ericteunis/m-thesis-introduction
1
0
Fork 0
mirror of https://gitlab.science.ru.nl/mthesis-edeboone/m-thesis-introduction.git synced 2024-11-13 10:03:32 +01:00
Code Issues Projects Releases Packages Wiki Activity
m-thesis-introduction/fourier/01_fourier.ipynb

878 lines
874 KiB
Text
Raw Normal View History

WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
{
"cells": [
{
"cell_type": "markdown",
"metadata": {},
"source": [
"# Fourier Transforms"
]
},
{
"cell_type": "code",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"execution_count": 2,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
"outputs": [],
"source": [
"%matplotlib inline\n",
"\n",
"import numpy as np\n",
"import scipy.fft as ft\n",
"import matplotlib.pyplot as plt\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"import matplotlib.gridspec as gridspec\n",
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"import matplotlib.ticker as tck\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"rng = np.random.default_rng()"
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"The Fourier transform (FT) of a quantity $f(t)$ is defined as\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
"$$\n",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"\\hat{f}(\\omega) = F(f(t)) = \\frac{1}{\\sqrt{2\\pi}} \\int_{-\\infty}^{\\infty} \\mathrm{d}t\\, f(t)\\, \\exp{ \\left(-2 \\pi i f t \\right)}\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
".\n",
"$$\n",
"\n",
"In signal processing, taking the integral from $t = -\\infty$ to $t = \\infty$ is not practical. Together with a finite sample space $t$, the integral can be turned into a (discrete) sum, giving a Discrete Fourier Transform (DFT)\n",
"\n",
"$$\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"F(t) = \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N-1} f(t_k)\\, \\exp{ \\left(-i \\omega t_k \\right)}\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\\label{eq:DFT} \\tag{1}\n",
",\n",
"$$\n",
"where the sum iterates over each sample $t_k$ up to the end ($k=N-1$) of the signal."
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"# Interdependence $\\Delta t$, $T$, $\\Delta f$, $f_{min}$, $f_{max}$"
]
},
{
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"cell_type": "markdown",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"source": [
"The highest frequency $f_\\mathrm{max}$ (also known as the Nyquist frequency) that can be (reliably) measured within a signal is dependent only on the sampling rate ($1/\\Delta t$) of the signal with\n",
"$$\n",
" f_\\mathrm{max} = \\frac{1}{2} f_\\mathrm{sampling} = \\frac{1}{2} \\frac{1}{\\Delta t}\n",
" .\n",
"$$\n",
Fixup: always put a ylabel
2021-11-30 15:35:09 +01:00
"Higher frequencies will fall in between two adjacent samples. This means that these frequencies are then 'measured\\` with differing phases in such a way that they are 'folded' around the Nyquist frequency and appear as aliased frequencies below it.\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"\n",
"Likewise, the lowest frequency depends on the length of the signal $T$, such that over the whole signal one oscillation can be found\n",
"$$\n",
" f_\\mathrm{min} \\sim \\frac{1}{T}\n",
" .\n",
"$$\n",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"Even lower frequencies will no longer be detected as a frequency. Instead, they will introduce a bias for the $0 Hz$ component in the spectrum.\n",
"\n",
"\n",
"$$\n",
"\\delta f = \\frac{1}{T}\n",
"$$"
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
]
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"# FTs of ideal signals"
]
},
{
"cell_type": "code",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"execution_count": 3,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
"outputs": [],
"source": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"def ft_spectrum( signal, sample_rate, fft=None, freq=None, mask_bias=False):\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \"\"\"Return a FT of $signal$, with corresponding frequencies\"\"\"\n",
" n_samples = len(signal)\n",
Fixup: always put a ylabel
2021-11-30 15:35:09 +01:00
" real_signal = np.isrealobj(signal)\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" if fft is None:\n",
" if real_signal:\n",
" fft = ft.rfft\n",
" freq = ft.rfftfreq\n",
" else:\n",
" fft = ft.fft\n",
" freq = ft.fftfreq\n",
"\n",
" if freq is None:\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" freq = ft.fftfreq\n",
" \n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" spectrum = fft(signal) / sample_rate\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" freqs = freq(n_samples, 1/sample_rate)\n",
" \n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" if not mask_bias:\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" return spectrum, freqs\n",
" else:\n",
" return spectrum[1:], freqs[1:]\n",
"\n",
" \n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"def plot_spectrum( ax, spectrum, freqs, plot_complex=False, plot_power=False, plot_amplitude=None):\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \"\"\" Plot a signal's spectrum on an Axis object\"\"\"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" plot_amplitude = plot_amplitude or (not plot_power and not plot_complex)\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" alpha = 1\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" \n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" ax.set_title(\"Spectrum\")\n",
" ax.set_xlabel(\"f (Hz)\")\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" ylabel = \"\"\n",
Fixup: always put a ylabel
2021-11-30 15:35:09 +01:00
" if plot_amplitude or plot_complex:\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" ylabel = \"Amplitude\"\n",
" if plot_power:\n",
" if ylabel:\n",
" ylabel += \"|\"\n",
" ylabel += \"Power\"\n",
" ax.set_ylabel(ylabel)\n",
"\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" if plot_complex:\n",
" alpha = 0.5\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" ax.plot(freqs, np.real(spectrum), '.-', label='Real', alpha=alpha)\n",
" ax.plot(freqs, np.imag(spectrum), '.-', label='Imag', alpha=alpha)\n",
"\n",
" if plot_power:\n",
" ax.plot(freqs, np.abs(spectrum)**2, '.-', label='Power', alpha=alpha)\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" \n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" if plot_amplitude:\n",
" ax.plot(freqs, np.abs(spectrum), '.-', label='Abs', alpha=alpha)\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"\n",
Fixup: always put a ylabel
2021-11-30 15:35:09 +01:00
" ax.legend()\n",
"\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" return ax\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"\n",
"\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"def plot_phase( ax, spectrum, freqs, ylim_epsilon=0.5):\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" ax.set_ylabel(\"Phase\")\n",
" ax.set_xlabel(\"f (Hz)\")\n",
"\n",
" ax.plot(freqs, np.angle(spectrum), '.-')\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
" ax.set_ylim(-1*np.pi - ylim_epsilon, np.pi + ylim_epsilon)\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" return ax\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"\n",
"def plot_combined_spectrum(spectrum, freqs, \n",
" spectrum_kwargs={}, fig=None, gs=None):\n",
" \"\"\"Plot both the frequencies and phase in one figure.\"\"\"\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" # configure plotting layout\n",
" if fig is None:\n",
" fig = plt.figure(figsize=(8, 16))\n",
"\n",
" if gs is None:\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
" gs = gridspec.GridSpec(2, 1, figure=fig, height_ratios=[3,1], hspace=0)\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"\n",
" ax1 = fig.add_subplot(gs[:-1, -1])\n",
" ax2 = fig.add_subplot(gs[-1, -1], sharex=ax1)\n",
"\n",
" axes = np.array([ax1, ax2])\n",
" \n",
" # plot the spectrum \n",
" plot_spectrum(ax1, spectrum, freqs, **spectrum_kwargs)\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" # plot the phase\n",
" plot_phase(ax2, spectrum, freqs)\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"\n",
" ax1.xaxis.tick_top()\n",
" [label.set_visible(False) for label in ax1.get_xticklabels()]\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" \n",
" return fig, axes\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \n",
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"def plot_signal( ax, signal, sample_rate = 1):\n",
" ax.set_title(\"Signal\")\n",
" ax.set_xlabel(\"t (s)\")\n",
" ax.set_ylabel(\"A(t)\")\n",
"\n",
" ax.plot(np.arange(len(signal)) / sample_rate, signal)\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" return ax\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"\n",
"def plot_signal_and_spectrum( signal, sample_rate, title=None,\n",
" ft_kwargs = {}, spectrum_kwargs = {}):\n",
" \"\"\"Plot a signal and its spectrum in one go.\"\"\"\n",
" fig = plt.figure(figsize=(16, 4))\n",
" \n",
" if title:\n",
" fig.suptitle(title)\n",
"\n",
" # setup plot layout\n",
" gs0 = gridspec.GridSpec(1, 2, figure=fig)\n",
" gs00 = gs0[0].subgridspec(1, 1)\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
" gs01 = gs0[1].subgridspec(2, 1, height_ratios=[3,1], hspace=0)\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
" \n",
" # plot the signal\n",
" ax1 = fig.add_subplot(gs00[0, 0])\n",
" plot_signal(ax1, signal)\n",
" \n",
" # plot spectrum\n",
" signal_fft, freqs = ft_spectrum(signal, sample_rate, **ft_kwargs)\n",
" _, (ax2, ax3) = plot_combined_spectrum(signal_fft, freqs, spectrum_kwargs = spectrum_kwargs, fig=fig, gs=gs01)\n",
"\n",
" # return the axes\n",
" axes = np.array([ax1, ax2, ax3])\n",
" \n",
" return (fig, axes)"
]
},
{
"cell_type": "code",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"execution_count": 4,
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"metadata": {},
"outputs": [],
"source": [
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"sample_rate = 1/1e-3 # s\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"n_samples = int(1e3)\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"t = np.arange(n_samples) / sample_rate"
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"### FTs: constant signal\n",
"\n",
"A constant signal (also termed offset or bias) results in only a single component in the Fourier transform, at the zero frequency.\n",
"\n",
"Since often such a component is included in a signal (for example when a signal is not on average zero), it can help to mask out the zero frequency when plotting the spectrum.\n",
"Doing this for a constant signal, we get a totally flat spectrum."
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
{
"cell_type": "code",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"execution_count": 4,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
"outputs": [
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
},
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"signal_constant = np.ones(int(n_samples))\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"fig, axes = plot_signal_and_spectrum(signal_constant, sample_rate, \"Constant signal\")\n",
"axes.flat[1].set_xlim(0,10);\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"fig, axes = plot_signal_and_spectrum(signal_constant, sample_rate, \"Constant signal (masked zero)\", ft_kwargs={'mask_bias':True})\n",
"axes.flat[1].set_xlim(0,10);\n"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"### FTs: noise (normal distributed)\n",
"\n",
"A FT of normal distributed noise will not have easily identifiable peaks in the spectrum.\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"Instead, the spectrum is on average a bit flat, with only low power in any individual peak."
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
]
},
{
"cell_type": "code",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"execution_count": 5,
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"metadata": {},
"outputs": [
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
"signal_normal_noise = rng.normal(size=n_samples)\n",
"\n",
"plot_signal_and_spectrum(signal_normal_noise, sample_rate, \"Noise (normal distributed)\");"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"### FTs: sine wave"
]
},
{
"cell_type": "code",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"execution_count": 6,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
"outputs": [
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"text/plain": [
"(95.0, 105.0)"
]
},
"execution_count": 6,
"metadata": {},
"output_type": "execute_result"
},
{
"data": {
"image/png": "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
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"f = 1e2 # Hz\n",
"if f > sample_rate/2:\n",
" print(\"Sampling a frequency above the sample_rate/2 gives problems\")\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"signal_sine = np.sin( 2*np.pi*f*t )\n",
Fixup: always put a ylabel
2021-11-30 15:35:09 +01:00
"\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"if False:\n",
" # aliased peak\n",
Fixup: always put a ylabel
2021-11-30 15:35:09 +01:00
" f_alias = (1.1* sample_rate/2)\n",
" signal_sine += 1/2*np.sin( 2*np.pi* f_alias *t)\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"fig, axes = plot_signal_and_spectrum(signal_sine, sample_rate, \"Single frequency at $f = {:g}$MHz\".format(f/10**6))\n",
"axes.flat[1].axvline(sample_rate/2, color='r', label='Nyquist Frequency');\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"axes.flat[1].legend();\n",
"axes.flat[1].set_xlim(f-5, f+5)"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"A sine wave will give very clear peaks at the frequency of the sine wave."
]
},
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
{
"cell_type": "code",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"execution_count": 7,
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"metadata": {},
"outputs": [
{
"data": {
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"image/png": "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
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"text/plain": [
"<Figure size 1152x576 with 2 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"with_spectrum = True\n",
"phase_offsets = np.linspace(0, 2*np.pi, 8, endpoint=False) # rad\n",
"f = 99 # Hz\n",
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"\n",
"if f > sample_rate/2:\n",
" print(\"Sampling a frequency above the sample_rate/2 gives problems\")\n",
"\n",
"if with_spectrum:\n",
" fig, axes = plt.subplots(2,1, sharex=True, figsize=(16,8))\n",
"else:\n",
" fig, ax = plt.subplots(figsize=(16,4))\n",
" axes = np.array([None, ax])\n",
" \n",
"if with_spectrum:\n",
" axes[0].set_ylabel(\"Amplitude\")\n",
" axes[0].axvline(f, alpha=0.3, label='f = {:g}Hz'.format(f))\n",
"\n",
"axes[1].axvline(f, alpha=0.3, label='f = {:g}Hz'.format(f))\n",
"axes[1].set_ylabel(\"Phase\")\n",
"axes[1].set_xlabel(\"f\")\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"axes[1].set_xlim( f-2, f+2)\n",
"axes[1].set_ylim( -1 - 0.2, 1+ 0.2)\n",
"axes[1].grid()\n",
"axes[1].yaxis.set_major_formatter(tck.FormatStrFormatter('%g $\\pi$'))\n",
"axes[1].yaxis.set_major_locator(tck.MultipleLocator(base=0.5))\n",
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"for phase in phase_offsets:\n",
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
" signal = np.sin( 2*np.pi*f*t + phase )\n",
" \n",
" ft_signal, freqs = ft_spectrum(signal, sample_rate)\n",
" \n",
" if with_spectrum:\n",
" axes[0].plot(freqs, np.real(ft_signal), '.-', label='Re $\\\\varphi = {}\\\\pi$'.format(phase/np.pi))\n",
" \n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
" axes[1].plot(freqs, np.angle(ft_signal)/np.pi, '.-', label='$\\\\varphi = {}\\\\pi$'.format(phase/np.pi))\n",
"\n",
"# trigger legends\n",
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"if with_spectrum:\n",
" axes[0].legend(loc='center right');\n",
"axes[1].legend(loc='center right');\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"\n",
Show angles vs phase offset for sine waves
2021-11-30 17:14:50 +01:00
"plt.show()"
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"For a sine wave, the phase of the spectrum at it's frequency is $\\theta( \\varphi = 0 ) = - \\dfrac{\\pi}{2}$."
]
},
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
{
"cell_type": "markdown",
"metadata": {},
"source": [
"### FTs: step function"
]
},
{
"cell_type": "code",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"execution_count": 8,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
"outputs": [
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
},
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"t_0 = t[n_samples//4]\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"signal_step = np.heaviside(t - t_0, 1)\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"fig, axes = plot_signal_and_spectrum(signal_step, sample_rate, \"Step function $t_0 = {:g}ns$\".format(t_0 * 10**9), ft_kwargs={'mask_bias':True});\n",
"axes.flat[1].set_xlim(0, 20);\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
"t_0 = t[n_samples//2]\n",
"signal_step = np.heaviside(t - t_0, 1)\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"fig, axes = plot_signal_and_spectrum(signal_step, sample_rate, \"Step function $t_0 = {:g}ns$\".format(t_0 * 10**9), ft_kwargs={'mask_bias':True});\n",
"axes.flat[1].set_xlim(0, 20);"
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
Fourier: Delta peaks at different times in the signal
2021-11-30 17:38:49 +01:00
"### FTs: delta peak\n",
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"\n",
Fourier: Delta peaks at different times in the signal
2021-11-30 17:38:49 +01:00
"All frequencies are accounted for with the same amplitude, but the phase will change depending on the position of the delta peak within the signal.\n",
"\n",
"Still, the individual phases are linearly related to their corresponding frequencies."
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
]
},
{
"cell_type": "code",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"execution_count": 10,
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"metadata": {},
"outputs": [
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
{
"data": {
"image/png": "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
"text/plain": [
"<Figure size 1152x288 with 3 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
},
{
"data": {
"image/png": "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
"text/plain": [
"<Figure size 1152x288 with 3 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
},
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "iVBORw0KGgoAAAANSUhEUgAAA7sAAAEjCAYAAADzMBbxAAAABHNCSVQICAgIfAhkiAAAAAlwSFlzAAALEgAACxIB0t1+/AAAADh0RVh0U29mdHdhcmUAbWF0cGxvdGxpYiB2ZXJzaW9uMy4xLjMsIGh0dHA6Ly9tYXRwbG90bGliLm9yZy+AADFEAAAgAElEQVR4nOy9e5ykW1nf+33qfulbVffM9G26p2Hf2OARyQajCYpgIqCISTTZoDH4wXAkmsREYyDxJMQjR/RoSIySHBGFiApoPAkm4CUiUQS37C0o7g0b9p6a6st0z/RUVd/qfln5Y73VU9NT3V2XVd3VPc/386lPd72X9a71vG9VrWet33oeMcagKIqiKIqiKIqiKOcJ32lXQFEURVEURVEURVFco86uoiiKoiiKoiiKcu5QZ1dRFEVRFEVRFEU5d6izqyiKoiiKoiiKopw71NlVFEVRFEVRFEVRzh3q7CqKoiiKoiiKoijnDnV2FUVRFEVRFEVRlHOHOruKoiiKoiiKoijKuUOdXUVRlHsMEbkmIl/vqKwHReQzIrIrIv/IRZldXPtJEXnZSV5zGDjt++fy+qfNeWqLoiiKcjfq7CqKopwxvA560XNQtkTkkyLyPSLS9Xe6g87+DwEfN8aMGmN+uo9yjqRdPY0xzzfGfHxQ1+ymLgf2f5+IPC4iZRF57yHHzIrI6oFt94tISUTe3+m1HHDk/VNnUFEURTnLqLOrKIpyNnmNMWYUWATeAfxz4D2nUI9F4MlTuO4wcx34UeAXjjjm1cBvHdj2s8CnB1WpQ9D7pyiKopxb1NlVFEU5wxhjto0xHwb+DvD3ROQFsD9z+F9EZFNEUu0kqiLyS8AC8JsisiciP+Rtf4uIPOvNHD8lIn+j3bVF5GPA1wE/453/gLfdiMh9Lce9V0R+1Pv/moj8oIj8uYhsi8gHRSTScuxlEfkNr94ZEfmZI+q5P+soIs8TkY97M91Pisg3H6jrkdc9cOyh7T+sLgfuyW8YY/4rkGlXvsergY+0lPsosAX8XofXemGHbTnULofdv36u38lz11L+PxeRNc/OT4vIK1r2HXUPronIP/OunxeR94jIJRH5qHf8/xSRxIHj3+qVkxORXzzCXh3XX1EURRl+1NlVFEU5Bxhj/gRYBV4qVs78m8CfAXPAK4DvF5FvOHDO3wWWsbPEI8aYn/B2PQu8FBgH/g3wfhGZaXPNlwN/CHyfd/4XO6zu3wZeCSwB/wfwBgAR8QP/HUgDV7y6f+CIeuKdF/Ta+zvAReAfAr8sIg92ct02HNr+4+rSCV59vwb4Xe/9GPAjwA+0HnfMtY5ty3F2Oe7+dXv9Tp87r24PAt8HvNhTKHwDcK3lkOOewb8F/DXgAeA1wEeBfwFMYfs2B53Ub/eu8VzvnB9uU6eO668oiqKcDdTZVRRFOT9cB5LAi4ELxpgfMcZUjDFXgXcDj3ZSiDHm14wx140xDWPMB4EvAS9xWM+f9srPYp2LF3rbXwLMAv/MGJM3xpSMMZ/ooLy/DIwA7/Da+zGs0/y6Dq97ByfQ/q8B/swYs+u9/7+B9xhjVrooo5O2dGqXXmh3/W6euzoQBh4WkaAx5pox5tnmzg7uwX8wxtwwxqxhHfbHjDGfMcaUgf8f+IoD1/sZY8yKV9+3H2KDvj43iqIoyvAROO0KKIqiKM6YA7LYdZizIrLVss+PdQqORUS+E/in2NlVsA7TlLtqstHyfwHr4AJcBtLGmFqX5c0CK8aYRsu2NNYenVz3Dk6g/fsSZhF5IfD13O2cHUcnbenULr3Q7vodP3fGmGdE5PuBtwHPF5HfBv6pMeY6dHQPbrT8X2zzfuTAJVsHEtK0t1dfnxtFURRl+FBnV1EU5RwgIi/GOjGfwHb0U8aY+zs41RwoZxE7m/UK4FPGmLqIfBaQLqpTAGIt76exEuvjWAEWRCTQxuE17U7wuA5cFhFfi2O3AHQqq96nw/YfVZdOeDXQXIP6MqxDtywiYO+dX0QeNsa8qM9rubBLN9dfofPnDmPMrwC/4sm4/z/gx4G/6+gZPMjllv8XsLbpq/6KoijK8KMyZkVRlDOMiIyJyDcBHwDeb4z5HPAnwI4XACgqIn4ReYHnEB/kBvCclvdxrIOz6ZX/XcALuqzWZ4HXe9d9JfC1HZ73J8A68A4RiYtIRET+yiH1bOUxIA/8kIgExebefQ3WJt3SSfuPqgsiEvACIPmxjmtERALeviUgbIz5gnf4z2HXkb7Qe/0n4H9g15cee61jcGGXbq7f8XMnNr/vy0UkDJSws7F1b7eLZ/Ag3ysi8yKSxK7t/WA/9VcURVHOBursKoqinE1+U0R2sbNR/xL4t8B3ARhj6lin5oVACrgF/Dw22M9Bfgz4YbHRen/QGPMU8FPAp7COzpcBf9Rl3f6xd/0tbGCg/9rJSS31vg8bGGkVG2X6rnoeOK8CfDPwKmxb3wV8Z4tD2TEdtv/Qunj8MNZ5ewvwHd7/zYBI30hLFGZjTMEYs9F8AXtAyRiz2eG1jmqLC7t0fP0un7swNmXWLawk+iLWCe30HnTLr2ADdV31Xj/aZ/0VRVGUM4AY068aS1EURVGUThCRj2CDJX3k2IMVJ4jINeC7jTH/87TroiiKopwsOrOrKGcIEfl2EfmdE7jOy0SkkzWWiqJ0x8eB3z/tSiiKoijKvYA6u4oyhIjIXxWRT4rItohkReSPROTFxphfNsb89dOun6IovWGM+QljTPG066Eoym0O+80d4PWuicjXD6p8RVFuo9GYFWXI8CKT/nfgzcCHgBDwUqB8mvVSFEU5ixhjrpx2HZThZRh/cw+JSK8oSg/ozK6iDB8PABhjftUYUzfGFI0xv2OM+XMReYOIfKJ5oIj8dRF52huNfpeI/C8R+W5v3xtE5BMi8pMikhORlIi8quXc7xKRz4vIrohcFZH/8+SbqiiKoiinynG/uX8kIv/B+539goi8onmiiIyLyHtEZF1E1kTkR0XE37L/77f8zj4lIi8SkV/Cpr/6TRHZE5EfEpErImJE5I0isgx8rN1yotYZYRF5m4j8moi83yv/cyLygIi8VURuisiKiKgSTLnnUWdXUYaPLwJ1EXmfiLxKRBLtDhKRKeDXgbcCk8DTwFcfOOwrve1TwE8A7xGRZq7Km8A3AWPYKL7vFJEXuW6MoiiKogwxx/3mfiU2gvcU8K+B3/BSWAG8D6hhI8h/BfDXgeaA87cBbwO+E/s7+81Axhjzd7HR5l9jjBkxxvxEy7W+Fnget1OPHcdrgF8CEsBngN/G9u3ngB/B5q9WlHsadXYVZcgwxuwAfxWbZ/LdwKaIfFhELh049NXAk8aY3/DkTj+NTeHRStoY824vpcb7gBngkned/2GMedZY/hc2LcdLB9cyRVEURRkuOvjNvQn8O2NM1RjzQewA8jd6+18FfL8xJm+MuQm8E3jUO++7gZ8wxnza+519xhiTPqY6b/PK6nRd/x8aY37b6wP8GnABeIcxporNp31FRCY6LEtRziXq7CrKEGKM+bwx5g3GmHngBcAs8O8OHDaLzbHaPMdg85K2stGyv+D9OwLgjWD/sReMYwvrPE+5bYmiKIqiDDfH/OaumTvzdKa9/YtAEFj38lBvYWdSL3rHXQae7bIqK8cfcgc3Wv4vAre8we3me/B+8xXlXkWdXUUZcowxXwDei/0BbmUdmG++8eTJ83SAiISB/wL8JHDJGDMBfASQI09UFEVRlHNMm9/cuZblP2DX217HOqZlYMoYM+G9xowxz/eOWwGee9hlOtieB2LNN95a4AvdtEVRFHV2FWXoEJGHROQHRGTee38ZeB3wxwcO/R/Al4nIt4hIAPheYLrDy4SAMLAJ1LzAVRrIQlEURbmn6OA39yLwj0Qk6K3DfR7wEWPMOnb5z0+JyJiI+ETkuSLytd55Pw/8oIj8JbHcJyKL3r4bwHOOqdoXgYiIfKOIBIEfxv5uK4rSBersKsrwsYsNiPGYiOSxP7h/AfxA60HGmFvAt2EDT2WAh4HH6SBdgjFmF/hH2DQLOeD1wIfdNUFRFEVRzgTH/eY+Btw
Fourier: Delta peaks at different times in the signal
2021-11-30 17:38:49 +01:00
"text/plain": [
"<Figure size 1152x288 with 3 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
},
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
Fourier: Delta peaks at different times in the signal
2021-11-30 17:38:49 +01:00
"text/plain": [
"<Figure size 1152x288 with 3 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
},
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"text/plain": [
"<Figure size 1152x288 with 3 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
"\n",
FourierPhase: better plot for frequency and time domain phase relationship This is somewhat dependent on the frequency and the sample_rate
2021-12-09 20:24:59 +01:00
"for n in [1, -1, 4, 2, -4]:\n",
" index_t0 = min(n_samples//n, n_samples-1)\n",
Fourier: Delta peaks at different times in the signal
2021-11-30 17:38:49 +01:00
"\n",
" t_0 = t[index_t0]\n",
" signal_step = np.zeros(n_samples)\n",
" signal_step[index_t0] = 1\n",
"\n",
" fig, axes = plot_signal_and_spectrum(signal_step, sample_rate, ft_kwargs={'mask_bias':True}, spectrum_kwargs={'plot_complex':True, 'plot_amplitude':True});\n",
" fig.suptitle(\"Delta function at ${}/{}$th of the sample\".format(np.sign(n), np.abs(n)))\n",
" axes.flat[1].set_xlim(0, 20);"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
Add Gaussian Sine signal to Fourier notebook
2022-01-13 11:00:14 +01:00
{
"cell_type": "markdown",
"metadata": {},
"source": [
"## FTs: gaussian with sine"
]
},
{
"cell_type": "code",
"execution_count": 9,
"metadata": {},
"outputs": [
{
"data": {
"image/png": "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
"text/plain": [
"<Figure size 1152x288 with 3 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
"f = 1e1 # Hz\n",
"if f > sample_rate/2:\n",
" print(\"Sampling a frequency above the sample_rate/2 gives problems\")\n",
"\n",
"def gaussian(x, mu=0, sigma=1 ):\n",
" return 1/(sigma*np.sqrt(2*np.pi)) * np.exp(- (x-mu)**2 / sigma**2 )\n",
"\n",
"def dgaussian(x, mu=0, sigma=1, dmu=1, dsigma=0):\n",
" return gaussian(x, mu, sigma) + gaussian(x, mu+dmu, sigma+dsigma)\n",
"\n",
"if not True:\n",
" signal = gaussian(t, t[2*len(t)//5], 100/len(t)) - gaussian(t, t[3*len(t)//5], 100/len(t))\n",
"else:\n",
" signal = gaussian(t, t[2*len(t)//5], 100/len(t)) * np.sin(2*np.pi*f*t)\n",
"\n",
"fig, axes = plot_signal_and_spectrum(signal, sample_rate, \"Gaussian pulse\", spectrum_kwargs={'plot_complex':True, 'plot_amplitude':True})\n",
"axes.flat[1].axvline(sample_rate/2, color='r', label='Nyquist Frequency')\n",
"axes.flat[2].axvline(sample_rate/2, color='r')\n",
"axes.flat[1].legend();\n",
"\n",
"if not True:\n",
" axes.flat[1].set_xlim(0, 20);\n",
"else:\n",
" axes.flat[1].set_xlim(max(0, f - max(f/5, 10)), f + max(f/5, 10));\n",
" "
]
},
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
{
"cell_type": "markdown",
"metadata": {},
"source": [
"#### FTs: delta peak: group velocity"
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"In the above plots, the phases follow"
]
},
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
{
"cell_type": "markdown",
"metadata": {},
"source": [
"# Peculiarities $F^{-1}( F(A(t)) ) \\sim A(t)$"
]
},
{
"cell_type": "code",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"execution_count": 10,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"outputs": [
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"text/plain": [
"<Figure size 1152x288 with 2 Axes>"
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
"t_0 = t[n_samples//4]\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"signal_step = np.heaviside(t - t_0, 1) + 1\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"\n",
"signal_fft = ft.rfft(signal_step) / sample_rate\n",
"signal_ifft = ft.irfft(signal_fft, len(signal_fft))\n",
"ft_freqs = ft.rfftfreq(n_samples, 1/sample_rate)\n",
"\n",
"\n",
"alpha = 0.8\n",
"fig, (ax1, ax2) = plt.subplots(1,2, figsize=(16,4))\n",
"ax1.set_title(\"Spectrum\")\n",
"ax1.set_xlabel(\"f (Hz)\")\n",
"ax1.set_ylabel(\"Amplitude\")\n",
"ax1.set_xlim(-1,20)\n",
"ax1.plot(ft_freqs, np.real(signal_fft), '.-', label='Real', alpha=alpha)\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"ax1.plot(ft_freqs, np.imag(signal_fft), '.--', label='Imag', alpha=alpha)\n",
"ax1.plot(ft_freqs, np.abs(signal_fft), '.-', label='Abs', alpha=alpha)\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"ax1.legend()\n",
"\n",
"# Signal and Inversed FFT\n",
"ax2.set_title(\"Signal and Inversed FFT\")\n",
"ax2.set_xlabel(\"t (s)\")\n",
"ax2.set_ylabel(\"A(t)\")\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"ax2.plot(np.arange(len(signal_ifft)) / sample_rate * 2, np.abs(signal_ifft)*sample_rate/2, label=\"Inversed FFT\")\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"ax2.plot(np.arange(len(signal_step)) / sample_rate, signal_step, label=\"Original\")\n",
"ax2.legend()\n",
"\n",
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"if False:\n",
" ax2.set_xlim(t_0*(1-0.2), t_0*(1+0.2))\n",
"\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"plt.show();\n"
]
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"# DFT\n",
"\n",
"A naive implementation of a DFT is simple to setup by implementing Eq. (1)\n",
"\n",
"$$\n",
"\\hat{f}(\\omega) = F(t) = \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N-1} f(t_k)\\, \\exp{ \\left(-i \\omega t_k \\right)}\n",
".\n",
"$$"
]
},
{
"cell_type": "code",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"execution_count": 11,
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"metadata": {},
"outputs": [],
"source": [
"def naive_DFT( signal ):\n",
" \"\"\"\n",
" Calculate DFT in a naive way, returns a complex DFT.\n",
" \"\"\"\n",
"\n",
" N = np.size(signal)\n",
"\n",
" x_k = 2*np.pi/N*np.arange(N)\n",
" ft = np.zeros(N, dtype=np.complex128)\n",
" for j in range(N):\n",
" ft[j] = np.dot(signal, np.exp(- 1j * j * x_k ))\n",
"\n",
" return ft"
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
"### DFT: Cooley and Tukey (or Divide and Conquer)"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
},
{
"cell_type": "markdown",
"metadata": {},
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"A smarter DFT (Cooley and Tukey) can be implemented by splitting the sum in Eq. (1) into two parts: $k$ even and $k$ odd.\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"With a uniform sample space $t$, the label $t_k$ can be rewritten to $t_k = k \\Delta t = $.\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
"This gives\n",
"$$\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"F(t) = \n",
" \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N/2-1} f(t_{2k})\\, \\exp{ \\left(-i \\omega \\, t_{2k} \\right)}\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" +\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N/2-1} f(t_{2k+1})\\, \\exp{ \\left(-i \\omega \\, t_{2k+1} \\right)}\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \\\\\n",
" =\n",
" \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N/2-1} f(t_{2k})\\, \\exp{ \\left(-i \\omega \\, 2k \\Delta t \\right)}\n",
" +\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N/2-1} f(t_{2k+1})\\, \\exp{ \\left(-i \\omega \\, 2k \\Delta t \\right)}\\exp{ \\left(-i \\omega \\, \\Delta t \\right)}\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" \\\\\n",
" =\n",
" \\frac{1}{\\sqrt{2\\pi}} \\sum_{k=0}^{N/2-1} f(t_{2k})\\, \\exp{ \\left(-i \\omega \\, 2k \\Delta t \\right)}\n",
" +\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" \\frac{\\exp{ \\left(-i \\omega \\, \\Delta t \\right)} }{\\sqrt{2\\pi}} \\sum_{k=0}^{N/2-1} f(t_{2k+1})\\, \\exp{ \\left(-i \\omega \\, 2k \\Delta t \\right)}\n",
" \\\\\n",
" =\n",
" F(t_{even}) + F(t_{odd}) \\exp{ \\left(-i \\omega \\, \\Delta t \\right)}\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"$$"
]
},
{
"cell_type": "code",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"execution_count": 12,
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"metadata": {},
"outputs": [],
"source": [
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"def cooley_tukey_DFT( signal ):\n",
" \"\"\"\n",
" Calculate a DFT according to the Cooley and Tukey algorithm (radix-2)\n",
" also known as Divide and Conquer.\n",
" \n",
" It divides the terms into 2 streams with odd and even index.\n",
" \"\"\"\n",
" radix = 2\n",
"\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
" N = np.size(signal)\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" \n",
" if N <= radix:\n",
" return naive_DFT(signal)\n",
" \n",
" if N % radix > 0:\n",
" raise ValueError(\"Provide a signal with N%{radix} == 0 values.\".format(radix=radix))\n",
" \n",
" # divide and conquer\n",
" DFT_even = cooley_tukey_DFT(signal[::radix])\n",
" DFT_odd = cooley_tukey_DFT(signal[1::radix])\n",
" \n",
" phase_terms = np.exp( -2j * np.pi * np.arange(0, N) / N )\n",
" \n",
" return np.tile(DFT_even, 2) + np.tile(DFT_odd,2) * phase_terms\n"
]
},
{
"cell_type": "code",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"execution_count": 13,
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"metadata": {
"scrolled": true
},
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"outputs": [
{
"data": {
Fourier: fixed inverse FFT
2021-12-07 10:47:39 +01:00
"image/png": "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
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"text/plain": [
Always show the phase below an amplitude plot
2021-11-30 15:06:04 +01:00
"<Figure size 1152x288 with 3 Axes>"
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
]
},
"metadata": {
"needs_background": "light"
},
"output_type": "display_data"
}
],
"source": [
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"dft_sample_rate = 1/1e-3 # s\n",
"dft_n_samples = 2**10\n",
"dft_t = np.arange(dft_n_samples) / dft_sample_rate\n",
"\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
"f = 1e2 # Hz\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"if f > dft_sample_rate/2:\n",
Fourier: working DFT and CooleyTukey
2021-11-25 18:49:42 +01:00
" print(\"Sampling a frequency above the sample_rate/2 gives problems\")\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"signal_sine = np.sin( 2*np.pi*f*dft_t )\n",
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
"\n",
WUOD: mostly work on sines and their phases
2021-11-30 18:03:17 +01:00
"fig, axes = plot_signal_and_spectrum(signal_sine, dft_sample_rate, \"Single frequency at $f = {:g}$MHz\".format(f/10**6), ft_kwargs={'fft': cooley_tukey_DFT})\n",
"axes.flat[1].axvline(dft_sample_rate/2, color='r', label='Nyquist Frequency');"
WIP: Fourier Transforms Still missing: - (split) DFT - ifft(fft(signal)) - interdependence t, f
2021-11-23 15:22:20 +01:00
]
}
],
"metadata": {
"kernelspec": {
"display_name": "Python 3",
"language": "python",
"name": "python3"
},
"language_info": {
"codemirror_mode": {
"name": "ipython",
"version": 3
},
"file_extension": ".py",
"mimetype": "text/x-python",
"name": "python",
"nbconvert_exporter": "python",
"pygments_lexer": "ipython3",
"version": "3.7.6"
}
},
"nbformat": 4,
"nbformat_minor": 4
}
Reference in a new issue Copy permalink