Source code for gammapy.datasets.map

# Licensed under a 3-clause BSD style license - see LICENSE.rst
import logging
import numpy as np
import astropy.units as u
from astropy.io import fits
from astropy.table import Table
from regions import CircleSkyRegion
import matplotlib.pyplot as plt
from gammapy.data import GTI
from gammapy.irf import EDispKernelMap, EDispMap, PSFKernel, PSFMap, RecoPSFMap
from gammapy.maps import Map, MapAxis
from gammapy.modeling.models import DatasetModels, FoVBackgroundModel
from gammapy.stats import (
    CashCountsStatistic,
    WStatCountsStatistic,
    cash,
    cash_sum_cython,
    get_wstat_mu_bkg,
    wstat,
)
from gammapy.utils.fits import HDULocation, LazyFitsData
from gammapy.utils.random import get_random_state
from gammapy.utils.scripts import make_name, make_path
from gammapy.utils.table import hstack_columns
from .core import Dataset
from .evaluator import MapEvaluator
from .utils import get_axes

__all__ = ["MapDataset", "MapDatasetOnOff", "create_map_dataset_geoms"]

log = logging.getLogger(__name__)


RAD_MAX = 0.66
RAD_AXIS_DEFAULT = MapAxis.from_bounds(
    0, RAD_MAX, nbin=66, node_type="edges", name="rad", unit="deg"
)
MIGRA_AXIS_DEFAULT = MapAxis.from_bounds(
    0.2, 5, nbin=48, node_type="edges", name="migra"
)

BINSZ_IRF_DEFAULT = 0.2 * u.deg

EVALUATION_MODE = "local"
USE_NPRED_CACHE = True


[docs]def create_map_dataset_geoms( geom, energy_axis_true=None, migra_axis=None, rad_axis=None, binsz_irf=BINSZ_IRF_DEFAULT, ): """Create map geometries for a `MapDataset`. Parameters ---------- geom : `~gammapy.maps.WcsGeom` Reference target geometry in reco energy, used for counts and background maps energy_axis_true : `~gammapy.maps.MapAxis` True energy axis used for IRF maps migra_axis : `~gammapy.maps.MapAxis` If set, this provides the migration axis for the energy dispersion map. If not set, an EDispKernelMap is produced instead. Default is None rad_axis : `~gammapy.maps.MapAxis` Rad axis for the psf map binsz_irf : float IRF Map pixel size in degrees. Returns ------- geoms : dict Dict with map geometries """ rad_axis = rad_axis or RAD_AXIS_DEFAULT if energy_axis_true is not None: energy_axis_true.assert_name("energy_true") else: energy_axis_true = geom.axes["energy"].copy(name="energy_true") geom_image = geom.to_image() geom_exposure = geom_image.to_cube([energy_axis_true]) geom_irf = geom_image.to_binsz(binsz=binsz_irf) geom_psf = geom_irf.to_cube([rad_axis, energy_axis_true]) if migra_axis: geom_edisp = geom_irf.to_cube([migra_axis, energy_axis_true]) else: geom_edisp = geom_irf.to_cube([geom.axes["energy"], energy_axis_true]) return { "geom": geom, "geom_exposure": geom_exposure, "geom_psf": geom_psf, "geom_edisp": geom_edisp, }
[docs]class MapDataset(Dataset): """Main map dataset for likelihood fitting. It bundles together binned counts, background, IRFs in the form of `~gammapy.maps.Map`. A safe mask and a fit mask can be added to exclude bins during the analysis. If models are assigned to it, it can compute predicted counts in each bin of the counts `Map` and compute the associated statistic function, here the Cash statistic (see `~gammapy.stats.cash`). For more information see :ref:`datasets`. Parameters ---------- models : `~gammapy.modeling.models.Models` Source sky models. counts : `~gammapy.maps.WcsNDMap` or `~gammapy.utils.fits.HDULocation` Counts cube exposure : `~gammapy.maps.WcsNDMap` or `~gammapy.utils.fits.HDULocation` Exposure cube background : `~gammapy.maps.WcsNDMap` or `~gammapy.utils.fits.HDULocation` Background cube mask_fit : `~gammapy.maps.WcsNDMap` or `~gammapy.utils.fits.HDULocation` Mask to apply to the likelihood for fitting. psf : `~gammapy.irf.PSFMap` or `~gammapy.utils.fits.HDULocation` PSF kernel edisp : `~gammapy.irf.EDispMap` or `~gammapy.utils.fits.HDULocation` Energy dispersion kernel mask_safe : `~gammapy.maps.WcsNDMap` or `~gammapy.utils.fits.HDULocation` Mask defining the safe data range. gti : `~gammapy.data.GTI` GTI of the observation or union of GTI if it is a stacked observation meta_table : `~astropy.table.Table` Table listing information on observations used to create the dataset. One line per observation for stacked datasets. If an `HDULocation` is passed the map is loaded lazily. This means the map data is only loaded in memory as the corresponding data attribute on the MapDataset is accessed. If it was accessed once it is cached for the next time. Examples -------- >>> from gammapy.datasets import MapDataset >>> filename = "$GAMMAPY_DATA/cta-1dc-gc/cta-1dc-gc.fits.gz" >>> dataset = MapDataset.read(filename, name="cta-dataset") >>> print(dataset) MapDataset ---------- <BLANKLINE> Name : cta-dataset <BLANKLINE> Total counts : 104317 Total background counts : 91507.70 Total excess counts : 12809.30 <BLANKLINE> Predicted counts : 91507.69 Predicted background counts : 91507.70 Predicted excess counts : nan <BLANKLINE> Exposure min : 6.28e+07 m2 s Exposure max : 1.90e+10 m2 s <BLANKLINE> Number of total bins : 768000 Number of fit bins : 691680 <BLANKLINE> Fit statistic type : cash Fit statistic value (-2 log(L)) : nan <BLANKLINE> Number of models : 0 Number of parameters : 0 Number of free parameters : 0 See Also -------- MapDatasetOnOff, SpectrumDataset, FluxPointsDataset """ stat_type = "cash" tag = "MapDataset" counts = LazyFitsData(cache=True) exposure = LazyFitsData(cache=True) edisp = LazyFitsData(cache=True) background = LazyFitsData(cache=True) psf = LazyFitsData(cache=True) mask_fit = LazyFitsData(cache=True) mask_safe = LazyFitsData(cache=True) _lazy_data_members = [ "counts", "exposure", "edisp", "psf", "mask_fit", "mask_safe", "background", ] def __init__( self, models=None, counts=None, exposure=None, background=None, psf=None, edisp=None, mask_safe=None, mask_fit=None, gti=None, meta_table=None, name=None, ): self._name = make_name(name) self._evaluators = {} self.counts = counts self.exposure = exposure self.background = background self._background_cached = None self._background_parameters_cached = None self.mask_fit = mask_fit if psf and not isinstance(psf, (PSFMap, HDULocation)): raise ValueError( f"'psf' must be a 'PSFMap' or `HDULocation` object, got {type(psf)}" ) self.psf = psf if edisp and not isinstance(edisp, (EDispMap, EDispKernelMap, HDULocation)): raise ValueError( "'edisp' must be a 'EDispMap', `EDispKernelMap` or 'HDULocation' " f"object, got `{type(edisp)}` instead." ) self.edisp = edisp self.mask_safe = mask_safe self.gti = gti self.models = models self.meta_table = meta_table # TODO: keep or remove? @property def background_model(self): try: return self.models[f"{self.name}-bkg"] except (ValueError, TypeError): pass def __str__(self): str_ = f"{self.__class__.__name__}\n" str_ += "-" * len(self.__class__.__name__) + "\n" str_ += "\n" str_ += "\t{:32}: {{name}} \n\n".format("Name") str_ += "\t{:32}: {{counts:.0f}} \n".format("Total counts") str_ += "\t{:32}: {{background:.2f}}\n".format("Total background counts") str_ += "\t{:32}: {{excess:.2f}}\n\n".format("Total excess counts") str_ += "\t{:32}: {{npred:.2f}}\n".format("Predicted counts") str_ += "\t{:32}: {{npred_background:.2f}}\n".format( "Predicted background counts" ) str_ += "\t{:32}: {{npred_signal:.2f}}\n\n".format("Predicted excess counts") str_ += "\t{:32}: {{exposure_min:.2e}}\n".format("Exposure min") str_ += "\t{:32}: {{exposure_max:.2e}}\n\n".format("Exposure max") str_ += "\t{:32}: {{n_bins}} \n".format("Number of total bins") str_ += "\t{:32}: {{n_fit_bins}} \n\n".format("Number of fit bins") # likelihood section str_ += "\t{:32}: {{stat_type}}\n".format("Fit statistic type") str_ += "\t{:32}: {{stat_sum:.2f}}\n\n".format( "Fit statistic value (-2 log(L))" ) info = self.info_dict() str_ = str_.format(**info) # model section n_models, n_pars, n_free_pars = 0, 0, 0 if self.models is not None: n_models = len(self.models) n_pars = len(self.models.parameters) n_free_pars = len(self.models.parameters.free_parameters) str_ += "\t{:32}: {} \n".format("Number of models", n_models) str_ += "\t{:32}: {}\n".format("Number of parameters", n_pars) str_ += "\t{:32}: {}\n\n".format("Number of free parameters", n_free_pars) if self.models is not None: str_ += "\t" + "\n\t".join(str(self.models).split("\n")[2:]) return str_.expandtabs(tabsize=2) @property def geoms(self): """Map geometries. Returns ------- geoms : dict Dict of map geometries involved in the dataset. """ geoms = {} geoms["geom"] = self._geom if self.exposure: geoms["geom_exposure"] = self.exposure.geom if self.psf: geoms["geom_psf"] = self.psf.psf_map.geom if self.edisp: geoms["geom_edisp"] = self.edisp.edisp_map.geom return geoms @property def models(self): """Models set on the dataset (`~gammapy.modeling.models.Models`).""" return self._models @property def excess(self): """Observed excess: counts-background.""" return self.counts - self.background @models.setter def models(self, models): """Models setter""" self._evaluators = {} if models is not None: models = DatasetModels(models) models = models.select(datasets_names=self.name) for model in models: if not isinstance(model, FoVBackgroundModel): evaluator = MapEvaluator( model=model, evaluation_mode=EVALUATION_MODE, gti=self.gti, use_cache=USE_NPRED_CACHE, ) self._evaluators[model.name] = evaluator self._models = models @property def evaluators(self): """Model evaluators.""" return self._evaluators @property def _geom(self): """Main analysis geometry.""" if self.counts is not None: return self.counts.geom elif self.background is not None: return self.background.geom elif self.mask_safe is not None: return self.mask_safe.geom elif self.mask_fit is not None: return self.mask_fit.geom else: raise ValueError( "Either 'counts', 'background', 'mask_fit'" " or 'mask_safe' must be defined." ) @property def data_shape(self): """Shape of the counts or background data (tuple).""" return self._geom.data_shape def _energy_range(self, mask_map=None): """Compute the energy range maps with or without the fit mask.""" geom = self._geom energy = geom.axes["energy"].edges e_i = geom.axes.index_data("energy") geom = geom.drop("energy") if mask_map is not None: mask = mask_map.data if mask.any(): idx = mask.argmax(e_i) energy_min = energy.value[idx] mask_nan = ~mask.any(e_i) energy_min[mask_nan] = np.nan mask = np.flip(mask, e_i) idx = mask.argmax(e_i) energy_max = energy.value[::-1][idx] energy_max[mask_nan] = np.nan else: energy_min = np.full(geom.data_shape, np.nan) energy_max = energy_min.copy() else: data_shape = geom.data_shape energy_min = np.full(data_shape, energy.value[0]) energy_max = np.full(data_shape, energy.value[-1]) map_min = Map.from_geom(geom, data=energy_min, unit=energy.unit) map_max = Map.from_geom(geom, data=energy_max, unit=energy.unit) return map_min, map_max @property def energy_range(self): """Energy range maps defined by the mask_safe and mask_fit.""" return self._energy_range(self.mask) @property def energy_range_safe(self): """Energy range maps defined by the mask_safe only.""" return self._energy_range(self.mask_safe) @property def energy_range_fit(self): """Energy range maps defined by the mask_fit only.""" return self._energy_range(self.mask_fit) @property def energy_range_total(self): """Largest energy range among all pixels, defined by mask_safe and mask_fit.""" energy_min_map, energy_max_map = self.energy_range return np.nanmin(energy_min_map.quantity), np.nanmax(energy_max_map.quantity)
[docs] def npred(self): """Total predicted source and background counts. Returns ------- npred : `Map` Total predicted counts """ npred_total = self.npred_signal() if self.background: npred_total += self.npred_background() npred_total.data[npred_total.data < 0.0] = 0 return npred_total
[docs] def npred_background(self): """Predicted background counts. The predicted background counts depend on the parameters of the `FoVBackgroundModel` defined in the dataset. Returns ------- npred_background : `Map` Predicted counts from the background. """ background = self.background if self.background_model and background: if self._background_parameters_changed: values = self.background_model.evaluate_geom(geom=self.background.geom) if self._background_cached is None: self._background_cached = background * values else: self._background_cached.quantity = ( background.quantity * values.value ) return self._background_cached else: return background return background
def _background_parameters_changed(self): values = self.background_model.parameters.value # TODO: possibly allow for a tolerance here? changed = ~np.all(self._background_parameters_cached == values) if changed: self._background_parameters_cached = values return changed
[docs] def npred_signal(self, model_name=None): """Model predicted signal counts. If a model name is passed, predicted counts from that component are returned. Else, the total signal counts are returned. Parameters ---------- model_name: str Name of SkyModel for which to compute the npred for. If none, the sum of all components (minus the background model) is returned Returns ------- npred_sig: `gammapy.maps.Map` Map of the predicted signal counts """ npred_total = Map.from_geom(self._geom, dtype=float) evaluators = self.evaluators if model_name is not None: evaluators = {model_name: self.evaluators[model_name]} for evaluator in evaluators.values(): if evaluator.needs_update: evaluator.update( self.exposure, self.psf, self.edisp, self._geom, self.mask_image, ) if evaluator.contributes: npred = evaluator.compute_npred() npred_total.stack(npred) return npred_total
[docs] @classmethod def from_geoms( cls, geom, geom_exposure=None, geom_psf=None, geom_edisp=None, reference_time="2000-01-01", name=None, **kwargs, ): """ Create a MapDataset object with zero filled maps according to the specified geometries. Parameters ---------- geom : `Geom` geometry for the counts and background maps geom_exposure : `Geom` geometry for the exposure map geom_psf : `Geom` geometry for the psf map geom_edisp : `Geom` geometry for the energy dispersion kernel map. If geom_edisp has a migra axis, this will create an EDispMap instead. reference_time : `~astropy.time.Time` the reference time to use in GTI definition name : str Name of the returned dataset. Returns ------- dataset : `MapDataset` or `SpectrumDataset` A dataset containing zero filled maps """ name = make_name(name) kwargs = kwargs.copy() kwargs["name"] = name kwargs["counts"] = Map.from_geom(geom, unit="") kwargs["background"] = Map.from_geom(geom, unit="") if geom_exposure: kwargs["exposure"] = Map.from_geom(geom_exposure, unit="m2 s") if geom_edisp: if "energy" in geom_edisp.axes.names: kwargs["edisp"] = EDispKernelMap.from_geom(geom_edisp) else: kwargs["edisp"] = EDispMap.from_geom(geom_edisp) if geom_psf: if "energy_true" in geom_psf.axes.names: kwargs["psf"] = PSFMap.from_geom(geom_psf) elif "energy" in geom_psf.axes.names: kwargs["psf"] = RecoPSFMap.from_geom(geom_psf) kwargs.setdefault( "gti", GTI.create([] * u.s, [] * u.s, reference_time=reference_time) ) kwargs["mask_safe"] = Map.from_geom(geom, unit="", dtype=bool) return cls(**kwargs)
[docs] @classmethod def create( cls, geom, energy_axis_true=None, migra_axis=None, rad_axis=None, binsz_irf=BINSZ_IRF_DEFAULT, reference_time="2000-01-01", name=None, meta_table=None, **kwargs, ): """Create a MapDataset object with zero filled maps. Parameters ---------- geom : `~gammapy.maps.WcsGeom` Reference target geometry in reco energy, used for counts and background maps energy_axis_true : `~gammapy.maps.MapAxis` True energy axis used for IRF maps migra_axis : `~gammapy.maps.MapAxis` If set, this provides the migration axis for the energy dispersion map. If not set, an EDispKernelMap is produced instead. Default is None rad_axis : `~gammapy.maps.MapAxis` Rad axis for the psf map binsz_irf : float IRF Map pixel size in degrees. reference_time : `~astropy.time.Time` the reference time to use in GTI definition name : str Name of the returned dataset. meta_table : `~astropy.table.Table` Table listing information on observations used to create the dataset. One line per observation for stacked datasets. Returns ------- empty_maps : `MapDataset` A MapDataset containing zero filled maps Examples -------- >>> from gammapy.datasets import MapDataset >>> from gammapy.maps import WcsGeom, MapAxis >>> energy_axis = MapAxis.from_energy_bounds(1.0, 10.0, 4, unit="TeV") >>> energy_axis_true = MapAxis.from_energy_bounds( 0.5, 20, 10, unit="TeV", name="energy_true" ) >>> geom = WcsGeom.create( skydir=(83.633, 22.014), binsz=0.02, width=(2, 2), frame="icrs", proj="CAR", axes=[energy_axis] ) >>> empty = MapDataset.create(geom=geom, energy_axis_true=energy_axis_true, name="empty") """ geoms = create_map_dataset_geoms( geom=geom, energy_axis_true=energy_axis_true, rad_axis=rad_axis, migra_axis=migra_axis, binsz_irf=binsz_irf, ) kwargs.update(geoms) return cls.from_geoms( reference_time=reference_time, name=name, meta_table=meta_table, **kwargs )
@property def mask_safe_image(self): """Reduced safe mask.""" if self.mask_safe is None: return None return self.mask_safe.reduce_over_axes(func=np.logical_or) @property def mask_fit_image(self): """Reduced fit mask.""" if self.mask_fit is None: return None return self.mask_fit.reduce_over_axes(func=np.logical_or) @property def mask_image(self): """Reduced mask.""" if self.mask is None: mask = Map.from_geom(self._geom.to_image(), dtype=bool) mask.data |= True return mask return self.mask.reduce_over_axes(func=np.logical_or) @property def mask_safe_psf(self): """Safe mask for psf maps.""" if self.mask_safe is None or self.psf is None: return None geom = self.psf.psf_map.geom.squash("energy_true").squash("rad") mask_safe_psf = self.mask_safe_image.interp_to_geom(geom.to_image()) return mask_safe_psf.to_cube(geom.axes) @property def mask_safe_edisp(self): """Safe mask for edisp maps.""" if self.mask_safe is None or self.edisp is None: return None if self.mask_safe.geom.is_region: return self.mask_safe geom = self.edisp.edisp_map.geom.squash("energy_true") if "migra" in geom.axes.names: geom = geom.squash("migra") mask_safe_edisp = self.mask_safe_image.interp_to_geom(geom.to_image()) return mask_safe_edisp.to_cube(geom.axes) return self.mask_safe.interp_to_geom(geom)
[docs] def to_masked(self, name=None, nan_to_num=True): """Return masked dataset. Parameters ---------- name : str Name of the masked dataset. nan_to_num: bool Non-finite values are replaced by zero if True (default). Returns ------- dataset : `MapDataset` or `SpectrumDataset` Masked dataset """ dataset = self.__class__.from_geoms(**self.geoms, name=name) dataset.stack(self, nan_to_num=nan_to_num) return dataset
[docs] def stack(self, other, nan_to_num=True): r"""Stack another dataset in place. The original dataset is modified. Safe mask is applied to compute the stacked counts data. Counts outside each dataset safe mask are lost. The stacking of 2 datasets is implemented as follows. Here, :math:`k` denotes a bin in reconstructed energy and :math:`j = {1,2}` is the dataset number The ``mask_safe`` of each dataset is defined as: .. math:: \epsilon_{jk} =\left\{\begin{array}{cl} 1, & \mbox{if bin k is inside the thresholds}\\ 0, & \mbox{otherwise} \end{array}\right. Then the total ``counts`` and model background ``bkg`` are computed according to: .. math:: \overline{\mathrm{n_{on}}}_k = \mathrm{n_{on}}_{1k} \cdot \epsilon_{1k} + \mathrm{n_{on}}_{2k} \cdot \epsilon_{2k} \overline{bkg}_k = bkg_{1k} \cdot \epsilon_{1k} + bkg_{2k} \cdot \epsilon_{2k} The stacked ``safe_mask`` is then: .. math:: \overline{\epsilon_k} = \epsilon_{1k} OR \epsilon_{2k} Parameters ---------- other: `~gammapy.datasets.MapDataset` or `~gammapy.datasets.MapDatasetOnOff` Map dataset to be stacked with this one. If other is an on-off dataset alpha * counts_off is used as a background model. nan_to_num: bool Non-finite values are replaced by zero if True (default). """ if self.counts and other.counts: self.counts.stack( other.counts, weights=other.mask_safe, nan_to_num=nan_to_num ) if self.exposure and other.exposure: self.exposure.stack( other.exposure, weights=other.mask_safe_image, nan_to_num=nan_to_num ) # TODO: check whether this can be improved e.g. handling this in GTI if "livetime" in other.exposure.meta and np.any(other.mask_safe_image): if "livetime" in self.exposure.meta: self.exposure.meta["livetime"] += other.exposure.meta["livetime"] else: self.exposure.meta["livetime"] = other.exposure.meta[ "livetime" ].copy() if self.stat_type == "cash": if self.background and other.background: background = self.npred_background() background.stack( other.npred_background(), weights=other.mask_safe, nan_to_num=nan_to_num, ) self.background = background if self.psf and other.psf: self.psf.stack(other.psf, weights=other.mask_safe_psf) if self.edisp and other.edisp: self.edisp.stack(other.edisp, weights=other.mask_safe_edisp) if self.mask_safe and other.mask_safe: self.mask_safe.stack(other.mask_safe) if self.mask_fit and other.mask_fit: self.mask_fit.stack(other.mask_fit) elif other.mask_fit: self.mask_fit = other.mask_fit.copy() if self.gti and other.gti: self.gti.stack(other.gti) self.gti = self.gti.union() if self.meta_table and other.meta_table: self.meta_table = hstack_columns(self.meta_table, other.meta_table) elif other.meta_table: self.meta_table = other.meta_table.copy()
[docs] def stat_array(self): """Statistic function value per bin given the current model parameters.""" return cash(n_on=self.counts.data, mu_on=self.npred().data)
[docs] def residuals(self, method="diff", **kwargs): """Compute residuals map. Parameters ---------- method: {"diff", "diff/model", "diff/sqrt(model)"} Method used to compute the residuals. Available options are: - "diff" (default): data - model - "diff/model": (data - model) / model - "diff/sqrt(model)": (data - model) / sqrt(model) **kwargs : dict Keyword arguments forwarded to `Map.smooth()` Returns ------- residuals : `gammapy.maps.Map` Residual map. """ npred, counts = self.npred(), self.counts.copy() if self.mask: npred = npred * self.mask counts = counts * self.mask if kwargs: kwargs.setdefault("mode", "constant") kwargs.setdefault("width", "0.1 deg") kwargs.setdefault("kernel", "gauss") with np.errstate(invalid="ignore", divide="ignore"): npred = npred.smooth(**kwargs) counts = counts.smooth(**kwargs) if self.mask: mask = self.mask.smooth(**kwargs) npred /= mask counts /= mask residuals = self._compute_residuals(counts, npred, method=method) if self.mask: residuals.data[~self.mask.data] = np.nan return residuals
[docs] def plot_residuals_spatial( self, ax=None, method="diff", smooth_kernel="gauss", smooth_radius="0.1 deg", **kwargs, ): """Plot spatial residuals. The normalization used for the residuals computation can be controlled using the method parameter. Parameters ---------- ax : `~astropy.visualization.wcsaxes.WCSAxes` Axes to plot on. method : {"diff", "diff/model", "diff/sqrt(model)"} Normalization used to compute the residuals, see `MapDataset.residuals`. smooth_kernel : {"gauss", "box"} Kernel shape. smooth_radius: `~astropy.units.Quantity`, str or float Smoothing width given as quantity or float. If a float is given, it is interpreted as smoothing width in pixels. **kwargs : dict Keyword arguments passed to `~matplotlib.axes.Axes.imshow`. Returns ------- ax : `~astropy.visualization.wcsaxes.WCSAxes` WCSAxes object. Examples -------- >>> from gammapy.datasets import MapDataset >>> dataset = MapDataset.read("$GAMMAPY_DATA/cta-1dc-gc/cta-1dc-gc.fits.gz") >>> kwargs = {"cmap": "RdBu_r", "vmin":-5, "vmax":5, "add_cbar": True} >>> dataset.plot_residuals_spatial(method="diff/sqrt(model)", **kwargs) # doctest: +SKIP """ counts, npred = self.counts.copy(), self.npred() if counts.geom.is_region: raise ValueError("Cannot plot spatial residuals for RegionNDMap") if self.mask is not None: counts *= self.mask npred *= self.mask counts_spatial = counts.sum_over_axes().smooth( width=smooth_radius, kernel=smooth_kernel ) npred_spatial = npred.sum_over_axes().smooth( width=smooth_radius, kernel=smooth_kernel ) residuals = self._compute_residuals(counts_spatial, npred_spatial, method) if self.mask_safe is not None: mask = self.mask_safe.reduce_over_axes(func=np.logical_or, keepdims=True) residuals.data[~mask.data] = np.nan kwargs.setdefault("add_cbar", True) kwargs.setdefault("cmap", "coolwarm") kwargs.setdefault("vmin", -5) kwargs.setdefault("vmax", 5) ax = residuals.plot(ax, **kwargs) return ax
[docs] def plot_residuals_spectral(self, ax=None, method="diff", region=None, **kwargs): """Plot spectral residuals. The residuals are extracted from the provided region, and the normalization used for its computation can be controlled using the method parameter. The error bars are computed using the uncertainty on the excess with a symmetric assumption. Parameters ---------- ax : `~matplotlib.axes.Axes` Axes to plot on. method : {"diff", "diff/sqrt(model)"} Normalization used to compute the residuals, see `SpectrumDataset.residuals`. region: `~regions.SkyRegion` (required) Target sky region. **kwargs : dict Keyword arguments passed to `~matplotlib.axes.Axes.errorbar`. Returns ------- ax : `~matplotlib.axes.Axes` Axes object. Examples -------- >>> from gammapy.datasets import MapDataset >>> dataset = MapDataset.read("$GAMMAPY_DATA/cta-1dc-gc/cta-1dc-gc.fits.gz") >>> kwargs = {"markerfacecolor": "blue", "markersize":8, "marker":'s'} >>> dataset.plot_residuals_spectral(method="diff/sqrt(model)", **kwargs) # doctest: +SKIP """ counts, npred = self.counts.copy(), self.npred() if self.mask is None: mask = self.counts.copy() mask.data = 1 else: mask = self.mask counts *= mask npred *= mask counts_spec = counts.get_spectrum(region) npred_spec = npred.get_spectrum(region) residuals = self._compute_residuals(counts_spec, npred_spec, method) if self.stat_type == "wstat": counts_off = (self.counts_off * mask).get_spectrum(region) with np.errstate(invalid="ignore"): alpha = (self.background * mask).get_spectrum(region) / counts_off mu_sig = (self.npred_signal() * mask).get_spectrum(region) stat = WStatCountsStatistic( n_on=counts_spec, n_off=counts_off, alpha=alpha, mu_sig=mu_sig, ) elif self.stat_type == "cash": stat = CashCountsStatistic(counts_spec.data, npred_spec.data) excess_error = stat.error if method == "diff": yerr = excess_error elif method == "diff/sqrt(model)": yerr = excess_error / np.sqrt(npred_spec.data) else: raise ValueError( 'Invalid method, choose between "diff" and "diff/sqrt(model)"' ) kwargs.setdefault("color", kwargs.pop("c", "black")) ax = residuals.plot(ax, yerr=yerr, **kwargs) ax.axhline(0, color=kwargs["color"], lw=0.5) label = self._residuals_labels[method] ax.set_ylabel(f"Residuals ({label})") ax.set_yscale("linear") ymin = 1.05 * np.nanmin(residuals.data - yerr) ymax = 1.05 * np.nanmax(residuals.data + yerr) ax.set_ylim(ymin, ymax) return ax
[docs] def plot_residuals( self, ax_spatial=None, ax_spectral=None, kwargs_spatial=None, kwargs_spectral=None, ): """Plot spatial and spectral residuals in two panels. Calls `~MapDataset.plot_residuals_spatial` and `~MapDataset.plot_residuals_spectral`. The spectral residuals are extracted from the provided region, and the normalization used for its computation can be controlled using the method parameter. The region outline is overlaid on the residuals map. If no region is passed, the residuals are computed for the entire map Parameters ---------- ax_spatial : `~astropy.visualization.wcsaxes.WCSAxes` Axes to plot spatial residuals on. ax_spectral : `~matplotlib.axes.Axes` Axes to plot spectral residuals on. kwargs_spatial : dict Keyword arguments passed to `~MapDataset.plot_residuals_spatial`. kwargs_spectral : dict Keyword arguments passed to `~MapDataset.plot_residuals_spectral`. The region should be passed as a dictionary key Returns ------- ax_spatial, ax_spectral : `~astropy.visualization.wcsaxes.WCSAxes`, `~matplotlib.axes.Axes` Spatial and spectral residuals plots. Examples -------- >>> from regions import CircleSkyRegion >>> from astropy.coordinates import SkyCoord >>> import astropy.units as u >>> from gammapy.datasets import MapDataset >>> dataset = MapDataset.read("$GAMMAPY_DATA/cta-1dc-gc/cta-1dc-gc.fits.gz") >>> reg = CircleSkyRegion(SkyCoord(0,0, unit="deg", frame="galactic"), radius=1.0 * u.deg) >>> kwargs_spatial = {"cmap": "RdBu_r", "vmin":-5, "vmax":5, "add_cbar": True} >>> kwargs_spectral = {"region":reg, "markerfacecolor": "blue", "markersize": 8, "marker": "s"} # noqa: E501 >>> dataset.plot_residuals(kwargs_spatial=kwargs_spatial, kwargs_spectral=kwargs_spectral) # doctest: +SKIP noqa: E501 """ ax_spatial, ax_spectral = get_axes( ax_spatial, ax_spectral, 12, 4, [1, 2, 1], [1, 2, 2], {"projection": self._geom.to_image().wcs}, ) kwargs_spatial = kwargs_spatial or {} kwargs_spectral = kwargs_spectral or {} self.plot_residuals_spatial(ax_spatial, **kwargs_spatial) self.plot_residuals_spectral(ax_spectral, **kwargs_spectral) # Overlay spectral extraction region on the spatial residuals region = kwargs_spectral.get("region") if region is not None: pix_region = region.to_pixel(self._geom.to_image().wcs) pix_region.plot(ax=ax_spatial) return ax_spatial, ax_spectral
[docs] def stat_sum(self): """Total statistic function value given the current model parameters.""" counts, npred = self.counts.data.astype(float), self.npred().data if self.mask is not None: return cash_sum_cython(counts[self.mask.data], npred[self.mask.data]) else: return cash_sum_cython(counts.ravel(), npred.ravel())
[docs] def fake(self, random_state="random-seed"): """Simulate fake counts for the current model and reduced IRFs. This method overwrites the counts defined on the dataset object. Parameters ---------- random_state : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`} Defines random number generator initialisation. Passed to `~gammapy.utils.random.get_random_state`. """ random_state = get_random_state(random_state) npred = self.npred() data = np.nan_to_num(npred.data, copy=True, nan=0.0, posinf=0.0, neginf=0.0) npred.data = random_state.poisson(data) self.counts = npred
[docs] def to_hdulist(self): """Convert map dataset to list of HDUs. Returns ------- hdulist : `~astropy.io.fits.HDUList` Map dataset list of HDUs. """ # TODO: what todo about the model and background model parameters? exclude_primary = slice(1, None) hdu_primary = fits.PrimaryHDU() header = hdu_primary.header header["NAME"] = self.name hdulist = fits.HDUList([hdu_primary]) if self.counts is not None: hdulist += self.counts.to_hdulist(hdu="counts")[exclude_primary] if self.exposure is not None: hdulist += self.exposure.to_hdulist(hdu="exposure")[exclude_primary] if self.background is not None: hdulist += self.background.to_hdulist(hdu="background")[exclude_primary] if self.edisp is not None: hdulist += self.edisp.to_hdulist()[exclude_primary] if self.psf is not None: hdulist += self.psf.to_hdulist()[exclude_primary] if self.mask_safe is not None: hdulist += self.mask_safe.to_hdulist(hdu="mask_safe")[exclude_primary] if self.mask_fit is not None: hdulist += self.mask_fit.to_hdulist(hdu="mask_fit")[exclude_primary] if self.gti is not None: hdulist.append(fits.BinTableHDU(self.gti.table, name="GTI")) if self.meta_table is not None: hdulist.append(fits.BinTableHDU(self.meta_table, name="META_TABLE")) return hdulist
[docs] @classmethod def from_hdulist(cls, hdulist, name=None, lazy=False, format="gadf"): """Create map dataset from list of HDUs. Parameters ---------- hdulist : `~astropy.io.fits.HDUList` List of HDUs. name : str Name of the new dataset. format : {"gadf"} Format the hdulist is given in. Returns ------- dataset : `MapDataset` Map dataset. """ name = make_name(name) kwargs = {"name": name} if "COUNTS" in hdulist: kwargs["counts"] = Map.from_hdulist(hdulist, hdu="counts", format=format) if "EXPOSURE" in hdulist: exposure = Map.from_hdulist(hdulist, hdu="exposure", format=format) if exposure.geom.axes[0].name == "energy": exposure.geom.axes[0].name = "energy_true" kwargs["exposure"] = exposure if "BACKGROUND" in hdulist: kwargs["background"] = Map.from_hdulist( hdulist, hdu="background", format=format ) if "EDISP" in hdulist: kwargs["edisp"] = EDispMap.from_hdulist( hdulist, hdu="edisp", exposure_hdu="edisp_exposure", format=format ) if "PSF" in hdulist: kwargs["psf"] = PSFMap.from_hdulist( hdulist, hdu="psf", exposure_hdu="psf_exposure", format=format ) if "MASK_SAFE" in hdulist: mask_safe = Map.from_hdulist(hdulist, hdu="mask_safe", format=format) mask_safe.data = mask_safe.data.astype(bool) kwargs["mask_safe"] = mask_safe if "MASK_FIT" in hdulist: mask_fit = Map.from_hdulist(hdulist, hdu="mask_fit", format=format) mask_fit.data = mask_fit.data.astype(bool) kwargs["mask_fit"] = mask_fit if "GTI" in hdulist: gti = GTI(Table.read(hdulist, hdu="GTI")) kwargs["gti"] = gti if "META_TABLE" in hdulist: meta_table = Table.read(hdulist, hdu="META_TABLE") kwargs["meta_table"] = meta_table return cls(**kwargs)
[docs] def write(self, filename, overwrite=False): """Write Dataset to file. A MapDataset is serialised using the GADF format with a WCS geometry. A SpectrumDataset uses the same format, with a RegionGeom. Parameters ---------- filename : str Filename to write to. overwrite : bool Overwrite file if it exists. """ self.to_hdulist().writeto(str(make_path(filename)), overwrite=overwrite)
@classmethod def _read_lazy(cls, name, filename, cache, format=format): name = make_name(name) kwargs = {"name": name} try: kwargs["gti"] = GTI.read(filename) except KeyError: pass path = make_path(filename) for hdu_name in ["counts", "exposure", "mask_fit", "mask_safe", "background"]: kwargs[hdu_name] = HDULocation( hdu_class="map", file_dir=path.parent, file_name=path.name, hdu_name=hdu_name.upper(), cache=cache, format=format, ) kwargs["edisp"] = HDULocation( hdu_class="edisp_map", file_dir=path.parent, file_name=path.name, hdu_name="EDISP", cache=cache, format=format, ) kwargs["psf"] = HDULocation( hdu_class="psf_map", file_dir=path.parent, file_name=path.name, hdu_name="PSF", cache=cache, format=format, ) return cls(**kwargs)
[docs] @classmethod def read(cls, filename, name=None, lazy=False, cache=True, format="gadf"): """Read a dataset from file. Parameters ---------- filename : str Filename to read from. name : str Name of the new dataset. lazy : bool Whether to lazy load data into memory cache : bool Whether to cache the data after loading. format : {"gadf"} Format of the dataset file. Returns ------- dataset : `MapDataset` Map dataset. """ if name is None: header = fits.getheader(str(make_path(filename))) name = header.get("NAME", name) ds_name = make_name(name) if lazy: return cls._read_lazy( name=ds_name, filename=filename, cache=cache, format=format ) else: with fits.open(str(make_path(filename)), memmap=False) as hdulist: return cls.from_hdulist(hdulist, name=ds_name, format=format)
[docs] @classmethod def from_dict(cls, data, lazy=False, cache=True): """Create from dicts and models list generated from YAML serialization.""" filename = make_path(data["filename"]) dataset = cls.read(filename, name=data["name"], lazy=lazy, cache=cache) return dataset
@property def _counts_statistic(self): """Counts statistics of the dataset.""" return CashCountsStatistic(self.counts, self.background)
[docs] def info_dict(self, in_safe_data_range=True): """Info dict with summary statistics, summed over energy. Parameters ---------- in_safe_data_range : bool Whether to sum only in the safe energy range Returns ------- info_dict : dict Dictionary with summary info. """ info = {} info["name"] = self.name if self.mask_safe and in_safe_data_range: mask = self.mask_safe.data.astype(bool) else: mask = slice(None) counts = 0 background, excess, sqrt_ts = np.nan, np.nan, np.nan if self.counts: counts = self.counts.data[mask].sum() if self.background: summed_stat = self._counts_statistic[mask].sum() background = summed_stat.n_bkg excess = summed_stat.n_sig sqrt_ts = summed_stat.sqrt_ts info["counts"] = int(counts) info["excess"] = float(excess) info["sqrt_ts"] = sqrt_ts info["background"] = float(background) npred = np.nan if self.models or not np.isnan(background): npred = self.npred().data[mask].sum() info["npred"] = float(npred) npred_background = np.nan if self.background: npred_background = self.npred_background().data[mask].sum() info["npred_background"] = float(npred_background) npred_signal = np.nan if self.models: npred_signal = self.npred_signal().data[mask].sum() info["npred_signal"] = float(npred_signal) exposure_min = np.nan * u.Unit("cm s") exposure_max = np.nan * u.Unit("cm s") livetime = np.nan * u.s if self.exposure is not None: mask_exposure = self.exposure.data > 0 if self.mask_safe is not None: mask_spatial = self.mask_safe.reduce_over_axes(func=np.logical_or).data mask_exposure = mask_exposure & mask_spatial[np.newaxis, :, :] if not mask_exposure.any(): mask_exposure = slice(None) exposure_min = np.min(self.exposure.quantity[mask_exposure]) exposure_max = np.max(self.exposure.quantity[mask_exposure]) livetime = self.exposure.meta.get("livetime", np.nan * u.s).copy() info["exposure_min"] = exposure_min.item() info["exposure_max"] = exposure_max.item() info["livetime"] = livetime ontime = u.Quantity(np.nan, "s") if self.gti: ontime = self.gti.time_sum info["ontime"] = ontime info["counts_rate"] = info["counts"] / info["livetime"] info["background_rate"] = info["background"] / info["livetime"] info["excess_rate"] = info["excess"] / info["livetime"] # data section n_bins = 0 if self.counts is not None: n_bins = self.counts.data.size info["n_bins"] = int(n_bins) n_fit_bins = 0 if self.mask is not None: n_fit_bins = np.sum(self.mask.data) info["n_fit_bins"] = int(n_fit_bins) info["stat_type"] = self.stat_type stat_sum = np.nan if self.counts is not None and self.models is not None: stat_sum = self.stat_sum() info["stat_sum"] = float(stat_sum) return info
[docs] def to_spectrum_dataset(self, on_region, containment_correction=False, name=None): """Return a ~gammapy.datasets.SpectrumDataset from on_region. Counts and background are summed in the on_region. Exposure is taken from the average exposure. The energy dispersion kernel is obtained at the on_region center. Only regions with centers are supported. The model is not exported to the ~gammapy.datasets.SpectrumDataset. It must be set after the dataset extraction. Parameters ---------- on_region : `~regions.SkyRegion` the input ON region on which to extract the spectrum containment_correction : bool Apply containment correction for point sources and circular on regions name : str Name of the new dataset. Returns ------- dataset : `~gammapy.datasets.SpectrumDataset` the resulting reduced dataset """ from .spectrum import SpectrumDataset dataset = self.to_region_map_dataset(region=on_region, name=name) if containment_correction: if not isinstance(on_region, CircleSkyRegion): raise TypeError( "Containment correction is only supported for" " `CircleSkyRegion`." ) elif self.psf is None or isinstance(self.psf, PSFKernel): raise ValueError("No PSFMap set. Containment correction impossible") else: geom = dataset.exposure.geom energy_true = geom.axes["energy_true"].center containment = self.psf.containment( position=on_region.center, energy_true=energy_true, rad=on_region.radius, ) dataset.exposure.quantity *= containment.reshape(geom.data_shape) kwargs = {"name": name} for key in [ "counts", "edisp", "mask_safe", "mask_fit", "exposure", "gti", "meta_table", ]: kwargs[key] = getattr(dataset, key) if self.stat_type == "cash": kwargs["background"] = dataset.background return SpectrumDataset(**kwargs)
[docs] def to_region_map_dataset(self, region, name=None): """Integrate the map dataset in a given region. Counts and background of the dataset are integrated in the given region, taking the safe mask into account. The exposure is averaged in the region again taking the safe mask into account. The PSF and energy dispersion kernel are taken at the center of the region. Parameters ---------- region : `~regions.SkyRegion` Region from which to extract the spectrum name : str Name of the new dataset. Returns ------- dataset : `~gammapy.datasets.MapDataset` the resulting reduced dataset """ name = make_name(name) kwargs = {"gti": self.gti, "name": name, "meta_table": self.meta_table} if self.mask_safe: kwargs["mask_safe"] = self.mask_safe.to_region_nd_map(region, func=np.any) if self.mask_fit: kwargs["mask_fit"] = self.mask_fit.to_region_nd_map(region, func=np.any) if self.counts: kwargs["counts"] = self.counts.to_region_nd_map( region, np.sum, weights=self.mask_safe ) if self.stat_type == "cash" and self.background: kwargs["background"] = self.background.to_region_nd_map( region, func=np.sum, weights=self.mask_safe ) if self.exposure: kwargs["exposure"] = self.exposure.to_region_nd_map(region, func=np.mean) region = region.center if region else None # TODO: Compute average psf in region if self.psf: kwargs["psf"] = self.psf.to_region_nd_map(region) # TODO: Compute average edisp in region if self.edisp is not None: kwargs["edisp"] = self.edisp.to_region_nd_map(region) return self.__class__(**kwargs)
[docs] def cutout(self, position, width, mode="trim", name=None): """Cutout map dataset. Parameters ---------- position : `~astropy.coordinates.SkyCoord` Center position of the cutout region. width : tuple of `~astropy.coordinates.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 `~astropy.nddata.utils.Cutout2D`. name : str Name of the new dataset. Returns ------- cutout : `MapDataset` Cutout map dataset. """ name = make_name(name) kwargs = {"gti": self.gti, "name": name, "meta_table": self.meta_table} cutout_kwargs = {"position": position, "width": width, "mode": mode} if self.counts is not None: kwargs["counts"] = self.counts.cutout(**cutout_kwargs) if self.exposure is not None: kwargs["exposure"] = self.exposure.cutout(**cutout_kwargs) if self.background is not None and self.stat_type == "cash": kwargs["background"] = self.background.cutout(**cutout_kwargs) if self.edisp is not None: kwargs["edisp"] = self.edisp.cutout(**cutout_kwargs) if self.psf is not None: kwargs["psf"] = self.psf.cutout(**cutout_kwargs) if self.mask_safe is not None: kwargs["mask_safe"] = self.mask_safe.cutout(**cutout_kwargs) if self.mask_fit is not None: kwargs["mask_fit"] = self.mask_fit.cutout(**cutout_kwargs) return self.__class__(**kwargs)
[docs] def downsample(self, factor, axis_name=None, name=None): """Downsample map dataset. The PSFMap and EDispKernelMap are not downsampled, except if a corresponding axis is given. Parameters ---------- factor : int Downsampling factor. axis_name : str Which non-spatial axis to downsample. By default only spatial axes are downsampled. name : str Name of the downsampled dataset. Returns ------- dataset : `MapDataset` or `SpectrumDataset` Downsampled map dataset. """ name = make_name(name) kwargs = {"gti": self.gti, "name": name, "meta_table": self.meta_table} if self.counts is not None: kwargs["counts"] = self.counts.downsample( factor=factor, preserve_counts=True, axis_name=axis_name, weights=self.mask_safe, ) if self.exposure is not None: if axis_name is None: kwargs["exposure"] = self.exposure.downsample( factor=factor, preserve_counts=False, axis_name=None ) else: kwargs["exposure"] = self.exposure.copy() if self.background is not None and self.stat_type == "cash": kwargs["background"] = self.background.downsample( factor=factor, axis_name=axis_name, weights=self.mask_safe ) if self.edisp is not None: if axis_name is not None: kwargs["edisp"] = self.edisp.downsample( factor=factor, axis_name=axis_name, weights=self.mask_safe_edisp ) else: kwargs["edisp"] = self.edisp.copy() if self.psf is not None: kwargs["psf"] = self.psf.copy() if self.mask_safe is not None: kwargs["mask_safe"] = self.mask_safe.downsample( factor=factor, preserve_counts=False, axis_name=axis_name ) if self.mask_fit is not None: kwargs["mask_fit"] = self.mask_fit.downsample( factor=factor, preserve_counts=False, axis_name=axis_name ) return self.__class__(**kwargs)
[docs] def pad(self, pad_width, mode="constant", name=None): """Pad the spatial dimensions of the dataset. The padding only applies to counts, masks, background and exposure. Counts, background and masks are padded with zeros, exposure is padded with edge value. Parameters ---------- pad_width : {sequence, array_like, int} Number of pixels padded to the edges of each axis. name : str Name of the padded dataset. Returns ------- dataset : `MapDataset` Padded map dataset. """ name = make_name(name) kwargs = {"gti": self.gti, "name": name, "meta_table": self.meta_table} if self.counts is not None: kwargs["counts"] = self.counts.pad(pad_width=pad_width, mode=mode) if self.exposure is not None: kwargs["exposure"] = self.exposure.pad(pad_width=pad_width, mode=mode) if self.background is not None: kwargs["background"] = self.background.pad(pad_width=pad_width, mode=mode) if self.edisp is not None: kwargs["edisp"] = self.edisp.copy() if self.psf is not None: kwargs["psf"] = self.psf.copy() if self.mask_safe is not None: kwargs["mask_safe"] = self.mask_safe.pad(pad_width=pad_width, mode=mode) if self.mask_fit is not None: kwargs["mask_fit"] = self.mask_fit.pad(pad_width=pad_width, mode=mode) return self.__class__(**kwargs)
[docs] def slice_by_idx(self, slices, name=None): """Slice sub dataset. The slicing only applies to the maps that define the corresponding axes. Parameters ---------- slices : dict 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. name : str Name of the sliced dataset. Returns ------- dataset : `MapDataset` or `SpectrumDataset` Sliced dataset Examples -------- >>> from gammapy.datasets import MapDataset >>> dataset = MapDataset.read("$GAMMAPY_DATA/cta-1dc-gc/cta-1dc-gc.fits.gz") >>> slices = {"energy": slice(0, 3)} #to get the first 3 energy slices >>> sliced = dataset.slice_by_idx(slices) >>> print(sliced.geoms["geom"]) WcsGeom axes : ['lon', 'lat', 'energy'] shape : (320, 240, 3) ndim : 3 frame : galactic projection : CAR center : 0.0 deg, 0.0 deg width : 8.0 deg x 6.0 deg wcs ref : 0.0 deg, 0.0 deg """ name = make_name(name) kwargs = {"gti": self.gti, "name": name, "meta_table": self.meta_table} if self.counts is not None: kwargs["counts"] = self.counts.slice_by_idx(slices=slices) if self.exposure is not None: kwargs["exposure"] = self.exposure.slice_by_idx(slices=slices) if self.background is not None and self.stat_type == "cash": kwargs["background"] = self.background.slice_by_idx(slices=slices) if self.edisp is not None: kwargs["edisp"] = self.edisp.slice_by_idx(slices=slices) if self.psf is not None: kwargs["psf"] = self.psf.slice_by_idx(slices=slices) if self.mask_safe is not None: kwargs["mask_safe"] = self.mask_safe.slice_by_idx(slices=slices) if self.mask_fit is not None: kwargs["mask_fit"] = self.mask_fit.slice_by_idx(slices=slices) return self.__class__(**kwargs)
[docs] def slice_by_energy(self, energy_min=None, energy_max=None, name=None): """Select and slice datasets in energy range Parameters ---------- energy_min, energy_max : `~astropy.units.Quantity` Energy bounds to compute the flux point for. name : str Name of the sliced dataset. Returns ------- dataset : `MapDataset` Sliced Dataset Examples -------- >>> from gammapy.datasets import MapDataset >>> dataset = MapDataset.read("$GAMMAPY_DATA/cta-1dc-gc/cta-1dc-gc.fits.gz") >>> sliced = dataset.slice_by_energy(energy_min="1 TeV", energy_max="5 TeV") >>> sliced.data_shape (3, 240, 320) """ name = make_name(name) energy_axis = self._geom.axes["energy"] if energy_min is None: energy_min = energy_axis.bounds[0] if energy_max is None: energy_max = energy_axis.bounds[1] energy_min, energy_max = u.Quantity(energy_min), u.Quantity(energy_max) group = energy_axis.group_table(edges=[energy_min, energy_max]) is_normal = group["bin_type"] == "normal " group = group[is_normal] slices = { "energy": slice(int(group["idx_min"][0]), int(group["idx_max"][0]) + 1) } return self.slice_by_idx(slices, name=name)
[docs] def reset_data_cache(self): """Reset data cache to free memory space""" for name in self._lazy_data_members: if self.__dict__.pop(name, False): log.info(f"Clearing {name} cache for dataset {self.name}")
[docs] def resample_energy_axis(self, energy_axis, name=None): """Resample MapDataset over new reco energy axis. Counts are summed taking into account safe mask. Parameters ---------- energy_axis : `~gammapy.maps.MapAxis` New reconstructed energy axis. name: str Name of the new dataset. Returns ------- dataset: `MapDataset` or `SpectrumDataset` Resampled dataset. """ name = make_name(name) kwargs = {"gti": self.gti, "name": name, "meta_table": self.meta_table} if self.exposure: kwargs["exposure"] = self.exposure if self.psf: kwargs["psf"] = self.psf if self.mask_safe is not None: kwargs["mask_safe"] = self.mask_safe.resample_axis( axis=energy_axis, ufunc=np.logical_or ) if self.mask_fit is not None: kwargs["mask_fit"] = self.mask_fit.resample_axis( axis=energy_axis, ufunc=np.logical_or ) if self.counts is not None: kwargs["counts"] = self.counts.resample_axis( axis=energy_axis, weights=self.mask_safe ) if self.background is not None and self.stat_type == "cash": kwargs["background"] = self.background.resample_axis( axis=energy_axis, weights=self.mask_safe ) # Mask_safe or mask_irf?? if isinstance(self.edisp, EDispKernelMap): kwargs["edisp"] = self.edisp.resample_energy_axis( energy_axis=energy_axis, weights=self.mask_safe_edisp ) else: # None or EDispMap kwargs["edisp"] = self.edisp return self.__class__(**kwargs)
[docs] def to_image(self, name=None): """Create images by summing over the reconstructed energy axis. Parameters ---------- name : str Name of the new dataset. Returns ------- dataset : `MapDataset` or `SpectrumDataset` Dataset integrated over non-spatial axes. """ energy_axis = self._geom.axes["energy"].squash() return self.resample_energy_axis(energy_axis=energy_axis, name=name)
[docs] def peek(self, figsize=(12, 10)): """Quick-look summary plots. Parameters ---------- figsize : tuple Size of the figure. """ def plot_mask(ax, mask, **kwargs): if mask is not None: mask.plot_mask(ax=ax, **kwargs) fig, axes = plt.subplots( ncols=2, nrows=2, subplot_kw={"projection": self._geom.wcs}, figsize=figsize, gridspec_kw={"hspace": 0.1, "wspace": 0.1}, ) axes = axes.flat axes[0].set_title("Counts") self.counts.sum_over_axes().plot(ax=axes[0], add_cbar=True) plot_mask(ax=axes[0], mask=self.mask_fit_image, alpha=0.2) plot_mask(ax=axes[0], mask=self.mask_safe_image, hatches=["///"], colors="w") axes[1].set_title("Excess counts") self.excess.sum_over_axes().plot(ax=axes[1], add_cbar=True) plot_mask(ax=axes[1], mask=self.mask_fit_image, alpha=0.2) plot_mask(ax=axes[1], mask=self.mask_safe_image, hatches=["///"], colors="w") axes[2].set_title("Exposure") self.exposure.sum_over_axes().plot(ax=axes[2], add_cbar=True) plot_mask(ax=axes[2], mask=self.mask_safe_image, hatches=["///"], colors="w") axes[3].set_title("Background") self.background.sum_over_axes().plot(ax=axes[3], add_cbar=True) plot_mask(ax=axes[3], mask=self.mask_fit_image, alpha=0.2) plot_mask(ax=axes[3], mask=self.mask_safe_image, hatches=["///"], colors="w")
[docs]class MapDatasetOnOff(MapDataset): """Map dataset for on-off likelihood fitting. It bundles together the binned on and off counts, the binned IRFs as well as the on and off acceptances. A safe mask and a fit mask can be added to exclude bins during the analysis. It uses the Wstat statistic (see `~gammapy.stats.wstat`), therefore no background model is needed. For more information see :ref:`datasets`. Parameters ---------- models : `~gammapy.modeling.models.Models` Source sky models. counts : `~gammapy.maps.WcsNDMap` Counts cube counts_off : `~gammapy.maps.WcsNDMap` Ring-convolved counts cube acceptance : `~gammapy.maps.WcsNDMap` Acceptance from the IRFs acceptance_off : `~gammapy.maps.WcsNDMap` Acceptance off exposure : `~gammapy.maps.WcsNDMap` Exposure cube mask_fit : `~gammapy.maps.WcsNDMap` Mask to apply to the likelihood for fitting. psf : `~gammapy.irf.PSFKernel` PSF kernel edisp : `~gammapy.irf.EDispKernel` Energy dispersion mask_safe : `~gammapy.maps.WcsNDMap` Mask defining the safe data range. gti : `~gammapy.data.GTI` GTI of the observation or union of GTI if it is a stacked observation meta_table : `~astropy.table.Table` Table listing information on observations used to create the dataset. One line per observation for stacked datasets. name : str Name of the dataset. See Also -------- MapDataset, SpectrumDataset, FluxPointsDataset """ stat_type = "wstat" tag = "MapDatasetOnOff" def __init__( self, models=None, counts=None, counts_off=None, acceptance=None, acceptance_off=None, exposure=None, mask_fit=None, psf=None, edisp=None, name=None, mask_safe=None, gti=None, meta_table=None, ): self._name = make_name(name) self._evaluators = {} self.counts = counts self.counts_off = counts_off self.exposure = exposure self.acceptance = acceptance self.acceptance_off = acceptance_off self.gti = gti self.mask_fit = mask_fit self.psf = psf self.edisp = edisp self.models = models self.mask_safe = mask_safe self.meta_table = meta_table def __str__(self): str_ = super().__str__() counts_off = np.nan if self.counts_off is not None: counts_off = np.sum(self.counts_off.data) str_ += "\t{:32}: {:.0f} \n".format("Total counts_off", counts_off) acceptance = np.nan if self.acceptance is not None: acceptance = np.sum(self.acceptance.data) str_ += "\t{:32}: {:.0f} \n".format("Acceptance", acceptance) acceptance_off = np.nan if self.acceptance_off is not None: acceptance_off = np.sum(self.acceptance_off.data) str_ += "\t{:32}: {:.0f} \n".format("Acceptance off", acceptance_off) return str_.expandtabs(tabsize=2) @property def _geom(self): """Main analysis geometry""" if self.counts is not None: return self.counts.geom elif self.counts_off is not None: return self.counts_off.geom elif self.acceptance is not None: return self.acceptance.geom elif self.acceptance_off is not None: return self.acceptance_off.geom else: raise ValueError( "Either 'counts', 'counts_off', 'acceptance' or 'acceptance_of' must be defined." ) @property def alpha(self): """Exposure ratio between signal and background regions See :ref:`wstat` Returns ------- alpha : `Map` Alpha map """ with np.errstate(invalid="ignore", divide="ignore"): data = self.acceptance.quantity / self.acceptance_off.quantity data = np.nan_to_num(data) return Map.from_geom(self._geom, data=data.to_value(""), unit="")
[docs] def npred_background(self): """Predicted background counts estimated from the marginalized likelihood estimate. See :ref:`wstat` Returns ------- npred_background : `Map` Predicted background counts """ mu_bkg = self.alpha.data * get_wstat_mu_bkg( n_on=self.counts.data, n_off=self.counts_off.data, alpha=self.alpha.data, mu_sig=self.npred_signal().data, ) mu_bkg = np.nan_to_num(mu_bkg) return Map.from_geom(geom=self._geom, data=mu_bkg)
[docs] def npred_off(self): """Predicted counts in the off region; mu_bkg/alpha See :ref:`wstat` Returns ------- npred_off : `Map` Predicted off counts """ return self.npred_background() / self.alpha
@property def background(self): """Computed as alpha * n_off See :ref:`wstat` Returns ------- background : `Map` Background map """ if self.counts_off is None: return None return self.alpha * self.counts_off
[docs] def stat_array(self): """Statistic function value per bin given the current model parameters""" mu_sig = self.npred_signal().data on_stat_ = wstat( n_on=self.counts.data, n_off=self.counts_off.data, alpha=list(self.alpha.data), mu_sig=mu_sig, ) return np.nan_to_num(on_stat_)
@property def _counts_statistic(self): """Counts statistics of the dataset.""" return WStatCountsStatistic(self.counts, self.counts_off, self.alpha)
[docs] @classmethod def from_geoms( cls, geom, geom_exposure=None, geom_psf=None, geom_edisp=None, reference_time="2000-01-01", name=None, **kwargs, ): """Create an empty `MapDatasetOnOff` object according to the specified geometries. Parameters ---------- geom : `gammapy.maps.WcsGeom` geometry for the counts, counts_off, acceptance and acceptance_off maps geom_exposure : `gammapy.maps.WcsGeom` geometry for the exposure map geom_psf : `gammapy.maps.WcsGeom` geometry for the psf map geom_edisp : `gammapy.maps.WcsGeom` geometry for the energy dispersion kernel map. If geom_edisp has a migra axis, this will create an EDispMap instead. reference_time : `~astropy.time.Time` the reference time to use in GTI definition name : str Name of the returned dataset. Returns ------- empty_maps : `MapDatasetOnOff` A MapDatasetOnOff containing zero filled maps """ # TODO: it seems the super() pattern does not work here? dataset = MapDataset.from_geoms( geom=geom, geom_exposure=geom_exposure, geom_psf=geom_psf, geom_edisp=geom_edisp, name=name, reference_time=reference_time, **kwargs, ) off_maps = {} for key in ["counts_off", "acceptance", "acceptance_off"]: off_maps[key] = Map.from_geom(geom, unit="") return cls.from_map_dataset(dataset, name=name, **off_maps)
[docs] @classmethod def from_map_dataset( cls, dataset, acceptance, acceptance_off, counts_off=None, name=None ): """Create on off dataset from a map dataset. Parameters ---------- dataset : `MapDataset` Spectrum dataset defining counts, edisp, aeff, livetime etc. acceptance : `Map` Relative background efficiency in the on region. acceptance_off : `Map` Relative background efficiency in the off region. counts_off : `Map` Off counts map . If the dataset provides a background model, and no off counts are defined. The off counts are deferred from counts_off / alpha. name : str Name of the returned dataset. Returns ------- dataset : `MapDatasetOnOff` Map dataset on off. """ if counts_off is None and dataset.background is not None: alpha = acceptance / acceptance_off counts_off = dataset.npred_background() / alpha if np.isscalar(acceptance): acceptance = Map.from_geom(dataset._geom, data=acceptance) if np.isscalar(acceptance_off): acceptance_off = Map.from_geom(dataset._geom, data=acceptance_off) return cls( models=dataset.models, counts=dataset.counts, exposure=dataset.exposure, counts_off=counts_off, edisp=dataset.edisp, psf=dataset.psf, mask_safe=dataset.mask_safe, mask_fit=dataset.mask_fit, acceptance=acceptance, acceptance_off=acceptance_off, gti=dataset.gti, name=name, meta_table=dataset.meta_table, )
[docs] def to_map_dataset(self, name=None): """Convert a MapDatasetOnOff to a MapDataset. The background model template is taken as alpha * counts_off. Parameters ---------- name: str Name of the new dataset Returns ------- dataset: `MapDataset` Map dataset with cash statistics """ name = make_name(name) return MapDataset( counts=self.counts, exposure=self.exposure, psf=self.psf, edisp=self.edisp, name=name, gti=self.gti, mask_fit=self.mask_fit, mask_safe=self.mask_safe, background=self.counts_off * self.alpha, meta_table=self.meta_table, )
@property def _is_stackable(self): """Check if the Dataset contains enough information to be stacked""" incomplete = ( self.acceptance_off is None or self.acceptance is None or self.counts_off is None ) unmasked = np.any(self.mask_safe.data) if incomplete and unmasked: return False else: return True
[docs] def stack(self, other, nan_to_num=True): r"""Stack another dataset in place. The ``acceptance`` of the stacked dataset is normalized to 1, and the stacked ``acceptance_off`` is scaled so that: .. math:: \alpha_\text{stacked} = \frac{1}{a_\text{off}} = \frac{\alpha_1\text{OFF}_1 + \alpha_2\text{OFF}_2}{\text{OFF}_1 + OFF_2} Parameters ---------- other : `MapDatasetOnOff` Other dataset nan_to_num: bool Non-finite values are replaced by zero if True (default). """ if not isinstance(other, MapDatasetOnOff): raise TypeError("Incompatible types for MapDatasetOnOff stacking") if not self._is_stackable or not other._is_stackable: raise ValueError("Cannot stack incomplete MapDatasetOnOff.") geom = self.counts.geom total_off = Map.from_geom(geom) total_alpha = Map.from_geom(geom) if self.counts_off: total_off.stack( self.counts_off, weights=self.mask_safe, nan_to_num=nan_to_num ) total_alpha.stack( self.alpha * self.counts_off, weights=self.mask_safe, nan_to_num=nan_to_num, ) if other.counts_off: total_off.stack( other.counts_off, weights=other.mask_safe, nan_to_num=nan_to_num ) total_alpha.stack( other.alpha * other.counts_off, weights=other.mask_safe, nan_to_num=nan_to_num, ) with np.errstate(divide="ignore", invalid="ignore"): acceptance_off = total_off / total_alpha average_alpha = total_alpha.data.sum() / total_off.data.sum() # For the bins where the stacked OFF counts equal 0, the alpha value is # performed by weighting on the total OFF counts of each run is_zero = total_off.data == 0 acceptance_off.data[is_zero] = 1 / average_alpha self.acceptance.data[...] = 1 self.acceptance_off = acceptance_off self.counts_off = total_off super().stack(other, nan_to_num=nan_to_num)
[docs] def stat_sum(self): """Total statistic function value given the current model parameters. If the off counts are passed as None and the elements of the safe mask are False, zero will be returned. Otherwise, the stat sum will be calculated and returned. """ if self.counts_off is None and not np.any(self.mask_safe.data): return 0 else: return Dataset.stat_sum(self)
[docs] def fake(self, npred_background, random_state="random-seed"): """Simulate fake counts (on and off) for the current model and reduced IRFs. This method overwrites the counts defined on the dataset object. Parameters ---------- npred_background : `~gammapy.maps.Map` Expected number of background counts in the on region random_state : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`} Defines random number generator initialisation. Passed to `~gammapy.utils.random.get_random_state`. """ random_state = get_random_state(random_state) npred = self.npred_signal() data = np.nan_to_num(npred.data, copy=True, nan=0.0, posinf=0.0, neginf=0.0) npred.data = random_state.poisson(data) npred_bkg = random_state.poisson(npred_background.data) self.counts = npred + npred_bkg npred_off = npred_background / self.alpha data_off = np.nan_to_num( npred_off.data, copy=True, nan=0.0, posinf=0.0, neginf=0.0 ) npred_off.data = random_state.poisson(data_off) self.counts_off = npred_off
[docs] def to_hdulist(self): """Convert map dataset to list of HDUs. Returns ------- hdulist : `~astropy.io.fits.HDUList` Map dataset list of HDUs. """ hdulist = super().to_hdulist() exclude_primary = slice(1, None) del hdulist["BACKGROUND"] del hdulist["BACKGROUND_BANDS"] if self.counts_off is not None: hdulist += self.counts_off.to_hdulist(hdu="counts_off")[exclude_primary] if self.acceptance is not None: hdulist += self.acceptance.to_hdulist(hdu="acceptance")[exclude_primary] if self.acceptance_off is not None: hdulist += self.acceptance_off.to_hdulist(hdu="acceptance_off")[ exclude_primary ] return hdulist
@classmethod def _read_lazy(cls, filename, name=None, cache=True, format="gadf"): raise NotImplementedError( f"Lazy loading is not implemented for {cls}, please use option lazy=False." )
[docs] @classmethod def from_hdulist(cls, hdulist, name=None, format="gadf"): """Create map dataset from list of HDUs. Parameters ---------- hdulist : `~astropy.io.fits.HDUList` List of HDUs. name : str Name of the new dataset. format : {"gadf"} Format the hdulist is given in. Returns ------- dataset : `MapDatasetOnOff` Map dataset. """ kwargs = {} kwargs["name"] = name if "COUNTS" in hdulist: kwargs["counts"] = Map.from_hdulist(hdulist, hdu="counts", format=format) if "COUNTS_OFF" in hdulist: kwargs["counts_off"] = Map.from_hdulist( hdulist, hdu="counts_off", format=format ) if "ACCEPTANCE" in hdulist: kwargs["acceptance"] = Map.from_hdulist( hdulist, hdu="acceptance", format=format ) if "ACCEPTANCE_OFF" in hdulist: kwargs["acceptance_off"] = Map.from_hdulist( hdulist, hdu="acceptance_off", format=format ) if "EXPOSURE" in hdulist: kwargs["exposure"] = Map.from_hdulist( hdulist, hdu="exposure", format=format ) if "EDISP" in hdulist: edisp_map = Map.from_hdulist(hdulist, hdu="edisp", format=format) try: exposure_map = Map.from_hdulist( hdulist, hdu="edisp_exposure", format=format ) except KeyError: exposure_map = None if edisp_map.geom.axes[0].name == "energy": kwargs["edisp"] = EDispKernelMap(edisp_map, exposure_map) else: kwargs["edisp"] = EDispMap(edisp_map, exposure_map) if "PSF" in hdulist: psf_map = Map.from_hdulist(hdulist, hdu="psf", format=format) try: exposure_map = Map.from_hdulist( hdulist, hdu="psf_exposure", format=format ) except KeyError: exposure_map = None kwargs["psf"] = PSFMap(psf_map, exposure_map) if "MASK_SAFE" in hdulist: mask_safe = Map.from_hdulist(hdulist, hdu="mask_safe", format=format) kwargs["mask_safe"] = mask_safe if "MASK_FIT" in hdulist: mask_fit = Map.from_hdulist(hdulist, hdu="mask_fit", format=format) kwargs["mask_fit"] = mask_fit if "GTI" in hdulist: gti = GTI(Table.read(hdulist, hdu="GTI")) kwargs["gti"] = gti if "META_TABLE" in hdulist: meta_table = Table.read(hdulist, hdu="META_TABLE") kwargs["meta_table"] = meta_table return cls(**kwargs)
[docs] def info_dict(self, in_safe_data_range=True): """Basic info dict with summary statistics. If a region is passed, then a spectrum dataset is extracted, and the corresponding info returned. Parameters ---------- in_safe_data_range : bool Whether to sum only in the safe energy range Returns ------- info_dict : dict Dictionary with summary info. """ # TODO: remove code duplication with SpectrumDatasetOnOff info = super().info_dict(in_safe_data_range) if self.mask_safe and in_safe_data_range: mask = self.mask_safe.data.astype(bool) else: mask = slice(None) summed_stat = self._counts_statistic[mask].sum() counts_off = 0 if self.counts_off is not None: counts_off = summed_stat.n_off info["counts_off"] = int(counts_off) acceptance = 1 if self.acceptance: acceptance = self.acceptance.data[mask].sum() info["acceptance"] = float(acceptance) acceptance_off = np.nan alpha = np.nan if self.acceptance_off: alpha = summed_stat.alpha acceptance_off = acceptance / alpha info["acceptance_off"] = float(acceptance_off) info["alpha"] = float(alpha) info["stat_sum"] = self.stat_sum() return info
[docs] def to_spectrum_dataset(self, on_region, containment_correction=False, name=None): """Return a ~gammapy.datasets.SpectrumDatasetOnOff from on_region. Counts and OFF counts are summed in the on_region. Acceptance is the average of all acceptances while acceptance OFF is taken such that number of excess is preserved in the on_region. Effective area is taken from the average exposure. The energy dispersion kernel is obtained at the on_region center. Only regions with centers are supported. The models are not exported to the ~gammapy.dataset.SpectrumDatasetOnOff. It must be set after the dataset extraction. Parameters ---------- on_region : `~regions.SkyRegion` the input ON region on which to extract the spectrum containment_correction : bool Apply containment correction for point sources and circular on regions name : str Name of the new dataset. Returns ------- dataset : `~gammapy.datasets.SpectrumDatasetOnOff` the resulting reduced dataset """ from .spectrum import SpectrumDatasetOnOff dataset = super().to_spectrum_dataset( on_region=on_region, containment_correction=containment_correction, name=name, ) kwargs = {"name": name} if self.counts_off is not None: kwargs["counts_off"] = self.counts_off.get_spectrum( on_region, np.sum, weights=self.mask_safe ) if self.acceptance is not None: kwargs["acceptance"] = self.acceptance.get_spectrum( on_region, np.mean, weights=self.mask_safe ) norm = self.background.get_spectrum( on_region, np.sum, weights=self.mask_safe ) acceptance_off = kwargs["acceptance"] * kwargs["counts_off"] / norm np.nan_to_num(acceptance_off.data, copy=False) kwargs["acceptance_off"] = acceptance_off return SpectrumDatasetOnOff.from_spectrum_dataset(dataset=dataset, **kwargs)
[docs] def cutout(self, position, width, mode="trim", name=None): """Cutout map dataset. Parameters ---------- position : `~astropy.coordinates.SkyCoord` Center position of the cutout region. width : tuple of `~astropy.coordinates.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 `~astropy.nddata.utils.Cutout2D`. name : str Name of the new dataset. Returns ------- cutout : `MapDatasetOnOff` Cutout map dataset. """ cutout_kwargs = { "position": position, "width": width, "mode": mode, "name": name, } cutout_dataset = super().cutout(**cutout_kwargs) del cutout_kwargs["name"] if self.counts_off is not None: cutout_dataset.counts_off = self.counts_off.cutout(**cutout_kwargs) if self.acceptance is not None: cutout_dataset.acceptance = self.acceptance.cutout(**cutout_kwargs) if self.acceptance_off is not None: cutout_dataset.acceptance_off = self.acceptance_off.cutout(**cutout_kwargs) return cutout_dataset
[docs] def downsample(self, factor, axis_name=None, name=None): """Downsample map dataset. The PSFMap and EDispKernelMap are not downsampled, except if a corresponding axis is given. Parameters ---------- factor : int Downsampling factor. axis_name : str Which non-spatial axis to downsample. By default, only spatial axes are downsampled. name : str Name of the downsampled dataset. Returns ------- dataset : `MapDatasetOnOff` Downsampled map dataset. """ dataset = super().downsample(factor, axis_name, name) counts_off = None if self.counts_off is not None: counts_off = self.counts_off.downsample( factor=factor, preserve_counts=True, axis_name=axis_name, weights=self.mask_safe, ) acceptance, acceptance_off = None, None if self.acceptance_off is not None: acceptance = self.acceptance.downsample( factor=factor, preserve_counts=False, axis_name=axis_name ) factor = self.background.downsample( factor=factor, preserve_counts=True, axis_name=axis_name, weights=self.mask_safe, ) acceptance_off = acceptance * counts_off / factor return self.__class__.from_map_dataset( dataset, acceptance=acceptance, acceptance_off=acceptance_off, counts_off=counts_off, )
[docs] def pad(self): raise NotImplementedError
[docs] def slice_by_idx(self, slices, name=None): """Slice sub dataset. The slicing only applies to the maps that define the corresponding axes. Parameters ---------- slices : dict 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. name : str Name of the sliced dataset. Returns ------- map_out : `Map` Sliced map object. """ kwargs = {"name": name} dataset = super().slice_by_idx(slices, name) if self.counts_off is not None: kwargs["counts_off"] = self.counts_off.slice_by_idx(slices=slices) if self.acceptance is not None: kwargs["acceptance"] = self.acceptance.slice_by_idx(slices=slices) if self.acceptance_off is not None: kwargs["acceptance_off"] = self.acceptance_off.slice_by_idx(slices=slices) return self.from_map_dataset(dataset, **kwargs)
[docs] def resample_energy_axis(self, energy_axis, name=None): """Resample MapDatasetOnOff over reconstructed energy edges. Counts are summed taking into account safe mask. Parameters ---------- energy_axis : `~gammapy.maps.MapAxis` New reco energy axis. name: str Name of the new dataset. Returns ------- dataset: `SpectrumDataset` Resampled spectrum dataset . """ dataset = super().resample_energy_axis(energy_axis, name) counts_off = None if self.counts_off is not None: counts_off = self.counts_off counts_off = counts_off.resample_axis( axis=energy_axis, weights=self.mask_safe ) acceptance = 1 acceptance_off = None if self.acceptance is not None: acceptance = self.acceptance acceptance = acceptance.resample_axis( axis=energy_axis, weights=self.mask_safe ) norm_factor = self.background.resample_axis( axis=energy_axis, weights=self.mask_safe ) acceptance_off = acceptance * counts_off / norm_factor return self.__class__.from_map_dataset( dataset, acceptance=acceptance, acceptance_off=acceptance_off, counts_off=counts_off, name=name, )