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

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#!/usr/bin/env python3
# vim: fdm=indent ts=4
"""
Find beacon phases in antenna traces
And save these to a file
"""
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import h5py
import matplotlib.pyplot as plt
import numpy as np
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import aa_generate_beacon as beacon
import lib
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if __name__ == "__main__":
from os import path
import sys
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f_beacon_band = (49e-3,55e-3) #GHz
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allow_frequency_fitting = False
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read_frequency_from_file = True
use_AxB_trace = True
use_beacon_trace = True # only applicable if AxB = False
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show_plots = True
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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()):
h5ant = group[name]
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# use E_AxB only instead of polarisations
if use_AxB_trace:
if 'E_AxB' not in h5ant.keys():
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print(f"Antenna does not have 'E_AxB' in {name}")
sys.exit(1)
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traces = h5ant['E_AxB']
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t_trace = traces[0]
test_traces = [ traces[1] ]
orients = ['E_AxB']
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# use separate polarisations
else:
if 'traces' not in h5ant.keys():
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print(f"Antenna file corrupted? no 'traces' in {name}")
sys.exit(1)
traces = h5ant['traces']
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t_trace = traces[0]
if use_beacon_trace:
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# only take the Beacon trace
test_traces = [traces[4]]
orients = ['B']
else:
test_traces = traces[1:]
orients = ['Ex', 'Ey', 'Ez', 'B']
# Do Fourier Transforms
# to find phases and amplitudes
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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 = h5ant.attrs['t0']
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phases = [ 2*np.pi*t0*f_beacon ]
amps = [ 3e-7 ]
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# choose highest amp
idx = 0
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if False and len(phases) > 1:
#idx = np.argmax(amplitudes, axis=-1)
raise NotImplementedError
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frequency = freqs[idx]
phase = phases[idx]
amplitude = amps[idx]
orientation = orients[idx]
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# for reporting using plots
found_data[i] = frequency, phase, amplitude
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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')
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ax.set_title(f"Beacon at antenna {h5ant.attrs['name']}\nF:{frequency:.2e}, P:{phase:.4f}, A:{amplitude:.1e}")
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ax.legend()
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# save to file
h5beacon_info = h5ant.require_group('beacon_info')
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# only take n_sig significant digits into account
# for naming in hdf5 file
n_sig = 3
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decimal = int(np.floor(np.log10(abs(frequency))))
freq_name = str(np.around(frequency, n_sig-decimal))
# delete previous values
if freq_name in h5beacon_info:
del h5beacon_info[freq_name]
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h5beacon_freq_info = h5beacon_info.create_group(freq_name)
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h5attrs = h5beacon_freq_info.attrs
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h5attrs['freq'] = frequency
h5attrs['phase'] = phase
h5attrs['amplitude'] = amplitude
h5attrs['orientation'] = orientation
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print("Beacon Phases, Amplitudes and Frequencies written to", antennas_fname)
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# show histogram of found frequencies
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if show_plots:
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if True or allow_frequency_fitting:
fig, ax = plt.subplots()
ax.set_xlabel("Frequency")
ax.set_ylabel("Counts")
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ax.axvline(f_beacon, ls='dashed', color='g')
ax.hist(found_data[:,0], bins='sqrt', density=False)
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if True:
fig, ax = plt.subplots()
ax.set_xlabel("Amplitudes")
ax.set_ylabel("Counts")
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ax.hist(found_data[:,2], bins='sqrt', density=False)
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plt.show()