ConstantTemporalModel¶

class gammapy.modeling.models.ConstantTemporalModel(**kwargs)[source]¶

Bases: gammapy.modeling.models.TemporalModel

Constant temporal model.

Parameters

normfloat: The normalization of the constant temporal model

Attributes Summary

`default_parameters`
`norm`	A model parameter.
`parameters`	Parameters (`Parameters`)
`tag`

Methods Summary

`copy`(self)	A deep copy.
`create`(tag, \args, \\*kwargs)	Create a model instance.
`evaluate_norm_at_time`(self, time)	Evaluate for a given time.
`from_dict`(data)
`sample_time`(self, n_events, t_min, t_max[, …])	Sample arrival times of events.
`to_dict`(self)	Create dict for YAML serialisation

Attributes Documentation

default_parameters = <gammapy.modeling.parameter.Parameters object>¶

norm¶

A model parameter.

Note that the parameter value has been split into a factor and scale like this:

value = factor x scale

Users should interact with the value, quantity or min and max properties and consider the fact that there is a factor` and scale an implementation detail.

That was introduced for numerical stability in parameter and error estimation methods, only in the Gammapy optimiser interface do we interact with the factor, factor_min and factor_max properties, i.e. the optimiser “sees” the well-scaled problem.

Parameters

namestr: Name
factorfloat or Quantity: Factor
scalefloat, optional: Scale (sometimes used in fitting)
unitUnit or str, optional: Unit
minfloat, optional: Minimum (sometimes used in fitting)
maxfloat, optional: Maximum (sometimes used in fitting)
frozenbool, optional: Frozen? (used in fitting)

parameters¶: Parameters (Parameters)

tag = 'ConstantTemporalModel'¶

Methods Documentation

copy(self)¶: A deep copy.

static create(tag, *args, **kwargs)¶

Create a model instance.

Examples

>>> from gammapy.modeling import Model
>>> spectral_model = Model.create("PowerLaw2SpectralModel", amplitude="1e-10 cm-2 s-1", index=3)
>>> type(spectral_model)
gammapy.modeling.models.spectral.PowerLaw2SpectralModel

evaluate_norm_at_time(self, time)[source]¶

Evaluate for a given time.

Parameters

timearray_like: Time since the reference time.

Returns

normfloat: Mean norm

classmethod from_dict(data)¶

sample_time(self, n_events, t_min, t_max, random_state=0)[source]¶

Sample arrival times of events.

Parameters

n_eventsint: Number of events to sample.
t_minTime: Start time of the sampling.
t_maxTime: Stop time of the sampling.
random_state{int, ‘random-seed’, ‘global-rng’, RandomState}: Defines random number generator initialisation. Passed to get_random_state.

Returns

timeQuantity: Array with times of the sampled events.

to_dict(self)¶: Create dict for YAML serialisation