grunwaldt, R. Schmidt, D. König, R. König, F.-H. Massmann.
Radio Occultation. Temperature [C] at 100 mb (16km) Evolving COSMIC Constellation.
Formosat3/COSMIC Workshop, Taipei, Oct. 1-3, 2008 The Ionosphere as Signal and Noise in Radio Occultation Christian Rocken, Sergey Sokolovskiy, Bill Schreiner,
0 Earth Observation with COSMIC. 1 COSMIC at a Glance l Constellation Observing System for Meteorology Ionosphere and Climate (ROCSAT-3) l 6 Satellites.
This document contains proprietary and controlled information of National Space Organization (NSPO) of Taiwan and shall not be duplicated in whole or in.
Electron density profile retrieval from RO data Xin’an Yue, Bill Schreiner  Abel inversion error of Ne  Data Assimilation test.
Data Assimilation Retrieval of Electron Density Profiles from Radio Occultation Measurements Xin’an Yue, W. S. Schreiner, Jason Lin, C. Rocken, Y-H. Kuo.
GPS Observations for Atmospheric Science Ground-based and Radio Occultation Observations for Weather, Climate and Ionosphere C. Rocken, S. Sokolovskiy,
IGARSS 2011, Vancuver, Canada July 28, of 14 Chalmers University of Technology Monitoring Long Term Variability in the Atmospheric Water Vapor Content.
COSMIC Ionospheric measurements Jiuhou Lei NCAR ASP/HAO Research review, Boulder, March 8, 2007.
COSMIC: Constellation Observing System for Meteorology, Ionosphere and Climate Mission Status and Results UCAR COSMIC Project FORMOSAT-3.
GPS Radio-Occultation data (COSMIC mission) Lidia Cucurull NOAA Joint Center for Satellite Data Assimilation.
COSMIC Status and Research Highlights Bill Kuo UCAR COSMIC NCAR ESSL/MMM Division.
Formosat-3/COSMIC WorkshopNov 28 - Dec 1, 2006Taipei, Taiwan Estimates of the precision of LEO orbit determination and GPS radio occultations from the.
COSMIC: Constellation Observing System for Meteorology, Ionosphere and Climate Mission Status and Results UCAR COSMIC Project FORMOSAT-3.
Observational Error Estimation of FORMOSAT-3/COSMIC GPS Radio Occultation Data SHU-YA CHEN AND CHING-YUANG HUANG Department of Atmospheric Sciences, National.
Unit 4 Lesson 5 Weather Maps and Weather Prediction
Center for Atmospheric & Space Sciences
Formosat3 / COSMIC The Ionosphere as Signal and Noise
Hui Liu, Jeff Anderson, and Bill Kuo
Formosat3 / COSMIC The Ionosphere as Signal and Noise
Mission Status and Data Distribution
Open Loop Tracking of GPS Radio Occultation for LEOs
Presentation transcript:

NSPO’s Microsatellite Program Y. S. Chen and Bill Wu National Space Organization, Taiwan UNIVERSAT-2006, Moscow State University, Russia 26~30 June 2006

Outline Introduction University Projects FORMOSAT-3/COSMIC Mission Related Science Researches in Taiwan Intense Observation Period Conclusion

Introduction Major Part of NSPO’s Mission is for Meteorological Research – Typhoon, Flood, Earthquakes, etc., that concerns the General Population on Taiwan Ionosphere Research has Generated Some Interests in the Science Community Microsatellite Development for Low-cost and Timely Launch of Experiments Constellation Deployment Strategy – a Future Trend in Microsatellite Applications University Teams for Strengthening the Education in Science and Engineering

University Projects NCKU Microsatellite System Layout Name: PACESAT 2 Orbit: 500 km, 22° Inclination Mass: 30 kg Communication: UHF/VHF Mission: Earth ELF/ULF Observations Gravity Gradient Boom

University Projects NCKU Microsatellite

University Projects TKU Microsatellite System Layout Name: TUUSAT Orbit: 500 km, 22° Inclination Mass: 22 kg Communication: UHF/VHF Mission: CCD Meteorology Observations Battery and Power Control TT&C CCD, C&DH and GPS

University Projects TKU Microsatellite

Before Compression: 340KBbytes After Compression: 53KBbytes Adjustable Image Data Compression Ratio

FORMOSAT-3/COSMIC Mission FORMOSAT-3/COSMIC Satellite Mission Life : 2 years minimum. Design Life : 5 years. Constellation : consist of 6 satellites. Weight : 62 Kg/each (including propellant). Dimension : diameter 103 cm , height 16 cm ; with two circular solar panels deployed at 121 degrees and 59 degrees. Orbit period : ~100 minutes. Mission Orbit : circular orbit , altitude Km , inclination 72 degree. Payloads: GPS Occultation Experiment (GOX), Tiny Ionosphere Photometer (TIP) and Tri-Band Beacon (TBB)

FORMOSAT-3/COSMIC Payloads GPS Occultation Experiment (GOX) –Function: Track L1/L2 signals to collect occultation data and to determine precise orbit. –Mission: Retrieve the vertical profile of atmosphere/ionosphere, for –Weather and space weather forecasts –Climate and ionospheric research Determine the precise orbit for geodetic research Tiny Ionosphere Photometer (TIP) –Function: Measure 135.6nm photon emission at satellite’s nadir direction. –Mission: Retrieve nighttime electron number density for ionospheric research Map aurora boundaries Tri-Band Beacon (TBB) –Function: Transmit phase coherent signals in 150, 400, MHz. –Mission: (TBB signals will be received on ground receivers) Compute the satellite to ground linked TEC, for –3-D maps of Ionosphere tomography –Scintillation monitoring

FORMOSAT-3 Assembly at NSPO

FORMOSAT-3 Thermal Vacuum I&T 10~12 Days Continuous Tests for each Satellite

FORMOSAT-3 Acoustic/Vibration I&T

FORMOSAT-3 Solar Panel Tests

FORMOSAT-3 on Minotaur LV

FORMOSAT-3 Launch Trajectory Stage 2 Skirt Stage 1 Fairing Stage 2 Stage 3 Payload Separation +

FORMOSAT-3 Mission Operation

GPS Occultation Sounding To obtain the temperature, pressure, and water vapor pressure To provide TEC and electron density profiles GPS (24 + Satellites) Atmosphere Ionosphere FORMOSAT-3/ COSMIC GPS Signal

FORMOSAT-3 & GPS Constellations GPS constellation –24-30 satellites in 6 orbit planes (55  inclination) –~3.8km/s at 20,200km altitude –Orbit period ~12hr FORMOSAT-3 Constellation Observing System for Meteorology, Ionosphere, and Climate (COSMIC) –6 satellites in 6 orbit planes (72  inclination) –~7km/s at km altitude –Orbit period ~100min

System Architecture 6-satellite FORMOSAT-3/COSMIC Constellation

GOX Measurements: 2500 Soundings Per Day An average of 2500 globally distributed atmospheric soundings will be obtained each day.

TIP Measurements Nighttime ionospheric TEC measurements (e  ) –radiative recombination –O + + e  ->O + h (135.6nm) Map aurora boundaries (O) –electron impact excitation –O + e  -> O + e  + h With the BaF2 filter, TIP can detect the molecular N 2 LBH emissions. (N 2 ) O, N 2 & e  number densities are all retrieved from measured FUV radiance intensity (or photon counts, #/sec). FORMOSAT-3 Orbit track TIP Line of sight

TBB Measurements Signals measured by a chain of ground receivers will be used to –Retrieve electron density & 2-D Tomography Orbit Receiver Irregularity TBB signals FORMOSAT-3

3-D Tomography if Multiple Chains

Data Processing in CDAAC Real-time processing (RT) –Run automatically, as data are received, on one or more cluster nodes. Currently processing CHAMP results are generated on ~15 min. after receipt of CHAMP raw data Expect to complete data processing from one orbit in min after reception of FORMOSAT-3 occultation raw data –Uses predicted GPS orbits and forecast weather grids (NCEP/AVN) Post-Processing (PP) –Done 1-2 months behind real-time, in batches of one month –Done with more fiducial sites, precise GPS orbits and better fiducial troposphere values than those used in RT

CDAAC Development Develop software, database, and web system –Improve and speed up for the orbit, atmosphere inversion, data validation, and constellation data simulation open loop tracking Single difference for excess phase computation non-local observational operator –Ionospheric profiling and tomography Fiducial network –~20 IGS stations (igsHrf) –~30 Natural Resources of Canada (NRCan) stations (canHrf) –5 netRS GPS receivers (cosHrf) 3 in South Pacific + 2 in Brazil –Global Bit Grabber network (under plan) To assist with open loop tracking

Fiducial Network Host agreed Host needed Bit Grabber

TACC Data Flow Archive all raw data, TACC&CDAAC products, TBB data CWB, NSPO, Science teams DVD Raw data & TACC products Data assimilation (CWB) GOX product (atmPrf) GOX data and products TIP data socket 5 Global users Ionospheric science team (NCU) ftp MSS/CWB TBB data from Pacific chain 3-month RT products (TBD) 1-year PP products CDAAC/UCAR ftp, DVD TACC/CWB GOX and TIP low level data (TBD) ftp (< 24h) http (web interface) Ionospheric science team (NCU) Data generated by TACC Data generated by CDAAC RT: real-time PP: post-processing

Related Science Research in Taiwan Application of FORMOSAT-3/COSMIC Data Improve global/regional scale weather and space weather forecasting Provide data sets for the research of climate change, global warming detecting, scintillation, ionospheric structure, and Earth gravity field. –Meteorology: global weather analysis, interaction between low- and mid- latitudes weather system… –Climate: long-term observation record, global climate variability –Ionosphere: TEC, electron density distribution, scintillation, sporadic E (E S ) layer… –Geodesy: gravitational field, precise satellite orbit…

Atmospheric Research in Taiwan Typhoon study by 3D-VAR assimilations –Using CHAMP and SAC-C data to study the route and rainfall of typhoons passing Taiwan. Implementation of ray-tracing operator and bending angle (and/or local refractivity) assimilation system into the CWB forecast model. Occultation inversion technique –Occultation retrieval scheme by 3D vector analysis –New ionospheric correction method –Effects of multipath and diffraction on retrieved parameters –Ground-based GPS observations sensing precipitable water vapor and its dynamics during the passage of typhoon

Development of Occultation Inversion Technique Comparison of retrieved profiles for bending angle and temperature –NCURO is developed by Dr. Huang (2004) Identical with UCAR result Difference above 25km is due to the different background models

Assimilated Typhoon Route By Adding CHAMP Occultation Data Mindulle typhoon in June, 2004 –Red: CWB’s optimized route –“G”: assimilated route by using traditional measurements –“B”: assimilated result by traditional and CHAMP data Agree with the optimized route? –“B” is better than “G” before Mindulle landed Taiwan. –Both “G” and “B” are bad after landing. Due to the complexity of topographic model and the long time computation error.

Ionospheric Research in Taiwan Setup of four transmitter/receiver pairs of 30 MHz bistatic coherent radar system in Taiwan: –Measuring the ionospheric E region irregularity to determine the possibility of the TBB or GPS signal scintillations For TBB operation in the Pacific chain, the bistatic radar observations will provide a referenced index for the UHF&L-band mode to be turned on. More vertical data with Sounding Rocket Experiments Ionospheric global modeling and space weather forecast 3D/4D Computerized ionospheric tomography (CIT) Retrieval/validation of electron density through occultation data

Geodetic Research in Taiwan POD techniques –A CTODS (reduced-dynamic orbit) package was developed for precise orbit and gravity determination from spaceborn GPS data. –Kinetic orbit procedures were developed to support the near- real time processing of occultation inversion. Earth’s mantle discontinuity in 3D –The 3D inversion of the Earth’s underground structures was studied by comparing the recent gravity model with the perturbation of satellite orbit from POD data. Two major boundary layers in the Earth’s mantle are at depth of 400 km and 670 km within the mantle, respectively.

Pair in tandem 90 days Pair in tandem 230 days Intensive Observation Period FORMOSAT-3 Constellation Orbits Deployment Launch and early orbit (L&EO): 1st month Constellation deployment: 1 ~ 12th month Final orbit: after the 13th month

Intense Observation Period (IOP) Campaign Taking advantage of very dense observation points due to localized (in longitude) FORMOSAT-3 satellite orbits during the earlier deployment phase to conduct IOP campaign. –Allows most complete comparison and validation of FORMOSAT- 3 GPS occultation observations with ground-based observations and dropsonde experiments and other space-based observations in East Asia longitude region. –Improve weather forecast capability, typhoon prediction, and monsoon rainfall in East Asia region. –Improve global space weather monitoring capability and earthquake application.

IOP Items IOP campaign provides a platform for Taiwan to play a major role in international collaboration on research in atmosphere, ionosphere and geodesy. –Period: 2006/ /11 –Hold an IOP Campaign workshop/conference in November or December, 2006 in Taiwan IOP Campaign for atmospheric study in East Asia Region –Taiwan: 2006/ /11 –Southwesterly flow: 2006/05 – 2006/06 –Typhoon: 2006/05 – 2006/10 –Instruments: radiosonde, GPS receiver, dropsonde, satellites, etc. IOP Campaign for global ionospheric study –Observation comparison between GOX, TIP, ground GPS and ionospheric radars: 2006/ /11

2006 South China sea Southwesterly flow/Typhoon path forecast experiment UAV sonde + Microwave Radiometric profiler Dropsonde SW-IOP TY-IOP FORMOSAT GPS Radiosonde

Conclusion University microsatellite projects are on going. FORMOSAT-3/COSMIC has been launched on April With the real-time operations, FORMOSAT-3/COSMIC results will complement other Earth observing systems and improve global weather analyses and Numerical Weather Prediction (NWP) forecasts. The science teams in Taiwan are actively pursuing FORMOSAT-3/COSMIC researches in the areas of GPS occultation for weather forecasting, climate prediction, ionospheric monitoring, and a suite of related earth science studies. The period during the orbit deployment provides a very unique opportunity for special studies. Many researches are being planned for this Intensive Operation Period.