Exemple #1
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def gratArray(outerrad, hubdist, angle, inc, l=95.):
    """Trace rays leaving SPO petal to the fanned grating array.
    Start with outermost radius and rotate grating array about
    the hub. Define outermost grating position by max ray radius
    at desired axial height.
    Rays have been traced to bottom of outermost grating.
    """
    #Put origin at bottom of outermost grating
    PT.transform(outerrad, 0, 0, 0, 0, 0)
    #Go to proper incidence angle of grating
    PT.transform(0, 0, 0, 0, 0, -pi / 2)
    PT.transform(0, 0, 0, -pi / 2 - angle + inc, 0, 0)
    #Go to hub
    PT.transform(0, hubdist, 0, 0, 0, 0)
    #Trace out gratings until no rays hit a grating
    #Flat
    #Indices
    #Reflect
    #Apply Grating
    #Next
    PT.flat()
    ind = np.logical_and(PT.y < -hubdist, PT.y > -l - hubdist)
    ang = l * sin(inc) / hubdist
    i = 0
    while np.sum(ind) > 0:
        i = i + 1
        PT.reflect(ind=ind)
        PT.radgrat(0., 160. / hubdist, 0, 1., ind=ind)
        PT.transform(0, 0, 0, ang, 0, 0)
        PT.flat()
        ind = np.logical_and(PT.y < -hubdist, PT.y > -l - hubdist)
        sys.stdout.write('%i \r' % i)
        sys.stdout.flush()
    pdb.set_trace()
Exemple #2
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def setupSource(wave,N,radius=450.,focal=8000.,scatter=50e-6,\
                gwidth=25.,glength=32.,pitch=0.,yaw=0.,roll=0.):
    """Set up converging beam with some scatter.
    Idea is to place a grating at radius and focal length
    with an incidence angle of 1.5 degrees
    """
    #Setup rays over grating surface
    PT.x = np.random.uniform(low=-gwidth / 2, high=gwidth / 2, size=N)
    PT.y = np.random.uniform(low=-glength / 2, high=glength / 2, size=N)
    PT.z = np.repeat(0., N)
    PT.l = np.zeros(N)
    PT.m = np.zeros(N)
    PT.n = np.zeros(N)
    PT.ux = np.zeros(N)
    PT.uy = np.zeros(N)
    PT.uz = np.repeat(1., N)
    #Transform to nominal focus to set ray cosines
    PT.transform(0, 0, 0, -88.5 * np.pi / 180, 0, 0)
    PT.transform(0, radius, -focal, 0, 0, 0)
    rad = np.sqrt(PT.x**2 + PT.y**2 + PT.z**2)
    PT.l = -PT.x / rad
    PT.m = -PT.y / rad
    PT.n = -PT.z / rad
    #Add scatter
    PT.l = PT.l + scatter / 10. * np.random.normal(size=N)
    PT.m = PT.m + scatter * np.random.normal(size=N)
    PT.n = -np.sqrt(1. - PT.l**2 - PT.m**2)
    #Go back to plane of of grating
    PT.transform(0, -radius, focal, 0, 0, 0)
    PT.transform(0, 0, 0, 88.5 * np.pi / 180, 0, np.pi)
    #Place grating and diffract
    hubdist = np.sqrt(radius**2 + focal**2) * np.cos(1.5 * np.pi / 180)
    PT.flat()
    PT.reflect()
    PT.transform(0, 0, 0, pitch, roll, yaw)
    PT.radgrat(hubdist, 160. / hubdist, 1, wave)
    PT.itransform(0, 0, 0, pitch, roll, yaw)
    #Go to focal plane
    PT.transform(0, 0, 0, np.pi / 2, 0, 0)
    PT.transform(0, 0, -hubdist, 0, 0, 0)
    PT.transform(0, 0, 27.27727728 - .04904905, 0, 0, 0)
    PT.flat()

    #plt.plot(PT.x,PT.y,'.')

    return PT.centroid()
Exemple #3
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def arc(inc, yaw, hubdist, wave, order, dpermm):
    """Return x and y positions of diffraction arc
    as a function of wavelength for a given order"""
    #Set up source ray
    PT.circularbeam(0., 1)
    #Transform to grating frame
    PT.transform(0, 0, 0, pi / 2 + inc, 0, 0)
    PT.transform(0, 0, 0, 0, 0, yaw)
    PT.flat()
    #Apply grating
    PT.reflect()
    PT.radgrat(hubdist, dpermm, order, wave)
    #Go to focus
    PT.transform(0, 0, 0, 0, 0, -yaw)
    PT.transform(0, hubdist, 0, 0, 0, 0)
    PT.transform(0, 0, 0, pi / 2, 0, 0)
    PT.flat()
    #Get ray positions
    return PT.x[0], PT.y[0]
Exemple #4
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def traceBeam(gratAlign,order=1.,wave=2.48,blaze=30.):
    """Traces a beam to grating, applies misalignment,
    then traces to focal plane and returns mean
    x,y position
    x refers to spectral direction
    """
    #Compute yaw to achieve Littrow configuration
    phi0 = arccos(sin(1.5*pi/180)/cos(blaze*pi/180))
    yaw = -tan(sin(blaze*pi/180)/tan(phi0))
##    yaw = yaw - pi/2
##    pdb.set_trace()
    
    #Set up beam
    rays = PT.pointsource(0.,10) #multiple rays to avoid Python complaints

    #Rotate to nominal grating reference frame
    PT.transform(rays,0,0,0,pi/2+1.5*pi/180,0,0)

    #Apply misalignment
    PT.transform(rays,*gratAlign)

    #Trace grating
    PT.flat(rays)
    PT.transform(rays,0,0,0,0,0,yaw) #-1.73211678*pi/180
    PT.radgrat(rays,11500.,160./11500.,order,wave)
    PT.itransform(rays,0,0,0,0,0,yaw)

    #Reverse misalignment
    PT.itransform(rays,*gratAlign)

    #Trace to focal plane
    PT.transform(rays,0,11500.,0,0,0,0)
    PT.transform(rays,0,0,0,pi/2,0,0)
    PT.flat(rays)

    #Return mean positions
    return mean(rays[1]),mean(rays[2])