WcsNDMap#

class gammapy.maps.WcsNDMap(geom, data=None, dtype='float32', meta=None, unit='')[source]#

Bases: gammapy.maps.wcs.core.WcsMap

WCS map with any number of non-spatial dimensions.

This class uses an ND numpy array to store map values. For maps with non-spatial dimensions and variable pixel size it will allocate an array with dimensions commensurate with the largest image plane.

Parameters
geomWcsGeom

WCS geometry object.

datandarray

Data array. If none then an empty array will be allocated.

dtypestr, optional

Data type, default is float32

metadict

Dictionary to store meta data.

unitstr or Unit

The map unit

Attributes Summary

data

Data array (ndarray)

geom

Map geometry (Geom)

is_mask

Whether map is mask with bool dtype

meta

Map meta (dict)

quantity

Map data times unit (Quantity)

tag

unit

Map unit (Unit)

Methods Summary

apply_edisp(edisp)

Apply energy dispersion to map.

binary_dilate(width[, kernel, use_fft])

Binary dilation of boolean mask adding a given margin

binary_erode(width[, kernel, use_fft])

Binary erosion of boolean mask removing a given margin

coadd(map_in[, weights])

Add the contents of map_in to this map.

convolve(kernel[, method, mode])

Convolve map with a kernel.

copy(**kwargs)

Copy map instance and overwrite given attributes, except for geometry.

create([map_type, npix, binsz, width, proj, ...])

Factory method to create an empty WCS map.

crop(crop_width)

Crop the spatial dimensions of the map.

cumsum(axis_name)

Compute cumulative sum along a given axis

cutout(position, width[, mode, odd_npix])

Create a cutout around a given position.

downsample(factor[, preserve_counts, ...])

Downsample the spatial dimension by a given factor.

fill_by_coord(coords[, weights])

Fill pixels at coords with given weights.

fill_by_idx(idx[, weights])

Fill pixels at idx with given weights.

fill_by_pix(pix[, weights])

Fill pixels at pix with given weights.

fill_events(events)

Fill event coordinates (EventList).

from_geom(geom[, meta, data, unit, dtype])

Generate an empty map from a Geom instance.

from_hdu(hdu[, hdu_bands, format])

Make a WcsNDMap object from a FITS HDU.

from_hdulist(hdu_list[, hdu, hdu_bands, format])

Make a WcsMap object from a FITS HDUList.

from_stack(maps[, axis, axis_name])

Create Map from list of images and a non-spatial axis.

get_by_coord(coords[, fill_value])

Return map values at the given map coordinates.

get_by_idx(idx)

Return map values at the given pixel indices.

get_by_pix(pix[, fill_value])

Return map values at the given pixel coordinates.

get_image_by_coord(coords)

Return spatial map at the given axis coordinates.

get_image_by_idx(idx)

Return spatial map at the given axis pixel indices.

get_image_by_pix(pix)

Return spatial map at the given axis pixel coordinates

get_spectrum([region, func, weights])

Extract spectrum in a given region.

integral(axis_name, coords, **kwargs)

Compute integral along a given axis

interp_by_coord(coords[, method, ...])

Interpolate map values at the given map coordinates.

interp_by_pix(pix[, method, fill_value, ...])

Interpolate map values at the given pixel coordinates.

interp_to_geom(geom[, preserve_counts, ...])

Interpolate map to input geometry.

is_allclose(other[, rtol_axes, atol_axes])

Compare two Maps for close equivalency

iter_by_axis(axis_name[, keepdims])

"Iterate over a given axis

iter_by_image([keepdims])

Iterate over image planes of a map.

iter_by_image_data()

Iterate over image planes of the map.

mask_contains_region(region)

Check if input region is contained in a boolean mask map.

mask_nearest_position(position)

Given a sky coordinate return nearest valid position in the mask

normalize([axis_name])

Normalise data in place along a given axis.

pad(pad_width[, axis_name, mode, cval, method])

Pad the spatial dimensions of the map.

plot([ax, fig, add_cbar, stretch])

Plot image on matplotlib WCS axes.

plot_grid([figsize, ncols])

Plot map as a grid of subplots for non-spatial axes

plot_interactive([rc_params])

Plot map with interactive widgets to explore the non spatial axes.

plot_mask([ax])

Plot the mask as a shaded area

read(filename[, hdu, hdu_bands, map_type, ...])

Read a map from a FITS file.

reduce(axis_name[, func, keepdims, weights])

Reduce map over a single non-spatial axis

reduce_over_axes([func, keepdims, ...])

Reduce map over non-spatial axes

rename_axes(names, new_names)

Rename the Map axes.

reproject_to_geom(geom[, preserve_counts, ...])

Reproject map to input geometry.

resample(geom[, weights, preserve_counts])

Resample pixels to geom with given weights.

resample_axis(axis[, weights, ufunc])

Resample map to a new axis by grouping and reducing smaller bins by a given ufunc

sample_coord(n_events[, random_state])

Sample position and energy of events.

set_by_coord(coords, vals)

Set pixels at coords with given vals.

set_by_idx(idx, vals)

Set pixels at idx with given vals.

set_by_pix(pix, vals)

Set pixels at pix with given vals.

slice_by_idx(slices)

Slice sub map from map object.

smooth(width[, kernel])

Smooth the map.

split_by_axis(axis_name)

Split a Map along an axis into multiple maps.

stack(other[, weights, nan_to_num])

Stack cutout into map.

sum_over_axes([axes_names, keepdims, weights])

To sum map values over all non-spatial axes.

to_cube(axes)

Append non-spatial axes to create a higher-dimensional Map.

to_hdu([hdu, hdu_bands, sparse])

Make a FITS HDU from this map.

to_hdulist([hdu, hdu_bands, sparse, format])

Convert to HDUList.

to_region_nd_map([region, func, weights, method])

Get region ND map in a given region.

to_unit(unit)

Convert map to different unit

upsample(factor[, order, preserve_counts, ...])

Upsample the spatial dimension by a given factor.

write(filename[, overwrite])

Write to a FITS file.

Attributes Documentation

data#

Data array (ndarray)

geom#

Map geometry (Geom)

is_mask#

Whether map is mask with bool dtype

meta#

Map meta (dict)

quantity#

Map data times unit (Quantity)

tag = 'map'#
unit#

Map unit (Unit)

Methods Documentation

apply_edisp(edisp)#

Apply energy dispersion to map. Requires energy axis.

Parameters
edispgammapy.irf.EDispKernel

Energy dispersion matrix

Returns
mapWcsNDMap

Map with energy dispersion applied.

binary_dilate(width, kernel='disk', use_fft=True)[source]#

Binary dilation of boolean mask adding a given margin

Parameters
widthtuple of Quantity

Angular sizes of the margin in (lon, lat) in that specific order. If only one value is passed, the same margin is applied in (lon, lat).

kernel{‘disk’, ‘box’}

Kernel shape

use_fftbool

Use scipy.signal.fftconvolve if True (default) and scipy.ndimage.binary_dilation otherwise.

Returns
mapWcsNDMap

Dilated mask map

binary_erode(width, kernel='disk', use_fft=True)[source]#

Binary erosion of boolean mask removing a given margin

Parameters
widthQuantity, str or float

If a float is given it interpreted as width in pixels. If an (angular) quantity is given it converted to pixels using geom.wcs.wcs.cdelt. The width corresponds to radius in case of a disk kernel, and the side length in case of a box kernel.

kernel{‘disk’, ‘box’}

Kernel shape

use_fftbool

Use scipy.signal.fftconvolve if True (default) and scipy.ndimage.binary_erosion otherwise.

Returns
mapWcsNDMap

Eroded mask map

coadd(map_in, weights=None)#

Add the contents of map_in to this map.

This method can be used to combine maps containing integral quantities (e.g. counts) or differential quantities if the maps have the same binning.

Parameters
map_inMap

Input map.

weights: `Map` or `~numpy.ndarray`

The weight factors while adding

convolve(kernel, method='fft', mode='same')[source]#

Convolve map with a kernel.

If the kernel is two dimensional, it is applied to all image planes likewise. If the kernel is higher dimensional, it should either match the map in the number of dimensions or the map must be an image (no non-spatial axes). In that case, the corresponding kernel is selected and applied to every image plane or to the single input image respectively.

Parameters
kernelPSFKernel or numpy.ndarray

Convolution kernel.

methodstr

The method used by convolve. Default is ‘fft’.

modestr

The convolution mode used by convolve. Default is ‘same’.

Returns
mapWcsNDMap

Convolved map.

copy(**kwargs)#

Copy map instance and overwrite given attributes, except for geometry.

Parameters
**kwargsdict

Keyword arguments to overwrite in the map constructor.

Returns
copyMap

Copied Map.

classmethod create(map_type='wcs', npix=None, binsz=0.1, width=None, proj='CAR', frame='icrs', refpix=None, axes=None, skydir=None, dtype='float32', meta=None, unit='')#

Factory method to create an empty WCS map.

Parameters
map_type{‘wcs’, ‘wcs-sparse’}

Map type. Selects the class that will be used to instantiate the map.

npixint or tuple or list

Width of the map in pixels. A tuple will be interpreted as parameters for longitude and latitude axes. For maps with non-spatial dimensions, list input can be used to define a different map width in each image plane. This option supersedes width.

widthfloat or tuple or list

Width of the map in degrees. A tuple will be interpreted as parameters for longitude and latitude axes. For maps with non-spatial dimensions, list input can be used to define a different map width in each image plane.

binszfloat or tuple or list

Map pixel size in degrees. A tuple will be interpreted as parameters for longitude and latitude axes. For maps with non-spatial dimensions, list input can be used to define a different bin size in each image plane.

skydirtuple or SkyCoord

Sky position of map center. Can be either a SkyCoord object or a tuple of longitude and latitude in deg in the coordinate system of the map.

frame{“icrs”, “galactic”}, optional

Coordinate system, either Galactic (“galactic”) or Equatorial (“icrs”).

axeslist

List of non-spatial axes.

projstring, optional

Any valid WCS projection type. Default is ‘CAR’ (cartesian).

refpixtuple

Reference pixel of the projection. If None then this will be chosen to be center of the map.

dtypestr, optional

Data type, default is float32

metadict

Dictionary to store meta data.

unitstr or Unit

The unit of the map

Returns
mapWcsMap

A WCS map object.

crop(crop_width)[source]#

Crop the spatial dimensions of the map.

Parameters
crop_width{sequence, array_like, int}

Number of pixels cropped from the edges of each axis. Defined analogously to pad_with from numpy.pad.

Returns
mapMap

Cropped map.

cumsum(axis_name)#

Compute cumulative sum along a given axis

Parameters
axis_namestr

Along which axis to integrate.

Returns
cumsumMap

Map with cumulative sum

cutout(position, width, mode='trim', odd_npix=False)[source]#

Create a cutout around a given position.

Parameters
positionSkyCoord

Center position of the cutout region.

widthtuple of Angle

Angular sizes of the region in (lon, lat) in that specific order. If only one value is passed, a square region is extracted.

mode{‘trim’, ‘partial’, ‘strict’}

Mode option for Cutout2D, for details see Cutout2D.

odd_npixbool

Force width to odd number of pixels.

Returns
cutoutWcsNDMap

Cutout map

downsample(factor, preserve_counts=True, axis_name=None, weights=None)[source]#

Downsample the spatial dimension by a given factor.

Parameters
factorint

Downsampling factor.

preserve_countsbool

Preserve the integral over each bin. This should be true if the map is an integral quantity (e.g. counts) and false if the map is a differential quantity (e.g. intensity).

axis_namestr

Which axis to downsample. By default spatial axes are downsampled.

Returns
mapMap

Downsampled map.

fill_by_coord(coords, weights=None)#

Fill pixels at coords with given weights.

Parameters
coordstuple or MapCoord

Coordinate arrays for each dimension of the map. Tuple should be ordered as (lon, lat, x_0, …, x_n) where x_i are coordinates for non-spatial dimensions of the map.

weightsndarray

Weights vector. Default is weight of one.

fill_by_idx(idx, weights=None)[source]#

Fill pixels at idx with given weights.

Parameters
idxtuple

Tuple of pixel index arrays for each dimension of the map. Tuple should be ordered as (I_lon, I_lat, I_0, …, I_n) for WCS maps and (I_hpx, I_0, …, I_n) for HEALPix maps.

weightsndarray

Weights vector. Default is weight of one.

fill_by_pix(pix, weights=None)#

Fill pixels at pix with given weights.

Parameters
pixtuple

Tuple of pixel index arrays for each dimension of the map. Tuple should be ordered as (I_lon, I_lat, I_0, …, I_n) for WCS maps and (I_hpx, I_0, …, I_n) for HEALPix maps. Pixel indices can be either float or integer type. Float indices will be rounded to the nearest integer.

weightsndarray

Weights vector. Default is weight of one.

fill_events(events)#

Fill event coordinates (EventList).

static from_geom(geom, meta=None, data=None, unit='', dtype='float32')#

Generate an empty map from a Geom instance.

Parameters
geomGeom

Map geometry.

datanumpy.ndarray

data array

metadict

Dictionary to store meta data.

unitstr or Unit

Data unit.

Returns
map_outMap

Map object

classmethod from_hdu(hdu, hdu_bands=None, format=None)[source]#

Make a WcsNDMap object from a FITS HDU.

Parameters
hduBinTableHDU or ImageHDU

The map FITS HDU.

hdu_bandsBinTableHDU

The BANDS table HDU.

format{‘gadf’, ‘fgst-ccube’,’fgst-template’}

FITS format convention.

Returns
mapWcsNDMap

Wcs map

classmethod from_hdulist(hdu_list, hdu=None, hdu_bands=None, format='gadf')#

Make a WcsMap object from a FITS HDUList.

Parameters
hdu_listHDUList

HDU list containing HDUs for map data and bands.

hdustr

Name or index of the HDU with the map data.

hdu_bandsstr

Name or index of the HDU with the BANDS table.

format{‘gadf’, ‘fgst-ccube’, ‘fgst-template’}

FITS format convention.

Returns
wcs_mapWcsMap

Map object

classmethod from_stack(maps, axis=None, axis_name=None)#

Create Map from list of images and a non-spatial axis.

The image geometries must be aligned, except for the axis that is stacked.

Parameters
mapslist of Map objects

List of maps

axisMapAxis

If a MapAxis is provided the maps are stacked along the last data axis and the new axis is introduced.

axis_namestr

If an axis name is as string the given the maps are stacked along the given axis name.

Returns
mapMap

Map with additional non-spatial axis.

get_by_coord(coords, fill_value=nan)#

Return map values at the given map coordinates.

Parameters
coordstuple or MapCoord

Coordinate arrays for each dimension of the map. Tuple should be ordered as (lon, lat, x_0, …, x_n) where x_i are coordinates for non-spatial dimensions of the map.

fill_valuefloat

Value which is returned if the position is outside of the projection footprint

Returns
valsndarray

Values of pixels in the map. np.nan used to flag coords outside of map.

get_by_idx(idx)[source]#

Return map values at the given pixel indices.

Parameters
idxtuple

Tuple of pixel index arrays for each dimension of the map. Tuple should be ordered as (I_lon, I_lat, I_0, …, I_n) for WCS maps and (I_hpx, I_0, …, I_n) for HEALPix maps.

Returns
valsndarray

Array of pixel values. np.nan used to flag coordinate outside of map

get_by_pix(pix, fill_value=nan)#

Return map values at the given pixel coordinates.

Parameters
pixtuple

Tuple of pixel index arrays for each dimension of the map. Tuple should be ordered as (I_lon, I_lat, I_0, …, I_n) for WCS maps and (I_hpx, I_0, …, I_n) for HEALPix maps. Pixel indices can be either float or integer type.

fill_valuefloat

Value which is returned if the position is outside of the projection footprint

Returns
valsndarray

Array of pixel values. np.nan used to flag coordinates outside of map

get_image_by_coord(coords)#

Return spatial map at the given axis coordinates.

Parameters
coordstuple or dict

Tuple should be ordered as (x_0, …, x_n) where x_i are coordinates for non-spatial dimensions of the map. Dict should specify the axis names of the non-spatial axes such as {‘axes0’: x_0, …, ‘axesn’: x_n}.

Returns
map_outMap

Map with spatial dimensions only.

Examples

import numpy as np
from gammapy.maps import Map, MapAxis
from astropy.coordinates import SkyCoord
from astropy import units as u

# Define map axes
energy_axis = MapAxis.from_edges(
    np.logspace(-1., 1., 4), unit='TeV', name='energy',
)

time_axis = MapAxis.from_edges(
    np.linspace(0., 10, 20), unit='h', name='time',
)

# Define map center
skydir = SkyCoord(0, 0, frame='galactic', unit='deg')

# Create map
m_wcs = Map.create(
    map_type='wcs',
    binsz=0.02,
    skydir=skydir,
    width=10.0,
    axes=[energy_axis, time_axis],
)

# Get image by coord tuple
image = m_wcs.get_image_by_coord(('500 GeV', '1 h'))

# Get image by coord dict with strings
image = m_wcs.get_image_by_coord({'energy': '500 GeV', 'time': '1 h'})

# Get image by coord dict with quantities
image = m_wcs.get_image_by_coord({'energy': 0.5 * u.TeV, 'time': 1 * u.h})
get_image_by_idx(idx)#

Return spatial map at the given axis pixel indices.

Parameters
idxtuple

Tuple of scalar indices for each non spatial dimension of the map. Tuple should be ordered as (I_0, …, I_n).

Returns
map_outMap

Map with spatial dimensions only.

get_image_by_pix(pix)#

Return spatial map at the given axis pixel coordinates

Parameters
pixtuple

Tuple of scalar pixel coordinates for each non-spatial dimension of the map. Tuple should be ordered as (I_0, …, I_n). Pixel coordinates can be either float or integer type.

Returns
map_outMap

Map with spatial dimensions only.

get_spectrum(region=None, func=<function nansum>, weights=None)#

Extract spectrum in a given region.

The spectrum can be computed by summing (or, more generally, applying func) along the spatial axes in each energy bin. This occurs only inside the region, which by default is assumed to be the whole spatial extension of the map.

Parameters
region: `~regions.Region`

Region (pixel or sky regions accepted).

funcnumpy.func

Function to reduce the data. Default is np.nansum. For a boolean Map, use np.any or np.all.

weightsWcsNDMap

Array to be used as weights. The geometry must be equivalent.

Returns
spectrumRegionNDMap

Spectrum in the given region.

integral(axis_name, coords, **kwargs)#

Compute integral along a given axis

This method uses interpolation of the cumulative sum.

Parameters
axis_namestr

Along which axis to integrate.

coordsdict or MapCoord

Map coordinates

**kwargsdict

Coordinates at which to evaluate the IRF

Returns
arrayQuantity

Returns 2D array with axes offset

interp_by_coord(coords, method='linear', fill_value=None, values_scale='lin')[source]#

Interpolate map values at the given map coordinates.

Parameters
coordstuple, dict or MapCoord

Coordinate arrays for each dimension of the map. Tuple should be ordered as (lon, lat, x_0, …, x_n) where x_i are coordinates for non-spatial dimensions of the map. “lon” and “lat” are optional and will be taken at the center of the region by default.

method{“linear”, “nearest”}

Method to interpolate data values. By default linear interpolation is performed.

fill_valueNone or float value

The value to use for points outside of the interpolation domain. If None, values outside the domain are extrapolated.

values_scale{“lin”, “log”, “sqrt”}

Optional value scaling. Default is “lin”.

Returns
valsndarray

Interpolated pixel values.

interp_by_pix(pix, method='linear', fill_value=None, values_scale='lin')[source]#

Interpolate map values at the given pixel coordinates.

Parameters
pixtuple

Tuple of pixel coordinate arrays for each dimension of the map. Tuple should be ordered as (p_lon, p_lat, p_0, …, p_n) where p_i are pixel coordinates for non-spatial dimensions of the map.

method{“linear”, “nearest”}

Method to interpolate data values. By default linear interpolation is performed.

fill_valueNone or float value

The value to use for points outside of the interpolation domain. If None, values outside the domain are extrapolated.

Returns
valsndarray

Interpolated pixel values.

interp_to_geom(geom, preserve_counts=False, fill_value=0, **kwargs)#

Interpolate map to input geometry.

Parameters
geomGeom

Target Map geometry

preserve_countsbool

Preserve the integral over each bin. This should be true if the map is an integral quantity (e.g. counts) and false if the map is a differential quantity (e.g. intensity)

**kwargsdict

Keyword arguments passed to Map.interp_by_coord

Returns
interp_mapMap

Interpolated Map

is_allclose(other, rtol_axes=0.001, atol_axes=1e-06, **kwargs)#

Compare two Maps for close equivalency

Parameters
othergammapy.maps.Map

The Map to compare against

rtol_axesfloat

Relative tolerance for the axes comparison.

atol_axesfloat

Relative tolerance for the axes comparison.

**kwargsdict

keywords passed to numpy.allclose

Returns
is_allclosebool

Whether the Map is all close.

iter_by_axis(axis_name, keepdims=False)#

“Iterate over a given axis

Yields
mapMap

Map iteration.

See also

iter_by_image

iterate by image returning a map

iter_by_image(keepdims=False)#

Iterate over image planes of a map.

Parameters
keepdimsbool

Keep dimensions.

Yields
mapMap

Map iteration.

See also

iter_by_image_data

iterate by image returning data and index

iter_by_image_data()#

Iterate over image planes of the map.

The image plane index is in data order, so that the data array can be indexed directly.

Yields
(data, idx)tuple

Where data is a numpy.ndarray view of the image plane data, and idx is a tuple of int, the index of the image plane.

See also

iter_by_image

iterate by image returning a map

mask_contains_region(region)[source]#

Check if input region is contained in a boolean mask map.

Parameters
region: `~regions.SkyRegion` or `~regions.PixRegion`

Region or list of Regions (pixel or sky regions accepted).

Returns
containedbool

Whether region is contained in the mask

mask_nearest_position(position)#

Given a sky coordinate return nearest valid position in the mask

If the mask contains additional axes, the mask is reduced over those.

Parameters
positionSkyCoord

Test position

Returns
positionSkyCoord

Nearest position in the mask

normalize(axis_name=None)#

Normalise data in place along a given axis.

Parameters
axis_namestr

Along which axis to normalize.

pad(pad_width, axis_name=None, mode='constant', cval=0, method='linear')#

Pad the spatial dimensions of the map.

Parameters
pad_width{sequence, array_like, int}

Number of pixels padded to the edges of each axis.

axis_namestr

Which axis to downsample. By default spatial axes are padded.

mode{‘edge’, ‘constant’, ‘interp’}

Padding mode. ‘edge’ pads with the closest edge value. ‘constant’ pads with a constant value. ‘interp’ pads with an extrapolated value.

cvalfloat

Padding value when mode=’consant’.

Returns
mapMap

Padded map.

plot(ax=None, fig=None, add_cbar=False, stretch='linear', **kwargs)[source]#

Plot image on matplotlib WCS axes.

Parameters
axWCSAxes, optional

WCS axis object to plot on.

figFigure

Figure object.

add_cbarbool

Add color bar?

stretchstr

Passed to astropy.visualization.simple_norm.

**kwargsdict

Keyword arguments passed to imshow.

Returns
axWCSAxes

WCS axis object

plot_grid(figsize=None, ncols=3, **kwargs)#

Plot map as a grid of subplots for non-spatial axes

Parameters
figsizetuple of int

Figsize to plot on

ncolsint

Number of columns to plot

**kwargsdict

Keyword arguments passed to Map.plot.

Returns
axesndarray of Axes

Axes grid

plot_interactive(rc_params=None, **kwargs)#

Plot map with interactive widgets to explore the non spatial axes.

Parameters
rc_paramsdict

Passed to matplotlib.rc_context(rc=rc_params) to style the plot.

**kwargsdict

Keyword arguments passed to WcsNDMap.plot.

Examples

You can try this out e.g. using a Fermi-LAT diffuse model cube with an energy axis:

from gammapy.maps import Map

m = Map.read("$GAMMAPY_DATA/fermi_3fhl/gll_iem_v06_cutout.fits")
m.plot_interactive(add_cbar=True, stretch="sqrt")

If you would like to adjust the figure size you can use the rc_params argument:

rc_params = {'figure.figsize': (12, 6), 'font.size': 12}
m.plot_interactive(rc_params=rc_params)
plot_mask(ax=None, **kwargs)[source]#

Plot the mask as a shaded area

Parameters
axWCSAxes, optional

WCS axis object to plot on.

**kwargsdict

Keyword arguments passed to contourf

Returns
axWCSAxes, optional

WCS axis object to plot on.

static read(filename, hdu=None, hdu_bands=None, map_type='auto', format=None, colname=None)#

Read a map from a FITS file.

Parameters
filenamestr or Path

Name of the FITS file.

hdustr

Name or index of the HDU with the map data.

hdu_bandsstr

Name or index of the HDU with the BANDS table. If not defined this will be inferred from the FITS header of the map HDU.

map_type{‘wcs’, ‘wcs-sparse’, ‘hpx’, ‘hpx-sparse’, ‘auto’, ‘region’}

Map type. Selects the class that will be used to instantiate the map. The map type should be consistent with the format of the input file. If map_type is ‘auto’ then an appropriate map type will be inferred from the input file.

colnamestr, optional

data column name to be used of healix map.

Returns
map_outMap

Map object

reduce(axis_name, func=<ufunc 'add'>, keepdims=False, weights=None)#

Reduce map over a single non-spatial axis

Parameters
axis_name: str

The name of the axis to reduce over

funcufunc

Function to use for reducing the data.

keepdimsbool, optional

If this is set to true, the axes which are summed over are left in the map with a single bin

weightsMap

Weights to be applied.

Returns
map_outMap

Map with the given non-spatial axes reduced

reduce_over_axes(func=<ufunc 'add'>, keepdims=False, axes_names=None, weights=None)#

Reduce map over non-spatial axes

Parameters
funcufunc

Function to use for reducing the data.

keepdimsbool, optional

If this is set to true, the axes which are summed over are left in the map with a single bin

axes_names: list

Names of MapAxis to reduce over If None, all will reduced

weightsMap

Weights to be applied.

Returns
map_outMap

Map with non-spatial axes reduced

rename_axes(names, new_names)#

Rename the Map axes.

Parameters
nameslist or str

Names of the axes.

new_nameslist or str

New names of the axes (list must be of same length than names).

Returns
geomMap

Renamed Map.

reproject_to_geom(geom, preserve_counts=False, precision_factor=10)#

Reproject map to input geometry.

Parameters
geomGeom

Target Map geometry

preserve_countsbool

Preserve the integral over each bin. This should be true if the map is an integral quantity (e.g. counts) and false if the map is a differential quantity (e.g. intensity)

precision_factorint

Minimal factor between the bin size of the output map and the oversampled base map. Used only for the oversampling method.

Returns
output_mapMap

Reprojected Map

resample(geom, weights=None, preserve_counts=True)#

Resample pixels to geom with given weights.

Parameters
geomGeom

Target Map geometry

weightsndarray

Weights vector. Default is weight of one. Must have same shape as the data of the map.

preserve_countsbool

Preserve the integral over each bin. This should be true if the map is an integral quantity (e.g. counts) and false if the map is a differential quantity (e.g. intensity)

Returns
resampled_mapMap

Resampled map

resample_axis(axis, weights=None, ufunc=<ufunc 'add'>)#

Resample map to a new axis by grouping and reducing smaller bins by a given ufunc

By default, the map content are summed over the smaller bins. Other numpy ufunc can be used, e.g. numpy.logical_and or numpy.logical_or.

Parameters
axisMapAxis

New map axis.

weightsMap

Array to be used as weights. The spatial geometry must be equivalent to other and additional axes must be broadcastable.

ufuncufunc

ufunc to use to resample the axis. Default is numpy.add.

Returns
mapMap

Map with resampled axis.

sample_coord(n_events, random_state=0)#

Sample position and energy of events.

Parameters
n_eventsint

Number of events to sample.

random_state{int, ‘random-seed’, ‘global-rng’, RandomState}

Defines random number generator initialisation. Passed to get_random_state.

Returns
coordsMapCoord object.

Sequence of coordinates and energies of the sampled events.

set_by_coord(coords, vals)#

Set pixels at coords with given vals.

Parameters
coordstuple or MapCoord

Coordinate arrays for each dimension of the map. Tuple should be ordered as (lon, lat, x_0, …, x_n) where x_i are coordinates for non-spatial dimensions of the map.

valsndarray

Values vector.

set_by_idx(idx, vals)[source]#

Set pixels at idx with given vals.

Parameters
idxtuple

Tuple of pixel index arrays for each dimension of the map. Tuple should be ordered as (I_lon, I_lat, I_0, …, I_n) for WCS maps and (I_hpx, I_0, …, I_n) for HEALPix maps.

valsndarray

Values vector.

set_by_pix(pix, vals)#

Set pixels at pix with given vals.

Parameters
pixtuple

Tuple of pixel index arrays for each dimension of the map. Tuple should be ordered as (I_lon, I_lat, I_0, …, I_n) for WCS maps and (I_hpx, I_0, …, I_n) for HEALPix maps. Pixel indices can be either float or integer type. Float indices will be rounded to the nearest integer.

valsndarray

Values vector.

slice_by_idx(slices)#

Slice sub map from map object.

Parameters
slicesdict

Dict of axes names and integers or slice object pairs. Contains one element for each non-spatial dimension. For integer indexing the corresponding axes is dropped from the map. Axes not specified in the dict are kept unchanged.

Returns
map_outMap

Sliced map object.

smooth(width, kernel='gauss', **kwargs)[source]#

Smooth the map.

Iterates over 2D image planes, processing one at a time.

Parameters
widthQuantity, str or float

Smoothing width given as quantity or float. If a float is given it interpreted as smoothing width in pixels. If an (angular) quantity is given it converted to pixels using geom.wcs.wcs.cdelt. It corresponds to the standard deviation in case of a Gaussian kernel, the radius in case of a disk kernel, and the side length in case of a box kernel.

kernel{‘gauss’, ‘disk’, ‘box’}

Kernel shape

kwargsdict

Keyword arguments passed to uniform_filter (‘box’), gaussian_filter (‘gauss’) or convolve (‘disk’).

Returns
imageWcsNDMap

Smoothed image (a copy, the original object is unchanged).

split_by_axis(axis_name)#

Split a Map along an axis into multiple maps.

Parameters
axis_namestr

Name of the axis to split

Returns
mapslist

A list of Map

stack(other, weights=None, nan_to_num=True)[source]#

Stack cutout into map.

Parameters
otherWcsNDMap

Other map to stack

weightsWcsNDMap

Array to be used as weights. The spatial geometry must be equivalent to other and additional axes must be broadcastable.

nan_to_num: bool

Non-finite values are replaced by zero if True (default).

sum_over_axes(axes_names=None, keepdims=True, weights=None)#

To sum map values over all non-spatial axes.

Parameters
keepdimsbool, optional

If this is set to true, the axes which are summed over are left in the map with a single bin

axes_names: list of str

Names of MapAxis to reduce over. If None, all will summed over

weightsMap

Weights to be applied. The Map should have the same geometry.

Returns
map_outMap

Map with non-spatial axes summed over

to_cube(axes)#

Append non-spatial axes to create a higher-dimensional Map.

This will result in a Map with a new geometry with N+M dimensions where N is the number of current dimensions and M is the number of axes in the list. The data is reshaped onto the new geometry

Parameters
axeslist

Axes that will be appended to this Map. The axes should have only one bin

Returns
mapWcsNDMap

new map

to_hdu(hdu='SKYMAP', hdu_bands=None, sparse=False)#

Make a FITS HDU from this map.

Parameters
hdustr

The HDU extension name.

hdu_bandsstr

The HDU extension name for BANDS table.

sparsebool

Set INDXSCHM to SPARSE and sparsify the map by only writing pixels with non-zero amplitude.

Returns
hduBinTableHDU or ImageHDU

HDU containing the map data.

to_hdulist(hdu=None, hdu_bands=None, sparse=False, format='gadf')#

Convert to HDUList.

Parameters
hdustr

Name or index of the HDU with the map data.

hdu_bandsstr

Name or index of the HDU with the BANDS table.

sparsebool

Sparsify the map by only writing pixels with non-zero amplitude.

format{‘gadf’, ‘fgst-ccube’,’fgst-template’}

FITS format convention.

Returns
hdu_listHDUList
to_region_nd_map(region=None, func=<function nansum>, weights=None, method='nearest')[source]#

Get region ND map in a given region.

By default the whole map region is considered.

Parameters
region: `~regions.Region` or `~astropy.coordinates.SkyCoord`

Region.

funcnumpy.func

Function to reduce the data. Default is np.nansum. For boolean Map, use np.any or np.all.

weightsWcsNDMap

Array to be used as weights. The geometry must be equivalent.

method{“nearest”, “linear”}

How to interpolate if a position is given.

Returns
spectrumRegionNDMap

Spectrum in the given region.

to_unit(unit)#

Convert map to different unit

Parameters
unitUnit or str

New unit

Returns
mapMap

Map with new unit and converted data

upsample(factor, order=0, preserve_counts=True, axis_name=None)[source]#

Upsample the spatial dimension by a given factor.

Parameters
factorint

Upsampling factor.

orderint

Order of the interpolation used for upsampling.

preserve_countsbool

Preserve the integral over each bin. This should be true if the map is an integral quantity (e.g. counts) and false if the map is a differential quantity (e.g. intensity).

axis_namestr

Which axis to upsample. By default spatial axes are upsampled.

Returns
mapMap

Upsampled map.

write(filename, overwrite=False, **kwargs)#

Write to a FITS file.

Parameters
filenamestr

Output file name.

overwritebool

Overwrite existing file?

hdustr

Set the name of the image extension. By default this will be set to SKYMAP (for BINTABLE HDU) or PRIMARY (for IMAGE HDU).

hdu_bandsstr

Set the name of the bands table extension. By default this will be set to BANDS.

formatstr, optional

FITS format convention. By default files will be written to the gamma-astro-data-formats (GADF) format. This option can be used to write files that are compliant with format conventions required by specific software (e.g. the Fermi Science Tools). The following formats are supported:

  • “gadf” (default)

  • “fgst-ccube”

  • “fgst-ltcube”

  • “fgst-bexpcube”

  • “fgst-srcmap”

  • “fgst-template”

  • “fgst-srcmap-sparse”

  • “galprop”

  • “galprop2”

sparsebool

Sparsify the map by dropping pixels with zero amplitude. This option is only compatible with the ‘gadf’ format.