Example #1
0
def transverse_trace_space_rms_emittance(x,
                                         px,
                                         py=None,
                                         pz=None,
                                         w=None,
                                         disp_corrected=False,
                                         corr_order=1):
    """Calculate the trasnverse trace-space RMS emittance of the
    particle distribution in a given plane.

    Parameters
    ----------
    x : array
        Contains the transverse position of the particles in one of the
        transverse planes in units of meters

    px : array
        Contains the transverse momentum of the beam particles in the same
        plane as x in non-dimmensional units (beta*gamma)

    py : array
        Contains the transverse momentum of the beam particles in the opposite
        plane as as x in non-dimmensional units (beta*gamma). Necessary if
        disp_corrected=True.

    pz : array
        Contains the longitudinal momentum of the beam particles in
        non-dimmensional units (beta*gamma). Necessary if disp_corrected=True.

    w : array or single value
        Statistical weight of the particles.

    disp_corrected : bool
        Whether ot not to correct for dispersion contributions.

    corr_order : int
        Highest order up to which dispersion effects should be corrected.

    Returns
    -------
    A float with the emmitance value in units of m * rad
    """
    if len(x) > 1:
        xp = px / pz
        if disp_corrected:
            # remove x-gamma correlation
            gamma = np.sqrt(1 + np.square(px) + np.square(py) + np.square(pz))
            gamma_avg = np.average(gamma, weights=w)
            dgamma = (gamma - gamma_avg) / gamma_avg
            x = remove_correlation(dgamma, x, w, corr_order)
            # remove xp-gamma correlation
            xp = remove_correlation(dgamma, xp, w, corr_order)
        cov_x = np.cov(x, xp, aweights=np.abs(w))
        em_x = np.sqrt(np.linalg.det(cov_x.astype(np.float32, copy=False)))
    else:
        em_x = 0
    return em_x
Example #2
0
def normalized_transverse_rms_slice_emittance(z,
                                              x,
                                              px,
                                              py=None,
                                              pz=None,
                                              w=None,
                                              disp_corrected=False,
                                              corr_order=1,
                                              n_slices=10,
                                              len_slice=None):
    """Calculate the normalized transverse RMS slice emittance of the particle
    distribution in a given plane.

    Parameters
    ----------
    z : array
        Contains the longitudinal position of the particles in units of meters

    x : array
        Contains the transverse position of the particles in one of the
        transverse planes in units of meters

    px : array
        Contains the transverse momentum of the beam particles in the same
        plane as x in non-dimmensional units (beta*gamma)

    py : array
        Contains the transverse momentum of the beam particles in the opposite
        plane as as x in non-dimmensional units (beta*gamma). Necessary if
        disp_corrected=True.

    pz : array
        Contains the longitudinal momentum of the beam particles in
        non-dimmensional units (beta*gamma). Necessary if disp_corrected=True.

    w : array or single value
        Statistical weight of the particles.

    disp_corrected : bool
        Whether ot not to correct for dispersion contributions.

    corr_order : int
        Highest order up to which dispersion effects should be corrected.

    n_slices : array
        Number of longitudinal slices in which to divite the particle
        distribution. Not used if len_slice is specified.

    len_slice : array
        Length of the longitudinal slices. If not None, replaces n_slices.

    Returns
    -------
    A tuple containing:
    - An array with the emmitance value in each slice in units of m * rad.
    - An array with the statistical weight of each slice.
    - An array with the slice edges.
    - A float with the weigthed average of the slice values.
    """
    if disp_corrected:
        # remove x-gamma correlation
        gamma = np.sqrt(1 + np.square(px) + np.square(py) + np.square(pz))
        gamma_avg = np.average(gamma, weights=w)
        dgamma = (gamma - gamma_avg) / gamma_avg
        x = remove_correlation(dgamma, x, w, corr_order)
    slice_lims, n_slices = create_beam_slices(z, n_slices, len_slice)
    slice_em = np.zeros(n_slices)
    slice_weight = np.zeros(n_slices)
    for i in np.arange(0, n_slices):
        a = slice_lims[i]
        b = slice_lims[i + 1]
        slice_particle_filter = (z > a) & (z <= b)
        if slice_particle_filter.any():
            x_slice = x[slice_particle_filter]
            px_slice = px[slice_particle_filter]
            # if py is not None:
            #    py_slice = py[slice_particle_filter]
            # else:
            #    py_slice=None
            # if pz is not None:
            #    pz_slice = pz[slice_particle_filter]
            # else:
            #    pz_slice=None
            if hasattr(w, '__iter__'):
                w_slice = w[slice_particle_filter]
            else:
                w_slice = w
            slice_em[i] = normalized_transverse_rms_emittance(x_slice,
                                                              px_slice,
                                                              w=w_slice)
            slice_weight[i] = np.sum(w_slice)
    slice_avg = calculate_slice_average(slice_em, slice_weight)
    return slice_em, slice_weight, slice_lims, slice_avg
Example #3
0
def twiss_parameters(x,
                     px,
                     pz,
                     py=None,
                     w=None,
                     emitt='tr',
                     disp_corrected=False,
                     corr_order=1):
    """Calculate the alpha and beta functions of the beam in a certain
    transverse plane

    Parameters
    ----------
    x : array
        Contains the transverse position of the particles in one of the
        transverse planes in units of meters

    px : array
        Contains the transverse momentum of the beam particles in the same
        plane as x in non-dimmensional units (beta*gamma)

    py : array
        Contains the transverse momentum of the beam particles in the opposite
        plane as as x in non-dimmensional units (beta*gamma). Necessary if
        disp_corrected=True or emitt='ph'.

    pz : array
        Contains the longitudinal momentum of the beam particles in
        non-dimmensional units (beta*gamma).

    w : array or single value
        Statistical weight of the particles.

    emitt : str
        Determines which emittance to use to calculate the Twiss parameters.
        Possible values are 'tr' for trace-space emittance and 'ph' for
        phase-space emittance

    disp_corrected : bool
        Whether ot not to correct for dispersion contributions.

    corr_order : int
        Highest order up to which dispersion effects should be corrected.

    Returns
    -------
    A tuple with the value of the alpha, beta [m] and gamma [m^-1] functions
    """
    if emitt == 'ph':
        em_x = normalized_transverse_rms_emittance(x, px, py, pz, w,
                                                   disp_corrected, corr_order)
        gamma = np.sqrt(1 + np.square(px) + np.square(py) + np.square(pz))
        gamma_avg = np.average(gamma, weights=w)
        x_avg = np.average(x, weights=w)
        px_avg = np.average(px, weights=w)
        # center x and x
        x = x - x_avg
        px = px - px_avg
        if disp_corrected:
            # remove x-gamma correlation
            dgamma = (gamma - gamma_avg) / gamma_avg
            x = remove_correlation(dgamma, x, w, corr_order)
        b_x = np.average(x**2, weights=w) * gamma_avg / em_x
        a_x = -np.average(x * px, weights=w) / em_x
    elif emitt == 'tr':
        em_x = transverse_trace_space_rms_emittance(x, px, py, pz, w,
                                                    disp_corrected, corr_order)
        xp = px / pz
        # center x and xp
        x_avg = np.average(x, weights=w)
        xp_avg = np.average(xp, weights=w)
        x = x - x_avg
        xp = xp - xp_avg
        if disp_corrected:
            # remove x-gamma correlation
            gamma = np.sqrt(1 + np.square(px) + np.square(py) + np.square(pz))
            gamma_avg = np.average(gamma, weights=w)
            dgamma = (gamma - gamma_avg) / gamma_avg
            x = remove_correlation(dgamma, x, w, corr_order)
            # remove xp-gamma correlation
            xp = remove_correlation(dgamma, xp, w, corr_order)
        b_x = np.average(x**2, weights=w) / em_x
        a_x = -np.average(x * xp, weights=w) / em_x
    g_x = (1 + a_x**2) / b_x
    return (a_x, b_x, g_x)