Week2: Finished Exercise 1 - requires rewrite
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week2/ex1.py
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week2/ex1.py
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#!/usr/bin/env python3
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import numpy as np
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# Example Functions
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def func1(x):
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return np.exp(20j * x) + np.exp(40j * x )
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def func2(x):
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return np.exp( 5j * x**2 )
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####################
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# Fourier Transforms
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####################
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def DFT(yk):
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N = np.size(yk)
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xk = 2*np.pi/N*np.arange(N)
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# beta = np.zeros(N, dtype=np.complex128)
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beta = np.zeros(N, dtype=np.float64)
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for j in range(N):
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beta[j] = np.dot(yk, np.exp(- 1j * j * xk ))
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return beta
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def FFT(yk):
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N = np.size(yk)
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if ( N%2 > 0 ):
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raise ValueError("The data set does not consist of 2^M values:", N)
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if N <= 2:
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return DFT(yk)
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else:
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beta_even = FFT(yk[::2])
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beta_odd = FFT(yk[1::2])
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exp_terms = np.exp( -2j * np.pi * np.arange(0,N) / N )
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beta_even_full = np.concatenate([beta_even, beta_even])
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beta_odd_full = np.concatenate([beta_odd, beta_odd])
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return beta_even_full + exp_terms * beta_odd_full
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# Plotting functions
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def plot_DFTs(N = 128, fft1 = DFT, fft2 = np.fft.fft, funcs=[func1,func2]):
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from matplotlib import pyplot
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j = np.arange(N)
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xk = 2*np.pi/N * np.arange(N)
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pyplot.subplot()
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pyplot.title("Discrete Fourier Transform")
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pyplot.xlabel("j")
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pyplot.ylabel("|$\\beta_j$|")
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# First Function
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for i, dataf in enumerate(datafuncs):
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pyplot.plot(j, np.abs(fft1(func1(xk))), label="{} {}".format(fft1.__name__, dataf.__name__), linewidth=3)
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pyplot.plot(j, np.abs(fft2(func1(xk))), '--', label="{} {}".format(fft1.__name__, dataf.__name__))
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pyplot.legend()
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pyplot.show()
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def time_FT_func(func, yk, *args, **kwargs):
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import timeit
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tOut = timeit.repeat(stmt=lambda: func(yk), *args, **kwargs)
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return np.mean(tOut)
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def plot_FT_func_timing(func = DFT, M_max = 4, repeat = 10, number = 5, show = True):
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from matplotlib import pyplot
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M = np.arange(1,M_max)
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Ns = 2**M
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times = np.zeros(M_max-1)
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for i in range(np.size(times)):
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xk = 2*np.pi/Ns[i] * np.arange(Ns[i])
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yk = func1(xk)
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times[i] = time_FT_func(func, yk, repeat=repeat,number=number)
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pyplot.subplot()
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pyplot.title("Evaluation Time for {}*{} DFTs for each N ".format(repeat, number))
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pyplot.ylabel("Time (sec)")
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pyplot.xlabel("$N^2$")
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pyplot.ticklabel_format(scilimits=(0,0))
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pyplot.plot(Ns**2, times, "o:", label=func.__name__)
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pyplot.legend()
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if show:
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pyplot.show()
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if __name__ == "__main__":
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plot_DFTs(fft1=DFT,fft2=FFT)
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plot_FT_func_timing(M_max = 9, func=FFT, show = False) # 12 takes 10 seconds, 13 takes 50 seconds
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plot_FT_func_timing(M_max = 9, func=DFT) # 12 takes 10 seconds, 13 takes 50 seconds
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week2/week2.pdf
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week2/week2.pdf
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