82 Commission 3 – Earth Rotation and Geodynamics HAGEDOORN J.M., WOLF D.: Pleistocene and Recent deglaciation in Svalbard: implications for tide-gauge, GPS and VLBI measurements. J. Geodyn., 35, 415-423, 2003. HAGEDOORN J.M., WOLF D., MARTINEC Z.: An estimate of global mean sea-level rise inferred from tide-gauge measurements using glacial-isostatic models consistent with the relative sea-level record. Pure Appl. Geophys., 164, 791-818, doi: 10.1007/s00024-007-0186-7, 2007. HERGERT T., HEIDBACH O.: New insights into the mechanism of postseismic stress relaxation exemplified by the 23 June 2001 Mw=8.4 earthquake in southern Peru. Geophys. Res. Lett. (33) L02307, 4pp, 2006. JACOBY W.R., CAVSAK H.: Inversion of gravity anomalies over spreading oceanic ridges. J. Geodynamics (39) 461-474, 2005. KANIUTH K.: Co- and post-seismic displacements of permanent GPS stations associated with the December 26, 2004 and March 28, 2005 Sumatra earthquakes. Zeitschr. für Verm. (130) 324-328, 2005. KANIUTH K., HUBER S.: Nachweis von Höhenänderungen aufgrund atmosphärischer Druckvariationen aus GPS-Messungen. Zeitschr. für Verm. (128) 278-283, 2003. KANIUTH K., HUBER S.: Modelling vertical site displacements due to atmospheric pressure loading with the Bernese software - A demonstation using EUREF data. Mitteilungen des BKG (33) 89-95, 2004. KANIUTH K., STUBER K.: Apparent and real local movements of two co-located permanent GPS stations at Bogota, Colombia. Zeitschr. für Verm. (130) 41-46, 2005. KANIUTH K., VETTER S.: GPS estimates of postglacial uplift in Fennoscandia. Zeitschr. für Verm. (129) 168-175, 2004. KANIUTH K., VETTER S.: Vertical velocities of European coastal sites derived from continuous GPS observations. GPS Solutions (9) 32-40, DOI 10.1007/s10291-004-0124-4, 2005. KANIUTH K., VETTER S.: Estimating atmospheric pressure loading regression coefficients from GPS observations. GPS Solutions (10) 126-134, DOI 10.1007/s10291-005-0014-4, 2006. KAUFMANN G.: Geodetic signatures of a Late Pleistocene Tibetan ice sheet. J. Geodyn., 39, 111-125, 2005. KAUFMANN G., WU P., IVINS E.R.: Lateral viscosity variations beneath Antarctica and their implications on regional rebound motions and seismotectonics. J. Geodyn., 39, 165- 181, 2005. KHAZARADZE G., KLOTZ J.: Short- and long-term effects of GPS measured crustal deformation rates along the south central Andes. J. Geophys. Res. (108) B6, 5, 15pp, 2003. KLEMANN V., WOLF D.: The eustatic reduction of shoreline diagrams: implications for the inference of relaxation-rate spectra and the viscosity stratification below Fennoscandia. Geophys. J. Int., 162, 249-256, 2005. KLEMANN V., WOLF D.: Using fuzzy logic for the analysis of sealevel indicators with respect to glacial-isostatic adjustment: an application to the Richmond-Gulf region, Hudson Bay. Pure Appl. Geophys., 164, 683-696, doi:10.1007/s00024- 007-0191-x, 2007. KLEMANN V., WU P., WOLF D.: Compressible viscoelasticity: stability of solutions for plane-earth models. Geophys. J. Int., 153, 569-585, 2003. KLEMANN V., IVINS E.R., MARTINEC Z., WOLF D.: Models of active glacial isostasy roofing warm subduction: the case of the South Patagonian ice field. J. Geophys. Res., in press, (2007). KRAWINKEL J.J.: Struktur und Kinematik am konvergenten Plattenrand der südlichen zentralamerikanischen Landbrücke (Zentral- und Süd-Costa Rica, West-Panama). Profil, Stuttgart, No. 30, 2003. KUSCHE J., SCHRAMA E.J.O.: Mass redistribution from global GPS time series and GRACE gravity fields: inversion issues. Springer, <strong>IAG</strong> Symposia, Vol. 129, 322-327, 2005. MÄKINEN J., ENGFELDT A., HARSSON B.G., RUOTSALAINEN H., STRYKOWSKI G., OJA T., WOLF D.: The Fennoscandian land uplift gravity lines: status 2004. In: Ehlers C., Eklund O., Korja A., Kruuna A., Lahtinen R., Pesonen L.J., eds., Programme and Extended Abstracts of the Third Symposium on Structure, Composition and Evolution of the Lithosphere in Finland, pp. 81-87, Institute of Seismology, University of Helsinki, Helsinki, 2004. MÄKINEN J., ENGFELDT A., HARSSON B.G., RUOTSALAINEN H., STRYKOWSKI G., OJA T., WOLF D.: The Fennoscandian land uplift gravity lines 1966-2003. In: Jekeli C., Bastos L., Fernandez J., eds., Gravity, Geoid and Space Missions, pp. 328-332, Springer, Berlin, 2005. MARTINEC Z.: Propagator-matrix technique for the viscoelastic response of a multi-layered sphere to surface toroidal traction. Pure Appl. Geophys., 164, 663-681, doi:10.1007/ s00024-007-0188-5, 2007. MARTINEC Z., WOLF D.: Inverting the Fennoscandian relaxationtime spectrum in terms of an axisymmetric viscosity distribution with a lithospheric root. J. Geodyn., 39, 143-163, doi:10.1016/j.jog.2004.08.007, 2005. MÜLLER J., TIMMEN L., DENKER H.: Absolute gravimetry in the Fennoscandian land uplift area: Monitoring of temporal gravity changes for GRACE. Geotechnologien Science Report No. 3, 112-115, 2003. MÜLLER J., TIMMEN L., GITLEIN O., DENKER H.: Gravity changes in the Fennoscandian uplift area to be observed by GRACE and absolute gravimetry. Springer, <strong>IAG</strong> Symposia, Vol. 129, 304-309, 2005. MÜLLER J., NEUMANN-REDLIN M., JARECKI F., DENKER H., GITLEIN O.: Gravity changes in northern Europe as observed by GRACE. Springer, <strong>IAG</strong> Symposia, Vol. 130, 523-527, 2006. RABUS B., KNÖPFELE W.: Erstellung von Höhenmodellen und Bewegungskarten der Erdoberfläche durch Satelliten- Radarinterferometrie. Geologica Bavarica (107) 235-247, 2003. RAMILLIEN G., CAZENAVE A., REIGBER C., SCHMIDT R., SCHWINTZER P.: Recovery of global time-variations of surface water mass by GRACE geoid inversion. Springer, <strong>IAG</strong> Symposia, Vol. 129, 310-315, 2005. RICHTER B., ZERBINI S., MATONTI F., SIMON D.: Long-term crustal deformation monitored by gravity and space techniques at Medicina, Italy and Wettzell, Germany. J. Geodynamics (38) 281-292, 2004. RIEDEL B., THALES-WILLIGE B., NIEMEIER W.: A combined remote sensing approach of dInSAR and geologic-structural analysis for the detection of landslide hazard zones. Springer, <strong>IAG</strong> Symposia, Vol. (130), 2007. ROZSA SZ., HECK B., MAYER M., SEITZ K., WESTERHAUS M., ZIPPELT K.: Determination of displacements in the upper Rhine graben area from GPS and levelling data. Int. J. Earth Sci. (94) 538-549, 2005. ROZSA SZ., MAYER M., WESTERHAUS M., SEITZ K., HECK B.: Towards the determination of displacements in the upper Rhine Graben area using GPS measurements and precise antenna modelling. Quaternary Science Reviews (24) 427- 440, 2005.
SASGEN, I., MULVANEY R., KLEMANN V., WOLF D.: Glacialisostatic adjustment and sea-level change near Berkner Island, Antarctica. Sci. Techn. Rep. GFZ Potsdam, 20 pp., in press (2007). SCHMIDT M., HAN S.-C., KUSCHE J., SANCHEZ L., SHUM C.K.: Regional high-resolution spatiotemporal gravity modeling from GRACE data using spherical wavelets. Geophys. Res. Lett. (33) L08403, 2006. SEEMÜLLER W., DREWES H.: Annual Report 2001 of IGS RNAAC SIR. In: IGS 2001-2002 Technical Reports. JPL Publ. 04- 017, 285-290, IGS Central Bureau, JPL Pasadena, 2004. SEEMÜLLER W., KANIUTH K., DREWES H.: Station positions and velocities of the IGS regional network for SIRGAS. DGFI Report No. 76, 2004. SPATA M., RAVEN P., SCHUCHARDT J., MORITZ U., BECKERS H.: Das GPS-basierte Deformationsnetz Eifel-Plume. Allg. Verm. Nachr. (114) 82-88, 2007.Haas, R., A. Nothnagel, J. Campbell, E. Gueguen: Recent crustal movements observed with the European VLBI network: geodetic analysis and results. J. Geodynamics (35) 391-414, 2003. STEFFEN H., KAUFMANN G.: Glacial isostatic adjustment of Scandinavia and northwestern Europe and the radial viscosity structure of the earth’s mantle. Geophys. J. Int., 163, 801-812, 2005. STEFFEN H., KAUFMANN G., WU P.: Three-dimensional finiteelement modelling of the glacial isostatic adjustment in Fennoscandia. Earth Planet. Space Sci., 250, 358-375, 2006. H. Drewes, D. Wolf: Crustal deformation and Geodynamics 83 STEFFEN H., WU P., KAUFMANN G.: Sensitivity of crustal velocities in Fennoscandia to radial and lateral viscosity variations in the mantle. Earth Planet. Sci. Lett., 257, 474-485, 2007. TIMMEN L. and 20 others: Observing Fennoscandian gravity change by absolute gravimetry. Springer, <strong>IAG</strong> Symposia, Vol. 131, 193-199, 2006. TRUBITSYN V., KABAN M., MOONEY W., REIGBER C., SCHWINTZER P.: Simulation of active tectonic processes for a convecting mantle with moving continents. Geophys. J. Int. (164) 611-623, 2006. WENDT J., DIETRICH R.: Determination of recent crustal deformations based on precise GPS measurements in the Vogtland earthquake area.. J. Geodynamics (35) 235-246, 2003. WOLF D., KLEMANN V., WÜNSCH J., ZHANG F.-P.: A reanalysis and reinterpretation of geodetic and geological evidence of glacial-isostatic adjustment in the Churchill region, Hudson Bay. Sci. Techn. Rep. GFZ Potsdam, STR04/11, 49pp, 2004. WOLF D., KLEMANN V., WÜNSCH J., ZHANG F.-P.: A reanalysis and reinterpretation of geodetic and geological evidence of glacial-isostatic adjustment in the Churchill region, Hudson Bay. Surv. Geophys., 27, 19-61, doi:10.1007/s 10712-005-0641-x, 2006. ZIMMERMANN J.: Konzeption und Umsetzung eines Informationssystems zur geodätischen Deformationsanalyse. Dt. Geod. Komm., München, Reihe C, Nr. 574, 2004.
- Page 1:
DEUTSCHE GEODÄTISCHE KOMMISSION be
- Page 4 and 5:
Adresse des Herausgebers / Address
- Page 7 and 8:
Contents Commission 1 - Reference F
- Page 9:
COMMISSION 1 REFERENCE FRAMES 7
- Page 12 and 13:
10 Commission 1 - Reference Frames
- Page 14 and 15:
12 Commission 1 - Reference Frames
- Page 16 and 17:
14 Introduction Celestial Reference
- Page 18 and 19:
16 Commission 1 - Reference Frames
- Page 20 and 21:
18 Commission 1 - Reference Frames
- Page 22 and 23:
20 Commission 1 - Reference Frames
- Page 24 and 25:
22 Commission 1 - Reference Frames
- Page 26 and 27:
24 Introduction The contributions o
- Page 28 and 29:
26 Commission 1 - Reference Frames
- Page 30 and 31:
28 Satellite altimetry provides a p
- Page 32 and 33:
30 Commission 1 - Reference Frames
- Page 35: COMMISSION 2 GRAVITY FIELD 33
- Page 38 and 39: 36 Commission 2 - Gravity Field res
- Page 40 and 41: 38 Commission 2 - Gravity Field aut
- Page 42 and 43: 40 Commission 2 - Gravity Field in
- Page 44 and 45: 42 Commission 2 - Gravity Field sho
- Page 46 and 47: 44 Commission 2 - Gravity Field KRE
- Page 48 and 49: 46 Commission 2 - Gravity Field Dev
- Page 50 and 51: 48 Commission 2 - Gravity Field ILK
- Page 52 and 53: 50 Introduction In the reporting pe
- Page 54 and 55: 52 Commission 2 - Gravity Field of
- Page 56 and 57: 54 Commission 2 - Gravity Field GRU
- Page 58 and 59: 56 Commission 2 - Gravity Field LEM
- Page 60 and 61: 58 1. Modelling Techniques Fundamen
- Page 62 and 63: 60 Commission 2 - Gravity Field BUN
- Page 64 and 65: 62 Commission 2 - Gravity Field Geo
- Page 66 and 67: 64 Commission 2 - Gravity Field SCH
- Page 68 and 69: 66 Commission 2 - Gravity Field gra
- Page 70 and 71: 68 Commission 2 - Gravity Field LOM
- Page 72 and 73: 70 Introduction The four years sinc
- Page 74 and 75: 72 Commission 2 - Gravity Field met
- Page 76 and 77: 74 Commission 2 - Gravity Field SCH
- Page 79 and 80: Introduction The determination of E
- Page 81 and 82: Introduction German investigations
- Page 83: In Europe, there are detailed inves
- Page 87 and 88: enabling us to map the behaviour of
- Page 89 and 90: NAUJOKS M, JAHR T., JENTZSCH G.,. K
- Page 91 and 92: nental hydrosphere. Thus, interpret
- Page 93 and 94: M. Thomas, M. Soffel, H. Drewes: Ea
- Page 95 and 96: M. Thomas, M. Soffel, H. Drewes: Ea
- Page 97 and 98: observed that the resulting masscha
- Page 99 and 100: Since 2001, the IERS Central Bureau
- Page 101 and 102: COMMISSION 4 POSITIONING AND APPLIC
- Page 103 and 104: The main highlights in the past fou
- Page 105 and 106: VLBI Space Geodetic Techniques (VLB
- Page 107 and 108: A. Nothnagel: Space Geodetic Techni
- Page 109 and 110: A. Nothnagel: Space Geodetic Techni
- Page 111 and 112: also be able to track the broadband
- Page 113 and 114: CHEN X., DEKING A., LANDAU H., STOL
- Page 115 and 116: SEEBER G.: Beitrag für „Directio
- Page 117 and 118: 2003, WÜBBENA et al. 2006a) or in
- Page 119 and 120: Permanent GNSS Networks, including
- Page 121 and 122: G. Weber, M. Becker, J. Ihde: Perma
- Page 123 and 124: G. Weber, M. Becker, J. Ihde: Perma
- Page 125 and 126: General remarks The continuous and
- Page 127 and 128: Introduction GNSS Based Sounding of
- Page 129 and 130: J. Wickert, N. Jakowski: GNSS Based
- Page 131 and 132: J. Wickert, N. Jakowski: GNSS Based
- Page 133 and 134: References ADAM N.: TerraFirma Qual
- Page 135 and 136:
Introduction The period 2003 - 2007
- Page 137 and 138:
procedures and surveying instrument
- Page 139 and 140:
Motivation During the last years, n
- Page 141 and 142:
AVILA-RODRIGUEZ J.-A., PANY T., EIS
- Page 143 and 144:
SEIFERT A., KLEUSBERG A. (2003): An
- Page 145 and 146:
IAG PROJECTS 143
- Page 147 and 148:
The Global Geodetic Observing Syste
- Page 149 and 150:
KRÜGEL M., TESMER V., ANGERMANN D.
- Page 151 and 152:
Inter-commission Committees (ICC) A
- Page 153 and 154:
After the restructuring of the IAG
- Page 155 and 156:
Introduction Physical Aspects of Ge
- Page 157 and 158:
H. Drewes, M. Soffel: Physical Aspe
- Page 159 and 160:
W. Keller, W. Freeden: Mathematical
- Page 161 and 162:
W. Keller, W. Freeden: Mathematical
- Page 163 and 164:
H. Kutterer, W.-D. Schuh: Quality M
- Page 165 and 166:
H. Kutterer, W.-D. Schuh: Quality M
- Page 167 and 168:
H. Kutterer, W.-D. Schuh: Quality M
- Page 169 and 170:
B. ICC on Planetary Geodesy (ICCPG)
- Page 171 and 172:
Introduction Various space missions
- Page 173 and 174:
Photogrammetrie, Fernerkundung und
Change language