# Licensed under a 3-clause BSD style license - see LICENSE.rst
"""Helper functions to work with distributions."""
import numbers
import numpy as np
import scipy.integrate
from astropy.coordinates import Angle
from astropy.time import TimeDelta
__all__ = [
"get_random_state",
"sample_sphere",
"sample_sphere_distance",
"sample_powerlaw",
"sample_times",
"normalize",
"draw",
"pdf",
]
[docs]def normalize(func, x_min, x_max):
"""Normalize a 1D function over a given range."""
def f(x):
return func(x) / scipy.integrate.quad(func, x_min, x_max)[0]
return f
[docs]def pdf(func):
"""One-dimensional PDF of a given radial surface density."""
def f(x):
return x * func(x)
return f
[docs]def draw(low, high, size, dist, random_state="random-seed", *args, **kwargs):
"""Allows drawing of random numbers from any distribution."""
from .inverse_cdf import InverseCDFSampler
n = 1000
x = np.linspace(low, high, n)
pdf = dist(x)
sampler = InverseCDFSampler(pdf=pdf, random_state=random_state)
idx = sampler.sample(size)
x_sampled = np.interp(idx, np.arange(n), x)
return np.squeeze(x_sampled)
[docs]def get_random_state(init):
"""Get a `numpy.random.RandomState` instance.
The purpose of this utility function is to have a flexible way
to initialise a `~numpy.random.RandomState` instance,
a.k.a. a random number generator (``rng``).
See :ref:`dev_random` for usage examples and further information.
Parameters
----------
init : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`}
Available options to initialise the RandomState object:
* ``int`` -- new RandomState instance seeded with this integer
(calls `~numpy.random.RandomState` with ``seed=init``)
* ``'random-seed'`` -- new RandomState instance seeded in a random way
(calls `~numpy.random.RandomState` with ``seed=None``)
* ``'global-rng'``, return the RandomState singleton used by ``numpy.random``.
* `~numpy.random.RandomState` -- do nothing, return the input.
Returns
-------
random_state : `~numpy.random.RandomState`
RandomState instance.
"""
if isinstance(init, (numbers.Integral, np.integer)):
return np.random.RandomState(init)
elif init == "random-seed":
return np.random.RandomState(None)
elif init == "global-rng":
return np.random.mtrand._rand
elif isinstance(init, np.random.RandomState):
return init
else:
raise ValueError(
"{} cannot be used to seed a numpy.random.RandomState"
" instance".format(init)
)
[docs]def sample_sphere(size, lon_range=None, lat_range=None, random_state="random-seed"):
"""Sample random points on the sphere.
Reference: http://mathworld.wolfram.com/SpherePointPicking.html
Parameters
----------
size : int
Number of samples to generate
lon_range : `~astropy.coordinates.Angle`, optional
Longitude range (min, max)
lat_range : `~astropy.coordinates.Angle`, optional
Latitude range (min, max)
random_state : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`}
Defines random number generator initialisation.
Passed to `~gammapy.utils.random.get_random_state`.
Returns
-------
lon, lat: `~astropy.coordinates.Angle`
Longitude and latitude coordinate arrays
"""
random_state = get_random_state(random_state)
if lon_range is None:
lon_range = Angle([0.0, 360.0], "deg")
if lat_range is None:
lat_range = Angle([-90.0, 90.0], "deg")
# Sample random longitude
u = random_state.uniform(size=size)
lon = lon_range[0] + (lon_range[1] - lon_range[0]) * u
# Sample random latitude
v = random_state.uniform(size=size)
z_range = np.sin(lat_range)
z = z_range[0] + (z_range[1] - z_range[0]) * v
lat = np.arcsin(z)
return lon, lat
[docs]def sample_sphere_distance(
distance_min=0, distance_max=1, size=None, random_state="random-seed"
):
"""Sample random distances if the 3-dim space density is constant.
This function uses inverse transform sampling
(`Wikipedia <http://en.wikipedia.org/wiki/Inverse_transform_sampling>`__)
to generate random distances for an observer located in a 3-dim
space with constant source density in the range ``(distance_min, distance_max)``.
Parameters
----------
distance_min, distance_max : float, optional
Distance range in which to sample
size : int or tuple of ints, optional
Output shape. Default: one sample. Passed to `numpy.random.uniform`.
random_state : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`}
Defines random number generator initialisation.
Passed to `~gammapy.utils.random.get_random_state`.
Returns
-------
distance : array
Array of samples
"""
random_state = get_random_state(random_state)
# Since the differential distribution is dP / dr ~ r ^ 2,
# we have a cumulative distribution
# P(r) = a * r ^ 3 + b
# with P(r_min) = 0 and P(r_max) = 1 implying
# a = 1 / (r_max ^ 3 - r_min ^ 3)
# b = -a * r_min ** 3
a = 1.0 / (distance_max ** 3 - distance_min ** 3)
b = -a * distance_min ** 3
# Now for inverse transform sampling we need to use the inverse of
# u = a * r ^ 3 + b
# which is
# r = [(u - b)/ a] ^ (1 / 3)
u = random_state.uniform(size=size)
distance = ((u - b) / a) ** (1.0 / 3)
return distance
[docs]def sample_powerlaw(x_min, x_max, gamma, size=None, random_state="random-seed"):
"""Sample random values from a power law distribution.
f(x) = x ** (-gamma) in the range x_min to x_max
It is assumed that *gamma* is the **differential** spectral index.
Reference: http://mathworld.wolfram.com/RandomNumber.html
Parameters
----------
x_min : float
x range minimum
x_max : float
x range maximum
gamma : float
Power law index
size : int, optional
Number of samples to generate
random_state : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`}
Defines random number generator initialisation.
Passed to `~gammapy.utils.random.get_random_state`.
Returns
-------
x : array
Array of samples from the distribution
"""
random_state = get_random_state(random_state)
size = int(size)
exp = -gamma
base = random_state.uniform(x_min ** exp, x_max ** exp, size)
x = base ** (1 / exp)
return x
[docs]def sample_times(
size,
rate,
dead_time=TimeDelta(0, format="sec"),
return_diff=False,
random_state="random-seed",
):
"""Make random times assuming a Poisson process.
This function can be used to test event time series,
to have a comparison what completely random data looks like.
Can be used in two ways (in either case the return type is `~astropy.time.TimeDelta`):
* ``return_delta=False`` - Return absolute times, relative to zero (default)
* ``return_delta=True`` - Return time differences between consecutive events.
Parameters
----------
size : int
Number of samples
rate : `~astropy.units.Quantity`
Event rate (dimension: 1 / TIME)
dead_time : `~astropy.units.Quantity` or `~astropy.time.TimeDelta`, optional
Dead time after event (dimension: TIME)
return_diff : bool
Return time difference between events? (default: no, return absolute times)
random_state : {int, 'random-seed', 'global-rng', `~numpy.random.RandomState`}
Defines random number generator initialisation.
Passed to `~gammapy.utils.random.get_random_state`.
Returns
-------
time : `~astropy.time.TimeDelta`
Time differences (second) after time zero.
Examples
--------
Example how to simulate 100 events at a rate of 10 Hz.
As expected the last event occurs after about 10 seconds.
>>> from astropy.units import Quantity
>>> from gammapy.time import random_times
>>> rate = Quantity(10, 'Hz')
>>> times = random_times(size=100, rate=rate, random_state=0)
>>> times[-1]
<TimeDelta object: scale='None' format='sec' value=9.186484131475076>
"""
random_state = get_random_state(random_state)
dead_time = TimeDelta(dead_time)
scale = (1 / rate).to("s").value
time_delta = random_state.exponential(scale=scale, size=size)
time_delta += dead_time.to("s").value
if return_diff:
return TimeDelta(time_delta, format="sec")
else:
time = time_delta.cumsum()
return TimeDelta(time, format="sec")