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GLOBK

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Title: GLOBK


1
GLOBK
  • Thomas Herring
  • Room 54-611 617-253-5941
  • tah_at_mit.edu
  • http//geoweb.mit.edu

2
Summary
  • Applications of globk (why do we need it).
  • Structure of how globk works and philosophy
  • GLOBK Command file
  • Use of process noise models
  • Main commands that are encountered.
  • GLORG command file
  • Coordinate system definition module (or frame
    stabilization)
  • Pos_org and rate_org commands

3
Function of GLOBK
  • The number of parameters in GPS phase analysis
    are dominated by bias and atmospheric delay
    parameters. The bias parameters increase as the
    number of stations times the numbers of
    satellites. It is not practical to include large
    numbers of stations in an analysis without some
    method of eliminating these bias and atmospheric
    delay parameters Globk provides one way of
    eliminating these parameters.
  • Phase analysis is CPU time intensive and another
    benefit of the Globk approach is that decisions
    on parameter constraints (such as site
    coordinates, Earth orientation parameters,
    orbits) can be done (quickly) at the Globk level.
  • Principle is to carry forward solution and
    variance-covariance matrix for global
    parameters.

4
Introduction to Kalman filtering
  • Estimation method in which parameters can be
    stochastic processes (i.e. parameters are not
    fixed, deterministic quantities but rather they
    vary with time according to statistical noise
    processes).
  • Examples polar motion and UT1, radiation
    pressure effects on satellites, possible
    transient events, monument instability noise.
  • Nearly all parameters in globk can be stochastic
    or deterministic
  • Statistical character of parameters are set with
    commands of the form apr_XXX (specifies the
    apriori uncertainty of a parameter) and mar_XXX
    (specifies the stochastic nature of the
    parameter)
  • The parameters that are estimated in Globk are
    based on those that are given apriori
    uncertainties (special method used to put zero
    apriori constraint on parameter, i.e., fix the
    parameter value).

5
Stochastic processes
  • Stochastic models in globk are random walks.
    Random walks are the sums of white noise they
    are a special case of a first order Gauss-Markov
    process with infinite correlation time.
  • The variance of the change in a random walk over
    a time interval is proportional to the time
    interval. (Strictly, a random walk is not a
    stationary process).
  • Globk uses random walks because process can be
    represented with a single parameter.
  • If process noise is zero, then classed as
    deterministic

6
Common applications of Globk
  • Combine sessions to get average position over an
    observing campaign
  • Allows connection between sites that were not
    simultaneously observed
  • When large numbers of stations need to be
    processed, network can be broken into manageable
    sub-networks (e.g., 40-50 stations each) and the
    sub-networks combined with Globk. (Special case
    is combination of regional networks and global
    network for orbit determination).
  • Combine averaged files together to estimate
    velocities
  • Other parameters can also estimated such as
    earthquake offsets, possible scale variations for
    long duration combinations.
  • Analysis of individual sessions and combined
    files for repeatability

7
Things Globk can not do
  • Non-linear effects in aproiri models can not be
    removed. In some campaign processing, this can
    be a problem. Rough rule of thumb 100-10001
    convergence rate (e.g., a 1 meter error in an
    apriori coordinate could result in 1-10 mm error
    in final position). Gamit detects and corrects
    (by default) this problem.
  • Fix errors in original analysis such as cycle
    slips or antenna phase center models
  • Sites can be deleted which often stops effect on
    other stations
  • Ambiguities can not be resolved in Globk (would
    make files too large)
  • (Antenna height errors can be corrected in Globk
    hfupd)

8
GLOBK Command file
  • Example given in gg/example/gsoln/globk_comb.cmd
  • Basic features of command files (also common to
    other input files used by globk)
  • Character in column 1 denotes comment
  • only minimum redundant part of command needed
  • In many cases, not all arguments need be given

9
Preparing globk
  • sh_glred automates standard runs with globk and
    can be used as a starting point.
  • Assumes internet access but can be run without
  • Globk needs
  • Binary h-files (htoglb) These are the input
    files quasi-data files used by Globk. They
    contain parameter estimates, covariance matrices
    and ancillary information (such as receiver and
    antenna information).
  • Command file to tell it what to do. File is read
    through a series of command lines. There are a
    few restrictions on order of commands. Each
    command acts on results from previous commands.
  • Optional apriori information files such as site
    coordinates and velocities, polar motion/UT1
    information. (Much of this information can be
    carried from h-files themselves)

10
Binary h-files
  • There are number of methods and sources of binary
    hfiles
  • From Gamit, they can be generated with htoglb
    from the hltexptgta.ltyygtltdoygt files in processing
    day directories
  • Other major source Solution Independent Exchange
    Format files (SINEX). Available for GPS, VLBI,
    SLR and DORIS.
  • Older formats from VLBI, SLR and GPS can be read
    but now replaced by SINEX. (JPL stacov files can
    be read but very poor meta data in these files).
  • Program detects which type of file is given.
  • De-constraining options are available for SINEX
    and should be used.
  • Globk itself can write binary h-files
  • Generally Globk assumes h-files are loosely
    constrained.

11
HTOGLB
  • Running htoglb
  • Runstring
  • htoglb ltdirgt ltephemeris filegt options ltlist of
    ascii filesgt
  • dir is directory where binary files will be
    written
  • ephemeris file is satellite orbit file (not used
    any more, make_svs). This file also contains the
    aproiri coordinates of the sites in the hfiles.
  • options allow control of file names, and
    de-constraints
  • -d options allows rotation and translation
    covariances to be added. Needed for IGS sinex
    and PBO frame SINEX files.
  • -n allows name format to be changed.
  • list of ascii files, usually with UNIX wild
    cards.
  • If no arguments are given help is printed.

12
Module sequence
  • The sequence of modules are
  • globk -- Main controlling program that calls
    other modules
  • glinit -- Initialization program, reads the
    headers of all the binary h-files to determine
    their contents. (Allows wild cards in names etc.)
  • glfor -- Forward kalman filter
  • glbak -- Backards running filter and smoother.
    Only invoked when temporal variations in
    stochastic parameters is needed. For
    deterministic parameters such as positions and
    velocities, only forward solution is needed.
  • glsave -- Saves combined binary h-files
  • glout -- basic output program
  • glorg -- origin definition program plus post
    analysis constraints (e.g., setting velocities of
    close sites to be equal)

13
Stand-alone programs
  • glsave and glorg are often run as separate
    programs
  • Commands can be put in the globk command that
    will run these modules
  • Sometimes these commands are not included in the
    globk command file and in most cases they can be
    run after the globk program completes running
    (explicit name must given for the com_file for
    post-globk runs.)
  • Caution Internal files used by globk may be
    replaced with subsequent runs of globk so there
    needs to be some caution with multiple globk
    runs. Solution is to use wild-card names for
    com_file, srt_file and sol_file. (names are
    derived from gdl file name).

14
Associated programs
  • Other program associated with globk
  • glist -- lists the contents of a series of
    h-files
  • glbtosnx -- Generates SINEX files from binary
    h-files
  • hfupd -- Updates binary h-files for changes in
    station.info or sinex header file (distributed by
    IGS)
  • glred -- Convenient way of running globk
    multiple times. This program is commonly used for
    repeatability analyses which are in turn used to
    set the process noise statistics in globk.
  • ensum, enfit -- time series analysis (batch)
  • Matlab derived programs (interactive)
  • velview -- displays and analyzes velocity fields
  • tsview -- displays and analyzse time series.
  • Both these programs are available as executables
    for Linux and Mac OSX.

15
Running globk
  • Typing globk will list the help Runstring
  • globk ltcrtgt ltprint filegt ltlog filegt ltgdl filegt
    ltcommand filegt ltOPTgt
  • where ltcrtgt 6 (screen output)
  • ltprint filegt -- Print file name (can be 6 for
    screen)
  • ltlog filegt -- log file name (can be 6)
  • ltgdl filegt -- file containing list of hfiles to
    be processed. Options can be added at the ends
    of line to re-weight files
  • ltglobk command filegt -- command file name
  • ltOPTgt is a string (case sensitive) such that
    lines which start with this string will be
    interpreted as commands. This allows one command
    files to be for different purposes such as a
    velocity and repeatability runs.

16
globk files
  • The gdl file is generated normally with an 'ls'
    of the directory containing the binary hfiles
  • command file is created with an editor (can be
    based on gg/example templates version of file)
  • print and log files are written by globk. When
    glorg in invoked inside globk, the .prt extent
    from the print file name is replaced with .org
    and this file is written also. Depending on
    options, files may not be output at all or may be
    erased before output (default is to append to
    files).

17
Main globk commands
  • Commands commonly used
  • Globk uses three "scratch" files which can be
    explicilty named
  • com_file -- Common file contains information
    about run
  • srt_file -- binary file with time-sorted list of
    hfiles
  • sol_file -- binary file with solution and
    covariance matrix
  • To use glorg stand-alone, com_file command must
    be used

18
Estimation commands rules
  • For a parameter to estimated in globk, apr_xxx
    command must be used where xxx is a parameter
    type (e.g., NEU, SVS, WOB, UT1, ATM)
  • If zero given as aprori sigma, then parameter is
    not estimated (effectively left unconstrained)
  • To force a parameter to apriori value, F is used
    as the apriori sigma
  • eg, apr_neu SITE 10 10 10 F F Fwould force the
    velocity to apriori value
  • When glorg is used to define reference frame,
    apr_neu, apr_wob and apr_ut1 should be kept
    loosely constained (equivalent of 1-10 meters)

19
Estimation commands
  • Site position estimation
  • apr_neu ltsitegt ltsigNgt ltsigEgt ltsigUgt ltsigVNgt
    ltsigVEgt ltsigVUgt
  • site is site name maybe ALL to apply to all
    stations. Wild card _at_ at end of line can be used
    to apply to multiple sites (e.g., AOA1__at_ would
    apply to AOA1_GNR and AOA1_GHT if these both were
    in solution).
  • ltsigNgt ltsigEgt ltsigUgt aprior sigma on position (m)
  • ltsigVNgt ltsigVEgt ltsigVUgt apriori sigma on
    velocities (m/yr)
  • Stochastic noise process
  • mar_neu ltsitegt ltRWNgt ltRWEgt ltRWUgt ltRWVNgt ltRWVEgt
    ltRWVUgt
  • site name, may be all
  • ltRWNgt ltRWEgt ltRWUgt Random walk positions (m2/yr)
  • ltRWVNgt ltRWVEgt ltRWVUgt Random walk velocities
    ((m/yr)2/yr) Normally 0 0 0 used

20
Estimation commands
  • Satellites Orbit
  • apr_svs ltPRNgt ltX Y Zgt ltVx Vy Vzgt ltRadiation
    parametersgt
  • ltPRNgt is PRN_NN or all (normal)
  • ltX Y Zgt Position sigma (3 values) (m)
  • ltVx Vy Vzgt Velocity sigma (3 values) (mm/s)
  • Radiation pameter sigmas (upto 11 values)
    (fraction 0-1)

21
Satellite orbit parameters
  • Normally apr_svs only used in to two forms
  • When global GPS sites included so orbit can be
    estimated well
  • apr_svs all 100 100 100 10 10 10 1R
  • When only local data used and constrain to
    apriori orbit
  • apr_svs all 0.1 0.1 0.1 0.01 0.01 0.01 0.01R
  • R at end of line means remaining radiation
    parameters
  • With modern data and IGS orbits, the orbits can
    be completely fixed i.e.apr_svs_all F F F F F F
    FR

22
Earth Orientation Parameters (EOP)
  • Apriori uncertainties
  • apr_wob lt?Xgt lt?Ygt lt?Xdotgt lt?Ydotgt
  • ?X, ?Y pole position apriori sigma (mas)
  • ?Xdot ?Ydot apriori sigma for rate of change
    (mas/day)
  • apr_ut1 ltsut1gt lt?lodgt
  • lt sut1 gt in mas, lt ?lod gt in (mas/day)
  • Process noise has same form
  • mar_wob ltRWXgt ltRWYgt ltRWXdgt ltRWYdgt
  • units are (mas2)/yr and (mas/day)2/yr
  • mar_ut1 ltRW UT1gt ltRW lodgt
  • Nominally EOP are well known today (0.1 mas
    typically), however in many analyses we like to
    keep these parameter loose to allow common-mode
    local rotation (for IGS runs still needed)

23
EOP statistics
  • Normally used in two forms
  • Global network of stations
  • apr_wob 10 10 1 1
  • apr_ut1 10 1
  • Regional network (constrained). When constrained
    this way system is not free to rotate (see
    pos_org in glorg).
  • apr_wob 0.2 0.2 0.02 0.02
  • apr_ut1 0.2 0.02
  • In many analyses, the global form is used even
    for local networks. (Care is needed if local
    network is not not surrounded by stations with
    well defined motions).

24
UT1 issues
  • Some care needs to be used with UT1 because it
    cannot be separated from the nodes of the
    satellites orbits
  • UT1 tables and orbits must have used the same
    frame for constraints on UT1 to applied.
  • If local processing, then should be OK
  • If orbits were determined with different EOP
    tables, then UT1 should be loosened. (More of a
    problem with older analyses -- mid 1990s and
    earlier)

25
Frame estimation commands
  • apr_tran ltX YZgt ltVx Vy Vzgt -- estimate
    translation of coordinate system
  • apr_scale ltppbgt ltppb/yrgt -- estimate scale and
    scale rate
  • mar_tran and mar_scale specify the process noise
  • Normally only used in global networks but can be
    help full in regional networks to allow for
    common mode errors. (Generally, small networks
    can translate easily and so explicit translation
    not needed).
  • apr_scale MUST be used if scale allowed in glorg
    frame definition.
  • When combining data, pre- and post-absolute phase
    center models (Week 1400, Nov 2006), apr_scale
    should be used.

26
File commands
  • A number of commands are used control the files
    used by globk
  • apr_file ltnamegt lets a new apriori coordinate
    file be used
  • Format is
  • Site_name X Y Z Vx Vy Vz epoch
  • Site names are 8 characters, for GPS ABCD_GPS
  • X Y Z are geocenter Cartesian (m)
  • Velocities are m/yr
  • Epoch is deciminal years

27
Apriori position files
  • apr_files commands can be issued multiple times
    with the latest values taken
  • If not specified, GAMIT apriori's are used (no
    velocities)
  • EXTENDED option allows more complex behaviors
    (see globk.hlp)
  • Allows for jumps in positions and velocities
  • Periodic signals
  • Logarithmic and exponential decay after
    earthquakes.

28
Orbit files
  • When single days are processed, orbits from gamit
    will be used by default
  • For multiple days, with globk, the make_svs
    command is needed to generate an orbit file.
  • Form
  • make_svs ltfile namegt
  • ltfile namegt will be overwritten
  • Command must be near top of command file.

29
EOP files
  • GAMIT EOP are used by default, but can be changed
    with in_pmu command
  • Form
  • in_pmu ltfile namegt
  • Format of file is
  • yy mm dd hr min Xpole - Ypole - UT1-AT -
  • Must be uniformly spaced
  • Pole in arc-seconds, UT1 in time-seconds

30
Earthquake files
  • It is possible to automatically account for
    displacement caused by earthquakes with the
    earthquake file
  • To main functions
  • Earthquakes specified by 2-char code
  • renames of sites either due to wrong names in
    gamit processing or problem with position change
    after equipment change.
  • Rename command
  • Rename ltoldgt ltnewgt HFile code Epoch ranges
    Position shift
  • Changing positions with rename commands no longer
    recommended.

31
Earthquakes in eq_file
  • For earthquake
  • eq_def ltcodegt Lat Long Radius Depth Epoch
  • eq_cosei ltcodegt ltStatic Variancegt ltdistance
    dependent variancesgt
  • eq_post ltcodegt ltdurgt ltStatic RWgt ltdistance
    dependent RWgt
  • eq_rename ltcodegt
  • eq_log ltcodegt lttau (days)gt ltstatic NEU sigma
    (m)gt ltSpatial sigma NEUgt
  • The rename option cause site to renamed from
    xxxx_GPS to xxxx_GCode

32
GLORG
  • Glorg allows coordinates systems to be defined by
    applying explicitly rotations and translations
    rather than tightly constraining some stations
  • Allows post applications of constraints (e.g.
    equating velocities at near by sites)
  • If loose constraints on site positions and
    velocities, apriori coordinates and velocities
    can be changed.
  • It can be run as a separate program or during the
    globk run itself

33
Glorg commands imbedded in globk command file
  • The globk command file imbedded glorg commands
    are
  • org_cmd ltglorg command file namegt
  • org_opt ltOptions for outputgt
  • org_out ltoutput file namegt
  • If org_out is not given then the extent on the
    print file name is replaced with .org

34
Miscellaneous commands
  • max_chi ltmax chi2 Incrementgt ltmax prefit
    differencegt ltmax rotationgt
  • allows automatic deleting of bad h-files and bad
    coordinates
  • app_ptid allows applying the pole tide correction
    if not included in gamit run.
  • (Careful with SINEX files, since these don't
    specify if correction has been applied)

35
Miscellaneous commands
  • crt_opt, prt_opt, org_opt specify output options
    for screen, print and org files
  • glorg help gives all options, main ones are
  • ERAS -- erase file before writing (normally files
    appended)
  • NOPR -- Do not write output
  • BLEN -- Baseline lengths
  • BRAT -- baseline rates when velocities estimated
  • RNRP -- generates reports on differences in
    parameter estimates after renames.
  • FIXA -- makes apriori coordinates and velocities
    consistent when equates are used in glorg (can
    sometimes fail in complicated rename
    scenarios--best apriori files are consistent)
  • VSUM -- Lat/long summary of velocity (needed to
    plot velocities)
  • PSUM -- Lat/long position summary
  • GDLF --Include list of hfiles and chi2
    increments from run
  • CMDS -- Echos globk command file into output file
  • MIDP -- Refer positions to mid-point of data span
  • PBOP -- Output PBO formatted time series and
    velocities

36
Defining coordinate system in globk
  • To define a coordinate system need origin,
    orientation and possibly scale
  • Strictly for GPS scale should be defined but
    systematic errors in the position of the phase
    center of satellites cause a scale error and
    scale rate error (due to evolving GPS
    constellation Problem should be reduced with new
    absolute phase center model but all old data will
    need to be reprocessed once new orbits have been
    generated).
  • Strictly, origin is also defined but mis-modeled
    perturbation on satellite orbits can cause shift
    in origin

37
glorg coordinate definition
  • The glorg module in globk defines the coordinate
    system by applying rotation, translation, and
    scale to best align with coordinates of a
    selected set of stations
  • Algorithm assumes these parameters are loosely
    constrained.
  • Apriori coordinates and velocities define frame.
  • User chooses which of the translation, rotation
    and scale are included
  • If scale is used, it must be explicitly estimated
    in globk
  • For velocity definition Same generalized system
    can be applied i.e. rates of translation,
    rotation, scale aligned with velocities of sites.
  • In general No specific station coordinates are
    tightly constrained

38
GLORG pos_org and rate_org
  • The two commands determine how coordinate system
    will be realized from loose globk analysis.
  • Class of parameters
  • Xtran ytran ztran allows translation
  • Xrot yrot zrot allows rotation
  • Scale allows rescaling of system
  • Strictly when translation used the apr_tran and
    mar_tran commands should be used in globk
    analysis. (We are still not sure this is best
    thing to do)
  • Absolutely if scale used, apr_scale and mar_scale
    commands should be used in globk

39
GLORG Rotation
  • If rotation used in pos_org, EOPs must be loose
    in globk (apr_wob/mar_wob and apr_ut1/mar_ut1)
  • If rotation not used then EOPs should be
    constrained (Often good on small networks) but
    position errors grow near edges of network
  • There can be problems with zrot terms because of
    differences between the node position of the
    satellites and UT1 tables used in globk analysis.
  • Rotation rate EOP tables are in
    Nuvel-not-net-rotation frame. If analysis done
    in another frame (e.g., North America fixed)
    rotation rates should be allowed or EOP file
    generated in corrected frame (no module yet to do
    this but will be done soon).

40
USING PBO products
  • PBO sinex files can be downloaded from Unavco and
    used in globk analyses.
  • Two types of sinex files are made available
  • Loose Loosely constrained files. These can be
    converted to binary hfiles with normal htoglb
    run.
  • Frame Frame defined files. There are two
    choices here. A standard htoglb run will
    generate solution with coordinates well
    determined in the PBO reference frame. To use
    these binary hfiles to generate results in
    another reference frame, the apr_rot and apr_tran
    commands should be used to allow the solutions to
    rotate and translate. An alternative approach is
    to use the -dtr option in htoglb which add
    rotational and translational covariances to the
    binary hfiles.
  • The orbits are fixed to IGS orbits in the PBO
    sinex files.

41
Summary
  • Basics of Kalman filtering
  • Inputs to globk
  • Control of globk
  • Glorg applications (discussed in more detail in
    reference frame section)
  • Basic programs in the globk suite
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