m-thesis-introduction/simulations/airshower_beacon_simulation/ca_period_from_shower.py

#!/usr/bin/env python3
# vim: fdm=indent ts=4

"""
Find the best integer multiple to shift
antennas to be able to resolve
"""

import h5py
from itertools import combinations, zip_longest, product
import matplotlib.pyplot as plt
import numpy as np
from os import path
import os
from scipy.interpolate import interp1d

from earsim import REvent
from atmocal import AtmoCal
import aa_generate_beacon as beacon
import lib
from lib import rit

def find_best_sample_shifts_summing_at_location(test_loc, antennas, allowed_sample_shifts, dt=None, sample_shift_first_trace=0, plot_iteration_with_shifted_trace=None, fig_dir=None, fig_distinguish=None):
    """
    Find the best sample_shift for each antenna by summing the antenna traces
    and seeing how to get the best alignment.
    """
    a_ = []
    t_ = []
    t_min = 1e9
    t_max = -1e9
    a_maxima = []
    N_ant = len(antennas)

    if dt is None:
        dt = antennas[0].t_AxB[1] - antennas[0].t_AxB[0]

    if not hasattr(plot_iteration_with_shifted_trace, '__len__'):
        if plot_iteration_with_shifted_trace:
            plot_iteration_with_shifted_trace = [ plot_iteration_with_shifted_trace ]
        else:
            plot_iteration_with_shifted_trace = []

    # propagate to test location
    for i, ant in enumerate(antennas):
        aloc = [ant.x, ant.y, ant.z]
        delta, dist = atm.light_travel_time(test_loc, aloc)
        delta = delta*1e9

        t__ = np.subtract(ant.t_AxB, delta)
        t_.append(t__)
        a_.append(ant.E_AxB)
        a_maxima.append(max(ant.E_AxB))

        if t__[0] < t_min:
            t_min = t__[0]
        if t__[-1] > t_max:
            t_max = t__[-1]

    # sort traces with descending maxima
    sort_idx = np.argsort(a_maxima)[::-1]
    t_ = [ t_[i] for i in sort_idx ]
    a_ = [ a_[i] for i in sort_idx ]

    # Interpolate and find best sample shift
    max_neg_shift = 0 #np.min(allowed_sample_shifts) * dt
    max_pos_shift = 0 #np.max(allowed_sample_shifts) * dt

    t_sum = np.arange(t_min+max_neg_shift, t_max+max_pos_shift, dt)
    a_sum = np.zeros(len(t_sum))

    best_sample_shifts = np.zeros( (len(antennas)) ,dtype=int)
    for i, (t_r, E_) in enumerate(zip(t_, a_)):
        f = interp1d(t_r, E_, assume_sorted=True, bounds_error=False, fill_value=0)
        a_int = f(t_sum)

        if i == 0:
            a_sum += a_int
            best_sample_shifts[i] = sample_shift_first_trace
            continue

        # init figure
        if i in plot_iteration_with_shifted_trace:
            fig, ax = plt.subplots()
            ax.set_title("Traces at ({:.1f},{:.1f},{:.1f}) i={i}/{tot}".format(*test_loc, i=i, tot=N_ant))
            ax.set_xlabel("Time [ns]")
            ax.set_ylabel("Amplitude")
            ax.plot(t_sum, a_sum)

        shift_maxima = np.zeros( len(allowed_sample_shifts) )
        for j, shift in enumerate(allowed_sample_shifts):
            augmented_a = np.roll(a_int, shift)

            shift_maxima[j] = np.max(augmented_a + a_sum)

            if i in plot_iteration_with_shifted_trace:
                ax.plot(t_sum, augmented_a, alpha=0.7, ls='dashed', label=f'{shift}')

        # transform maximum into best_sample_shift
        best_idx = np.argmax(shift_maxima)

        best_sample_shifts[i] = allowed_sample_shifts[best_idx]
        best_augmented_a = np.roll(a_int, best_sample_shifts[i])
        a_sum += best_augmented_a

        # cleanup figure
        if i in plot_iteration_with_shifted_trace:
            if True: # plot best k again
                ax.plot(t_sum, augmented_a, alpha=0.8, label=f'best k={best_sample_shifts[i]}', lw=2)

            ax.legend( ncol=5 )
            if fig_dir:
                fig.tight_layout()
                fname = path.join(fig_dir, path.basename(__file__) + f'.{fig_distinguish}i{i}' + '.loc{:.1f}-{:.1f}-{:.1f}'.format(*test_loc))
                if True:
                    old_xlim = ax.get_xlim()

                    if True: # zoomed on part without peak of this trace
                        wx = 100
                        x = max(t_r) - wx
                        ax.set_xlim(x-wx, x+wx)
                        fig.savefig(fname + ".zoomed.beacon.pdf")

                    if True: # zoomed on peak of this trace
                        x = t_r[np.argmax(E_)]
                        wx = 50 + (max(best_sample_shifts) - min(best_sample_shifts))*dt
                        ax.set_xlim(x-wx, x+wx)
                        fig.savefig(fname + ".zoomed.peak.pdf")

                    ax.set_xlim(*old_xlim)

                fig.savefig(fname + ".pdf")
            plt.close(fig)

    # sort by antenna (undo sorting by maximum)
    undo_sort_idx = np.argsort(sort_idx)

    best_sample_shifts = best_sample_shifts[undo_sort_idx]

    # Return ks
    return best_sample_shifts, np.max(a_sum)

if __name__ == "__main__":
    import sys
    import os
    import matplotlib
    if os.name == 'posix' and "DISPLAY" not in os.environ:
        matplotlib.use('Agg')

    atm = AtmoCal()

    from scriptlib import MyArgumentParser
    parser = MyArgumentParser(default_fig_dir="./figures/periods_from_shower_figures/")
    args = parser.parse_args()

    fname = "ZH_airshower/mysim.sry"

    fig_dir = args.fig_dir
    fig_subdir = path.join(fig_dir, 'shifts/')
    show_plots = args.show_plots

    allowed_ks = [ -2, -1, 0, 1, 2]
    Xref = 400

    N_runs = 3
    remove_beacon_from_trace = True

    ####
    fname_dir = path.dirname(fname)
    antennas_fname = path.join(fname_dir, beacon.antennas_fname)
    time_diffs_fname = 'time_diffs.hdf5' if not True else antennas_fname

    ## This is a file indicating whether the k-finding algorithm was
    ## stopped early. This happens when the ks do not change between
    ## two consecutive iterations.
    run_break_fname = path.join(fname_dir, 'ca_breaked_run')

    # create fig_dir
    if fig_dir:
        os.makedirs(fig_dir, exist_ok=True)
        if fig_subdir:
            os.makedirs(fig_subdir, exist_ok=True)

    # Read in antennas from file
    _, tx, antennas = beacon.read_beacon_hdf5(antennas_fname)
    # Read original REvent
    ev = REvent(fname)
    # .. patch in our antennas
    ev.antennas = antennas

    # For now only implement using one freq_name
    freq_names = antennas[0].beacon_info.keys()
    if len(freq_names) > 1:
        raise NotImplementedError

    freq_name = next(iter(freq_names))
    f_beacon = ev.antennas[0].beacon_info[freq_name]['freq']

    # Prepare polarisation and passbands
    rit.set_pol_and_bp(ev, low=0.03, high=0.08)

    # Remove time due to true phase
    # and optionally remove the beacon
    for i, ant in enumerate(ev.antennas):
        clock_phase = ant.beacon_info[freq_name]['sigma_phase_mean']
        clock_phase_time = clock_phase/(2*np.pi*f_beacon)

        ev.antennas[i].orig_t = ev.antennas[i].t_AxB
        ev.antennas[i].t_AxB += clock_phase_time

        if remove_beacon_from_trace:
            meas_phase = ant.beacon_info[freq_name]['phase']
            f = ant.beacon_info[freq_name]['freq']
            ampl = ant.beacon_info[freq_name]['amplitude']
            calc_beacon = lib.sine_beacon(f, ev.antennas[i].t_AxB, amplitude=ampl, phase=meas_phase-clock_phase)

            ev.antennas[i].E_AxB -= calc_beacon

            # Make a figure of the manipulated traces
            if i == 2:
                orig_beacon_amplifier = ampl/max(ant.beacon)

                fig, ax = plt.subplots()
                ax.set_title(f"Signal and Beacon traces Antenna {i}")
                ax.set_xlabel("Time [ns]")
                ax.set_ylabel("Amplitude [$\\mu V/m$]")

                ax.plot(ant.t_AxB, ant.E_AxB + calc_beacon, alpha=0.6, ls='dashed', label='Signal') # calc_beacon was already removed
                ax.plot(ant.t_AxB, calc_beacon,             alpha=0.6, ls='dashed', label='Calc Beacon')
                ax.plot(ant.t_AxB, ant.E_AxB,               alpha=0.6,              label="Signal - Calc Beacon")

                ax.legend()

                # save
                if fig_dir:
                    fig.tight_layout()
                    if True: # zoom
                        old_xlim = ax.get_xlim()

                        wx, x = 100, 0#ant.t_AxB[np.argmax(ant.E_AxB)]
                        ax.set_xlim(x-wx, x+wx)

                        fig.savefig(path.join(fig_dir, __file__+f'.traces.zoomed.A{i}.pdf'))

                        ax.set_xlim(*old_xlim)

                    fig.savefig(path.join(fig_dir, __file__+f'.traces.A{i}.pdf'))

    if show_plots:
        plt.show()


    # determine allowable ks per location
    dt = ev.antennas[0].t_AxB[1] - ev.antennas[0].t_AxB[0]
    allowed_sample_shifts = np.rint(allowed_ks/f_beacon /dt).astype(int)
    print("Checking:", allowed_ks, ": shifts :", allowed_sample_shifts)

    ##
    ## Determine grid positions
    ##

    dXref = atm.distance_to_slant_depth(np.deg2rad(ev.zenith),Xref,0)
    scale2d = dXref*np.tan(np.deg2rad(2.))
    scale4d = dXref*np.tan(np.deg2rad(4.))

    if not True: #quicky
        x_coarse = np.linspace(-scale2d, scale2d, 4)
        y_coarse = np.linspace(-scale2d, scale2d, 4)

        x_fine = x_coarse/4
        y_fine = y_coarse/4
    else: # long
        N_runs = 5
        x_coarse = np.linspace(-scale4d, scale4d, 40)
        y_coarse = np.linspace(-scale4d, scale4d, 40)

        x_fine = np.linspace(-scale2d, scale2d, 40)
        y_fine = np.linspace(-scale2d, scale2d, 40)

    ## Remove run_break_fname if it exists
    try:
        os.remove(run_break_fname)
    except OSError:
        pass

    ##
    ## Do calculations on the grid
    ##

    for r in range(N_runs):
        # Setup Plane grid to test
        xoff, yoff = 0,0
        if r == 0:
            x = x_coarse
            y = y_coarse
        else:
            # zooming in
            old_ks_per_loc = ks_per_loc[best_idx]
            xoff = xx[best_idx]
            yoff = yy[best_idx]
            if r == 1:
                x = x_fine
                y = y_fine
            else:
                x /= 4
                y /= 4

        print(f"Testing grid run {r} centered on {xoff}, {yoff}")

        ks_per_loc = np.zeros( (len(x)*len(y), len(ev.antennas)) , dtype=int)
        maxima_per_loc = np.zeros( (len(x)*len(y)))

        ## Check each location on grid
        xx = []
        yy = []
        N_loc = len(maxima_per_loc)

        for i, (x_, y_) in enumerate(product(x,y)):
            tmp_fig_subdir = None
            if i % 10 ==0:
                print(f"Testing location {i} out of {N_loc}")
                tmp_fig_subdir = fig_subdir

            test_loc = (x_+xoff)* ev.uAxB + (y_+yoff)*ev.uAxAxB + dXref *ev.uA
            xx.append(x_+xoff)
            yy.append(y_+yoff)

            # Find best k for each antenna
            shifts, maximum = find_best_sample_shifts_summing_at_location(test_loc, ev.antennas, allowed_sample_shifts, dt=dt, fig_dir=tmp_fig_subdir, plot_iteration_with_shifted_trace=[ 5, len(ev.antennas)-1], fig_distinguish=f"run{r}.")

            # Translate sample shifts back into period multiple k
            ks = np.rint(shifts*f_beacon*dt)

            ks_per_loc[i] = ks
            maxima_per_loc[i] = maximum

        xx = np.array(xx)
        yy = np.array(yy)
        locs = list(zip(xx, yy))

        ## Save maxima to file
        np.savetxt(path.join(fig_dir, path.basename(__file__)+f'.maxima.run{r}.txt'), np.column_stack((locs, maxima_per_loc, ks_per_loc)) )

        if True: #plot maximum at test locations
            fig, axs = plt.subplots()
            axs.set_title(f"Optimizing signal strength varying k per antenna,\n Grid Run {r}")
            axs.set_ylabel("vxvxB [km]")
            axs.set_xlabel("  vxB [km]")
            axs.set_aspect('equal', 'datalim')
            sc = axs.scatter(xx/1e3, yy/1e3, c=maxima_per_loc, cmap='Spectral_r', alpha=0.6)
            fig.colorbar(sc, ax=axs, label='Max Amplitude [$\\mu V/m$]')

            # indicate maximum value
            idx = np.argmax(maxima_per_loc)
            axs.plot(xx[idx]/1e3, yy[idx]/1e3, 'bx', ms=30)

            if fig_dir:
                old_xlims = axs.get_xlim()
                old_ylims = axs.get_ylim()
                fig.tight_layout()
                fig.savefig(path.join(fig_dir, path.basename(__file__)+f'.maxima.run{r}.pdf'))
                if False:
                    axs.plot(tx.x/1e3, tx.y/1e3, marker='X', color='k')
                    fig.tight_layout()
                    fig.savefig(path.join(fig_dir, path.basename(__file__)+f'.maxima.run{r}.with_tx.pdf'))
                axs.set_xlim(*old_xlims)
                axs.set_ylim(*old_ylims)
                fig.tight_layout()

        ##
        best_idx = np.argmax(maxima_per_loc)
        best_k = ks_per_loc[best_idx]

        print("Max at location: ", locs[best_idx])
        print('Best k:', best_k)

        ## Save best ks to file
        np.savetxt(path.join(fig_dir, path.basename(__file__)+f'.bestk.run{r}.txt'), best_k )

        ## Do a small reconstruction of the shower for best ks
        if True:
            print("Reconstructing for best k")

            for j in range(2):
                power_reconstruction = j==1

                if power_reconstruction: # Do power reconstruction
                    # backup antenna times
                    backup_times = [ ant.t_AxB for ant in ev.antennas ]

                    # incorporate ks into timing
                    for i, ant in enumerate(ev.antennas):
                        ev.antennas[i].t_AxB = ant.t_AxB - best_k[i] * 1/f_beacon

                    xx, yy, p, ___ = rit.shower_plane_slice(ev, X=Xref, Nx=len(x), Ny=len(y), wx=x[-1]-x[0], wy=y[-1]-y[0], xoff=xoff, yoff=yoff, zgr=0)

                    # repair antenna times
                    for i, backup_t_AxB in enumerate(backup_times):
                        ev.antennas[i].t_AxB = backup_t_AxB
                else: # get maximum amplitude at each location
                    maxima = np.empty( len(locs) )
                    for i, loc in enumerate(locs):
                        test_loc = loc[0]* ev.uAxB + loc[1]*ev.uAxAxB + dXref *ev.uA
                        P, t_, a_, a_sum, t_sum = rit.pow_and_time(test_loc, ev, dt=dt)
                        maxima[i] = np.max(a_sum)

                fig, axs = plt.subplots()
                axs.set_title(f"Shower slice for best k, Grid Run {r}")
                axs.set_ylabel("vxvxB [km]")
                axs.set_xlabel("  vxB [km]")
                axs.set_aspect('equal', 'datalim')
                if power_reconstruction:
                    sc = axs.scatter(xx/1e3, yy/1e3, c=p, cmap='Spectral_r', alpha=0.6)
                    fig.colorbar(sc, ax=axs, label='Power')
                else:
                    sc = axs.scatter(xx/1e3, yy/1e3, c=maxima, cmap='Spectral_r', alpha=0.6)
                    fig.colorbar(sc, ax=axs, label='Max Amplitude [$\\mu V/m$]')


                if fig_dir:
                    if power_reconstruction:
                        fname_extra = "power"
                    else:
                        fname_extra = "max_amp"

                    fig.tight_layout()
                    fig.savefig(path.join(fig_dir, path.basename(__file__)+f'.reconstruction.run{r}.{fname_extra}.pdf'))

        # Abort if no improvement
        if ( r!= 0 and (old_ks_per_loc == ks_per_loc[best_idx]).all() ):
            print(f"No changes from previous grid, breaking at iteration {r} out of {N_runs}")

            try:
                with open(run_break_fname, 'wt', encoding='utf-8') as fp:
                    fp.write(f"Breaked at grid iteration {r} out of {N_runs}")
            except:
                pass

            break

    old_ks_per_loc = ks_per_loc[best_idx]

    # Save best ks to hdf5 antenna file
    with h5py.File(antennas_fname, 'a') as fp:
        group = fp.require_group('antennas')

        for i, ant in enumerate(antennas):
            h5ant = group[ant.name]

            h5beacon_info = h5ant['beacon_info']

            # find out freq_name
            if freq_name is None:
                freq_name = [ k for k in h5beacon_info.keys() if np.isclose(h5beacon_info[k].attrs['freq'], f_beacon)][0]

            h5attrs = h5beacon_info[freq_name].attrs

            h5attrs['best_k'] = old_ks_per_loc[i]
            h5attrs['best_k_time'] = old_ks_per_loc[i]*dt/f_beacon

    if show_plots:
        plt.show()