"""Weights (tapering) for the driving function."""
# from scipy import signal
import numpy as np
[docs]def none(active):
"""No tapering window."""
return np.asarray(active, dtype=np.float64)
[docs]def kaiser(active):
"""Kaiser tapering window."""
idx = _windowidx(active)
# compute coefficients
window = np.zeros(active.shape)
window[idx] = np.kaiser(len(idx), 2)
return window
[docs]def tukey(active, alpha):
"""Tukey tapering window."""
idx = _windowidx(active)
# alpha out of limits
if alpha <= 0 or alpha >= 1:
return none(active)
# design Tukey window
x = np.linspace(0, 1, len(idx)+2)
w = np.ones(x.shape)
first_condition = x < alpha/2
w[first_condition] = 0.5 * (1 + np.cos(2*np.pi/alpha *
(x[first_condition] - alpha/2)))
third_condition = x >= (1 - alpha/2)
w[third_condition] = 0.5 * (1 + np.cos(2*np.pi/alpha *
(x[third_condition] - 1 + alpha/2)))
# fit window into tapering function
window = np.zeros(active.shape)
window[idx] = w[1:-1]
return window
def _windowidx(active):
"""Returns list of connected indices for window function."""
active = np.asarray(active, dtype=np.float64)
# find index were active loudspeakers begin (works for connected contours)
if (active[0] == 1 and active[-1] == 0) or np.all(active):
a0 = 0
else:
a0 = np.argmax(np.diff(active)) + 1
# shift generic index vector to get a connected list of indices
idx = np.roll(np.arange(len(active)), -a0)
# remove indices of inactive secondary sources
idx = idx[0:len(np.squeeze(np.where(active == 1)))]
return idx