def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
from wp_toolbox.qtlab_data import save
save(self.get_name(), meta, x__x__um=self._x, y__y__um=self._y,
z__counts__Hz=self._data['countrates'])
def _start_running(self):
CyclopeanInstrument._start_running(self)
self._counter = self._ins_count.get_is_running()
self._ins_count.set_is_running(False)
self.setup_data()
self._current_line = 0
self._last_line = 0
def _start_running(self):
CyclopeanInstrument._start_running(self)
self._counter = self._ins_count.get_is_running()
self._ins_count.set_is_running(False)
self.setup_data()
self._current_line = 0
self._last_line = 0
def _start_running(self):
CyclopeanInstrument._start_running(self)
self._ins_ADwin.Stop_Process(4)
self._ins_ADwin.Load('D:\\Lucio\\AdWin codes\\ADwin_Gold_II\\simple_counting.tb4')
self._ins_ADwin.Set_Par(24,self._integration_time)
time.sleep(0.001)
self._ins_ADwin.Start_Process(4)
def __init__(self, name, channel='1'):
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# relevant parameters
self.add_parameter('countrate',
flags=Instrument.FLAG_GET,
units='Hz',
tags=['measure'],
channels=('cntr1', 'cntr2'),
channel_prefix='%s_',
doc="""
Returns the count rates for all counters.
""")
# public functions
self.add_function("monitor_countrates")
# init parameters
self._countrate = {'cntr1': 0.0, 'cntr2': 0.0, }
# instruments we need to access
# import qt
# self._ins_adwin = qt.instruments['adwin']
# cyclopean features
self._supported = {
'get_running': True,
'get_recording': True,
'set_running': True,
'set_recording': False,
'save': False,
}
self._busy = False
def __init__(self, name, adwin, **kw):
print 'init cyclopean_instrument'
CyclopeanInstrument.__init__(self, name, tags=[])
print 'initialising masterofchar'
self._adwin = qt.instruments[adwin]
self._fine_piezos = 'PI_fine_tuning'
#self.set_fine_piezo_voltages(0,0,0)
# #design properties in mm (see JPE datasheet).
# self.cfg_pars = moc_cfg.config['moc_cav1']
# self.fiber_z_offset = self.cfg_pars['fiber_z_offset'] #fiber offset with respect to fiber interface
# self.h = self.cfg_pars['h_mm']+self.fiber_z_offset#33.85+self.fiber_z_offset
# self.R = self.cfg_pars['R_mm']#14.5
# self.max_spindle_steps = self.cfg_pars['max_spindle_steps']
# #Cartesian coordinates in the lab-frame (mm)
self.track_v_piezo_1 = None
# Do I need this?
# reinit_spindles = kw.pop('reinit_spindles', False)
# if reinit_spindles:
# self.reset_spindle_tracker()
# else:
# print 'Tracker initialized from file...'
# self.tracker_file_readout()
self.add_function('set_fine_piezo_voltages')
def _start_running(self):
#print 'counters started running'
CyclopeanInstrument._start_running(self)
self._ins_adwin.start_counter(
set_integration_time=self._integration_time,
set_avg_periods=self._avg_periods,
set_single_run=0)
def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
from wp_toolbox.qtlab_data import save
save(self.get_name(), meta, x__x__um=self._x, y__y__um=self._y,
z__counts__Hz=self._data['countrates'], do_plot=False)
def _start_running(self):
#print 'counters started running'
CyclopeanInstrument._start_running(self)
self._ins_adwin.start_counter(
set_integration_time=self._integration_time,
set_avg_periods=self._avg_periods,
set_single_run=0)
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=['measure', 'generate', 'virtual'])
# relevant parameters
self.add_parameter('integration_time',
type=types.IntType,
flags=Instrument.FLAG_SET | Instrument.FLAG_SOFTGET,
units='ms',
minval=1, maxval=10000,
doc="""
How long to count to determine the rate.
""")
self.add_parameter('channel',
type=types.IntType,
flags=Instrument.FLAG_SET | Instrument.FLAG_SOFTGET,
units='',
minval=1, maxval=5,
doc="""
ADwin counter channel (1 - 4) or ADwiun counter 1 + counter 2 (channel 5)
""")
self.add_parameter('counts',
type=types.IntType,
flags=Instrument.FLAG_GET,
units='counts',
tags=['measure'],
doc="""
Returns the counts acquired during the last counting period.
""")
self.add_parameter('countrate',
type=types.IntType,
flags=Instrument.FLAG_GET,
units='Hz',
tags=['measure'],
doc="""
Returns the count rate based on the current count value.
""")
# init parameters
self.set_channel(5)
self._counts = 0
self._countrate = 0
# instruments we need to access
import qt
# self._ins_pos = qt.instruments['dummy_pos']
self._ins_ADwin = qt.instruments['ADwin']
self.set_integration_time(20.0)
self._supported = {
'get_running': True,
'get_recording': True,
'set_running': True,
'set_recording': False,
'save': False,
}
def _start_running(self):
CyclopeanInstrument._start_running(self)
self._prepare()
self._linescan.set_is_running(True)
qt.msleep(0.1)
while self._linescan.get_is_running():
qt.msleep(0.1)
return self._process_fit()
def _start_running(self):
CyclopeanInstrument._start_running(self)
self._prepare()
self._linescan.set_is_running(True)
qt.msleep(0.1)
while self._linescan.get_is_running():
qt.msleep(0.1)
return self._process_fit()
def _start_running(self):
CyclopeanInstrument._start_running(self)
self._ins_ADwin.Stop_Process(4)
self._ins_ADwin.Load(
'D:\\Lucio\\AdWin codes\\ADwin_Gold_II\\simple_counting.tb4')
self._ins_ADwin.Set_Par(24, self._integration_time)
time.sleep(0.001)
self._ins_ADwin.Start_Process(4)
def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
# NOTE a test of hdf5 data
dat = h5.HDF5Data(name=self.get_name())
dat.create_dataset('x', data=self._x)
dat.create_dataset('y', data=self._y)
dat.create_dataset('countrate', data=self._data['countrates'])
dat.close()
def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
from wp_toolbox import qtlab_data
qtlab_data.save(self.get_name(),
meta,
x__x__um=self._x,
y__y__um=self._y,
z__counts__Hz=self._data)
def _start_running(self):
CyclopeanInstrument._start_running(self)
# make sure the counter is off.
if self._counters.get_is_running():
self._counter_was_running = True
self._counters.set_is_running(False)
self.setup_data()
self._current_line = 0
self._last_line = 0
self._next_line()
def _start_running(self):
CyclopeanInstrument._start_running(self)
# make sure the counter is off.
if self._counters.get_is_running():
self._counter_was_running = True
self._counters.set_is_running(False)
self.setup_data()
self._current_line = 0
self._last_line = 0
self._next_line()
def __init__(self, name, adwin):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# relevant parameters
self.add_parameter('countrate',
flags=Instrument.FLAG_GET,
units='Hz',
type=types.FloatType,
tags=['measure'],
channels=('cntr1', 'cntr2', 'cntr3'),
channel_prefix='%s_',
doc="""
Returns the count rates for all counters.
""")
self.add_parameter('integration_time',
flags=Instrument.FLAG_GETSET,
units='ms',
minval=1,
maxval=1e6,
type=types.IntType)
self.add_parameter('avg_periods',
flags=Instrument.FLAG_GETSET,
minval=1,
maxval=1e6,
type=types.IntType)
# init parameters
self._countrate = {'cntr1': 0.0, 'cntr2': 0.0, 'cntr3': 0.0}
self._integration_time = 1
self._avg_periods = 100
# instruments we need to access
self._ins_adwin = qt.instruments[adwin]
# cyclopean features
self._supported = {
'get_running': True,
'get_recording': True,
'set_running': True,
'set_recording': False,
'save': False,
}
self._busy = False
def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
import qt
qt.mstart()
data = qt.Data(name='dummy 2D scan')
data.add_coordinate('x [um]')
data.add_coordinate('y [um]')
data.add_value('counts [Hz]')
data.create_file()
for i in range(self._xsteps):
for j in range(self._ysteps):
data.add_data_point(self._x[i], self._y[j], self._data[j, i])
data.new_block()
data.close_file()
qt.mend()
def _start_running(self):
CyclopeanInstrument._start_running(self)
# determine points of the line
self._points = zeros((len(self._dimensions), self._steps))
for i,d in enumerate(self._dimensions):
self._points[i,:] = linspace(self._starts[i], self._stops[i],self._steps)
# start the linescan
if not self._mos.linescan_start(self._dimensions, self._starts,
self._stops, self._steps, self._px_time,
value=self._scan_value):
self.set_is_running(False)
def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
import qt
qt.mstart()
data = qt.Data(name='dummy 2D scan')
data.add_coordinate('x [um]')
data.add_coordinate('y [um]')
data.add_value('counts [Hz]')
data.create_file()
for i in range(self._xsteps):
for j in range(self._ysteps):
data.add_data_point(self._x[i], self._y[j], self._data[j,i])
data.new_block()
data.close_file()
qt.mend()
def _start_running(self):
CyclopeanInstrument._start_running(self)
# initalize data field and set current status (i.e, empty)
# general feature for scan: data for points
#
# create a field of correct shape; each line, in whatever form
# specified via starts and stops gets their own points
pts_shape = list(self._linescan_starts.shape)
pts_shape.append(self._linescan_steps)
pts = zeros(tuple(pts_shape))
dim_lines = zeros(self._linescan_starts.shape)
dim_lines_flat = dim_lines.flat
# index gets incremented after the item is being read out, so we
# start populating before the first readout and stop before the
# last one
ndx = dim_lines_flat.coords
pts[ndx] = linspace(self._linescan_starts[ndx],
self._linescan_stops[ndx], self._linescan_steps)
# line index of course without the dimensions in which we scan
self._current_line = ndx[:-1]
# print self._current_line
for i in dim_lines_flat:
i = linspace(self._linescan_starts[ndx], self._linescan_stops[ndx],
self._linescan_steps)
if dim_lines_flat.index < dim_lines.size:
ndx = dim_lines_flat.coords
pts[ndx] = linspace(self._linescan_starts[ndx],
self._linescan_stops[ndx],
self._linescan_steps)
self._data['points'] = pts
# set up correct data field, to be implemented by user
self._setup_data()
# hook up linescanner changes
self._linescan.connect('changed', self._linescan_update)
# now start the actual scanning
self._next_line()
def _start_running(self):
CyclopeanInstrument._start_running(self)
# initalize data field and set current status (i.e, empty)
# general feature for scan: data for points
#
# create a field of correct shape; each line, in whatever form
# specified via starts and stops gets their own points
pts_shape = list(self._linescan_starts.shape)
pts_shape.append(self._linescan_steps)
pts = zeros(tuple(pts_shape))
dim_lines = zeros(self._linescan_starts.shape)
dim_lines_flat = dim_lines.flat
# index gets incremented after the item is being read out, so we
# start populating before the first readout and stop before the
# last one
ndx = dim_lines_flat.coords
pts[ndx] = linspace(self._linescan_starts[ndx],
self._linescan_stops[ndx], self._linescan_steps)
# line index of course without the dimensions in which we scan
self._current_line = ndx[:-1]
# print self._current_line
for i in dim_lines_flat:
i = linspace(self._linescan_starts[ndx],
self._linescan_stops[ndx], self._linescan_steps)
if dim_lines_flat.index < dim_lines.size:
ndx = dim_lines_flat.coords
pts[ndx] = linspace(self._linescan_starts[ndx],
self._linescan_stops[ndx], self._linescan_steps)
self._data['points'] = pts
# set up correct data field, to be implemented by user
self._setup_data()
# hook up linescanner changes
self._linescan.connect('changed', self._linescan_update)
# now start the actual scanning
self._next_line()
def __init__(self, name, adwin):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# relevant parameters
self.add_parameter('countrate',
flags=Instrument.FLAG_GET,
units='Hz',
tags=['measure'],
channels=('cntr1', 'cntr2'),
channel_prefix='%s_',
doc="""
Returns the count rates for all counters.
""")
self.add_parameter('integration_time',
flags=Instrument.FLAG_GETSET,
units='ms',
minval=1,
maxval=1e6)
self.add_parameter('avg_periods',
flags=Instrument.FLAG_GETSET,
minval=1,
maxval=1e6)
# init parameters
self._countrate = {'cntr1': 0.0, 'cntr2': 0.0, }
self._integration_time = 1
self._avg_periods = 100
# instruments we need to access
self._ins_adwin = qt.instruments[adwin]
# cyclopean features
self._supported = {
'get_running': True,
'get_recording': True,
'set_running': True,
'set_recording': False,
'save': False,
}
self._busy = False
def __init__(self, name, use={}):
CyclopeanInstrument.__init__(self, name, tags=[], use=use)
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('keyword',
type = types.StringType,
flags=Instrument.FLAG_GETSET,
units='' )
self.add_function('set_control_variable')
self.add_function('get_control_variable')
def __init__(self, name, use={}):
CyclopeanInstrument.__init__(self, name, tags=[], use=use)
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('keyword',
type=types.StringType,
flags=Instrument.FLAG_GETSET,
units='')
self.add_function('set_control_variable')
self.add_function('get_control_variable')
def __init__(self, name, linescan, mos):
CyclopeanInstrument.__init__(self, name, tags=['measure'])
self._mos = qt.instruments[mos]
self._linescan = qt.instruments[linescan]
# add the relevant parameters for a scanner based on line scans
self.add_parameter('linescan_dimensions',
type=types.TupleType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('linescan_px_time',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='ms')
self.add_parameter('linescan_steps',
type=types.IntType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('linescan_starts',
type=types.ListType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('linescan_stops',
type=types.ListType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('current_line',
type=types.TupleType,
flags=Instrument.FLAG_GET)
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': True,
}
# initialize vars
self._current_line = ()
def __init__(self, name, linescan, mos):
CyclopeanInstrument.__init__(self, name, tags=['measure'])
self._mos = qt.instruments[mos]
self._linescan = qt.instruments[linescan]
# add the relevant parameters for a scanner based on line scans
self.add_parameter('linescan_dimensions',
type=types.TupleType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('linescan_px_time',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='ms')
self.add_parameter('linescan_steps',
type=types.IntType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('linescan_starts',
type=types.ListType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('linescan_stops',
type=types.ListType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('current_line',
type=types.TupleType,
flags=Instrument.FLAG_GET)
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': True,
}
# initialize vars
self._current_line = ()
def _start_running(self):
CyclopeanInstrument._start_running(self)
# determine points of the line
self._points = zeros((len(self._dimensions), self._steps))
for i, d in enumerate(self._dimensions):
self._points[i, :] = linspace(self._starts[i], self._stops[i],
self._steps)
# start the linescan
if not self._mos.linescan_start(self._dimensions,
self._starts,
self._stops,
self._steps,
self._px_time,
value=self._scan_value):
self.set_is_running(False)
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('doubleSpinBox_start_F',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=99.0,
doc='')
self._doubleSpinBox_start_F = 0.0
self.add_parameter('doubleSpinBox_stop_f',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=99.0,
doc='')
self._doubleSpinBox_stop_f = 0.0
self.add_parameter('doubleSpinBox_step_f',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=99.0,
doc='')
self._doubleSpinBox_step_f = 0.0
self.add_function('start_scan_button')
self.add_function('stop_scan_button')
self.add_function('save_scan_button')
def _start_running(self):
CyclopeanInstrument._start_running(self)
# determine points of the line in x/y space
self._ins_ADwin.Start_Process(2)
while self._ins_ADwin.Process_Status(2) > 0:
# qt.msleep(0.1)
time.sleep(0.01)
channel = self._ins_ADwin_count.get_channel()
if channel < 5:
self._values = self._ins_ADwin.Get_Data_Long(
channel, 1, self._nr_of_points)
elif channel == 5:
self._values = numpy.add(
self._ins_ADwin.Get_Data_Long(1, 1, self._nr_of_points),
self._ins_ADwin.Get_Data_Long(2, 1, self._nr_of_points))
self.get_values()
self.do_set_is_running(False)
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('t_range',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=99,
doc='')
self._t_range = 0
self.add_parameter('integration_time',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=99,
doc='')
self._integration_time = 0
self.add_parameter('countrate',
type=types.IntType,
flags=Instrument.FLAG_GET,
units='',
doc='')
self._countrate = 0
self.set_is_running(True)
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('t_range',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=99,
doc='')
self._t_range = 0
self.add_parameter('integration_time',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=99,
doc='')
self._integration_time = 0
self.add_parameter('countrate',
type=types.IntType,
flags=Instrument.FLAG_GET,
units='',
doc='')
self._countrate = 0
self.set_is_running(True)
def __init__(self, name, jpe, adwin, laser, use_cfg=False, **kw):
CyclopeanInstrument.__init__(self, name, tags=[])
self._laser = qt.instruments[laser]
self._adwin = qt.instruments[adwin]
self._jpe_cadm = qt.instruments[jpe]
self._laser_updated = False
print 'Initializing master_of_cavity... '
self.add_parameter('address',
flags=Instrument.FLAG_GETSET,
type=types.IntType)
self.address = 1
self.add_parameter('temperature',
flags=Instrument.FLAG_GETSET,
units='K',
type=types.IntType,
minval=0,
maxval=300)
self.temperature = 300
self.add_parameter('JPE_freq',
flags=Instrument.FLAG_GETSET,
units='Hz',
type=types.IntType,
minval=0,
maxval=600)
self.JPE_freq = 100
self.add_parameter('rel_step_size',
flags=Instrument.FLAG_GETSET,
units='%',
type=types.IntType,
minval=0,
maxval=100)
self.rel_step_size = 30
self.add_parameter('track_curr_x',
type=types.FloatType,
flags=Instrument.FLAG_GET,
units='nm')
self.add_parameter('track_curr_y',
type=types.FloatType,
flags=Instrument.FLAG_GET,
units='nm')
self.add_parameter('track_curr_z',
type=types.FloatType,
flags=Instrument.FLAG_GET,
units='nm')
self.addr = 1
self.ch_x = 1
self.ch_y = 2
self.ch_z = 3
# self._jpe_tracker = JPE_pos_tracker(reinit_spindles=False)
self._step_size = None
self._fine_piezos = [
'jpe_fine_tuning_1', 'jpe_fine_tuning_2', 'jpe_fine_tuning_3'
]
#self.set_fine_piezo_voltages(0,0,0)
# Init that was originally in the JPE_pos_tracker.
# all coordinates are in mm, angles in radians
# the number of spindle rotations for z1,z2,z3
self.track_z1 = 0
self.track_z2 = 0
self.track_z3 = 0
#design properties in mm (see JPE Interface drawings).
self.cfg_pars = moc_cfg.config['moc_cav1']
self.fiber_z_offset = self.cfg_pars[
'fiber_z_offset'] #fiber offset with respect to fiber interface
self.h = self.cfg_pars[
'h_mm'] + self.fiber_z_offset #33.85+self.fiber_z_offset
self.R = self.cfg_pars['R_mm'] #14.5
self.max_spindle_steps = self.cfg_pars['max_spindle_steps']
#Cartesian coordinates in the lab-frame (mm)
self.track_curr_x = 0
self.track_curr_y = 0
self.track_curr_z = 0
self.track_v_piezo_1 = None
self.track_v_piezo_2 = None
self.track_v_piezo_3 = None
self.tracker_file_name = 'D:\measuring\measurement\config\jpe_tracker.npz'
reinit_spindles = kw.pop('reinit_spindles', False)
if reinit_spindles:
self.reset_spindle_tracker()
else:
print 'Tracker initialized from file...'
self.tracker_file_readout()
#variable properties are saved in the cfg file
if use_cfg:
cfg_fn = os.path.join(qt.config['ins_cfg_path'], name + '.cfg')
if not os.path.exists(cfg_fn):
_f = open(cfg_fn, 'w')
_f.write('')
_f.close()
self.ins_cfg = config.Config(cfg_fn)
self.load_cfg()
self.save_cfg()
# remote access functions:
self.add_function('get_params')
self.add_function('get_track_z')
self.add_function('status')
#position control function
self.add_function('step')
self.add_function('set_as_origin')
self.add_function('move_to_xyz')
self.add_function('set_fine_piezo_voltages')
self.add_function('move_spindle_steps')
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('test_value',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=1,
maxval=100,
doc='')
self._test_value = 10
self.add_parameter('float_test_value',
type=types.FloatType,
flags=Instrument.FLAG_GET,
units='',
minval=0.0,
maxval=99.0,
doc='')
self._float_test_value = 0.0
self.add_parameter('string_test_value',
type=types.StringType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._string_test_value = 'Test'
self.add_parameter('slider_value',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=99,
doc='')
self._slider_value = 0
self.add_parameter('check_value',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._check_value = False
self.add_parameter('radio1',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._radio1 = True
self.add_parameter('radio2',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._radio2 = False
self.add_parameter('radio3',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._radio3 = False
self.add_function('do_something')
self.add_function('do_something_else')
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('keyword',
type=types.StringType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._keyword = ''
self.add_parameter('x',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=-100.000000000000000,
maxval=100.000000000000000,
doc='')
self._x = 0.0
self.add_parameter('y',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=-100.000000000000000,
maxval=100.000000000000000,
doc='')
self._y = 0.0
self.add_parameter('z',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=100.000000000000000,
doc='')
self._z = 0.0
self.add_parameter('z_slider',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=400,
doc='')
self._z_slider = 500
self.add_parameter('step',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=99.0,
doc='')
self._step = 1.000000000000000
self.add_function('step_up')
self.add_function('step_left')
self.add_function('step_right')
self.add_function('step_down')
def __init__(self, name):
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# also get the counter, need to disable when linescanning
self._counters = qt.instruments['counters_demo']
self._counter_was_running = False
# add the relevant parameters for a 2D PL scanner
self.add_parameter('pixel_time', type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='ms',
minval=1.0, maxval=99.0,
doc="""
Integration time per image pixel.
""")
self.add_parameter('xstart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('xstop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('ystart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('ystop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('xsteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='')
self.add_parameter('ysteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='')
self.add_parameter('last_line_index',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='',
doc="""
Returns the index of the last line of which data
is available.
""")
self.add_parameter('last_line',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='cps',
doc="""
Returns the last line of the measured data.
""")
self.add_parameter('counter',
type=types.IntType,
flags=Instrument.FLAG_GETSET)
# relevant functions to be visible outside
self.add_function('get_line')
self.add_function('get_lines')
self.add_function('get_x')
self.add_function('get_y')
self.add_function('get_data')
self.add_function('setup_data')
# self.add_function('move_abs_xy')
# default params
self.set_pixel_time(1.0)
self.set_xstart(-2.0)
self.set_xstop(2.0)
self.set_ystart(-2.0)
self.set_ystop(2.0)
self.set_xsteps(11)
self.set_ysteps(11)
self.set_counter(1)
# more set up
self.setup_data()
self._current_line = 0
self._last_line = 0
self._busy = False
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': True,
}
def __init__(self, name):
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# also get the counter, need to disable when linescanning
self._counters = qt.instruments['counters_demo']
self._counter_was_running = False
# add the relevant parameters for a 2D PL scanner
self.add_parameter('pixel_time',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='ms',
minval=1.0,
maxval=99.0,
doc="""
Integration time per image pixel.
""")
self.add_parameter('xstart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('xstop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('ystart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('ystop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um')
self.add_parameter('xsteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='')
self.add_parameter('ysteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='')
self.add_parameter('last_line_index',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='',
doc="""
Returns the index of the last line of which data
is available.
""")
self.add_parameter('last_line',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='cps',
doc="""
Returns the last line of the measured data.
""")
self.add_parameter('counter',
type=types.IntType,
flags=Instrument.FLAG_GETSET)
# relevant functions to be visible outside
self.add_function('get_line')
self.add_function('get_lines')
self.add_function('get_x')
self.add_function('get_y')
self.add_function('get_data')
self.add_function('setup_data')
# self.add_function('move_abs_xy')
# default params
self.set_pixel_time(1.0)
self.set_xstart(-2.0)
self.set_xstop(2.0)
self.set_ystart(-2.0)
self.set_ystop(2.0)
self.set_xsteps(11)
self.set_ysteps(11)
self.set_counter(1)
# more set up
self.setup_data()
self._current_line = 0
self._last_line = 0
self._busy = False
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': True,
}
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=["positioner", "virtual"])
self.add_parameter(
"X_position", type=types.FloatType, flags=Instrument.FLAG_GETSET, units="um", format="%.03f, %.03f"
)
self.add_parameter(
"Y_position", type=types.FloatType, flags=Instrument.FLAG_GETSET, units="um", format="%.03f, %.03f"
)
self.add_parameter(
"Z_position", type=types.FloatType, flags=Instrument.FLAG_GETSET, units="um", format="%.03f, %.03f"
)
self.add_parameter(
"speed",
type=types.FloatType,
flags=Instrument.FLAG_SET | Instrument.FLAG_SOFTGET,
format="%.01f, %.01f",
units="V/s",
)
self.add_parameter("LT", type=types.IntType, flags=Instrument.FLAG_GETSET, minval=0, maxval=1)
# self.add_function('move_abs_xy')
self._X_position = 0.0
self._Y_position = 0.0
self._Z_position = 0.0
self._speed = 1.0
self._LT = 0 # set to 1 for low temperature operation
self._max_x_RT = 40.0 # micrometer
self._max_y_RT = self._max_x_RT # micrometer
self._max_z_RT = 24.0 # micrometer
self._cal_x_RT = 107.0 # mV/micrometer
self._cal_y_RT = self._cal_x_RT # mV/micrometer
self._cal_z_RT = 171.4 # mV/micrometer
self._max_V_RT = 4.29 # Volt
self._max_x_LT = 30.0 # micrometer
self._max_y_LT = self._max_x_LT # micrometer
self._max_z_LT = 15.0 # micrometer
self._cal_x_LT = 357.0 # mV/micrometer
self._cal_y_LT = self._cal_x_LT # mV/micrometer
self._cal_z_LT = 714.3 # mV/micrometer
self._max_V_LT = 10.0 # Volt
self._max_speed = 1.0 # V/s
self._supported = {
"get_running": False,
"get_recording": False,
"set_running": False,
"set_recording": False,
"save": False,
}
import qt
self._ins_ADwin = qt.instruments["ADwin"]
self._ins_ADwin.Load("D:\\Lucio\\AdWin codes\\ADwin_Gold_II\\cursor_move.tb0")
if self._speed <= self._max_speed:
self._ins_ADwin.Set_FPar(29, self._speed * 1000.0)
else:
self._ins_ADwin.Set_FPar(29, self._max_speed * 1000.0)
self.set_speed(1.0)
def __init__(self, name, adwin, dimension_set):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['positioner'])
self._adwin = qt.instruments[adwin]
# should not change often, hardcode is fine for now
self.rt_dimensions = moscfg.config[dimension_set]['rt_dimensions']
self.lt_dimensions = moscfg.config[dimension_set]['lt_dimensions']
self.dimensions = self.rt_dimensions
# auto generate parameters incl set and get for all dimensions
self._make_get_set()
# scan control
self._linescan_running = False
self._linescan_px_clock = 0
self.add_parameter('linescan_running',
type=types.BooleanType,
flags=Instrument.FLAG_GET)
self.add_parameter('linescan_px_clock',
type=types.IntType,
flags=Instrument.FLAG_GET)
self.add_function('linescan_start')
# for positioning with attocubes
self.add_parameter('lt_settings',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET)
self._lt_settings = False
# managing the coordinate system
self.add_function('set_origin')
self.add_function('get_origin')
self.add_function('from_relative')
self.add_function('to_relative')
self.add_function('set_relative_position')
self.add_function('get_relative_position')
self.add_function('move_to_xyz_pos')
# markers
self._markers = {}
self.add_function('set_marker')
self.add_function('get_marker')
self.add_function('get_markers')
self.add_function('goto_marker')
self.add_function('push_position')
self.add_function('pop_position')
self.add_function('init_positions_from_adwin_dacs')
# set up config file
cfg_fn = os.path.join(qt.config['ins_cfg_path'], name+'.cfg')
if not os.path.exists(cfg_fn):
_f = open(cfg_fn, 'w')
_f.write('')
_f.close()
self.ins_cfg = config.Config(cfg_fn)
self.load_cfg()
self.save_cfg()
self.init_positions_from_adwin_dacs()
def __init__(self, name, adwin):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['positioner'])
self._adwin = qt.instruments[adwin]
# should not change often, hardcode is fine for now
self.rt_dimensions = {
'x': {
'dac': 'atto_x',
'micron_per_volt': 9.324,
'max_v': 4.29,
'min_v': 0.,
'default': 0.,
'origin': 0.,
},
'z': {
'dac': 'atto_z',
'micron_per_volt': 5.59,
'min_v': 0.,
'max_v': 4.29,
'default': 0.,
'origin': 0.,
},
'y': {
'dac': 'atto_y',
'micron_per_volt': 9.324,
'max_v': 4.29,
'min_v': 0.,
'default': 0.,
'origin': 0.,
},
}
self.lt_dimensions = {
'x': {
'dac': 'atto_x',
'micron_per_volt': 2.8,
'max_v': 10,
'min_v': 0.,
'default': 0.,
'origin': 0.,
},
'z': {
'dac': 'atto_z',
'micron_per_volt': 1.40,
'min_v': 0.,
'max_v': 10,
'default': 0.,
'origin': 0.,
},
'y': {
'dac': 'atto_y',
'micron_per_volt': 2.8,
'max_v': 10,
'min_v': 0.,
'default': 0.,
'origin': 0.,
},
}
self.dimensions = self.rt_dimensions
# auto generate parameters incl set and get for all dimensions
for d in self.dimensions:
dim = self.dimensions[d]
# make set and get
self._make_get(d)
self._make_set(d)
# make stepping function
self._make_stepfunc(d)
# register parameter (set and get need to exist already)
self.add_parameter(
d,
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um',
minval=dim['min_v'] * dim['micron_per_volt'],
maxval=dim['max_v'] * dim['micron_per_volt'],
)
# register the step function
self.add_function('step_' + d)
# scan control
self._linescan_running = False
self._linescan_px_clock = 0
self.add_parameter('linescan_running',
type=types.BooleanType,
flags=Instrument.FLAG_GET)
self.add_parameter('linescan_px_clock',
type=types.IntType,
flags=Instrument.FLAG_GET)
self.add_function('linescan_start')
# for positioning with attocubes
self.add_parameter('lt_settings',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET)
self._lt_settings = False
# managing the coordinate system
self.add_function('set_origin')
self.add_function('get_origin')
self.add_function('from_relative')
self.add_function('to_relative')
self.add_function('set_relative_position')
self.add_function('get_relative_position')
self.add_function('move_to_xyz_pos')
# markers
self._markers = {}
self.add_function('set_marker')
self.add_function('get_marker')
self.add_function('get_markers')
self.add_function('goto_marker')
self.add_function('push_position')
self.add_function('pop_position')
# set up config file
cfg_fn = os.path.join(qt.config['ins_cfg_path'], name + '.cfg')
if not os.path.exists(cfg_fn):
_f = open(cfg_fn, 'w')
_f.write('')
_f.close()
self.ins_cfg = config.Config(cfg_fn)
self.load_cfg()
self.save_cfg()
# set initial position values (need to know whether LT or RT settings)
for d in self.dimensions:
dim = self.dimensions[d]
voltage = self._adwin.get_dac_voltage(dim['dac'])
position = voltage * dim['micron_per_volt']
setattr(self, '_' + d, position)
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
self.add_parameter('keyword',
type=types.StringType,
flags=Instrument.FLAG_GETSET,
units='',
doc='')
self._keyword = ''
self.add_parameter('x',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=-100.000000000000000,
maxval=100.000000000000000,
doc='')
self._x = 0.0
self.add_parameter('y',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=-100.000000000000000,
maxval=100.000000000000000,
doc='')
self._y = 0.0
self.add_parameter('z',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=100.000000000000000,
doc='')
self._z = 0.0
self.add_parameter('z_slider',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=400,
doc='')
self._z_slider = 500
self.add_parameter('step',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0.0,
maxval=99.0,
doc='')
self._step = 1.000000000000000
self.add_function('step_up')
self.add_function('step_left')
self.add_function('step_right')
self.add_function('step_down')
def __init__(self, name, adwin, powermeter, parent=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._adwin = qt.instruments[adwin]
self._pmeter = qt.instruments[powermeter]
self.dac_no = 8
self.adc_no = 2
self.i = 0
self.sampling_interval = 100
self.add_parameter('plot_DFG_values',
flags=Instrument.FLAG_GET,
units='uW',
tags=['measure'],
channels=('temperature_channel', 'dfg_channel'),
channel_prefix='%s_',
doc="""
Returns the measured temperature and dfg power
""")
self._plot_DFG_values = {
'temperature_channel': 0.0,
'dfg_channel': 0.0,
}
self.add_parameter('curr_temperature',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='deg',
minval=-20,
maxval=120)
self.curr_temperature = 0
self.add_parameter('knob_temperature',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='deg',
minval=-20,
maxval=120)
self.knob_temperature = 0
self.add_parameter('DFG_power',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='muW',
minval=0,
maxval=2000)
self.DFG_power = 0
self.add_parameter('target_temperature',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='deg',
minval=-50,
maxval=120)
self.target_temperature = 0.00
self.add_parameter('set_temperature',
type=types.FloatType,
flags=Instrument.FLAG_SET,
units='deg',
minval=-50,
maxval=120)
self.set_temperature = 0.00
self.add_parameter('plot_temperature',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='deg',
minval=-50,
maxval=120)
self.plot_temperature = 0.00
self.add_parameter('plot_dfg',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='uW',
minval=-50,
maxval=120)
self.plot_dfg = 0.00
self.add_parameter('Tmin',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='deg',
minval=-50,
maxval=120)
self.Tmin = 0.00
self.add_parameter('Tmax',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='deg',
minval=-50,
maxval=120)
self.Tmax = 0.00
self.add_parameter('nsteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='',
minval=0,
maxval=1000)
self.nsteps = 0
self.add_parameter('dwell_time',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='us',
minval=0,
maxval=1000)
self.dwell_time = 0
# self.add_function('apply_voltage')
self.add_function('read_temperature')
self.add_function('read_DFG_power')
# self.add_function('readNset_target')
self.add_function('start_running')
# self.add_function('display_values')
self.add_function('check_knob_temperature')
def __init__(self, name, adwin, dimension_set):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['positioner'])
self._adwin = qt.instruments[adwin]
# should not change often, hardcode is fine for now
self.rt_dimensions = moscfg.config[dimension_set]['rt_dimensions']
self.lt_dimensions = moscfg.config[dimension_set]['lt_dimensions']
self.dimensions = self.rt_dimensions
# auto generate parameters incl set and get for all dimensions
self._make_get_set()
# scan control
self._linescan_running = False
self._linescan_px_clock = 0
self.add_parameter('linescan_running',
type=types.BooleanType,
flags=Instrument.FLAG_GET)
self.add_parameter('linescan_px_clock',
type=types.IntType,
flags=Instrument.FLAG_GET)
self.add_function('linescan_start')
# for positioning with attocubes
self.add_parameter('lt_settings',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET)
self._lt_settings = False
# managing the coordinate system
self.add_function('set_origin')
self.add_function('get_origin')
self.add_function('from_relative')
self.add_function('to_relative')
self.add_function('set_relative_position')
self.add_function('get_relative_position')
self.add_function('move_to_xyz_pos')
# markers
self._markers = {}
self.add_function('set_marker')
self.add_function('get_marker')
self.add_function('get_markers')
self.add_function('goto_marker')
self.add_function('push_position')
self.add_function('pop_position')
self.add_function('init_positions_from_adwin_dacs')
# set up config file
cfg_fn = os.path.join(qt.config['ins_cfg_path'], name+'.cfg')
if not os.path.exists(cfg_fn):
_f = open(cfg_fn, 'w')
_f.write('')
_f.close()
self.ins_cfg = config.Config(cfg_fn)
self.load_cfg()
self.save_cfg()
self.init_positions_from_adwin_dacs()
def save(self, meta=""): # inherited doesn't do any saving. Implement.
CyclopeanInstrument.save(self, meta)
return
def save(self, meta=""): # inherited doesn't do any saving. Implement.
CyclopeanInstrument.save(self, meta)
return
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self,
name,
tags=['measure', 'generate', 'virtual'])
# add the relevant parameters for a 2D PL scanner
self.add_parameter('pixel_time',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='ms',
minval=1,
maxval=1000,
doc="""
Integration time per image pixel.
""")
self.add_parameter('xstart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0,
maxval=50.0,
units='um')
self.add_parameter('xstop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0,
maxval=50.0,
units='um')
self.add_parameter('ystart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0,
maxval=50.0,
units='um')
self.add_parameter('ystop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0,
maxval=50.0,
units='um')
self.add_parameter('xsteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
minval=2,
maxval=1000,
units='')
self.add_parameter('ysteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
minval=2,
maxval=1000,
units='')
self.add_parameter('data',
tags=['measure'],
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='cps',
doc="""
Returns the full data array, not a single value.
The dimensions are given by the scan settings.
""")
self.add_parameter('x',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='um',
doc="""
Returns the x coordinates of the data pixels.
""")
self.add_parameter('y',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='um',
doc="""
Returns the y coordinates of the data pixels.
""")
self.add_parameter('last_line_index',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='',
doc="""
Returns the index of the last line of which data is
available.
""")
self.add_parameter('last_line',
tags=['measure'],
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='cps',
doc="""
Returns the last line of the measured data.
""")
# relevant functions to be visible outside
# a method that gives only a specified range of lines back
# (minimize data exchange)
self.add_function('get_line')
self.add_function('get_lines')
# method to set up the data field: after setting the scan area, use this
# to create a data field of appropriate size
self.add_function('setup_data')
# default params
self.set_pixel_time(10)
self.set_xstart(0.0)
self.set_xstop(10.0)
self.set_ystart(0.0)
self.set_ystop(10.0)
self.set_xsteps(101)
self.set_ysteps(101)
self.set_sampling_interval(500)
# more set up
self.setup_data()
self._current_line = 0
self._last_line = 0
# instruments and access functions for the panels
import qt
self._ins_linescan = qt.instruments['ADwin_linescan']
self._ins_pos = qt.instruments['ADwin_pos']
self._ins_count = qt.instruments['ADwin_count']
self.add_function('move_abs_xy')
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': True,
}
self._busy = False
self._counter = False
def _stop_running(self):
CyclopeanInstrument._start_running(self)
return
def _start_running(self):
CyclopeanInstrument._start_running(self)
def __init__(self, name, adwin, mos, *arg, **kw):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
mos : string
qtlab-name of the master of space to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# adwin and positioner
self._adwin = qt.instruments[adwin]
self._mos = qt.instruments[mos]
self._scan_value = 'counts'
# connect the mos to monitor methods
self._mos.connect('changed', self._mos_changed)
# params that define the linescan
self.add_parameter(
'dimensions',
type=types.TupleType,
flags=Instrument.FLAG_GETSET,
doc="""Sets the names of the dimensions involved, as specified
in the master of space""")
self.add_parameter('starts',
type=types.TupleType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('stops',
type=types.TupleType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('steps',
type=types.IntType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('px_time',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='ms')
self.add_parameter('scan_value',
type=types.StringType,
flags=Instrument.FLAG_GETSET)
self.add_function('get_points')
self._points = ()
# self._values = {1: [], 2: []}
self.set_steps(1)
self.set_px_time(1)
self.set_dimensions(())
self.set_starts(())
self.set_stops(())
self.set_scan_value('counts')
# other vars
self._px_clock = 0
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
def __init__(self, name, adwin, powermeter, parent=None):
CyclopeanInstrument.__init__(self, name, tags=[])
self._adwin = adwin
self._pmeter = powermeter
def __init__(self, name, linescan, mos, counters):
CyclopeanInstrument.__init__(self, name, tags=[])
self._linescan = qt.instruments[linescan]
self._mos = qt.instruments[mos]
self._counters = qt.instruments[counters]
self._counter_was_running = False
self.add_parameter('dimension',
type=types.StringType,
flags=Instrument.FLAG_GETSET)
self.add_parameter(
'scan_length',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um',
)
self.add_parameter(
'pixel_time',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='ms',
)
self.add_parameter(
'nr_of_points',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
)
self.add_parameter(
'gaussian_fit',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET,
)
self.add_parameter(
'fit_error',
type=types.ListType,
flags=Instrument.FLAG_GET,
)
self.add_parameter(
'fit_result',
type=types.ListType,
flags=Instrument.FLAG_GET,
)
self.add_parameter(
'opt_pos',
type=types.FloatType,
flags=Instrument.FLAG_GET,
)
self.add_parameter(
'counter',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
)
self.add_parameter(
'points',
type=types.ListType,
flags=Instrument.FLAG_GET,
)
### public functions
self.add_function('run')
# set defaults
self._scan_length = 1.
self._nr_of_points = 21
self._pixel_time = 10
self._gaussian_fit = True
self._fit_error = []
self._fit_result = []
self._opt_pos = 0.
self._counter = 1
self._fitdata = []
self._points = []
self._busy = False
self._dimension = 'x'
def __init__(self, name, adwin, mos, *arg, **kw):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
mos : string
qtlab-name of the master of space to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['measure'])
# adwin and positioner
self._adwin = qt.instruments[adwin]
self._mos = qt.instruments[mos]
self._scan_value = 'counts'
# connect the mos to monitor methods
self._mos.connect('changed', self._mos_changed)
# params that define the linescan
self.add_parameter('dimensions',
type=types.TupleType,
flags=Instrument.FLAG_GETSET,
doc="""Sets the names of the dimensions involved, as specified
in the master of space""")
self.add_parameter('starts',
type=types.TupleType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('stops',
type=types.TupleType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('steps',
type=types.IntType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('px_time',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='ms')
self.add_parameter('scan_value',
type=types.StringType,
flags=Instrument.FLAG_GETSET)
self.add_function('get_points')
self._points = ()
# self._values = {1: [], 2: []}
self.set_steps(1)
self.set_px_time(1)
self.set_dimensions(())
self.set_starts(())
self.set_stops(())
self.set_scan_value('counts')
# other vars
self._px_clock = 0
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
def save(self, meta=""):
CyclopeanInstrument.save(self, meta)
def __init__(self, name, linescan, mos, counters):
CyclopeanInstrument.__init__(self, name, tags=[])
self._linescan = qt.instruments[linescan]
self._mos = qt.instruments[mos]
self._counters = qt.instruments[counters]
self._counter_was_running = False
self.add_parameter('dimension',
type=types.StringType,
flags=Instrument.FLAG_GETSET)
self.add_parameter('scan_length',
type = types.FloatType,
flags = Instrument.FLAG_GETSET,
units = 'um',)
self.add_parameter('pixel_time',
type = types.FloatType,
flags = Instrument.FLAG_GETSET,
units = 'ms',)
self.add_parameter('nr_of_points',
type = types.IntType,
flags = Instrument.FLAG_GETSET, )
self.add_parameter('gaussian_fit',
type = types.BooleanType,
flags = Instrument.FLAG_GETSET, )
self.add_parameter('fit_error',
type = types.ListType,
flags = Instrument.FLAG_GET,)
self.add_parameter('fit_result',
type = types.ListType,
flags = Instrument.FLAG_GET,)
self.add_parameter('opt_pos',
type = types.FloatType,
flags = Instrument.FLAG_GET,)
self.add_parameter('counter',
type = types.IntType,
flags = Instrument.FLAG_GETSET, )
self.add_parameter('points',
type = types.ListType,
flags = Instrument.FLAG_GET, )
### public functions
self.add_function('run')
# set defaults
self._scan_length = 1.
self._nr_of_points = 21
self._pixel_time = 10
self._gaussian_fit = True
self._fit_error = []
self._fit_result = []
self._opt_pos = 0.
self._counter = 1
self._fitdata = []
self._points = []
self._busy = False
self._dimension = 'x'
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self, name,
tags=['measure', 'generate', 'virtual'])
# add the relevant parameters for a 2D PL scanner
self.add_parameter('pixel_time', type=types.IntType,
flags=Instrument.FLAG_GETSET,
units='ms',
minval=1, maxval=1000,
doc="""
Integration time per image pixel.
""")
self.add_parameter('xstart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0, maxval=50.0,
units='um')
self.add_parameter('xstop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0, maxval=50.0,
units='um')
self.add_parameter('ystart',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0, maxval=50.0,
units='um')
self.add_parameter('ystop',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
minval=0.0, maxval=50.0,
units='um')
self.add_parameter('xsteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
minval=2, maxval=1000,
units='')
self.add_parameter('ysteps',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
minval=2, maxval=1000,
units='')
self.add_parameter('data',
tags=['measure'],
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='cps',
doc="""
Returns the full data array, not a single value.
The dimensions are given by the scan settings.
""")
self.add_parameter('x',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='um',
doc="""
Returns the x coordinates of the data pixels.
""")
self.add_parameter('y',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='um',
doc="""
Returns the y coordinates of the data pixels.
""")
self.add_parameter('last_line_index',
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='',
doc="""
Returns the index of the last line of which data is
available.
""")
self.add_parameter('last_line',
tags=['measure'],
type=types.ObjectType,
flags=Instrument.FLAG_GET,
units='cps',
doc="""
Returns the last line of the measured data.
""")
# relevant functions to be visible outside
# a method that gives only a specified range of lines back
# (minimize data exchange)
self.add_function('get_line')
self.add_function('get_lines')
# method to set up the data field: after setting the scan area, use this
# to create a data field of appropriate size
self.add_function('setup_data')
# default params
self.set_pixel_time(10)
self.set_xstart(0.0)
self.set_xstop(10.0)
self.set_ystart(0.0)
self.set_ystop(10.0)
self.set_xsteps(101)
self.set_ysteps(101)
self.set_sampling_interval(500)
# more set up
self.setup_data()
self._current_line = 0
self._last_line = 0
# instruments and access functions for the panels
import qt
self._ins_linescan = qt.instruments['ADwin_linescan']
self._ins_pos = qt.instruments['ADwin_pos']
self._ins_count = qt.instruments['ADwin_count']
self.add_function('move_abs_xy')
self._supported = {
'get_running': True,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': True,
}
self._busy = False
self._counter = False
def __init__(self, name, adwin):
"""
Parameters:
adwin : string
qtlab-name of the adwin instrument to be used
"""
CyclopeanInstrument.__init__(self, name, tags=['positioner'])
self._adwin = qt.instruments[adwin]
# should not change often, hardcode is fine for now
self.rt_dimensions = {
'x' : {
'dac' : 'atto_x',
'micron_per_volt' : 9.324,
'max_v' : 4.29,
'min_v' : 0.,
'default' : 0.,
'origin' : 0.,
},
'z' : {
'dac' : 'atto_z',
'micron_per_volt' : 5.59,
'min_v' : 0.,
'max_v' : 4.29,
'default' : 0.,
'origin' : 0.,
},
'y' : {
'dac' : 'atto_y',
'micron_per_volt' : 9.324,
'max_v' : 4.29,
'min_v' : 0.,
'default' : 0.,
'origin' : 0.,
},
}
self.lt_dimensions = {
'x' : {
'dac' : 'atto_x',
'micron_per_volt' : 2.8,
'max_v' : 10,
'min_v' : 0.,
'default' : 0.,
'origin' : 0.,
},
'z' : {
'dac' : 'atto_z',
'micron_per_volt' : 1.40,
'min_v' : 0.,
'max_v' : 10,
'default' : 0.,
'origin' : 0.,
},
'y' : {
'dac' : 'atto_y',
'micron_per_volt' : 2.8,
'max_v' : 10,
'min_v' : 0.,
'default' : 0.,
'origin' : 0.,
},
}
self.dimensions = self.rt_dimensions
# auto generate parameters incl set and get for all dimensions
for d in self.dimensions:
dim = self.dimensions[d]
# make set and get
self._make_get(d)
self._make_set(d)
# make stepping function
self._make_stepfunc(d)
# register parameter (set and get need to exist already)
self.add_parameter(d,
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um',
minval=dim['min_v']*dim['micron_per_volt'],
maxval=dim['max_v']*dim['micron_per_volt'], )
# register the step function
self.add_function('step_'+d)
# scan control
self._linescan_running = False
self._linescan_px_clock = 0
self.add_parameter('linescan_running',
type=types.BooleanType,
flags=Instrument.FLAG_GET)
self.add_parameter('linescan_px_clock',
type=types.IntType,
flags=Instrument.FLAG_GET)
self.add_function('linescan_start')
# for positioning with attocubes
self.add_parameter('lt_settings',
type=types.BooleanType,
flags=Instrument.FLAG_GETSET)
self._lt_settings = False
# managing the coordinate system
self.add_function('set_origin')
self.add_function('get_origin')
self.add_function('from_relative')
self.add_function('to_relative')
self.add_function('set_relative_position')
self.add_function('get_relative_position')
self.add_function('move_to_xyz_pos')
# markers
self._markers = {}
self.add_function('set_marker')
self.add_function('get_marker')
self.add_function('get_markers')
self.add_function('goto_marker')
self.add_function('push_position')
self.add_function('pop_position')
# set up config file
cfg_fn = os.path.join(qt.config['ins_cfg_path'], name+'.cfg')
if not os.path.exists(cfg_fn):
_f = open(cfg_fn, 'w')
_f.write('')
_f.close()
self.ins_cfg = config.Config(cfg_fn)
self.load_cfg()
self.save_cfg()
# set initial position values (need to know whether LT or RT settings)
for d in self.dimensions:
dim = self.dimensions[d]
voltage = self._adwin.get_dac_voltage(dim['dac'])
position = voltage * dim['micron_per_volt']
setattr(self, '_'+d, position)
def _stop_running(self):
CyclopeanInstrument._stop_running(self)
self._counts = 0
self._countrate = 0
self._ins_ADwin.Stop_Process(4)
def __init__(self, name, address=None):
CyclopeanInstrument.__init__(self,
name,
tags=['positioner', 'virtual'])
self.add_parameter('X_position',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um',
format='%.03f, %.03f')
self.add_parameter('Y_position',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um',
format='%.03f, %.03f')
self.add_parameter('Z_position',
type=types.FloatType,
flags=Instrument.FLAG_GETSET,
units='um',
format='%.03f, %.03f')
self.add_parameter('speed',
type=types.FloatType,
flags=Instrument.FLAG_SET | Instrument.FLAG_SOFTGET,
format='%.01f, %.01f',
units='V/s')
self.add_parameter('LT',
type=types.IntType,
flags=Instrument.FLAG_GETSET,
minval=0,
maxval=1)
# self.add_function('move_abs_xy')
self._X_position = 0.0
self._Y_position = 0.0
self._Z_position = 0.0
self._speed = 1.0
self._LT = 0 # set to 1 for low temperature operation
self._max_x_RT = 40.0 # micrometer
self._max_y_RT = self._max_x_RT # micrometer
self._max_z_RT = 24.0 # micrometer
self._cal_x_RT = 107.0 # mV/micrometer
self._cal_y_RT = self._cal_x_RT # mV/micrometer
self._cal_z_RT = 171.4 # mV/micrometer
self._max_V_RT = 4.29 # Volt
self._max_x_LT = 30.0 # micrometer
self._max_y_LT = self._max_x_LT # micrometer
self._max_z_LT = 15.0 # micrometer
self._cal_x_LT = 357.0 # mV/micrometer
self._cal_y_LT = self._cal_x_LT # mV/micrometer
self._cal_z_LT = 714.3 # mV/micrometer
self._max_V_LT = 10.0 # Volt
self._max_speed = 1.0 # V/s
self._supported = {
'get_running': False,
'get_recording': False,
'set_running': False,
'set_recording': False,
'save': False,
}
import qt
self._ins_ADwin = qt.instruments['ADwin']
self._ins_ADwin.Load(
'D:\\Lucio\\AdWin codes\\ADwin_Gold_II\\cursor_move.tb0')
if self._speed <= self._max_speed:
self._ins_ADwin.Set_FPar(29, self._speed * 1000.0)
else:
self._ins_ADwin.Set_FPar(29, self._max_speed * 1000.0)
self.set_speed(1.0)
