| 1 | """ |
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| 2 | This module is responsible to compute invariant related computation. |
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| 3 | @author: Gervaise B. Alina/UTK |
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| 4 | """ |
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| 5 | |
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| 6 | import math |
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| 7 | from DataLoader.data_info import Data1D as LoaderData1D |
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| 8 | class InvariantCalculator(object): |
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| 9 | """ |
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| 10 | Compute invariant if data is given. |
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| 11 | Can provide volume fraction and surface area if the user provides |
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| 12 | Porod constant and contrast values. |
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| 13 | @precondition: the user must send a data of type DataLoader.Data1D |
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| 14 | @note: The data boundaries are assumed as infinite range. |
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| 15 | """ |
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| 16 | def __init__(self, data): |
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| 17 | """ |
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| 18 | Initialize variables |
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| 19 | @param data: data must be of type DataLoader.Data1D |
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| 20 | @param contrast: contrast value of type float |
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| 21 | @param pConst: Porod Constant of type float |
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| 22 | """ |
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| 23 | ## Invariant |
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| 24 | self.q_star = self._get_q_star(data= data) |
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| 25 | |
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| 26 | def _get_q_star(self, data): |
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| 27 | """ |
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| 28 | @param data: data of type Data1D |
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| 29 | @return invariant value |
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| 30 | """ |
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| 31 | if not issubclass(data.__class__, LoaderData1D): |
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| 32 | #Process only data that inherited from DataLoader.Data_info.Data1D |
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| 33 | raise ValueError,"Data must be of type DataLoader.Data1D" |
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| 34 | |
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| 35 | # Check whether we have slit smearing information |
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| 36 | if data.is_slit_smeared(): |
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| 37 | return self._get_qstar_unsmeared(data= data) |
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| 38 | else: |
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| 39 | return self._get_qstar_smeared(data= data) |
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| 40 | |
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| 41 | |
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| 42 | |
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| 43 | def _get_qstar_unsmeared(self, data): |
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| 44 | """ |
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| 45 | @param data: data of type Data1D |
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| 46 | Compute invariant given by |
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| 47 | q_star= x0**2 *y0 *dx0 +x1**2 *y1 *dx1 + ..+ xn**2 *yn *dxn |
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| 48 | where n= infinity |
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| 49 | dxi = 1/2*(xi+1 - xi) + (xi - xi-1) |
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| 50 | dx0 = x1 - x0 |
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| 51 | dxn = xn - xn-1 |
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| 52 | """ |
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| 53 | if len(data.x)<=1 or len(data.y)<=1 or len(data.x)!=len(data.y): |
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| 54 | msg= "Length x and y must be equal" |
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| 55 | msg +=" and greater than 1; got x=%s, y=%s"%(len(data.x), |
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| 56 | len(data.y)) |
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| 57 | raise ValueError,msg |
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| 58 | elif len(data.x)==1 and len(data.y)==1: |
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| 59 | return 0 |
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| 60 | |
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| 61 | else: |
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| 62 | n= len(data.x)-1 |
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| 63 | #compute the first delta |
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| 64 | dx0= data.x[1]- data.x[0] |
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| 65 | #compute the last delta |
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| 66 | dxn= data.x[n]- data.x[n-1] |
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| 67 | sum = 0 |
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| 68 | sum += data.x[0]* data.x[0]* data.y[0]*dx0 |
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| 69 | sum += data.x[n]* data.x[n]* data.y[n]*dxn |
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| 70 | if len(data.x)==2: |
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| 71 | return sum |
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| 72 | else: |
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| 73 | #iterate between for element different from the first and the last |
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| 74 | for i in xrange(1, n-1): |
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| 75 | dxi = (data.x[i+1] - data.x[i-1])/2 |
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| 76 | sum += data.x[i]*data.x[i]* data.y[i]* dxi |
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| 77 | return sum |
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| 78 | |
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| 79 | |
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| 80 | def _get_qstar_smeared(self, data): |
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| 81 | """ |
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| 82 | @param data: data of type Data1D |
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| 83 | Compute invariant with slit smearing info |
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| 84 | q_star= x0*dxl *y0 *dx0 + x1*dxl *y1 *dx1 + ..+ xn*dxl *yn *dxn |
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| 85 | where n= infinity |
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| 86 | dxi = 1/2*(xi+1 - xi) + (xi - xi-1) |
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| 87 | dx0 = x1 - x0 |
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| 88 | dxn = xn - xn-1 |
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| 89 | dxl: slit smearing value |
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| 90 | """ |
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| 91 | if data.dxl ==None: |
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| 92 | msg = "Cannot compute Smear invariant dxl " |
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| 93 | msg +="must be a list, got dx= %s"%str(data.dxl) |
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| 94 | raise ValueError,msg |
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| 95 | |
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| 96 | if len(data.x)<=1 or len(data.y)<=1 or len(data.x)!=len(data.y)\ |
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| 97 | or len(data.x)!= len(data.dxl): |
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| 98 | |
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| 99 | msg = "x, dxl, and y must be have the same length and greater than 1" |
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| 100 | raise ValueError,msg |
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| 101 | else: |
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| 102 | n= len(data.x)-1 |
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| 103 | #compute the first delta |
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| 104 | dx0= data.x[1]- data.x[0] |
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| 105 | #compute the last delta |
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| 106 | dxn= data.x[n]- data.x[n-1] |
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| 107 | sum = 0 |
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| 108 | sum += data.x[0]* data.dxl[0]* data.y[0]*dx0 |
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| 109 | sum += data.x[n]* data.dxl[n]* data.y[n]*dxn |
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| 110 | if len(data.x)==2: |
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| 111 | return sum |
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| 112 | else: |
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| 113 | #iterate between for element different from the first and the last |
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| 114 | for i in xrange(1, n-1): |
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| 115 | dxi = (data.x[i+1] - data.x[i-1])/2 |
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| 116 | sum += data.x[i]* data.dxl[i]* data.y[i]* dxi |
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| 117 | return sum |
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| 118 | |
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| 119 | def get_volume_fraction(self, contrast): |
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| 120 | """ |
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| 121 | Compute volume fraction is given by: |
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| 122 | |
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| 123 | q_star= 2*(pi*contrast)**2* volume( 1- volume) |
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| 124 | for k = 10^(8)*q_star/(2*(pi*|contrast|)**2) |
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| 125 | we get 2 values of volume: |
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| 126 | volume1 = (1- sqrt(1- 4*k))/2 |
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| 127 | volume2 = (1+ sqrt(1- 4*k))/2 |
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| 128 | contrast unit is 1/A^(2)= 10^(16)cm^(2) |
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| 129 | q_star unit 1/A^(3)*1/cm |
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| 130 | |
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| 131 | the result returned will be 0<= volume <= 1 |
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| 132 | |
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| 133 | @param contrast: contrast value provides by the user of type float |
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| 134 | @return: volume fraction |
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| 135 | @note: volume fraction must have no unit |
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| 136 | """ |
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| 137 | if contrast < 0: |
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| 138 | raise ValueError, "contrast must be greater than zero" |
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| 139 | |
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| 140 | if self.q_star ==None: |
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| 141 | raise RuntimeError, "Q_star is not defined" |
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| 142 | |
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| 143 | if self.q_star < 0: |
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| 144 | raise ValueError, "invariant must be greater than zero. Q_star=%g" % self.q_star |
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| 145 | |
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| 146 | #compute intermediate constant |
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| 147 | k = 1.e-8*self.q_star /(2*(math.pi* math.fabs(float(contrast)))**2) |
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| 148 | #check discriminant value |
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| 149 | discrim= 1 - 4*k |
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| 150 | if discrim < 0: |
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| 151 | raise RuntimeError, "could not compute the volume fraction: negative discriminant" |
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| 152 | elif discrim ==0: |
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| 153 | volume = 1/2 |
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| 154 | return volume |
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| 155 | else: |
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| 156 | # compute the volume |
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| 157 | volume1 = 0.5 *(1 - math.sqrt(discrim)) |
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| 158 | volume2 = 0.5 *(1 + math.sqrt(discrim)) |
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| 159 | |
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| 160 | if 0<= volume1 and volume1 <= 1: |
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| 161 | return volume1 |
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| 162 | elif 0<= volume2 and volume2<= 1: |
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| 163 | return volume2 |
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| 164 | raise RuntimeError, "could not compute the volume fraction: inconsistent results" |
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| 165 | |
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| 166 | def get_surface(self, contrast, porod_const): |
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| 167 | """ |
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| 168 | Compute the surface given by: |
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| 169 | surface = (2*pi *volume(1- volume)*pConst)/ q_star |
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| 170 | |
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| 171 | @param contrast: contrast value provides by the user of type float |
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| 172 | @param porod_const: Porod constant |
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| 173 | @return: specific surface |
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| 174 | """ |
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| 175 | # Compute the volume |
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| 176 | volume = self.get_volume_fraction(contrast) |
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| 177 | |
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| 178 | # Check whether we have Q star |
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| 179 | if self.q_star ==None: |
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| 180 | raise RuntimeError, "Q_star is not defined" |
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| 181 | |
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| 182 | if self.q_star ==0: |
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| 183 | raise ValueError, "invariant must be greater than zero. Q_star=%g" % self.q_star |
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| 184 | |
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| 185 | return 2*math.pi*volume*(1-volume)*float(porod_const)/self.q_star |
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| 186 | |
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| 187 | |
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