Esempio n. 1
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    def __init__(self,
                 s,
                 seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 pilotbundle_solution=-1,
                 pilotbundle_generation="complex",
                 pilotbundle_delta_angle=1 * degree,
                 pilotbundle_delta_size=0.1,
                 pilotbundle_sampling_points=3,
                 name="",
                 kind="aimy",
                 **kwargs):

        super(Aimy, self).__init__(name=name, kind=kind, **kwargs)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave
        self.pilotbundle_solution = pilotbundle_solution
        self.pilotbundle_generation = pilotbundle_generation
        self.pilotbundle_delta_angle = pilotbundle_delta_angle
        self.pilotbundle_delta_size = pilotbundle_delta_size
        self.pilotbundle_sampling_points = pilotbundle_sampling_points

        self.update(s, seq)
Esempio n. 2
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    def __init__(self,
                 s,
                 seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 pilotbundle_solution=-1,
                 pilotbundle_generation="complex",
                 pilotbundle_delta_angle=1 * degree,
                 pilotbundle_delta_size=0.1,
                 pilotbundle_sampling_points=3,
                 name=""):
        # TODO: reduce arguments by summarizing pilotbundle
        # parameters into class

        super(Aimy, self).__init__(name=name)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave
        self.pilotbundle_solution = pilotbundle_solution
        self.pilotbundle_generation = pilotbundle_generation
        self.pilotbundle_delta_angle = pilotbundle_delta_angle
        self.pilotbundle_delta_size = pilotbundle_delta_size
        self.pilotbundle_sampling_points = pilotbundle_sampling_points

        self.update(s, seq)
Esempio n. 3
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def bundles_step3(nrays=100, rpup=7.5, maxfield_deg=2.):
    """
    Creates an array of collimated RayBundle objects for step 3.
    """
    bundles = []
    fields_rad = np.array([0, 0.5*np.sqrt(2), 1]) * maxfield_deg * pi / 180.

    (px, py) = RectGrid().getGrid(nrays)

    for field in fields_rad:
        starty = -30 * np.tan(field)
        # TODO: this step explicitly sets the pupil
        # so the stop position is ignored. Better get Aimy to run ...

        o = np.vstack((rpup*px, rpup*py + starty, np.zeros_like(px)))
        k = np.zeros_like(o)
        k[1, :] = np.sin(field)
        k[2, :] = np.cos(field)
        E0 = np.cross(k, canonical_ex, axisa=0, axisb=0).T

        bundles += [RayBundle(o, k, E0, wave=Fline)]
        bundles += [RayBundle(o, k, E0, wave=dline)]
        bundles += [RayBundle(o, k, E0, wave=Cline)]

    return bundles
Esempio n. 4
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    def bundle(fpx, fpy, nrays=16, rpup=5):
        """
        Creates a RayBundle

        * o is the origin - this is ok
        * k is the wave vector, i.e. direction; needs to be normalized
        * E0 is the polarization vector

        """

        (px, py) = RectGrid().getGrid(nrays)

        #pts_on_first_surf = np.vstack((rpup*px, rpup*py, np.zeros_like(px)))
        pts_on_entrance_pupil = np.vstack(
            (rpup * px, rpup * py, np.ones(px.shape) * spd.psys.entpup))

        o = np.concatenate([ fpx * spd.psys.field_size_obj() * np.ones([1,len(px)]), \
                            -fpy * spd.psys.field_size_obj() * np.ones([1,len(px)]), \
                             spd.psys.obj_dist() * np.ones([1,len(px)]) ], axis=0 )

        k = (pts_on_entrance_pupil - o)

        normk = np.sqrt([np.sum(k * k, axis=0)])
        k = k / (np.matmul(np.ones([3, 1]), normk))

        E0 = np.cross(k, canonical_ex, axisa=0, axisb=0).T

        #wavelength is in [mm]
        return RayBundle(o, k, E0, wave=0.00058756), px, py
Esempio n. 5
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    def __init__(self,
                 s,
                 seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 name="",
                 kind="aimy",
                 **kwargs):

        super(Aimy, self).__init__(name=name, kind=kind, **kwargs)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave

        self.update(s, seq)
Esempio n. 6
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def bundle_step1(nrays=100, rpup=7.5):
    """
    Creates an on-axis collimated RayBundle for step 1.
    """

    (px, py) = RectGrid().getGrid(nrays)
    o = np.vstack((rpup*px, rpup*py, np.zeros_like(px)))
    k = np.zeros_like(o)
    k[2, :] = 1.  # 2.*math.pi/wavelength
    E0 = np.cross(k, canonical_ex, axisa=0, axisb=0).T

    return RayBundle(o, k, E0, wave=dline)
Esempio n. 7
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File: aim.py Progetto: joha2/pyrate
    def __init__(self, s, seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 pilotbundle_solution=-1,
                 pilotbundle_generation="complex",
                 pilotbundle_delta_angle=1*degree,
                 pilotbundle_delta_size=0.1,
                 pilotbundle_sampling_points=3,
                 name="", kind="aimy", **kwargs):

        super(Aimy, self).__init__(name=name, kind=kind, **kwargs)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave
        self.pilotbundle_solution = pilotbundle_solution
        self.pilotbundle_generation = pilotbundle_generation
        self.pilotbundle_delta_angle = pilotbundle_delta_angle
        self.pilotbundle_delta_size = pilotbundle_delta_size
        self.pilotbundle_sampling_points = pilotbundle_sampling_points

        self.update(s, seq)
Esempio n. 8
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class Aimy(BaseLogger):
    """
    Should take care about ray aiming (approximatively and real).
    Should generate aiming matrices and raybundles according to
    aiming specifications and field specifications.
    """
    def __init__(self,
                 s,
                 seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 pilotbundle_solution=-1,
                 pilotbundle_generation="complex",
                 pilotbundle_delta_angle=1 * degree,
                 pilotbundle_delta_size=0.1,
                 pilotbundle_sampling_points=3,
                 name=""):
        # TODO: reduce arguments by summarizing pilotbundle
        # parameters into class

        super(Aimy, self).__init__(name=name)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave
        self.pilotbundle_solution = pilotbundle_solution
        self.pilotbundle_generation = pilotbundle_generation
        self.pilotbundle_delta_angle = pilotbundle_delta_angle
        self.pilotbundle_delta_size = pilotbundle_delta_size
        self.pilotbundle_sampling_points = pilotbundle_sampling_points

        self.update(s, seq)

    def setKind(self):
        self.kind = "aimy"

    def extract_abcd(self, xyuv):
        """
        Extracts sub matrices from a general linear transfer matrix.
        """

        self.debug(str(xyuv.shape))

        a_xyuv = xyuv[0:2, 0:2]
        b_xyuv = xyuv[0:2, 2:4]  # take only real part of the k vectors
        c_xyuv = xyuv[2:4, 0:2]
        d_xyuv = xyuv[2:4, 2:4]

        return (a_xyuv, b_xyuv, c_xyuv, d_xyuv)

    def update(self, system, seq):
        """
        Update the matrices from object to stop and
        from stop to image for a specific system and a
        specific sequence.
        """

        obj_dx = self.pilotbundle_delta_size  # pilot bundle properties
        obj_dphi = self.pilotbundle_delta_angle  # pilot bundle properties

        first_element_seq_name = seq[0]
        (first_element_name, first_element_seq) = first_element_seq_name
        (objsurfname, _) = first_element_seq[0]

        self.objectsurface = system.elements[first_element_name].\
            surfaces[objsurfname]
        self.start_material = system.material_background
        # TODO: pilotray starts always in background (how about immersion?)
        # if mat is None: ....

        if self.pilotbundle_generation.lower() == "real":
            self.info("call real sampled pilotbundle")
            pilotbundles = build_pilotbundle(
                self.objectsurface,
                self.start_material, (obj_dx, obj_dx), (obj_dphi, obj_dphi),
                num_sampling_points=self.pilotbundle_sampling_points)
            # TODO: wavelength?
        elif self.pilotbundle_generation.lower() == "complex":
            self.info("call complex sampled pilotbundle")
            pilotbundles = build_pilotbundle_complex(
                self.objectsurface,
                self.start_material, (obj_dx, obj_dx), (obj_dphi, obj_dphi),
                num_sampling_points=self.pilotbundle_sampling_points)

        self.info("choose " + str(self.pilotbundle_solution) + " raybundle")
        self.pilotbundle = pilotbundles[self.pilotbundle_solution]
        # one of the last two

        (self.m_obj_stop,
         self.m_stop_img) =\
            system.extractXYUV(
                self.pilotbundle,
                seq,
                pilotbundle_generation=self.pilotbundle_generation)

        self.info("show linear matrices")
        self.info(
            "obj -> stop:\n" +
            np.array_str(self.m_obj_stop, precision=10, suppress_small=True))
        self.info(
            "stop -> img:\n" +
            np.array_str(self.m_stop_img, precision=10, suppress_small=True))

    def aim_core_angle_known(self, theta2d):
        """
        Calculates different start positions for the rays
        when direction vector is known.
        """

        (thetax, thetay) = theta2d

        rmx = rodrigues(thetax, [0, 1, 0])
        rmy = rodrigues(thetay, [1, 0, 0])
        rmfinal = np.dot(rmy, rmx)

        dpilot_global = self.pilotbundle.returnKtoD()[0, :, 0]
        kpilot_global = self.pilotbundle.k[0, :, 0]
        dpilot_object = self.objectsurface.rootcoordinatesystem.\
            returnGlobalToLocalDirections(dpilot_global)[:, np.newaxis]
        kpilot_object = self.objectsurface.rootcoordinatesystem.\
            returnGlobalToLocalDirections(kpilot_global)[:, np.newaxis]
        kpilot_object = np.repeat(kpilot_object, self.num_pupil_points, axis=1)
        dvec = np.dot(rmfinal, dpilot_object)

        kvec = returnDtoK(dvec)  # TODO: implement fake implementation
        dk_vec = kvec - kpilot_object
        dk_obj = dk_vec[0:2, :]

        (a_obj_stop, b_obj_stop, _, _) = self.extract_abcd(self.m_obj_stop)

        a_obj_stop_inv = np.linalg.inv(a_obj_stop)

        (xraster, yraster) = self.pupil_raster.getGrid(self.num_pupil_points)
        dr_stop = (np.vstack((xraster, yraster)) * self.stopsize)

        intermediate = np.dot(b_obj_stop, dk_obj)
        dr_obj = np.dot(a_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj)

    def aim_core_k_known(self, dk_obj):
        """
        Calculates different start position and angles when
        k-vector is known.
        """
        (a_obj_stop, b_obj_stop, _, _) = self.extract_abcd(self.m_obj_stop)

        a_obj_stop_inv = np.linalg.inv(a_obj_stop)

        (xraster, yraster) = self.pupil_raster.getGrid(self.num_pupil_points)
        (num_points, ) = xraster.shape

        dr_stop = (np.vstack((xraster, yraster)) * self.stopsize)

        dk_obj2 = np.repeat(dk_obj[:, np.newaxis], num_points, axis=1)

        intermediate = np.dot(b_obj_stop, dk_obj2)
        dr_obj = np.dot(a_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj2)

    def aim_core_r_known(self, delta_xy):
        """
        Calculates different start position and angles when
        position at stop is known.
        """

        (a_obj_stop, b_obj_stop, _, _) = self.extract_abcd(self.m_obj_stop)

        self.debug(str(b_obj_stop.shape))

        b_obj_stop_inv = np.linalg.inv(b_obj_stop)

        (xraster, yraster) = self.pupil_raster.getGrid(self.num_pupil_points)
        (num_points, ) = xraster.shape

        dr_stop = (np.vstack((xraster, yraster)) * self.stopsize)

        dr_obj = np.repeat(delta_xy[:, np.newaxis], num_points, axis=1)

        dk_obj = np.dot(b_obj_stop_inv, dr_stop - np.dot(a_obj_stop, dr_obj))

        # TODO: in general some direction vector is derived
        # TODO: this must been mapped to a k vector

        # TODO: what about anamorphic systems?

        return (dr_obj, dk_obj)

    def aim(self, delta_xy, fieldtype="angle"):
        """
        Generates bundles.
        """

        if fieldtype == "angle":
            (dr_obj, dk_obj) = self.aim_core_angle_known(delta_xy)
        elif fieldtype == "objectheight":
            (dr_obj, dk_obj) = self.aim_core_r_known(delta_xy)
        elif fieldtype == "kvector":
            # (dr_obj, dk_obj) = self.aim_core_k_known(delta_xy)
            raise NotImplementedError()
        else:
            raise NotImplementedError()

        (_, num_points) = np.shape(dr_obj)

        dr_obj3d = np.vstack((dr_obj, np.zeros(num_points)))
        dk_obj3d = np.vstack((dk_obj, np.zeros(num_points)))

        xp_objsurf = self.objectsurface.rootcoordinatesystem.\
            returnGlobalToLocalPoints(self.pilotbundle.x[0, :, 0])
        xp_objsurf = np.repeat(xp_objsurf[:, np.newaxis], num_points, axis=1)
        dx3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T,
                      dr_obj3d)
        xparabasal = xp_objsurf + dx3d

        kp_objsurf = self.objectsurface.rootcoordinatesystem.\
            returnGlobalToLocalDirections(self.pilotbundle.k[0, :, 0])
        kp_objsurf = np.repeat(kp_objsurf[:, np.newaxis], num_points, axis=1)
        dk3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T,
                      dk_obj3d)
        # FIXME: k coordinate system for which dispersion relation is respected
        # modified k in general violates dispersion relation

        kparabasal = kp_objsurf + dk3d
        efield_obj = self.pilotbundle.Efield[0, :, 0]
        efield_parabasal = np.repeat(efield_obj[:, np.newaxis],
                                     num_points,
                                     axis=1)

        # Eparabasal introduces anisotropy in aiming through
        # rotationally symmetric system since copy of Eparabasal (above)
        # is not in the right direction for the
        # dispersion relation (i.e. in isotropic media k perp E which is not
        # fulfilled); solution: use k, insert into propagator (svdmatrix),
        # calculate E by (u, sigma, v) = np.linalg.svd(propagator) where E is
        # some linearcombination of all u which belong to sigma = 0 values.
        # This is necessary to get the right ray direction also in isotropic
        # case
        # Outstanding problems:
        # * Only vacuum considered (attach to material!)
        #   [i.e. svdmatrix should come from material]
        # * Selection of E depends only on smallest eigenvalue
        #   (this is the "I don't care about polarization variant")
        #   => Later the user should choose the polarization in an stable
        #   reproducible way (i.e. sorting by scalar products)

        (_, nlength) = kparabasal.shape

        kronecker = np.repeat(np.identity(3)[np.newaxis, :, :],
                              nlength,
                              axis=0)

        svdmatrix = -kronecker * np.sum(kparabasal * kparabasal,
                                        axis=0)[:, np.newaxis, np.newaxis] +\
            np.einsum("i...,j...", kparabasal, kparabasal) +\
            kronecker  # epstensor

        # svdmatrix = -delta_ij (k*k) + k_i k_j + delta

        (unitary_arrays, singular_values, _) = np.linalg.svd(svdmatrix)

        smallest_absolute_values = np.argsort(np.abs(singular_values),
                                              axis=1).T[0]

        for i in range(nlength):
            efield_parabasal[:, i] =\
                unitary_arrays[i, :, smallest_absolute_values[i]]

        # Aimy: returns only linearized results which are not exact
        return RayBundle(xparabasal,
                         kparabasal,
                         efield_parabasal,
                         wave=self.wave)
Esempio n. 9
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class Aimy(BaseLogger):
    """
    Should take care about ray aiming (approximatively and real).
    Should generate aiming matrices and raybundles according to
    aiming specifications and field specifications.
    """
    def __init__(self,
                 s,
                 seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 pilotbundle_solution=-1,
                 pilotbundle_generation="complex",
                 pilotbundle_delta_angle=1 * degree,
                 pilotbundle_delta_size=0.1,
                 pilotbundle_sampling_points=3,
                 name=""):

        super(Aimy, self).__init__(name=name)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave
        self.pilotbundle_solution = pilotbundle_solution
        self.pilotbundle_generation = pilotbundle_generation
        self.pilotbundle_delta_angle = pilotbundle_delta_angle
        self.pilotbundle_delta_size = pilotbundle_delta_size
        self.pilotbundle_sampling_points = pilotbundle_sampling_points

        self.update(s, seq)

    def setKind(self):
        self.kind = "aimy"

    def extractABCD(self, xyuv):

        self.debug(str(xyuv.shape))

        Axyuv = xyuv[0:2, 0:2]
        Bxyuv = xyuv[0:2, 2:4]  # take only real part of the k vectors
        Cxyuv = xyuv[2:4, 0:2]
        Dxyuv = xyuv[2:4, 2:4]

        return (Axyuv, Bxyuv, Cxyuv, Dxyuv)

    def update(self, s, seq):

        obj_dx = self.pilotbundle_delta_size  # pilot bundle properties
        obj_dphi = self.pilotbundle_delta_angle  # pilot bundle properties

        first_element_seq_name = seq[0]
        (first_element_name, first_element_seq) = first_element_seq_name
        (objsurfname, objsurfoptions) = first_element_seq[0]

        self.objectsurface = s.elements[first_element_name].surfaces[
            objsurfname]
        self.start_material = s.material_background
        # TODO: pilotray starts always in background (how about immersion?)
        # if mat is None: ....

        if self.pilotbundle_generation.lower() == "real":
            self.info("call real sampled pilotbundle")
            pilotbundles = build_pilotbundle(
                self.objectsurface,
                self.start_material, (obj_dx, obj_dx), (obj_dphi, obj_dphi),
                num_sampling_points=self.pilotbundle_sampling_points)
            # TODO: wavelength?
        elif self.pilotbundle_generation.lower() == "complex":
            self.info("call complex sampled pilotbundle")
            pilotbundles = build_pilotbundle_complex(
                self.objectsurface,
                self.start_material, (obj_dx, obj_dx), (obj_dphi, obj_dphi),
                num_sampling_points=self.pilotbundle_sampling_points)

        self.info("choose " + str(self.pilotbundle_solution) + " raybundle")
        self.pilotbundle = pilotbundles[self.pilotbundle_solution]
        # one of the last two

        (self.m_obj_stop, self.m_stop_img) = s.extractXYUV(
            self.pilotbundle,
            seq,
            pilotbundle_generation=self.pilotbundle_generation)

        self.info("show linear matrices")
        self.info(
            "obj -> stop:\n" +
            np.array_str(self.m_obj_stop, precision=10, suppress_small=True))
        self.info(
            "stop -> img:\n" +
            np.array_str(self.m_stop_img, precision=10, suppress_small=True))

    def aim_core_angle_known(self, theta2d):
        """
        knows about xyuv matrices
        """

        (thetax, thetay) = theta2d

        rmx = rodrigues(thetax, [0, 1, 0])
        rmy = rodrigues(thetay, [1, 0, 0])
        rmfinal = np.dot(rmy, rmx)

        dpilot_global = self.pilotbundle.returnKtoD()[0, :, 0]
        kpilot_global = self.pilotbundle.k[0, :, 0]
        dpilot_object = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(
            dpilot_global)[:, np.newaxis]
        kpilot_object = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(
            kpilot_global)[:, np.newaxis]
        kpilot_object = np.repeat(kpilot_object, self.num_pupil_points, axis=1)
        d = np.dot(rmfinal, dpilot_object)

        k = returnDtoK(d)  # TODO: implement fake implementation
        dk = k - kpilot_object
        dk_obj = dk[0:2, :]

        (A_obj_stop, B_obj_stop, C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        A_obj_stop_inv = np.linalg.inv(A_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        dr_stop = (np.vstack((xp, yp)) * self.stopsize)

        intermediate = np.dot(B_obj_stop, dk_obj)
        dr_obj = np.dot(A_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj)

    def aim_core_k_known(self, dk_obj):
        """
        knows about xyuv matrices
        """
        (A_obj_stop, B_obj_stop, C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        A_obj_stop_inv = np.linalg.inv(A_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        (num_points, ) = xp.shape

        dr_stop = (np.vstack((xp, yp)) * self.stopsize)

        dk_obj2 = np.repeat(dk_obj[:, np.newaxis], num_points, axis=1)

        intermediate = np.dot(B_obj_stop, dk_obj2)
        dr_obj = np.dot(A_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj2)

    def aim_core_r_known(self, delta_xy):

        (A_obj_stop, B_obj_stop, C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        self.debug(str(B_obj_stop.shape))

        B_obj_stop_inv = np.linalg.inv(B_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        (num_points, ) = xp.shape

        dr_stop = (np.vstack((xp, yp)) * self.stopsize)

        dr_obj = np.repeat(delta_xy[:, np.newaxis], num_points, axis=1)

        dk_obj = np.dot(B_obj_stop_inv, dr_stop - np.dot(A_obj_stop, dr_obj))

        # TODO: in general some direction vector is derived
        # TODO: this must been mapped to a k vector

        # TODO: what about anamorphic systems?

        return (dr_obj, dk_obj)

    def aim(self, delta_xy, fieldtype="angle"):
        """
        Generates bundles.
        """

        if fieldtype == "angle":
            (dr_obj, dk_obj) = self.aim_core_angle_known(delta_xy)
        elif fieldtype == "objectheight":
            (dr_obj, dk_obj) = self.aim_core_r_known(delta_xy)
        elif fieldtype == "kvector":
            # (dr_obj, dk_obj) = self.aim_core_k_known(delta_xy)
            raise NotImplementedError()
        else:
            raise NotImplementedError()

        (dim, num_points) = np.shape(dr_obj)

        dr_obj3d = np.vstack((dr_obj, np.zeros(num_points)))
        dk_obj3d = np.vstack((dk_obj, np.zeros(num_points)))

        xp_objsurf = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalPoints(
            self.pilotbundle.x[0, :, 0])
        xp_objsurf = np.repeat(xp_objsurf[:, np.newaxis], num_points, axis=1)
        dx3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T,
                      dr_obj3d)
        xparabasal = xp_objsurf + dx3d

        kp_objsurf = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(
            self.pilotbundle.k[0, :, 0])
        kp_objsurf = np.repeat(kp_objsurf[:, np.newaxis], num_points, axis=1)
        dk3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T,
                      dk_obj3d)
        # FIXME: k coordinate system for which dispersion relation is respected
        # modified k in general violates dispersion relation

        kparabasal = kp_objsurf + dk3d
        self.debug("E pilotbundle")
        self.debug(str(self.pilotbundle.Efield.shape))
        self.debug(str(self.pilotbundle.Efield))
        E_obj = self.pilotbundle.Efield[0, :, 0]
        self.debug("E_obj")
        self.debug(str(E_obj))
        Eparabasal = np.repeat(E_obj[:, np.newaxis], num_points, axis=1)
        self.debug(str(np.sum(kparabasal * Eparabasal, axis=0)))

        # FIXME: Efield introduces anisotropy in aiming through
        # rotationally symmetric system
        # since copy of Eparabasal is not in the right direction for the
        # dispersion relation (i.e. in isotropic media k perp E which is not
        # fulfilled); solution: use k, insert into propagator, calculate
        # E by (u, sigma, v) = np.linalg.svd(propagator) where E is
        # linearcombination of all u which belong to sigma = 0 values.
        # This is necessary to get the right ray direction also in isotropic
        # case

        # Aimy: returns only linearized results which are not exact
        return RayBundle(xparabasal, kparabasal, Eparabasal, wave=self.wave)
Esempio n. 10
0
class Aimy(BaseLogger):
    """
    Should take care about ray aiming (approximatively and real).
    Should generate aiming matrices and raybundles according to
    aiming specifications and field specifications.
    """
    def __init__(self,
                 s,
                 seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 name="",
                 kind="aimy",
                 **kwargs):

        super(Aimy, self).__init__(name=name, kind=kind, **kwargs)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave

        self.update(s, seq)

    def extractABCD(self, xyuv):

        self.info(str(xyuv.shape))

        Axyuv = xyuv[0:2, 0:2]
        Bxyuv = xyuv[0:2, 2:4]  # take only real part of the k vectors
        Cxyuv = xyuv[2:4, 0:2]
        Dxyuv = xyuv[2:4, 2:4]

        return (Axyuv, Bxyuv, Cxyuv, Dxyuv)

    def update(self, s, seq):

        obj_dx = 0.1  # pilot bundle properties
        obj_dphi = 1. * degree  # pilot bundle properties

        first_element_seq_name = seq[0]
        (first_element_name, first_element_seq) = first_element_seq_name
        (objsurfname, objsurfoptions) = first_element_seq[0]

        self.objectsurface = s.elements[first_element_name].surfaces[
            objsurfname]
        self.start_material = s.material_background
        # TODO: pilotray starts always in background (how about immersion?)
        # if mat is None: ....

        #build_pilotbundle(
        #    self.objectsurface,
        #    self.start_material,
        #    (obj_dx, obj_dx),
        #    (obj_dphi, obj_dphi),
        #    num_sampling_points=3) # TODO: wavelength?

        self.info("call complex sampled pilotbundle")
        pilotbundles = build_pilotbundle_complex(self.objectsurface,
                                                 self.start_material,
                                                 (obj_dx, obj_dx),
                                                 (obj_dphi, obj_dphi),
                                                 num_sampling_points=3)

        self.info("choose last raybundle (hard coded)")
        self.pilotbundle = pilotbundles[-1]
        # TODO: one solution selected hard coded

        (self.m_obj_stop,
         self.m_stop_img) = s.extractXYUV(self.pilotbundle, seq)

        self.info("show linear matrices")
        self.info(
            np.array_str(self.m_obj_stop, precision=5, suppress_small=True))
        self.info(
            np.array_str(self.m_stop_img, precision=5, suppress_small=True))

    def aim_core_angle_known(self, theta2d):
        """
        knows about xyuv matrices
        """

        (thetax, thetay) = theta2d

        rmx = rodrigues(thetax, [0, 1, 0])
        rmy = rodrigues(thetay, [1, 0, 0])
        rmfinal = np.dot(rmy, rmx)

        dpilot_global = self.pilotbundle.returnKtoD()[0, :, 0]
        kpilot_global = self.pilotbundle.k[0, :, 0]
        dpilot_object = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(
            dpilot_global)[:, np.newaxis]
        kpilot_object = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(
            kpilot_global)[:, np.newaxis]
        kpilot_object = np.repeat(kpilot_object, self.num_pupil_points, axis=1)
        d = np.dot(rmfinal, dpilot_object)

        k = returnDtoK(d)  # TODO: implement fake implementation
        dk = k - kpilot_object
        dk_obj = dk[0:2, :]

        (A_obj_stop, B_obj_stop, C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        A_obj_stop_inv = np.linalg.inv(A_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        dr_stop = (np.vstack((xp, yp)) * self.stopsize)

        intermediate = np.dot(B_obj_stop, dk_obj)
        dr_obj = np.dot(A_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj)

    def aim_core_k_known(self, dk_obj):
        """
        knows about xyuv matrices
        """
        (A_obj_stop, B_obj_stop, C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        A_obj_stop_inv = np.linalg.inv(A_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        dr_stop = (np.vstack((xp, yp)) * self.stopsize)

        dk_obj2 = np.repeat(dk_obj[:, np.newaxis],
                            self.num_pupil_points,
                            axis=1)

        intermediate = np.dot(B_obj_stop, dk_obj2)
        dr_obj = np.dot(A_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj2)

    def aim_core_r_known(self, delta_xy):

        (A_obj_stop, B_obj_stop, C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        self.info(str(B_obj_stop.shape))

        B_obj_stop_inv = np.linalg.inv(B_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        dr_stop = (np.vstack((xp, yp)) * self.stopsize)

        dr_obj = np.repeat(delta_xy[:, np.newaxis],
                           self.num_pupil_points,
                           axis=1)
        dk_obj = np.dot(B_obj_stop_inv, dr_stop - np.dot(A_obj_stop, dr_obj))

        # TODO: in general some direction vector is derived
        # TODO: this must been mapped to a k vector

        # TODO: what about anamorphic systems?

        return (dr_obj, dk_obj)

    def aim(self, delta_xy, fieldtype="angle"):
        """
        Generates bundles.
        """

        if fieldtype == "angle":
            (dr_obj, dk_obj) = self.aim_core_angle_known(delta_xy)
        elif fieldtype == "objectheight":
            (dr_obj, dk_obj) = self.aim_core_r_known(delta_xy)
        elif fieldtype == "kvector":
            # (dr_obj, dk_obj) = self.aim_core_k_known(delta_xy)
            raise NotImplementedError()
        else:
            raise NotImplementedError()

        (dim, num_points) = np.shape(dr_obj)

        dr_obj3d = np.vstack((dr_obj, np.zeros(num_points)))
        dk_obj3d = np.vstack((dk_obj, np.zeros(num_points)))

        xp_objsurf = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalPoints(
            self.pilotbundle.x[0, :, 0])
        xp_objsurf = np.repeat(xp_objsurf[:, np.newaxis], num_points, axis=1)
        dx3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T,
                      dr_obj3d)
        xparabasal = xp_objsurf + dx3d

        kp_objsurf = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(
            self.pilotbundle.k[0, :, 0])
        kp_objsurf = np.repeat(kp_objsurf[:, np.newaxis], num_points, axis=1)
        dk3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T,
                      dk_obj3d)
        # TODO: k coordinate system for which dispersion relation is respected

        kparabasal = kp_objsurf + dk3d
        E_obj = self.pilotbundle.Efield[0, :, 0]
        Eparabasal = np.repeat(E_obj[:, np.newaxis], num_points, axis=1)

        # Aimy: returns only linearized results which are not exact
        return RayBundle(xparabasal, kparabasal, Eparabasal, wave=self.wave)
Esempio n. 11
0
File: aim.py Progetto: joha2/pyrate
class Aimy(BaseLogger):

    """
    Should take care about ray aiming (approximatively and real).
    Should generate aiming matrices and raybundles according to
    aiming specifications and field specifications.
    """

    def __init__(self, s, seq,
                 wave=standard_wavelength,
                 num_pupil_points=100,
                 stopsize=10,
                 pilotbundle_solution=-1,
                 pilotbundle_generation="complex",
                 pilotbundle_delta_angle=1*degree,
                 pilotbundle_delta_size=0.1,
                 pilotbundle_sampling_points=3,
                 name="", kind="aimy", **kwargs):

        super(Aimy, self).__init__(name=name, kind=kind, **kwargs)
        self.field_raster = RectGrid()
        self.pupil_raster = RectGrid()
        self.stopsize = stopsize
        self.num_pupil_points = num_pupil_points
        self.wave = wave
        self.pilotbundle_solution = pilotbundle_solution
        self.pilotbundle_generation = pilotbundle_generation
        self.pilotbundle_delta_angle = pilotbundle_delta_angle
        self.pilotbundle_delta_size = pilotbundle_delta_size
        self.pilotbundle_sampling_points = pilotbundle_sampling_points

        self.update(s, seq)

    def extractABCD(self, xyuv):

        self.debug(str(xyuv.shape))

        Axyuv = xyuv[0:2, 0:2]
        Bxyuv = xyuv[0:2, 2:4]  # take only real part of the k vectors
        Cxyuv = xyuv[2:4, 0:2]
        Dxyuv = xyuv[2:4, 2:4]

        return (Axyuv, Bxyuv, Cxyuv, Dxyuv)

    def update(self, s, seq):

        obj_dx = self.pilotbundle_delta_size  # pilot bundle properties
        obj_dphi = self.pilotbundle_delta_angle  # pilot bundle properties

        first_element_seq_name = seq[0]
        (first_element_name, first_element_seq) = first_element_seq_name
        (objsurfname, objsurfoptions) = first_element_seq[0]

        self.objectsurface = s.elements[first_element_name].surfaces[objsurfname]
        self.start_material = s.material_background
        # TODO: pilotray starts always in background (how about immersion?)
        # if mat is None: ....

        if self.pilotbundle_generation.lower() == "real":
            self.info("call real sampled pilotbundle")
            pilotbundles = build_pilotbundle(
                self.objectsurface,
                self.start_material,
                (obj_dx, obj_dx),
                (obj_dphi, obj_dphi),
                num_sampling_points=self.pilotbundle_sampling_points)
                # TODO: wavelength?
        elif self.pilotbundle_generation.lower() == "complex":
            self.info("call complex sampled pilotbundle")
            pilotbundles = build_pilotbundle_complex(
                self.objectsurface,
                self.start_material,
                (obj_dx, obj_dx),
                (obj_dphi, obj_dphi),
                num_sampling_points=self.pilotbundle_sampling_points)

        self.info("choose " + str(self.pilotbundle_solution) + " raybundle")
        self.pilotbundle = pilotbundles[self.pilotbundle_solution]
        # one of the last two

        (self.m_obj_stop, self.m_stop_img) = s.extractXYUV(self.pilotbundle,
                                                           seq,
                                                           pilotbundle_generation=self.pilotbundle_generation)

        self.info("show linear matrices")
        self.info("obj -> stop:\n" + np.array_str(self.m_obj_stop, precision=10, suppress_small=True))
        self.info("stop -> img:\n" + np.array_str(self.m_stop_img, precision=10, suppress_small=True))


    def aim_core_angle_known(self, theta2d):
        """
        knows about xyuv matrices
        """

        (thetax, thetay) = theta2d

        rmx = rodrigues(thetax, [0, 1, 0])
        rmy = rodrigues(thetay, [1, 0, 0])
        rmfinal = np.dot(rmy, rmx)

        dpilot_global = self.pilotbundle.returnKtoD()[0, :, 0]
        kpilot_global = self.pilotbundle.k[0, :, 0]
        dpilot_object = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(dpilot_global)[:, np.newaxis]
        kpilot_object = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(kpilot_global)[:, np.newaxis]
        kpilot_object = np.repeat(kpilot_object, self.num_pupil_points, axis=1)
        d = np.dot(rmfinal, dpilot_object)

        k = returnDtoK(d) # TODO: implement fake implementation
        dk = k - kpilot_object
        dk_obj = dk[0:2, :]

        (A_obj_stop, B_obj_stop, C_obj_stop, D_obj_stop) = self.extractABCD(self.m_obj_stop)

        A_obj_stop_inv = np.linalg.inv(A_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        dr_stop = (np.vstack((xp, yp))*self.stopsize)

        intermediate = np.dot(B_obj_stop, dk_obj)
        dr_obj = np.dot(A_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj)


    def aim_core_k_known(self, dk_obj):
        """
        knows about xyuv matrices
        """
        (A_obj_stop,
         B_obj_stop,
         C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        A_obj_stop_inv = np.linalg.inv(A_obj_stop)


        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        (num_points,) = xp.shape

        dr_stop = (np.vstack((xp, yp))*self.stopsize)

        dk_obj2 = np.repeat(dk_obj[:, np.newaxis], num_points, axis=1)

        intermediate = np.dot(B_obj_stop, dk_obj2)
        dr_obj = np.dot(A_obj_stop_inv, dr_stop - intermediate)

        return (dr_obj, dk_obj2)

    def aim_core_r_known(self, delta_xy):

        (A_obj_stop,
         B_obj_stop,
         C_obj_stop,
         D_obj_stop) = self.extractABCD(self.m_obj_stop)

        self.debug(str(B_obj_stop.shape))

        B_obj_stop_inv = np.linalg.inv(B_obj_stop)

        (xp, yp) = self.pupil_raster.getGrid(self.num_pupil_points)
        (num_points,) = xp.shape

        dr_stop = (np.vstack((xp, yp))*self.stopsize)

        dr_obj = np.repeat(delta_xy[:, np.newaxis], num_points, axis=1)

        dk_obj = np.dot(B_obj_stop_inv, dr_stop - np.dot(A_obj_stop, dr_obj))

        # TODO: in general some direction vector is derived
        # TODO: this must been mapped to a k vector

        # TODO: what about anamorphic systems?

        return (dr_obj, dk_obj)

    def aim(self, delta_xy, fieldtype="angle"):
        """
        Generates bundles.
        """

        if fieldtype == "angle":
            (dr_obj, dk_obj) = self.aim_core_angle_known(delta_xy)
        elif fieldtype == "objectheight":
            (dr_obj, dk_obj) = self.aim_core_r_known(delta_xy)
        elif fieldtype == "kvector":
            # (dr_obj, dk_obj) = self.aim_core_k_known(delta_xy)
            raise NotImplementedError()
        else:
            raise NotImplementedError()

        (dim, num_points) = np.shape(dr_obj)

        dr_obj3d = np.vstack((dr_obj, np.zeros(num_points)))
        dk_obj3d = np.vstack((dk_obj, np.zeros(num_points)))

        xp_objsurf = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalPoints(self.pilotbundle.x[0, :, 0])
        xp_objsurf = np.repeat(xp_objsurf[:, np.newaxis], num_points, axis=1)
        dx3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T, dr_obj3d)
        xparabasal = xp_objsurf + dx3d

        kp_objsurf = self.objectsurface.rootcoordinatesystem.returnGlobalToLocalDirections(self.pilotbundle.k[0, :, 0])
        kp_objsurf = np.repeat(kp_objsurf[:, np.newaxis], num_points, axis=1)
        dk3d = np.dot(self.objectsurface.rootcoordinatesystem.localbasis.T, dk_obj3d)
        # FIXME: k coordinate system for which dispersion relation is respected
        # modified k in general violates dispersion relation

        kparabasal = kp_objsurf + dk3d
        self.debug("E pilotbundle")
        self.debug(str(self.pilotbundle.Efield.shape))
        self.debug(str(self.pilotbundle.Efield))
        E_obj = self.pilotbundle.Efield[0, :, 0]
        self.debug("E_obj")
        self.debug(str(E_obj))
        Eparabasal = np.repeat(E_obj[:, np.newaxis], num_points, axis=1)
        self.debug(str(np.sum(kparabasal*Eparabasal, axis=0)))

        # FIXME: Efield introduces anisotropy in aiming through
        # rotationally symmetric system
        # since copy of Eparabasal is not in the right direction for the
        # dispersion relation (i.e. in isotropic media k perp E which is not
        # fulfilled); solution: use k, insert into propagator, calculate
        # E by (u, sigma, v) = np.linalg.svd(propagator) where E is
        # linearcombination of all u which belong to sigma = 0 values.
        # This is necessary to get the right ray direction also in isotropic
        # case

        # Aimy: returns only linearized results which are not exact
        return RayBundle(xparabasal, kparabasal, Eparabasal, wave=self.wave)