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WIP new version of ultrasound

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Change-Id: Iadb83396a64e277f6f0a37f7a96d92105648c4fe
This commit is contained in:
zolliker
2025-01-28 09:40:36 +01:00
parent b7bc81710d
commit 2e99e45aea
2 changed files with 517 additions and 426 deletions
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374
frappy_psi/ultrasound.py
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@ -19,18 +19,19 @@
"""frappy support for ultrasound"""
import math
#import serial
import os
import time
import numpy as np
import frappy_psi.iqplot as iqplot
from frappy_psi.adq_mr import Adq
from frappy_psi.adq_mr import Adq, PEdata, RUSdata
from frappy.core import Attached, BoolType, Done, FloatRange, HasIO, \
IntRange, Module, Parameter, Readable, StringIO, StringType, \
IDLE, DISABLED, TupleOf, ArrayOf
IntRange, Module, Parameter, Readable, Writable, Drivable, StringIO, StringType, \
IDLE, BUSY, DISABLED, ERROR, TupleOf, ArrayOf, Command
from frappy.properties import Property
#from frappy.modules import Collector
Collector = Readable
def fname_from_time(t, extension):
@ -55,7 +56,7 @@ class Roi(Readable):
enable = Parameter('calculate this roi', BoolType(), readonly=False, default=True)
pollinterval = Parameter(export=False)
interval = (0,0)
interval = (0, 0)
def initModule(self):
super().initModule()
@ -92,80 +93,22 @@ class FreqStringIO(StringIO):
end_of_line = '\r'
class Frequency(HasIO, Readable):
pars = Attached()
curves = Attached(mandatory=False)
maxy = Property('plot y scale', datatype=FloatRange(), default=0.5)
value = Parameter('frequency@I,q', datatype=FloatRange(unit='Hz'), default=0)
basefreq = Parameter('base frequency', FloatRange(unit='Hz'), readonly=False)
nr = Parameter('number of records', datatype=IntRange(1,10000), default=500)
sr = Parameter('samples per record', datatype=IntRange(1,1E9), default=16384)
freq = Parameter('target frequency', FloatRange(unit='Hz'), readonly=False)
bw = Parameter('bandwidth lowpassfilter', datatype=FloatRange(unit='Hz'),default=10E6)
class Frequency(HasIO, Writable):
value = Parameter('frequency', unit='Hz')
amp = Parameter('amplitude', FloatRange(unit='dBm'), readonly=False)
control = Parameter('control loop on?', BoolType(), readonly=False, default=True)
rusmode = Parameter('RUS mode on?', BoolType(), readonly=False, default=False)
time = Parameter('pulse start time', FloatRange(unit='nsec'),
readonly=False)
size = Parameter('pulse length (starting from time)', FloatRange(unit='nsec'),
readonly=False)
pulselen = Parameter('adjusted pulse length (integer number of periods)', FloatRange(unit='nsec'), default=1)
maxstep = Parameter('max frequency step', FloatRange(unit='Hz'), readonly=False,
default=10000)
minstep = Parameter('min frequency step for slope calculation', FloatRange(unit='Hz'),
readonly=False, default=4000)
slope = Parameter('inphase/frequency slope', FloatRange(), readonly=False,
default=1e6)
plot = Parameter('create plot images', BoolType(), readonly=False, default=True)
save = Parameter('save data', BoolType(), readonly=False, default=True)
pollinterval = Parameter(datatype=FloatRange(0,120))
last_change = 0
ioClass = FreqStringIO
dif = None
lastfreq = None
old = None
starttime = None
interval = (0,0)
def register_dif(self, dif):
self.dif = dif
def earlyInit(self):
super().earlyInit()
self.adq = Adq(self.nr, self.sr, self.bw)
self.roilist = []
self.write_nr(self.nr)
self.write_sr(self.sr)
self.skipctrl = 0
self.plotter = iqplot.Plot(self.maxy)
self.calc_interval()
def calc_interval(self):
self.interval = (self.time, self.time + self.size)
def write_time(self, value):
self.time = value
self.calc_interval()
return Done
def write_size(self, value):
self.size = value
self.calc_interval()
return Done
def write_nr(self, value):
# self.pollinterval = value * 0.0001
return value
def write_sr(self, value):
return value
def register_roi(self, roi):
self.roilist.append(roi)
def set_freq(self):
freq = self.freq + self.basefreq
self.communicate('FREQ %.15g;FREQ?' % freq)
#self._iodev.readline().decode('ascii')
return freq
def write_target(self, value):
self.communicate('FREQ %.15g;FREQ?' % value)
self.last_change = time.time()
if self.dif:
self.dif.read_value()
def write_amp(self, amp):
reply = self.communicate('AMPR %g;AMPR?' % amp)
@ -175,105 +118,196 @@ class Frequency(HasIO, Readable):
reply = self.communicate('AMPR?')
return float(reply)
def write_freq(self, value):
self.skipctrl = 2 # suppress control for the 2 next steps
return value
def doPoll(self):
"""main poll loop body"""
if self.lastfreq is None:
self.lastfreq = self.set_freq()
if self.rusmode:
self.sr = int(12e9/self.lastfreq) #picking up 12 period at the ith frequency in the time scale
# self.adq.samples_per_record = self.sr
self.adq.start()
class FrequencyDif(Readable):
freq = Attached(Frequency)
base = Parameter('base frequency', FloatRange(unit='Hz'), default=0)
value = Parameter('difference to base frequency', FloatRange(unit='Hz'), default=0)
if self.starttime is None:
self.starttime = time.time()
times = []
times.append(('init', time.time()))
seadata = {p: float(getattr(self.pars, p)) for p in self.pars.parameters}
data = self.adq.getdata() # this will wait, if not yet finished
#save sample
#np.save('sample.dat',data)
times.append(('wait',time.time()))
if self.control:
freq = self.lastfreq # data was acquired at this freq
else:
freq = self.set_freq()
seadata['frequency'] = freq
if self.control:
self.lastfreq = self.set_freq()
times.append(('setf',time.time()))
self.adq.start() # start next acq
times.append(('start',time.time()))
roilist = [r for r in self.roilist if r.enable]
def initModule(self):
super().initModule()
self.freq.register_dif(self)
gates = self.adq.gates_and_curves(data, freq, self.interval,
[r.interval for r in roilist])
if self.curves: # if attached Curves module is defined, update it
self.curves.value = self.adq.curves
if self.save:
times.append(('save',time.time()))
tdata, idata, qdata, pdata = self.adq.curves
seadata['timestep'] = tdata[1] - tdata[0]
iqdata = np.array((idata, qdata, pdata), dtype='f4')
ts = seadata['timestamp']
if ts:
filename = fname_from_time(ts, '.npz')
seanp = np.array(list(seadata.items()), dtype=[('name', 'U16'), ('value', 'f8')])
np.savez(filename, seadata=seanp, iqdata=iqdata)
# can be load back via
# content = np.load(filename)
# content['seadata'], content['iqdata']
self.pulselen = self.adq.pulselen
times.append(('ana',time.time()))
if self.plot:
# get reduced interval from adq.sinW
pulseint = (self.interval[0], self.interval[0] + self.pulselen)
try:
self.plotter.plot(
self.adq.curves,
rois=[pulseint] + [r.interval for r in roilist],
average=([r.time for r in roilist],
[r.i for r in roilist],
[r.q for r in roilist]))
except Exception as e:
self.log.warning('can not plot %r' % e)
else:
self.plotter.close()
now = time.time()
times.append(('plot',now))
# print(' '.join('%s %5.3f' % (label, t - self.starttime) for label, t in times))
self.starttime = now
self.value = freq - self.basefreq
for i, roi in enumerate(roilist):
roi.i = a = gates[i][0]
roi.q = b = gates[i][1]
roi.value = math.sqrt(a ** 2 + b ** 2)
roi.phase = math.atan2(a,b) * 180 / math.pi
inphase = self.roilist[0].i
if self.control:
newfreq = freq + inphase * self.slope - self.basefreq
# step = sorted((-self.maxstep, inphase * self.slope, self.maxstep))[1]
if self.old:
fdif = freq - self.old[0]
idif = inphase - self.old[1]
if abs(fdif) >= self.minstep:
self.slope = - fdif / idif
else:
fdif = 0
idif = 0
newfreq = freq + self.minstep
self.old = (freq, inphase)
if self.skipctrl > 0: # do no control for some time after changing frequency
self.skipctrl -= 1
elif self.control:
self.freq = sorted((self.freq - self.maxstep, newfreq, self.freq + self.maxstep))[1]
#print(times)
return Done
def read_value(self):
return self.freq - self.base
class Curves(Readable):
class Base(Collector):
freq = Attached()
adq = Attached(Adq)
sr = Parameter('samples per record', datatype=IntRange(1, 1E9), default=16384)
pollinterval = Parameter(datatype=FloatRange(0, 120)) # allow pollinterval = 0
_data = None
_data_args = None
def read_status(self):
adqstate = self.adq.get_status()
if adqstate == Adq.BUSY:
return BUSY, 'acquiring'
if adqstate == Adq.UNDEFINED:
return ERROR, 'no data yet'
if adqstate == Adq.READY:
return IDLE, 'new data available'
return IDLE, ''
def get_data(self):
data = self.adq.get_data(*self._data_args)
if id(data) != id(self._data):
self._data = data
return data
return None
class PulseEcho(Base):
value = Parameter("t, i, q, pulse curves",
TupleOf(*[ArrayOf(FloatRange(), 0, 16283) for _ in range(4)]), default=[[]] * 4)
nr = Parameter('number of records', datatype=IntRange(1, 9999), default=500)
bw = Parameter('bandwidth lowpassfilter', datatype=FloatRange(unit='Hz'), default=10E6)
control = Parameter('control loop on?', BoolType(), readonly=False, default=True)
time = Parameter('pulse start time', FloatRange(unit='nsec'),
readonly=False)
size = Parameter('pulse length (starting from time)', FloatRange(unit='nsec'),
readonly=False)
pulselen = Parameter('adjusted pulse length (integer number of periods)', FloatRange(unit='nsec'), default=1)
starttime = None
def initModule(self):
super().initModule()
self.adq = Adq()
self.adq.init(self.sr, self.nr)
self.roilist = []
def write_nr(self, value):
self.adq.init(self.sr, value)
def write_sr(self, value):
self.adq.init(value, self.nr)
def write_bw(self, value):
self.adq.bw_cutoff = value
def register_roi(self, roi):
self.roilist.append(roi)
def go(self):
self.starttime = time.time()
self.adq.start()
def read_value(self):
if self.get_rawdata(): # new data available
roilist = [r for r in self.roilist if r.enable]
freq = self.freq.value
gates = self.adq.gates_and_curves(self._data, freq,
(self.time, self.time + self.size),
[r.interval for r in roilist])
for i, roi in enumerate(roilist):
roi.i = a = gates[i][0]
roi.q = b = gates[i][1]
roi.value = math.sqrt(a ** 2 + b ** 2)
roi.phase = math.atan2(a, b) * 180 / math.pi
return self.adq.curves
# TODO: CONTROL
# inphase = self.roilist[0].i
# if self.control:
# newfreq = freq + inphase * self.slope - self.basefreq
# # step = sorted((-self.maxstep, inphase * self.slope, self.maxstep))[1]
# if self.old:
# fdif = freq - self.old[0]
# idif = inphase - self.old[1]
# if abs(fdif) >= self.minstep:
# self.slope = - fdif / idif
# else:
# fdif = 0
# idif = 0
# newfreq = freq + self.minstep
# self.old = (freq, inphase)
# if self.skipctrl > 0: # do no control for some time after changing frequency
# self.skipctrl -= 1
# elif self.control:
# self.freq = sorted((self.freq - self.maxstep, newfreq, self.freq + self.maxstep))[1]
class RUS(Base):
value = Parameter('averaged (I, Q) tuple', TupleOf(FloatRange(), FloatRange()))
periods = Parameter('number of periods', IntRange(1, 9999), default=12)
scale = Parameter('scale,taking into account input attenuation', FloatRange(), default=0.1)
input_phase_stddev = Parameter('input signal quality', FloatRange(unit='rad'))
output_phase_slope = Parameter('output signal phase slope', FloatRange(unit='rad/sec'))
output_amp_slope = Parameter('output signal amplitude change', FloatRange(unit='1/sec'))
phase = Parameter('phase', FloatRange(unit='deg'))
amp = Parameter('amplitude', FloatRange())
starttime = None
_data_args = None
def initModule(self):
super().initModule()
self.adq = Adq()
# self.write_periods(self.periods)
def read_value(self):
if self._data_args is None:
return self.value # or may we raise as no value is defined yet?
data = self.get_data(RUSdata, *self._data_args)
if data:
# data available
data.calc_quality()
self.input_phase_stddev = data.input_stddev.imag
self.output_phase_slope = data.output_slope.imag
self.output_amp_slope = data.output_slope.real
iq = data.iq * self.scale
self.phase = np.arctan2(iq.imag, iq.real) * 180 / np.pi
self.amp = np.abs(iq.imag, iq.real)
return iq.real, iq.imag
return self.value
def go(self):
self.starttime = time.time()
freq = self.freq.value
self._data_args = (RUSdata, freq, self.periods)
self.sr = round(self.periods * self.adq.sample_rate / freq)
self.adq.init(self.sr, 1)
self.adq.start()
self.read_status()
class ControlLoop:
maxstep = Parameter('max frequency step', FloatRange(unit='Hz'), readonly=False,
default=10000)
minstep = Parameter('min frequency step for slope calculation', FloatRange(unit='Hz'),
readonly=False, default=4000)
slope = Parameter('inphase/frequency slope', FloatRange(), readonly=False,
default=1e6)
# class Frequency(HasIO, Readable):
# pars = Attached()
# curves = Attached(mandatory=False)
# maxy = Property('plot y scale', datatype=FloatRange(), default=0.5)
#
# value = Parameter('frequency@I,q', datatype=FloatRange(unit='Hz'), default=0)
# basefreq = Parameter('base frequency', FloatRange(unit='Hz'), readonly=False)
# nr = Parameter('number of records', datatype=IntRange(1,10000), default=500)
# sr = Parameter('samples per record', datatype=IntRange(1,1E9), default=16384)
# freq = Parameter('target frequency', FloatRange(unit='Hz'), readonly=False)
# bw = Parameter('bandwidth lowpassfilter', datatype=FloatRange(unit='Hz'),default=10E6)
# amp = Parameter('amplitude', FloatRange(unit='dBm'), readonly=False)
# control = Parameter('control loop on?', BoolType(), readonly=False, default=True)
# rusmode = Parameter('RUS mode on?', BoolType(), readonly=False, default=False)
# time = Parameter('pulse start time', FloatRange(unit='nsec'),
# readonly=False)
# size = Parameter('pulse length (starting from time)', FloatRange(unit='nsec'),
# readonly=False)
# pulselen = Parameter('adjusted pulse length (integer number of periods)', FloatRange(unit='nsec'), default=1)
# maxstep = Parameter('max frequency step', FloatRange(unit='Hz'), readonly=False,
# default=10000)
# minstep = Parameter('min frequency step for slope calculation', FloatRange(unit='Hz'),
# readonly=False, default=4000)
# slope = Parameter('inphase/frequency slope', FloatRange(), readonly=False,
# default=1e6)
# plot = Parameter('create plot images', BoolType(), readonly=False, default=True)
# save = Parameter('save data', BoolType(), readonly=False, default=True)
# pollinterval = Parameter(datatype=FloatRange(0,120))