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#!/usr/bin/env python3
# vim: fdm=indent ts=4
"""
Find the best integer multiple to shift
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antennas to be able to resolve
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"""
import h5py
from itertools import combinations , zip_longest , product
import matplotlib . pyplot as plt
import numpy as np
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from os import path
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import os
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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
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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 ) :
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"""
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
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a_maxima = [ ]
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N_ant = len ( antennas )
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if dt is None :
dt = antennas [ 0 ] . t_AxB [ 1 ] - antennas [ 0 ] . t_AxB [ 0 ]
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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 = [ ]
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# 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 )
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a_maxima . append ( max ( ant . E_AxB ) )
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if t__ [ 0 ] < t_min :
t_min = t__ [ 0 ]
if t__ [ - 1 ] > t_max :
t_max = t__ [ - 1 ]
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# 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 ]
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# Interpolate and find best sample shift
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max_neg_shift = 0 #np.min(allowed_sample_shifts) * dt
max_pos_shift = 0 #np.max(allowed_sample_shifts) * dt
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t_sum = np . arange ( t_min + max_neg_shift , t_max + max_pos_shift , dt )
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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
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best_sample_shifts [ i ] = sample_shift_first_trace
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continue
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# init figure
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if i in plot_iteration_with_shifted_trace :
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fig , ax = plt . subplots ( figsize = figsize )
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ax . set_title ( " Traces at ( {:.1f} , {:.1f} , {:.1f} ) i= {i} / {tot} " . format ( * test_loc , i = i , tot = N_ant ) )
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ax . set_xlabel ( " Time [ns] " )
ax . set_ylabel ( " Amplitude " )
ax . plot ( t_sum , a_sum )
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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 )
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if i in plot_iteration_with_shifted_trace :
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ax . plot ( t_sum , augmented_a , alpha = 0.7 , ls = ' dashed ' , label = f ' { shift } ' )
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# transform maximum into best_sample_shift
best_idx = np . argmax ( shift_maxima )
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best_sample_shifts [ i ] = allowed_sample_shifts [ best_idx ]
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best_augmented_a = np . roll ( a_int , best_sample_shifts [ i ] )
a_sum + = best_augmented_a
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# cleanup figure
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if i in plot_iteration_with_shifted_trace :
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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 )
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if fig_dir :
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fig . tight_layout ( )
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fname = path . join ( fig_dir , path . basename ( __file__ ) + f ' . { fig_distinguish } i { i } ' + ' .loc {:.1f} - {:.1f} - {:.1f} ' . format ( * test_loc ) )
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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_ ) ]
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wx = 50 + ( max ( best_sample_shifts ) - min ( best_sample_shifts ) ) * dt
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ax . set_xlim ( x - wx , x + wx )
fig . savefig ( fname + " .zoomed.peak.pdf " )
ax . set_xlim ( * old_xlim )
fig . savefig ( fname + " .pdf " )
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plt . close ( fig )
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# sort by antenna (undo sorting by maximum)
undo_sort_idx = np . argsort ( sort_idx )
best_sample_shifts = best_sample_shifts [ undo_sort_idx ]
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# Return ks
return best_sample_shifts , np . max ( a_sum )
if __name__ == " __main__ " :
import sys
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import os
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import matplotlib
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if os . name == ' posix ' and " DISPLAY " not in os . environ :
matplotlib . use ( ' Agg ' )
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atm = AtmoCal ( )
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from scriptlib import MyArgumentParser
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parser = MyArgumentParser ( default_fig_dir = " ./figures/periods_from_shower_figures/ " )
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parser . add_argument ( ' --quick_run ' , action = ' store_true ' , help = ' Use a very coarse grid (6x6) ' )
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parser . add_argument ( ' --max-k ' , type = float , default = 2 , help = ' Maximum abs(k) allowed to be shifted. (Default: %(default)d ) ' )
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parser . add_argument ( ' -N ' , ' --N_runs ' , type = int , default = 5 , help = ' Maximum amount of iterations to grid search. (Default: %(default)d ) ' )
parser . add_argument ( ' -l ' , ' --passband-low ' , type = float , default = 30e-3 , help = ' Lower frequency [GHz] of the passband filter. (set -1 for np.inf) (Default: %(default)g ) ' )
parser . add_argument ( ' -u ' , ' --passband-high ' , type = float , default = 80e-3 , help = ' Upper frequency [GHz] of the passband filter. (set -1 for np.inf) (Default: %(default)g ) ' )
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parser . add_argument ( ' --input-fname ' , type = str , default = None , help = ' Path to mysim.sry, either directory or path. If empty it takes DATA_DIR and appends mysim.sry. (Default: %(default)s ) ' )
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args = parser . parse_args ( )
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if not args . input_fname :
args . input_fname = args . data_dir
if path . isdir ( args . input_fname ) :
args . input_fname = path . join ( args . input_fname , " mysim.sry " )
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figsize = ( 12 , 8 )
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fig_dir = args . fig_dir
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fig_subdir = path . join ( fig_dir , ' shifts/ ' )
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show_plots = args . show_plots
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max_k = int ( args . max_k )
allowed_ks = np . arange ( - max_k , max_k + 1 , dtype = int )
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Xref = 400
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N_runs = args . N_runs
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remove_beacon_from_trace = True
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apply_signal_window_from_max = True
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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
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####
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fname_dir = args . data_dir
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antennas_fname = path . join ( fname_dir , beacon . antennas_fname )
time_diffs_fname = ' time_diffs.hdf5 ' if not True else antennas_fname
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tx_fname = path . join ( fname_dir , beacon . tx_fname )
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snr_fname = path . join ( fname_dir , beacon . snr_fname )
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## 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 ' )
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# create fig_dir
if fig_dir :
os . makedirs ( fig_dir , exist_ok = True )
if fig_subdir :
os . makedirs ( fig_subdir , exist_ok = True )
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# Read in antennas from file
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_ , tx , antennas = beacon . read_beacon_hdf5 ( antennas_fname )
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_ , __ , txdata = beacon . read_tx_file ( tx_fname )
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# Read original REvent
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ev = REvent ( args . input_fname )
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# .. patch in our antennas
ev . antennas = antennas
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# read in snr information
snrs = beacon . read_snr_file ( snr_fname )
snr_str = f " $ \\ langle SNR \\ rangle$ = { snrs [ ' mean ' ] : .1e } "
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# 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 ' ]
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##
## Manipulate time and traces of each antenna
##
### Remove time due to true phase
### and optionally remove the beacon
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### Note: there is no use in changing *_AxB variables here (except for plotting),
### they're recomputed by the upcoming rit.set_pol_and_bp call.
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measured_repair_offsets = beacon . read_antenna_clock_repair_offsets ( ev . antennas , mode = ' phases ' , freq_name = freq_name )
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for i , ant in enumerate ( ev . antennas ) :
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ev . antennas [ i ] . orig_t = ev . antennas [ i ] . t
ev . antennas [ i ] . t + = measured_repair_offsets [ i ]
# t_AxB will be set by the rit.set_pol_and_bp function
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ev . antennas [ i ] . t_AxB + = measured_repair_offsets [ i ]
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if apply_signal_window_from_max :
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N_pre , N_post = 250 , 250 # TODO: make this configurable
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# Get max idx from all the traces
# and select the strongest
max_idx = [ ]
maxs = [ ]
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for trace in [ ant . Ex , ant . Ey , ant . Ez ] :
idx = np . argmax ( np . abs ( trace ) )
max_idx . append ( idx )
maxs . append ( np . abs ( trace [ idx ] ) )
idx = np . argmax ( maxs )
max_idx = max_idx [ idx ]
# Create window around max_idx
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low_idx = max ( 0 , max_idx - N_pre )
high_idx = min ( len ( ant . t ) , max_idx + N_post )
ev . antennas [ i ] . orig_t = ant . orig_t [ low_idx : high_idx ]
ev . antennas [ i ] . t = ant . t [ low_idx : high_idx ]
ev . antennas [ i ] . Ex = ant . Ex [ low_idx : high_idx ]
ev . antennas [ i ] . Ey = ant . Ey [ low_idx : high_idx ]
ev . antennas [ i ] . Ez = ant . Ez [ low_idx : high_idx ]
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ev . antennas [ i ] . t_AxB = ant . t_AxB [ low_idx : high_idx ]
ev . antennas [ i ] . E_AxB = ant . E_AxB [ low_idx : high_idx ]
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# .. and remove the beacon from the traces
# Note: ant.E_AxB is recalculated by rit.set_pol_and_bp
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if remove_beacon_from_trace :
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clock_phase = measured_repair_offsets [ i ] * 2 * np . pi * f_beacon
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beacon_phase = ant . beacon_info [ freq_name ] [ ' beacon_phase ' ]
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f = ant . beacon_info [ freq_name ] [ ' freq ' ]
ampl = ant . beacon_info [ freq_name ] [ ' amplitude ' ]
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calc_beacon = lib . sine_beacon ( f , ev . antennas [ i ] . t , amplitude = ampl , phase = beacon_phase - clock_phase )
tx_amps = txdata [ ' amplitudes ' ]
tx_amps_sum = np . sum ( tx_amps )
# Split up contribution to the various polarisations
for j , amp in enumerate ( tx_amps ) :
if j == 0 :
ev . antennas [ i ] . Ex - = amp * ( 1 / tx_amps_sum ) * calc_beacon
elif j == 1 :
ev . antennas [ i ] . Ey - = amp * ( 1 / tx_amps_sum ) * calc_beacon
elif j == 2 :
ev . antennas [ i ] . Ez - = amp * ( 1 / tx_amps_sum ) * calc_beacon
# Subtract the beacon from E_AxB
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ev . antennas [ i ] . E_AxB - = calc_beacon
# Make a figure of the manipulated traces
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if i == 72 :
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orig_beacon_amplifier = ampl / max ( ant . beacon )
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fig , ax = plt . subplots ( figsize = figsize )
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ax . set_title ( f " Signal and Beacon traces Antenna { ant . name } " )
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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 " )
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ax . legend ( title = snr_str )
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# save
if fig_dir :
fig . tight_layout ( )
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if True : # zoom
old_xlim = ax . get_xlim ( )
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if True : # zoomed on part without peak of this trace
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wx , x = 200 , min ( ant . t_AxB )
ax . set_xlim ( x - 5 , x + wx )
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fig . savefig ( path . join ( fig_dir , __file__ + f ' .traces.A { ant . name } .zoomed.beacon.pdf ' ) )
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if True : # zoomed on peak of this trace
idx = np . argmax ( ev . antennas [ i ] . E_AxB )
x = ev . antennas [ i ] . t_AxB [ idx ]
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wx = 300
ax . set_xlim ( x - wx / / 2 , x + wx / / 2 )
fig . savefig ( path . join ( fig_dir , __file__ + f " .traces.A { ant . name } .zoomed.peak.pdf " ) )
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ax . set_xlim ( * old_xlim )
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fig . savefig ( path . join ( fig_dir , __file__ + f ' .traces.A { ant . name } .pdf ' ) )
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if show_plots :
plt . show ( )
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# Prepare polarisation and passbands
rit . set_pol_and_bp ( ev , low = low_bp , high = high_bp )
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# 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 )
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##
## Determine grid positions
##
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dXref = atm . distance_to_slant_depth ( np . deg2rad ( ev . zenith ) , Xref , 0 )
scale2d = dXref * np . tan ( np . deg2rad ( 2. ) )
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scale4d = dXref * np . tan ( np . deg2rad ( 4. ) )
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if args . quick_run : #quicky
x_coarse = np . linspace ( - scale2d , scale2d , 6 )
y_coarse = np . linspace ( - scale2d , scale2d , 6 )
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x_fine = x_coarse / 4
y_fine = y_coarse / 4
else : # long
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 )
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## Remove run_break_fname if it exists
try :
os . remove ( run_break_fname )
except OSError :
pass
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##
## Do calculations on the grid
##
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for r in range ( N_runs ) :
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# Setup Plane grid to test
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if r == 0 :
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xoff , yoff = 0 , 0
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x = x_coarse
y = y_coarse
else :
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# zooming in
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# best_idx is defined at the end of the loop
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old_ks_per_loc = ks_per_loc [ best_idx ]
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xoff , yoff = locs [ best_idx ]
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if r == 1 :
x = x_fine
y = y_fine
else :
x / = 4
y / = 4
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print ( f " Testing grid run { r } centered on ( { xoff } , { yoff } ) " )
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ks_per_loc = np . zeros ( ( len ( x ) * len ( y ) , len ( ev . antennas ) ) , dtype = int )
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maxima_per_loc = np . zeros ( ( len ( x ) * len ( y ) ) )
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## Check each location on grid
xx = [ ]
yy = [ ]
N_loc = len ( maxima_per_loc )
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for i , ( x_ , y_ ) in enumerate ( product ( x , y ) ) :
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tmp_fig_subdir = None
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if i % 10 == 0 :
print ( f " Testing location { i } out of { N_loc } " )
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tmp_fig_subdir = fig_subdir
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test_loc = ( x_ + xoff ) * ev . uAxB + ( y_ + yoff ) * ev . uAxAxB + dXref * ev . uA
xx . append ( x_ + xoff )
yy . append ( y_ + yoff )
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# Find best k for each antenna
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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 } . " )
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# Translate sample shifts back into period multiple k
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ks = np . rint ( shifts * f_beacon * dt )
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ks_per_loc [ i ] = ks
maxima_per_loc [ i ] = maximum
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xx = np . array ( xx )
yy = np . array ( yy )
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locs = list ( zip ( xx , yy ) )
## Save maxima to file
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np . savetxt ( path . join ( fig_dir , path . basename ( __file__ ) + f ' .maxima.run { r } .txt ' ) , np . column_stack ( ( locs , maxima_per_loc , ks_per_loc ) ) )
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if True : #plot maximum at test locations
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fig , axs = plt . subplots ( figsize = figsize )
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axs . set_title ( f " Optimizing signal strength by varying $k$ per antenna, \n Grid Run { r } " )
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axs . set_ylabel ( " vxvxB [km] " )
axs . set_xlabel ( " vxB [km] " )
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axs . set_aspect ( ' equal ' , ' datalim ' )
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sc = axs . scatter ( xx / 1e3 , yy / 1e3 , c = maxima_per_loc , cmap = ' Spectral_r ' , alpha = 0.6 )
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fig . colorbar ( sc , ax = axs , label = ' Max Amplitude [$ \\ mu V/m$] ' )
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axs . legend ( title = snr_str )
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# indicate maximum value
idx = np . argmax ( maxima_per_loc )
axs . plot ( xx [ idx ] / 1e3 , yy [ idx ] / 1e3 , ' bx ' , ms = 30 )
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if fig_dir :
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old_xlims = axs . get_xlim ( )
old_ylims = axs . get_ylim ( )
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fig . tight_layout ( )
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fig . savefig ( path . join ( fig_dir , path . basename ( __file__ ) + f ' .maxima.run { r } .pdf ' ) )
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if False :
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axs . plot ( tx . x / 1e3 , tx . y / 1e3 , marker = ' X ' , color = ' k ' )
fig . tight_layout ( )
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fig . savefig ( path . join ( fig_dir , path . basename ( __file__ ) + f ' .maxima.run { r } .with_tx.pdf ' ) )
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axs . set_xlim ( * old_xlims )
axs . set_ylim ( * old_ylims )
fig . tight_layout ( )
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##
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best_idx = np . argmax ( maxima_per_loc )
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best_k = ks_per_loc [ best_idx ]
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print ( " Max at location: " , locs [ best_idx ] )
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print ( ' Best k: ' , best_k )
## Save best ks to file
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np . savetxt ( path . join ( fig_dir , path . basename ( __file__ ) + f ' .bestk.run { r } .txt ' ) , best_k )
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## Do a small reconstruction of the shower for best ks
if True :
print ( " Reconstructing for best k " )
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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 )
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fig , axs = plt . subplots ( figsize = figsize )
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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$] ' )
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axs . legend ( title = snr_str )
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if fig_dir :
if power_reconstruction :
fname_extra = " power "
else :
fname_extra = " max_amp "
fig . tight_layout ( )
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fig . savefig ( path . join ( fig_dir , path . basename ( __file__ ) + f ' .reconstruction.run { r } . { fname_extra } .pdf ' ) )
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# Abort if no improvement
if ( r != 0 and ( old_ks_per_loc == ks_per_loc [ best_idx ] ) . all ( ) ) :
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print ( f " No changes from previous grid, breaking at iteration { r } out of { N_runs } " )
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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
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break
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old_ks_per_loc = ks_per_loc [ best_idx ]
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# 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 ]
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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 ]
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h5attrs [ ' best_k_time ' ] = old_ks_per_loc [ i ] / f_beacon
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if show_plots :
plt . show ( )