def dcst2(f): """ Takes DCT along x, then DST along y IN: f, the input 2D numpy array OUT: b, the 2D transformed array """ M = f.shape[0] # Number of rows N = f.shape[1] # Number of columns a = np.zeros((M, N)) # Intermediate array b = np.zeros((M, N)) # Final array # Take transform along x for j in range(N): a[:, j] = dct(f[:, j]) # Take transform along y for i in range(M): b[i, :] = dst(a[i, :]) return b
ft_inverse_2 = np.fft.irfft(fk_dow2) #PLOTTING THE DATA FILE AS WELL AS THE FOURIER TRANSFORM WHERE LAST 90% OF COEFFICIENTS IS SET TO ZERO plt.xlabel('Time') plt.ylabel(r'$f(t)$') plt.title('DFT::Original data and last "98%" freq set to zero') plt.plot(t_dow2,y_dow2,'b', label = 'original data') plt.plot(t_dow2,ft_inverse_2,'r', label = 'Higher freq set to zero') plt.legend(fontsize = 'x-small') plt.savefig('dow2_dft.png',bbox_inches = 'tight') plt.show() plt.clf() #DCT fk_dct_dow2 = dct(y_dow2) #SETTING THE LAST 98 % OF THE FOURIER COEFFIECIENTS TO ZERO for i in range(len(freq_dow2)): if i > (0.02 * len(freq_dow2)): fk_dct_dow2[i] = 0 ft_dct_inverse_2 = idct(fk_dct_dow2) #PLOTTING THE DATA FILE AS WELL AS THE FOURIER TRANSFORM WHERE LAST 90% OF COEFFICIENTS IS SET TO ZERO plt.xlabel('Time') plt.ylabel(r'$f(t)$') plt.title('DCT::Original data and last "98%" freq set to zero') plt.plot(t_dow2,y_dow2,'b', label = 'original data') plt.plot(t_dow2,ft_dct_inverse_2,'r', label = 'Higher freq set to zero')
N=len(c) for i in range(N//50,N): c[i]=0 y = np.fft.irfft(c) plt.grid(True, which="both") plt.plot(price,color='blue',label='Original data') plt.plot(y,color='red',label='2% fourier coefficients with FFT') plt.title('Dow Jones Industrial Average (2% fourier coefficients with FFT)') plt.gca().legend() plt.savefig('dow_fft_2percent.png') plt.show() dct = dcst.dct(price) N=len(price) for i in range(N//50,N): dct[i]=0 y = dcst.idct(dct) plt.grid(True, which="both") plt.plot(price,color='blue',label='Original data') plt.plot(y,color='red',label='2% fourier coefficients with DCT') plt.title('Dow Jones Industrial Average (2% fourier coefficients with DCT)') plt.gca().legend() plt.savefig('dow_dct_2percent.png') plt.show()
y = np.loadtxt("dow2.txt") plt.figure(1, figsize=(10, 4)) plt.plot(y, label='raw DJIA') plt.grid() plt.xlabel('Time (days)') plt.ylabel('DJIA index') plt.autoscale(enable=True, axis='x', tight=True) fy = np.fft.rfft(y) N_coeffs = len(fy) fy_lopass = 1 * fy fy_lopass[int(0.02 * N_coeffs):] = 0. y_lopass = np.fft.irfft(fy_lopass) plt.plot(y_lopass, '--', label='low-pass filtered') # Q1cb -----------------------------------------------------------------------| cty = dcst.dct(y) cty_lopass = 1 * cty cty_lopass[int(0.02 * N_coeffs):] = 0. y_lopass_ct = dcst.idct(cty_lopass) plt.plot(y_lopass_ct, ':', label='low-pass filtered, CT') plt.legend() plt.tight_layout() plt.savefig('dow-nonperiodic.png', dpi=150) # plt.show()
#plot both the original and filtered data plt.figure(0) plt.plot(days, dow, label='Original') plt.plot(days, dow_filtered, label='Filtered (DFT)') plt.legend(loc='upper left') plt.title('DOW closing value raw and filtered') plt.xlabel('Business days since start of the data stream') plt.ylabel('DOW closing value (in points)') plt.savefig('../images/1c_dft.png') #------------------------------------------------------------------- #part b #compute dct a = dct(dow) #calculate the number of values of a to keep non-zero keep_length_2 = round(keep_frac*len(a)) #create a new array from c with only the first designated fraction #non-zero a_new = np.zeros(len(a), dtype=complex) a_new[:keep_length_2] = a[:keep_length_2] #compute inverse fourier transform of filtered c values dow_filtered_2 = idct(a_new) #plot both the original and filtered data plt.figure(2) plt.plot(days, dow, label='Original')
# plotting function of time plt.figure(figsize=(10,5)) plt.plot(dow2, label='Original', alpha=0.7) plt.plot(dow2_filtered, label='Filtered, 2 \%' ) plt.legend() plt.xlabel("Time (days)") plt.ylabel("Price") plt.title("Daily closing values of the Dow Jones Index from 2004 to 2008") plt.savefig("Lab05_Q1ci") # we repeat the process but with the discrete cosine routine in dcst.py c_dow2_cos = dcst.dct(dow2) N = len(c_dow2_cos) c_dow2_cos[int(N* 0.02):] = 0 dow2_cosfiltered = dcst.idct(c_dow2_cos) plt.figure(figsize=(10,5)) plt.plot(dow2, label='Original', alpha=0.7) plt.plot(dow2_cosfiltered, label='Filtered DCT, 2 \%' ) plt.legend() plt.xlabel("Time (days)") plt.ylabel("Price") plt.title("Daily closing values of the Dow Jones Index from 2004 to 2008") plt.savefig("Lab05_Q1cii")
import matplotlib.pyplot as plt from dcst import dct, idct ############################################################################### # This program finds the discrete cosine transform of a set of data, then discards # all but the first 2% of coefficients to approximate the data ################################## LOAD DATA ################################## dow = np.loadtxt('dow2.txt') ################################## MAIN PROGRAM ################################## # Do discrete cosine transform cks = dct(dow) # Choose a percentage of coefficients to discard and find corresponding index percent_discard = 0.02 # 2% ind = int(percent_discard * len(cks)) # Create new coefficient array cks_new = np.concatenate((cks[:ind], np.zeros(len(cks) - ind))) # Find inverse Fourier transform to determine approximation dow_new = idct(cks_new) ################################## PLOT ################################## plt.title('Dow Jones Industrial Average') plt.xlabel('Day (relative to start day)')
import matplotlib.pyplot as plt from dcst import dct,idct ############################################################################### # This program finds the discrete cosine transform of a set of data, then discards # all but the first 2% of coefficients to approximate the data ################################## LOAD DATA ################################## dow = np.loadtxt('dow2.txt') ################################## MAIN PROGRAM ################################## # Do discrete cosine transform cks = dct(dow) # Choose a percentage of coefficients to discard and find corresponding index percent_discard = 0.02 # 2% ind = int(percent_discard*len(cks)) # Create new coefficient array cks_new = np.concatenate((cks[:ind],np.zeros(len(cks)-ind))) # Find inverse Fourier transform to determine approximation dow_new = idct(cks_new) ################################## PLOT ################################## plt.title('Dow Jones Industrial Average') plt.xlabel('Day (relative to start day)')