DOCSLIB.ORG

Space Cooperation Between India and France

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Space Cooperation Between India and France Space cooperation between India and France Céline Bouhey-Klapisz International Affairs, CNES ESPI, 1st February 2017 1 01/02/17 Long standing cooperation … Together in space since 1964 • Space cooperation between India and France turned 50 years in 2014 • celebrated in 2014 during the Bangalore Space Expo & during the Indian Prime Minister visit in France in 2015 • => making it India’s oldest and most important collaboration with a European nation • ISRO is CNES’s number two partner after NASA in terms of volume of activity • Opening of a CNES office in 2013 in Bangalore ([email protected]) 2 50 years French-Indian cooperation French Megha-Tropiques stamp French and Indian posts initiative 3 Living Trust and Commitment It all started with sounding rockets • 1964 : First bilateral agreement • 50 years later / April 2015 : new (licences to build Belier and impetus Centaure sounding rockets in india) • Signature of a CNES and ISRO cooperation agreement during the visit • 50 French rockets were built locally of Indian Prime Minister, Mr. Modi • 1965 : First French sounding rockets launched from India (Trivandrum rocket center) 4 01/02/17 59 INDIAN CENTAURES AND 2 DRAGONS PAVING THE WAY TO RH560 5 LAUNCHER GOLDEN AGE : THE 1970 S French technology still used on Viking / Vikas engine Indian launchers • 1969 : first Indian rocket, Rohini, derived from French technology • 1969: CNES provides technical support to creation of Shriharikota launch base • 1972: India acquires licences for French Viking engine adopted under the name of Vikas still equips India’s entire range of launchers (giving Ariane 4 a sort of second lease of life) • 1977: First India-France intergovernmental space cooperation agreement 6 01/02/17 TWO OPERATIONAL INDO –FRENCH MISSIONS • MEGHA-TROPIQUES • SARAL-ALTIKA 7 01/02/17 TWO OPERATIONAL INDO-FRENCH SPACE MISSIONS (1/2) MEGHA-TROPIQUES : An Earth Observation mission of the tropical atmosphere • First French-Indo satellite • Launched on 12 October 2011 by the Indian PSLV launcher (from Shriharikota) • CNES provides 3 instruments ( Saphir, Scarab & Madras) • Delivers simultaneus measurements of different states of water in the atmosphere • Megha- Tropiques maps atmospheric distribution of water vapour, clouds, rainfall and water evaporation in three dimensions in the tropical belt • The mission also provides relevant data for global Earth climate understanding because tropical processes may also affect the global climate • Since April 2015, EUMETcast broadcast to Meteorological agency near real time data from SAPHIR for assimilation in numerical prediction models • Megha-Tropiques is also part of the constellation of 10 satellites participating in the Global Precipitation Measurement (GPM) mission that NASA, JAXA, ISRO and CNES are pursuing together 8 01/02/17 TWO OPERATIONAL INDO-FRENCH SPACE MISSIONS (2/2) SARAL-Altika : Mission dedicated to the environmental, mainly oceanic, survey • Second joint ISRO-CNES mission • Launched on 25 February 2013 by an Indian PSLV launcher • First scientific and technical Indo-French cooperation in the field of oceanography • Two missions are on-board the SARAL satellite : < ALTIKa mission SARALó Satellite with ARgos and ALtika , also means “easy” in sanskrit सरल < ARGOS-3 mission (data collection and localization instrument) • Provides global measurements of sea-surface heigh of unmatched precision (order of one millimetre) • Provides hightly accurante information to study the freshwater cycle (led to important breakthroughs in the scope of Hydrology) • The Argos system collects data from thousands of transmitters at sea and on land 9 01/02/17 2015 : NEW IMPETUS • 10/04/2015 : signature of an agreement between CNES and ISRO defining the framework for a reinforced cooperation in space activities • Objective: define a new cooperation framework for the implementation of future joint missions • Three fields of cooperation identified : • A joint Thermal Infrared satellite mission (TIR) • Argos 4 mission (to embark Argos 4 on the Oceansat 3 indian satellite) • Cooperation in the field of planetary exploration • 25/01/2016 : signature, in presence of French President, François Hollande, and First Indian Prime Minister, Mr Modi, of THREE cooperation agreements : • Implementing Arrangement (IA) on InfraRed joint satellite • Implementing Arrangement (IA) on Argos 4 -> Oceansat 3 will embark last generation of the French localisation instrument • LoI on planetary exploration -> set up of a working group in view of studying the French participation to future interplanetary indian missions <-> These cooperation agreements are structuring the future of the French-Indo cooperation 10 01/02/17 Joint Climate Surveillance Existing and Planned Missions 11 Indo-French Thermal Infrared Sat Global Heat Exchange Mapping 12 Joint ARGOS Missions Climate and Wildlife Data Collection 13 Indian New Space French Eyes on the Moon • 09/01/17 : CNES signed an agreement with TEAM INDUS, an India private company who is competing for The Google Lunar XPrize • <-> The first ever privately funded trip to the moon • More than a dozen teams from around the world entered the race, and recently XPrize announced the finalized list of five competitors that still remain among which TEAM INDUS • The deal is : The grand prize is $20 million, and the teams have until December 31, 2017 to land an unmanned spacecraft on the moon, travel at least 500 meters and deliver a "mooncast" of high-definition video back to Earth • CNES will provide the cameras • Launched scheduled on December 20, 2017 by a Polar Satellite Launch Vehicle (PSLV) • It's expected to be one of the lightest rovers to reach the moon. 14 Indian New Space French Eyes on the Moon 15 COP 21 AND DECLARATION OF NEW DELHI CNES and ISRO : two space agencies leader in the fight against climate change • 15 Years of cooperation in the field of climate change • 03/04/16, on the joint initiative of Chairman of ISRO, AS Kiran Kumar, and President of CNES, Jean-Yves Le Gall, Head of space agencies gathered in New Delhi and approved the « Declaration of New Delhi » which propose a worldwide system of greenhouses gas emissions reductions satellites, key of the implementation of the COP21 Paris agreement (COP 21) signed in December 2015 • Thanks to the joint exploitation of the two Earth Observation satellites Saral et Megha- Tropiques, CNES and ISRO paved the way to major improvements in the field of climate and its impacts • The two joint • missions recently decided confirm the CNES and ISRO’s commitments for the monitoring of climate from space 16 01/02/17.
Load more

Recommended publications
  • 25 Years of Indian Remote Sensing Satellite (IRS)
    2525 YearsYears ofof IndianIndian RemoteRemote SensingSensing SatelliteSatellite (IRS)(IRS) SeriesSeries Vinay K Dadhwal Director National Remote Sensing Centre (NRSC), ISRO Hyderabad, INDIA 50 th Session of Scientific & Technical Subcommittee of COPUOS, 11-22 Feb., 2013, Vienna The Beginning • 1962 : Indian National Committee on Space Research (INCOSPAR), at PRL, Ahmedabad • 1963 : First Sounding Rocket launch from Thumba (Nov 21, 1963) • 1967 : Experimental Satellite Communication Earth Station (ESCES) established at Ahmedabad • 1969 : Indian Space Research Organisation (ISRO) established (15 August) PrePre IRSIRS --1A1A SatellitesSatellites • ARYABHATTA, first Indian satellite launched in April 1975 • Ten satellites before IRS-1A (7 for EO; 2 Met) • 5 Procured & 5 SLV / ASLV launch SAMIR : 3 band MW Radiometer SROSS : Stretched Rohini Series Satellite IndianIndian RemoteRemote SensingSensing SatelliteSatellite (IRS)(IRS) –– 1A1A • First Operational EO Application satellite, built in India, launch USSR • Carried 4-band multispectral camera (3 nos), 72m & 36m resolution Satellite Launch: March 17, 1988 Baikanur Cosmodrome Kazakhstan SinceSince IRSIRS --1A1A • Established of operational EO activities for – EO data acquisition, processing & archival – Applications & institutionalization – Public services in resource & disaster management – PSLV Launch Program to support EO missions – International partnership, cooperation & global data sets EarlyEarly IRSIRS MultispectralMultispectral SensorsSensors • 1st Generation : IRS-1A, IRS-1B •
    [Show full text]
  • The Space-Based Global Observing System in 2010 (GOS-2010)
    WMO Space Programme SP-7 The Space-based Global Observing For more information, please contact: System in 2010 (GOS-2010) World Meteorological Organization 7 bis, avenue de la Paix – P.O. Box 2300 – CH 1211 Geneva 2 – Switzerland www.wmo.int WMO Space Programme Office Tel.: +41 (0) 22 730 85 19 – Fax: +41 (0) 22 730 84 74 E-mail: [email protected] Website: www.wmo.int/pages/prog/sat/ WMO-TD No. 1513 WMO Space Programme SP-7 The Space-based Global Observing System in 2010 (GOS-2010) WMO/TD-No. 1513 2010 © World Meteorological Organization, 2010 The right of publication in print, electronic and any other form and in any language is reserved by WMO. Short extracts from WMO publications may be reproduced without authorization, provided that the complete source is clearly indicated. Editorial correspondence and requests to publish, reproduce or translate these publication in part or in whole should be addressed to: Chairperson, Publications Board World Meteorological Organization (WMO) 7 bis, avenue de la Paix Tel.: +41 (0)22 730 84 03 P.O. Box No. 2300 Fax: +41 (0)22 730 80 40 CH-1211 Geneva 2, Switzerland E-mail: [email protected] FOREWORD The launching of the world's first artificial satellite on 4 October 1957 ushered a new era of unprecedented scientific and technological achievements. And it was indeed a fortunate coincidence that the ninth session of the WMO Executive Committee – known today as the WMO Executive Council (EC) – was in progress precisely at this moment, for the EC members were very quick to realize that satellite technology held the promise to expand the volume of meteorological data and to fill the notable gaps where land-based observations were not readily available.
    [Show full text]
  • Design of the Wavefront Sensor Unit of ARGOS, the LBT Laser Guide Star System
    UNIVERSITA` DEGLI STUDI DI FIRENZE Dipartimento di Fisica e Astronomia Scuola di Dottorato in Astronomia Ciclo XXIV - FIS05 Design of the wavefront sensor unit of ARGOS, the LBT laser guide star system Candidato: Marco Bonaglia arXiv:1203.5081v1 [astro-ph.IM] 22 Mar 2012 Tutore: Prof. Alberto Righini Cotutore: Dott. Simone Esposito A common use for a glass plate is as a beam splitter, tilted at an angle of 45◦ [:::] Since this can severely degrade the image, such plate beam splitters are not recommended in convergent or divergent beams. W. J. Smith, Modern Optical Engineering. Contents 1 Introduction 1 1.1 The Large Binocular Telescope . 2 1.2 LUCI . 4 1.3 First Light AO system . 5 1.3.1 Angular anisoplanatism . 8 1.4 Wide field AO correction . 9 1.5 Laser guide star AO . 10 1.5.1 Limits of LGS AO . 11 1.5.2 Rayleigh LGS . 13 1.6 LGS-GLAO facilities . 14 1.6.1 GLAS . 15 1.6.2 The MMT GLAO system . 15 1.6.3 SAM . 18 2 ARGOS: a laser guide star AO system for the LBT 21 2.1 System design . 22 2.2 Study of ARGOS performance . 29 2.2.1 The simulation code . 30 2.2.2 Results of ARGOS end-to-end simulations . 36 3 The wavefront sensor dichroic 43 3.1 Effects of a window in a convergent beam . 43 3.2 Aberration compensation with window shape . 47 3.2.1 Effects of a wedge between surfaces . 48 3.2.2 Effects of a cylindrical surface .
    [Show full text]
  • + Return to Flight Implementation Plan -- 12Th Edition (8.4 Mb PDF)
    NASA’s Implementation Plan for Space Shuttle Return to Flight and Beyond A periodically updated document demonstrating our progress toward safe return to flight and implementation of the Columbia Accident Investigation Board recommendations June 20, 2006 Volume 1, Twelfth Edition An electronic version of this implementation plan is available at www.nasa.gov NASA’s Implementation Plan for Space Shuttle Return to Flight and Beyond June 20, 2006 Twelfth Edition Change June 20, 2006 This 12th revision to NASA’s Implementation Plan for Space Shuttle Return to Flight and Beyond provides updates to three Columbia Accident Investigation Board Recommendations that were not fully closed by the Return to Flight Task Group, R3.2-1 External Tank (ET), R6.4-1 Thermal Protection System (TPS) On-Orbit Inspection and Repair, and R3.3-2 Orbiter Hardening and TPS Impact Tolerance. These updates reflect the latest status of work being done in preparation for the STS-121 mission. Following is a list of sections updated by this revision: Message from Dr. Michael Griffin Message from Mr. William Gerstenmaier Part 1 – NASA’s Response to the Columbia Accident Investigation Board’s Recommendations 3.2-1 External Tank Thermal Protection System Modifications (RTF) 3.3-2 Orbiter Hardening (RTF) 6.4-1 Thermal Protection System On-Orbit Inspect and Repair (RTF) Remove Pages Replace with Pages Cover (Feb 17, 2006) Cover (Jun. 20, 2006 ) Title page (Feb 17, 2006) Title page (Jun. 20, 2006) Message From Michael D. Griffin Message From Michael D. Griffin (Feb 17, 2006)
    [Show full text]
  • Final Report for a Robotic Exploration Mission to Mars and Phobos Argos
    NASA-CR-197168 NASw-4435 /'/F/ 4 '_/e'7 t'/-q 1- Final Report for a Robotic Exploration Mission to Mars and Phobos PROJECT AENEAS Response to RFP Number ASE274L.0893 o r,4 u_ 4" submitted to: I ,-- ,0 U i'_ C_ e" 0 Z _ 0 Dr. George Botbyl The University of Texas at Austin Department of Aerospace Engineering and Engineering Mechanics Austin, Texas 78712 Z cn _. submitted by: 0 cO_ 0 Argos Space Endeavours 29 November 1993 zxI_f _rOos 8Face _.aea_ours _roJect Aeneas CDestBn _"eam Fall 1993 Chief Executive Officer Justin H. Kerr Chief Engineer Erin Defoss6 Chief Administrator Quang Ho Engineers Emisto Barriga Grant Davis Steve McCourt Matt Smith Aeneas Project Preliminary Design of a Robotic Exploration Mission to Mars and Phobos Approved: Justin H. Kerr CEO, Argos Space Endeavours Approved: Erin Defoss6 Chief Engineer, Argos Space Endeavours Approved: Quang Ho Administrative Officer, Argos Space Endeavours Argos 8pace q .aca ours University of Texas at Austin Department of Aerospace Engineering and Engineering Mechanics November 1993 Acknowledgments Argos Space Endeavours would like to thank all personnel at The University and in industry who made Project Aeneas possible. This project was conducted with the support of the NASA/USRA Advanced Design Program. Argos Space Endeavours wholeheartedly thanks the following faculty, staff, and students from the University of Texas at Austin: Dr. Wallace Fowler, Dr. Ronald Stearman, Dr. John Lundberg, Professor Richard Drury, Dr. David Dolling, Ms. Kelly Spears, Mr. Elfego Piton, Mr. Tony Economopoulos, and Mr. David Garza. The support of Project Aeneas from the aerospace industry was overwhelming.
    [Show full text]
  • Fusion of Wildlife Tracking and Satellite Geomagnetic Data for the Study of Animal Migration Fernando Benitez-Paez1,2 , Vanessa Da Silva Brum-Bastos1 , Ciarán D
    Benitez-Paez et al. Movement Ecology (2021) 9:31 https://doi.org/10.1186/s40462-021-00268-4 METHODOLOGY ARTICLE Open Access Fusion of wildlife tracking and satellite geomagnetic data for the study of animal migration Fernando Benitez-Paez1,2 , Vanessa da Silva Brum-Bastos1 , Ciarán D. Beggan3 , Jed A. Long1,4 and Urška Demšar1* Abstract Background: Migratory animals use information from the Earth’s magnetic field on their journeys. Geomagnetic navigation has been observed across many taxa, but how animals use geomagnetic information to find their way is still relatively unknown. Most migration studies use a static representation of geomagnetic field and do not consider its temporal variation. However, short-term temporal perturbations may affect how animals respond - to understand this phenomenon, we need to obtain fine resolution accurate geomagnetic measurements at the location and time of the animal. Satellite geomagnetic measurements provide a potential to create such accurate measurements, yet have not been used yet for exploration of animal migration. Methods: We develop a new tool for data fusion of satellite geomagnetic data (from the European Space Agency’s Swarm constellation) with animal tracking data using a spatio-temporal interpolation approach. We assess accuracy of the fusion through a comparison with calibrated terrestrial measurements from the International Real-time Magnetic Observatory Network (INTERMAGNET). We fit a generalized linear model (GLM) to assess how the absolute error of annotated geomagnetic intensity varies with interpolation parameters and with the local geomagnetic disturbance. Results: We find that the average absolute error of intensity is − 21.6 nT (95% CI [− 22.26555, − 20.96664]), which is at the lower range of the intensity that animals can sense.
    [Show full text]
  • Spacecraft Navigation Using X-Ray Pulsars
    JOURNAL OF GUIDANCE,CONTROL, AND DYNAMICS Vol. 29, No. 1, January–February 2006 Spacecraft Navigation Using X-Ray Pulsars Suneel I. Sheikh∗ and Darryll J. Pines† University of Maryland, College Park, Maryland 20742 and Paul S. Ray,‡ Kent S. Wood,§ Michael N. Lovellette,¶ and Michael T. Wolff∗∗ U.S. Naval Research Laboratory, Washington, D.C. 20375 The feasibility of determining spacecraft time and position using x-ray pulsars is explored. Pulsars are rapidly rotating neutron stars that generate pulsed electromagnetic radiation. A detailed analysis of eight x-ray pulsars is presented to quantify expected spacecraft position accuracy based on described pulsar properties, detector parameters, and pulsar observation times. In addition, a time transformation equation is developed to provide comparisons of measured and predicted pulse time of arrival for accurate time and position determination. This model is used in a new pulsar navigation approach that provides corrections to estimated spacecraft position. This approach is evaluated using recorded flight data obtained from the unconventional stellar aspect x-ray timing experiment. Results from these data provide first demonstration of position determination using the Crab pulsar. Introduction sources, including neutron stars, that provide stable, predictable, and HROUGHOUT history, celestial sources have been utilized unique signatures, may provide new answers to navigating through- T for vehicle navigation. Many ships have successfully sailed out the solar system and beyond. the Earth’s oceans using only these celestial aides. Additionally, ve- This paper describes the utilization of pulsar sources, specifically hicles operating in the space environment may make use of celestial those emitting in the x-ray band, as navigation aides for spacecraft.
    [Show full text]
  • ARGOS Advanced Rayleigh Ground Layer Adaptive Optics System
    Large Binocular Telescope ARGOS Advanced Rayleigh Ground layer adaptive Optics System Science Case Study Doc. No. ARGOS PDR 001 Issue 1.1 Date 19.12.2008 Prepared R. Davies 2008/12/19 Name Date Approved S. Rabien 2009/02/04 Name Date Released S. Rabien 2009/02/04 Name Date © ARGOS Consortium Doc: ARGOS PDR 001 Science Case Study Issue 1.1 Date 19.12.2008 Page 2 of 48 TABLE OF CONTENTS Change Record ................................................................................................................................................ 3 Updates from Phase A to PDR........................................................................................................................ 3 Contributing Authors....................................................................................................................................... 4 1 Scope ...................................................................................................................................................... 4 2 Applicable documents ............................................................................................................................ 4 3 Overview ................................................................................................................................................ 5 4 Gains in Science Capability from GLAO............................................................................................... 7 4.1 Increased Point Source Sensitivity................................................................................................
    [Show full text]
  • Case Study: Lunar Mobility • Overview of Past Lunar Rover Missions • Design Review of NASA Robotic Prospector (RP) Rover for Lunar Exploration
    Case Study: Lunar Mobility • Overview of past lunar rover missions • Design review of NASA Robotic Prospector (RP) rover for lunar exploration © 2020 David L. Akin - All rights reserved http://spacecraft.ssl.umd.edu U N I V E R S I T Y O F Slopes and Static Stability ENAE 788X - Planetary Surface Robotics MARYLAND 1 Lunar Motorcycle in KC-135 Testing U N I V E R S I T Y O F Slopes and Static Stability ENAE 788X - Planetary Surface Robotics MARYLAND 8 Lunar Motorcycle in Suspension Testing U N I V E R S I T Y O F Slopes and Static Stability ENAE 788X - Planetary Surface Robotics MARYLAND 9 National Aeronautics and Space Administration RP Rover Tiger Team Mission Overview The Lunar Resource Prospector (RP) rover was an earlier version of what became Volatiles Investigating Polar Exploration Rover (VIPER), which will be launched to the Moon in 2023. The technical details are not necessarily representative of the final VIPER design. Level-1 Mission Requirements 1.1 RP SHALL LAND AT A LUNAR POLAR REGION TO ENABLE PROSPECTING FOR VOLATILES • Full Success Criteria: Land at a polar location that maximizes the combined potential for obtaining a high volatile (hydrogen) concentration signature and mission duration within traverse capabilities • Minimum Success Criteria: Land at a polar location that maximizes the potential for obtaining a high volatile (hydrogen) concentration signature 1.2 RP SHALL BE CAPABLE OF OBTAINING KNOWLEDGE ABOUT THE LUNAR SURFACE AND SUBSURFACE VOLATILES AND MATERIALS • Full Success Criteria: Take both sub-surface measurements
    [Show full text]
  • General Coporation Tax Allocation Percentage Report 2003
    2003 General Corporation Tax Allocation Percentage Report Page - 1- @ONCE.COM INC .02 A AND J TITLE SEARCHING CO INC .01 @RADICAL.MEDIA INC 25.08 A AND L AUTO RENTAL SERVICES INC 1.00 @ROAD INC 1.47 A AND L CESSPOOL SERVICE CORP 96.51 "K" LINE AIR SERVICE U.S.A. INC 20.91 A AND L GENERAL CONTRACTORS INC 2.38 A OTTAVINO PROPERTY CORP 29.38 A AND L INDUSTRIES INC .01 A & A INDUSTRIAL SUPPLIES INC 1.40 A AND L PEN MANUFACTURING CORP 53.53 A & A MAINTENANCE ENTERPRISE INC 2.92 A AND L SEAMON INC 4.46 A & D MECHANICAL INC 64.91 A AND L SHEET METAL FABRICATIONS CORP 69.07 A & E MANAGEMENT SYSTEMS INC 77.46 A AND L TWIN REALTY INC .01 A & E PRO FLOOR AND CARPET .01 A AND M AUTO COLLISION INC .01 A & F MUSIC LTD 91.46 A AND M ROSENTHAL ENTERPRISES INC 51.42 A & H BECKER INC .01 A AND M SPORTS WEAR CORP .01 A & J REFIGERATION INC 4.09 A AND N BUSINESS SERVICES INC 46.82 A & M BRONX BAKING INC 2.40 A AND N DELIVERY SERVICE INC .01 A & M FOOD DISTRIBUTORS INC 93.00 A AND N ELECTRONICS AND JEWELRY .01 A & M LOGOS INTERNATIONAL INC 81.47 A AND N INSTALLATIONS INC .01 A & P LAUNDROMAT INC .01 A AND N PERSONAL TOUCH BILLING SERVICES INC 33.00 A & R CATERING SERVICE INC .01 A AND P COAT APRON AND LINEN SUPPLY INC 32.89 A & R ESTATE BUYERS INC 64.87 A AND R AUTO SALES INC 16.50 A & R MEAT PROVISIONS CORP .01 A AND R GROCERY AND DELI CORP .01 A & S BAGEL INC .28 A AND R MNUCHIN INC 41.05 A & S MOVING & PACKING SERVICE INC 73.95 A AND R SECURITIES CORP 62.32 A & S WHOLESALE JEWELRY CORP 78.41 A AND S FIELD SERVICES INC .01 A A A REFRIGERATION SERVICE INC 31.56 A AND S TEXTILE INC 45.00 A A COOL AIR INC 99.22 A AND T WAREHOUSE MANAGEMENT CORP 88.33 A A LINE AND WIRE CORP 70.41 A AND U DELI GROCERY INC .01 A A T COMMUNICATIONS CORP 10.08 A AND V CONTRACTING CORP 10.87 A A WEINSTEIN REALTY INC 6.67 A AND W GEMS INC 71.49 A ADLER INC 87.27 A AND W MANUFACTURING CORP 13.53 A AND A ALLIANCE MOVING INC .01 A AND X DEVELOPMENT CORP.
    [Show full text]
  • JTA-29 Final Report
    INTERGOVERNMENTAL OCEANOGRAPHIC WORLD METEOROLOGICAL ORGANIZATION COMMISSION (OF UNESCO) _____________ ___________ ARGOS JOINT TARIFF AGREEMENT TWENTY-NINTH MEETING Paris, France, 2-3 October 2009 FINAL REPORT NOTES WMO DISCLAIMER Regulation 42 Recommendations of working groups shall have no status within the Organization until they have been approved by the responsible constituent body. In the case of joint working groups, the recommendations must be concurred with by the presidents of the constituent bodies concerned before being submitted to the designated constituent body. Regulation 43 In the case of a recommendation made by a working group between sessions of the responsible constituent body, either in a session of a working group or by correspondence, the president of the body may, as an exceptional measure, approve the recommendation on behalf of the constituent body when the matter is, in his opinion, urgent, and does not appear to imply new obligations for Members. He may then submit this recommendation for adoption by the Executive Council or to the President of the Organization for action in accordance with Regulation 9(5). © World Meteorological Organization, 2008 The right of publication in print, electronic and any other form and in any language is reserved by WMO. Short extracts from WMO publications may be reproduced without authorization provided that the complete source is clearly indicated. Editorial correspondence and requests to publish, reproduce or translate this publication (articles) in part or in whole should be addressed to: Chairperson, Publications Board World Meteorological Organization (WMO) 7 bis, avenue de la Paix Tel.: +41 (0)22 730 84 03 P.O. Box No.
    [Show full text]
  • Special Edition
    argos FORUM # 85 11/18 SPECIAL EDITION EUROPEAN USER CONFERENCE ON ARGOS WILDLIFE Innovations in Argos wildlife SHARE, EXCHANGE, DISCOVER - 1 - ARGOS FORUM # 85 ArgosForum is published by CLS (www.cls.fr) ISSN : 1638 -315x Cover: ©UEA-BirdLife-EBBCC Publication director: Christophe Vassal Editorial directors: Marie-Claire Demmou [email protected] Yann Bernard [email protected] Editor-in-Chief Marianna Childress [email protected] Contributed to this issue: Alexa Burgunder [email protected] Anne-Marie Bréonce [email protected] Sophe Baudel [email protected] Aline Duplaa [email protected] Anna Salsac-Jimenez [email protected] Design: Ogham Printing: Delort Printed on recycled paper. www.argos-system.org - 2 - ARGOS FORUM # 85 © CLS FOR 40 YEARS, Argos has been the key tool of Earth scientists and Life scientists to study our physical environment and reveal the mysteries of the animal world. With over 100,000 animals tracked since its inception, Argos is the only satellite system that caters to biologists, with miniaturized platforms, low power transmitters, and the ability to send data in extremely difficult conditions. Argos manufacturers are largely responsible for the innovations that have pushed the limits of Argos satellite telemetry ever further, to track more than 1,000 species today. Our mission is to build on this successful past, continuing to work hand in hand with scientists and manufacturers, while introducing more satellites, a wider frequency bandwidth dedicated to low power transmitters, and greater transmission capabilities so scientists can send more positions and more sensor data, via ever smaller, light-weight tags. To do so, Argos joins the New Space movement while maintaining close ties to the international space agencies that govern the system (CNES, ISRO, EUMETSAT, NOAA).
    [Show full text]