ZH: cli arguments for beacon generation

This commit is contained in:
Eric Teunis de Boone 2023-01-13 16:23:15 +01:00
parent 25a5539a81
commit 031e21636d

View file

@ -241,36 +241,44 @@ def write_baseline_time_diffs_hdf5(fname, baselines, true_phase_diffs, k_periods
if __name__ == "__main__":
from os import path
from argparse import ArgumentParser
parser = ArgumentParser()
parser.add_argument('-n', '--noise-sigma', type=float, default=1e3, help='in [muV/m]')
parser.add_argument('-f', '--beacon-frequency', type=float, default=51.53e-3, help='The beacon\'s frequency [GHz]')
# Beacon Properties
parser.add_argument('-a', '--beacon-amplitudes', type=float, nargs=3, default=[1e3, 0, 0], help='in [muV/m]')
parser.add_argument('-d', '--beacon-rsq-decay', type=bool, default=True, help='Use Beacon amplitudes at 0,0,0')
# Bandpass
parser.add_argument('-p', '--use-passband', type=bool, default=True)
parser.add_argument('-l', '--passband-low', type=float, default=30e-3, help='Lower frequency [GHz] of the passband filter. (set -1 for np.inf)')
parser.add_argument('-u', '--passband-high', type=float, default=80e-3, help='Upper frequency [GHz] of the passband filter. (set -1 for np.inf)')
# Trace length modification
parser.add_argument('-N', '--new-trace-length', type=float, help='resize airshower trace', default=1e4)
parser.add_argument('-P', '--pre-trace-length', type=float, help='amount of trace to prepend the airshower when resizing', default=2e3)
args = parser.parse_args()
##
## End of ArgumentParsing
##
rng = np.random.default_rng()
fname = "ZH_airshower/mysim.sry"
# Transmitter
remake_tx = True
tx = Antenna(x=-2e3,y=0,z=0,name='tx') # m
if False:
# Move tx out a long way
tx.x, tx.y = -75e3, 75e3 # m
elif False:
# Move it to 0,0,0 (among the antennas)
tx.x, tx.y = 0, 0 #m
# Noise properties
noise_sigma = args.noise_sigma # mu V/m set to None to ignore
# Beacon properties
if False: # slowest beacon to be found:
f_beacon = 10e-3 # GHz
low_bp = 5e-3 # GHz
high_bp = 80e-3 # GHz
else: # original wanted beacon
f_beacon = 51.53e-3 # GHz
beacon_amplitudes = np.array(args.beacon_amplitudes) # mu V/m
beacon_radiate_rsq = args.beacon_rsq_decay # beacon_amplitude is repaired for distance to 0,0,0
# Bandpass for E field blockfilter
low_bp = 30e-3 # GHz
high_bp = 80e-3 # GHz
beacon_amplitudes = 1e-6*np.array([1e3, 0, 0]) # mu V/m
beacon_radiate_rsq = True # beacon_amplitude is repaired for distance to 0,0,0
# Beacon properties
f_beacon = args.beacon_frequency # GHz
# modify beacon power to be beacon_amplitude at 0,0,0
if beacon_radiate_rsq:
@ -280,11 +288,23 @@ if __name__ == "__main__":
beacon_amplitudes *= ampl
# Noise properties
noise_sigma = 1e-4 # set to None to ignore
# Transmitter
remake_tx = True
# Disable block_filter
if False:
tx = Antenna(x=0,y=0,z=0,name='tx') # m
if True:
# Move tx out a long way
tx.x, tx.y = -75e3, 75e3 # m
elif False:
# Move it to 0,0,0 (among the antennas)
tx.x, tx.y = 0, 0 #m
# Bandpass for E field blockfilter
low_bp = args.passband_low if args.passband_low >= 0 else np.inf # GHz
high_bp = args.passband_high if args.passband_high >= 0 else np.inf # GHz
# Enable/Disable block_filter
if not args.use_passband:
block_filter = lambda x, dt, low, high: x
####
@ -300,8 +320,9 @@ if __name__ == "__main__":
print("Beacon amplitude at tx [muV/m]:", beacon_amplitudes)
print("Beacon amplitude at 0,0,0 [muV/m]:", beacon_amplitudes/ampl)
print("Tx location:", [tx.x, tx.y, tx.z])
print("Noise sigma:", noise_sigma)
print("Noise sigma [muV/m]:", noise_sigma)
# read in antennas
ev = REvent(fname)
@ -315,11 +336,10 @@ if __name__ == "__main__":
if i%10 == 0:
print(f"Beaconed antenna {i} out of", len(ev.antennas))
if not False: # modify trace lengths
if args.new_trace_length: # modify trace lengths
N_samples = len(antenna.t)
#new_N = 2*N_samples
new_N = 10000 # ns = 10us
pre_N = 2000 # ns = 2us
new_N = int(args.new_trace_length)
pre_N = int(args.pre_trace_length)
after_N = new_N - pre_N
dt = antenna.t[1] - antenna.t[0]
@ -335,12 +355,12 @@ if __name__ == "__main__":
if i%10 == 0:
print(f"Modified trace lengths by {pre_N},{after_N-N_samples}")
beacon = lib.beacon_from(tx, antenna, f_beacon, antenna.t, c_light=c_light, radiate_rsq=beacon_radiate_rsq)
beacon = 1e-6 * lib.beacon_from(tx, antenna, f_beacon, antenna.t, c_light=c_light, radiate_rsq=beacon_radiate_rsq) # mu V/m
# noise realisation
noise_realisation = 0
if noise_sigma is not None:
noise_realisation = rng.normal(0, noise_sigma, size=len(beacon))
noise_realisation = 1e-6 * rng.normal(0, noise_sigma, size=len(beacon)) # mu V/m
# Collect all data to be saved (with the first 3 values the E fields)
traces = np.array([antenna.Ex, antenna.Ey, antenna.Ez, beacon, noise_realisation])