xrscipy.fft.ifft
- xrscipy.fft.ifft(a, coord, n=None, norm=None)
Compute the 1-D inverse discrete Fourier Transform.
This function computes the inverse of the 1-D n-point discrete Fourier transform computed by fft. In other words,
ifft(fft(x)) == x
to within numerical accuracy.The input should be ordered in the same way as is returned by fft, i.e.,
x[0]
should contain the zero frequency term,x[1:n//2]
should contain the positive-frequency terms,x[n//2 + 1:]
should contain the negative-frequency terms, in increasing order starting from the most negative frequency.
For an even number of input points,
x[n//2]
represents the sum of the values at the positive and negative Nyquist frequencies, as the two are aliased together. See fft for details.- Parameters:
a (xarray object) – The data to transform.
n (int, optional) – Length of the transformed axis of the output. If n is smaller than the length of the input, the input is cropped. If it is larger, the input is padded with zeros. If n is not given, the length of the input along the axis specified by axis is used. See notes about padding issues.
coord (string) – The axis along which the transform is applied. The coordinate must be evenly spaced.
norm ({"backward", "ortho", "forward"}, optional) – Normalization mode (see fft). Default is “backward”.
- Returns:
out – The truncated or zero-padded input, transformed along the axis indicated by axis, or the last one if axis is not specified.
- Return type:
complex ndarray
- Raises:
IndexError – If axes is larger than the last axis of x.
See also
fft
The 1-D (forward) FFT, of which ifft is the inverse.
ifft2
The 2-D inverse FFT.
ifftn
The N-D inverse FFT.
scipy.fft.ifft
scipy.fft.ifft : Original scipy implementation
Notes
If the input parameter n is larger than the size of the input, the input is padded by appending zeros at the end. Even though this is the common approach, it might lead to surprising results. If a different padding is desired, it must be performed before calling ifft.
If
x
is a 1-D array, then the ifft is equivalent toy[k] = np.sum(x * np.exp(2j * np.pi * k * np.arange(n)/n)) / len(x)
As with fft, ifft has support for all floating point types and is optimized for real input.
Examples
>>> import scipy.fft >>> import numpy as np >>> scipy.fft.ifft([0, 4, 0, 0]) array([ 1.+0.j, 0.+1.j, -1.+0.j, 0.-1.j]) # may vary
Create and plot a band-limited signal with random phases:
Examples
>>> import matplotlib.pyplot as plt >>> rng = np.random.default_rng() >>> t = np.arange(400) >>> n = np.zeros((400,), dtype=complex) >>> n[40:60] = np.exp(1j*rng.uniform(0, 2*np.pi, (20,))) >>> s = scipy.fft.ifft(n) >>> plt.plot(t, s.real, 'b-', t, s.imag, 'r--') [<matplotlib.lines.Line2D object at ...>, <matplotlib.lines.Line2D object at ...>]
Examples
>>> plt.legend(('real', 'imaginary')) <matplotlib.legend.Legend object at ...>
Examples
>>> plt.show()