Effect of Surface Loading on Regional Reference Frame Realization Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory University.

Slides:

Advertisements

Similar presentations

Principles of the Global Positioning System Lecture 19 Prof. Thomas Herring Room A;

Advertisements

ILRS Workshop, 2008, A 33 Year Time History of the J2 Changes from SLR Minkang Cheng and Byron D. Tapley Center for Space Research.

Earth, Atmospheric and Planetary Sciences Massachusetts Institute of Technology 77 Massachusetts Avenue | A | Cambridge MA V F.

Atmospheric Loading Nicole M. Shivers.  “The Earth’s surface is perpetually being displaced due to temporally varying atmospheric oceanic and continental.

1 Establishing Global Reference Frames Nonlinar, Temporal, Geophysical and Stochastic Aspects Athanasios Dermanis Department of Geodesy and Surveying The.

Reference Frames for GPS Applications and Research

Seasonal Position Variations and Regional Reference Frame Realization Jeff Freymueller Geophysical Institute University of Alaska Fairbanks.

2-3 November 2009NASA Sea Level Workshop1 The Terrestrial Reference Frame and its Impact on Sea Level Change Studies GPS VLBI John Ries Center for Space.

Data centres and observablesModern Seismology – Data processing and inversion 1 Data in seismology: networks, instruments, current problems  Seismic networks,

International Terrestrial Reference Frame - Latest Developments Horst Müller 16th International Workshop on Laser Ranging, Poznan, Poland, October

Facilitating Joint Analysis of Data From Several Systems Using Geophysical Models Hans-Peter Plag, William C. Hammond, Geoffrey Blewitt Nevada Bureau of.

Laser Ranging Contributions to Earth Rotation Studies Richard S. Gross Jet Propulsion Laboratory California Institute of Technology Pasadena, CA 91109–8099,

IGS Analysis Center Workshop, Miami Beach, 2-6 June 2008 M. Fritsche, R. Dietrich, A. Rülke Institut für Planetare Geodäsie (IPG), Technische Universität.

DGF – Santiago, Chile – Geodesy and Geodynamics By Christophe Vigny National Center for scientific Research (CNRS) & Ecole Normale Supérieure (ENS)

DORIS - DAYS Toulouse May 2-3, 2000 DORIS Doppler Orbitography and Radiopositioning Integrated by Satellite  Basic system concept  Main missions  Schedules.

Research Progress on Joint Inversion of Dynamic Geodetic and Geophysical Data School of Geodesy and Geomatics, Wuhan University Xu Caijun.

The Contribution to GGOS from Asian Region Jong Uk Park & Young-Hong Shin Space Geodesy Division, Korea Astronomy and Space Science Institute, Daejeon,

Task AR-07-03: Global Geodetic Reference Frames Report to ADC-5 prepared by Hans-Peter Plag (IAG/GGOS) Nevada Bureau of Mines and Geology and Seismological.

IGCP 565: The workshop series and recommendations Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory, University of Nevada,

Chapter 8: The future geodetic reference frames Thomas Herring, Hans-Peter Plag, Jim Ray, Zuheir Altamimi.

Regional and Global Measurements: The Reference Frame for Understanding Observations Geoff Blewitt University of Nevada, Reno, USA Zuheir Altamimi IGN,

1/17 REFAG Symposium 6 October 2010 – Marne-la-Vallée, France Recent Results from the IGS Terrestrial Frame Combinations __________________________________________________________________________________________________.

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.,

IGS Analysis Center Workshop, 2-6 June 2008, Florida, USA GPS in the ITRF Combination D. Angermann, H. Drewes, M. Krügel, B. Meisel Deutsches Geodätisches.

NKG Working Group for Geodynamics Copenhagen, 23 –24 April, Tasks of a new Working Group on Absolute Gravimetry Herbert Wilmes Federal Agency for.

Determination of seasonal geocenter variations from DORIS, GPS and SLR data.

Sea-Level Change Driven by Recent Cryospheric and Hydrological Mass Flux Mark Tamisiea Harvard-Smithsonian Center for Astrophysics James Davis Emma Hill.

Faculty of Applied Engineering and Urban Planning Civil Engineering Department Introduction to Geodesy and Geomatics Position, Positioning Modes, and the.

GGOS User Requirements and Functional Specifications Richard S. Gross Jet Propulsion Laboratory, California Institute of Technology, Pasadena, USA Global.

(a) Pre-earthquake and (b) post-earthquake Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) images of North Sentinel Island. The.

01/0000 HEO and Daylight Ranging “Reality and Wishes” Ramesh Govind ILRS Fall Workshop, 4 th October 2005.

GPS: “Where goeth thou” Thomas Herring With results from Jen Alltop: Geosystems Thesis Katy Quinn: Almost graduated Ph.D

SNARF: Theory and Practice, and Implications Thomas Herring Department of Earth Atmospheric and Planetary Sciences, MIT

Workshops for Establishing a Stable North American Reference Frame (SNARF) to Enable Geophysical and Geodetic Studies with EarthScope: Annual Report

Assessment of Reference Frame Stability trough offset detection in GPS coordinate time series Dragan Blagojević 1), Goran Todorović 2), Violeta Vasilić.

State-of-the-art physical models for calculating atmospheric pressure loading effects 1 Geodätische Woche October, Köln, Germany Dudy D.

Introduction Ian Thomas, Matt King, Peter Clarke, Nigel Penna, David Lavallée Global GPS Processing strategy Conclusions and Future Work The preliminary.

Environmental Geodesy Lecture 11 (April 4, 2011): Loading - Predicting loading signals - Atmospheric loading - Ocean tidal loading - Non-tidal ocean loading.

Positioning America for the Future NATIONAL OCEANIC AND ATMOSPHERIC ADMINISTRATION National Ocean Service National Geodetic Survey Real-Time Mantra Pass.

NGOS NORDIC GEODETIC OBSERVING SYSTEM NKG Task Force Markku Poutanen, Per Knudsen, Mikael Lilje, Hans-Peter Plag, Hans-Georg Scherneck.

Hydrogeodesy: what is it, how can it help, what are the challenges? Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory, University.

Reference Frame Theory & Practice: Implications for SNARF SNARF Workshop 1/27/04 Geoff Blewitt University of Nevada, Reno.

Application of a North America reference frame to the Pacific Northwest Geodetic Array (PANGA) M M Miller, V M Santillan, Geodesy Laboratory, Central Washington.

Extract deep geophysical signals from GPS data analysis Signals and noises inside GPS solutions Network adjustment Time series analysis Search subtle signals.

Earth Surface and Interior Focus Area Space Geodetic Networks for Maintaining the Reference Frame Geodesy's Critical Contributions to NASA (Earth Science)

NATO Workshop Veszprem 2004 Recent Monitoring of Crustal Movements in the Eastern Mediterranean The Usage of GPS Measurements G. Stangl, Federal Office.

Earth Observation Support for Adaptation to an Uncertain Sea Level Rise Hans-Peter Plag Nevada Bureau of Mines and Geology & Seismological Laboratory University.

Principles of the Global Positioning System Lecture 18 Prof. Thomas Herring Room A;

1. The International Terrestrial Reference Frame (ITRF) needs to be made more robust and stable over multi-decadal time scales. –target accuracy is 0.1.

Water vapour estimates over Antarctica from 12 years of globally reprocessed GPS solutions Ian Thomas, Matt King, Peter Clarke Newcastle University, UK.

Satellite geodesy (ge-2112) Introduction E. Schrama.

Towards a standard model for present-day signals due to postglacial rebound H.-P. Plag, C. Kreemer Nevada Bureau of Mines and Geology and Seismological.

A proposal for a consistent model of air pressure loading as part of the International Terrestrial Reference System (ITRS) Conventions Plag, H.-P. (1),

Task AR-07-03: Global Geodetic Reference Frames Report to ADC-6 prepared by Hans-Peter Plag (IAG/GGOS)‏ Nevada Bureau of Mines and Geology and Seismological.

12/12/01Fall AGU Vertical Reference Frames for Sea Level Monitoring Thomas Herring Department of Earth, Atmosphere and Planetary Sciences

IGARSS 2011, Vancuver, Canada July 28, of 14 Chalmers University of Technology Monitoring Long Term Variability in the Atmospheric Water Vapor Content.

Terrestrial Reference Frame Effects on Global Sea Level Rise determination from TOPEX/Poseidon altimetric data Laurent Morel a, Pascal Willis b,c a Ecole.

11-12 April 2005NASA Sea Level Workshop1 SPACE GEODETIC MEASUREMENT SYSTEM FOR GLOBAL SEA LEVEL CHANGE "In all things it is a good idea to hang a question.

Importance of SLR in the Determination of the ITRF Zuheir Altamimi IGN, France Geoscience Australia, Canberra, August 29, 2005 SLR Strength: its contribution.

29 August 2005Geosciences Australia1 Space Geodesy, SLR and Global Sea Level Change John Ries Canberra, Australia August 29,,2005.

Ggim.un.org Positioning geospatial information to address global challenges Global and National Geodetic Reference Frames: how they are connected and why.

Hydrogeodesy Training Session Approximately 15 attendees, Three seminars 1. Introduction to Hydrogeodesy 2. Introduction to Data Assimilation 3. Introduction.

Thomas Herring, IERS ACC, MIT

Reference Frame Representations: The ITRF from the user perspective

Reference Frames Global Continental Local -- may be self-defined

Geodesy & Crustal Deformation

Geodesy & Crustal Deformation

X SERBIAN-BULGARIAN ASTRONOMICAL CONFERENCE 30 MAY - 3 JUNE, 2016, BELGRADE, SERBIA EARTH ORIENTATION PARAMETERS AND GRAVITY VARIATIONS DETERMINED FROM.

VLBI Estimates of Vertical Crustal Motion in Europe

Stable North America Reference Frame Working Group

Presentation transcript:

Effect of Surface Loading on Regional Reference Frame Realization Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory University of Nevada, Reno With input from W. Hammond and G.Blewitt

Contents Effect of Reference Station Network on Time Series Extending the Reference Frame Conventions Conclusion Towards a Future Predictive Non-Linear Terrestrial Reference Frame for Improved Geodetic Monitoring of the Global Hydrological Cycle

Introduction Displacement is the difference between predicted and computed positions Determination of anomalous displacements (=unknown geophysical signals)poses high demands on quality of predicted reference motion

ITRF: Brief Review of Current Conventions Definition of ITRF: Polyhedron with the motion of the vertices given as “regularized coordinates”: Coordinates and Velocities are: Determined from observations; Affected by “station motion model”, troposphere & ionosphere treatment, antenna model, analysis strategy,... Access to the ITRF: Through GNSS: Accurate satellite orbits and clocks and EOP. These global parameters are affected by station motion model,... Consistency of global parameters with the ITRF determination.

Station motion model (depending on length of analysis interval): Conventional models: (1) Earth tides, (2) ocean tidal loading, (3) pole tide Contributions not included in the reference and station motion model are globally filtered and/or biased! ITRF: Brief Review of Current Conventions

Space-geodetic time series of Earth's surface point displacements contain unexplained variations; Sub-daily to decadal geophysical signals are significantly biased; Spatial and temporal resolution of the monitoring insufficient; Ground-based network geometry and temporal stability; Technique specific problems (antenna characteristics, satellite models,...) Reference frame definition, determination, and maintenance Alignment of solutions to reference frame Limitation of Reference Motion

The Network Effect Aligning free solutions to the ITRF (Helmert) Transformation: Rotation, translation, scale; Fit to “secular ITRF polyhedron”;

The Network Effect Aligning free solutions to the ITRF (Helmert) Transformation: Rotation, translation, scale; Fit to “secular ITRF polyhedron”; Challenge: Change in network geometry; Incomplete sampling: Leakage of unmodeled geophysical signals

The Network Effect Aligning free solutions to the ITRF (Helmert) Transformation: Rotation, translation, scale; Fit to “secular ITRF polyhedron”; More stations, better sampling of geophysical signals;

The Network Effect JPL NGL

The Network Effect JPL - NGL

The Network Effect JPL NGL JPL - NGL

The Network Effect Tz Ty Tx Scale JPL-NGL Seasonal cycle in vertical displacement filtered by frame alignments ~ 20 mm

Extending the Reference Frame Concept Extensions either in: Station motion model in processing of observations Regularized coordinates used in the alignment of solutions to ITRF Potential extensions of station motion model: Atmospheric tidal loading Atmospheric loading Ocean non-tidal loading Terrestrial water storage Earthquake displacement field

Prediction of geodetic fingerprints of mass redistribution in hydrological cycle requires gravitationally consistent modeling: The geodetic signals of mass redistribution in the global hydrological cycle need to be modeled in a gravitationally consistent integrated model of the Earth system accounting for the linkage between reservoirs in the hydrological cycle as well as the feedback of the changes in Earth's shape, gravity field and rotation on the distribution of mass in these reservoirs (Clarke et al., 2005). Separate models of the main reservoirs not sufficient to meet accuracy requirements: A conventional approach to load-induced geodetic signals based on separate models for the main reservoirs of the global hydrological cycle will not meet the accuracy and consistency goal of 1 ppb (Plag et al., 2007). Comments on the model

Extending the reference frame concept: Dynamic Reference Earth Model (DREM) Reference motion for any point on Earth (not just the polyhedron): with predicted by the DREM In order to capture geophysical signals unbiased and unmodified in space- geodetic time series of surface displacements, a reference frame approach based on a dynamic reference Earth model is required. Comments on the Model

Conclusion Geodetic fingerprints of global change processes are above the accuracy level of geodetic observations. The accuracy of the modeled fingerprints of mass redistribution and geodynamics impacts the accuracy of geodetic products. In order to serve Earth sciences with improved products and to extract global change signals from geodetic observations, geodesy needs to understand and model consistently Earth system processes on a wide range of spatial and temporal scales.