Gauges

With AMRClaw in two space dimensions and GeoClaw it is possible to specify gauge locations as points (x,y) where the values of all components of q should be output every time step during the computation over some time range (t1,t2).

Gauges are useful in several ways, e.g.:

  1. To compare computational results to measurements from physical gauges such as a pressure gauge or tide gauge that record data as a function of time at a single point,

  2. To better visualize how the solution behaves at a single point,

  3. To better compare results obtained with different methods or grid resolutions. Comparing two-dimensional pcolor or contour plots can be difficult whereas comparing to curves that give the solution as a function of time often reveals more clearly differences in accuracy or nonphysical oscillations.

Note: The capability of using Lagrangian gauges for particle tracking has been added to GeoClaw in Version 5.7.0 (it is not available in AMRClaw at this time).

Note: One can also use the Fixed grid output capabilities added to GeoClaw in Version 5.9.0 in order to capture the solution over a specified fixed grid at frequent output times. If this output is frequent enough, then it is also possible to sample these outputs at a fixed location to give a time series similar to a gauge output, but with the advantage that the points need not be specified prior to the run (at least for any point that can be spatially interpolated from the fgout grid(s) captured in the run). The temporal resolution will be that specified for the fgout grids. See Fixed grid output for more details.

Gauge parameters in setrun

See also Specifying AMRClaw run-time parameters in setrun.py.

Gauges are specified in setrun by adding lists of gauge data for each desired gauge to the ClawRunData object rundata.gaugedata.gauges. This is initialized as an empty list and new gauges can be specified by:

rundata.gaugedata.gauges.append([gaugeno, x, y, t1, t2])

with values

  • gaugeno : integer

    the number of this gauge

  • x, y : floats

    the location of this gauge

  • t1, t2 : floats

    the time interval over which gauge data should be output.

During the computation the value of all components of q at all gauge locations will be output to a single file fort.gauge in the output directory. Lines of this file have the form:

gaugeno  level  t  q[0]  q[1] ...  q[meqn-1]

where level is the AMR level used to determine the q values at this time. Internally the finest level available at each gauge is used, with bilinear interpolation to the gauge locations from the 4 nearest cell centers.

Note: In GeoClaw, zero-order interpolation is used instead of piecewise linear interpolation; see Nearshore interpolation.

New in 5.4.0. The output that is in the gauge files can be controlled by a variety of parameters. These can be specified on a per gauge basis or set for all gauges specified. The output parameters are

  • file_format : Specifies the file format of the gauge data. Starting in v5.9.0, this value can be “ascii”, “binary64”, or “binary32”. The latter value generally results in the smallest file size and reduction of the 8-byte computated values to 4-byte output still gives sufficient precision for most applications.

  • display_format : Specifies the format of the numbers written to the gauge file for each field, in the case file_format=”ascii”. These are Fortran format strings defaulting to “e15.7”.

  • q_out_fields : Specifies which fields of the q array to output. Specify as a list the indices that should be output. Defaults to “all”.

  • aux_out_fields : Specifies which fields of the aux array to output. Specify as a list the indices that should be output. Defaults to “none”

  • min_time_increment : Specify a minimum amount of time that should pass before recording the values at a gauge. This can be useful for decreasing the amount of output at a gauge location that is currently being time-stepped at small increments. The default is 0 which effectively turns off this constraint.

Setting these values can be done in multiple ways for convenience. The most direct way is via a dictionary with the keys as the gauge ids and the corresponding parameter as the value. For example, if we had 3 gauges with ids 3, 7, 13 we could specify that they all use the display format e26.16 by setting:

rundata.gaugedata.display_format = "e26.16"

or:

rundata.gaugedata.display_format = {3:"e26.16", 13:"e8.6"}

to set gauge 3’s display format to “e26.16”, leave gauge 7 set to the default and set 13’s to “e8.6”.

For the parameters q_out_fields and aux_out_fields one can also specify “all” to output all fields or “none” to specify none of them (equivalent to an empty list of indices). Both of these arrays use Python indexing, i.e. they start at 0.

Note: For GeoClaw, the sea-surface value \(\eta = h + B\) (sum of water depth and topography) is also output as another column after the q fields. In the case of the multilayer code the eta for each surface follows the q fields for that layer.

New in 5.4.0:

  • Gauge output is accumulated in a buffer internally and written out intermitently, instead of writing to disk every time step. (The parameter MAX_BUFFER in the amrclaw library routines gauges_module.f90 controls the size of this buffer.)

  • The gauge output for the gauges is written to distinct files in the output directory, e.g. gauge00001.txt for gauge number 1. In previous versions of Clawpack all gauges were written to a single file fort.gauge. The new approach allows gauges to be written in parallel and also facilitates reading in a single gauge more quickly.

  • Some header info appears in each of these files to describe the gauge output.

  • New in 5.9.0: If binary output is requested (see below) then files such as gauge00001.txt contain only a header for each gauge, but the data is all in a corresponding binary file such as gauge00001.bin.

  • When doing a restart (see Checkpointing and restarting), gauge output from the original run is no longer overwritten by the second run. Instead gauge output from the restart run will be appended to the end of each gaugeXXXXX.txt file (or gaugeXXXXX.bin in the case of binary output). Note that if you restart from a time earlier than the end of the previous computation, or do multiple restarts from the same checkpoint file, the appended data will not be at monotonically increasing times.

Plotting tools

Several Python plotting tools are available to plot the gauge data, so you do not have to parse the file fort.gauge yourself.

If you want to read in the data for a particular gauge to manipulate it yourself, you can do, for example:

from clawpack.pyclaw.gauges import GaugeSolution
g = GaugeSolution(gauge_id=1, path='_output')

to examine gauge number 1, for example.

Then:

  • g.t is the array of times,

  • g.q is the array of values recorded at the gauges (g.q[m,n] is the m`th variable at time `t[n])

Alternatively, you can use the getgauge method of a ClawPlotData object, e.g.:

from clawpack.visclaw.data import ClawPlotData
plotdata = ClawPlotData()
plotdata.outdir = '_output'   # set to the proper output directory
gaugeno = 1                   # gauge number to examine
g = plotdata.getgauge(gaugeno)

In the setplot Python script you can specify plots that are to be done for each gauge, similar to the manner in which you can specify plots that are to be done for each time frame. For example, to plot the component q[0] at each gauge, include in setplot lines of this form:

plotfigure = plotdata.new_plotfigure(name='q[0] at gauges', figno=300, \
                type='each_gauge')

# Set up for axes in this figure:
plotaxes = plotfigure.new_plotaxes()
plotaxes.xlimits = 'auto'
plotaxes.ylimits = [-1.5, 1.5]
plotaxes.title = 'q[0]'

# Plot q[0] as blue line:
plotitem = plotaxes.new_plotitem(plot_type='1d_plot')
plotitem.plot_var = 0
plotitem.plotstyle = 'b-'

Note that plotdata.new_plotfigure is called with type=’each_gauge’ which denotes that this plot is to be produced for each gauge found in setgauges.data. (When type is not specified, the default is type=’each_frame’ for time frame data).

If you type:

$ make .plots

then html files will be created for the gauge plots along with the time frame plots and will all show up in the index (usually in _plots/_PlotIndex.html).

When using Iplotclaw to interactively view plots, try:

PLOTCLAW> plotgauge 1

to produce the plot for gauge 1, or simply:

PLOTCLAW> plotgauge

to loop through all gauges. If you rerun the code without re-executing Iplotclaw, you can refresh the gauge data via:

PLOTCLAW> cleargauges

You can of course specify more than one plotitem on each plotaxes if you want. For example to plot the each gauge from the current run as a blue line and the same gauge from some previous run (perhaps with a different grid resolution) as a red line, you could add the following lines to the above example:

# Plot q[0] from previous run as red line:
plotitem = plotaxes.new_plotitem(plot_type='1d_plot')
plotitem.plot_var = 0
plotitem.plotstyle = 'r-'
plotitem.outdir = '_output_from_previous_run'

Plotting gauge locations

It is often convenient to plot the locations of the gauges on pcolor or contour plots each time frame. You can do this as follows, for example:

plotfigure = plotdata.new_plotfigure(name='pcolor', figno=0)
plotaxes = plotfigure.new_plotaxes('pcolor')
plotitem = plotaxes.new_plotitem(plot_type='2d_pcolor')
# set other attributes as desired

def addgauges(current_data):
    from clawpack.visclaw import gaugetools
    gaugetools.plot_gauge_locations(current_data.plotdata, \
         gaugenos='all', format_string='ko', add_labels=True)

plotaxes.afteraxes = addgauges

You can replace gaugenos=’all’ by gaugenos=[1,2] or other list of specific gauges to plot. The format_string above specifies a black dot at each gauge location and add_labels=True means that the gauge number will appear next to each gauge.

If you want more control over this plotting you can of course copy the function plot_gauge_locations from clawpack.visclaw.gaugetools.py to your setplot.py file and modify at will.

Examples

Several of the examples found in $CLAW/amrclaw/examples/ and $CLAW/geoclaw/examples/ contain the specification of gauges.