def plot_detuning(x, y, x_err, y_err, labels, x_min=None, x_max=None, y_min=None, y_max=None,
                  odr_plot=linear_odr_plot, output=None, show=True):
    """ Plot amplitude detuning.

    Args:
        x: Action data.
        y: Tune data.
        x_err: Action error.
        y_err: Tune error.
        x_min: Lower action range to plot.
        x_max: Upper action range to plot.
        y_min: Lower tune range to plot.
        y_max: Upper tune range to plot.
        odr_plot: function to add a odr fitting line to axes (e.g. see linear_odr_plot)
        labels: Dict of labels to use for the data ("line"), the x-axis ("x") and the y-axis ("y")
        output: Output file of the plot.
        show: Show the plot in window.

    Returns:
        Plotted Figure
    """
    ps.set_style("standard",
                 {u"lines.marker": u"o",
                  u"lines.linestyle": u"",
                  u'figure.figsize': [9.5, 4],
                  }
                 )

    fig = plt.figure()
    ax = fig.add_subplot(111)

    x_min = 0 if x_min is None else x_min
    x_max = max(x + x_err)*1.01 if x_max is None else x_max

    offset = odr_plot(ax, x, y, x_err, y_err, lim=[x_min, x_max])
    ax.errorbar(x, y-offset, xerr=x_err, yerr=y_err, label=labels.get("line", None))

    default_labels = const.get_paired_lables("{}", "{}")
    ax.set_xlabel(labels.get("x", default_labels[0]))
    ax.set_ylabel(labels.get("y", default_labels[1]))

    ax.set_xlim(left=x_min, right=x_max)
    ax.set_ylim(bottom=y_min, top=y_max)

    plt.legend(loc='lower left', bbox_to_anchor=(0.0, 1.01), ncol=2,)
    fig.tight_layout()

    if output:
        fig.savefig(output)
        ps.set_name(os.path.basename(output))

    if show:
        plt.draw()

    return fig
Ejemplo n.º 2
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    def plot_rdts(self, rdt_names=None, apply_fun=np.abs, combined=True):
        """ Plot Resonance Driving Terms """
        LOG.debug("Plotting Resonance Driving Terms")
        rdts = self.get_rdts(rdt_names)
        is_s = regex_in(r'\AS$', rdts.columns)
        rdts = rdts.dropna()
        rdts.loc[:, ~is_s] = rdts.loc[:, ~is_s].applymap(apply_fun)
        pstyle.set_style(self._plot_options.style, self._plot_options.manual)

        if combined:
            ax = rdts.plot(x='S')
            ax.set_title('Resonance Driving Terms')
            pstyle.small_title(ax)
            pstyle.set_name('Resonance Driving Terms', ax)
            pstyle.set_yaxis_label(apply_fun.__name__, 'F_{{jklm}}', ax)
            self._nice_axes(ax)
        else:
            for rdt in rdts.loc[:, ~is_s]:
                ax = rdts.plot(x='S', y=rdt)
                ax.set_title('Resonance Driving Term ' + rdt)
                pstyle.small_title(ax)
                pstyle.set_name('Resonance Driving Term ' + rdt, ax)
                pstyle.set_yaxis_label(apply_fun.__name__, rdt, ax)
                self._nice_axes(ax)
Ejemplo n.º 3
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    def plot_phase_advance(self, combined=True):
        """ Plots the phase advances between two consecutive elements

        Args:
            combined (bool): If 'True' plots x and y into the same axes.
        """
        raise NotImplementedError(
            'Plotting Phase Advance Shift is not Implemented yet.')
        #TODO: reimplement the phase-advance shift calculations (if needed??)
        LOG.debug("Plotting Phase Advance")
        tw = self.mad_twiss
        pa = self._phase_advance
        dpa = self._dphase_advance
        phase_advx = np.append(pa['X'].iloc[0, -1] + tw.Q1,
                               pa['X'].values.diagonal(offset=-1))
        dphase_advx = np.append(dpa['X'].iloc[0, -1],
                                dpa['X'].values.diagonal(offset=-1))
        phase_advy = np.append(pa['Y'].iloc[0, -1] + tw.Q2,
                               pa['Y'].values.diagonal(offset=-1))
        dphase_advy = np.append(dpa['Y'].iloc[0, -1],
                                dpa['Y'].values.diagonal(offset=-1))
        phase_adv = tw[["S"]].copy()
        phase_adv['MUX'] = np.cumsum(phase_advx + dphase_advx) % 1 - .5
        phase_adv['MUY'] = np.cumsum(phase_advy + dphase_advy) % 1 - .5

        title = 'Phase'
        pstyle.set_style(self._plot_options.style, self._plot_options.manual)

        if combined:
            ax_dx = phase_adv.plot(x='S')
            ax_dx.set_title(title)
            pstyle.small_title(ax_dx)
            pstyle.set_name(title, ax_dx)
            pstyle.set_yaxis_label('phase', 'x,y', ax_dx, delta=False)
            ax_dy = ax_dx
        else:
            ax_dx = phase_adv.plot(x='S', y='MUX')
            ax_dx.set_title(title)
            pstyle.small_title(ax_dx)
            pstyle.set_name(title, ax_dx)
            pstyle.set_yaxis_label('phase', 'x', ax_dx, delta=False)

            ax_dy = phase_adv.plot(x='S', y='MUY')
            ax_dy.set_title(title)
            pstyle.small_title(ax_dy)
            pstyle.set_name(title, ax_dy)
            pstyle.set_yaxis_label('phase', 'y', ax_dy, delta=False)

        for ax in (ax_dx, ax_dy):
            self._nice_axes(ax)
            ax.legend()
Ejemplo n.º 4
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    def plot_chromatic_beating(self, combined=True):
        """ Plot the Chromatic Beating

        Available after calc_chromatic_beating

        Args:
            combined (bool): If 'True' plots x and y into the same axes.
        """
        LOG.debug("Plotting Chromatic Beating")
        chrom_beat = self.get_chromatic_beating().dropna()
        title = 'Chromatic Beating'
        pstyle.set_style(self._plot_options.style, self._plot_options.manual)

        if combined:
            ax_dx = chrom_beat.plot(x='S')
            ax_dx.set_title(title)
            pstyle.small_title(ax_dx)
            pstyle.set_name(title, ax_dx)
            pstyle.set_yaxis_label('dbetabeat', 'x,y', ax_dx)
            ax_dy = ax_dx
        else:
            ax_dx = chrom_beat.plot(x='S', y='DBEATX')
            ax_dx.set_title(title)
            pstyle.small_title(ax_dx)
            pstyle.set_name(title, ax_dx)
            pstyle.set_yaxis_label('dbetabeat', 'x', ax_dx)

            ax_dy = chrom_beat.plot(x='S', y='DBEATY')
            ax_dy.set_title(title)
            pstyle.small_title(ax_dy)
            pstyle.set_name(title, ax_dy)
            pstyle.set_yaxis_label('dbetabeat', 'y', ax_dy)

        for ax in (ax_dx, ax_dy):
            self._nice_axes(ax)
            ax.legend()
Ejemplo n.º 5
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def plot_bbq_data(bbq_df,
                  interval=None,
                  xmin=None,
                  xmax=None,
                  ymin=None,
                  ymax=None,
                  output=None,
                  show=True,
                  two_plots=False):
    """ Plot BBQ data.

    Args:
        bbq_df: BBQ Dataframe with moving average columns
        interval: start and end time of used interval, will be marked with red bars
        xmin: Lower x limit (time)
        xmax: Upper x limit (time)
        ymin: Lower y limit (tune)
        ymax: Upper y limit (tune)
        output: Path to the output file
        show: Shows plot if `True`
        two_plots: Plots each tune in it's own axes if `True`

    Returns:
        Plotted figure

    """
    LOG.debug("Plotting BBQ data.")

    ps.set_style("standard", {u"lines.marker": u""})

    fig = plt.figure()

    if two_plots:
        gs = gridspec.GridSpec(2, 1, height_ratios=[1, 1])
        ax = [fig.add_subplot(gs[1]), fig.add_subplot(gs[0])]
    else:
        gs = gridspec.GridSpec(1, 1, height_ratios=[1])
        ax = fig.add_subplot(gs[0])
        ax = [ax, ax]

    bbq_df.index = [
        datetime.datetime.fromtimestamp(time, tz=TIMEZONE)
        for time in bbq_df.index
    ]

    for idx, plane in enumerate(PLANES):
        color = ps.get_mpl_color(idx)
        mask = bbq_df[COL_IN_MAV(plane)]

        with suppress_warnings(UserWarning):  # caused by _nolegend_
            bbq_df.plot(y=COL_BBQ(plane),
                        ax=ax[idx],
                        color=color,
                        alpha=.2,
                        label="_nolegend_")
        bbq_df.loc[mask, :].plot(y=COL_BBQ(plane),
                                 ax=ax[idx],
                                 color=color,
                                 alpha=.4,
                                 label="$Q_{:s}$ filtered".format(
                                     plane.lower()))
        bbq_df.plot(y=COL_MAV(plane),
                    ax=ax[idx],
                    color=color,
                    label="$Q_{:s}$ moving av.".format(plane.lower()))

        if ymin is None and two_plots:
            ax[idx].set_ylim(bottom=min(bbq_df.loc[mask, COL_BBQ(plane)]))

        if ymax is None and two_plots:
            ax[idx].set_ylim(top=max(bbq_df.loc[mask, COL_BBQ(plane)]))

    # things to add/do only once if there is only one plot
    for idx in range(1 + two_plots):
        if interval:
            ax[idx].axvline(x=interval[0], color="red")
            ax[idx].axvline(x=interval[1], color="red")

        ax[idx].set_ylabel('Tune')
        ax[idx].set_ylim(bottom=ymin, top=ymax)
        ax[idx].yaxis.set_major_formatter(FormatStrFormatter('%.5f'))

        ax[idx].set_xlim(left=xmin, right=xmax)
        ax[idx].set_xlabel('Time')
        ax[idx].xaxis.set_major_formatter(mdates.DateFormatter('%H:%M:%S'))

        # don't show labels on upper plot (if two plots)
        if idx:
            # use the visibility to allow cursor x-position to be shown
            ax[idx].tick_params(labelbottom=False)
            ax[idx].xaxis.get_label().set_visible(False)

    plt.tight_layout()

    if output:
        fig.savefig(output)
        ps.set_name(os.path.basename(output))

    if show:
        plt.draw()

    return fig