Exemplo n.º 1
0
def get_reflectance(paf1="air",
                    paf2="",
                    wl_um=[],
                    um_range=[0.3, 0.6],
                    a_deg=[],
                    a_range=(0, 90),
                    n_steps=100,
                    interpolate_kind="default",
                    verbose=0):
    """
    Import a file from RefractiveIndex.info and output the refractive index for the desired wavelengths. 
    
    
    INPUT:
    paf (str): path and filename
    wl_um (ndarray): wavelength axis, in micrometer
    um_range (list with 2 elements): if wl_um is not given, it will plot a range.
    n_steps (int): number of steps to plot the range.
    ax (plt axis): if False, it will make a new figure
    interpolate_kind (str): for tabulated data, the type of interpolation
    
    """
    if len(wl_um) == 0:
        wl_um = numpy.linspace(um_range[0], um_range[1], num=n_steps)

    # material 1
    if paf1 in ["", "air"]:
        n1 = numpy.ones(len(wl_um))
    elif type(paf1) == float:
        n1 = numpy.ones(len(wl_um)) * paf1
    else:
        temp = paf1.split("/")
        DEBUG.verbose("Importing data for %s by %s" %
                      (temp[-2], temp[-1][:-4]),
                      verbose_level=1)
        db_record = RIRY.import_refractive_index(paf=paf1, verbose=verbose)
        DEBUG.verbose("  Imported data", verbose_level=0)
        n1 = ri_for_wavelengths(db_record, wl_um, verbose=verbose)

    # material 1
    if paf2 in ["", "air"]:
        n2 = numpy.ones(len(wl_um))
    elif type(paf2) == float:
        n2 = numpy.ones(len(wl_um)) * paf2
    else:
        temp = paf2.split("/")
        DEBUG.verbose("Importing data for %s by %s" %
                      (temp[-2], temp[-1][:-4]),
                      verbose_level=1)
        db_record = RIRY.import_refractive_index(paf=paf2, verbose=verbose)
        DEBUG.verbose("  Imported data", verbose_level=0)
        n2 = ri_for_wavelengths(db_record, wl_um, verbose=verbose)

    a_deg, Rs, Rp = EQ.reflectance(n1,
                                   n2,
                                   a_deg=[],
                                   a_range=a_range,
                                   n_steps=-1)

    return wl_um, a_deg, Rs, Rp
Exemplo n.º 2
0
 def test_a_deg_simple(self):
     """
     Basic test using a_deg
     """
     n = 10
     n1 = numpy.ones(n)
     n2 = numpy.linspace(1.1, 1.5, num=n)
     a_deg = [0, 10]
     a_deg, Rs, Rp = EQ.reflectance(n1, n2, a_deg=a_deg)
     self.assertTrue(numpy.shape(a_deg) == (2, ))
     self.assertTrue(numpy.shape(Rs) == (2, 10))
     self.assertTrue(numpy.shape(Rp) == (2, 10))
Exemplo n.º 3
0
 def test_list_inputs(self):
     """
     use integer inputs for a_deg, n1 and n2
     """
     n1 = [1, 1, 1, 1, 1]
     n2 = [1.1, 1.2, 1.3, 1.4, 1.5]
     a_deg = [0, 10]
     a_deg, Rs, Rp = EQ.reflectance(n1, n2, a_deg=a_deg)
     #         print(numpy.count_nonzero(numpy.isnan(Rs)))
     self.assertTrue(numpy.shape(a_deg) == (2, ))
     self.assertTrue(numpy.shape(Rs) == (2, 5))
     self.assertTrue(numpy.shape(Rp) == (2, 5))
Exemplo n.º 4
0
 def test_int_inputs(self):
     """
     use integer inputs for a_deg, n1 and n2
     """
     n1 = 0
     n2 = 1.5
     a_deg = 0
     a_deg, Rs, Rp = EQ.reflectance(n1, n2, a_deg=a_deg)
     #         print(numpy.count_nonzero(numpy.isnan(Rs)))
     self.assertTrue(numpy.shape(a_deg) == (1, ))
     self.assertTrue(numpy.shape(Rs) == (1, 1))
     self.assertTrue(numpy.shape(Rp) == (1, 1))
Exemplo n.º 5
0
 def test_arange_simple(self):
     """
     Basic test using a_range
     """
     n = 10
     n1 = numpy.ones(n)
     n2 = numpy.linspace(1.1, 1.5, num=n)
     a_range = (0, 90)
     a_deg, Rs, Rp = EQ.reflectance(n1, n2, a_range=a_range)
     self.assertTrue(numpy.shape(a_deg) == (91, ))
     self.assertTrue(numpy.shape(Rs) == (91, 10))
     self.assertTrue(numpy.shape(Rp) == (91, 10))
     self.assertTrue(numpy.count_nonzero(numpy.isnan(Rs)) == 0)
Exemplo n.º 6
0
 def test_arange_critical_angle_2(self):
     """
     Check if the critical angle is handled properly (it should give NaN)
     """
     n = 10
     n1 = numpy.ones(n)
     n2 = numpy.linspace(0.5, 1.5, num=n)
     a_range = (0, 90)
     a_deg, Rs, Rp = EQ.reflectance(n1, n2, a_range=a_range)
     #         print(numpy.count_nonzero(numpy.isnan(Rs)))
     self.assertTrue(numpy.shape(a_deg) == (91, ))
     self.assertTrue(numpy.shape(Rs) == (91, 10))
     self.assertTrue(numpy.shape(Rp) == (91, 10))
     self.assertTrue(numpy.count_nonzero(numpy.isnan(Rs)) == 211)
Exemplo n.º 7
0
 def test_arange_no_critical_angle(self):
     """
     Check if the critical angle is handled properly (it should give NaN)
     This tests for between 0 and 40 degrees, none should be NaN       
     """
     n = 10
     n2 = numpy.ones(n)
     n1 = numpy.linspace(1.1, 1.5, num=n)
     a_range = (0, 40)
     a_deg, Rs, Rp = EQ.reflectance(n1, n2, a_range=a_range)
     #         print(numpy.count_nonzero(numpy.isnan(Rs)))
     self.assertTrue(numpy.shape(a_deg) == (41, ))
     self.assertTrue(numpy.shape(Rs) == (41, 10))
     self.assertTrue(numpy.shape(Rp) == (41, 10))
     self.assertTrue(numpy.count_nonzero(numpy.isnan(Rs)) == 0)
Exemplo n.º 8
0
 def test_correct(self):
     A = [0, 1, 1, 0]
     t = numpy.arange(5)
     res = EQ.rb_cos(A, t)
     check = numpy.ones(5)
     self.assertTrue(numpy.all(res == check))
Exemplo n.º 9
0
 def test_t_as_list(self):
     A = [0, 1]
     t = [0, 0, 0, 0, 0]
     res = EQ.quadratic(A, t)
     check = numpy.array([0, 0, 0, 0, 0])
     self.assertTrue(numpy.all(res == check))
Exemplo n.º 10
0
 def test_A_as_int(self):
     A = 0
     t = numpy.arange(5)
     res = EQ.quadratic(A, t)
     check = numpy.array([0, 0, 0, 0, 0])
     self.assertTrue(numpy.all(res == check))
Exemplo n.º 11
0
 def test_correct(self):
     A = [0, 1]
     t = numpy.arange(5)
     res = EQ.quadratic(A, t)
     check = numpy.array([0, 1, 2, 3, 4])
     self.assertTrue(numpy.all(res == check))
Exemplo n.º 12
0
def gaussian_beam_diameter(position,
                           intensity,
                           ax=False,
                           label="",
                           flag_interpolate=True,
                           interpolate_kind="linear",
                           interpolate_step=-1,
                           position_unit="mm",
                           center_plot_on_zero=True):
    """
    Calculate the diameter of a gaussian beam.
    
    INPUT:
    - position (list, ndarray): list with positions
    - intensity (list, ndarray): list with intensities corresponding to the positions
    - ax (axis object, or False): if False, the result will not be plotted
    - label (string): label used in the fit
    - flag_interpolate (BOOL, True): if the positions are not equidistant, then it has to be interpolated. 
    - interpolate_kind
    - interpolate_step (number): stepsize of the interpolation. If the value is negative, that is the number of steps that will be used. If the value is 0, 100 steps will be used. 
    - position_unit (string, mm): unit of the position
    - center_plot_on_zero (BOOL, True): Subtract the mean position from the position. 
    
    
    """

    print("--- %s ---" % label)

    if position[1] < position[0]:
        position = position[::-1]
        intensity = intensity[::-1]

    if flag_interpolate:
        if interpolate_step == 0:
            x = numpy.linspace(position[0], position[-1], num=100)
        elif interpolate_step < 0:
            x = numpy.linspace(position[0],
                               position[-1],
                               num=-interpolate_step)
        else:
            x = numpy.arange(position[0], position[-1], interpolate_step)
        f = interp1d(position, intensity, kind=interpolate_kind)
        y = f(x)
    else:
        x = numpy.copy(position)
        y = numpy.copy(intensity)

    dx = x[1] - x[0]

    mean_guess = x[numpy.argmax(y)]
    A = [1, mean_guess, 1, 1]
    A_final = MATH.fit(x, y, EQ.rb_gaussian, A)

    if center_plot_on_zero:
        print("Mean: %2.3f %s (shifted in plot)" % (A_final[1], position_unit))
    else:
        print("Mean: %2.3f %s" % (A_final[1], position_unit))

    y_fit = EQ.rb_gaussian(A_final, x)

    if center_plot_on_zero:
        x -= A_final[1]
        A_final[1] = 0

    temp = numpy.where(y_fit > (0.135 * numpy.amax(y_fit)))[0]
    print("1/e2: %2.3f %s" % (x[temp[-1]] - x[temp[0]], position_unit))

    temp = numpy.where(y_fit > (0.5 * numpy.amax(y_fit)))[0]
    print("FWHM: %2.3f %s" % (x[temp[-1]] - x[temp[0]], position_unit))

    y_fit -= numpy.amin(y_fit)
    y /= numpy.amax(y_fit)
    y_fit /= numpy.amax(y_fit)

    s = label
    ax.plot(x, y, label=s)
    s = label + " fit"
    ax.plot(x, y_fit, label=s)

    ax.set_xlabel("Position (%s, shifted)" % position_unit)
    ax.set_ylabel("Intensity (norm)")

    ax.legend()

    print("Stepsize positions: %2.3f" % dx)

    print("Fitting parameters:")
    print("    Sigma:", A_final[0])
    print("    Mean:", A_final[1])
    print("    Y-offset:", A_final[2])
    print("    Scale:", A_final[3])
Exemplo n.º 13
0
def gvd_for_wavelengths(db_record,
                        wl_um,
                        interpolate_kind="default",
                        verbose=0):
    """
    Calculate the GVD for wavelengths wl_um. The GVD is calculated as the second derivative of the refractive index with respect to the wavelength. The input is the data from refractiveindex.info and comes as one of 9 equations (not all of them are implemented) or as a table of values. 
    
    For the equations, the second derivatives were calculated using WolframAlpha. 
    """

    if "type" not in db_record:
        raise KeyError(
            "gvd_for_wavelengths: The database record does not have a key 'type'."
        )

    wl_um = CF.make_numpy_ndarray(wl_um)

    error_string = "GVD is not implemented for "

    # check the range
    if "formula" in db_record["type"]:
        if wl_um[0] < db_record["range"][0]:
            raise ValueError(
                "Error, wavelength %1.2f micron is too low! It should be above %1.2f micron."
                % (wl_um[0], db_record["range"][0]))
        elif wl_um[-1] > db_record["range"][1]:
            raise ValueError(
                "Error, wavelength %1.2f micron is too high! It should be below %1.2f micron."
                % (wl_um[-1], db_record["range"][-1]))

    if "tabulated" in db_record["type"]:
        raise NotImplementedError(
            "GVD can't be calculated for tabulated data.")

    if db_record["type"] == "formula 1":
        DEBUG.verbose(
            "  Using formula 1 to calculate group velocity dispersion",
            verbose_level=1)
        gvd = EQ.gvd_formula_1(wl_um, db_record["coefficients"])
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 2":
        """
        Formula 2 is the same as formula 1, but some given coefficients are already squared. The square root of these coefficients is taken and the GVD equation for formula 1 is used. 
        """
        DEBUG.verbose(
            "  Using formula 2 to calculate group velocity dispersion",
            verbose_level=1)
        s = numpy.copy(db_record["coefficients"])
        for i in range(len(s)):
            if i > 0 and i % 2 == 0:
                s[i] = numpy.sqrt(s[i])
        gvd = EQ.gvd_formula_1(wl_um, s)
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 3":
        DEBUG.verbose(
            "  Using formula 3 to calculate group velocity dispersion",
            verbose_level=1)
        gvd = EQ.gvd_formula_3(wl_um, db_record["coefficients"])
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 4":
        DEBUG.verbose(
            "  Using formula 4 to calculate group velocity dispersion",
            verbose_level=1)
        gvd = EQ.gvd_formula_4(wl_um, db_record["coefficients"])
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 5":
        DEBUG.verbose(
            "  Using formula 5 to calculate group velocity dispersion",
            verbose_level=1)
        gvd = EQ.gvd_formula_5(wl_um, db_record["coefficients"])
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 6":
        DEBUG.verbose(
            "  Using formula 6 to calculate group velocity dispersion",
            verbose_level=1)
        gvd = EQ.gvd_formula_6(wl_um, db_record["coefficients"])
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 7":
        DEBUG.verbose(
            "  Using formula 7 to calculate group velocity dispersion",
            verbose_level=1)
        gvd = EQ.gvd_formula_7(wl_um, db_record["coefficients"])
        gvd = (1e21 * gvd * wl_um**3) / (2 * numpy.pi * (CONST.c_ms)**2)

    elif db_record["type"] == "formula 8":
        raise NotImplementedError(error_string + "formula 8")

    elif db_record["type"] == "formula 9":
        raise NotImplementedError(error_string + "formula 9")

    else:
        raise ValueError(
            "The type of data in the database record is unknown (usually formula 1-9). Type here is %s."
            % db_record["type"])

    return wl_um, gvd