Exemplo n.º 1
0
def collectFocalPlaneRays(z):
    tra2 = np.dot(tr.translation_matrix([40,-100,0]),\
               tr.rotation_matrix(pi/2,[0,0,1,0]))
    rot2 = tr.rotation_matrix(pi / 2, [0, 0, 1, 0])
    tra3 = np.dot(tr.translation_matrix([1000,-1000,0]),\
               tr.rotation_matrix(-pi/2,[0,0,1,0]))
    rot3 = tr.rotation_matrix(-pi / 2, [0, 0, 1, 0])
    tra4 = np.dot(tr.translation_matrix([1020,920,0]),\
               tr.rotation_matrix(pi,[0,0,1,0]))
    rot4 = tr.rotation_matrix(pi, [0, 0, 1, 0])

    f = open(
        '/home/rallured/Dropbox/Arcus/Raytrace/FocalPlaneLayout/160412_Rays.pkl',
        'r')
    rays = pickle.load(f)
    f.close()

    rays2 = np.copy(rays)
    rays2 = [rays2[0],rays2[1],-rays2[2],rays2[3],\
             rays2[4],-rays2[5],rays2[6],\
             rays2[7],rays2[8],rays2[9]]
    rays3 = np.copy(rays)
    rays3 = [rays3[0],rays3[1],-rays3[2],rays3[3],\
             rays3[4],-rays3[5],rays3[6],\
             rays3[7],rays3[8],rays3[9]]
    rays4 = np.copy(rays)

    tran.itransform(rays2, 40, -100, 0, 0, 0, pi / 2)
    tran.itransform(rays3, 1000, 1000, 0, 0, 0, -pi / 2)
    tran.itransform(rays4, 1020, 920, 0, 0, 0, pi)

    #Plot to make sure
    plt.plot(rays[1], rays[2], '.')
    plt.plot(rays2[1], rays2[2], '.')
    plt.plot(rays3[1], rays3[2], '.')
    plt.plot(rays4[1], rays4[2], '.')

    #Transform everything up
    r = [rays, rays2, rays3, rays4]
    [tran.transform(ri, 0, 0, z, 0, 0, 0) for ri in r]
    [surf.flat(ri) for ri in r]
    plt.figure()
    [plt.plot(ri[1], ri[2], '.') for ri in r]
Exemplo n.º 2
0
def transformCoords_wMag(x,y,tx,ty,theta,mag):
    """Transforms coordinates x,y by magnifying x,y by a constant factor,
    then translating tx,ty and rotating theta about x
    Returns: x,y of new coords
    """
    mag_x,mag_y = x*mag,y*mag
    trans = tr.translation_matrix([tx,ty,0])
    rot = tr.rotation_matrix(theta,[0,0,1],point=[np.mean(x),np.mean(y),0])
    pos0 = np.array((mag_x,mag_y,np.repeat(0.,np.size(x)),np.repeat(1.,np.size(x))))
    pos1 = np.dot(trans,np.dot(rot,pos0))
    return pos1[0],pos1[1]
Exemplo n.º 3
0
def transformCoords(x,y,tx,ty,theta):
    """Transforms coordinates x,y by translating tx,ty
    and rotation theta about x
    Returns: x,y of new coords
    """
    trans = tr.translation_matrix([tx,ty,0])
    rot = tr.rotation_matrix(theta,[0,0,1],point=[np.mean(x),np.mean(y),0])
    pos0 = np.array((x,y,np.repeat(0.,np.size(x)),np.repeat(1.,np.size(x))))
    pos1 = np.dot(trans,np.dot(rot,pos0))

    return pos1[0],pos1[1]
Exemplo n.º 4
0
def matchArc(arc):
    """Take the raytraced arc, negate the dispersion direction, and
    compute the translation and rotation transformations to
    match the two spectra
    """
    #Create the second arc by negating the dispersion direction
    sh = np.shape(arc)
    arc = [arc[0], arc[1], np.zeros(sh[1]), np.ones(sh[1])]
    arc2 = np.copy(arc)
    arc2[1] = -arc2[1]

    #Transform second arc by pi/2
    r = tr.rotation_matrix(pi / 2, [0, 0, 1])
    arc2 = np.dot(r, arc2)

    #Get gradients
    dx = np.diff(arc2[0])[0]
    gr = np.gradient(arc2[1], dx)
    pdb.set_trace()

    #Apply rotation to match slopes
    angle = pi / 2 + np.arctan(gr[-1]) + np.arctan(gr[0])
    print angle
    r2 = tr.rotation_matrix(-angle, [0, 0, 1])
    arc3 = np.dot(r2, arc2)

    #Apply translation to match
    pdb.set_trace()
    ##    arc3[0] = arc3[0] + (arc[0][-1]-arc3[0][0])
    ##    arc3[1] = arc3[1] + (arc[1][-1]-arc3[1][0])
    t = tr.translation_matrix([(arc[0][-1]-arc3[0][0]),\
                               (arc[1][-1]-arc3[1][0]),\
                               0.])
    arc3 = np.dot(t, arc3)
    tra = np.dot(t, (np.dot(r2, r)))

    #Get even closer
    dist = np.sqrt((arc[0][0] - arc3[0][-1])**2 + (arc[1][0] - arc3[1][-1])**2)
    lever = np.sqrt((arc[0][0] - arc[0][-1])**2 + (arc[1][0] - arc[1][-1])**2)
    angle2 = dist / lever
    new = tr.rotation_matrix(angle2, [0, 0, 1],
                             point=[arc3[0][0], arc3[1][0], 0])
    tra2 = np.dot(new, tra)

    #Return transformation
    return tra2, angle, angle2, new, tra
Exemplo n.º 5
0
def makeLayout(arc, sepAngle):
    tra, angle = matchArc(arc)  #Get nominal transformation for paired petal
    tra2 = np.dot(tr.rotation_matrix(angle / 2, [0, 0, 1]), tra)
    tra1 = tr.rotation_matrix(angle / 2, [0, 0, 1])

    #Create the second arc by negating the dispersion direction
    sh = np.shape(arc)
    arc = [arc[0], arc[1], np.zeros(sh[1]), np.ones(sh[1])]
    arc2 = np.copy(arc)
    arc2[1] = -arc2[1]

    #Apply transformations
    arc2 = np.dot(tra2, arc2)
    arc1 = np.dot(tra1, arc)

    #Find center of second arc
    xc, yc = fit.circle(arc2[0], arc2[1], 0, 0)[0]

    #Rotate each petal about this point
    tra1 = np.dot(tr.rotation_matrix(sepAngle, [0, 0, 1], point=[xc, yc, 0]),
                  tra1)
    tra2 = np.dot(tr.rotation_matrix(-sepAngle, [0, 0, 1], point=[xc, yc, 0]),
                  tra2)

    #Add translation to second petal
    tra2 = np.dot(tr.translation_matrix([10 / np.sqrt(2), 10 / np.sqrt(2), 0]),
                  tra2)

    #Now plot the petals with the correct translations
    pet1 = plotPetal(arc[0], arc[1], tra=tra1, color='blue')
    pet2 = plotPetal(arc[0], -arc[1], tra=tra2, color='red')

    #Plot dashed line between corners closest to arcs
    x1, x2, y1, y2 = pet1[1][0][3], pet2[1][0][2], pet1[1][1][3], pet2[1][1][2]
    plt.plot([pet1[1][0][3], pet2[1][0][2]], [pet1[1][1][3], pet2[1][1][2]],
             'k--')