THEMIS Particle Spectrograms: Difference between revisions

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[[File:thm_esa_spec.png|200px|thumb|right|Energy, phi, and theta spectrograms from THEMIS ESA ion data.]]
[[File:thm_esa_spec.png|200px|thumb|right|Energy, phi, and theta spectrograms from THEMIS ESA ion data.]]


Angular and energy spectrograms can be produced from THEMIS ESA and SST particle data.  Spectrograms (or spectra) are produced after selecting a spacecraft, data type, and time range.  The data are then averaged across the non-selected dimensions and plotted across time.  Magnetic field aligned spectra can also be generated.
Angular and energy spectrograms can be produced from THEMIS [[THEMIS Electrostatic Analyzer|ESA]] and [[THEMIS Solid State Telescope|SST]] particle data.  Spectrograms (or spectra) are produced after selecting a spacecraft, data type, and time range.  The data are then averaged across the non-selected dimensions and plotted across time.  Magnetic field aligned spectra can also be generated.


For command line usage see:
For command line usage see:

Latest revision as of 01:19, 28 May 2015

Energy, phi, and theta spectrograms from THEMIS ESA ion data.

Angular and energy spectrograms can be produced from THEMIS ESA and SST particle data. Spectrograms (or spectra) are produced after selecting a spacecraft, data type, and time range. The data are then averaged across the non-selected dimensions and plotted across time. Magnetic field aligned spectra can also be generated.

For command line usage see:

/projects/THEMIS/examples/basic/thm_crib_part_products.pro


SPEDAS Plugin

SPEDAS GUI plugin for producing THEMIS particle spectrograms

Particle spectrograms can be created from the SPEDAS GUI.

SPEDAS> spd_gui

From the File menu select Load Data then select the THEMIS Derived Spectra tab. Most parameters can be edited from this interface, however some remain command line only. Multiple probes and data types may be selected. All selected output types will be created for each probe/datatype combination. Required support data will be loaded automatically.

Basic Spectrograms

These spectra are created by averaging the data in the native DSL coordinates.

All basic spectra are produced by default when using the command line. Outputs may also be specified:

SPEDAS> thm_part_products, probe='a', datatype='peif', trange=[t0,t1]

SPEDAS> thm_part_products, probe='a', datatype='peif', trange=[t0,t1], outputs = 'energy phi'

Energy

The data are averaged across all look directions (phi & theta) to create an omni-directional energy spectrogram. The plot's y axis is energy.

Phi

The data are averaged across energy and theta (latitude - measured from the spacecraft's spin plane to spin axis) to create an azimuthal spectrogram. The plot's y axis is phi (longitude).

Theta

The data are average across energy and phi (longitude - measured along the spacecraft's spin plane) to create a latitudinal spectrogram. The plot's y axis is theta (latitude).

Field Aligned Spectrograms

Field aligned spectra are produced by first transforming the data into magnetic field aligned coordinates. Field aligned coordinates always use the magnetic field as their z axis. The direction of x and y depend on the particular variant. By default, th?_fgs will be used as the magnetic field vector, however any tplot variable may be used. After the data is transformed into the new coordinates it is interpolated onto a regular grid. The resolution of that grid may be specified. For information on magnetic field variables see THEMIS Fluxgate Magnetometer.

SPEDAS> thm_part_products, probe='a', datatype='peif', trange=[t0,t1], outputs = 'gyro pa'

SPEDAS> thm_part_products, probe='a', datatype='peif', trange=[t0,t1], outputs = 'gyro pa', mag_data = 'tha_fgs'

Gyrophase

The data are transformed into magnetic field aligned coordinates then averaged across all energies and latitudes to create a field aligned azimuthal spectrogram. The plot's y axis is gyrophase (latitude) starting from the coordinate's x axis.

Pitch Angle

The data are transformed into magnetic field aligned coordinates then averaged across all energies and longitudes to create a field aligned colatitudinal spectrogram. This plot's y axis is pitch angle (colatitude) from the magnetic field (z axis)

Energy and angle limits

The subset of the data used to produce spectra can be constrained by setting limits to energy, phi, theta, gyrophase, and pitch angle. Data outside the specified limits will be ignored when producing spectra. Limits to energy, phi, and theta apply to all outputs. Limits to gyrophase and pitch angle ranges will only apple to field aligned spectra and energy spectra. Phi and gyrophase limits are allowed to span 0°.

SPEDAS> thm_part_products, probe='a', datatype='peif', trange=[t0,t1], energy = [1e3,2e5], theta=[-45,45]

SPEDAS> thm_part_products, probe='a', datatype='peif', trange=[t0,t1], pitch = [45,135], gyro=[90,270], outputs='pa gyro'

Contamination

Spacecraft potential

ESA electron energy spectrogram with overlaid spacecraft potential

Increased spacecraft potential may affect the lower energy bins for ESA data. A tplot variable containing spacecraft potential can be specified when producing spectra (and moments). If no variable is specified then "th?_pxxm_pot" will be used, if present. Spacecraft potential must be loaded separately:

SPEDAS> thm_load_mom, probe='a', trange=[t0,t1]

SPEDAS> thm_part_products, probe='a', datatype='peef', trange=[t0,t1], sc_pot_name='tha_pxxm_pot'

ESA background subtraction

Background subtraction for ESA data is enabled by default when producing spectra. For background removal options see ESA Background Removal. For example usage see:

/projects/THEMIS/examples/advanced/thm_crib_esa_bgnd_remove.pro

SST contamination

In most cases, contaminated SST bins should be masked and interpolated over automatically. If the default set of bins is inadequate then a list may be specified instead. For more information see SST Contamination Removal.

SPEDAS> thm_part_products, probe='a', datatype='psif', trange=[t0,t1], sst_sun_bins=[0,8,16,24,32,33,34,40,47,48,49,50,55,56,57]

Resources

ESA instrument page

SST instrument page