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https://gitlab.science.ru.nl/mthesis-edeboone/m-thesis-introduction.git
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ZH: update baseline phase script
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parent
ecb671bee8
commit
929c6c7748
1 changed files with 46 additions and 37 deletions
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@ -21,7 +21,7 @@ if __name__ == "__main__":
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fname = "ZH_airshower/mysim.sry"
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c_light = 3e8*1e-9
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show_plots = not True
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show_plots = True
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ref_ant_id = None # leave None for all baselines
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####
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@ -66,7 +66,6 @@ if __name__ == "__main__":
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# Get true phase diffs
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try:
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true_phases = np.array([ant.beacon_info[freq_name]['true_phase'] for ant in base])
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true_phases_diff = lib.phase_mod(lib.phase_mod(true_phases[1]) - lib.phase_mod(true_phases[0]))
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except IndexError:
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@ -79,59 +78,69 @@ if __name__ == "__main__":
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beacon.write_baseline_time_diffs_hdf5(time_diffs_fname, baselines, phase_diffs[:,1], [0]*len(phase_diffs), phase_diffs[:,0])
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# Read actual phases from antenna hdf5
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actual_antenna_measured_phases = { a.name: 2*np.pi*a.attrs['clock_offset']*f_beacon for a in antennas }
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##############################
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# Compare actual time shifts #
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##############################
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actual_antenna_true_phases = { a.name: -2*np.pi*a.attrs['clock_offset']*f_beacon for a in antennas }
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# Compare actual time shifts
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my_phase_diffs = []
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for i,b in enumerate(baselines):
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actual_phase_measured_diff = lib.phase_mod( lib.phase_mod(actual_antenna_measured_phases[b[1].name]) - lib.phase_mod(actual_antenna_measured_phases[b[0].name]))
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actual_true_phase_diff = lib.phase_mod( lib.phase_mod(actual_antenna_true_phases[b[1].name]) - lib.phase_mod(actual_antenna_true_phases[b[0].name]))
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# remove phase due to time delay from transmitter difference
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tds = np.array([ lib.geometry_time(tx, ant, c_light=c_light) for ant in base])
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delta_td = tds[1] - tds[0]
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delta_td_phase = lib.phase_mod(delta_td*2*np.pi*f_beacon)
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actual_phase_diff = lib.phase_mod( actual_phase_measured_diff - delta_td_phase)
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my_phase_diffs.append(actual_phase_diff)
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this_actual_true_phase_diff = lib.phase_mod( actual_true_phase_diff )
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my_phase_diffs.append(this_actual_true_phase_diff)
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# Make a plot
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if True:
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N_base = len(baselines)
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N_ant = len(antennas)
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phase_residuals = lib.phase_mod(phase_diffs[:,1] - my_phase_diffs)
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for i in range(2):
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plot_residuals = i == 1
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colors = ['blue', 'orange']
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fig, axs = plt.subplots(2, 1, sharex=True)
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axs[0].set_title("Measured phase difference - Actual phase difference")
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axs[0].set_xlabel("Phase $\\Delta\\varphi = \\varphi_{meas} - \\varphi_{true}$")
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axs[0].tick_params(bottom=True, labelbottom=True)
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#axs[1].tick_params(top=True, labeltop=True, bottom=False, labelbottom=False)
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fig, axs = plt.subplots(2, 1, sharex=True)
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if True:
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forward = lambda x: x/(2*np.pi*f_beacon)
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inverse = lambda x: 2*np.pi*x*f_beacon
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secax = axs[0].secondary_xaxis('top', functions=(forward, inverse))
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secax.set_xlabel('Time $\\Delta\\varphi/(2\\pi f_{beac})$ [ns]')
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if True:
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forward = lambda x: x/(2*np.pi*f_beacon)
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inverse = lambda x: 2*np.pi*x*f_beacon
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secax = axs[0].secondary_xaxis('top', functions=(forward, inverse))
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secax.set_xlabel('Time $\\Delta\\varphi/(2\\pi f_{beac})$ [ns]')
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i=0
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axs[i].set_ylabel("#")
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axs[i].hist(phase_residuals, bins='sqrt', density=False)
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if plot_residuals:
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phase_residuals = lib.phase_mod(phase_diffs[:,1] - my_phase_diffs)
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i=1
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axs[i].set_ylabel("Baseline\n combination #")
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if not True:
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axs[i].plot(my_phase_diffs, np.arange(N_base), ls='none', marker='+', label='actual time shifts')
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l = axs[i].plot(phase_diffs[:,1], np.arange(N_base), ls='none', marker='x', label='calculated')
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axs[0].set_title("Difference between Measured and Actual phase difference for Baseline (i,j)")
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axs[1].set_xlabel("Baseline Phase Residual $\\varphi_{ij_{meas}} - \\varphi_{ij_{true}}$ [rad]")
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else:
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axs[0].set_title("Comparison Measured and Actual phase difference for Baseline (i,j)")
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axs[1].set_xlabel("Baseline Phase $\\varphi_{ij}$ [rad]")
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axs[i].legend()
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i=0
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axs[i].set_ylabel("#")
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if plot_residuals:
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axs[i].hist(phase_residuals, bins='sqrt', density=False, alpha=0.8, color=colors[0])
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else:
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axs[i].hist(phase_diffs[:,1], bins='sqrt', density=False, alpha=0.8, color=colors[0], ls='solid' , histtype='step', label='Measured')
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axs[i].hist(my_phase_diffs, bins='sqrt', density=False, alpha=0.8, color=colors[1], ls='dashed', histtype='step', label='Actual')
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else:
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axs[i].plot(phase_residuals, np.arange(N_base), ls='none', marker='x')
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fig.tight_layout()
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i=1
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axs[i].set_ylabel("Baseline no.")
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if not plot_residuals:
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axs[i].plot(phase_diffs[:,1], np.arange(N_base), alpha=0.8, color=colors[0], ls='none', marker='x', label='calculated')
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axs[i].plot(my_phase_diffs, np.arange(N_base), alpha=0.8, color=colors[1], ls='none', marker='+', label='actual time shifts')
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if fig_dir:
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fig.savefig(path.join(fig_dir, __file__ + f".F{freq_name}.pdf"))
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axs[i].legend()
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else:
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axs[i].plot(phase_residuals, np.arange(N_base), alpha=0.6, ls='none', marker='x', color=colors[0])
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fig.tight_layout()
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if fig_dir:
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extra_name = "measured"
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if plot_residuals:
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extra_name = "differences"
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fig.savefig(path.join(fig_dir, __file__ + f".{extra_name}.F{freq_name}.pdf"))
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if show_plots:
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plt.show()
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