Made code to compile and probably work with 32-bits floating point. This requires quite some testing to be done
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@ -21,7 +21,7 @@ elseif(${RPI})
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set(DEFAULT_RTAUDIO OFF)
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set(DEFAULT_PORTAUDIO ON)
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set(DEFAULT_ULDAQ OFF)
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set(DEFAULT_DOUBLE_PRECISION OFF)
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else()
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set(DEFAULT_RTAUDIO OFF)
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set(DEFAULT_PORTAUDIO ON)
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@ -11,7 +11,7 @@ using std::cerr;
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using std::endl;
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// Safe some typing. Linspace form 0 up to (and NOT including N).
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#define lin0N arma::linspace(0, N - 1, N)
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#define lin0N arma::linspace<vd>(0, N - 1, N)
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vd Window::hann(const us N) {
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return arma::pow(arma::sin((arma::datum::pi/N) * lin0N), 2);
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@ -24,8 +24,8 @@ vd Window::blackman(const us N) {
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d a0 = 7938. / 18608.;
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d a1 = 9240. / 18608.;
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d a2 = 1430. / 18608.;
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return a0 - a1 * d_cos((2 * number_pi/N) * lin0N) +
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a2 * d_cos((4 * number_pi / N)* lin0N );
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return a0 - a1 * arma::cos((2 * number_pi/N) * lin0N) +
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a2 * arma::cos((4 * number_pi / N)* lin0N );
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}
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vd Window::rectangular(const us N) { return arma::ones(N); }
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@ -44,6 +44,12 @@ void init_siggen(py::module &m);
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PYBIND11_MODULE(lasp_cpp, m) {
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#if LASP_DOUBLE_PRECISION == 1
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m.attr("LASP_DOUBLE_PRECISION") = true;
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#else
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m.attr("LASP_DOUBLE_PRECISION") = false;
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#endif
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init_dsp(m);
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init_deviceinfo(m);
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init_daqconfiguration(m);
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@ -51,6 +57,5 @@ PYBIND11_MODULE(lasp_cpp, m) {
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init_streammgr(m);
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init_datahandler(m);
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init_siggen(m);
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}
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/** @} */
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@ -12,6 +12,7 @@ __all__ = ['freqResponse', 'bandpass_fir_design', 'lowpass_fir_design',
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import numpy as np
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from scipy.signal import freqz, hann, firwin2
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from ..lasp_config import empty
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def freqResponse(fs, freq, coefs_b, coefs_a=1.):
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@ -44,7 +45,7 @@ def bandpass_fir_design(L, fs, fl, fu, window=hann):
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Omg2 = 2*np.pi*fu/fs
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Omg1 = 2*np.pi*fl/fs
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fir = np.empty(L, dtype=float)
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fir = empty(L, dtype=float)
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# First Create ideal band-pass filter
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fir[L//2] = (Omg2-Omg1)/np.pi
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@ -64,7 +65,7 @@ def lowpass_fir_design(L, fs, fc, window=hann):
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" than upper cut-off"
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Omgc = 2*np.pi*fc/fs
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fir = np.empty(L, dtype=float)
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fir = empty(L, dtype=float)
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# First Create ideal band-pass filter
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fir[L//2] = Omgc/np.pi
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@ -6,8 +6,14 @@ Author: J.A. de Jong - ASCEE
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Description: LASP configuration
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"""
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import numpy as np
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from .lasp_cpp import LASP_DOUBLE_PRECISION
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if LASP_DOUBLE_PRECISION:
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LASP_NUMPY_FLOAT_TYPE = np.float64
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LASP_NUMPY_COMPLEX_TYPE = np.float128
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else:
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LASP_NUMPY_FLOAT_TYPE = np.float32
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LASP_NUMPY_COMPLEX_TYPE = np.float64
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def zeros(shape):
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@ -64,6 +64,7 @@ from .lasp_version import LASP_VERSION_MAJOR, LASP_VERSION_MINOR
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from .lasp_cpp import Window, DaqChannel, AvPowerSpectra
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from typing import List
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from functools import lru_cache
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from .lasp_config import ones
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# Measurement file extension
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MEXT = 'h5'
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@ -223,7 +224,7 @@ class IterData(IterRawData):
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def __init__(self, fa, channels, sensitivity, **kwargs):
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super().__init__(fa, channels, **kwargs)
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self.sens = np.asarray(sensitivity)[self.channels]
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self.sens = np.asarray(sensitivity, dtype=LASP_NUMPY_FLOAT_TYPE)[self.channels]
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assert self.sens.ndim == 1
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def __next__(self):
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@ -329,10 +330,10 @@ class Measurement:
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try:
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sens = f.attrs["sensitivity"]
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self._sens = (
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sens * np.ones(self.nchannels) if isinstance(sens, float) else sens
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sens * ones(self.nchannels) if isinstance(sens, float) else sens
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)
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except KeyError:
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self._sens = np.ones(self.nchannels)
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self._sens = ones(self.nchannels)
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# The time is cached AND ALWAYS ASSUMED TO BE AN IMMUTABLE OBJECT.
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# It is also cached. Changing the measurement timestamp should not
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@ -885,7 +886,7 @@ class Measurement:
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"""
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if isinstance(sens, float):
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# Put all sensitivities equal
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sens = sens * np.ones(self.nchannels)
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sens = sens * ones(self.nchannels)
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elif isinstance(sens, list):
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sens = np.asarray(sens)
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@ -1199,7 +1200,7 @@ class Measurement:
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nchannels = 1
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nframes = len(data)
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data = data[:, np.newaxis]
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sensitivity = np.ones(nchannels)
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sensitivity = ones(nchannels)
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with h5.File(newfn, "w") as hf:
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hf.attrs["samplerate"] = samplerate
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@ -77,6 +77,7 @@ class FirFilterBank:
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self.fs = fs
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self.xs = list(range(xmin, xmax + 1))
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raise RuntimeError('Not working code anymore')
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maxdecimation = self.designer.firDecimation(self.xs[0])
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self.decimators = []
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@ -245,7 +246,7 @@ class SosFilterBank:
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for i, x in enumerate(self.xs):
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channel = self.designer.createSOSFilter(x)
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if sos is None:
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sos = np.empty((channel.size, len(self.xs)))
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sos = empty((channel.size, len(self.xs)))
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sos[:, i] = channel.flatten()
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self._fb = BiquadBank(sos)
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@ -6,6 +6,7 @@ Description:
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Reverberation time estimation tool using least squares
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"""
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from .lasp_common import getTime
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from .lasp_config import ones
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import numpy as np
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@ -56,7 +57,7 @@ class ReverbTime:
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x = self._t[istart:istop][:, np.newaxis]
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# Solve the least-squares problem, by creating a matrix of
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A = np.hstack([x, np.ones(x.shape)])
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A = np.hstack([x, ones(x.shape)])
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# print(A.shape)
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# print(points.shape)
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@ -5,6 +5,7 @@ Sound level meter implementation
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@author: J.A. de Jong - ASCEE
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"""
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from .lasp_cpp import cppSLM
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from .lasp_config import empty
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import numpy as np
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from .lasp_common import (TimeWeighting, FreqWeighting, P_REF)
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from .filter import SPLFilterDesigner
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@ -101,7 +102,7 @@ class SLM:
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assert fbdesigner.fs == fs
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sos_firstx = fbdesigner.createSOSFilter(self.xs[0]).flatten()
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self.nom_txt.append(fbdesigner.nominal_txt(self.xs[0]))
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sos = np.empty((sos_firstx.size, nfilters), dtype=float, order='C')
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sos = empty((sos_firstx.size, nfilters), dtype=float, order='C')
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sos[:, 0] = sos_firstx
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for i, x in enumerate(self.xs[1:]):
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@ -47,7 +47,7 @@ class WeighCal:
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P = 2048 # Filter length (number of taps)
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self._firs = np.empty((P, self.nchannels))
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self._firs = empty((P, self.nchannels))
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self._fbs = []
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for chan in range(self.nchannels):
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fir = arbitrary_fir_design(fs, P, freq_design,
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@ -21,6 +21,7 @@ import copy
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import numpy as np
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from numpy import log2, pi, sin
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from ..lasp_cpp import freqSmooth
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from ..lasp_config import zeros
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@unique
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@ -31,7 +31,7 @@ def test_backward_fft():
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nfft = 2048
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freq = getFreq(nfft, nfft)
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# Sig = np.zeros(nfft//2+1, dtype=complex)
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# Sig = zeros(nfft//2+1, dtype=complex)
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Sigr = np.random.randn(nfft//2+1)
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Sigi = np.random.randn(nfft//2+1)
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