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Author SHA1 Message Date
peterlu14 52a4dac990 [update] down sample 2021-09-03 19:02:59 +08:00
peterlu14 9a3d9689fd Merge branch 'master' into feature/spike_detect 2021-09-03 19:01:53 +08:00
+31 -20
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@@ -1,5 +1,6 @@
import sys
import ast
import time
import psycopg2
import numpy as np
import pandas as pd
@@ -8,6 +9,21 @@ from math import ceil, floor
from json import loads, dumps
from scipy.fft import fft, fftfreq, rfft, rfftfreq, irfft, ifft
import lttb
from lttb.validators import has_two_columns, x_is_regular
def get_downsampled_signal(ori_signal, output_length):
signal_length = len(ori_signal)
signal = np.array([range(signal_length), ori_signal]).T
assert signal.shape == (signal_length, 2)
# Downsampling
downsampled_signal = lttb.downsample(signal, n_out=output_length, validators=[has_two_columns, x_is_regular])
assert downsampled_signal.shape == (output_length, 2)
downsampled_signal_index = downsampled_signal[:, 0]
downsampled_signal_value = downsampled_signal[:, 1]
return downsampled_signal_index, downsampled_signal_value
if __name__ == '__main__':
params = {}
@@ -20,7 +36,7 @@ if __name__ == '__main__':
cut_off_freq = int(params['cut_off_freq'])
threshold = ast.literal_eval('[' + params['threshold'] + ']')
waveform = ast.literal_eval('[' + params['waveform'] + ']')
SAMPLE_RATE = int(params['sample_rate'])
SAMPLE_RATE = int(float(params['sample_rate']))
DURATION = ceil(float(params['time_duration']))
DELTA_TIME = 1e6 / SAMPLE_RATE
N = SAMPLE_RATE * DURATION
@@ -39,30 +55,22 @@ if __name__ == '__main__':
print(e)
exit
finally:
time = np.array([], dtype=int)
data = np.array([])
timeArray = np.array([], dtype=int)
dataArray = np.array([])
for sub_data in ret:
for split_data in sub_data[0].split('"***"')[:-1]:
value = np.array(split_data.split(' '))
time = np.append(time, value[::2].astype(np.int))
data = np.append(data, value[1::2].astype(np.int))
# print(len(time), len(data))
timeArray = np.append(timeArray, value[::2].astype(np.int32))
dataArray = np.append(dataArray, value[1::2].astype(np.int32))
xf = rfftfreq(N, 1 / SAMPLE_RATE)
points_per_freq = len(xf) / (SAMPLE_RATE / 2)
target_idx = int(points_per_freq * cut_off_freq)
# print(xf[target_idx])
yf = rfft(data)
yf = rfft(dataArray)
yf[:target_idx] = 0
new_sig = np.round(irfft(yf, len(data)),3)
# print(time[-1])
# print(len(datas))
# print(len(yf),yf)
new_sig = np.round(irfft(yf, len(dataArray)),3)
if threshold[0] == 'below':
th = new_sig < threshold[1]
@@ -77,23 +85,26 @@ if __name__ == '__main__':
filter_array = []
for idx, point in enumerate(thresholded_edge_indices):
if idx > 0:
if time[thresholded_edge_indices[idx]] - int(waveform[2]) >= time[thresholded_edge_indices[idx-1]]:
if timeArray[thresholded_edge_indices[idx]] - int(waveform[2]) >= timeArray[thresholded_edge_indices[idx-1]]:
filter_array.append(True)
elif time[thresholded_edge_indices[idx]] - int(waveform[1]) >= time[thresholded_edge_indices[idx-1]]:
elif timeArray[thresholded_edge_indices[idx]] - int(waveform[1]) >= timeArray[thresholded_edge_indices[idx-1]]:
filter_array.append(True)
else:
filter_array.append(False)
else:
if time[thresholded_edge_indices[idx]] - int(waveform[1]) < 0:
if timeArray[thresholded_edge_indices[idx]] - int(waveform[1]) < 0:
filter_array.append(False)
else:
filter_array.append(True)
timemark_list = thresholded_edge_indices[filter_array]
OUTPUT_SIGNAL_SIZE = 2000
downsampled_signal_index, downsampled_signal_value = get_downsampled_signal(new_sig, OUTPUT_SIGNAL_SIZE)
if ret_data_type == 'all':
print(' '.join(str(x) for x in time))
print(' '.join(str(x) for x in new_sig))
print(' '.join(str(x) for x in timeArray))
print(' '.join(str(x) for x in downsampled_signal_index))
print(' '.join(str(x) for x in downsampled_signal_value))
print(' '.join(str(x) for x in timemark_list))
elif ret_data_type == 'partial':
return_sub_signal_lists = {}