import numpy as np
from pylops import LinearOperator
[docs]class CausalIntegration(LinearOperator):
r"""Causal integration.
Apply causal integration to a multi-dimensional array along ``dir`` axis.
Parameters
----------
N : :obj:`int`
Number of samples in model.
dims : :obj:`list`, optional
Number of samples for each dimension
(``None`` if only one dimension is available)
dir : :obj:`int`, optional
Direction along which smoothing is applied.
sampling : :obj:`float`, optional
Sampling step ``dx``.
halfcurrent : :obj:`bool`, optional
Add half of current value (``True``) or the entire value (``False``).
This will be *deprecated* in v2.0.0, use instead `kind=half` to obtain
the same behaviour.
dtype : :obj:`str`, optional
Type of elements in input array.
kind : :obj:`str`, optional
Integration kind (``full``, ``half``, or ``trapezoidal``).
removefirst : :obj:`bool`, optional
Remove first sample (``True``) or not (``False``).
Attributes
----------
shape : :obj:`tuple`
Operator shape
explicit : :obj:`bool`
Operator contains a matrix that can be solved explicitly (``True``)
or not (``False``)
Notes
-----
The CausalIntegration operator applies a causal integration to any chosen
direction of a multi-dimensional array.
For simplicity, given a one dimensional array, the causal integration is:
.. math::
y(t) = \int x(t) dt
which can be discretised as :
.. math::
y[i] = \sum_{j=0}^i x[j] dt
or
.. math::
y[i] = (\sum_{j=0}^{i-1} x[j] + 0.5x[i]) dt
or
.. math::
y[i] = (\sum_{j=1}^{i-1} x[j] + 0.5x[0] + 0.5x[i]) dt
where :math:`dt` is the ``sampling`` interval. In our implementation, the
choice to add :math:`x[i]` or :math:`0.5x[i]` is made by selecting ``kind=full``
or ``kind=half``, respectively. The choice to add :math:`0.5x[i]` and
:math:`0.5x[0]` instead of made by selecting the ``kind=trapezoidal``.
Note that the integral of a signal has no unique solution, as any constant
:math:`c` can be added to :math:`y`, for example if :math:`x(t)=t^2` the
resulting integration is:
.. math::
y(t) = \int t^2 dt = \frac{t^3}{3} + c
If we apply a first derivative to :math:`y` we in fact obtain:
.. math::
x(t) = \frac{dy}{dt} = t^2
no matter the choice of :math:`c`.
"""
def __init__(self, N, dims=None, dir=-1, sampling=1,
halfcurrent=True, dtype='float64',
kind='full', removefirst=False):
self.N = N
self.dir = dir
self.sampling = sampling
self.kind = kind
if kind == 'full' and halfcurrent: # ensure backcompatibility
self.kind = 'half'
self.removefirst = removefirst
# define samples to remove from output
rf = 0
if removefirst:
rf = 1 if dims is None else self.N // dims[self.dir]
if dims is None:
self.dims = [self.N, 1]
self.dimsd = [self.N - rf, 1]
self.reshape = False
else:
if np.prod(dims) != self.N:
raise ValueError('product of dims must equal N!')
else:
self.dims = dims
self.dimsd = list(dims)
if self.removefirst:
self.dimsd[self.dir] -= 1
self.reshape = True
self.shape = (self.N-rf, self.N)
self.dtype = np.dtype(dtype)
self.explicit = False
def _matvec(self, x):
if self.reshape:
x = np.reshape(x, self.dims)
if self.dir != -1:
x = np.swapaxes(x, self.dir, -1)
y = self.sampling * np.cumsum(x, axis=-1)
if self.kind in ('half', 'trapezoidal'):
y -= self.sampling * x / 2.
if self.kind == 'trapezoidal':
y[..., 1:] -= self.sampling * x[..., 0:1] / 2.
if self.removefirst:
y = y[..., 1:]
if self.dir != -1:
y = np.swapaxes(y, -1, self.dir)
return y.ravel()
def _rmatvec(self, x):
if self.reshape:
x = np.reshape(x, self.dimsd)
if self.removefirst:
x = np.insert(x, 0, 0, axis=self.dir)
if self.dir != -1:
x = np.swapaxes(x, self.dir, -1)
xflip = np.flip(x, axis=-1)
if self.kind == 'half':
y = self.sampling * (np.cumsum(xflip, axis=-1) - xflip / 2.)
elif self.kind == 'trapezoidal':
y = self.sampling * (np.cumsum(xflip, axis=-1) - xflip / 2.)
y[..., -1] = self.sampling * np.sum(xflip, axis=-1) / 2.
else:
y = self.sampling * np.cumsum(xflip, axis=-1)
y = np.flip(y, axis=-1)
if self.dir != -1:
y = np.swapaxes(y, -1, self.dir)
return y.ravel()