VIANC/xfer_tracer/script.py

#!/usr/bin/env python3

import pyvisa
import time

import pyaudio as pa
import numpy as np
import scipy as sc
import matplotlib.pyplot as plt

current_phase = 0.0
normalized_f  = 0.0 # in cycles per sample : f = normalized_f * f_sampling

trans_len = 2000
intro = 0.5 * (1 - np.cos(2 * np.linspace(0, np.pi/2, trans_len)))
outro = 0.5 * (1 + np.cos(2 * np.linspace(0, np.pi/2, trans_len)))

intro = np.append(intro, np.ones(1024))
outro = np.append(outro, np.zeros(1024))

change_f = True
trans_done = False
new_f = 0.0
fade_time = 0


def audio_callback(in_data, frame_count, time_info, status):
	global fade_time
	global change_f
	global new_f
	global current_phase
	global normalized_f
	global trans_done

	if change_f == True:
		change_f = False
		trans_done = False
		fade_time = 0

	if(fade_time != 2*trans_len):
		if(fade_time < trans_len):
			last_fade = fade_time + frame_count
			envelope = outro[fade_time:last_fade]
			fade_time = min(last_fade, trans_len)
		elif(fade_time >= trans_len and fade_time < 2*trans_len):
			normalized_f = new_f
			if(new_f == 0):
				current_phase = 0. # Avoid weird sub-audio behavior
			last_fade = fade_time + frame_count
			envelope = intro[fade_time - trans_len:last_fade - trans_len]
			fade_time = min(last_fade, 2*trans_len)

	if(fade_time == 2*trans_len):
		trans_done = True

	sine = np.sin(2 * np.pi * (current_phase + np.arange(frame_count)*normalized_f))
	delta = frame_count*normalized_f
	delta -= np.floor(delta)

	if(delta + current_phase > 1):
		current_phase += delta - 1
	else:
		current_phase += delta

	if(fade_time != 2*trans_len):
		sine *= envelope

	return (sine.astype(np.float32).tobytes(), pa.paContinue)

paudio = pa.PyAudio()

audio_strm = paudio.open(format=pa.paFloat32,
	channels=1,
	rate=44100,
	output=True,
	input=False,
	stream_callback=audio_callback,
	start=True)
print(paudio.get_default_output_device_info())
print(audio_strm.is_active())

def acquire_samples(sc_frequency, oscillo):
	global new_f
	global change_f
	global trans_done
	new_f = sc_frequency
	change_f = True
	while (change_f == True) or (trans_done == False):
		time.sleep(0.05)
	time.sleep(0.2)

	oscillo.write("acquire:state run")
	oscillo.write("data:source CH1")
	input_ch = oscillo.query_binary_values("curve?",datatype="b",container=np.array).astype(np.float64)
	oscillo.write("data:source CH2")
	output_ch = oscillo.query_binary_values("curve?",datatype="b",container=np.array).astype(np.float64)

	return input_ch, output_ch

def manage_measures(f_list, oscillo): # These are NOT normalized frequencies
	hscales = [0.25, 100e-3, 50e-3, 25e-3, 10e-3, 5e-3, 2.5e-3, 1e-3, 500e-6, 250e-6, 100e-6, 50e-6, 25e-6, 10e-6]
	hscales_str = ["2.5e-1", "1.0e-1", "5.0e-2", "2.5e-2", "1.0e-2", "5.0e-3", "2.5e-3", "1.0e-3", "5.0e-4", "2.5e-4", "1.0e-4", "5.0e-5", "2.5e-5", "1.0e-5"]

	hscale_index = 0
	current_hscale = hscales[hscale_index]

	cal_A = []
	cal_B = []
	cal_done = False

	H = []

	W = sc.signal.windows.flattop(2500)

	for f in f_list:
		sc_frequency = np.round(2**20/44100 * f)/2**20
		num_periods = f * 10 * current_hscale
		while(num_periods >= 5 * 2.5):
			hscale_index += 1
			current_hscale = hscales[hscale_index]
			num_periods = f * 10 * current_hscale
			print("horizontal:main:scale " + hscales_str[hscale_index])
			oscillo.write("horizontal:main:scale " + hscales_str[hscale_index])
			cal_done = False

		print(f, " : ", current_hscale,"s/div, ", num_periods, " periods")
		A, B = acquire_samples(sc_frequency, oscillo)
		if not cal_done:
			cal_A, cal_B = acquire_samples(0., oscillo)
			cal_done = True
		print(A)
		print(B)
		A, B = (A - cal_A)*W, (B - cal_B)*W
		f_acq = 250./current_hscale
		rel_f = f / f_acq

		# Obtain the Fourier transforms of A, B @ rel_f, with flattop windowing 
		V = np.exp(-2.0j * np.pi * np.arange(2500) * rel_f)
		h = np.sum(B*V)/np.sum(A*V)
		print("H(", f, ") = ", h)
		H.append(h)
	return H

def find_oscillo():
	rm = pyvisa.ResourceManager()
	R = rm.list_resources()
	print(R)
#	if R.empty():
#		print("No device found")
#		exit(1)
	return rm.open_resource(R[0])


osci = find_oscillo()
osci.timeout = 10000
print(osci.query("*IDN?"))

osci.write("*RST")
time.sleep(10)

osci.write("ch1:scale 2.5e-1")
osci.write("ch1:bandwidth ON")
osci.write("ch1:coupling AC")
osci.write("select:ch1 1")

osci.write("ch2:scale 2.5e-1")
osci.write("ch2:bandwidth ON")
osci.write("ch2:coupling AC")
osci.write("select:ch2 1")


osci.write("trigger:main:edge:source LINE")
osci.write("trigger:main:mode NORMAL")
osci.write("trigger:main:type EDGE")

osci.write("acquire:mode sample")
osci.write("acquire:stopafter sequence")
osci.write("data:encdg RIBinary")
decade = [1.0, 1.2, 1.5, 1.8, 2.2, 2.7, 3.3, 3.9, 4.7, 5.6, 6.8, 8.2]

X = [68., 82] + list(np.array(decade)*([100.]*len(decade))) + list(np.array(decade) * ([1000.]*len(decade))) + [1e4, 1.2e4, 1.5e4, 1.8e4]
H = manage_measures(X, osci)
Y = 20 * np.log10(np.abs(H))

fig, axes = plt.subplots(nrows = 2, ncols=1, sharex = True)
axes[0].semilogx(X,Y)
axes[0].grid()
axes[1].semilogx(X, np.angle(H, deg=True))
axes[1].grid()
plt.show()
First commit 2024-12-15 19:57:42 +01:00			`#!/usr/bin/env python3`

			`import pyvisa`
			`import time`

			`import pyaudio as pa`
			`import numpy as np`
test 2024-12-17 17:55:11 +01:00			`import scipy as sc`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`import matplotlib.pyplot as plt`
test 2024-12-17 17:55:11 +01:00
			`current_phase = 0.0`
			`normalized_f = 0.0 # in cycles per sample : f = normalized_f * f_sampling`

			`trans_len = 2000`
			`intro = 0.5 * (1 - np.cos(2 * np.linspace(0, np.pi/2, trans_len)))`
			`outro = 0.5 * (1 + np.cos(2 * np.linspace(0, np.pi/2, trans_len)))`

			`intro = np.append(intro, np.ones(1024))`
			`outro = np.append(outro, np.zeros(1024))`

			`change_f = True`
			`trans_done = False`
			`new_f = 0.0`
			`fade_time = 0`
First commit 2024-12-15 19:57:42 +01:00

			`def audio_callback(in_data, frame_count, time_info, status):`
test 2024-12-17 17:55:11 +01:00			`global fade_time`
			`global change_f`
			`global new_f`
			`global current_phase`
			`global normalized_f`
			`global trans_done`

			`if change_f == True:`
			`change_f = False`
			`trans_done = False`
			`fade_time = 0`

			`if(fade_time != 2*trans_len):`
			`if(fade_time < trans_len):`
			`last_fade = fade_time + frame_count`
			`envelope = outro[fade_time:last_fade]`
			`fade_time = min(last_fade, trans_len)`
			`elif(fade_time >= trans_len and fade_time < 2*trans_len):`
			`normalized_f = new_f`
			`if(new_f == 0):`
			`current_phase = 0. # Avoid weird sub-audio behavior`
			`last_fade = fade_time + frame_count`
			`envelope = intro[fade_time - trans_len:last_fade - trans_len]`
			`fade_time = min(last_fade, 2*trans_len)`

			`if(fade_time == 2*trans_len):`
			`trans_done = True`

			`sine = np.sin(2 * np.pi * (current_phase + np.arange(frame_count)*normalized_f))`
			`delta = frame_count*normalized_f`
			`delta -= np.floor(delta)`

			`if(delta + current_phase > 1):`
			`current_phase += delta - 1`
			`else:`
			`current_phase += delta`

			`if(fade_time != 2*trans_len):`
			`sine *= envelope`

			`return (sine.astype(np.float32).tobytes(), pa.paContinue)`
First commit 2024-12-15 19:57:42 +01:00
			`paudio = pa.PyAudio()`
test 2024-12-17 17:55:11 +01:00
			`audio_strm = paudio.open(format=pa.paFloat32,`
First commit 2024-12-15 19:57:42 +01:00			`channels=1,`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`rate=44100,`
First commit 2024-12-15 19:57:42 +01:00			`output=True,`
test 2024-12-17 17:55:11 +01:00			`input=False,`
			`stream_callback=audio_callback,`
			`start=True)`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`print(paudio.get_default_output_device_info())`
			`print(audio_strm.is_active())`
test 2024-12-17 17:55:11 +01:00
			`def acquire_samples(sc_frequency, oscillo):`
			`global new_f`
			`global change_f`
			`global trans_done`
			`new_f = sc_frequency`
			`change_f = True`
			`while (change_f == True) or (trans_done == False):`
			`time.sleep(0.05)`
			`time.sleep(0.2)`

			`oscillo.write("acquire:state run")`
			`oscillo.write("data:source CH1")`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`input_ch = oscillo.query_binary_values("curve?",datatype="b",container=np.array).astype(np.float64)`
test 2024-12-17 17:55:11 +01:00			`oscillo.write("data:source CH2")`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`output_ch = oscillo.query_binary_values("curve?",datatype="b",container=np.array).astype(np.float64)`
test 2024-12-17 17:55:11 +01:00
			`return input_ch, output_ch`

			`def manage_measures(f_list, oscillo): # These are NOT normalized frequencies`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`hscales = [0.25, 100e-3, 50e-3, 25e-3, 10e-3, 5e-3, 2.5e-3, 1e-3, 500e-6, 250e-6, 100e-6, 50e-6, 25e-6, 10e-6]`
			`hscales_str = ["2.5e-1", "1.0e-1", "5.0e-2", "2.5e-2", "1.0e-2", "5.0e-3", "2.5e-3", "1.0e-3", "5.0e-4", "2.5e-4", "1.0e-4", "5.0e-5", "2.5e-5", "1.0e-5"]`
test 2024-12-17 17:55:11 +01:00
			`hscale_index = 0`
			`current_hscale = hscales[hscale_index]`

			`cal_A = []`
			`cal_B = []`
			`cal_done = False`

			`H = []`

			`W = sc.signal.windows.flattop(2500)`

			`for f in f_list:`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`sc_frequency = np.round(2*20/44100 f)/2**20`
test 2024-12-17 17:55:11 +01:00			`num_periods = f * 10 * current_hscale`
			`while(num_periods >= 5 * 2.5):`
			`hscale_index += 1`
			`current_hscale = hscales[hscale_index]`
			`num_periods = f * 10 * current_hscale`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`print("horizontal:main:scale " + hscales_str[hscale_index])`
			`oscillo.write("horizontal:main:scale " + hscales_str[hscale_index])`
test 2024-12-17 17:55:11 +01:00			`cal_done = False`

			`print(f, " : ", current_hscale,"s/div, ", num_periods, " periods")`
			`A, B = acquire_samples(sc_frequency, oscillo)`
			`if not cal_done:`
			`cal_A, cal_B = acquire_samples(0., oscillo)`
			`cal_done = True`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`print(A)`
			`print(B)`
test 2024-12-17 17:55:11 +01:00			`A, B = (A - cal_A)W, (B - cal_B)W`
			`f_acq = 250./current_hscale`
			`rel_f = f / f_acq`

			`# Obtain the Fourier transforms of A, B @ rel_f, with flattop windowing`
			`V = np.exp(-2.0j * np.pi * np.arange(2500) * rel_f)`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`h = np.sum(BV)/np.sum(AV)`
test 2024-12-17 17:55:11 +01:00			`print("H(", f, ") = ", h)`
			`H.append(h)`
			`return H`

			`def find_oscillo():`
			`rm = pyvisa.ResourceManager()`
			`R = rm.list_resources()`
			`print(R)`
			`# if R.empty():`
			`# print("No device found")`
			`# exit(1)`
			`return rm.open_resource(R[0])`

xfer_tracer working 2024-12-17 21:49:00 +01:00
test 2024-12-17 17:55:11 +01:00			`osci = find_oscillo()`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`osci.timeout = 10000`
test 2024-12-17 17:55:11 +01:00			`print(osci.query("*IDN?"))`

			`osci.write("*RST")`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`time.sleep(10)`
test 2024-12-17 17:55:11 +01:00
xfer_tracer working 2024-12-17 21:49:00 +01:00			`osci.write("ch1:scale 2.5e-1")`
test 2024-12-17 17:55:11 +01:00			`osci.write("ch1:bandwidth ON")`
			`osci.write("ch1:coupling AC")`
			`osci.write("select:ch1 1")`

xfer_tracer working 2024-12-17 21:49:00 +01:00			`osci.write("ch2:scale 2.5e-1")`
test 2024-12-17 17:55:11 +01:00			`osci.write("ch2:bandwidth ON")`
			`osci.write("ch2:coupling AC")`
			`osci.write("select:ch2 1")`


			`osci.write("trigger:main:edge:source LINE")`
			`osci.write("trigger:main:mode NORMAL")`
			`osci.write("trigger:main:type EDGE")`

			`osci.write("acquire:mode sample")`
			`osci.write("acquire:stopafter sequence")`
xfer_tracer working 2024-12-17 21:49:00 +01:00			`osci.write("data:encdg RIBinary")`
			`decade = [1.0, 1.2, 1.5, 1.8, 2.2, 2.7, 3.3, 3.9, 4.7, 5.6, 6.8, 8.2]`

			`X = [68., 82] + list(np.array(decade)([100.]len(decade))) + list(np.array(decade) * ([1000.]*len(decade))) + [1e4, 1.2e4, 1.5e4, 1.8e4]`
			`H = manage_measures(X, osci)`
			`Y = 20 * np.log10(np.abs(H))`

			`fig, axes = plt.subplots(nrows = 2, ncols=1, sharex = True)`
			`axes[0].semilogx(X,Y)`
			`axes[0].grid()`
			`axes[1].semilogx(X, np.angle(H, deg=True))`
			`axes[1].grid()`
			`plt.show()`