DOCSLIB.ORG

DOPA) and the DOPA Explorer (Beta)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
DOPA) and the DOPA Explorer (Beta) An introduction to the Digital Observatory for Protected Areas (DOPA) and the DOPA Explorer (Beta) Grégoire Dubois, Michael Schulz, Jon Skøien, Andrew Cottam, William Temperley, Marco Clerici, Evangelia Drakou, Jurriaan van’t Klooster, Bart Verbeeck, Ilaria Palumbo, Pascal Derycke, Jean- François Pekel, Javier Martínez-López, Stephen Peedell, Philippe Mayaux 2013 Report EUR 26207 EN European Commission Joint Research Centre Institute for Environment and Sustainability Contact information Grégoire Dubois Address: Joint Research Centre, Via Enrico Fermi 2749, TP 440, 21027 Ispra (VA), Italy E-mail: [email protected] Tel.: +39 (0)332 786360 Fax: +39 (0)332 789960 http://dopa.jrc.ec.europa.eu/ http://www.jrc.ec.europa.eu/ This publication is a Reference Report by the Joint Research Centre of the European Commission. Legal Notice Neither the European Commission nor any person acting on behalf of the Commission is responsible for the use which might be made of this publication. Europe Direct is a service to help you find answers to your questions about the European Union Freephone number (*): 00 800 6 7 8 9 10 11 (*) Certain mobile telephone operators do not allow access to 00 800 numbers or these calls may be billed. A great deal of additional information on the European Union is available on the Internet. It can be accessed through the Europa server http://europa.eu/. JRC 85042 EUR 26207 EN ISBN 978-92-79-33612-6 (pdf) ISSN 1831-9424 (online) doi:10.2788/31842 Luxembourg: Publications Office of the European Union, 2013 © European Union, 2013 Reproduction is authorised provided the source is acknowledged. Printed in Italy “We are drowning in information, while starving for wisdom. The world henceforth will be run by synthesizers, people able to put together the right information at the right time, think critically about it, and make important choices wisely.” E. Wilson, 1998, Consilience TABLE OF CONTENTS Abstract ................................................................................................................................................... 3 Acknowledgements ................................................................................................................................. 5 Funding ................................................................................................................................................... 5 1. Introduction .................................................................................................................................... 7 1.1. The African Protected Areas Assessment Tool (APAAT) legacy .............................................. 7 1.2. From the APAAT to DOPA, evolving from web pages to web services ................................... 8 1.3. Contributions from Critical Biodiversity Data and Models Infrastructures ............................ 9 1.3.1. The UNEP World Conservation Monitoring Centre (UNEP-WCMC) ............................. 10 1.3.2. International Union for Conservation of Nature (IUCN) ............................................... 10 1.3.3. BirdLife International .................................................................................................... 10 1.3.4. The Global Biodiversity Information Facility (GBIF) Secretariat ................................... 10 1.3.5. The Joint Research Centre of the European Commission ............................................. 10 1.4. Open Data and Model services supporting DOPA ................................................................ 11 1.4.1. eSpecies for indicators on species richness and diversity ............................................ 12 1.4.2. Ecosystem services ........................................................................................................ 12 1.4.3. eHabitat for habitat and ecological niche modelling .................................................... 12 1.4.4. eStation for the monitoring of terrestrial ecosystems ................................................. 12 1.4.5. eMarine for the monitoring of marine ecosystems ...................................................... 12 1.4.6. Land cover change and threats to protected areas ...................................................... 13 1.4.7. Protected areas governance and management effectiveness ..................................... 13 2. The DOPA Explorer ........................................................................................................................ 15 2.1. End Users .............................................................................................................................. 16 2.2. DOPA Explorer Beta .............................................................................................................. 18 3. Using the graphical user interface of DOPA Explorer Beta in 6 steps........................................... 19 Step 1: Accessing DOPA Explorer and language selection ................................................................ 19 Step 2: Selecting the area of interest ................................................................................................ 20 Step 3: Summary statistics from the right navigation panel............................................................. 21 Step 4: Selecting a protected area .................................................................................................... 22 Step 5: Thematic information on protected areas ........................................................................... 24 Step 6: Summary information from the left navigation panel .......................................................... 25 4. Indicators and data sources .......................................................................................................... 27 4.1. Summary information: stratification by country and ecoregion .......................................... 27 4.2. Protected areas and regional coverage ................................................................................ 28 4.2.1. Country statistics ........................................................................................................... 28 4.2.2. Ecoregion statistics ....................................................................................................... 29 4.3. Species data and Species Irreplaceability (SI) Indicator ........................................................ 30 4.3.1. The IUCN Red List of Threatened Species (RLTS) .......................................................... 30 4.3.2. Species occurrences ...................................................................................................... 31 1 4.3.3. Displaying species lists and composition in DOPA Explorer ......................................... 31 4.3.4. Limitations of species lists............................................................................................. 34 4.3.5. Species Irreplaceability (SI) Indicator ............................................................................ 35 4.4. Habitat Replaceability Index and land cover types (HRI) ...................................................... 38 4.4.1. Assessing uniqueness and connectivity of ecosystems with the HRI ........................... 38 4.4.2. Extracting land cover types of the protected area ....................................................... 42 4.5. Climate information .............................................................................................................. 42 4.6. Ecosystem Services ............................................................................................................... 44 4.6.1. Comparison of Terrestrial Carbon Maps ....................................................................... 44 4.7. Pressure indicators ................................................................................................................ 45 4.7.1. Population Pressure Index (PP) ..................................................................................... 47 4.7.2. Agriculture Pressure Index (AP) .................................................................................... 47 4.8. Fire Ecology ........................................................................................................................... 48 4.9. Phenology ............................................................................................................................. 49 4.9.1. Vegetation ..................................................................................................................... 49 4.9.2. Rainfall .......................................................................................................................... 50 5. Accessing external data with DOPA Explorer................................................................................ 51 5.1. Using selected Web Map Services (WMS) ................................................................................. 51 5.2. Using external Web Map Services (WMS) ................................................................................. 52 6. Current status, known issues and next steps................................................................................ 55 7. Help and Feedback ........................................................................................................................ 57 7.1. DOPA Web site ...................................................................................................................... 57 7.2.
Load more

Recommended publications
  • University of Iowa Instruments in Space
    University of Iowa Instruments in Space A-D13-089-5 Wind Van Allen Probes Cluster Mercury Earth Venus Mars Express HaloSat MMS Geotail Mars Voyager 2 Neptune Uranus Juno Pluto Jupiter Saturn Voyager 1 Spaceflight instruments designed and built at the University of Iowa in the Department of Physics & Astronomy (1958-2019) Explorer 1 1958 Feb. 1 OGO 4 1967 July 28 Juno * 2011 Aug. 5 Launch Date Launch Date Launch Date Spacecraft Spacecraft Spacecraft Explorer 3 (U1T9)58 Mar. 26 Injun 5 1(U9T68) Aug. 8 (UT) ExpEloxrpelro r1e r 4 1915985 8F eJbu.l y1 26 OEGxOpl o4rer 41 (IMP-5) 19697 Juunlye 2 281 Juno * 2011 Aug. 5 Explorer 2 (launch failure) 1958 Mar. 5 OGO 5 1968 Mar. 4 Van Allen Probe A * 2012 Aug. 30 ExpPloiorenre 3er 1 1915985 8M Oarc. t2. 611 InEjuxnp lo5rer 45 (SSS) 197618 NAouvg.. 186 Van Allen Probe B * 2012 Aug. 30 ExpPloiorenre 4er 2 1915985 8Ju Nlyo 2v.6 8 EUxpKlo 4r e(rA 4ri1el -(4IM) P-5) 197619 DJuenc.e 1 211 Magnetospheric Multiscale Mission / 1 * 2015 Mar. 12 ExpPloiorenre 5e r 3 (launch failure) 1915985 8A uDge.c 2. 46 EPxpiolonreeerr 4130 (IMP- 6) 19721 Maarr.. 313 HMEaRgCnIe CtousbpeShaetr i(cF oMxu-1ltDis scaatelell itMe)i ssion / 2 * 2021081 J5a nM. a1r2. 12 PionPeioenr e1er 4 1915985 9O cMt.a 1r.1 3 EExpxlpolorerer r4 457 ( S(IMSSP)-7) 19721 SNeopvt.. 1263 HMaalogSnaett oCsupbhee Sriact eMlluitlet i*scale Mission / 3 * 2021081 M5a My a2r1. 12 Pioneer 2 1958 Nov. 8 UK 4 (Ariel-4) 1971 Dec. 11 Magnetospheric Multiscale Mission / 4 * 2015 Mar.
    [Show full text]
  • Information Summaries
    TIROS 8 12/21/63 Delta-22 TIROS-H (A-53) 17B S National Aeronautics and TIROS 9 1/22/65 Delta-28 TIROS-I (A-54) 17A S Space Administration TIROS Operational 2TIROS 10 7/1/65 Delta-32 OT-1 17B S John F. Kennedy Space Center 2ESSA 1 2/3/66 Delta-36 OT-3 (TOS) 17A S Information Summaries 2 2 ESSA 2 2/28/66 Delta-37 OT-2 (TOS) 17B S 2ESSA 3 10/2/66 2Delta-41 TOS-A 1SLC-2E S PMS 031 (KSC) OSO (Orbiting Solar Observatories) Lunar and Planetary 2ESSA 4 1/26/67 2Delta-45 TOS-B 1SLC-2E S June 1999 OSO 1 3/7/62 Delta-8 OSO-A (S-16) 17A S 2ESSA 5 4/20/67 2Delta-48 TOS-C 1SLC-2E S OSO 2 2/3/65 Delta-29 OSO-B2 (S-17) 17B S Mission Launch Launch Payload Launch 2ESSA 6 11/10/67 2Delta-54 TOS-D 1SLC-2E S OSO 8/25/65 Delta-33 OSO-C 17B U Name Date Vehicle Code Pad Results 2ESSA 7 8/16/68 2Delta-58 TOS-E 1SLC-2E S OSO 3 3/8/67 Delta-46 OSO-E1 17A S 2ESSA 8 12/15/68 2Delta-62 TOS-F 1SLC-2E S OSO 4 10/18/67 Delta-53 OSO-D 17B S PIONEER (Lunar) 2ESSA 9 2/26/69 2Delta-67 TOS-G 17B S OSO 5 1/22/69 Delta-64 OSO-F 17B S Pioneer 1 10/11/58 Thor-Able-1 –– 17A U Major NASA 2 1 OSO 6/PAC 8/9/69 Delta-72 OSO-G/PAC 17A S Pioneer 2 11/8/58 Thor-Able-2 –– 17A U IMPROVED TIROS OPERATIONAL 2 1 OSO 7/TETR 3 9/29/71 Delta-85 OSO-H/TETR-D 17A S Pioneer 3 12/6/58 Juno II AM-11 –– 5 U 3ITOS 1/OSCAR 5 1/23/70 2Delta-76 1TIROS-M/OSCAR 1SLC-2W S 2 OSO 8 6/21/75 Delta-112 OSO-1 17B S Pioneer 4 3/3/59 Juno II AM-14 –– 5 S 3NOAA 1 12/11/70 2Delta-81 ITOS-A 1SLC-2W S Launches Pioneer 11/26/59 Atlas-Able-1 –– 14 U 3ITOS 10/21/71 2Delta-86 ITOS-B 1SLC-2E U OGO (Orbiting Geophysical
    [Show full text]
  • Cluster-C1 Observations on the Geometrical Structure of Linear Magnetic Holes in the Solar Wind at 1 AU
    Ann. Geophys., 28, 1695–1702, 2010 www.ann-geophys.net/28/1695/2010/ Annales doi:10.5194/angeo-28-1695-2010 Geophysicae © Author(s) 2010. CC Attribution 3.0 License. Cluster-C1 observations on the geometrical structure of linear magnetic holes in the solar wind at 1 AU T. Xiao1,2, Q. Q. Shi1,3, T. L. Zhang4, S. Y. Fu3, L. Li1, Q. G. Zong3, Z. Y. Pu3, L. Xie3, W. J. Sun1, Z. X. Liu2, E. Lucek5, and H. Reme6,7 1School of Space Science and Physics, Shandong University at Weihai, Weihai, China 2State Key Laboratory of Space Weather, Center for Space Science and Applied Research, Chinese Academy of Sciences, Beijing, China 3Institute of Space Physics and Applied Technology, Peking University, Beijing, China 4Space Research Institute, Austrian Academy of Sciences, 8042 Graz, Austria 5Space and Atmospheric Physics Group, Blackett Laboratory, Imperial College, London, UK 6CESR, UPS, University of Toulouse, Toulouse, France 7UMR 5187, CNRS, Toulouse, France Received: 8 October 2009 – Revised: 1 June 2010 – Accepted: 16 July 2010 – Published: 20 September 2010 Abstract. Interplanetary linear magnetic holes (LMHs) are 1 Introduction structures in which the magnetic field magnitude decreases with little change in the field direction. They are a 10– Magnetic holes (MHs), also called magnetic decreases 30% subset of all interplanetary magnetic holes (MHs). Us- (MDs), are structures in interplanetary space with significant ing magnetic field and plasma measurements obtained by decreases in the magnetic field magnitude (e.g., Turner et Cluster-C1, we surveyed the LMHs in the solar wind at 1 AU. al., 1977; Winterhalter et al., 1994; Tsurutani and Ho, 1999; In total 567 interplanetary LMHs are identified from the Stevens and Kasper, 2007; Vasquez et al., 2007; Tsurutani magnetic field data when Cluster-C1 was in the solar wind et al., 2009).
    [Show full text]
  • Photographs Written Historical and Descriptive
    CAPE CANAVERAL AIR FORCE STATION, MISSILE ASSEMBLY HAER FL-8-B BUILDING AE HAER FL-8-B (John F. Kennedy Space Center, Hanger AE) Cape Canaveral Brevard County Florida PHOTOGRAPHS WRITTEN HISTORICAL AND DESCRIPTIVE DATA HISTORIC AMERICAN ENGINEERING RECORD SOUTHEAST REGIONAL OFFICE National Park Service U.S. Department of the Interior 100 Alabama St. NW Atlanta, GA 30303 HISTORIC AMERICAN ENGINEERING RECORD CAPE CANAVERAL AIR FORCE STATION, MISSILE ASSEMBLY BUILDING AE (Hangar AE) HAER NO. FL-8-B Location: Hangar Road, Cape Canaveral Air Force Station (CCAFS), Industrial Area, Brevard County, Florida. USGS Cape Canaveral, Florida, Quadrangle. Universal Transverse Mercator Coordinates: E 540610 N 3151547, Zone 17, NAD 1983. Date of Construction: 1959 Present Owner: National Aeronautics and Space Administration (NASA) Present Use: Home to NASA’s Launch Services Program (LSP) and the Launch Vehicle Data Center (LVDC). The LVDC allows engineers to monitor telemetry data during unmanned rocket launches. Significance: Missile Assembly Building AE, commonly called Hangar AE, is nationally significant as the telemetry station for NASA KSC’s unmanned Expendable Launch Vehicle (ELV) program. Since 1961, the building has been the principal facility for monitoring telemetry communications data during ELV launches and until 1995 it processed scientifically significant ELV satellite payloads. Still in operation, Hangar AE is essential to the continuing mission and success of NASA’s unmanned rocket launch program at KSC. It is eligible for listing on the National Register of Historic Places (NRHP) under Criterion A in the area of Space Exploration as Kennedy Space Center’s (KSC) original Mission Control Center for its program of unmanned launch missions and under Criterion C as a contributing resource in the CCAFS Industrial Area Historic District.
    [Show full text]
  • Acceleration of Particles to High Energies in Earth's Radiation Belts
    Space Sci Rev (2012) 173:103–131 DOI 10.1007/s11214-012-9941-x Acceleration of Particles to High Energies in Earth’s Radiation Belts R.M. Millan · D.N. Baker Received: 16 April 2012 / Accepted: 30 September 2012 / Published online: 25 October 2012 © The Author(s) 2012. This article is published with open access at Springerlink.com Abstract Discovered in 1958, Earth’s radiation belts persist in being mysterious and un- predictable. This highly dynamic region of near-Earth space provides an important natural laboratory for studying the physics of particle acceleration. Despite the proximity of the ra- diation belts to Earth, many questions remain about the mechanisms responsible for rapidly energizing particles to relativistic energies there. The importance of understanding the ra- diation belts continues to grow as society becomes increasingly dependent on spacecraft for navigation, weather forecasting, and more. We review the historical underpinning and observational basis for our current understanding of particle acceleration in the radiation belts. Keywords Particle acceleration · Radiation belts · Magnetosphere 1 Introduction 1.1 Motivation Shortly after the discovery of Earth’s radiation belts, the suggestion was put forward that processes occurring locally, in near-Earth space, might be responsible for the high energy particles observed there. Efforts were also carried out to search for an external source that could inject multi-MeV electrons into Earth’s inner magnetosphere where they could then be trapped by the magnetic field. Energetic electrons are in fact observed in interplanetary space, originating at both Jupiter and the sun. However, the electron intensity in Earth’s radiation belts is not correlated with the interplanetary intensity, and a significant external R.M.
    [Show full text]
  • <> CRONOLOGIA DE LOS SATÉLITES ARTIFICIALES DE LA
    1 SATELITES ARTIFICIALES. Capítulo 5º Subcap. 10 <> CRONOLOGIA DE LOS SATÉLITES ARTIFICIALES DE LA TIERRA. Esta es una relación cronológica de todos los lanzamientos de satélites artificiales de nuestro planeta, con independencia de su éxito o fracaso, tanto en el disparo como en órbita. Significa pues que muchos de ellos no han alcanzado el espacio y fueron destruidos. Se señala en primer lugar (a la izquierda) su nombre, seguido de la fecha del lanzamiento, el país al que pertenece el satélite (que puede ser otro distinto al que lo lanza) y el tipo de satélite; este último aspecto podría no corresponderse en exactitud dado que algunos son de finalidad múltiple. En los lanzamientos múltiples, cada satélite figura separado (salvo en los casos de fracaso, en que no llegan a separarse) pero naturalmente en la misma fecha y juntos. NO ESTÁN incluidos los llevados en vuelos tripulados, si bien se citan en el programa de satélites correspondiente y en el capítulo de “Cronología general de lanzamientos”. .SATÉLITE Fecha País Tipo SPUTNIK F1 15.05.1957 URSS Experimental o tecnológico SPUTNIK F2 21.08.1957 URSS Experimental o tecnológico SPUTNIK 01 04.10.1957 URSS Experimental o tecnológico SPUTNIK 02 03.11.1957 URSS Científico VANGUARD-1A 06.12.1957 USA Experimental o tecnológico EXPLORER 01 31.01.1958 USA Científico VANGUARD-1B 05.02.1958 USA Experimental o tecnológico EXPLORER 02 05.03.1958 USA Científico VANGUARD-1 17.03.1958 USA Experimental o tecnológico EXPLORER 03 26.03.1958 USA Científico SPUTNIK D1 27.04.1958 URSS Geodésico VANGUARD-2A
    [Show full text]
  • A Y' 1969-Deeber 1972
    - -7 5, 41, AN MA 969-DECEMBER43 D 47 197 AY' 1969-DEEBER 1972 S(NASA-TM-X-70481) TRAJECTORIES OF N73-33809 EXPLORERS 33, 35, 41, 43 AND 47, MAY 1969 - DEC. 1972 (NASA) 72 p HC $5.75 CSCL 22C Unclas "f -" G3/30 19441 D.' -'.FAIRFIELD K. W. BEAANNON( R. P LEPPING N. F. NESS "NFORMATN SERVI-E i -- SSpringfield, _ e te. VA.o Com 22151 e 1 AR -SPAC FLIGHT CETER S-ENBET MA RYLAND -N 14 N- TRAJECTORIES OF EXPLORERS 33, 35, 41, 43 and 47 May 1969-Dec 1972 D.H. Fairfield K.W. Behannon R.P. Lepping N.F. Ness Laboratory for Extraterrestrial Physics Goddard Space Flight Center Greenbelt, Maryland October 1973 /0 This document represents a continuation of a previous document (Behannon et al. 1970) and is presented with the intention that it will stimulate and facilitate correlative studies of data from various spacecraft. Figures 1-54 consist primarily of solar ecliptic plane projections of orbits of five different satellites although a limited number of XZ projections are shown to illustrate the large excursions of Explorer 33 away from the ecliptic plane. Nominal positions of the magnetopause and bow shock are included for reference. The plots are intended only to represent the trajectory of the spacecraft and imply nothing about the operational status of the various experiments nor the availability of the data. Information on these latter points can be ob- tained from the National Space Science Data Center, (e.g. King, 1971). It should be pointed out, however, that Explorers33 and 35 were very long lived spacecraft (> 2 yrs) and numerous experiments either ceased operation or exhibited a gradual deterioration during the extended lifetime.
    [Show full text]
  • Table of Artificial Satellites Launched in 1971
    This electronic version (PDF) was scanned by the International Telecommunication Union (ITU) Library & Archives Service from an original paper document in the ITU Library & Archives collections. La présente version électronique (PDF) a été numérisée par le Service de la bibliothèque et des archives de l'Union internationale des télécommunications (UIT) à partir d'un document papier original des collections de ce service. Esta versión electrónica (PDF) ha sido escaneada por el Servicio de Biblioteca y Archivos de la Unión Internacional de Telecomunicaciones (UIT) a partir de un documento impreso original de las colecciones del Servicio de Biblioteca y Archivos de la UIT. (ITU) ﻟﻼﺗﺼﺎﻻﺕ ﺍﻟﺪﻭﻟﻲ ﺍﻻﺗﺤﺎﺩ ﻓﻲ ﻭﺍﻟﻤﺤﻔﻮﻇﺎﺕ ﺍﻟﻤﻜﺘﺒﺔ ﻗﺴﻢ ﺃﺟﺮﺍﻩ ﺍﻟﻀﻮﺋﻲ ﺑﺎﻟﻤﺴﺢ ﺗﺼﻮﻳﺮ ﻧﺘﺎﺝ (PDF) ﺍﻹﻟﻜﺘﺮﻭﻧﻴﺔ ﺍﻟﻨﺴﺨﺔ ﻫﺬﻩ .ﻭﺍﻟﻤﺤﻔﻮﻇﺎﺕ ﺍﻟﻤﻜﺘﺒﺔ ﻗﺴﻢ ﻓﻲ ﺍﻟﻤﺘﻮﻓﺮﺓ ﺍﻟﻮﺛﺎﺋﻖ ﺿﻤﻦ ﺃﺻﻠﻴﺔ ﻭﺭﻗﻴﺔ ﻭﺛﻴﻘﺔ ﻣﻦ ﻧﻘﻼ ً◌ 此电子版(PDF版本)由国际电信联盟(ITU)图书馆和档案室利用存于该处的纸质文件扫描提供。 Настоящий электронный вариант (PDF) был подготовлен в библиотечно-архивной службе Международного союза электросвязи путем сканирования исходного документа в бумажной форме из библиотечно-архивной службы МСЭ. © International Telecommunication Union A COSMOS-428 1971 57A E 0 COSMOS-429 1971 61A COSMGS-430 1971 62A COSMOS-431 1971 65A APOLLO-14 1971 8A COSMOS-432 1971 66A EOLE 1971 71A OAR-901 1971 67C APOLLO-15 1971 63A COSMOS-433 1971 68A EXPLORER-43 1971 19A CAR-907 1971 67D APOLLO-15 CSUB•SAT 3 1971 63D COSMOS-434 1971 69A EXPLORER-44 1971 58A OREOL-1 1971 119A ARIEL-4 1971 109A COSMOS-435 1971 72A EXPLORER-45 1971 96A OSO- 7 1971 83A COSMOS-436
    [Show full text]
  • Index of Astronomia Nova
    Index of Astronomia Nova Index of Astronomia Nova. M. Capderou, Handbook of Satellite Orbits: From Kepler to GPS, 883 DOI 10.1007/978-3-319-03416-4, © Springer International Publishing Switzerland 2014 Bibliography Books are classified in sections according to the main themes covered in this work, and arranged chronologically within each section. General Mechanics and Geodesy 1. H. Goldstein. Classical Mechanics, Addison-Wesley, Cambridge, Mass., 1956 2. L. Landau & E. Lifchitz. Mechanics (Course of Theoretical Physics),Vol.1, Mir, Moscow, 1966, Butterworth–Heinemann 3rd edn., 1976 3. W.M. Kaula. Theory of Satellite Geodesy, Blaisdell Publ., Waltham, Mass., 1966 4. J.-J. Levallois. G´eod´esie g´en´erale, Vols. 1, 2, 3, Eyrolles, Paris, 1969, 1970 5. J.-J. Levallois & J. Kovalevsky. G´eod´esie g´en´erale,Vol.4:G´eod´esie spatiale, Eyrolles, Paris, 1970 6. G. Bomford. Geodesy, 4th edn., Clarendon Press, Oxford, 1980 7. J.-C. Husson, A. Cazenave, J.-F. Minster (Eds.). Internal Geophysics and Space, CNES/Cepadues-Editions, Toulouse, 1985 8. V.I. Arnold. Mathematical Methods of Classical Mechanics, Graduate Texts in Mathematics (60), Springer-Verlag, Berlin, 1989 9. W. Torge. Geodesy, Walter de Gruyter, Berlin, 1991 10. G. Seeber. Satellite Geodesy, Walter de Gruyter, Berlin, 1993 11. E.W. Grafarend, F.W. Krumm, V.S. Schwarze (Eds.). Geodesy: The Challenge of the 3rd Millennium, Springer, Berlin, 2003 12. H. Stephani. Relativity: An Introduction to Special and General Relativity,Cam- bridge University Press, Cambridge, 2004 13. G. Schubert (Ed.). Treatise on Geodephysics,Vol.3:Geodesy, Elsevier, Oxford, 2007 14. D.D. McCarthy, P.K.
    [Show full text]
  • Table of Artificial Satellites Launched in 1978
    This electronic version (PDF) was scanned by the International Telecommunication Union (ITU) Library & Archives Service from an original paper document in the ITU Library & Archives collections. La présente version électronique (PDF) a été numérisée par le Service de la bibliothèque et des archives de l'Union internationale des télécommunications (UIT) à partir d'un document papier original des collections de ce service. Esta versión electrónica (PDF) ha sido escaneada por el Servicio de Biblioteca y Archivos de la Unión Internacional de Telecomunicaciones (UIT) a partir de un documento impreso original de las colecciones del Servicio de Biblioteca y Archivos de la UIT. (ITU) ﻟﻼﺗﺼﺎﻻﺕ ﺍﻟﺪﻭﻟﻲ ﺍﻻﺗﺤﺎﺩ ﻓﻲ ﻭﺍﻟﻤﺤﻔﻮﻇﺎﺕ ﺍﻟﻤﻜﺘﺒﺔ ﻗﺴﻢ ﺃﺟﺮﺍﻩ ﺍﻟﻀﻮﺋﻲ ﺑﺎﻟﻤﺴﺢ ﺗﺼﻮﻳﺮ ﻧﺘﺎﺝ (PDF) ﺍﻹﻟﻜﺘﺮﻭﻧﻴﺔ ﺍﻟﻨﺴﺨﺔ ﻫﺬﻩ .ﻭﺍﻟﻤﺤﻔﻮﻇﺎﺕ ﺍﻟﻤﻜﺘﺒﺔ ﻗﺴﻢ ﻓﻲ ﺍﻟﻤﺘﻮﻓﺮﺓ ﺍﻟﻮﺛﺎﺋﻖ ﺿﻤﻦ ﺃﺻﻠﻴﺔ ﻭﺭﻗﻴﺔ ﻭﺛﻴﻘﺔ ﻣﻦ ﻧﻘﻼ ً◌ 此电子版(PDF版本)由国际电信联盟(ITU)图书馆和档案室利用存于该处的纸质文件扫描提供。 Настоящий электронный вариант (PDF) был подготовлен в библиотечно-архивной службе Международного союза электросвязи путем сканирования исходного документа в бумажной форме из библиотечно-архивной службы МСЭ. © International Telecommunication Union Table of artificial satellites launched in 1978 COSMOS-1 012 1978 54A C0SM0S-1064 1978 119A MOLNYA-1 (40 ) 1978 55A A C0SM0S-1013 1978 56A C0SM0S-1065 1978 120A MOLNYA-1 (41) 1978 72 A COSMOS-1066 1 21A MOLNYA-1 (42) 1978 80A AMSAT-OSCAR-8 1978 26B C0SM0S-1014 1978 56B 1978 MOLNYA-3 (9) 1 978 9A ANIK-B1 1978 116A C0SM0S-1015 1978 56 C COSMOS-1067 1978 122A C0SM0S-1016 1978 56D COSMOS-1 068 1978
    [Show full text]
  • United States Space Program Firsts
    KSC Historical Report 18 KHR-18 Rev. December 2003 UNITED STATES SPACE PROGRAM FIRSTS Robotic & Human Mission Firsts Kennedy Space Center Library Archives Kennedy Space Center, Florida Foreword This summary of the United States space program firsts was compiled from various reference publications available in the Kennedy Space Center Library Archives. The list is divided into four sections. Robotic mission firsts, Human mission firsts, Space Shuttle mission firsts and Space Station mission firsts. Researched and prepared by: Barbara E. Green Kennedy Space Center Library Archives Kennedy Space Center, Florida 32899 phone: [321] 867-2407 i Contents Robotic Mission Firsts ……………………..........................……………...........……………1-4 Satellites, missiles and rockets 1950 - 1986 Early Human Spaceflight Firsts …………………………............................……........…..……5-8 Projects Mercury, Gemini, Apollo, Skylab and Apollo Soyuz Test Project 1961 - 1975 Space Shuttle Firsts …………………………….........................…………........……………..9-12 Space Transportation System 1977 - 2003 Space Station Firsts …………………………….........................…………........………………..13 International Space Station 1998-2___ Bibliography …………………………………..............................…………........…………….....…14 ii KHR-18 Rev. December 2003 DATE ROBOTIC EVENTS MISSION 07/24/1950 First missile launched at Cape Canaveral. Bumper V-2 08/20/1953 First Redstone missile was fired. Redstone 1 12/17/1957 First long range weapon launched. Atlas ICBM 01/31/1958 First satellite launched by U.S. Explorer 1 10/11/1958 First observations of Earth’s and interplanetary magnetic field. Pioneer 1 12/13/1958 First capsule containing living cargo, squirrel monkey, Gordo. Although not Bioflight 1 a NASA mission, data was utilized in Project Mercury planning. 12/18/1958 First communications satellite placed in space. Once in place, Brigadier Project Score General Goodpaster passed a message to President Eisenhower 02/17/1959 First fully instrumented Vanguard payload.
    [Show full text]
  • 2010 Mad River Canoe Is a Registered Trademark of Confluence Watersports
    he story of Mad River Canoe begins in a patch of ferns, oh so long ago, with friend Rabbit. TNative American legend has it that Rabbit was a great hunter and a bit of a trickster, but most of all Rabbit was confident in his abilities. So confident in fact, that even as Lynx circles the fern, planning his attack, Rabbit is free to enjoy his pipe, secure in his abilities to avoid this mortal enemy. Within every legend, there is truth. And the truth in the legend of Rabbit is that confidence is a powerful asset when backed up by ability. The confidence you share with your Mad River Canoe will be backed up by our ability to produce the finest craft of its kind. We like to think that every Mad River Canoe is crafted from both truth and legend. For legends inspire us toward greatness, yet only through truth can we achieve it. I n n ova t e t h e n. O ur story continues on a picturesque hillside in Vermont, circa: 1971. In his backyard shed, Jim henry, the company founder, began his mission to build a better canoe through innovative thought, design and materials. With confidence in his abilities, he designed and built the first Malacite. he then raced in – and won – the downriver national Championship and the rest, you know. Word spread and demand grew. A tradition of innovation was born. From the beginning, Mad river Canoe explored new designs and experimented with new materials. We were the first to introduce Kevlar™ to the canoe industry and among the pioneers truth & legend to first mold our own royalex canoes.
    [Show full text]