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

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

import h5py
import matplotlib.pyplot as plt
import numpy as np

import aa_generate_beacon as beacon
import lib

if __name__ == "__main__":
    from os import path
    import sys


    f_beacon_band = (49e-3,55e-3) #GHz
    allow_frequency_fitting = False
    read_frequency_from_file = True

    show_plots = True

    fname = "ZH_airshower/mysim.sry"

    ####
    fname_dir = path.dirname(fname)
    antennas_fname = path.join(fname_dir, beacon.antennas_fname)

    if not path.isfile(antennas_fname):
        print("Antenna file cannot be found, did you try generating a beacon?")
        sys.exit(1)

    # read in antennas
    with h5py.File(antennas_fname, 'a') as fp:
        if 'antennas' not in fp.keys():
            print("Antenna file corrupted? no antennas")
            sys.exit(1)

        group = fp['antennas']

        f_beacon = None
        if read_frequency_from_file and 'tx' in fp:
            tx = fp['tx']
            if 'f_beacon' in tx.attrs:
                f_beacon = tx.attrs['f_beacon']
            else:
                print("No frequency found in file.")
                sys.exit(2)
            f_beacon_estimate_band = 0.01*f_beacon

        elif allow_frequency_fitting:
            f_beacon_estimate_band = (f_beacon_band[1] - f_beacon_band[0])/2
            f_beacon = f_beacon_band[1] - f_beacon_estimate_band
        else:
            print("Not allowed to fit frequency and no tx group found in file.")
            sys.exit(2)

        N_antennas = len(group.keys())
        # just for funzies
        found_data = np.zeros((N_antennas, 3))

        # Determine frequency and phase
        for i, name in enumerate(group.keys()):
            ant_group = group[name]

            if 'traces' not in ant_group.keys():
                print(f"Antenna file corrupted? no 'traces' in {name}")
                sys.exit(1)

            traces = ant_group['traces']
            t_trace = traces[0]

            if not True:
                # only take the Beacon trace
                test_traces = traces[4]
                orients = ['B']
            else:
                test_traces = traces[1:]
                orients = ['Ex', 'Ey', 'Ez', 'B']

            if True:
                freqs, phases, amps = lib.find_beacon_in_traces(
                        test_traces, t_trace,
                        f_beacon_estimate=f_beacon,
                        frequency_fit=allow_frequency_fitting,
                        f_beacon_estimate_band=f_beacon_estimate_band
                        )
            else:
                # Testing
                freqs = [f_beacon]
                t0 = ant_group.attrs['t0']

                phases = [ 2*np.pi*t0*f_beacon ]
                amps = [ 3e-7 ]

            # choose highest amp
            #idx = np.argmax(amps, axis=1)
            idx = 0

            frequency = freqs[idx]
            phase = phases[idx]
            amplitude = amps[idx]
            orientation = orients[idx]

            if show_plots and (i == 60 or i == 72):
                fig, ax = plt.subplots()
                trace_amp = max(traces[-1]) - min(traces[-1])

                myt = np.linspace(min(traces[0]), max(traces[0]), 10*len(traces[0]))
                ax.plot(t_trace, traces[-1], marker='.', label='trace')
                ax.plot(myt, lib.sine_beacon(frequency, myt, amplitude=amplitude, phase=phase), ls='dashed', label='simulated')
                ax.set_title(f"Beacon at antenna {ant_group}\nF:{frequency}, P:{phase}, A:{amplitude}")
                ax.legend()

            ant_group.attrs['beacon_freq'] = frequency
            ant_group.attrs['beacon_phase'] = phase
            ant_group.attrs['beacon_amplitude'] = amplitude
            ant_group.attrs['beacon_orientation'] = orientation

            found_data[i] = frequency, phase, amplitude

    print("Beacon Phases, Amplitudes and Frequencies written to", antennas_fname)

    # show histogram of found frequencies
    if show_plots:
        if True or allow_frequency_fitting:
            fig, ax = plt.subplots()
            ax.set_xlabel("Frequency")
            ax.set_ylabel("Counts")
            ax.axvline(f_beacon, ls='dashed', color='g')
            ax.hist(found_data[:,0], bins='sqrt', density=False)

        if True:
            fig, ax = plt.subplots()
            ax.set_xlabel("Amplitudes")
            ax.set_ylabel("Counts")
            ax.hist(found_data[:,2], bins='sqrt', density=False)

        plt.show()
WUotD 2022-11-14 20:49:35 +01:00			`#!/usr/bin/env python3`
			`# vim: fdm=indent ts=4`

			`import h5py`
ZH: ba_beacon_phase move functions to ./lib.py 2022-11-18 16:27:20 +01:00			`import matplotlib.pyplot as plt`
			`import numpy as np`
WUotD 2022-11-14 20:49:35 +01:00
			`import aa_generate_beacon as beacon`
ZH: ba_beacon_phase move functions to ./lib.py 2022-11-18 16:27:20 +01:00			`import lib`
WUotD 2022-11-14 20:49:35 +01:00
			`if __name__ == "__main__":`
			`from os import path`
			`import sys`

ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00
WUotD 2022-11-14 20:49:35 +01:00			`f_beacon_band = (49e-3,55e-3) #GHz`
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`allow_frequency_fitting = False`
WUotD 2022-11-14 20:49:35 +01:00			`read_frequency_from_file = True`

ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`show_plots = True`

WUotD 2022-11-14 20:49:35 +01:00			`fname = "ZH_airshower/mysim.sry"`

			`####`
			`fname_dir = path.dirname(fname)`
			`antennas_fname = path.join(fname_dir, beacon.antennas_fname)`

			`if not path.isfile(antennas_fname):`
			`print("Antenna file cannot be found, did you try generating a beacon?")`
			`sys.exit(1)`

			`# read in antennas`
			`with h5py.File(antennas_fname, 'a') as fp:`
			`if 'antennas' not in fp.keys():`
			`print("Antenna file corrupted? no antennas")`
			`sys.exit(1)`

			`group = fp['antennas']`

			`f_beacon = None`
			`if read_frequency_from_file and 'tx' in fp:`
			`tx = fp['tx']`
			`if 'f_beacon' in tx.attrs:`
			`f_beacon = tx.attrs['f_beacon']`
			`else:`
			`print("No frequency found in file.")`
			`sys.exit(2)`
			`f_beacon_estimate_band = 0.01*f_beacon`

			`elif allow_frequency_fitting:`
			`f_beacon_estimate_band = (f_beacon_band[1] - f_beacon_band[0])/2`
			`f_beacon = f_beacon_band[1] - f_beacon_estimate_band`
			`else:`
			`print("Not allowed to fit frequency and no tx group found in file.")`
			`sys.exit(2)`

			`N_antennas = len(group.keys())`
			`# just for funzies`
			`found_data = np.zeros((N_antennas, 3))`

			`# Determine frequency and phase`
			`for i, name in enumerate(group.keys()):`
			`ant_group = group[name]`

			`if 'traces' not in ant_group.keys():`
			`print(f"Antenna file corrupted? no 'traces' in {name}")`
			`sys.exit(1)`

			`traces = ant_group['traces']`
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`t_trace = traces[0]`

			`if not True:`
			`# only take the Beacon trace`
			`test_traces = traces[4]`
			`orients = ['B']`
			`else:`
			`test_traces = traces[1:]`
			`orients = ['Ex', 'Ey', 'Ez', 'B']`

			`if True:`
			`freqs, phases, amps = lib.find_beacon_in_traces(`
			`test_traces, t_trace,`
			`f_beacon_estimate=f_beacon,`
			`frequency_fit=allow_frequency_fitting,`
			`f_beacon_estimate_band=f_beacon_estimate_band`
			`)`
			`else:`
			`# Testing`
			`freqs = [f_beacon]`
			`t0 = ant_group.attrs['t0']`

			`phases = [ 2np.pit0*f_beacon ]`
			`amps = [ 3e-7 ]`
WUotD 2022-11-14 20:49:35 +01:00
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`# choose highest amp`
			`#idx = np.argmax(amps, axis=1)`
			`idx = 0`
WUotD 2022-11-14 20:49:35 +01:00
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`frequency = freqs[idx]`
			`phase = phases[idx]`
			`amplitude = amps[idx]`
			`orientation = orients[idx]`
WUotD 2022-11-14 20:49:35 +01:00
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`if show_plots and (i == 60 or i == 72):`
			`fig, ax = plt.subplots()`
			`trace_amp = max(traces[-1]) - min(traces[-1])`

			`myt = np.linspace(min(traces[0]), max(traces[0]), 10*len(traces[0]))`
			`ax.plot(t_trace, traces[-1], marker='.', label='trace')`
			`ax.plot(myt, lib.sine_beacon(frequency, myt, amplitude=amplitude, phase=phase), ls='dashed', label='simulated')`
			`ax.set_title(f"Beacon at antenna {ant_group}\nF:{frequency}, P:{phase}, A:{amplitude}")`
			`ax.legend()`
WUotD 2022-11-14 20:49:35 +01:00
			`ant_group.attrs['beacon_freq'] = frequency`
			`ant_group.attrs['beacon_phase'] = phase`
			`ant_group.attrs['beacon_amplitude'] = amplitude`
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`ant_group.attrs['beacon_orientation'] = orientation`
WUotD 2022-11-14 20:49:35 +01:00
			`found_data[i] = frequency, phase, amplitude`

ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`print("Beacon Phases, Amplitudes and Frequencies written to", antennas_fname)`

WUotD 2022-11-14 20:49:35 +01:00			`# show histogram of found frequencies`
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`if show_plots:`
WUotD 2022-11-14 20:49:35 +01:00			`if True or allow_frequency_fitting:`
			`fig, ax = plt.subplots()`
			`ax.set_xlabel("Frequency")`
			`ax.set_ylabel("Counts")`
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`ax.axvline(f_beacon, ls='dashed', color='g')`
			`ax.hist(found_data[:,0], bins='sqrt', density=False)`
WUotD 2022-11-14 20:49:35 +01:00
			`if True:`
			`fig, ax = plt.subplots()`
			`ax.set_xlabel("Amplitudes")`
			`ax.set_ylabel("Counts")`
ZH: beacon phase finding working 2022-11-18 19:31:24 +01:00			`ax.hist(found_data[:,2], bins='sqrt', density=False)`
WUotD 2022-11-14 20:49:35 +01:00
			`plt.show()`