aimc: matlab/bmm/carfac/Carfac.py annotate

annotate matlab/bmm/carfac/Carfac.py @ 470:8e8381785b2b

(none)

author	alan.strelzoff
date	Sun, 11 Mar 2012 00:49:12 +0000
parents	af9d803c0f2b
children	40cc1c0f20a8

rev	line source
alan@461	1 # Carfac.py - Cochlear filter model based on Dick Lyons work. This material taken from his Hearing book (to be published)
alan@470	2 # Author: Al Strelzoff: strelz@mit.edu
alan@461	3
alan@470	4 # The point of this file is to extract some of the formulas from the book and practice with them so as to better understand the filters.
alan@470	5 # The file has been written and tested for python 2.7
alan@461	6
alan@470	7 from numpy import cos, sin, pi, e, real,imag,arctan2
alan@470	8
alan@470	9
alan@470	10 from pylab import figure, plot,loglog, title, axis, show
alan@461	11
alan@461	12 fs = 22050.0 # sampling rate
alan@461	13
alan@461	14
alan@461	15 # given a frequency f, return the ERB
alan@461	16 def ERB_Hz(f):
alan@461	17 # Ref: Glasberg and Moore: Hearing Research, 47 (1990), 103-138
alan@461	18 return 24.7 * (1.0 + 4.37 * f / 1000.0)
alan@461	19
alan@461	20
alan@461	21 # ERB parameters
alan@461	22 ERB_Q = 1000.0/(24.7*4.37) # 9.2645
alan@461	23 ERB_break_freq = 1000/4.37 # 228.833
alan@461	24
alan@461	25 ERB_per_step = 0.3333
alan@461	26
alan@461	27 # set up channels
alan@461	28
alan@461	29 first_pole_theta = .78 * pi # We start at the top frequency.
alan@461	30 pole_Hz = first_pole_theta * fs / (2.0*pi) # frequency of top pole
alan@461	31 min_pole_Hz = 40.0 # bottom frequency
alan@461	32
alan@461	33 # set up the pole frequencies according to the above parameters
alan@461	34 pole_freqs = [] # empty list of pole frequencies to fill, zeroth will be the top
alan@461	35 while pole_Hz > min_pole_Hz:
alan@461	36 pole_Hz = pole_Hz - ERB_per_step * ERB_Hz(pole_Hz)
alan@461	37 pole_freqs.append(pole_Hz)
alan@461	38
alan@461	39 n_ch = len(pole_freqs) # n_ch is the number of channels or frequency steps
alan@461	40 print('num channels',n_ch)
alan@461	41
alan@461	42 # Now we have n_ch, the number of channels, so can make the array of filters by instantiating the filter class (see below)
alan@461	43
alan@461	44 # before we make the filters, let's plot the position of the frequencies and the values of ERB at each.
alan@461	45
alan@461	46 fscale = []
alan@461	47 erbs = []
alan@461	48
alan@470	49 figure(1)
alan@461	50 for i in range(n_ch):
alan@461	51
alan@461	52 f = pole_freqs[i] # the frequencies from the list
alan@461	53 ERB = ERB_Hz(f) # the ERB value at each frequency
alan@461	54 fscale.append(f)
alan@461	55 erbs.append(ERB)
alan@461	56
alan@461	57 # plot a verticle hash at each frequency:
alan@461	58 u = []
alan@461	59 v = []
alan@461	60 for j in range(5):
alan@461	61 u.append(f)
alan@461	62 v.append(10.0 + float(j))
alan@461	63
alan@461	64 plot(u,v)
alan@461	65
alan@461	66 loglog(fscale,erbs)
alan@461	67
alan@461	68 title('ERB scale')
alan@461	69
alan@461	70
alan@461	71
alan@461	72 # This filter class includes some methods useful only in design. They will not be used in run time implementation.
alan@461	73 # From figure 14.3 in Dick Lyon's book.
alan@470	74 # When translating to C++, this class will become a struct, and all the methods will be moved outside.
alan@461	75
alan@461	76
alan@461	77 #########################################################The Carfac filter class#################################################################################
alan@461	78
alan@461	79 # fixed parameters
alan@461	80 min_zeta = 0.12
alan@461	81
alan@461	82 class carfac():
alan@461	83
alan@461	84
alan@461	85 # instantiate the class (in C++, the constructor)
alan@461	86 def __init__(self,f):
alan@461	87
alan@461	88 self.frequency = f
alan@461	89
alan@461	90 theta = 2.0 * pi * f/fs
alan@461	91 r = 1.0 - sin(theta) * min_zeta
alan@461	92 a = r * cos(theta)
alan@461	93 c = r * sin(theta)
alan@470	94 h = sin(theta)
alan@470	95 g = (1.0 - 2.0 * a + r ** 2)/(1.0 - 2.0 * a + h * c + r ** 2)
alan@470	96
alan@470	97
alan@461	98
alan@470	99 self.gh = g*h # no need to repeat in real time
alan@461	100
alan@461	101 # make all parameters properties of the class
alan@461	102 self.a = a
alan@461	103 self.c = c
alan@461	104 self.r = r
alan@461	105 self.theta = theta
alan@461	106 self.h = h
alan@461	107 self.g = g
alan@461	108
alan@461	109
alan@461	110 # the two storage elements. Referring to diagram 14.3 on p.263, z2 is the upper storage register, z1, the lower
alan@461	111 self.z1 = 0.0
alan@461	112 self.z2 = 0.0
alan@461	113
alan@461	114
alan@461	115 # frequency response of this filter
alan@461	116 self.H = []
alan@461	117
alan@461	118
alan@461	119
alan@461	120 # the total frequency magnitude of this filter including all the filters in front of this one
alan@461	121 self.HT = [] # this list will be filled by multiplying all the H's ahead of it together with its own (H)
alan@461	122
alan@461	123
alan@461	124
alan@461	125 # execute one clock tick. Take in one input and output one result. Execution semantics taken from fig. 14.3
alan@461	126 # This execution model is not tested in this file. Here for reference. See the file Exec.py for testing this execution model. This is the main run time method.
alan@461	127 def input(self,X):
alan@461	128
alan@461	129 # recover the class definitions of these variables. These statements below take up zero time at execution since they are just compiler declarations.
alan@470	130 # computation below is organized as some loads, followed by 3 2x2 multiply accumulates
alan@470	131 # Note: this function is not exercised in this file and is here only for reference
alan@461	132
alan@461	133 a = self.a
alan@461	134 c = self.c
alan@461	135 g = self.g
alan@470	136 gh = self.gh
alan@461	137 z1 = self.z1 # z1 is the lower storage in fig. 14.3
alan@461	138 z2 = self.z2
alan@461	139
alan@461	140 # calculate what the next value of z1 will be, but don't overwrite current value yet.
alan@470	141 next_z1 = (a * z1) + (c * z2) # Note: it is a 2 element multiply accumulate. compute first so as not to have to do twice.
alan@461	142 # the output Y
alan@470	143 Y = g * X + gh * next_z1 # Note: organized as a 2 element multiply accumulate.
alan@461	144
alan@461	145 #stores
alan@470	146 self.z2 = X + (a * z2) - (c * z1) #Note: this is a 2 element multiply accumulate
alan@470	147 self.z1 = next_z1
alan@461	148
alan@461	149 return Y # The output
alan@461	150
alan@461	151 # complex frequency response of this filter at frequency w. That is, what it contributes to the cascade
alan@461	152 # this method is used for test only. It finds the frequency magnitude. Not included in run time filter class.
alan@461	153 def Hw(self,w):
alan@461	154
alan@461	155 a = self.a
alan@461	156 c = self.c
alan@461	157 g = self.g
alan@461	158 h = self.h
alan@461	159 r = self.r
alan@461	160 z = e ** (complex(0,w)) # w is in radians so this is z = exp(jw)
alan@470	161 return g * (1.0 + (hcz)/(z*2 - 2.0az + r*2 ))
alan@461	162
alan@461	163
alan@461	164
alan@461	165 ######################################################End of Carfac filter class########################################################################
alan@461	166
alan@461	167 # instantiate the filters
alan@461	168
alan@461	169 # n_ch is the number of filters as determined above
alan@461	170
alan@461	171 Filters = [] # the list of all filters, the zeroth is the top frequency
alan@461	172 for i in range(n_ch):
alan@461	173 f = pole_freqs[i]
alan@461	174 filter = carfac(f) # note: get the correct parameters for r and h from Dick's matlab script. Load them here from a table.
alan@461	175 Filters.append(filter)
alan@461	176
alan@461	177
alan@461	178
alan@461	179 # sweep parameters
alan@461	180 steps = 1000
alan@461	181
alan@470	182 figure(2)
alan@470	183 title('CarFac individual filter frequency response')
alan@470	184 # note: the scales are linear, not logrithmic as in the book
alan@461	185
alan@461	186
alan@461	187 for i in range(n_ch):
alan@461	188 filter = Filters[i]
alan@461	189 # plotting arrays
alan@461	190 u = []
alan@461	191 v = []
alan@461	192 # calculate the frequency magnitude by stepping the frequency in radians
alan@461	193 for j in range(steps):
alan@461	194
alan@470	195 w = pi * float(j)/steps
alan@461	196 u.append(w)
alan@461	197 mag = filter.Hw(w) # freq mag at freq w
alan@461	198 filter.H.append(mag) # save for later use
alan@461	199 filter.HT.append(mag) # will be total response of cascade to this point after we do the multiplication in a step below
alan@470	200 v.append(abs(mag)) # y plotting axis
alan@461	201
alan@461	202
alan@461	203 plot(u,v)
alan@461	204
alan@461	205
alan@461	206 # calculate the phase response of the same group of filters
alan@461	207 figure(3)
alan@470	208 title('Carfac individual filter Phase lag')
alan@461	209
alan@461	210
alan@461	211 for i in range(n_ch):
alan@461	212 filter = Filters[i]
alan@461	213
alan@461	214 u = []
alan@461	215 v = []
alan@461	216 for j in range(steps):
alan@470	217 x = pi * float(j)/steps
alan@461	218
alan@461	219 u.append(x)
alan@461	220
alan@461	221 mag = filter.H[j]
alan@470	222 phase = arctan2(-imag(mag),-real(mag)) - pi # this formula used to avoid wrap around
alan@461	223
alan@461	224 v.append(phase) # y plotting axis
alan@461	225
alan@461	226 plot(u,v)
alan@470	227 axis([0.0,pi,-3.0,0.05])
alan@461	228
alan@461	229
alan@470	230 # calulate and plot cascaded frequency response
alan@461	231
alan@461	232 figure(4)
alan@470	233 title('CarFac cascaded filter frequency response')
alan@461	234
alan@461	235
alan@461	236 for i in range(n_ch-1):
alan@461	237
alan@461	238 filter = Filters[i]
alan@461	239 next = Filters[i+1]
alan@461	240
alan@461	241
alan@461	242 u = []
alan@461	243 v = []
alan@461	244 for j in range(steps):
alan@470	245 w = pi * float(j)/steps
alan@470	246 u.append(w)
alan@461	247 mag = filter.HT[j] * next.HT[j]
alan@470	248 next.HT[j] = mag
alan@470	249 v.append(abs(mag))
alan@461	250
alan@461	251
alan@461	252 plot(u,v)
alan@461	253
alan@461	254
alan@461	255
alan@461	256 # calculate and plot the phase responses of the cascaded filters
alan@461	257
alan@470	258 figure(5)
alan@470	259 title('Carfac cascaded filter Phase lag')
alan@461	260
alan@461	261
alan@461	262 for i in range(n_ch):
alan@470	263
alan@461	264 filter = Filters[i]
alan@461	265
alan@461	266
alan@461	267 u = []
alan@470	268 v = [] # store list of phases
alan@470	269 w = [] # second copy of phases needed for phase unwrapping
alan@461	270 for j in range(steps):
alan@470	271 x = pi * float(j)/steps
alan@461	272
alan@461	273 u.append(x)
alan@461	274 mag = filter.HT[j]
alan@470	275 a = imag(mag)
alan@470	276 b = real(mag)
alan@470	277 phase = arctan2(a,b)
alan@461	278
alan@470	279 v.append(phase)
alan@470	280 w.append(phase)
alan@461	281
alan@470	282 # unwrap the phase
alan@461	283
alan@461	284
alan@470	285 for i in range(1,len(v)):
alan@470	286 diff = v[i]-v[i-1]
alan@470	287 if diff > pi:
alan@470	288 for j in range(i,len(w)):
alan@470	289 w[j] -= 2.0 * pi
alan@470	290 elif diff < -pi:
alan@470	291 for j in range(i,len(w)):
alan@470	292 w[j] += 2.0 * pi
alan@470	293
alan@470	294 else: continue
alan@470	295
alan@470	296
alan@470	297 plot(u,w)
alan@470	298 axis([0.0,pi,-25.0,0.05])
alan@461	299 show()
alan@461	300

Mercurial > hg > aimc

annotate matlab/bmm/carfac/Carfac.py @ 470:8e8381785b2b