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Akvo/akvo/tressel/harmonic.py

harmonic.py 8.1KB
文件历史 原始文件

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  1. import numpy as np 

  2. from scipy.optimize import least_squares 

  3. from scipy.optimize import minimize

  4. from scipy.linalg import lstsq as sclstsq

  5. import scipy.linalg as lin

  6. 

  7. def harmonic2 ( f1, f2, sN, fs, nK, t ): 

  8.     """

  9.     Performs inverse calculation of two harmonics contaminating a signal. 

  10.     Args:

  11.         f01 = base frequency of the first sinusoidal noise 

  12.         f02 = base frequency of the second sinusoidal noise 

  13.         sN = signal containing noise 

  14.         fs = sampling frequency

  15.         nK = number of harmonics to calculate 

  16.         t = time samples 

  17.     """

  18.     print("building matrix 2")

  19.     A = np.zeros( (len(t),  4*nK) )

  20.     #f1 = f1MHz * 1e-3

  21.     #f2 = f2MHz * 1e-3

  22.     for irow, tt in enumerate(t): 

  23.         A[irow, 0:2*nK:2]  = np.cos( np.arange(nK)*2*np.pi*(f1/fs)*irow )

  24.         A[irow, 1:2*nK:2]  = np.sin( np.arange(nK)*2*np.pi*(f1/fs)*irow )

  25.         A[irow, 2*nK::2]   = np.cos( np.arange(nK)*2*np.pi*(f2/fs)*irow )

  26.         A[irow, 2*nK+1::2] = np.sin( np.arange(nK)*2*np.pi*(f2/fs)*irow )

  27. 

  28.     v = np.linalg.lstsq(A, sN, rcond=1e-8)

  29.     #v = sclstsq(A, sN) #, rcond=1e-6)

  30. 

  31.     alpha = v[0][0:2*nK:2] + 1e-16

  32.     beta  = v[0][1:2*nK:2] + 1e-16

  33.     amp = np.sqrt( alpha**2 + beta**2 )

  34.     phase = np.arctan(- beta/alpha)

  35.     

  36.     alpha2 = v[0][2*nK::2]   + 1e-16

  37.     beta2  = v[0][2*nK+1::2] + 1e-16

  38.     amp2 = np.sqrt( alpha2**2 + beta2**2 )

  39.     phase2 = np.arctan(- beta2/alpha2)

  40. 

  41.     h = np.zeros(len(t))

  42.     for ik in range(nK):

  43.         h += np.sqrt( alpha[ik]**2 + beta[ik]**2)  * np.cos( 2.*np.pi*ik * (f1/fs) * np.arange(0, len(t), 1 )  + phase[ik] ) \

  44.            + np.sqrt(alpha2[ik]**2 + beta2[ik]**2) * np.cos( 2.*np.pi*ik * (f2/fs) * np.arange(0, len(t), 1 )  + phase2[ik] )

  45. 

  46.     return sN-h

  47. 

  48. def harmonic ( f0, sN, fs, nK, t ): 

  49.     """

  50.     Performs inverse calculation of harmonics contaminating a signal. 

  51.     Args:

  52.         f0 = base frequency of the sinusoidal noise 

  53.         sN = signal containing noise 

  54.         fs = sampling frequency

  55.         nK = number of harmonics to calculate 

  56.         t = time samples 

  57.     """

  58.     print("building matrix ")

  59.     A = np.zeros( (len(t),  2*nK) )

  60.     for irow, tt in enumerate(t): 

  61.         A[irow, 0::2] = np.cos( np.arange(nK)*2*np.pi*(f0/fs)*irow )

  62.         A[irow, 1::2] = np.sin( np.arange(nK)*2*np.pi*(f0/fs)*irow )

  63. 

  64.     v = np.linalg.lstsq(A, sN, rcond=1e-16) # rcond=None) #, rcond=1e-8)

  65.     #v = sclstsq(A, sN) #, rcond=1e-6)

  66.     alpha = v[0][0::2]

  67.     beta  = v[0][1::2]

  68.     

  69.     #print("Solving A A.T")

  70.     #v = lin.solve(np.dot(A,A.T).T, sN) #, rcond=1e-6)

  71.     #v = np.dot(A.T, v)

  72.     #v = np.dot(np.linalg.inv(np.dot(A.T, A)), np.dot(A.T, sN))

  73.     #alpha = v[0::2]

  74.     #beta  = v[1::2]

  75. 

  76.     amp = np.sqrt( alpha**2 + beta**2 )

  77.     phase = np.arctan(- beta/alpha)

  78. 

  79.     #print("amp:", amp, " phase", phase)

  80. 

  81.     h = np.zeros(len(t))

  82.     for ik in range(nK):

  83.         h += np.sqrt(alpha[ik]**2 + beta[ik]**2) * np.cos( 2.*np.pi*ik * (f0/fs) * np.arange(0, len(t), 1 )  + phase[ik] )

  84. 

  85.     #plt.matshow(A, aspect='auto')

  86.     #plt.colorbar()

  87. 

  88.     #plt.figure()

  89.     #plt.plot(alpha)

  90.     #plt.plot(beta)

  91.     #plt.plot(amp)

  92. 

  93.     #plt.figure()

  94.     #plt.plot(h)

  95.     #plt.title("modelled noise")

  96.     return sN-h

  97. 

  98. 

  99. def harmonicEuler ( f0, sN, fs, nK, t ): 

  100.     """

  101.     Performs inverse calculation of harmonics contaminating a signal. 

  102.     Args:

  103.         f0 = base frequency of the sinusoidal noise 

  104.         sN = signal containing noise 

  105.         fs = sampling frequency

  106.         nK = number of harmonics to calculate 

  107.         t = time samples 

  108.     """

  109.     print("building Euler matrix ")

  110.     A = np.zeros( (len(t),  nK), dtype=np.complex64)

  111.     for irow, tt in enumerate(t): 

  112.         A[irow,:] = np.exp(1j* np.arange(1,nK+1) * 2*np.pi* (f0/fs) * irow)

  113. 

  114.     v = np.linalg.lstsq(A, sN, rcond=None) # rcond=None) #, rcond=1e-8)

  115.     alpha = np.real(v[0]) #[0::2]

  116.     beta  = np.imag(v[0]) #[1::2]

  117. 

  118.     amp = np.abs(v[0])     #np.sqrt( alpha**2 + beta**2 )

  119.     phase = np.angle(v[0]) # np.arctan(- beta/alpha)

  120. 

  121.     h = np.zeros(len(t))

  122.     for ik in range(nK):

  123.         h +=  2*amp[ik] * np.cos( 2.*np.pi*(ik+1) * (f0/fs) * np.arange(0, len(t), 1 )  + phase[ik] )

  124. 

  125.     return sN-h

  126. 

  127. def harmonicEuler2 ( f0, f1, sN, fs, nK, t ): 

  128.     """

  129.     Performs inverse calculation of harmonics contaminating a signal. 

  130.     Args:

  131.         f0 = base frequency of the sinusoidal noise 

  132.         sN = signal containing noise 

  133.         fs = sampling frequency

  134.         nK = number of harmonics to calculate 

  135.         t = time samples 

  136.     """

  137.     print("building Euler matrix 2 ")

  138.     A = np.zeros( (len(t),  2*nK), dtype=np.complex64)

  139.     for irow, tt in enumerate(t): 

  140.         A[irow,0:nK]    = np.exp( 1j* np.arange(1,nK+1)*2*np.pi*(f0/fs)*irow )

  141.         A[irow,nK:2*nK] = np.exp( 1j* np.arange(1,nK+1)*2*np.pi*(f1/fs)*irow )

  142. 

  143.     v = np.linalg.lstsq(A, sN, rcond=None) # rcond=None) #, rcond=1e-8)

  144. 

  145.     amp = np.abs(v[0][0:nK])     

  146.     phase = np.angle(v[0][0:nK]) 

  147.     amp1 = np.abs(v[0][nK:2*nK])     

  148.     phase1 = np.angle(v[0][nK:2*nK]) 

  149. 

  150.     h = np.zeros(len(t))

  151.     for ik in range(nK):

  152.         h +=  2*amp[ik]  * np.cos( 2.*np.pi*(ik+1) * (f0/fs) * np.arange(0, len(t), 1 )  + phase[ik] ) + \

  153.               2*amp1[ik] * np.cos( 2.*np.pi*(ik+1) * (f1/fs) * np.arange(0, len(t), 1 )  + phase1[ik] )

  154. 

  155.     return sN-h

  156. 

  157. def jacEuler( f0, sN, fs, nK, t):

  158.     print("building Jacobian matrix ")

  159.     J = np.zeros( (len(t),  nK), dtype=np.complex64 )

  160.     for it, tt in enumerate(t):

  161.         for ik, k in enumerate( np.arange(0, nK) ):

  162.             c = 1j*2.*np.pi*(ik+1.)*it

  163.             J[it, ik] = c*np.exp( c*f0/fs ) / fs 

  164.     #plt.matshow(np.imag(J), aspect='auto')

  165.     #plt.show()

  166.     return J

  167. 

  168. def harmonicNorm ( f0, sN, fs, nK, t ): 

  169.     return np.linalg.norm( harmonicEuler(f0, sN, fs, nK, t) )

  170. 

  171. def harmonic2Norm ( f0, sN, fs, nK, t ): 

  172.     return np.linalg.norm(harmonicEuler2(f0[0], f0[1], sN, fs, nK, t))

  173. 

  174. def minHarmonic(f0, sN, fs, nK, t):

  175.     f02 = guessf0(sN, fs)

  176.     print("minHarmonic", f0, fs, nK, " guess=", f02)

  177.     # CG, BFGS, Newton-CG, L-BFGS-B, TNC, SLSQP, dogleg, trust-ncg, trust-krylov, trust-exact and trust-constr

  178.     res = minimize( harmonicNorm, np.array((f0)), args=(sN, fs, nK, t)) #, method='CG', jac=jacEuler) #, hess=None, bounds=None )

  179.     print(res)

  180.     return harmonicEuler(res.x[0], sN, fs, nK, t)

  181. 

  182. def minHarmonic2(f1, f2, sN, fs, nK, t):

  183.     #f02 = guessf0(sN, fs)

  184.     #print("minHarmonic2", f0, fs, nK, " guess=", f02)

  185.     #methods with bounds, L-BFGS-B, TNC, SLSQP

  186.     res = minimize( harmonic2Norm, np.array((f1,f2)), args=(sN, fs, nK, t)) #, bounds=((f1-1.,f1+1.0),(f2-1.0,f2+1.0)), method='TNC' )

  187.     print(res)

  188.     return harmonicEuler2(res.x[0], res.x[1], sN, fs, nK, t) 

  189. 

  190. def guessf0( sN, fs ):

  191.     S = np.fft.fft(sN)

  192.     w = np.fft.fftfreq( len(sN), 1/fs )

  193.     imax = np.argmax( np.abs(S) )

  194.     #plt.plot( w, np.abs(S) )

  195.     #plt.show()

  196.     #print(w)

  197.     #print ( w[imax], w[imax+1] )

  198.     return abs(w[imax])

  199. 

  200. if __name__ == "__main__":

  201.     

  202.     import matplotlib.pyplot as plt 

  203. 

  204.     f0 = 60      # Hz

  205.     f1 = 62      # Hz

  206.     delta  = np.random.rand() 

  207.     delta2 =  np.random.rand() 

  208.     print("delta", delta)

  209.     fs = 10000   # GMR 

  210.     t = np.arange(0, 1, 1/fs)

  211.     phi =  np.random.rand() 

  212.     phi2 = np.random.rand() 

  213.     A =  1.0

  214.     A2 = 0.25 

  215.     A3 = 1.0 

  216.     nK = 35

  217.     T2 = .200

  218.     sN  = A *np.sin( ( 1*(delta  +f0))*2*np.pi*t + phi ) + \

  219.           A2*np.sin( ( 1*(delta2 +f1))*2*np.pi*t + phi2 ) + \

  220.               np.random.normal(0,.1,len(t)) + \

  221.               + A3*np.exp( -t/T2  ) 

  222. 

  223.     sNc = A *np.sin(  (1*(delta +f0))*2*np.pi*t + phi ) + \

  224.           A2*np.sin(  (1*(delta2+f1))*2*np.pi*t + phi2 ) + \

  225.               + A3*np.exp( -t/T2  ) 

  226. 

  227. 

  228.     guessf0(sN, fs)

  229. 

  230.     # single freq

  231.     #h = harmonicEuler( f0, sN, fs, nK, t) 

  232.     #h = minHarmonic( f0, sN, fs, nK, t) 

  233.     

  234.     # two freqs 

  235.     h = minHarmonic2( f0, f1, sN, fs, nK, t) 

  236.     #h = harmonic2( f0, f1, sN, fs, nK, t) 

  237.     #h = harmonicEuler2( f0, f1, sN, fs, nK, t) 

  238. 

  239.     plt.figure()

  240.     plt.plot(t, sN, label="sN")

  241.     #plt.plot(t, sN-h, label="sN-h")

  242.     plt.plot(t, h, label='h')

  243.     plt.title("harmonic")

  244.     plt.legend()

  245. 

  246.     plt.figure()

  247.     plt.plot(t, sN-sNc, label='true noise')

  248.     plt.plot(t, h, label='harmonic removal')

  249.     plt.plot(t, np.exp(-t/T2), label="nmr")

  250.     plt.legend()

  251.     plt.title("true noise")

  252.     

  253.     plt.show()