Status and Progress of ARGO Jong Uk (James) Park Korea Astronomy & Space Science Institute Hyung-Chul Lim, Yoon-Kyung Seo, Jang-Hyun Park & Young-Su Kim.

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Presentation transcript:

Status and Progress of ARGO Jong Uk (James) Park Korea Astronomy & Space Science Institute Hyung-Chul Lim, Yoon-Kyung Seo, Jang-Hyun Park & Young-Su Kim Korea Astronomy and Space Science Institute Young Su Son Korea Institute of Machinary and Materials Yong Ki Kim Kongju National University

2 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Outline Backgrounds Overview of ARGO Project Requirements of ARGO System Summary 5 Milestone of ARGO Project

3 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Backgrounds Space Geodesy in KASI was started from early 90’s and now... 9 permanent GPS sites IGS site (DAEJ) IGS Global Data Center 3 VLBIs & Correlation Center Space Mission (KOMPSAT-5) Geodynamics, GNSS meteorology, Gravity, and other applications with very passionate staffs. The objective of this presentation is to show the current status and forthcoming steps of ARGO project; Korean new SLR systems.

4 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Korean GPS Networks  85 GPS Reference Stations including 2 IGS sites operated by 5 Agencies or Institutes  Well-distributed, nationwide GPS network with 20~50 Km inter-spacing  National Reference of Geodetic Coordinate, Mapping, Survey, Cartography, Navigation, ITS, LBS and Space Geodesy  Modernization plan for next generation GNSS services in near future  85 GPS Reference Stations including 2 IGS sites operated by 5 Agencies or Institutes  Well-distributed, nationwide GPS network with 20~50 Km inter-spacing  National Reference of Geodetic Coordinate, Mapping, Survey, Cartography, Navigation, ITS, LBS and Space Geodesy  Modernization plan for next generation GNSS services in near future Backgrounds – GNSS

5 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Backgrounds - VLBI Korean VLBI Networks Main Spec. Diameter21m MountingAZ/EL type Aperture Operating RangeAZ :± 270°, EL: 0~90° Operating Speed1"/sec ~ 3°/sec Max. Acceleration3°/sec ² Pointing wind 10m/sec Surface Accuracy 65 ㎛ (Manufacturing) Total Accuracy 150 ㎛ 10m/s) Frequency 2/8GHz, 22GHz, 43GHz 86GHz, 129GHz Seoul Ulsan Jeju  Three 21m Antennas  by KASI  Astronomy/Geodesy  Three 21m Antennas  by KASI  Astronomy/Geodesy

6 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 No! (STSAT-2) (KOMPSAT-5) Laser Retro-Reflector Array Backgrounds - SLR  Feasibility Study on Korean SLR system in 2004/2005  Planning Study on the R&D Project for SLR in 2005/2006  Development of Korean SLR Systems from 2008  40 Cm Mobile (ARGO-M) in 2011 and 1 M Fixed (ARGO-F) in 2013  STSAT-2 in 2009 and KOMPSAT-5 in 2010  Feasibility Study on Korean SLR system in 2004/2005  Planning Study on the R&D Project for SLR in 2005/2006  Development of Korean SLR Systems from 2008  40 Cm Mobile (ARGO-M) in 2011 and 1 M Fixed (ARGO-F) in 2013  STSAT-2 in 2009 and KOMPSAT-5 in 2010 Korean SLR System

7 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 KOMPSAT-5 +Z Nadir Direction +Y 33.7 Deg +X 23 Deg Backgrounds – KOMPSAT 5

8 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Overview of ARGO Project  ARGO: Accurate Ranging system for Geodetic Observation  The Name of Korean SLR program  It comes from the ship on which a great group of heroes boarded to find the Golden Fleece in the ancient Greek mythology  means also a group of specialists to carry out a great mission  Development Phase: 2008 – 2013 (6 years )  Final Goal  One fixed system(1m) and one mobile system(40cm)  Team members & Supporters  KASI, KIMM, KAERI, SatRec & Kongju Univ.  Advisory Committees, ILRS, … All of You!!

9 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Requirements - General  Tracking Coverage Possible to track satellites in the altitude of 25,000km STSAT-2, KOMPSAT-5, GPS, Galileo Satellites  Ranging Accuracy Lageos : 10mm(SS), 2-3mm(NP) GPS and Galileo : 20mm(SS), 3-5mm(NP) Ground Target : 3mm(SS), 1mm(NP) Epoch for NP data within 0.12μs of GPS time  Automatic Operation All system can be controlled from the remote site for the SLR systems Automatic observation according to the schedule and aircraft detection using radar Automated calibration by star camera and ground target Automated scheduling, planning and orbit prediction capability Automated diagnostic warning to network monitor  Etc Daylight tracking Optical tracking for the spacecraft and space launch vehicle (ARGO-F)

10 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 ClassificationARGO-MARGO-F Rx Telescope TypeCassegrainRichey-Cretien Aperture(cm)40100 Tx Telescope TypeRefractorRichey-Cretien Aperture(cm)10100 Generals M1 F Ratio1.5 FOV10 arc minutes50 arc seconds Tube Length975 mm1425 mm MaterialsZerodur/CFRP Tx.Rx pathSeparatePerforate mirror Daylight filter Oven controlled spectral filter Fabry-Perot Daylight Filter Bandwidth(nm) 0.31 Optics system Requirements - Optics

11 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 ClassificationARGO-MARGO-F Mount TypeEL over AZ Max slew rate Az (deg/s)20 Max slew rate El (deg/s)10 Max used tracking rate Az (deg/s)>= 5TBD Max used tracking rate El (deg/s)>= 2TBD Pointing accuracy (arc sec)TBD<= 5 Angle encoder accuracy (“)<0.1 Min. tracking elevation (deg)15 MotorsPMSM Torque Motors Motor controlServo control Drive typeDirect drive Tracking Mount Requirements - Mount

12 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 ClassificationARGO-MARGO-F Laser typeNd:YAG Primary wavelength (nm)1064 Primary max. energy (mJ) Not used for ranging Secondary wavelength (nm)532 Secondary max. energy (mJ) 120 Xmit energy adjustableNoYes Pulse width(FWHM) (ps)10<100 Max. repetition rate (Hz) Fullw. Beam divergence (“) Eye-safeNo Laser system Requirements - Laser

13 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 ClassificationARGO-MARGO-F Chain wavelength532 Detector TypeCSPAD FoV (“) Signal Processing Type Time walk compensated Time walk internally Amplitude measurement N/AYes Return-rate controlledYes Mode of operationMuti photonsSingle to Multi photons Time of Flight Observation TypeEvent timer Resolution (ps)<1.5 Precision (ps)<10 Optoelectronics system Requirements - Electronics

14 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 ClassificationARGO-MARGO-F Tracking Capabilities SatellitesGPS (21,000km)Yes Average values for Lageos Single shot RMS (mm)8<10 # of obs. per NP~ 12,000~ 100 Range gate width (ns) ,200 Beam pointing accuracy(“)52 Operation Secondary MissionNothingOptical tracking Remotely controllableYes Calibration Calibration type/locationPre+Post / External Mode of operationFew photonsSingle to multi Single shot RMS (mm)<3 Frequency Standard TypeCrystal oscillator Epoch accuracy (ns)<100 Preprocessing information On-site NP generationYes Upload intervalDaily Aircraft detectionRadar + ATC data Operation and Control system Requirements - Operation

15 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 Milestone of ARGO Development CDR PDR Development & Manufacture PDR (09.10) SDR (09.03) SRR (08.07) SRR SDR 1 st Stage ARGO nd Stage ARGO-F (Fixed) Spec. decision SDR/PDR/CDR (Optics, Mount, Laser, Photon-electronics Outsourcing (Additional systems) Site candidate surveying Site decision & Station Design Station Construction SDR/PDR/CDR (Operation, Remote Control system) System Integration Test Operation & Solving problems CDR (10.10) SRR(08.07) SDR(08.11) PDR(09.04) CDR(09.09) ARGO-M (Mobile) Spec. decision SDR/PDR/CDR (Optics, Mount, Dome, etc) SDR/PDR/CDR (Operation, Photon-electronics) Outsourcing (Laser, Additional systems) Test Operation & Solving problems Remarks ARGO-M ARGO-F Laser Tracking (STSAT-2, KOMPSAT-5) ILRS Associate AC Complete (10.10) System Integration TROS (China) Operation Univ. Institute International cooperation Development & Manufacture Complete (12.12) STSAT-2 Launch KOMPSAT-5 Launch

16 16 th International Workshop on Laser Ranging, October 2008 Poznan, Poland / 16 ARGO System ARGO, the name of forthcoming Korean SLR Systems, officially started from Jan. 1 st, 2008 to build a 40 cm mobile SLR system and 1 meter fixed SLR system. The lightweight telescopes, a KHz laser, remote control and fully automation concept are introduced for ARGO-M & ARGO-F. ARGO will be the member of ILRS sites in 2012 and 2014, respectively 1 Related Missions Space Programs equipped with LRRA STSAT-2 in 2009 & KOMPSAT-5 in 2010 Planned fundamental Station in Korea Korean 2th science complex in Antarctic ILN Program & Lunar Exploration 2020 Project 2 Summary

Thank you !!!