コード例 #1
0
    def __init__(self, *args, **kwargs):
        """
        Initialize a rectangular element

        hRect = rect(args,*,hw=1.0, hh=1.0, center=[0,0,0],euler=[0,0,0],conv='yxz',intrinsic=True,nAbcissa=[1,1])

        A rect object is returned, which can be used for computing a continuous wave field (ARFI pressure)

        hw        - half width of the element
        hh        - half height of the element
        center    - center of element
        euler     - orientation of element
        conv      - convention used for the orientation, order of rotations
        intrinsic - if true, the coordinate system is rotating
        nAbcissa  - number of Gaussian abcissas used for integration [nWidth,nHeight]
        """
        opt = dotdict({
            'hw': 1,
            'hh': 1,
            'center': [0, 0, 0],
            'euler': [0, 0, 0],
            'conv': 'yxz',
            'intrinsic': True,
            'nAbcissa': 1
        })
        opt.update(*args, **kwargs)
        opt.nAbcissa = np.array(opt.nAbcissa).flatten()

        super(rect, self).update(**opt)

        if len(self.nAbcissa) == 1:
            self.nAbcissa = np.r_[self.nAbcissa[0], self.nAbcissa[0]]

        self.center = np.array(self.center).flatten()
        self.euler = np.array(self.euler).flatten()
コード例 #2
0
ファイル: fnm.py プロジェクト: JensMunkHansen/sofus
    def __init__(self,*args, **kwargs):
        """
        Initialize a rectangular element

        hRect = rect(args,*,hw=1.0, hh=1.0, center=[0,0,0],euler=[0,0,0],conv='yxz',intrinsic=True,nAbcissa=[1,1])

        A rect object is returned, which can be used for computing a continuous wave field (ARFI pressure)

        hw        - half width of the element
        hh        - half height of the element
        center    - center of element
        euler     - orientation of element
        conv      - convention used for the orientation, order of rotations
        intrinsic - if true, the coordinate system is rotating
        nAbcissa  - number of Gaussian abcissas used for integration [nWidth,nHeight]
        """
        opt = dotdict({'hw' : 1,
                       'hh' : 1,
                       'center'    : [0,0,0],
                       'euler'     : [0,0,0],
                       'conv'      : 'yxz',
                       'intrinsic' : True,
                       'nAbcissa'  : 1})
        opt.update(*args,**kwargs)
        opt.nAbcissa = np.array(opt.nAbcissa).flatten()
        
        super(rect,self).update(**opt)

        if len(self.nAbcissa)==1:
            self.nAbcissa = np.r_[self.nAbcissa[0], self.nAbcissa[0]]

        self.center = np.array(self.center).flatten()
        self.euler  = np.array(self.euler).flatten()
コード例 #3
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ファイル: fhfields.py プロジェクト: JensMunkHansen/sofus
  def FourierToSpaceTimeNorway(P12,fx1,fy1,f1,**kwargs):

    opt = dotdict({'resolution' : np.r_[6e-5, 6e-5, 6e-5],
                   'c'          : 1540.0})
    opt.update(**kwargs)

    resolution = opt.resolution
    c          = opt.c

    testPlot = False

    dfx=(fx1[1]-fx1[0]);
    dfy=(fy1[1]-fy1[0]);
    df=(f1[1]-f1[0]);

    Nfx=int(2*np.round(c/dfx/resolution[0]/2)+1)
    Nfy=int(2*np.round(c/dfy/resolution[1]/2)+1)
    Nfs=int(2*np.round(c/2/df/resolution[2]/2)+1)

    xax=np.linspace(-1/dfx*c/2,1/dfx*c/2,Nfx);
    yax=np.linspace(-1/dfy*c/2,1/dfy*c/2,Nfy);
    zax=np.linspace(-1/df*c/4,1/df*c/4,Nfs);

    [Nx,Ny,Nf]=P12.shape
    P12zp=np.zeros((Nfx,Nfy,Nfs),dtype=np.complex128)
    ix1=int(np.round(1+(Nfx-1)/2-(Nx-1)/2))
    iy1=int(np.round(1+(Nfy-1)/2-(Ny-1)/2))
    if1=int(np.round(1+(Nfs-1)/2+1+f1[0]/df) - 1)
    P12zp[ix1:ix1+Nx,iy1:iy1+Ny,if1:if1+Nf]=P12;
    P12zp=np.fft.fftshift(P12zp);
    p12=ifftn(P12zp);
    p12=np.fft.fftshift(p12);

    return (p12,xax,yax,zax)
コード例 #4
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ファイル: fhfields.py プロジェクト: JensMunkHansen/sofus
 def FieldAtFocus(xdc, **kwargs):
   opt = dotdict({'nx' : 100,
                  'ny' : 100,
                  'dx' : 6e-5,
                  'dy' : 6e-5})
   # Maximum frequency
   fmax = None
   if xdc.bandwidth == 0.0:
     fmax = xdc.f0
コード例 #5
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  def compareWithReference(**kwargs):
    opt = dotdict({'method0'  : 'CalcCwFieldRef',
                   'method1'  : 'CalcCwFieldRef',
                   'location' : 'inside',
                   'ndiv'     : 2,
                   'eps'      : 1e-5,
                   'quiet'    : False})

    opt.update(**kwargs)
    quiet = opt.quiet
    
    areas = [2.0,3.0,4.0,5.0]
    widths  = np.array([areas[0],1.0,areas[2],1.0],dtype=np.float32)
    heights = np.array([1.0,areas[1],1.0,areas[3]],dtype=np.float32)
    
    xsign = np.array([1.0,-1.0,-1.0,1.0],dtype=np.float32)
    ysign = np.array([1.0,1.0,-1.0,-1.0],dtype=np.float32)
    
    # Ensure that we either slightly inside or outside
    scale = 40.0 * np.finfo(np.float32).eps
    
    epss = dict({'inside'  : -scale,
                 'outside' :  scale})
    
    ndiv = opt.ndiv
    iCorners = [0,1,2,3]
    
    eps    = epss[opt.location]
    method0 = opt.method0
    method1 = opt.method1
    
    scatters = np.c_[(widths+eps)/2.0 * xsign,
                     (heights+eps)/2.0 * ysign,
                     np.ones(4,dtype=np.float32)]
    if not(quiet):
      print('Testing: %s vs %s: %s' % (opt.method0,opt.method1, opt.location))
    success = True
    for iCorner in iCorners:
      a = fnm.ApertureFloat(1,
                            float(widths[iCorner]),
                            float(0.0),
                            float(heights[iCorner]))
      a.nthreads = 1
      a.nDivH = ndiv
      a.nDivW = ndiv
      a.f0 = 1
      a.c  = 1
      
      exec('result0 = a.'+method0+'([scatters[iCorner]])[1].flatten()')
      exec('result1 = a.'+method1+'([scatters[iCorner]])[1].flatten()')
      diff = np.abs(result0)-np.abs(result1)
      reldiff = diff / np.mean(np.abs(result0)+np.abs(result1))
      success = success and (reldiff < opt.eps)
      if not(quiet):
        print('Relative difference: %f' % (reldiff))
    return success
コード例 #6
0
ファイル: field.py プロジェクト: JensMunkHansen/sofus
 def getData(self):
   opt = dotdict({})
   # Consider returning full data
   opt['nx'], _    = self.data(self.index(0,0),Qt.DisplayRole).toInt()
   opt['dx']       = float(self.data(self.index(2,0),Qt.DisplayRole).toString())
   opt['offset_x'] = float(self.data(self.index(1,0),Qt.DisplayRole).toString())
   opt['nz'], _    = self.data(self.index(0,2),Qt.DisplayRole).toInt()
   opt['dz']       = float(self.data(self.index(2,2),Qt.DisplayRole).toString())
   opt['offset_z'] = float(self.data(self.index(1,2),Qt.DisplayRole).toString())
   opt['ny'], _    = self.data(self.index(0,1),Qt.DisplayRole).toInt()
   opt['dy']       = float(self.data(self.index(2,1),Qt.DisplayRole).toString())
   opt['offset_y'] = float(self.data(self.index(1,1),Qt.DisplayRole).toString())
   return opt
コード例 #7
0
ファイル: fhfields.py プロジェクト: JensMunkHansen/sofus
  def __init__(self, **kwargs):
    opt = dotdict({'pitch0' : 0.2e-3,
                   'N0'     : 64,
                   'pitch1' : 0.2e-3,
                   'N1'     : 64,
                   'f0'     : 7e6,
                   'focus'  : np.r_[0.0,0.0,3.0e-2]})
    opt.update(**kwargs)

    self._f0        = opt.f0
    self._focus     = opt.focus
    self._bandwidth = 1.0
    self.N0 = opt.N0
    self.pitch0 = opt.pitch0
    self.N1 = opt.N1
    self.pitch1 = opt.pitch1
コード例 #8
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 def getData(self):
     opt = dotdict({})
     # Consider returning full data
     opt['nx'], _ = self.data(self.index(0, 0), Qt.DisplayRole).toInt()
     opt['dx'] = float(
         self.data(self.index(2, 0), Qt.DisplayRole).toString())
     opt['offset_x'] = float(
         self.data(self.index(1, 0), Qt.DisplayRole).toString())
     opt['nz'], _ = self.data(self.index(0, 2), Qt.DisplayRole).toInt()
     opt['dz'] = float(
         self.data(self.index(2, 2), Qt.DisplayRole).toString())
     opt['offset_z'] = float(
         self.data(self.index(1, 2), Qt.DisplayRole).toString())
     opt['ny'], _ = self.data(self.index(0, 1), Qt.DisplayRole).toInt()
     opt['dy'] = float(
         self.data(self.index(2, 1), Qt.DisplayRole).toString())
     opt['offset_y'] = float(
         self.data(self.index(1, 1), Qt.DisplayRole).toString())
     return opt
コード例 #9
0
ファイル: fnm_arrays.py プロジェクト: JensMunkHansen/sofus
  def __init__(self,*args, **kwargs):
    opt = dotdict({'hw' : 0,
                   'hh' : 0,
                   'center'    : [0,0,0],
                   'euler'     : [0,0,0],
                   'conv'      : 'yxz',
                   'intrinsic' : True})
    opt.update(*args,**kwargs)
    super(rect,self).update(**opt)

    # Only 2 conventions are supported by Sofus
    conventionsSupported3 = ['yxy']
    conventionsSupported2 = ['yxz', 'yxy']
    if not(conventionsSupported2.count(opt.conv) > 0):
      raise Exception('Convention not supported')
    if (opt.euler[2] != 0.0):
      if not(conventionsSupported3.count(opt.conv) > 0):
        raise Exception('If convention yxz is used, z must be zero')

    self.center = np.array(self.center).flatten()
    self.euler  = np.array(self.euler).flatten()
コード例 #10
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    def __init__(self, *args, **kwargs):
        opt = dotdict({
            'hw': 0,
            'hh': 0,
            'center': [0, 0, 0],
            'euler': [0, 0, 0],
            'conv': 'yxz',
            'intrinsic': True
        })
        opt.update(*args, **kwargs)
        super(rect, self).update(**opt)

        # Only 2 conventions are supported by Sofus
        conventionsSupported3 = ['yxy']
        conventionsSupported2 = ['yxz', 'yxy']
        if not (conventionsSupported2.count(opt.conv) > 0):
            raise Exception('Convention not supported')
        if (opt.euler[2] != 0.0):
            if not (conventionsSupported3.count(opt.conv) > 0):
                raise Exception('If convention yxz is used, z must be zero')

        self.center = np.array(self.center).flatten()
        self.euler = np.array(self.euler).flatten()
コード例 #11
0
ファイル: fhfields.py プロジェクト: JensMunkHansen/sofus
  def FieldAtFocusNorway(xdc, **kwargs):
    """
    Field computed in the focal plane using the Fraunhofer approximation.

    This implementation is taken from Hans Torp, Trondheim.

    K-space is not computed properly to be used with FFT's.
    """
    opt = dotdict({'Apod'         : np.r_[0.0,0.0], # Rectangular windows
                   'oversampling' : 1,
                   'P'            : None,
                   'rng'          : np.array([0.006, 0.006, 0.0006])})

    oversampling = opt.oversampling

    c = xdc.c

    # Focus distance (azimuth, elevation) - assumed equal for now
    Rx = xdc.focus[2]
    Ry = xdc.focus[2]

    # Diameter (azimuth, elevation)
    [Dx,Dy,_] = xdc.extent[:,1] - xdc.extent[:,0]

    # Range (x,y,z)
    rng = opt.rng

    Rxy = np.r_[Rx, Ry]
    R = np.mean(Rxy)
    [betax, betay] = opt.Apod

    circsymm = 1

    bw = xdc.f0 * xdc.bandwidth
    f0 = xdc.f0

    if opt.P == None:
      df=c/2.0/rng[2]
      Nf=np.round(bw/df) + 1
      pData = dotdict({})
      pData.f1 = np.linspace(f0 - bw/2, f0 + bw/2, Nf)
      # Trond W. variant - exp(x**4), -1.5 < x < 1.5
      pData.P  = trondwin(len(pData.f1),1.5).T
      res = pData.P
      opt.f = pData.f1
      opt.P = pData.P

    e = None
    f = opt.f
    P = opt.P

    # TODO(JMH): Enable this
    ROCcorrection = 1
    sphericalCorrection = 1

    if (len(f) == 1):
      fmax = f[0]
    else:
      fmax = 1.1*f[-1]

    # Always odd number FFT (TODO: Specify freely instead of using Dx, Dy)
    Nx=1+2*np.round(rng[0]*fmax*Dx/R/c)
    Ny=1+2*np.round(rng[1]*fmax*Dy/R/c)
    fx=np.linspace(-fmax*Dx/R,fmax*Dx/R,Nx)
    fy=np.linspace(-fmax*Dy/R,fmax*Dy/R,Ny)
    fxi=np.linspace(-fmax*Dx/R,fmax*Dx/R,1+oversampling*(Nx-1))[None,:]
    fyi=np.linspace(-fmax*Dy/R,fmax*Dy/R,1+oversampling*(Ny-1))[None,:]
    fxm=np.dot(fxi.T,np.ones((1,fyi.shape[1])))
    fym=np.dot(np.ones((fxi.shape[1],1)),fyi)

    # 2D low-pass filter
    hlp2=np.ones((oversampling,oversampling))/(oversampling)**2
    P1=np.zeros((len(fx),len(fy),len(f)),dtype=np.complex128)
    P1i0=np.zeros((len(fxi.T),len(fyi.T)),dtype=np.complex128)

    # Loop over frequencies
    for k in range(len(f)):
      fxmax=0.5*Dx/R*f[k]
      fymax=0.5*Dy/R*f[k]
      Ix=np.where(np.abs(fxi)<fxmax)[1]
      Iy=np.where(np.abs(fyi)<fymax)[1]
      wx=tukeywin(len(Ix),betax)
      wy=tukeywin(len(Iy),betay)
      w=np.dot(wx[:,None],wy[None,:])
      if circsymm:
        w=tukey2(len(Ix),betax)
      P1k=P1i0
      P1k[Ix[0]:Ix[-1]+1,Iy[0]:Iy[-1]+1] = w*P[k]
      if oversampling>1:
        # Low-pass filter
        P1k=convolve2d(P1k,hlp2,'same')
      if ROCcorrection:
        Ha=apertureCorrection(R,Rxy[0],Rxy[1],f[k],fxi,fyi)
        P1k=P1k*Ha
      if sphericalCorrection:
        Hs=focalcorrection(R,f[k],fxi,fyi)
        P1u=P1k
        P1k=convolve2d(P1k,Hs,'same')
      P1k=P1k[0::oversampling,0::oversampling] # Decimation to correct sampling rate
      P1[:,:,k] = P1k
    return (P1,fx,fy,f)
コード例 #12
0
def convex_array(*args, **kwargs):
    opt = dotdict({
        'radius': 6.1e-2,
        'nElements': 192,
        'nSubH': 1,  # Elevation
        'nSubW': 1,  # Not used
        'pitch': None,
        'kerf': None,
        'height': 1.0e-2,
        'efocus': 0.02,
        'sector': 60.0 / 180 * np.pi,  # Redundant
    })

    opt.updateset(**kwargs)

    half_width = (opt.pitch - opt.kerf) / 2.0
    half_height = opt.height / 2.0

    R = 1.0
    focus = 1.0

    bFocused = opt.efocus != None and opt.nSubH > 1

    if bFocused:
        focus = opt.efocus
        elSector = 2 * np.arctan2(half_height, focus)
        R = np.sqrt(focus**2 + (half_height)**2)
    else:
        elSector = 0

    if (opt.sector != None):
        dAz = opt.sector / max((opt.nElements - 1), 1)
        if (opt.pitch == None):
            # We compute a pitch based on sector size
            opt.pitch = 2.0 * opt.radius * np.sin(dAz / 2.0)
            print('pitch is %f' % opt.pitch)
    else:
        # We compute sector based on pitch
        opt.sector = \
            (opt.nElements - 1) * 2.0 * np.arcsin(0.5 * opt.pitch / opt.radius)
        dAz = opt.sector / max((opt.nElements - 1), 1)

    azAngles = (np.r_[0:opt.nElements] - (opt.nElements - 1.0) / 2) * dAz
    rects = []
    el = 0.0

    dEl = elSector / max((opt.nSubH - 1), 1)
    elAngles = (np.r_[0:opt.nSubH] - (opt.nSubH - 1.0) / 2) * dEl

    chordLength = \
        {True : 2 * focus * np.sin(dEl/2), False : opt.height}[opt.nSubH > 1]

    R = np.sqrt(focus**2 + (opt.height / 2.0)**2)

    if opt.kerf == None:
        opt.kerf = 0.0

    half_width = (opt.pitch - opt.kerf) / 2.0

    for iAz in range(opt.nElements):
        for iEl in range(opt.nSubH):
            # Center position on element
            center = np.r_[0, 0, opt.radius]

            # Candidate (no rotation is done around elevation focus)
            center = center + np.r_[0, focus * np.tan(elAngles[iEl]),
                                    -(R * np.cos(elAngles[iEl]) - focus)]

            rotm = \
                euler2rot(azAngles[iAz],0,0,conv='yxz',intrinsic=True)

            # Rotate about origin
            center = np.dot(rotm, center)

            # Translate
            center = center - [0, 0, opt.radius]

            # Translate sub-elements
            rots = euler2rot(azAngles[iAz],
                             elAngles[iEl],
                             0,
                             conv='yxz',
                             intrinsic=True)

            for iSubW in range(opt.nSubW):
                # Shift center coordinate
                center1 = center + 2 * half_width / opt.nSubW * rots[:, 0] * (
                    iSubW - (opt.nSubW - 1) / 2.0)

                r = rect(hw=half_width / opt.nSubW,
                         hh=chordLength / 2.0,
                         center=center1,
                         euler=[azAngles[iAz], -elAngles[iEl], 0],
                         conv='yxz',
                         intrinsic=True)
                rects.append(r)

    elements = np.r_[[rects[i].element() for i in range(len(rects))]]
    elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

    a = fnm.ApertureFloat()
    a.subelements = elements.astype(np.float32)
    return a
コード例 #13
0
def convex_array3(*args, **kwargs):
    """
    Tissue-side ceramic radius, azimuth is outer radius
    """
    opt = dotdict({
        'radius': 6.1e-2,
        'nElements': 192,
        'nSubH': 1,  # Elevation
        'nSubW': 1,  # Not used
        'pitch': 2.3e-4,
        'kerf': None,
        'height': 1.0e-2,
        'efocus': 0.0,
        'elePlacement': 'Outer',
    })

    opt.updateset(**kwargs)

    focus = opt.efocus

    if (focus == None):
        focus = 0.0

    azR = opt.radius

    # Arc-length from center to center
    azArcLength = opt.pitch * (opt.nElements - 1.0)

    azSegment = azArcLength / azR

    dAz = azSegment / max(opt.nElements - 1.0, 1.0)

    azTanLength = 2.0 * azR * np.tan(dAz / 2.0)

    azAngles = (np.r_[0:opt.nElements] - (opt.nElements - 1.0) / 2) * dAz

    elR = np.sqrt(focus**2 + (opt.height / 2.0)**2)

    # Sector from outer edge to outer edge
    elSector = 2.0 * np.arctan2(opt.height / 2.0, focus)

    dEl = elSector / opt.nSubH

    elChordLength = 2.0 * elR * np.sin(dEl / 2.0)

    if (focus != 0.0):
        elTanLength = 2.0 * elR * np.tan(dEl / 2.0)
    else:
        elTanLength = opt.height / 2.0

    if opt.elePlacement == 'Outer':
        elAngles = (np.r_[0:(opt.nSubH)] - (opt.nSubH - 1.0) / 2.0) * dEl
        hh = elTanLength / 2.0
    else:
        elAngles = (np.r_[0:(opt.nSubH + 1)] - opt.nSubH / 2.0) * dEl
        hh = elChordLength / 2.0

    hw = 0.5 * (opt.pitch - opt.kerf)  #azTanLength / 2.0

    rects = []
    for iEl in range(opt.nSubH):
        # Rotation in elevation
        center = \
                 np.r_[0.0,
                       np.sin(elAngles[iEl])*elR,
                       -(np.cos(elAngles[iEl])*elR - elR) + azR] # focus replaced by elR
        for iAz in range(opt.nElements):
            # Rotation in azimuth
            rotm = \
                   euler2rot(azAngles[iAz],0,0,conv='yxz',intrinsic=True)
            # Rotate about origin
            center1 = np.dot(rotm, center) - np.r_[0, 0, azR]
            r = rect(hw=hw,
                     hh=hh,
                     center=center1,
                     euler=[azAngles[iAz], elAngles[iEl], 0],
                     conv='yxz',
                     intrinsic=True)
            rects.append(r)

    elements = np.r_[[rects[i].element() for i in range(len(rects))]]
    elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

    a = fnm.ApertureFloat()
    a.subelements = elements.astype(np.float32)
    return a
コード例 #14
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from dicts import dotdict


def log_compression(img, dBrange=60):
    logenv = 20 * np.log10(img / img.max())
    logenv[logenv < -dBrange] = -dBrange
    return logenv


plt.ion()

opt = dotdict({
    'c': 1540.0,
    'fs': 25e6,
    'f0': 5e6,
    'fprf': 10e3,
    'echo': True,
    'depth_offset': 0.03,
    'meanfilter': True,
    'threshold_ratio': -20
})

filedir = os.path.dirname(os.path.realpath(__file__))

datadir = os.path.join(filedir, '../data/')

bmodeFile = glob.glob(os.path.join(datadir, 'b*.mat'))[0]

rfdata = loadmat(bmodeFile)['bdata']

rfdata = rfdata / (2.0**15)
コード例 #15
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def linear_array3(*args, **kwargs):
    """
  Works for outer/inner radius. Outer is crazy if efocus is 0.0
  """
    opt = dotdict({
        'nElements': 192,
        'nSubH': 1,  # Elevation
        'elePlacement': 'Outer',
        'nSubW': 1,
        'pitch': 0.2e-3,
        'kerf': 0.2e-4,
        'height': 1.0e-2,
        'efocus': 0.0
    })

    opt.update(**kwargs)

    focus = opt.efocus

    R = np.sqrt(focus**2 + (opt.height / 2.0)**2)

    # Sector from outer edge to outer edge
    elSector = 2.0 * np.arctan2(opt.height / 2.0, focus)

    dEl = elSector / opt.nSubH
    hw = (opt.pitch - opt.kerf) / 2.0

    chordLength = 2.0 * R * np.sin(dEl / 2.0)

    tanLength = 2.0 * R * np.tan(dEl / 2.0)

    if opt.elePlacement == 'Outer':
        elAngles = (np.r_[0:(opt.nSubH)] - (opt.nSubH - 1.0) / 2.0) * dEl
        eleSize = tanLength
    else:
        elAngles = (np.r_[0:(opt.nSubH + 1)] - opt.nSubH / 2.0) * dEl
        eleSize = chordLength

    # Sagitta (height) of the segment (not used)
    h = R * (1.0 - np.cos(dEl))

    # Height of triangular portion (not used)
    d = R - h

    rects = []

    if opt.elePlacement == 'Outer':
        for iElement in range(opt.nElements):
            for iSubH in range(opt.nSubH):
                center = \
                  np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                        np.sin(elAngles[iSubH])*R,
                        -(np.cos(elAngles[iSubH])*R - focus)]
                for iSubW in range(opt.nSubW):
                    center1 = center + \
                              2 * hw/opt.nSubW * np.r_[1,0,0] * (iSubW - (opt.nSubW-1)/2.0)
                    r = rect(hw=hw / opt.nSubW,
                             hh=eleSize / 2.0,
                             center=center1,
                             euler=[0, elAngles[iSubH], 0],
                             conv='yxz',
                             intrinsic=True)
                    rects.append(r)
    else:
        for iElement in range(opt.nElements):
            for iSubH in range(opt.nSubH):
                center = \
                  np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                        0.5*(np.sin(elAngles[iSubH]) + np.sin(elAngles[iSubH+1]))*R,
                        -(0.5*(np.cos(elAngles[iSubH]) + np.cos(elAngles[iSubH+1]))*R - focus)]
                for iSubW in range(opt.nSubW):
                    center1 = center + \
                              2 * hw/opt.nSubW * np.r_[1,0,0] * (iSubW - (opt.nSubW-1)/2.0)
                    r = rect(hw=hw / opt.nSubW,
                             hh=eleSize / 2.0,
                             center=center1,
                             euler=[
                                 0,
                                 0.5 * (elAngles[iSubH] + elAngles[iSubH + 1]),
                                 0
                             ],
                             conv='yxz',
                             intrinsic=True)
                    rects.append(r)

    elements = np.r_[[rects[i].element() for i in range(len(rects))]]
    elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

    a = fnm.ApertureFloat()
    a.subelements = elements.astype(np.float32)
    return a
コード例 #16
0
ファイル: transducer.py プロジェクト: thewtex/sofus
 def getData(self):
   opt = dotdict({})
   for i in range(self.columnCount()):
     exec("opt['%s']" % (str(self.headerData(i, Qt.Horizontal, Qt.DisplayRole).toString())) + "=%s" %(self.data(self.index(0,i),Qt.DisplayRole).toString()))
   return opt
コード例 #17
0
ファイル: fhfields_test.py プロジェクト: JensMunkHansen/sofus
import numpy as np

import matplotlib.pyplot as plt

filedir = os.path.dirname(os.path.realpath(__file__))
sys.path.append(os.path.join(filedir, '../fnm'))

from dicts import dotdict
from fhfields import (FraunhoferAperture, FraunhoferField)
from parula import parula_map

plt.ion()

opt = dotdict({'pitch0' : 0.2e-3,
               'N0'     : 64,
               'pitch1' : 0.2e-3,
               'N1'     : 64,
               'f0'     : 7e6,
               'focus'  : np.r_[0.0,0.0,3.0e-2]})

xdc = FraunhoferAperture(**opt)
xdc.bandwidth = 0.2

resolution = np.r_[1.000e-004, 1.000e-004, 1.0000e-005]
rng        = np.r_[0.003, 0.003, 0.006]

opt = dotdict({'resolution' : resolution,
               'rng'        : rng})

[P12, fx1, fy1, f1] = FraunhoferField.FieldAtFocusNorway(xdc, **opt)

[p12,xax,yax,zax] = FraunhoferField.FourierToSpaceTimeNorway(P12,fx1,fy1,f1,**opt)
コード例 #18
0
ファイル: fnm_arrays.py プロジェクト: JensMunkHansen/sofus
def linear_array(*args,**kwargs):
  """
  Key-value arguments: nElements, nSubH, pitch, kerf, height, focus
  """
  opt = dotdict({'nElements' : 192,
                 'nSubH'     : 1, # Elevation
                 'nSubW'     : 1,
                 'pitch'     : 0.2e-3,
                 'kerf'      : 0.2e-4,
                 'height'    : 1.0e-2,
                 'efocus'     : None})

  opt.update(**kwargs)

  half_width  = (opt.pitch - opt.kerf) / 2.0
  half_height = opt.height / 2.0
  rects = []

  focus = 1.0
  R     = 1.0

  bFocused = opt.efocus != None and opt.nSubH > 1
  
  if bFocused:
      focus = opt.efocus
      elSector = 2 * np.arctan2(half_height, focus)
      R = np.sqrt(focus**2 + (opt.height / 2.0)**2)
  else:
      elSector = 0

  dEl =  elSector / max((opt.nSubH-1),1)
  elAngles = (np.r_[0:opt.nSubH] - (opt.nSubH - 1.0)/2) * dEl

  if bFocused:
      chordLength = 2 * focus * np.sin(dEl/2)
  else:
      chordLength = opt.height/opt.nSubH

  for iElement in range(opt.nElements):
      for iSubH in range(opt.nSubH):
          if bFocused:
              center = np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                             focus * np.tan(elAngles[iSubH]),
                             -(R * np.cos(elAngles[iSubH]) - focus)]
          else:
              center = np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                             (iSubH - (opt.nSubH - 1.0)/2.0)*chordLength,
                             0]
          for iSubW in range(opt.nSubW):
              center1 = center + 2 * half_width/opt.nSubW * np.r_[1,0,0] * (iSubW - (opt.nSubW-1)/2.0)
              r = rect(hw=half_width/opt.nSubW,
                       hh=chordLength/2.0,
                       center=center1,
                       euler=[0,-elAngles[iSubH],0],conv='yxz',intrinsic=True)
              rects.append(r)

  elements = np.r_[[rects[i].element() for i in range(len(rects))]]
  elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

  a = fnm.ApertureFloat()
  a.subelements = elements.astype(np.float32)
  return a
コード例 #19
0
ファイル: fnm_arrays.py プロジェクト: JensMunkHansen/sofus
def linear_array3(*args, **kwargs):
  """
  Works for outer/inner radius. Outer is crazy if efocus is 0.0
  """
  opt = dotdict({'nElements'    : 192,
                 'nSubH'        : 1,       # Elevation
                 'elePlacement' : 'Outer',
                 'nSubW'        : 1,
                 'pitch'        : 0.2e-3,
                 'kerf'         : 0.2e-4,
                 'height'       : 1.0e-2,
                 'efocus'       : 0.0})

  opt.update(**kwargs)

  focus = opt.efocus

  R = np.sqrt(focus**2 + (opt.height / 2.0)**2)
  
  # Sector from outer edge to outer edge
  elSector = 2.0 * np.arctan2(opt.height/2.0, focus)

  dEl =  elSector / opt.nSubH
  hw  = (opt.pitch - opt.kerf) / 2.0

  chordLength = 2.0 * R * np.sin(dEl/2.0)

  tanLength   = 2.0 * R * np.tan(dEl/2.0)

  if opt.elePlacement == 'Outer':
    elAngles = (np.r_[0:(opt.nSubH)] - (opt.nSubH-1.0)/2.0) * dEl
    eleSize = tanLength
  else:
    elAngles = (np.r_[0:(opt.nSubH+1)] - opt.nSubH/2.0) * dEl
    eleSize = chordLength

  # Sagitta (height) of the segment (not used)
  h = R*(1.0-np.cos(dEl))
    
  # Height of triangular portion (not used)
  d = R - h
    
  rects = []

  if opt.elePlacement == 'Outer':
    for iElement in range(opt.nElements):
      for iSubH in range(opt.nSubH):
        center = \
          np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                np.sin(elAngles[iSubH])*R,
                -(np.cos(elAngles[iSubH])*R - focus)]
        for iSubW in range(opt.nSubW):
          center1 = center + \
                    2 * hw/opt.nSubW * np.r_[1,0,0] * (iSubW - (opt.nSubW-1)/2.0)
          r = rect(hw=hw/opt.nSubW,
                   hh=eleSize/2.0,
                   center=center1,
                   euler=[0,elAngles[iSubH],0],
                   conv='yxz',
                   intrinsic=True)
          rects.append(r)
  else:
    for iElement in range(opt.nElements):
      for iSubH in range(opt.nSubH):
        center = \
          np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                0.5*(np.sin(elAngles[iSubH]) + np.sin(elAngles[iSubH+1]))*R,
                -(0.5*(np.cos(elAngles[iSubH]) + np.cos(elAngles[iSubH+1]))*R - focus)]
        for iSubW in range(opt.nSubW):
          center1 = center + \
                    2 * hw/opt.nSubW * np.r_[1,0,0] * (iSubW - (opt.nSubW-1)/2.0)
          r = rect(hw=hw/opt.nSubW,
                   hh=eleSize/2.0,
                   center=center1,
                   euler=[0,0.5*(elAngles[iSubH]+elAngles[iSubH+1]),0],
                   conv='yxz',
                   intrinsic=True)
          rects.append(r)

  elements = np.r_[[rects[i].element() for i in range(len(rects))]]
  elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

  a = fnm.ApertureFloat()
  a.subelements = elements.astype(np.float32)
  return a
コード例 #20
0
ファイル: fnm_arrays.py プロジェクト: JensMunkHansen/sofus
def convex_array(*args,**kwargs):
    opt = dotdict({'radius'    : 6.1e-2,
                   'nElements' : 192,
                   'nSubH'     : 1, # Elevation
                   'nSubW'     : 1, # Not used
                   'pitch'     : None,
                   'kerf'      : None,
                   'height'    : 1.0e-2,
                   'efocus'     : 0.02,
                   'sector'    : 60.0/180 * np.pi, # Redundant
                 })

    opt.updateset(**kwargs)

    half_width  = (opt.pitch - opt.kerf) / 2.0
    half_height = opt.height / 2.0

    R     = 1.0
    focus = 1.0

    bFocused = opt.efocus != None and opt.nSubH > 1
    
    if bFocused:
        focus = opt.efocus
        elSector = 2 * np.arctan2(half_height, focus)
        R = np.sqrt(focus**2 + (half_height)**2)
    else:
        elSector = 0
    
    if (opt.sector != None):
        dAz = opt.sector / max((opt.nElements - 1),1)
        if (opt.pitch == None):
            # We compute a pitch based on sector size
            opt.pitch = 2.0*opt.radius*np.sin(dAz/2.0)
            print('pitch is %f' % opt.pitch)
    else:
        # We compute sector based on pitch
        opt.sector = \
            (opt.nElements - 1) * 2.0 * np.arcsin(0.5 * opt.pitch / opt.radius)
        dAz = opt.sector / max((opt.nElements - 1),1)

    azAngles = (np.r_[0:opt.nElements] - (opt.nElements - 1.0)/2) * dAz
    rects = []
    el = 0.0

    dEl =  elSector / max((opt.nSubH-1),1)
    elAngles = (np.r_[0:opt.nSubH] - (opt.nSubH - 1.0)/2) * dEl

    chordLength = \
        {True : 2 * focus * np.sin(dEl/2), False : opt.height}[opt.nSubH > 1]

    R = np.sqrt(focus**2 + (opt.height / 2.0)**2)

    if opt.kerf == None:
        opt.kerf = 0.0

    half_width = (opt.pitch - opt.kerf) / 2.0

    for iAz in range(opt.nElements):
        for iEl in range(opt.nSubH):
            # Center position on element
            center = np.r_[0,0,opt.radius]
            
            # Candidate (no rotation is done around elevation focus)
            center = center + np.r_[0, focus * np.tan(elAngles[iEl]), -(R * np.cos(elAngles[iEl]) - focus) ]

            rotm = \
                euler2rot(azAngles[iAz],0,0,conv='yxz',intrinsic=True)

            # Rotate about origin
            center = np.dot(rotm,center)

            # Translate
            center = center - [0,0,opt.radius]

            # Translate sub-elements
            rots = euler2rot(azAngles[iAz],elAngles[iEl],0,conv='yxz',intrinsic=True)

            for iSubW in range(opt.nSubW):
                # Shift center coordinate
                center1 = center + 2 * half_width/opt.nSubW * rots[:,0] * (iSubW - (opt.nSubW-1)/2.0)
                
                r = rect(hw=half_width/opt.nSubW,hh=chordLength/2.0,
                         center=center1,
                         euler=[azAngles[iAz],-elAngles[iEl],0],conv='yxz',intrinsic=True)
                rects.append(r)

    elements = np.r_[[rects[i].element() for i in range(len(rects))]]
    elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

    a = fnm.ApertureFloat()
    a.subelements = elements.astype(np.float32)
    return a
コード例 #21
0
    def __init__(self, *args, **kwargs):

        opt = dotdict({
            'nElements': 192,
            'nSubH': 1,
            'nAbcissa': [1, 1],
            'pitch': 0.2e-3,
            'kerf': 0.2e-4,
            'height': 1.0e-2,
            'c': 1540.0,
            'focus': None
        })

        opt.update(**kwargs)

        half_width = (opt.pitch - opt.kerf) / 2.0
        half_height = opt.height / 2.0
        self.rects = []
        self.nElements = opt.nElements
        self.nSubH = opt.nSubH

        assert (self.nSubH % 2 == 1)

        focus = 1.0
        R = 1.0

        if (opt.focus != None):
            focus = opt.focus
            elSector = 2 * np.arctan2(half_height, focus)
            R = np.sqrt(focus**2 + (opt.height / 2.0)**2)
        else:
            elSector = 0

        dEl = elSector / max((opt.nSubH - 1), 1)
        elAngles = (np.r_[0:opt.nSubH] - (opt.nSubH - 1.0) / 2) * dEl

        if (opt.focus != None):
            chordLength = 2 * focus * np.sin(dEl / 2)
        else:
            chordLength = opt.height / opt.nSubH

        for iElement in range(opt.nElements):
            for iSubH in range(opt.nSubH):
                if opt.focus != None:
                    center = np.r_[(iElement - (opt.nElements - 1.0) / 2) *
                                   opt.pitch, focus * np.tan(elAngles[iSubH]),
                                   -(R * np.cos(elAngles[iSubH]) - focus)]
                else:
                    center = np.r_[(iElement -
                                    (opt.nElements - 1.0) / 2) * opt.pitch,
                                   (iSubH -
                                    (opt.nSubH - 1.0) / 2.0) * chordLength, 0]
                for iSubW in range(1):
                    center1 = center + 2 * half_width / 1.0 * np.r_[
                        1, 0, 0] * (iSubW - (1 - 1) / 2.0)
                    r = rect(hw=half_width / 1.0,
                             hh=chordLength / 2.0,
                             center=center1,
                             euler=[0, elAngles[iSubH], 0],
                             conv='yxz',
                             intrinsic=True,
                             nAbcissa=opt.nAbcissa)
                    self.rects.append(r)

        self.phases = np.ones(opt.nElements, dtype=np.complex128)
        self.c = opt.c
コード例 #22
0
ファイル: transducer.py プロジェクト: thewtex/sofus
import addpaths
from dicts import dotdict

xdc_data = dotdict({'Linear'                : dotdict({'N'      : int,
                                                       'width'  : float,
                                                       'kerf'   : float,
                                                       'pitch'  : float,
                                                       'height' : float,}),
                    'Linear (focused)'      : dotdict({'N'      : int,
                                                       'width'  : float,
                                                       'kerf'   : float,
                                                       'pitch'  : float,
                                                       'M'      : int,
                                                       'height' : float,
                                                       'efocus'  : float}),
                    'Curvelinear'           : dotdict({'N'      : int,
                                                       'width'  : float,
                                                       'kerf'   : float,
                                                       'pitch'  : float,
                                                       'radius' : float,
                                                       'height' : float,}),
                    'Curvelinear (focused)' : dotdict({'N'      : int,
                                                       'width'  : float,
                                                       'kerf'   : float,
                                                       'pitch'  : float,
                                                       'radius' : float,
                                                       'M'      : int,
                                                       'height' : float,
                                                       'efocus'  : float,})})

class ElevationPlacementModel(QtCore.QAbstractListModel):
コード例 #23
0
ファイル: fnm.py プロジェクト: JensMunkHansen/sofus
    def __init__(self,*args, **kwargs):

      opt = dotdict({'nElements' : 192,
                     'nSubH'     : 1,
                     'nAbcissa'  : [1,1],
                     'pitch'     : 0.2e-3,
                     'kerf'      : 0.2e-4,
                     'height'    : 1.0e-2,
                     'c'         : 1540.0,
                     'focus'     : None})

      opt.update(**kwargs)

      half_width  = (opt.pitch - opt.kerf) / 2.0
      half_height = opt.height / 2.0
      self.rects = []
      self.nElements = opt.nElements
      self.nSubH     = opt.nSubH

      assert(self.nSubH % 2 == 1)
      
      focus = 1.0
      R     = 1.0

      if (opt.focus != None):
          focus = opt.focus
          elSector = 2 * np.arctan2(half_height, focus)
          R = np.sqrt(focus**2 + (opt.height / 2.0)**2)
      else:
          elSector = 0
      
      dEl =  elSector / max((opt.nSubH-1),1)
      elAngles = (np.r_[0:opt.nSubH] - (opt.nSubH - 1.0)/2) * dEl
      
      if (opt.focus != None):
          chordLength = 2 * focus * np.sin(dEl/2)
      else:
          chordLength = opt.height/opt.nSubH
      
      for iElement in range(opt.nElements):
          for iSubH in range(opt.nSubH):
              if opt.focus != None:
                  center = np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                                 focus * np.tan(elAngles[iSubH]),
                                 -(R * np.cos(elAngles[iSubH]) - focus)]
              else:
                  center = np.r_[(iElement - (opt.nElements-1.0)/2)*opt.pitch,
                                 (iSubH - (opt.nSubH - 1.0)/2.0)*chordLength,
                                 0]
              for iSubW in range(1):
                  center1 = center + 2 * half_width/1.0 * np.r_[1,0,0] * (iSubW - (1-1)/2.0)
                  r = rect(hw=half_width/1.0,hh=chordLength/2.0,
                           center=center1,
                           euler=[0,elAngles[iSubH],0],
                           conv='yxz',
                           intrinsic=True,
                           nAbcissa=opt.nAbcissa)
                  self.rects.append(r)

      self.phases = np.ones(opt.nElements,dtype=np.complex128)
      self.c = opt.c
コード例 #24
0
ファイル: fnm_arrays.py プロジェクト: JensMunkHansen/sofus
def convex_array3(*args,**kwargs):
    """
    Tissue-side ceramic radius, azimuth is outer radius
    """
    opt = dotdict({'radius'       : 6.1e-2,
                   'nElements'    : 192,
                   'nSubH'        : 1, # Elevation
                   'nSubW'        : 1, # Not used
                   'pitch'        : 2.3e-4,
                   'kerf'         : None,
                   'height'       : 1.0e-2,
                   'efocus'       : 0.0,
                   'elePlacement' : 'Outer',
                 })

    opt.updateset(**kwargs)

    focus = opt.efocus

    if (focus == None):
      focus = 0.0
    
    azR = opt.radius
    
    # Arc-length from center to center
    azArcLength = opt.pitch * (opt.nElements-1.0)

    azSegment = azArcLength / azR

    dAz = azSegment / max(opt.nElements - 1.0,1.0)

    azTanLength   = 2.0 * azR * np.tan(dAz/2.0)

    azAngles = (np.r_[0:opt.nElements] - (opt.nElements - 1.0)/2) * dAz
    
    elR = np.sqrt(focus**2 + (opt.height / 2.0)**2)
  
    # Sector from outer edge to outer edge
    elSector = 2.0 * np.arctan2(opt.height/2.0, focus)

    dEl =  elSector / opt.nSubH

    elChordLength = 2.0 * elR * np.sin(dEl/2.0)

    if (focus != 0.0):
      elTanLength   = 2.0 * elR * np.tan(dEl/2.0)
    else:
      elTanLength   = opt.height / 2.0
    
    if opt.elePlacement == 'Outer':
      elAngles = (np.r_[0:(opt.nSubH)] - (opt.nSubH-1.0)/2.0) * dEl
      hh = elTanLength / 2.0
    else:
      elAngles = (np.r_[0:(opt.nSubH+1)] - opt.nSubH/2.0) * dEl
      hh = elChordLength / 2.0

    hw = 0.5*(opt.pitch - opt.kerf)#azTanLength / 2.0

    rects = []
    for iEl in range(opt.nSubH):
      # Rotation in elevation
      center = \
               np.r_[0.0,
                     np.sin(elAngles[iEl])*elR,
                     -(np.cos(elAngles[iEl])*elR - elR) + azR] # focus replaced by elR
      for iAz in range(opt.nElements):
        # Rotation in azimuth
        rotm = \
               euler2rot(azAngles[iAz],0,0,conv='yxz',intrinsic=True)
        # Rotate about origin
        center1 = np.dot(rotm,center) - np.r_[0,0,azR]
        r = rect(hw=hw,hh=hh,
                 center=center1,
                 euler=[azAngles[iAz],elAngles[iEl],0],conv='yxz',intrinsic=True)
        rects.append(r)
    
    elements = np.r_[[rects[i].element() for i in range(len(rects))]]
    elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

    a = fnm.ApertureFloat()
    a.subelements = elements.astype(np.float32)
    return a
コード例 #25
0
def linear_array(*args, **kwargs):
    """
  Key-value arguments: nElements, nSubH, pitch, kerf, height, focus
  """
    opt = dotdict({
        'nElements': 192,
        'nSubH': 1,  # Elevation
        'nSubW': 1,
        'pitch': 0.2e-3,
        'kerf': 0.2e-4,
        'height': 1.0e-2,
        'efocus': None
    })

    opt.update(**kwargs)

    half_width = (opt.pitch - opt.kerf) / 2.0
    half_height = opt.height / 2.0
    rects = []

    focus = 1.0
    R = 1.0

    bFocused = opt.efocus != None and opt.nSubH > 1

    if bFocused:
        focus = opt.efocus
        elSector = 2 * np.arctan2(half_height, focus)
        R = np.sqrt(focus**2 + (opt.height / 2.0)**2)
    else:
        elSector = 0

    dEl = elSector / max((opt.nSubH - 1), 1)
    elAngles = (np.r_[0:opt.nSubH] - (opt.nSubH - 1.0) / 2) * dEl

    if bFocused:
        chordLength = 2 * focus * np.sin(dEl / 2)
    else:
        chordLength = opt.height / opt.nSubH

    for iElement in range(opt.nElements):
        for iSubH in range(opt.nSubH):
            if bFocused:
                center = np.r_[(iElement - (opt.nElements - 1.0) / 2) *
                               opt.pitch, focus * np.tan(elAngles[iSubH]),
                               -(R * np.cos(elAngles[iSubH]) - focus)]
            else:
                center = np.r_[(iElement -
                                (opt.nElements - 1.0) / 2) * opt.pitch,
                               (iSubH - (opt.nSubH - 1.0) / 2.0) * chordLength,
                               0]
            for iSubW in range(opt.nSubW):
                center1 = center + 2 * half_width / opt.nSubW * np.r_[
                    1, 0, 0] * (iSubW - (opt.nSubW - 1) / 2.0)
                r = rect(hw=half_width / opt.nSubW,
                         hh=chordLength / 2.0,
                         center=center1,
                         euler=[0, -elAngles[iSubH], 0],
                         conv='yxz',
                         intrinsic=True)
                rects.append(r)

    elements = np.r_[[rects[i].element() for i in range(len(rects))]]
    elements = elements.reshape((opt.nElements, opt.nSubH * opt.nSubW, 8))

    a = fnm.ApertureFloat()
    a.subelements = elements.astype(np.float32)
    return a
コード例 #26
0
ファイル: fnm_sym_test.py プロジェクト: JensMunkHansen/sofus
def compareWithPython(**kwargs):
  opt = dotdict({'show'     : False,
                 'method'   : 'CalcCwFieldRef',
                 'location' : 'inside'})
  opt.update(**kwargs)
  
  areas = [2.0,3.0,4.0,5.0]
  widths  = np.array([areas[0],1.0,areas[2],1.0],dtype=np.float32)
  heights = np.array([1.0,areas[1],1.0,areas[3]],dtype=np.float32)

  xsign = np.array([1.0,-1.0,-1.0,1.0],dtype=np.float32)
  ysign = np.array([1.0,1.0,-1.0,-1.0],dtype=np.float32)

  show = opt.show
  # Ensure that we either slightly inside or outside
  scale = 40.0 * np.finfo(np.float32).eps

  epss = dict({'inside'  : -scale,
               'outside' :  scale})
  
  ndiv = 2
  iCorners = [0,1,2,3]

  eps    = epss[opt.location]
  method = opt.method

  scatters = np.c_[(widths+eps)/2.0 * xsign,
                   (heights+eps)/2.0 * ysign,
                   np.ones(4,dtype=np.float32)]

  print('Testing: %s vs %s: %s' % (opt.method,'H_accurate (Python)',opt.location))
  for iCorner in iCorners:
    a = fnm.ApertureFloat(1,float(widths[iCorner]),
                          float(0.0),
                          float(heights[iCorner]))
    a.nthreads = 1
    a.nDivH = ndiv
    a.nDivW = ndiv
    a.f0 = 1
    a.c  = 1
    if show:
      a.show()
      ax = plt.gca()
      ax.scatter([scatters[iCorner][0]],
                 [scatters[iCorner][1]],
                 [scatters[iCorner][2]],color='black',marker='o',s=20)
      
      ax.set_xlim([-widths.max(),widths.max()])
      ax.set_ylim([-heights.max(),heights.max()])
      ax.set_zlim([-5,5])
      ax.set_aspect('equal')
      plt.show()
    
    exec('result = a.'+method+'([scatters[iCorner]])')

    r = rect(hw=widths[iCorner]/2.0,hh=heights[iCorner]/2.0,center=[0,0,0],nAbcissa=ndiv)
          
    k = 2*np.pi / (a.c / a.f0)
  
    xs = np.ones((1,1))*scatters[iCorner][0]
    ys = np.ones((1,1))*scatters[iCorner][1]
    zs = np.ones((1,1))*scatters[iCorner][2]
  
    reference = r.H_accurate(xs,ys,zs,k)
    assert(np.abs(reference) - np.abs(result[1]) < np.finfo(np.float32).eps)
    diff = np.abs(reference)-np.abs(result[1])
    print('Relative difference: %f' % (diff / np.mean(np.abs(reference)+np.abs(result[1]))))
コード例 #27
0
def compareWithPython(**kwargs):
    opt = dotdict({
        'show': False,
        'method': 'CalcCwFieldRef',
        'location': 'inside'
    })
    opt.update(**kwargs)

    areas = [2.0, 3.0, 4.0, 5.0]
    widths = np.array([areas[0], 1.0, areas[2], 1.0], dtype=np.float32)
    heights = np.array([1.0, areas[1], 1.0, areas[3]], dtype=np.float32)

    xsign = np.array([1.0, -1.0, -1.0, 1.0], dtype=np.float32)
    ysign = np.array([1.0, 1.0, -1.0, -1.0], dtype=np.float32)

    show = opt.show
    # Ensure that we either slightly inside or outside
    scale = 40.0 * np.finfo(np.float32).eps

    epss = dict({'inside': -scale, 'outside': scale})

    ndiv = 2
    iCorners = [0, 1, 2, 3]

    eps = epss[opt.location]
    method = opt.method

    scatters = np.c_[(widths + eps) / 2.0 * xsign,
                     (heights + eps) / 2.0 * ysign,
                     np.ones(4, dtype=np.float32)]

    print('Testing: %s vs %s: %s' %
          (opt.method, 'H_accurate (Python)', opt.location))
    for iCorner in iCorners:
        a = fnm.ApertureFloat(1, float(widths[iCorner]), float(0.0),
                              float(heights[iCorner]))
        a.nthreads = 1
        a.nDivH = ndiv
        a.nDivW = ndiv
        a.f0 = 1
        a.c = 1
        if show:
            a.show()
            ax = plt.gca()
            ax.scatter([scatters[iCorner][0]], [scatters[iCorner][1]],
                       [scatters[iCorner][2]],
                       color='black',
                       marker='o',
                       s=20)

            ax.set_xlim([-widths.max(), widths.max()])
            ax.set_ylim([-heights.max(), heights.max()])
            ax.set_zlim([-5, 5])
            ax.set_aspect('equal')
            plt.show()

        exec('result = a.' + method + '([scatters[iCorner]])')

        r = rect(hw=widths[iCorner] / 2.0,
                 hh=heights[iCorner] / 2.0,
                 center=[0, 0, 0],
                 nAbcissa=ndiv)

        k = 2 * np.pi / (a.c / a.f0)

        xs = np.ones((1, 1)) * scatters[iCorner][0]
        ys = np.ones((1, 1)) * scatters[iCorner][1]
        zs = np.ones((1, 1)) * scatters[iCorner][2]

        reference = r.H_accurate(xs, ys, zs, k)
        assert (np.abs(reference) - np.abs(result[1]) < np.finfo(
            np.float32).eps)
        diff = np.abs(reference) - np.abs(result[1])
        print('Relative difference: %f' %
              (diff / np.mean(np.abs(reference) + np.abs(result[1]))))