# Licensed under a 3-clause BSD style license - see LICENSE.rst
"""FOVCube container."""
from __future__ import absolute_import, division, print_function, unicode_literals
import numpy as np
import astropy.units as u
from astropy.units import Quantity
from astropy.coordinates import Angle
from astropy.table import Table
from astropy.io import fits
from astropy.wcs import WCS
from ..utils.scripts import make_path
from ..utils.wcs import linear_wcs_to_arrays, linear_arrays_to_wcs
from ..utils.fits import table_to_fits_table
from ..utils.energy import Energy, EnergyBounds
__all__ = [
'FOVCube',
]
def _make_bin_edges_array(lo, hi):
"""Make bin edges array from a low values and a high values array.
TODO: move this function to somewhere else? (i.e. utils?)
Parameters
----------
lo : `~numpy.ndarray`
Lower boundaries.
hi : `~numpy.ndarray`
Higher boundaries.
Returns
-------
bin_edges : `~numpy.ndarray`
Array of bin edges as ``[[low], [high]]``.
"""
return np.append(lo.flatten(), hi.flatten()[-1:])
def _parse_data_units(data_unit):
"""Utility function to parse the data units correctly."""
# try 1st to parse them as astropy units
try:
u.Unit(data_unit)
# if it fails, try to parse them as fits units
except ValueError:
try:
u.Unit(data_unit, format='FITS')
# if it fails, try to parse them as ogip units (old FITS standard)
except ValueError:
try:
u.Unit(data_unit, format='ogip')
# if it still fails, raise an exception
except ValueError:
raise ValueError("Invalid unit format {}.".format(data_unit))
return data_unit
[docs]class FOVCube(object):
"""Field of view cube.
Container class for cubes *(X, Y, energy)*.
The class has methods for reading a cube from a FITS file,
write a cube to a FITS file and plot the cubes among others.
The order of the axes in the cube is **(E, y, x)**,
so in order to access the data correctly, the call is
``cube.data[energy_bin, coordy_bin, coordx_bin]``.
This class is very generic and can be used to contain cubes
of different kinds of data. However, for the FITS reading/writing
methods, special parameter names have to be defined, following
the corresponding specifications.
This is taken care of by the
`~gammapy.background.FOVCube.define_scheme` method.
The user only has to specify the correct **scheme** parameter.
Currently accepted schemes are:
* ``bg_cube``: scheme for background cubes; spatial coordinates
*(X, Y)* are in detector coordinates (a.k.a. nominal system
coordinates).
* ``bg_counts_cube``: scheme for count cubes specific for
background cube determination
* ``bg_livetime_cube``: scheme for livetime cubes specific for
background cube determination
If no scheme is specified, a generic one is applied.
New ones can be defined in
`~gammapy.background.FOVCube.define_scheme`.
The method also defines useful parameter names for the plots
axis/title labels specific to each scheme.
Parameters
----------
coordx_edges : `~astropy.coordinates.Angle`, optional
Spatial bin edges vector (low and high). X coordinate.
coordy_edges : `~astropy.coordinates.Angle`, optional
Spatial bin edges vector (low and high). Y coordinate.
energy_edges : `~gammapy.utils.energy.EnergyBounds`, optional
Energy bin edges vector (low and high).
data : `~astropy.units.Quantity`, optional
Data cube matrix in (energy, X, Y) format.
scheme : str, optional
String identifying parameter naming scheme for FITS files and plots.
Examples
--------
Access cube data:
.. code:: python
energy_bin = cube.energy_edges.find_energy_bin('2 TeV')
coord_bin = cube.find_coord_bin(coord=Angle([0., 0.], 'deg'))
cube.data[energy_bin, coord_bin[1], coord_bin[0]]
"""
scheme = ''
def __init__(self, coordx_edges=None, coordy_edges=None, energy_edges=None, data=None, scheme=None):
self.coordx_edges = coordx_edges
self.coordy_edges = coordy_edges
self._energy_edges = EnergyBounds(energy_edges)
if data is None:
self.data = np.zeros((len(energy_edges) - 1,
len(coordy_edges) - 1,
len(coordx_edges) - 1))
else:
self.data = data
# TODO: make this consistent with have the 2d BCK class works
# self.data = 'TODO'
self.scheme = scheme
@property
def scheme_dict(self):
"""Naming scheme, depending on the kind of cube (dict)."""
return self.define_scheme(self.scheme)
[docs] @staticmethod
def define_scheme(scheme=None):
"""Define naming scheme, depending on the kind of cube.
Parameters
----------
scheme : str, optional
String identifying parameter naming scheme for FITS files and plots.
Returns
-------
scheme_dict : dict
Dictionary containing parameter naming scheme for FITS files and plots.
"""
scheme_dict = dict()
if scheme is None or scheme == '':
# default values
scheme_dict['hdu_fits_name'] = 'DATA'
scheme_dict['coordx_fits_name'] = 'X'
scheme_dict['coordy_fits_name'] = 'Y'
scheme_dict['energy_fits_name'] = 'E'
scheme_dict['data_fits_name'] = 'DATA'
scheme_dict['coordx_plot_name'] = 'X'
scheme_dict['coordy_plot_name'] = 'Y'
scheme_dict['energy_plot_name'] = 'E'
scheme_dict['data_plot_name'] = 'DATA'
elif scheme == 'bg_cube':
scheme_dict['hdu_fits_name'] = 'BACKGROUND'
scheme_dict['coordx_fits_name'] = 'DETX'
scheme_dict['coordy_fits_name'] = 'DETY'
scheme_dict['energy_fits_name'] = 'ENERG'
scheme_dict['data_fits_name'] = 'BKG'
scheme_dict['coordx_plot_name'] = 'DET X'
scheme_dict['coordy_plot_name'] = 'DET Y'
scheme_dict['energy_plot_name'] = 'E'
scheme_dict['data_plot_name'] = 'Bg rate'
elif scheme == 'bg_counts_cube':
scheme_dict['hdu_fits_name'] = 'COUNTS'
scheme_dict['coordx_fits_name'] = 'DETX'
scheme_dict['coordy_fits_name'] = 'DETY'
scheme_dict['energy_fits_name'] = 'ENERG'
scheme_dict['data_fits_name'] = 'COUNTS'
scheme_dict['coordx_plot_name'] = 'DET X'
scheme_dict['coordy_plot_name'] = 'DET Y'
scheme_dict['energy_plot_name'] = 'E'
scheme_dict['data_plot_name'] = 'Counts'
elif scheme == 'bg_livetime_cube':
scheme_dict['hdu_fits_name'] = 'LIVETIME'
scheme_dict['coordx_fits_name'] = 'DETX'
scheme_dict['coordy_fits_name'] = 'DETY'
scheme_dict['energy_fits_name'] = 'ENERG'
scheme_dict['data_fits_name'] = 'LIVETIME'
scheme_dict['coordx_plot_name'] = 'DET X'
scheme_dict['coordy_plot_name'] = 'DET Y'
scheme_dict['energy_plot_name'] = 'E'
scheme_dict['data_plot_name'] = 'Livetime'
else:
raise ValueError("Invalid scheme {}.".format(scheme))
return scheme_dict
[docs] @classmethod
def from_fits_table(cls, hdu, scheme=None):
"""Read cube from a FITS binary table.
Parameters
----------
hdu : `~astropy.io.fits.BinTableHDU`
HDU binary table for the cube.
scheme : str, optional
String identifying parameter naming scheme for FITS files and plots.
Returns
-------
cube : `~gammapy.background.FOVCube`
FOVCube object.
"""
header = hdu.header
data = hdu.data
scheme_dict = cls.define_scheme(scheme)
x_name_lo = scheme_dict['coordx_fits_name'] + '_LO'
x_name_hi = scheme_dict['coordx_fits_name'] + '_HI'
y_name_lo = scheme_dict['coordy_fits_name'] + '_LO'
y_name_hi = scheme_dict['coordy_fits_name'] + '_HI'
e_name_lo = scheme_dict['energy_fits_name'] + '_LO'
e_name_hi = scheme_dict['energy_fits_name'] + '_HI'
# check correct axis order: 1st X, 2nd Y, 3rd energy, 4th data
if (header['TTYPE1'] != x_name_lo) or (header['TTYPE2'] != x_name_hi):
raise ValueError("Expecting X axis in first 2 places, not ({0}, {1})"
.format(header['TTYPE1'], header['TTYPE2']))
if (header['TTYPE3'] != y_name_lo) or (header['TTYPE4'] != y_name_hi):
raise ValueError("Expecting Y axis in second 2 places, not ({0}, {1})"
.format(header['TTYPE3'], header['TTYPE4']))
if (header['TTYPE5'] != e_name_lo) or (header['TTYPE6'] != e_name_hi):
raise ValueError("Expecting E axis in third 2 places, not ({0}, {1})"
.format(header['TTYPE5'], header['TTYPE6']))
if (header['TTYPE7'] != scheme_dict['data_fits_name']):
raise ValueError("Expecting data axis ({0}) in fourth place, not ({1})"
.format(scheme_dict['data_fits_name'], header['TTYPE7']))
# get coord X, Y binning
coordx_edges = _make_bin_edges_array(data[x_name_lo], data[x_name_hi])
coordy_edges = _make_bin_edges_array(data[y_name_lo], data[y_name_hi])
if header['TUNIT1'] == header['TUNIT2']:
coordx_unit = header['TUNIT1']
else:
raise ValueError("Coordinate X units not matching ({0}, {1})"
.format(header['TUNIT1'], header['TUNIT2']))
if header['TUNIT3'] == header['TUNIT4']:
coordy_unit = header['TUNIT3']
else:
raise ValueError("Coordinate Y units not matching ({0}, {1})"
.format(header['TUNIT3'], header['TUNIT4']))
if not coordx_unit == coordy_unit:
ss_error = "This is odd: units of X and Y coordinates not matching"
ss_error += "({0}, {1})".format(coordx_unit, coordy_unit)
raise ValueError(ss_error)
coordx_edges = Angle(coordx_edges, coordx_unit)
coordy_edges = Angle(coordy_edges, coordy_unit)
# get energy binning
energy_edges = _make_bin_edges_array(data[e_name_lo], data[e_name_hi])
if header['TUNIT5'] == header['TUNIT6']:
energy_unit = header['TUNIT5']
else:
raise ValueError("Energy units not matching ({0}, {1})"
.format(header['TUNIT5'], header['TUNIT6']))
energy_edges = Quantity(energy_edges, energy_unit)
# get data
data = data[scheme_dict['data_fits_name']][0]
data_unit = _parse_data_units(header['TUNIT7'])
data = Quantity(data, data_unit)
return cls(coordx_edges=coordx_edges,
coordy_edges=coordy_edges,
energy_edges=energy_edges,
data=data, scheme=scheme)
[docs] @classmethod
def from_fits_image(cls, image_hdu, energy_hdu, scheme=None):
"""Read cube from a FITS image.
Parameters
----------
image_hdu : `~astropy.io.fits.PrimaryHDU`
FOVCube image HDU.
energy_hdu : `~astropy.io.fits.BinTableHDU`
Energy binning table.
scheme : str, optional
String identifying parameter naming scheme for FITS files and plots.
Returns
-------
cube : `~gammapy.background.FOVCube`
FOVCube object.
"""
image_header = image_hdu.header
energy_header = energy_hdu.header
scheme_dict = cls.define_scheme(scheme)
# check correct axis order: 1st X, 2nd Y, 3rd energy, 4th data
if (image_header['CTYPE1'] != scheme_dict['coordx_fits_name']):
raise ValueError("Expecting X axis in first place, not ({})"
.format(image_header['CTYPE1']))
if (image_header['CTYPE2'] != scheme_dict['coordy_fits_name']):
raise ValueError("Expecting Y axis in second place, not ({})"
.format(image_header['CTYPE2']))
if (image_header['CTYPE3'] != scheme_dict['energy_fits_name']):
raise ValueError("Expecting E axis in third place, not ({})"
.format(image_header['CTYPE3']))
# check units
if (image_header['CUNIT1'] != image_header['CUNIT2']):
ss_error = "This is odd: units of X and Y coordinates not matching"
ss_error += "({0}, {1})".format(image_header['CUNIT1'], image_header['CUNIT2'])
raise ValueError(ss_error)
if (image_header['CUNIT3'] != energy_header['TUNIT1']):
ss_error = "This is odd: energy units not matching"
ss_error += "({0}, {1})".format(image_header['CUNIT3'], energy_header['TUNIT1'])
raise ValueError(ss_error)
# get coord X, Y binning
wcs = WCS(image_header, naxis=2) # select only the (X, Y) axes
coordx_edges, coordy_edges = linear_wcs_to_arrays(wcs,
image_header['NAXIS1'],
image_header['NAXIS2'])
# get energy binning
energy_edges = Quantity(energy_hdu.data['ENERGY'],
energy_header['TUNIT1'])
# get data
data = image_hdu.data
data_unit = _parse_data_units(image_header['DATAUNIT'])
data = Quantity(data, data_unit)
return cls(coordx_edges=coordx_edges,
coordy_edges=coordy_edges,
energy_edges=energy_edges,
data=data, scheme=scheme)
[docs] @classmethod
def read(cls, filename, format='table', scheme=None, hdu='bkg_3d'):
"""Read cube from FITS file.
Several input formats are accepted, depending on the value
of the **format** parameter:
* table (default and preferred format): `~astropy.io.fits.BinTableHDU`
* image (alternative format): `~astropy.io.fits.PrimaryHDU`,
with the energy binning stored as `~astropy.io.fits.BinTableHDU`
Parameters
----------
filename : str
Name of file with the cube.
format : str, optional
Format of the cube to read.
scheme : str, optional
String identifying parameter naming scheme for FITS files and plots.
Returns
-------
cube : `~gammapy.background.FOVCube`
FOVCube object.
"""
filename = make_path(filename)
scheme_dict = cls.define_scheme(scheme)
hdu_list = fits.open(str(filename))
if format == 'table':
hdu = hdu_list[hdu]
return cls.from_fits_table(hdu, scheme)
elif format == 'image':
return cls.from_fits_image(hdu_list['PRIMARY'], hdu_list['EBOUNDS'], scheme)
else:
raise ValueError("Invalid format {}.".format(format))
[docs] def to_table(self):
"""Convert cube to astropy table format.
The name of the table is stored in the table meta information
under the keyword 'name'.
Returns
-------
table : `~astropy.table.Table`
Table containing the cube.
"""
# data arrays
a_coordx_lo = Quantity([self.coordx_edges[:-1]])
a_coordx_hi = Quantity([self.coordx_edges[1:]])
a_coordy_lo = Quantity([self.coordy_edges[:-1]])
a_coordy_hi = Quantity([self.coordy_edges[1:]])
a_energy_lo = Quantity([self.energy_edges[:-1]])
a_energy_hi = Quantity([self.energy_edges[1:]])
a_data = Quantity([self.data])
# table
table = Table()
table[self.scheme_dict['coordx_fits_name'] + '_LO'] = a_coordx_lo
table[self.scheme_dict['coordx_fits_name'] + '_HI'] = a_coordx_hi
table[self.scheme_dict['coordy_fits_name'] + '_LO'] = a_coordy_lo
table[self.scheme_dict['coordy_fits_name'] + '_HI'] = a_coordy_hi
table[self.scheme_dict['energy_fits_name'] + '_LO'] = a_energy_lo
table[self.scheme_dict['energy_fits_name'] + '_HI'] = a_energy_hi
table[self.scheme_dict['data_fits_name']] = a_data
table.meta['name'] = self.scheme_dict['hdu_fits_name']
return table
[docs] def to_fits_table(self):
"""Convert cube to binary table FITS format.
Returns
-------
tbhdu : `~astropy.io.fits.BinTableHDU`
Table containing the cube.
"""
return table_to_fits_table(self.to_table())
[docs] def to_fits_image(self):
"""Convert cube to image FITS format.
Returns
-------
hdu_list : `~astropy.io.fits.HDUList`
HDU list with:
* one `~astropy.io.fits.PrimaryHDU` image for the cube.
* one `~astropy.io.fits.BinTableHDU` table for the energy binning.
"""
# data
imhdu = fits.PrimaryHDU(data=self.data.value,
header=self.coord_wcs.to_header())
# add some important header information
imhdu.header['DATAUNIT'] = '{0.unit:FITS}'.format(self.data)
imhdu.header['CTYPE3'] = self.scheme_dict['energy_fits_name']
imhdu.header['CUNIT3'] = '{0.unit:FITS}'.format(self.energy_edges)
# get WCS object and write it out as a FITS header
wcs_header = self.coord_wcs.to_header()
# get energy values as a table HDU, via an astropy table
energy_table = Table()
energy_table['ENERGY'] = self.energy_edges
energy_table.meta['name'] = 'EBOUNDS'
# TODO: this function should be reviewed/re-written, when
# the following PR is completed:
# https://github.com/gammapy/gammapy/pull/290
# as suggested in:
# https://github.com/gammapy/gammapy/pull/299#discussion_r35044977
enhdu = table_to_fits_table(energy_table)
hdu_list = fits.HDUList([imhdu, enhdu])
return hdu_list
[docs] def write(self, outfile, format='table', **kwargs):
"""Write cube to fits file.
Several output formats are accepted, depending on the value
of the **format** parameter:
* table (default and preferred format): `~astropy.io.fits.BinTableHDU`
* image (alternative format): `~astropy.io.fits.PrimaryHDU`,
with the energy binning stored as `~astropy.io.fits.BinTableHDU`
Depending on the value of the **format** parameter, this
method calls either `~astropy.io.fits.BinTableHDU.writeto` or
`~astropy.io.fits.HDUList.writeto`, forwarding the
**kwargs** arguments.
Parameters
----------
outfile : str
Name of file to write.
format : str, optional
Format of the cube to write.
kwargs
Extra arguments for the corresponding `astropy.io.fits` ``writeto`` method.
"""
if format == 'table':
self.to_fits_table().writeto(outfile, **kwargs)
elif format == 'image':
self.to_fits_image().writeto(outfile, **kwargs)
else:
raise ValueError("Invalid format {}.".format(format))
@property
def image_extent(self):
"""Image extent (`~astropy.coordinates.Angle`).
The output array format is ``(x_lo, x_hi, y_lo, y_hi)``.
"""
bx = self.coordx_edges
by = self.coordy_edges
return Angle([bx[0], bx[-1], by[0], by[-1]])
@property
def spectrum_extent(self):
"""Spectrum extent (`~astropy.units.Quantity`).
The output array format is ``(e_lo, e_hi)``.
"""
b = self.energy_edges
return Quantity([b[0], b[-1]])
@property
def image_bin_centers(self):
"""Image bin centers **(x, y)** (2x `~astropy.coordinates.Angle`).
Returning two separate elements for the X and Y bin centers.
"""
coordx_bin_centers = 0.5 * (self.coordx_edges[:-1] + self.coordx_edges[1:])
coordy_bin_centers = 0.5 * (self.coordy_edges[:-1] + self.coordy_edges[1:])
return coordx_bin_centers, coordy_bin_centers
@property
def energy_edges(self):
"""Energy binning (`~gammapy.utils.energy.EnergyBounds`)."""
return self._energy_edges
@property
def coord_wcs(self):
"""WCS object describing the coordinates of the coord (X, Y) bins (`~astropy.wcs.WCS`).
This method gives the correct answer only for linear X, Y binning.
"""
wcs = linear_arrays_to_wcs(name_x=self.scheme_dict['coordx_fits_name'],
name_y=self.scheme_dict['coordy_fits_name'],
bin_edges_x=self.coordx_edges,
bin_edges_y=self.coordx_edges)
return wcs
[docs] def find_coord_bin(self, coord):
"""Find the bins that contain the specified coord (X, Y) pairs.
Parameters
----------
coord : `~astropy.coordinates.Angle`
Array of coord (X, Y) pairs to search for.
Returns
-------
bin_index : `~numpy.ndarray`
Array of integers with the indices (x, y) of the coord
bin containing the specified coord (X, Y) pair.
"""
# check that the specified coord is within the boundaries of the cube
coord_extent = self.image_extent
check_x_lo = (coord_extent[0] <= coord[0]).all()
check_x_hi = (coord[0] < coord_extent[1]).all()
check_y_lo = (coord_extent[2] <= coord[1]).all()
check_y_hi = (coord[1] < coord_extent[3]).all()
if not (check_x_lo and check_x_hi) or not (check_y_lo and check_y_hi):
raise ValueError("Specified coord {0} is outside the boundaries {1}."
.format(coord, coord_extent))
bin_index_x = np.searchsorted(self.coordx_edges[1:], coord[0])
bin_index_y = np.searchsorted(self.coordy_edges[1:], coord[1])
return np.array([bin_index_x, bin_index_y])
[docs] def find_coord_bin_edges(self, coord):
"""Find the bin edges of the specified coord (X, Y) pairs.
Parameters
----------
coord : `~astropy.coordinates.Angle`
Array of coord (X, Y) pairs to search for.
Returns
-------
bin_edges : `~astropy.coordinates.Angle`
Coord bin edges (x_lo, x_hi, y_lo, y_hi).
"""
bin_index = self.find_coord_bin(coord)
bin_edges = Angle([self.coordx_edges[bin_index[0]],
self.coordx_edges[bin_index[0] + 1],
self.coordy_edges[bin_index[1]],
self.coordy_edges[bin_index[1] + 1]])
return bin_edges
[docs] def plot_image(self, energy, ax=None, style_kwargs=None):
"""Plot image for the energy bin containing the specified energy.
Parameters
----------
energy : `~gammapy.utils.energy.Energy`
Energy of cube bin to plot.
ax : `~matplotlib.axes.Axes`, optional
Axes of the figure for the plot.
style_kwargs : dict, optional
Style options for the plot.
Returns
-------
ax : `~matplotlib.axes.Axes`
Axes of the figure containing the plot.
"""
import matplotlib.pyplot as plt
from mpl_toolkits.axes_grid1 import make_axes_locatable
energy = Energy(energy)
# check shape of energy: only 1 value is accepted
if energy.size != 1:
raise IndexError("Expected exactly 1 value for energy"
", got {}.".format(energy.size))
extent = self.image_extent
# find energy bin containing the specified energy
energy_bin = self.energy_edges.find_energy_bin(energy)
energy_bin_edges = self.energy_edges[[energy_bin, energy_bin + 1]]
# get data for the plot
data = self.data[energy_bin]
# create plot
fig = plt.figure()
do_not_close_fig = False
if ax is None:
ax = fig.add_subplot(111)
# if no axis object is passed by ref, the figure should remain open
do_not_close_fig = True
if style_kwargs is None:
style_kwargs = dict()
fig.set_size_inches(8., 8., forward=True)
if 'cmap' not in style_kwargs:
style_kwargs['cmap'] = 'afmhot'
image = ax.imshow(data.value,
extent=extent.value,
origin='lower', # do not invert image
interpolation='nearest',
**style_kwargs)
# set title and axis names
ax.set_title('Energy = [{0:.1f}, {1:.1f}) {2}'.format(
energy_bin_edges[0].value, energy_bin_edges[1].value,
energy_bin_edges.unit))
ax.set_xlabel('{0} / {1}'.format(self.scheme_dict['coordx_plot_name'],
extent.unit))
ax.set_ylabel('{0} / {1}'.format(self.scheme_dict['coordy_plot_name'],
extent.unit))
# draw color bar
divider = make_axes_locatable(ax)
cax = divider.append_axes("right", size="5%", pad=0.05)
fig.colorbar(image, cax=cax,
label='{0} / {1}'.format(self.scheme_dict['data_plot_name'],
data.unit))
# eventually close figure to avoid white canvases
if not do_not_close_fig:
plt.close(fig)
return ax
[docs] def make_spectrum(self, coord, ebounds=None):
"""
Generate energy spectrum at a certain position in the FOV.
Parameters
----------
coord : `~astropy.units.Quantity`
Coord (X,Y) pair of cube bin to plot.
ebounds : `~gammapy.utils.energy.EnergyBounds`, optional
Energy binning for the spectrum
Returns
-------
spectrum : `~astropy.units.Quantity`
Energy spectrum
"""
ebounds = self.energy_edges if ebounds is None else ebounds
ebins = self.energy_edges.find_energy_bin(ebounds.log_centers)
coord = coord.flatten()
# check shape of coord: only 1 pair is accepted
nvalues = len(coord.flatten())
if nvalues != 2:
ss_error = "Expected exactly 2 values for coord (X, Y),"
ss_error += "got {}.".format(nvalues)
raise IndexError(ss_error)
# find coord bin containing the specified coord coordinates
coord_bin = self.find_coord_bin(coord)
# get data for the plot
spectrum = self.data[ebins, coord_bin[1], coord_bin[0]]
return spectrum
[docs] def plot_spectrum(self, coord, ebounds=None, ax=None, style_kwargs=None):
"""Plot spectra for the coord bin containing the specified coord (X, Y) pair.
Parameters
----------
coord : `~astropy.units.Quantity`
Coord (X,Y) pair of cube bin to plot.
ax : `~matplotlib.axes.Axes`, optional
Axes of the figure for the plot.
ebounds : `~gammapy.utils.energy.EnergyBounds`, optional
Energy binning for the spectrum
style_kwargs : dict, optional
Style options for the plot.
Returns
-------
ax : `~matplotlib.axes.Axes`
Axes of the figure containing the plot.
"""
import matplotlib.pyplot as plt
ebounds = self.energy_edges if ebounds is None else ebounds
data = self.make_spectrum(coord, ebounds=ebounds)
coord_bin_edges = self.find_coord_bin_edges(coord)
# create plot
fig = plt.figure()
do_not_close_fig = False
if ax is None:
ax = fig.add_subplot(111)
# if no axis object is passed by ref, the figure should remain open
do_not_close_fig = True
if style_kwargs is None:
style_kwargs = dict()
fig.set_size_inches(8., 8., forward=True)
ax.plot(ebounds.log_centers.to('TeV'), data, drawstyle='default',
**style_kwargs)
ax.loglog() # double log scale # slow!
# set title and axis names
ss_coordx_bin_edges = "[{0:.1f}, {1:.1f}) {2}".format(
coord_bin_edges[0].value, coord_bin_edges[1].value,
coord_bin_edges.unit)
ss_coordy_bin_edges = "[{0:.1f}, {1:.1f}) {2}".format(
coord_bin_edges[2].value, coord_bin_edges[3].value,
coord_bin_edges.unit)
ax.set_title('Coord = {0} {1}'.format(
ss_coordx_bin_edges, ss_coordy_bin_edges))
ax.set_xlabel('{0} / {1}'.format(self.scheme_dict['energy_plot_name'],
ebounds.unit))
ax.set_ylabel('{0} / {1}'.format(self.scheme_dict['data_plot_name'],
data.unit))
# eventually close figure to avoid white canvases
if not do_not_close_fig:
plt.close(fig)
return ax
@property
def integral(self):
"""Integral of the cube (`~astropy.units.Quantity`).
The returned quantity has dimension of the data in the cube
times solid angle times energy.
"""
delta_energy = self.energy_edges[1:] - self.energy_edges[:-1]
delta_y = self.coordy_edges[1:] - self.coordy_edges[:-1]
delta_x = self.coordx_edges[1:] - self.coordx_edges[:-1]
# define grid of deltas (i.e. bin widths for each 3D bin)
delta_energy, delta_y, delta_x = np.meshgrid(delta_energy, delta_y,
delta_x, indexing='ij')
bin_volume = delta_energy * (delta_y * delta_x).to('sr')
integral = self.data * bin_volume
return integral.sum()
@property
def integral_images(self):
"""Integral of the cube images (`~astropy.units.Quantity`).
Calculate the integral of each energy bin (slice) in the
cube. Returns an array of integrals.
The returned quantities have dimensions of the data in the cube
times solid angle.
"""
dummy_delta_energy = np.zeros_like(self.energy_edges[:-1])
delta_y = self.coordy_edges[1:] - self.coordy_edges[:-1]
delta_x = self.coordx_edges[1:] - self.coordx_edges[:-1]
# define grid of deltas (i.e. bin widths for each 3D bin)
dummy_delta_energy, delta_y, delta_x = np.meshgrid(dummy_delta_energy, delta_y,
delta_x, indexing='ij')
bin_area = (delta_y * delta_x).to('sr')
integral_images = self.data * bin_area
return integral_images.sum(axis=(1, 2))
@property
def bin_volume(self):
"""Per-pixel bin volume.
TODO: explain with formula and units
"""
delta_energy = self.energy_edges[1:] - self.energy_edges[:-1]
delta_y = self.coordy_edges[1:] - self.coordy_edges[:-1]
delta_x = self.coordx_edges[1:] - self.coordx_edges[:-1]
# define grid of deltas (i.e. bin widths for each 3D bin)
delta_energy, delta_y, delta_x = np.meshgrid(delta_energy, delta_y,
delta_x, indexing='ij')
bin_volume = delta_energy * (delta_y * delta_x).to('sr')
return bin_volume
[docs] def fill_events(self, event_lists):
"""Fill events histogram.
This add the counts to the existing value array.
Parameters
----------
event_lists : list of `~gammapy.data.EventList`
Python list of event list objects.
"""
for event_list in event_lists:
counts = self._fill_one_event_list(event_list)
self.data += Quantity(counts, self.data.unit)
def _fill_one_event_list(self, events):
"""Fill one event list into a counts array.
Parameters
----------
events :`~gammapy.data.EventList`
Event list objects.
"""
energy = events.energy.to('TeV').value
detx = np.array(events.table['DETX'])
dety = np.array(events.table['DETY'])
sample = np.vstack([energy, detx, dety]).T
bins = [self.energy_edges.value, self.coordy_edges.value, self.coordx_edges.value]
hist, edges = np.histogramdd(sample, bins)
return hist