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Code Issues 9 Pull Requests 2 Actions Packages Projects Releases Wiki Activity

feat/various-improvements #69

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hitz_s merged 54 commits from feat/various-improvements into main 2026-05-18 09:05:25 +02:00
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38 changed files with 4663 additions and 413 deletions
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debye_bec/bec_ipython_client/plugins/move_to_label.py
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from __future__ import annotations
import builtins
from typing import TYPE_CHECKING
from bec_lib import bec_logger
from debye_bec.devices.absorber import STATUS as ABS_STATUS
logger = bec_logger.logger
# import builtins to avoid linter errors
dev = builtins.__dict__.get("dev")
class MoveToLabelError(Exception):
"""Exception for the MoveToLabel function"""
def move_to_label():
"""
Function to move several motors to a specific position defined in the label dict.
"""
label = get_device_conditions(label="digitalTwin")
# Get absorber status and close if open
logger.info("Check Frontend Absorber Status")
abs_was_open = dev.abs.status.get() == ABS_STATUS.OPEN
if abs_was_open:
logger.info(" Close Frontend Absorber")
status = dev.abs.close()
status.wait()
# Move Frontend Slits
logger.info("Move Frontend Slits into position")
devices = ["sldi_centerx", "sldi_centery", "sldi_gapx", "sldi_gapy"]
matches = {key: label[key] for key in devices if key in label}
statuses = []
for device in matches.values():
statuses.append(device['device'].move(device['value']))
for status in statuses:
status.wait(timeout=30)
# Move Collimating mirror
logger.info("Move Collimating Mirror into position")
if "cm_rotx" in label: # pitch
logger.info(" Move pitch into position")
surveyed_movement(
axis=label['cm_rotx'],
surveyed_axes= [
{'device': dev.cm_rotz, 'abs_tol': 0.1},
]
)
# Restore absorber position
logger.info("Restore Frontend Absorber Status")
if abs_was_open:
status = dev.abs.open()
status.wait()
def surveyed_movement(axis, surveyed_axes):
"""
Moves an axis while surverying a set of axes.
Args:
axis (DeviceCondition): Device condition
surveyed_axes (list): List of dicts (same format as DeviceCondition)
Raises:
If during movement of axis, one of the surveyed axes moves out of tolerance.
"""
for surv_ax in surveyed_axes:
surv_ax['old_value'] = surv_ax['device'].read()
status = axis['device'].move(axis['value'])
while status.status == 'RUNNING':
for surv_ax in surveyed_axes:
if abs(surv_ax['device'].read() - surv_ax['old_value']) > surv_ax['abs_tol']:
axis['device'].stop()
raise MoveToLabelError(
f"During movement of {axis['device'].name}, {surv_ax['device'].name} " +
f"started to move unexpectedly (old pos: {surv_ax['old_value']}, " +
f"current pos: {surv_ax['device'].read()})"
)
debye_bec/bec_widgets/widgets/client.py
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# This file was automatically generated by generate_cli.py
# type: ignore
from __future__ import annotations
from bec_lib.logger import bec_logger
from bec_widgets.cli.rpc.rpc_base import RPCBase, rpc_call, rpc_timeout
logger = bec_logger.logger
# pylint: skip-file
_Widgets = {
"DigitalTwin": "DigitalTwin",
}
class DigitalTwin(RPCBase):
"""Main widget of Digital Twin"""
_IMPORT_MODULE = "debye_bec.bec_widgets.widgets.digital_twin.digital_twin"
@rpc_call
def remove(self):
"""
Cleanup the BECConnector
"""
@rpc_call
def attach(self):
"""
None
"""
@rpc_call
def detach(self):
"""
Detach the widget from its parent dock widget (if widget is in the dock), making it a floating widget.
"""
debye_bec/bec_widgets/widgets/designer_plugins.py
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# This file was automatically generated by generate_cli.py
# type: ignore
from __future__ import annotations
# pylint: skip-file
designer_plugins = {
"DigitalTwin": ("debye_bec.bec_widgets.widgets.digital_twin.digital_twin", "DigitalTwin"),
}
widget_icons = {
"DigitalTwin": "lightbulb",
}
debye_bec/bec_widgets/widgets/digital_twin/__init__.py
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debye_bec/bec_widgets/widgets/digital_twin/calc_positions.py
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import os
import numpy as np
from bec_lib import bec_logger
os.environ["USE_XRT"] = "False"
import debye_bec.bec_widgets.widgets.x01da_parameters as bl
logger = bec_logger.logger
def calc_positions(cfg):
pos = {}
## FE slits
trxr = -np.arctan(cfg['h_acc'])*bl.feSlits.center1[1]
trxw = (np.arctan(cfg['h_acc'])*bl.feSlits.center1[1])/bl.feSlits.center1[1]*bl.feSlits.center2[1]
tryb = -np.arctan(cfg['v_acc'])*bl.feSlits.center1[1]
tryt = (np.arctan(cfg['v_acc'])*bl.feSlits.center1[1])/bl.feSlits.center1[1]*bl.feSlits.center2[1]
# trxw_proj = trxw/bl.feSlits.center2[1]*bl.feSlits.center1[1]
# tryt_proj = tryt/bl.feSlits.center2[1]*bl.feSlits.center1[1]
# xcen = (trxr + trxw) / 2
# ycen = (tryb + tryt) / 2
xgap = trxw - trxr
ygap = tryt - tryb
pos['sldi_gapx'] = {'value': xgap}
pos['sldi_gapy'] = {'value': ygap}
## Collimating Mirror
obj_dist = bl.cm.center[1] # object distance
beam_vs = 2 * obj_dist * np.tan(cfg['v_acc']) # vertical size of beam after CM
# TRX
try:
index = bl.cm.surface.index(cfg['cm_stripe'])
except:
raise ValueError(f"Requested stripe {cfg['cm_stripe']} not found in parameters!")
cm_trx = -(bl.cm.limOptX[0][index] + bl.cm.limOptX[1][index]) / 2
pos['cm_trx'] = {'value': cm_trx}
# TRY
height = obj_dist * np.tan(cfg['v_acc'])**2 * 1 / np.tan(cfg['cm_pitch'])
pos['cm_try'] = {'value': height}
# Pitch
pos['cm_rotx'] = {'value': -cfg["cm_pitch"]*1e3} # invert and convert to mrad (same as EGU of rotx axis)
# Bending Radius
radius = 2. * obj_dist / np.sin(cfg['cm_pitch']) # Elements of modern X-ray Physics, page 108 ff.
pos['cm_bnd_radius'] = {'value': radius * 1e-6} # Convert to km
## Monochromator
# Bragg Angle
# if cfg['mo1_mode'] == 'Monochromatic':
# # Add 2x CM pitch to the bragg angle
# bragg = ((2 * cfg['cm_pitch']) + cfg['mo1_bragg']) / np.pi * 180
# elif cfg['mo1_mode'] == 'Pinkbeam':
# # Align xtal surfaces parallel to beam
# bragg = (2 * cfg['cm_pitch']) / np.pi * 180
# else:
# raise Exception('Monochromator mode not supported')
if cfg['mo1_mode'] == 'Monochromatic':
# Add 2x CM pitch to the bragg angle
bragg = cfg['mo1_bragg']
elif cfg['mo1_mode'] == 'Pinkbeam':
# Align xtal surfaces parallel to beam
bragg = 0
else:
raise Exception('Monochromator mode not supported')
pos['mo1_bragg_angle'] = {'value': bragg/np.pi*180} # Bragg angle in deg
# TRY, Height
l = bl.mo1.xtalGap[0]/np.sin(cfg['mo1_bragg'])
yhor = l*np.cos(2.*(cfg['mo1_bragg']+cfg['cm_pitch']))
yver = yhor*np.tan(2.*cfg['cm_pitch'])
if cfg['mo1_mode'] == 'Monochromatic':
beamOffsetCCM = l*np.sin(2.*(cfg['mo1_bragg']+cfg['cm_pitch']))-yver # Resultat ist korrekt!
elif cfg['mo1_mode'] == 'Pinkbeam':
beamOffsetCCM = 0
else:
raise Exception('Monochromator mode not supported')
def csc(a):
return 1/np.sin(a)
def cot(a):
return 1/np.tan(a)
# calculate height of center of first crystal surface
f = bl.mo1.rotOffset # rotation offset, mm
# logger.info(f'f = {f}')
d = bl.mo1.heightOffset # xtal height offset, mm
# logger.info(f'd = {d}')
c = d*csc(cfg['mo1_bragg'])-f*cot(cfg['mo1_bragg'])
# logger.info(f'c = {c}')
# Calculate height of center of rotation
b = np.sqrt(d**2*csc(cfg['mo1_bragg'])**2-2*d*f*cot(cfg['mo1_bragg'])*csc(cfg['mo1_bragg'])+f**2*cot(cfg['mo1_bragg'])**2+f**2)
# logger.info(f'b = {b}')
h = np.cos(np.pi/2-np.arctan(f/c)-cfg['mo1_bragg']-2*cfg['cm_pitch'])*b
# logger.info(f'h = {h}')
h2 = ((bl.mo1.center[1] - bl.cm.center[1])-np.sqrt(b**2-h**2))*np.tan(2*cfg['cm_pitch'])
# logger.info(f'mo1 = {bl.mo1.center[1]}')
# logger.info(f'cm = {bl.cm.center[1]}')
# logger.info(f'pitch = {cfg["cm_pitch"]}')
# logger.info(f'h2 = {h2}')
#TODO Mono height not exactly the same as in raytracing
heightCCM1real = h + h2 # per design, the height should not change if the pitch of the CM is not changed!
# heightCCM1real = heightCCM1real - 30 # Zero position of stage is at 1430 mm from ground.
if cfg['mo1_mode'] == 'Monochromatic':
pass
elif cfg['mo1_mode'] == 'Pinkbeam':
heightCCM1real = heightCCM1real - 13 # Move down to let beam pass between both crystal without touching copper cooler
else:
raise Exception('Monochromator mode not supported')
pos['mo1_try'] = {'value': heightCCM1real}
# TRX, Crystal selection
if cfg['mo1_mode'] == 'Monochromatic':
try:
xtal = cfg['mo1_xtal'].translate(str.maketrans('', '', '()')) # Remove brackets from xtal name to conform with parameters
index = bl.mo1.xtal.index(xtal)
except:
raise ValueError(f"Requested xtal {xtal} not found in parameters!")
pos['mo1_trx'] = {'value': bl.mo1.xtalOffsetX[index]}
else:
pos['mo1_trx'] = {'value': 0}
#TODO move to mono, calc for beam Z-movement between crystal surfaces
diag = bl.mo1.xtalGap[0] / np.sin(cfg['mo1_bragg']) # Calculations for Mono
dz = diag * np.cos(2 * (cfg['cm_pitch'] + cfg['mo1_bragg']))
## Slits 1
d = bl.opSlits1.center[1] - bl.cm.center[1] - dz
sl1_beam_height = d * np.tan(2 * cfg['cm_pitch']) + beamOffsetCCM
pos['sl1_centery'] = {'value': sl1_beam_height}
pos['sl1_gapy'] = {'value': beam_vs + 1} # Add 0.5 mm space on both sides of the beam
## Beam Monitor 1
d = bl.opBM1.center[1] - bl.cm.center[1] - dz
# logger.info(f'distance: {d}')
# logger.info(f'cm pitch: {cfg["cm_pitch"]}')
# logger.info(f'mono offset: {beamOffsetCCM}')
bm1_beam_height = d * np.tan(2 * cfg['cm_pitch']) + beamOffsetCCM
pos['bm1_try'] = {'value': bm1_beam_height}
## Focusing Mirror
p = bl.fm.center[1]
q = cfg['smpl'] - bl.fm.center[1]
f = (p*q)/(p+q) # focal length
# Bender radius
if cfg['fm_qy'] is None:
radius = 2 * q / np.sin(cfg['fm_rotx']) # ideal bending radius for focused beam
else:
radius = 2 * cfg['fm_qy'] / np.sin(cfg['fm_rotx']) # ideal bending radius for unfocused beam
pos['fm_bnd_radius'] = {'value': radius * 1e-6} # Convert to km
# Pitch
d = bl.fm.center[1] - bl.cm.center[1] - dz
fm_rotx = 2 * cfg['cm_pitch'] - cfg['fm_rotx'] # calculate pitch in absolute values (according to horizontal plane)
pos['fm_rotx'] = {'value': -fm_rotx * 1e3} # invert and convert to mrad (same as EGU of rotx axis)
if cfg['fm_stripe'] in ('Rh (toroid)', 'Pt (toroid)'):
# TRY
if cfg['fm_stripe'] in 'Rh (toroid)':
r = bl.fm.r[0]
h_cyl = bl.fm.hToroid[0]
else: # PT toroid
r = bl.fm.r[1]
h_cyl = bl.fm.hToroid[1]
widthBeam = 2 * bl.fm.center[1] * np.tan(cfg['h_acc'] * 1e-3)
alpha = np.arccos(1 - widthBeam**2 / (2 * r**2))
h = r - (r * np.cos(alpha / 2))
fm_beam_height = (d * np.tan(2 * cfg['cm_pitch']) + beamOffsetCCM) * cfg['fm_gain_height']
fm_height = (d * np.tan(2 * cfg['cm_pitch']) + beamOffsetCCM - h_cyl + h / 2) * cfg['fm_gain_height']
pos['fm_try'] = {'value': fm_height}
# TRX
if cfg['fm_stripe'] in 'Rh (toroid)':
x_cyl = - bl.fm.xToroid[0]
else:
x_cyl = - bl.fm.xToroid[1]
pos['fm_trx'] = {'value': x_cyl}
elif cfg['fm_stripe'] in ('Rh (flat)', 'Pt (flat)'):
# TRY
fm_height = (d * np.tan(2 * cfg['cm_pitch']) + beamOffsetCCM) * cfg['fm_gain_height']
fm_beam_height = fm_height
pos['fm_try'] = {'value': fm_height}
# TRX
if cfg['fm_stripe'] in 'Rh (flat)':
x_flat = - bl.fm.xFlat[0]
else:
x_flat = - bl.fm.xFlat[1]
pos['fm_trx'] = {'value': x_flat}
else:
raise Exception('FM Stripe selection not valid')
pos['fm_roty'] = {'value': 0}
pos['fm_rotz'] = {'value': 0}
## Slits 2
d = bl.opSlits2.center[1] - bl.fm.center[1]
sl2_beam_height = fm_beam_height - d * np.tan(-(2 * cfg['cm_pitch'] - 2 * cfg['fm_rotx']))
pos['sl2_centery'] = {'value': sl2_beam_height}
pos['sl2_gapy'] = {'value': beam_vs + 1} # Add 0.5 mm space on both sides of the beam
## Beam Monitor 2
d = bl.opBM2.center[1] - bl.fm.center[1]
bm2_beam_height = fm_beam_height - d * np.tan(-(2 * cfg['cm_pitch'] - 2 * cfg['fm_rotx']))
pos['bm2_try'] = {'value': bm2_beam_height}
## Optical Table
# TRY
d = bl.ehWindow.center[1] - bl.fm.center[1]
ot_height = fm_beam_height - d * np.tan(-(2 * cfg['cm_pitch'] - 2 * cfg['fm_rotx']))
# logger.info(fm_height)
# logger.info(d * np.tan((2 * cfg['cm_pitch'] - 2 * cfg['fm_rotx'])))
pos['ot_try'] = {'value': ot_height}
# Pitch
ot_pitch = - (2 * cfg['cm_pitch'] - 2 * cfg['fm_rotx'])
pos['ot_rotx'] = {'value': ot_pitch * 1e3}
# TRZ ES1
ot_es1_trz = cfg['smpl']
pos['ot_es1_trz'] = {'value': ot_es1_trz}
# ES0 exit window
pos['es0wi_try'] = {'value': 5} # At 5mm, the middle of the window is 500 mm from the table (neutral position)
return pos
debye_bec/bec_widgets/widgets/digital_twin/calc_sideview.py
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import numpy as np
import debye_bec.bec_widgets.widgets.x01da_parameters as bl
def calc_sideview(cfg):
# Calculate height of beam after CM
height = 2 * bl.cm.center[1] * np.tan(cfg['v_acc'])
# beam height (Y=height, Z=along beam)
beam = {}
beam['x'] = []
beam['y'] = []
beam['x'].append(0) # Source
beam['y'].append(bl.sourceHeight)
beam['x'].append(bl.cm.center[1]) # CM
beam['y'].append(bl.sourceHeight)
if cfg['mo1_mode'] in 'Monochromatic':
diag = bl.mo1.xtalGap[0]/np.sin(cfg['mo1_bragg']) # Calculations for Mono
dy = diag*np.sin(2*(cfg['cm_pitch']+cfg['mo1_bragg']))
dz = diag*np.cos(2*(cfg['cm_pitch']+cfg['mo1_bragg']))
beam['x'].append(bl.mo1.center[1]-dz/2) # Mono 1.1
beam['y'].append(bl.sourceHeight+np.tan(2*cfg['cm_pitch'])*(bl.mo1.center[1]-dz/2-bl.cm.center[1]))
beam['x'].append(bl.mo1.center[1]+dz/2) # Mono 1.2
beam['y'].append(bl.sourceHeight+np.tan(2*cfg['cm_pitch'])*(bl.mo1.center[1]-dz/2-bl.cm.center[1])+dy)
beam['x'].append(bl.fm.center[1]) # FM
beam['y'].append(bl.sourceHeight+np.tan(2*cfg['cm_pitch'])*(bl.fm.center[1]-bl.cm.center[1]-dz)+dy)
beam['x'].append(cfg['smpl']) # Experiment
beam['y'].append(bl.sourceHeight+np.tan(2*cfg['cm_pitch'])*(bl.fm.center[1]-bl.cm.center[1]-dz)+dy+np.tan(2*(cfg['cm_pitch']-cfg['fm_rotx']))*(cfg['smpl']-bl.fm.center[1]))
elif cfg['mo1_mode'] == 'Pinkbeam':
beam['x'].append(bl.fm.center[1]) # FM
beam['y'].append(bl.sourceHeight+np.tan(2*cfg['cm_pitch'])*(bl.fm.center[1]-bl.cm.center[1]))
beam['x'].append(cfg['smpl']) # Experiment
beam['y'].append(bl.sourceHeight+np.tan(2*cfg['cm_pitch'])*(bl.fm.center[1]-bl.cm.center[1])+np.tan(2*(cfg['cm_pitch']-cfg['fm_rotx']))*(cfg['smpl']-bl.fm.center[1]))
dy_fm_ex = beam['y'][-1] - beam['y'][-2]
dz_fm_ex = beam['x'][-1] - beam['x'][-2]
dz_fm_win = bl.ehWindow.center[1] - beam['x'][-2]
h_at_win = beam['y'][-2] + dy_fm_ex / dz_fm_ex * dz_fm_win
beam['heightWindow'] = h_at_win
return beam
debye_bec/bec_widgets/widgets/digital_twin/calc_surfaces.py
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import os
import re
import numpy as np
from bec_lib import bec_logger
logger = bec_logger.logger
os.environ["USE_XRT"] = "False"
import debye_bec.bec_widgets.widgets.x01da_parameters as bl
def calc_surfaces(cfg):
out = {
'cm': {'x': [], 'y': []},
'mo1_1': {'x': [], 'y': []},
'mo1_2': {'x': [], 'y': []},
'fm': {'x': [], 'y': []},
}
# Collimating mirror
l = 2 * bl.cm.center[1] * np.tan(cfg['v_acc'])/np.sin(cfg['cm_pitch'])
w1 = 2 * (bl.cm.center[1]-l/2) * np.tan(cfg['h_acc'])
w2 = 2 * (bl.cm.center[1]+l/2) * np.tan(cfg['h_acc'])
index = bl.cm.surface.index(cfg['cm_stripe'])
cen = (bl.cm.limOptX[0][index] + bl.cm.limOptX[1][index]) / 2
if cfg['cm_trx'] is not None:
cen = cfg['cm_trx']
out['cm']['x'] = [cen-w1/2, cen-w2/2, cen+w2/2, cen+w1/2]
out['cm']['y'] = [-l/2, l/2, l/2, -l/2]
# Monochromator
# calculate height of center of first crystal surface
c = bl.mo1.heightOffset*1/np.sin(cfg['mo1_bragg'])-bl.mo1.rotOffset*1/np.tan(cfg['mo1_bragg'])
e = bl.mo1.xtalGap[0]/np.tan(cfg['mo1_bragg'])-c
xtal = cfg['mo1_xtal'].translate(str.maketrans('', '', '()')) # Remove brackets from xtal name to conform with parameters
index = bl.mo1.xtal.index(xtal)
xtalPos = bl.mo1.xtalOffsetX[index]
xtalLength1 = bl.mo1.xtalLength1[index]
xtalLength2 = bl.mo1.xtalLength2[index]
widthBeam = 2 * bl.mo1.center[1] * np.tan(cfg['h_acc'])
heightBeam = 2 * bl.cm.center[1] * np.tan(cfg['v_acc'])
w = heightBeam / np.sin(cfg['mo1_bragg'])
if cfg['mo1_mode'] in 'Monochromatic':
out['mo1_1']['x'] = [xtalPos-widthBeam/2, xtalPos+widthBeam/2, xtalPos+widthBeam/2, xtalPos-widthBeam/2]
out['mo1_1']['y'] = [xtalLength1/2-c-w/2, xtalLength1/2-c-w/2, xtalLength1/2-c+w/2, xtalLength1/2-c+w/2]
out['mo1_2']['x'] = [xtalPos-widthBeam/2, xtalPos+widthBeam/2, xtalPos+widthBeam/2, xtalPos-widthBeam/2]
out['mo1_2']['y'] = [-xtalLength2/2+e-w/2, -xtalLength2/2+e-w/2, -xtalLength2/2+e+w/2, -xtalLength2/2+e+w/2]
else: # Pinkbeam
out['mo1_1']['x'] = []
out['mo1_1']['y'] = []
out['mo1_2']['x'] = []
out['mo1_2']['y'] = []
# Focusing mirror
if cfg['fm_stripe'] in ('Rh (toroid)', 'Pt (toroid)'):
surface = bl.fm.surfaceToroid
stripe = re.sub(r'\s*\(.*?\)', '', cfg['fm_stripe']).strip()
index = surface.index(stripe)
off = (bl.fm.limOptXToroid[0][index] + bl.fm.limOptXToroid[1][index]) / 2
r = bl.fm.r[index]
else:
surface = bl.fm.surfaceFlat
stripe = re.sub(r'\s*\(.*?\)', '', cfg['fm_stripe']).strip()
index = surface.index(stripe)
off = (bl.fm.limOptXFlat[0][index] + bl.fm.limOptXFlat[1][index]) / 2
r = bl.fm.r[index]
if cfg['fm_trx'] is not None:
off = cfg['fm_trx']
widthBeam = 2 * bl.fm.center[1] * np.tan(cfg['h_acc'])
if cfg['fm_stripe'] in ('Rh (toroid)', 'Pt (toroid)'):
l = heightBeam/np.sin(cfg['fm_rotx'])
alpha = np.arccos(1-widthBeam**2/(2*r**2))
h = r-(r*np.cos(alpha/2))
z = h/np.tan(cfg['fm_rotx'])
x = [off-widthBeam/2, off-widthBeam/2]
y = [l/2-z/2, -l/2-z/2]
# logger.info(f'stripe: {cfg["fm_stripe"]}')
# logger.info(f'fm_rotx: {cfg["fm_rotx"]}')
# logger.info(f'h: {h}')
# logger.info(f'z: {z}')
# logger.info(f'r: {r}')
res = 20
xElipse = np.linspace(0, np.pi, res)
yElipse = np.linspace(0, np.pi, res)
xElipse = [-widthBeam/2*np.cos(i)+off for i in xElipse]
yElipse = [widthBeam*np.sin(i)*z/widthBeam-l/2-z/2 for i in yElipse]
x.extend(xElipse)
y.extend(yElipse)
x.extend([off+widthBeam/2, off+widthBeam/2])
y.extend([-l/2-z/2, l/2-z/2])
res = 50
xElipse = np.linspace(np.pi, 0, res)
yElipse = np.linspace(np.pi, 0, res)
xElipse = [-widthBeam/2*np.cos(i)+off for i in xElipse]
yElipse = [widthBeam*np.sin(i)*z/widthBeam+l/2-z/2 for i in yElipse]
x.extend(xElipse)
y.extend(yElipse)
out['fm']['x'] = x
out['fm']['y'] = y
else: # flat surface, no toroid
l = heightBeam/np.sin(cfg['fm_rotx'])
w1 = 2 * (bl.fm.center[1]-l/2) * np.tan(cfg['h_acc'])
w2 = 2 * (bl.fm.center[1]+l/2) * np.tan(cfg['h_acc'])
out['fm']['x'] = [off-w1/2, off+w1/2, off+w2/2, off-w2/2]
out['fm']['y'] = [-l/2, -l/2, l/2, l/2]
return out
debye_bec/bec_widgets/widgets/digital_twin/calc_varia.py
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import re
import numpy as np
from scipy.interpolate import UnivariateSpline
from xrt.backends.raycing.physconsts import CHeVcm, AVOGADRO
from bec_lib import bec_logger
import debye_bec.bec_widgets.widgets.x01da_parameters as bl
logger = bec_logger.logger
def sldi_gap_to_acc(sldi_gapx, sldi_gapy):
d1 = bl.feSlits.center1[1]
d2 = bl.feSlits.center2[1]
h_acc = np.tan(sldi_gapx / (d2 + d1))
v_acc = np.tan(sldi_gapy / (d2 + d1))
# h_acc = np.tan(sldi_gapx / (2 * d1))
# v_acc = np.tan(sldi_gapy / (2 * d1))
return h_acc, v_acc
def cm_trx_to_stripe(cm_trx):
cm_stripe = None
for name, low, high in zip(bl.cm.surface, bl.cm.limOptX[0], bl.cm.limOptX[1]):
if low <= cm_trx <= high:
cm_stripe = name
return cm_stripe
def fm_trx_to_stripe(fm_trx):
fm_stripe = None
for name, low, high in zip(bl.fm.surfaceFlat, bl.fm.limOptXFlat[1], bl.fm.limOptXFlat[0]):
if low <= fm_trx <= high:
fm_stripe = name + ' (flat)'
for name, low, high in zip(bl.fm.surfaceToroid, bl.fm.limOptXToroid[1], bl.fm.limOptXToroid[0]):
if low <= fm_trx <= high:
fm_stripe = name + ' (toroid)'
return fm_stripe
def mo1_energy_resolution(xtal, energy):
index = bl.mo1.xtal.index(xtal)
crystal = bl.mo1.material1[index]
dtheta = np.linspace(-30, 90, 601)
theta = crystal.get_Bragg_angle(energy) + dtheta * 1e-6
refl = np.abs(crystal.get_amplitude(energy, np.sin(theta))[0])**2 # single crystal
refl2 = refl**2 # DCM with parallel crystals
# FWHM of the DCM curve
spline = UnivariateSpline(dtheta, refl2 - refl2.max()/2, s=0)
r1, r2 = spline.roots()
fwhm_rad = (r2 - r1) * 1e-6 # µrad → rad
# Energy resolution
theta_B = crystal.get_Bragg_angle(energy)
dE_over_E = fwhm_rad / np.tan(theta_B)
dE = dE_over_E * energy
# logger.info(f"DCM FWHM : {r2-r1:.2f} µrad")
# logger.info(f"ΔE/E : {dE_over_E:.2e}")
# logger.info(f"ΔE : {dE:.3f} eV at {E} eV")
return dE
def cm_reflectivity(cm_stripe, cm_pitch, energy):
index = bl.cm.surface.index(cm_stripe)
rs, rp = bl.cm.material[index].get_amplitude(
energy,
np.sin(cm_pitch)
)[0:2]
refl = abs(rs)**2
return refl
def fm_reflectivity(fm_stripe, fm_pitch, energy):
if fm_stripe in ('Rh (toroid)', 'Pt (toroid)'):
surface = bl.fm.surfaceToroid
material = bl.fm.materialToroid
stripe = re.sub(r'\s*\(.*?\)', '', fm_stripe).strip()
index = surface.index(stripe)
else:
surface = bl.fm.surfaceFlat
material = bl.fm.materialFlat
stripe = re.sub(r'\s*\(.*?\)', '', fm_stripe).strip()
index = surface.index(stripe)
rs, rp = material[index].get_amplitude(
energy,
np.sin(fm_pitch)
)[0:2]
refl = abs(rs)**2
return refl
def mo1_bragg_angle(mo_mode, d_spacing, energy, cm_pitch):
H = 6.62606957E-34
E = 1.602176634E-19
C = 299792458
wl = C * H / (E * energy)
val = wl / (2 * d_spacing * 1e-10)
bragg_angle = 0
if val > -1 and val < 1:
bragg_angle = np.asin(val)
if mo_mode in 'Monochromatic':
# Add 2x CM pitch to the bragg angle
bragg_angle_cor = ((2 * cm_pitch) + bragg_angle)
elif mo_mode in 'Pinkbeam':
# Align xtal surfaces parallel to beam
bragg_angle_cor = (2 * cm_pitch)
return bragg_angle, bragg_angle_cor
def fm_ideal_pitch(fm_focus, fm_stripe, smpl, sldi_hacc=None, sldi_vacc=None, fm_focx=None, fm_focy=None):
p = bl.fm.center[1] # posFM
q = smpl - bl.fm.center[1] # dist posFM to posEX
if fm_focus in 'Defocused':
a = 2 * np.tan(sldi_hacc) * bl.fm.center[1] # Beam width at focusing mirror
b = 2 * np.tan(sldi_vacc) * bl.cm.center[1] # Beam height at focusing mirror (collimated beam)
x = fm_focx
y = fm_focy
qx = q + x * p / a
qy = q + y * p / b
f = (p * qx) / (p + qx) # focal length
else: # Calculate for focused beam on sample in "manual" and "focused" mode
qy = None
f = (p * q) / (p + q) # focal length
pitch = 0
if 'Rh' in fm_stripe:
pitch = np.arcsin(bl.fm.r[0]/(2*f))# ideal pitch for FM
if 'Pt' in fm_stripe:
pitch = np.arcsin(bl.fm.r[1]/(2*f)) # ideal pitch for FM
return pitch, qy
def cm_critical_angle(cm_stripe, energy):
if cm_stripe in 'Si':
stripe = bl.stripeSi
elif cm_stripe in 'Pt':
stripe = bl.stripePt
elif cm_stripe in 'Rh':
stripe = bl.stripeRh
else:
raise Exception(f'Stripe {stripe} not found in beamline parameters!')
w = CHeVcm/100/energy # convert energy [eV] to wavelength [m]
# Calculate critical angle for mirror
f1 = stripe.elements[0].Z + np.real(stripe.elements[0].get_f1f2(energy))
numberDensity = stripe.rho*1e3*AVOGADRO/(stripe.elements[0].mass/1e3)
criticalAngle = np.sqrt(numberDensity*2.8179e-15*w**2*f1/np.pi)
return criticalAngle
def mirror_surface_geometries(mirror):
if mirror in "cm":
surface = bl.cm.surface
limOptX = bl.cm.limOptX
limOptY = bl.cm.limOptY
elif mirror in 'fm_toroid':
surface = bl.fm.surfaceToroid
limOptX = bl.fm.limOptXToroid
limOptY = bl.fm.limOptYToroid
elif mirror in 'fm_flat':
surface = bl.fm.surfaceFlat
limOptX = bl.fm.limOptXFlat
limOptY = bl.fm.limOptYFlat
else:
raise ValueError(f'Requested mirror {mirror} not available!')
geom = {}
for sf, lx, hx, ly, hy in zip(surface, limOptX[0], limOptX[1], limOptY[0], limOptY[1]):
geom[sf] = (lx, ly, hx-lx, hy-ly)
return geom
def mo_surface_geometries(mo, plane):
if mo in 'mo1':
xtal = bl.mo1.xtal
xtal_width = bl.mo1.xtalWidth
xtal_offset_x = bl.mo1.xtalOffsetX
if plane == 0:
xtal_length = bl.mo1.xtalLength1
else:
xtal_length = bl.mo1.xtalLength2
else:
raise ValueError(f'Requested mono {mo} not available!')
geom = {}
for sf, w, offx, length in zip(xtal, xtal_width, xtal_offset_x, xtal_length):
geom[sf] = (offx-w/2, -length/2, w, length)
return geom
def wall_geometries():
geom = []
for i, _ in enumerate(bl.walls.start):
geom.append([
bl.walls.start[i],
bl.walls.height[i][0],
bl.walls.end[i] - bl.walls.start[i],
bl.walls.height[i][1] - bl.walls.height[i][0],
])
return geom
def pipe_geometries():
pipes = []
for i, _ in enumerate(bl.vacuum_pipes.center):
top = bl.vacuum_pipes.center[i] + bl.vacuum_pipes.diameter[i]/2 + bl.sourceHeight
bottom = bl.vacuum_pipes.center[i] - bl.vacuum_pipes.diameter[i]/2 + bl.sourceHeight
pipes.append({
'x': np.array([bl.vacuum_pipes.start[i], bl.vacuum_pipes.end[i]]),
'y': np.array([top, top])
})
pipes.append({
'x': np.array([bl.vacuum_pipes.start[i], bl.vacuum_pipes.end[i]]),
'y': np.array([bottom, bottom])
})
return pipes
debye_bec/bec_widgets/widgets/digital_twin/digital_twin.py
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debye_bec/bec_widgets/widgets/digital_twin/digital_twin.pyproject
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{'files': ['digital_twin.py']}
debye_bec/bec_widgets/widgets/digital_twin/digital_twin_plugin.py
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# Copyright (C) 2022 The Qt Company Ltd.
# SPDX-License-Identifier: LicenseRef-Qt-Commercial OR BSD-3-Clause
from bec_widgets.utils.bec_designer import designer_material_icon
from qtpy.QtDesigner import QDesignerCustomWidgetInterface
from qtpy.QtWidgets import QWidget
from debye_bec.bec_widgets.widgets.digital_twin.digital_twin import DigitalTwin
DOM_XML = """
<ui language='c++'>
<widget class='DigitalTwin' name='digital_twin'>
</widget>
</ui>
"""
class DigitalTwinPlugin(QDesignerCustomWidgetInterface): # pragma: no cover
def __init__(self):
super().__init__()
self._form_editor = None
def createWidget(self, parent):
if parent is None:
return QWidget()
t = DigitalTwin(parent)
return t
def domXml(self):
return DOM_XML
def group(self):
return ""
def icon(self):
return designer_material_icon(DigitalTwin.ICON_NAME)
def includeFile(self):
return "digital_twin"
def initialize(self, form_editor):
self._form_editor = form_editor
def isContainer(self):
return False
def isInitialized(self):
return self._form_editor is not None
def name(self):
return "DigitalTwin"
def toolTip(self):
return "DigitalTwin"
def whatsThis(self):
return self.toolTip()
debye_bec/bec_widgets/widgets/digital_twin/move_widget.py
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import time
import random
import threading
# import qtawesome as qta
from bec_qthemes import material_icon
from bec_widgets.utils.colors import get_accent_colors
from bec_lib import bec_logger
from debye_bec.devices.absorber import STATUS as ABS_STATUS
from qtpy.QtCore import Qt, QThread, Signal, QObject, Property, QPropertyAnimation
from qtpy.QtWidgets import (
QGroupBox, QHBoxLayout, QVBoxLayout, QLabel, QPushButton,
QDoubleSpinBox, QFrame, QWidget, QApplication
)
from qtpy.QtGui import QTransform
logger = bec_logger.logger
class Status:
IN_POSITION = "in_position" # green mdi.check-circle
NOT_IN_POSITION = "not_in_position" # orange mdi.close-circle
MOVING = "moving" # blue mdi.loading (spinning)
ERROR = "error" # red mdi.alert-circle
class StatusIcon(QWidget):
"""
Displays a status icon using bec_qthemes Material Design Icons.
Handles its own spin animation for the MOVING state via QPropertyAnimation.
"""
ICON_SIZE = 20
_ICON_MAP = {
Status.IN_POSITION: ("check_circle", "#27ae60"),
Status.NOT_IN_POSITION: ("cancel", "#e6d922"),
Status.ERROR: ("warning", "#e74c3c"),
Status.MOVING: ("cycle", "#2980b9"),
}
def __init__(self, parent=None):
super().__init__(parent=parent)
self._status = None
self._rotation = 0.0
self._label = QLabel(self)
self._label.setFixedSize(self.ICON_SIZE, self.ICON_SIZE)
self._label.setAlignment(Qt.AlignCenter)
self.setFixedSize(self.ICON_SIZE, self.ICON_SIZE)
self._spin_anim = QPropertyAnimation(self, b"rotation")
self._spin_anim.setStartValue(0)
self._spin_anim.setEndValue(360)
self._spin_anim.setDuration(1000)
self._spin_anim.setLoopCount(-1) # Loop indefinitely
self.set_status(Status.NOT_IN_POSITION)
def get_rotation(self):
return self._rotation
def set_rotation(self, angle):
self._rotation = angle
if self._current_pixmap_base is not None:
cx = self._current_pixmap_base.width() / 2
cy = self._current_pixmap_base.height() / 2
t = QTransform().translate(cx, cy).rotate(angle).translate(-cx, -cy)
self._label.setPixmap(self._current_pixmap_base.transformed(t, Qt.SmoothTransformation))
rotation = Property(float, get_rotation, set_rotation)
def set_status(self, status: str):
if status == self._status:
return
self._status = status
icon_name, color = self._ICON_MAP[status]
icon = material_icon(icon_name, size=(self.ICON_SIZE, self.ICON_SIZE), color=color, convert_to_pixmap=True)
self._current_pixmap_base = icon
if status == Status.MOVING:
self._spin_anim.start()
else:
self._spin_anim.stop()
self._label.setPixmap(icon)
class MotionWorker(QObject):
"""
Executes motion on the specified motor and includes some safety during
motion for certain motors.
"""
position_changed = Signal(float)
error = Signal(bool) # True = error
finished = Signal(bool) # True = reached target, False = stopped
def __init__(self, dev, motor, target_pos: float):
super().__init__()
self.dev = dev
self.motor = motor
self._target = target_pos
self._stop_flag = threading.Event()
def stop(self):
self._stop_flag.set()
# def run(self):
# logger.info(f'Would run motor {self.motor}')
# simulated_run_time = 3
# start = time.time()
# while (time.time() - start) < simulated_run_time:
# if self._stop_flag.is_set():
# break
# time.sleep(0.01)
# # self.motor.move(self._target, relative=False)
# # while self.motor.motor_is_moving.get():
# # if self._stop_flag.is_set():
# # self.motor.motor_stop()
# # self.position_changed.emit(self.motor.read[self.name]['value'])
# # time.sleep(0.1)
# self.finished.emit(True)
def run(self):
match self.motor:
case 'sldi_gapx' | 'sldi_gapy' | 'sldi_centerx' | 'sldi_centery':
self.motion()
case 'cm_trx':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['cm_roty'], 'abs_tol': 0.05}
])
case 'cm_roty':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['cm_trx'], 'abs_tol': 0.05}
])
case 'cm_try':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['cm_rotx'], 'abs_tol': 0.05},
{'device': self.dev['cm_rotz'], 'abs_tol': 0.05},
])
case 'cm_rotx':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['cm_try'], 'abs_tol': 0.05},
{'device': self.dev['cm_rotz'], 'abs_tol': 0.05},
])
case 'cm_rotz':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['cm_try'], 'abs_tol': 0.05},
{'device': self.dev['cm_rotx'], 'abs_tol': 0.05},
])
case 'cm_bnd':
p1 = (1/(self.dev.cm_bnd_radius.read()['cm_bnd_radius']['value']*1e3) + 0.0284)/2e-6
p2 = (1/(self._target*1e3) + 0.0284)/2e-6
self._target = p2 - p1
self.motion(relative=True, rb=
{'device': self.dev['cm_bnd_radius']}
)
case 'mo1_try' | 'mo1_trx' | 'mo1_roty':
self.motion(abs_closed=True)
case 'mo1_bragg_angle':
self.motion()
case 'sl1_centery' | 'sl1_gapy' | 'bm1_try':
self.motion()
case 'fm_trx':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['fm_roty'], 'abs_tol': 0.05}
])
case 'fm_roty':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['fm_trx'], 'abs_tol': 0.05}
])
case 'fm_try':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['fm_rotx'], 'abs_tol': 0.05},
{'device': self.dev['fm_rotz'], 'abs_tol': 0.05},
])
case 'fm_rotx':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['fm_try'], 'abs_tol': 0.05},
{'device': self.dev['fm_rotz'], 'abs_tol': 0.05},
])
case 'fm_rotz':
self.motion(abs_closed=True, surveyed_axes=[
{'device': self.dev['fm_try'], 'abs_tol': 0.05},
{'device': self.dev['fm_rotx'], 'abs_tol': 0.05},
])
case 'fm_bnd':
p1 = (1/(self.dev.fm_bnd_radius.read()['fm_bnd_radius']['value']*1e3) + 4.28e-5)/1.84e-9
p2 = (1/(self._target*1e3) + 4.28e-5)/1.84e-9
self._target = p2 - p1
self.motion(relative=True, rb=
{'device': self.dev['fm_bnd_radius']}
)
case 'sl2_centery' | 'sl2_gapy' | 'bm2_try':
self.motion()
case 'ot_try' | 'ot_rotx' | 'ot_es1_trz':
self.motion()
case _:
logger.warning(f'Motor {self.motor} not integrated in digital twin!')
def motion(self, abs_closed=False, relative=False, rb=None, surveyed_axes = None):
"""
Moves an axis while surverying a set of axes (if set).
Example surveyed_axes:
[{'device': bec_device_object, 'abs_tol': 0.1},]
Args:
surveyed_axes (list): List of dictionaries of devices
"""
if abs_closed:
if self.dev.abs.status.get() == ABS_STATUS.OPEN:
status = self.dev.abs.close()
# TODO Set timeout to 0.001 and check if it actually raises (it should not start motion).
# Check of behavior of digital twin afterwards.
status.wait(timeout=5)
if surveyed_axes is not None:
for surv_ax in surveyed_axes:
surv_ax['name'] = surv_ax['device'].dotted_name
surv_ax['old_value'] = surv_ax['device'].read(cached=True)[surv_ax['name']]['value']
if rb is not None:
rb['name'] = rb['device'].dotted_name
self.dev[self.motor].move(self._target, relative=relative)
time.sleep(0.5)
while self.dev[self.motor].motor_is_moving.get():
if self._stop_flag.is_set():
self.dev[self.motor].stop()
self._stop_flag.clear()
if rb is not None:
self.position_changed.emit(rb['device'].read(cached=True)[rb['name']]['value'])
else:
self.position_changed.emit(self.dev[self.motor].read(cached=True)[self.motor]['value'])
if surveyed_axes is not None:
for surv_ax in surveyed_axes:
fb = surv_ax['device'].read(cached=True)[surv_ax['name']]['value']
if abs(fb - surv_ax['old_value']) > surv_ax['abs_tol']:
self.dev[self.motor].stop()
self.error.emit(1)
break
time.sleep(0.1)
self.finished.emit(True)
class MoveWidget(QWidget):
"""
One motor stage control group containing:
- Target label (target position)
- Feedback label (current position)
- Status icon (bec_qthemes)
- Start / Stop button
"""
def __init__(self, dev, motor, label: str = '', unit=None, decimals=3, deadband=0.0):
super().__init__()
self.fb = 0.0
self.target = 0
self.dev = dev
self.motor = motor
self.deadband = deadband
self.status = Status.IN_POSITION
self._thread: QThread | None = None
self._worker: MotionWorker | None = None
self.text_color = (0, 0, 0)
self.unit = unit
self.decimals = decimals
layout = QHBoxLayout(self)
layout.setContentsMargins(10, 0, 0, 0)
layout.setSpacing(0)
# Name
self.label = QLabel(label)
self.label.setFixedWidth(100)
self.label.setContentsMargins(0, 0, 10, 0)
self.label.setWordWrap(True)
layout.addWidget(self.label)
# Target
self.target_label = QLabel('-')
self.target_label.setFixedWidth(100)
layout.addWidget(self.target_label)
# Feedback
self.fb_label = QLabel('-')
self.fb_label.setFixedWidth(100)
layout.addWidget(self.fb_label)
# Status icon
self.status_icon = StatusIcon()
self.status_icon.setFixedWidth(30)
self.status_icon.setContentsMargins(0, 0, 10, 0)
layout.addWidget(self.status_icon)
# Start / Stop button
self.btn_action = QPushButton("Move")
self.btn_action.setFixedWidth(90)
self.btn_action.setFixedHeight(20)
self.btn_action.clicked.connect(self._on_button_clicked)
layout.addWidget(self.btn_action)
self.btn_mode = 'start'
self._apply_button_style("start")
self.apply_theme()
def apply_theme(self, theme=None):
if theme is None:
app = QApplication.instance()
theme = app.theme.theme # type: ignore
if theme == "light":
self.text_color = {'target': (79, 163, 224), 'fb': (240, 128, 60)}
else: # dark theme
self.text_color = {'target': (26, 111, 173), 'fb': (212, 83, 10)}
r, g, b = self.text_color['target']
self.target_label.setStyleSheet(f'QLabel {{color: rgb({r}, {g}, {b})}}')
r, g, b = self.text_color['fb']
self.fb_label.setStyleSheet(f'QLabel {{color: rgb({r}, {g}, {b})}}')
if self.btn_mode == 'start':
self.btn_action.setStyleSheet(
f"QPushButton {{background-color: {get_accent_colors().success.name()}; color: white;}}"
)
else:
self.btn_action.setStyleSheet(
f"QPushButton {{background-color: {get_accent_colors().emergency.name()}; color: white;}}"
)
def set_target(self, target):
self.target = target
text = f'{target:.{int(self.decimals)}f}'
if self.unit is not None:
text = text + ' ' + self.unit
self.target_label.setText(text)
self._on_target_or_fb_changed()
def set_feedback(self, fb):
if self.status != Status.MOVING:
self.fb = fb
text = f'{fb:.{int(self.decimals)}f}'
if self.unit is not None:
text = text + ' ' + self.unit
self.fb_label.setText(text)
self._on_target_or_fb_changed()
def _apply_button_style(self, mode: str):
self.btn_mode = mode
if mode == "start":
self.btn_action.setText("Move")
self.btn_action.setStyleSheet(
f"QPushButton {{background-color: {get_accent_colors().success.name()}; color: white;}}"
)
else: # stop
self.btn_action.setText("Stop")
self.btn_action.setStyleSheet(
f"QPushButton {{background-color: {get_accent_colors().emergency.name()}; color: white;}}"
)
def _set_status(self, status: str):
self.status = status
self.status_icon.set_status(status)
def _on_target_or_fb_changed(self):
"""Re-evaluate in-position status whenever the target value changes."""
if self.status in (Status.ERROR, Status.MOVING):
return
if abs(self.fb - self.target) <= self.deadband:
self._set_status(Status.IN_POSITION)
else:
self._set_status(Status.NOT_IN_POSITION)
def _on_button_clicked(self):
if self._thread and self._thread.isRunning():
self._stop_motion()
else:
self._start_motion()
def _start_motion(self):
target = self.target
if abs(target - self.fb) <= self.deadband:
self._set_status(Status.IN_POSITION)
return
self._set_status(Status.MOVING)
self._apply_button_style("stop")
self._worker = MotionWorker(self.dev, self.motor, target)
self._thread = QThread()
self._worker.moveToThread(self._thread)
self._thread.started.connect(self._worker.run)
self._worker.position_changed.connect(self._on_position_changed)
self._worker.error.connect(self._on_error)
self._worker.error.connect(self._thread.quit)
self._worker.finished.connect(self._on_motion_finished)
self._worker.finished.connect(self._thread.quit)
self._thread.finished.connect(self._cleanup_thread)
self._thread.start()
def _on_error(self):
self._set_status(Status.ERROR)
self._apply_button_style("start")
def _stop_motion(self):
if self._worker:
self._worker.stop()
def _on_position_changed(self, pos: float):
self.fb = pos
text = f'{pos:.{int(self.decimals)}f}'
if self.unit is not None:
text = text + ' ' + self.unit
self.fb_label.setText(text)
def _on_motion_finished(self, reached: bool):
target = self.target
if self.status not in Status.ERROR:
if abs(self.fb - target) <= self.deadband:
self._set_status(Status.IN_POSITION)
else:
self._set_status(Status.NOT_IN_POSITION)
self._apply_button_style("start")
def _cleanup_thread(self):
if self._thread:
self._thread.deleteLater()
self._thread = None
if self._worker:
self._worker.deleteLater()
self._worker = None
def shutdown(self):
if self._worker:
self._worker.stop()
if self._thread:
self._thread.quit()
self._thread.wait(2000) # max 2 s grace period
class AbsorberWidget(QWidget):
"""
Control of the frontend absorber (only open)
"""
def __init__(self, absorber, label: str = 'Absorber'):
super().__init__()
self.absorber = absorber
self.fb = False
self.text_color = (0, 0, 0)
layout = QHBoxLayout(self)
layout.setContentsMargins(10, 0, 0, 0)
layout.setSpacing(0)
# Name
self.label = QLabel(label)
self.label.setFixedWidth(100)
self.label.setContentsMargins(0, 0, 10, 0)
self.label.setWordWrap(True)
layout.addWidget(self.label)
# Blank
self.blank_label = QLabel('')
self.blank_label.setFixedWidth(100)
layout.addWidget(self.blank_label)
# Feedback
self.fb_label = QLabel('-')
self.fb_label.setFixedWidth(100)
layout.addWidget(self.fb_label)
# Blank icon
self.blank_icon = QLabel('')
self.blank_icon.setFixedWidth(30)
self.blank_icon.setContentsMargins(0, 0, 10, 0)
layout.addWidget(self.blank_icon)
# Open
self.btn_action = QPushButton("Open")
self.btn_action.setFixedWidth(90)
self.btn_action.setFixedHeight(20)
self.btn_action.clicked.connect(self._on_button_clicked)
layout.addWidget(self.btn_action)
def set_feedback(self, fb: bool):
self.fb = fb
if fb:
self.fb_label.setText('Open')
self.fb_label.setStyleSheet(
f"QLabel {{color: {get_accent_colors().success.name()}}}"
)
else:
self.fb_label.setText('Closed')
self.fb_label.setStyleSheet(
f"QLabel {{color: {get_accent_colors().emergency.name()}}}"
)
def enable_open(self, enable: bool = False):
if enable:
self.btn_action.setStyleSheet(
f"QPushButton {{background-color: {get_accent_colors().success.name()}; color: white;}}"
)
self.btn_action.setEnabled(True)
else: # disabled
self.btn_action.setStyleSheet(
"QPushButton {{background-color: rgb(120, 120, 120); color: white;}}"
)
self.btn_action.setDisabled(True)
def _on_button_clicked(self):
self.absorber.open()
debye_bec/bec_widgets/widgets/digital_twin/register_digital_twin.py
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def main(): # pragma: no cover
from qtpy import PYSIDE6
if not PYSIDE6:
print("PYSIDE6 is not available in the environment. Cannot patch designer.")
return
from PySide6.QtDesigner import QPyDesignerCustomWidgetCollection
from debye_bec.bec_widgets.widgets.digital_twin.digital_twin_plugin import DigitalTwinPlugin
QPyDesignerCustomWidgetCollection.addCustomWidget(DigitalTwinPlugin())
if __name__ == "__main__": # pragma: no cover
main()
debye_bec/bec_widgets/widgets/qt_widgets.py
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from functools import partial
# pylint: disable=E0611
from qtpy.QtWidgets import (
QWidget, QVBoxLayout, QHBoxLayout, QLabel, QLineEdit,
QPushButton, QGroupBox, QComboBox, QApplication, QDoubleSpinBox
)
from qtpy.QtGui import QFont
from qtpy.QtCore import Qt
from bec_widgets.utils.colors import get_accent_colors
class Group(QGroupBox):
def __init__(self, label, widgets):
super().__init__(label)
self.layout = QVBoxLayout(self) # type: ignore
for widget in widgets:
self.layout.addWidget(widget) # type: ignore
class NumberIndicator(QWidget):
def __init__(self, label='', unit=None, highlight=False, decimals=3):
super().__init__()
layout = QHBoxLayout(self)
layout.setContentsMargins(10, 0, 0, 0)
layout.setSpacing(0)
self.label = QLabel(label)
self.label.setFixedWidth(140)
self.label.setContentsMargins(0, 0, 10, 0)
self.label.setWordWrap(True)
layout.addWidget(self.label)
self.val = QLabel('-')
self.val.setAlignment(Qt.AlignTop) # type: ignore
# self.val.setFixedWidth(140)
layout.addWidget(self.val)
self.unit = unit
self.highlight = highlight
self.decimals = decimals
self.number = 0
if highlight:
font = QFont()
font.setBold(True)
font.setPointSize(14)
self.label.setFont(font)
self.val.setFont(font)
def value(self) -> float:
return self.number
def setLabel(self, label) -> None:
self.label.setText(label)
def setValue(self, number):
self.number = number
text = f'{number:.{int(self.decimals)}f}'
if self.unit is not None:
text = text + ' ' + self.unit
self.val.setText(text)
class InputNumberField(QWidget):
def __init__(self, identifier='', label='', unit=None, prefix=None, init=0.0, decimals=1, single_step=0.1, ll=-1e6, hl=1e6):
super().__init__()
layout = QHBoxLayout(self)
layout.setContentsMargins(10, 0, 0, 0)
layout.setSpacing(0)
self.identifier = identifier
self.label = QLabel(label)
self.label.setFixedWidth(140)
self.label.setContentsMargins(0, 0, 10, 0)
self.label.setWordWrap(True)
layout.addWidget(self.label)
self.val = QDoubleSpinBox()
self.val.setRange(ll, hl)
self.val.setDecimals(decimals)
self.val.setSingleStep(single_step)
self.val.setValue(init)
if unit is not None:
self.val.setSuffix(' ' + unit)
if prefix is not None:
self.val.setPrefix(prefix + ' ')
# self.val.setFixedWidth(140)
layout.addWidget(self.val)
def set_number(self, number):
self.val.setValue(number)
def has_focus(self) -> bool:
return self.val.hasFocus()
def value(self) -> float:
return self.val.value()
def value_changed_connect(self, func):
"""Connect a function to the Enter/Return key press."""
self.val.valueChanged.connect(
partial(func, identifier=self.identifier, value_obj=self.val, value=lambda: self.val.value())
)
class ComboBox(QWidget):
def __init__(self, identifier='', label='', enums=[]):
super().__init__()
layout = QHBoxLayout(self)
layout.setContentsMargins(10, 0, 0, 0)
layout.setSpacing(0)
self.identifier = identifier
self.label = QLabel(label)
self.label.setFixedWidth(140)
self.label.setContentsMargins(0, 0, 10, 0)
self.label.setWordWrap(True)
layout.addWidget(self.label)
self.value = QComboBox()
for entry in enums:
self.value.addItem(entry)
layout.addWidget(self.value)
def set_current_text(self, text):
self.value.setCurrentText(text)
def currentText(self) -> str:
return self.value.currentText()
def has_focus(self) -> bool:
return QApplication.focusWidget() is self.value.view()
def activated_connect(self, func):
"""Connect a function to the Enter/Return key press."""
self.value.activated.connect(
partial(func, identifier=self.identifier, value_obj=self.value, value=lambda: self.value.currentText())
)
def setDisabled(self, disable):
self.value.setDisabled(disable)
class Button(QWidget):
def __init__(self, label=None, label_button:str='', enabled=False):
super().__init__()
layout = QHBoxLayout(self)
layout.setContentsMargins(10, 0, 0, 0)
layout.setSpacing(0)
if label is not None:
self.label = QLabel(label)
self.label.setFixedWidth(140)
layout.addWidget(self.label)
self.button = QPushButton(label_button)
if label is not None:
self.button.setFixedWidth(160)
self.enable_button(enabled)
layout.addWidget(self.button)
def clicked_connect(self, func):
"""Connect a function to the button press."""
self.button.clicked.connect(func)
def enable_button(self, enable: bool = False):
if enable:
self.button.setStyleSheet(
f"QPushButton {{background-color: {get_accent_colors().default.name()}; color: white;}}"
)
self.button.setEnabled(True)
else: # disabled
self.button.setStyleSheet(
"QPushButton {{background-color: rgb(120, 120, 120); color: white;}}"
)
self.button.setDisabled(True)
def setText(self, text):
self.button.setText(text)
# class TextIndicator(QWidget):
# def __init__(self, label, unit=None, highlight=False):
# super().__init__()
# layout = QHBoxLayout(self)
# layout.setContentsMargins(10, 0, 0, 0)
# layout.setSpacing(0)
# self.label = QLabel(label)
# self.label.setFixedWidth(150)
# layout.addWidget(self.label)
# self.value = QLabel('-')
# self.value.setFixedWidth(160)
# layout.addWidget(self.value)
# self.unit = unit
# self.highlight = highlight
# if highlight:
# font = QFont()
# font.setBold(True)
# font.setPointSize(14)
# self.label.setFont(font)
# self.value.setFont(font)
# def set_text(self, text):
# if self.unit is not None:
# text = text + ' ' + self.unit
# self.value.setText(text)
# class Button(QWidget):
# def __init__(self, label, label_button):
# super().__init__()
# layout = QHBoxLayout(self)
# layout.setContentsMargins(10, 0, 0, 0)
# layout.setSpacing(0)
# self.label = QLabel(label)
# self.label.setFixedWidth(150)
# layout.addWidget(self.label)
# self.button = QPushButton(label_button)
# self.button.setStyleSheet("color: black; background-color: dodgerblue;")
# self.button.setFixedWidth(160)
# layout.addWidget(self.button)
# def set_on_press(self, func):
# """Connect a function to the button press."""
# self.button.clicked.connect(func)
# def enable_button(self):
# self.button.setEnabled(True)
# self.button.setStyleSheet("color: black; background-color: dodgerblue;")
# def disable_button(self):
# self.button.setEnabled(False)
# self.button.setStyleSheet("color: black; background-color: grey;")
# def set_button_text(self, text):
# self.button.setText(text)
# class LED(QWidget):
# def __init__(self, states, colors, label):
# super().__init__()
# self.states = states
# self.colors = colors
# layout = QHBoxLayout(self)
# layout.setContentsMargins(10, 0, 0, 0)
# layout.setSpacing(0)
# self.label = QLabel(label)
# self.label.setFixedWidth(150)
# layout.addWidget(self.label)
# self.led = QLabel()
# self.led.setFixedWidth(160)
# layout.addWidget(self.led)
# def apply_color(self, val):
# color = self.colors[self.states.index(val)]
# self.led.setStyleSheet(f"background-color: {color}; border: 1px solid black;")
# class InputTextField(QWidget):
# def __init__(self, topic, label):
# super().__init__()
# self.topic = topic
# layout = QHBoxLayout(self)
# layout.setContentsMargins(10, 0, 0, 0)
# layout.setSpacing(0)
# self.label = QLabel(label)
# self.label.setFixedWidth(140)
# self.label.setContentsMargins(0, 0, 10, 0)
# self.label.setWordWrap(True)
# layout.addWidget(self.label)
# self.val = QLineEdit()
# self.val.setPlaceholderText('0')
# # self.val.setFixedWidth(140)
# layout.addWidget(self.val)
# def set_text(self, text):
# self.val.setText(text)
# def has_focus(self) -> bool:
# return self.val.hasFocus()
# def text(self) -> str:
# return self.val.text()
# def set_on_return(self, func):
# """Connect a function to the Enter/Return key press."""
# self.val.returnPressed.connect(
# partial(func, self.val, self.topic, lambda: self.val.text())
# )
debye_bec/bec_widgets/widgets/x01da_offsets.yaml
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cm_try:
offset: 0.15
mo1_trx:
modifier:
axis: mo1_trx
range: [[-30, -0.1], [0.1, 30]]
offset: [0, 2.21]
mo1_try:
modifier:
axis: mo1_trx
range: [[-30, -0.1], [0.1, 30]]
offset: [0, -1.6]
sl1_centery:
offset: -1.8
fm_trx:
modifier:
axis: fm_trx
range: [[-66, -31], [-24, 7], [11, 31], [38, 66]]
offset: [0, 0, 0, -0.16]
fm_try:
modifier:
axis: fm_trx
range: [[-66, -31], [-24, 7], [11, 31], [38, 66]]
offset: [0, 0, 0, -0.45]
fm_rotx:
modifier:
axis: fm_trx
range: [[-66, -31], [-24, 7], [11, 31], [38, 66]]
offset: [0, 0, 0, 0.063]
fm_roty:
modifier:
axis: fm_trx
range: [[-66, -31], [-24, 7], [11, 31], [38, 66]]
offset: [0, 0, 0, -0.04]
sl2_centery:
offset: 1.2
ot_try:
offset: 0
ot_rotx:
offset: 0
debye_bec/bec_widgets/widgets/x01da_parameters.py
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"""
X01DA / Debye Beamline Parameters.
This file describes the parameter of each component of the Debye beamline
to be used for raytracing and geometrical calculations.
"""
import os
import numpy as np
from collections import namedtuple
import xrt.backends.raycing.materials as rm
# if os.environ.get("USE_XRT", "True").lower() in ("1", "true", "yes"):
# import xrt.backends.raycing.materials as rm # type: ignore
# else:
# class _DummyClass:
# def __init__(self, *args, **kwargs):
# pass
# class _DummyMaterials:
# Material = _DummyClass
# CrystalSi = _DummyClass
# rm = _DummyMaterials()
# XRT definitions
filterBeryl = rm.Material('Be', rho=1.85, kind='plate') # pyright: ignore[reportArgumentType]
filterDiamond = rm.Material('C', rho=3.52, kind='plate') # pyright: ignore[reportArgumentType]
filterGraphite = rm.Material('C', rho=2.266, kind='plate') # pyright: ignore[reportArgumentType]
stripeSi = rm.Material('Si', rho=2.33) # pyright: ignore[reportArgumentType]
stripePt = rm.Material('Pt', rho=21.45) # pyright: ignore[reportArgumentType]
stripeRh = rm.Material('Rh', rho=12.41) # pyright: ignore[reportArgumentType]
stripeCr = rm.Material('Cr', rho=7.14) # pyright: ignore[reportArgumentType]
stripePyrex = rm.Material('Si', rho=2.20) # Use Si as bare element and the density of SiO2 # pyright: ignore[reportArgumentType]
si111_1 = rm.CrystalSi(hkl=(1, 1, 1), tK=77) # first xtal surface
si311_1 = rm.CrystalSi(hkl=(3, 1, 1), tK=77) # first xtal surface
si333_1 = rm.CrystalSi(hkl=(3, 3, 3), tK=77) # first xtal surface
si511_1 = rm.CrystalSi(hkl=(5, 1, 1), tK=77) # first xtal surface
si111_2 = rm.CrystalSi(hkl=(1, 1, 1), tK=77) # second xtal surface
si311_2 = rm.CrystalSi(hkl=(3, 1, 1), tK=77) # second xtal surface
si333_2 = rm.CrystalSi(hkl=(3, 3, 3), tK=77) # second xtal surface
si511_2 = rm.CrystalSi(hkl=(5, 1, 1), tK=77) # second xtal surface
filterDiamond = rm.Material('C', rho=3.52, kind='plate') # pyright: ignore[reportArgumentType]
filterBe = rm.Material('Be', rho=1.85, kind='plate') # pyright: ignore[reportArgumentType]
filterSi3N4 = rm.Material(['Si', 'N'], quantities=[3, 4], rho=3.44, kind='plate') # pyright: ignore[reportArgumentType]
filterAl = rm.Material('Al', rho=2.69, kind='plate') # pyright: ignore[reportArgumentType]
filterGraphite = rm.Material('C', rho=2.266, kind='plate') # pyright: ignore[reportArgumentType]
# General parameters
sourceHeight = 0
#Synchrotron
synchrotron = namedtuple('synchrotron', ['eE', 'eI', 'eEspread',
'eEpsilonX', 'eEpsilonZ', 'betaX', 'betaZ'])
sls1 = synchrotron(
eE = 2.4,
eI = 0.4,
eEspread=0.878e-3,
eEpsilonX=5.63,
eEpsilonZ=0.007,
betaX=0.45,
betaZ=14.4,
)
sls2 = synchrotron(
eE=2.7,
eI=0.4,
eEspread=1.147e-3,
eEpsilonX=0.156,
eEpsilonZ=0.01,
betaX=0.18,
betaZ=4.6,
)
# Source
bendingMagnet = namedtuple('bendingMagnet', ['name', 'center', 'sync', 'B0'])
sls1_14t = bendingMagnet(
name='FE-BM-SLS1-1.4T',
center=(0, 0, 0),
sync=sls1,
B0=1.4,)
sls2_21t = bendingMagnet(
name='FE-BM-SLS2-2.1T',
center=(0, 0, 0),
sync=sls2,
B0=2.1,)
sls2_35t = bendingMagnet(
name='FE-BM-SLS2-3.5T',
center=(0, 0, 0),
sync=sls2,
B0=3.5,)
sls2_50t = bendingMagnet(
name='FE-BM-SLS2-5.0T',
center=(0, 0, 0),
sync=sls2,
B0=5.0,)
# FE slits
fe_slits = namedtuple('slits', ['name', 'center', 'center1', 'center2', 'maxDivH', 'maxDivV'])
feSlits = fe_slits(
name='FE-SLITS',
center=(0, 6117, sourceHeight),
center1=(0, 5045, sourceHeight),
center2=(0, 5289.5, sourceHeight),
maxDivH=1.8e-3,
maxDivV=0.8e-3,)
# FE Window
filt = namedtuple('filt', ['name', 'center', 'pitch', 'limPhysX', 'limPhysY', 'surface', 'material', 'thickness'])
feWindow = filt(
name='FE-WINDOW',
center=(0., 7020, sourceHeight),
pitch=np.pi/2,
limPhysX=(-6, 6),
limPhysY=(-3., 3.),
surface='None',
material=filterDiamond,
thickness=0.1,)
feWindow = feWindow._replace(surface=f'CVD Diamond window {feWindow.thickness*1e3:0.0f} $\\mu$m')
# Collimating mirror
collimatingMirror = namedtuple('collimatingMirror', ['name',
'center', 'surface', 'material', 'limPhysX', 'limPhysY',
'limOptX', 'limOptY', 'R', 'pitch', 'jack1', 'jack2', 'jack3',
'tx1', 'tx2'])
cm = collimatingMirror(
name='FE-CM',
center=[0, 6890, sourceHeight],
surface=('Si','Pt','Rh'),
material=(stripeSi, stripePt, stripeRh),
limPhysX=(-34, 34),
limPhysY=(-600, 600),
limOptX=((-21, -7, 14), (-11, 11, 23)),
limOptY=((-500, -500, -500), (500, 500, 500)),
R=[3e6, 15e6],
pitch=[-5.0e-3, -0.0e-3],
jack1=[0., 7210., 0.], #Tripod X, Y, Z (global)
jack2=[-210., 8310., 0.],
jack3=[210., 8310., 0.],
tx1=[0.0, -575.5], # X-Stage 1 [x, y] (local)
tx2=[0.0, 575],) # X-Stage 2
apertures = namedtuple('apertures', ['name', 'center', 'opening'])
fePS = apertures(
name='FE-PS',
center=[0, 8815, sourceHeight],
opening=[-20., 20., -20.+12.5, 20.+12.5]) # left, right, bottom, top
opWbBsBlock = apertures(
name='OP-WB-BS-BLOCK',
center=[0., 13860, sourceHeight],
opening=[-18., 18., 25, 85.5]) # left, right, bottom, top
# opening=[-18., 18., 42, 76], # X10DA
# Monochromator
monochromator = namedtuple('monochromator', ['name', 'center',
'xtal', 'material1', 'material2', 'xtalWidth', 'xtalOffsetX',
'xtalLength1', 'xtalLength2', 'xtalGap', 'rotOffset',
'heightOffset', 'braggLim', 'jack1', 'jack2', 'jack3', 'tx'])
mo1 = monochromator(
name='OP-MO1',
center=[0., 11750, sourceHeight],
xtal=('Si311','Si111'),
material1=(si311_1, si111_1),
material2=(si311_2, si111_2),
xtalWidth = (24, 24),
xtalOffsetX=(-21.2, 21.2),
xtalLength1 = (55, 55),
xtalLength2 = (105, 105),
xtalGap = (8, 8),
rotOffset = 6,
heightOffset = 8.5,
braggLim = [3.6, 33],
jack1=[0., 11350., 0.], #Tripod maybe not available!
jack2=[-400., 12350., 0.],
jack3=[400., 12350., 0.],
tx=0.0,) # X-Stage [x]
mo2 = monochromator(
name='OP-CCM2',
center=[0., 13250, sourceHeight],
xtal=('Si311','Si111'),
material1=(si311_1, si111_1),
material2=(si311_2, si111_2),
xtalWidth = (24, 24),
xtalOffsetX=(-21, 21),
xtalLength1 = (55, 55),
xtalLength2 = (105, 105),
xtalGap = (8, 8),
rotOffset = 6,
heightOffset = 8.5,
braggLim = [3.6, 33],
jack1=[0., 13350., 0.], #Tripod maybe not available!
jack2=[-400., 14350., 0.],
jack3=[400., 14350., 0.],
tx=0.0,) # X-Stage [x]
# OP Slits
op_slits = namedtuple('op_slits', ['name', 'center'])
opSlits1 = op_slits(
name='OP-SLITS 1',
center=(0, 14349.6, sourceHeight),
)
opSlits2 = op_slits(
name='OP-SLITS 2',
center=(0, 18134.8, sourceHeight),
)
# OP Beam Monitors
op_bm = namedtuple('op_bm', ['name', 'center'])
opBM1 = op_bm(
name='OP Beam Monitor 1',
center=(0, 14599.6, sourceHeight),
)
opBM2 = op_bm(
name='OP Beam Monitor 2',
center=(0, 18384.8, sourceHeight),
)
# Focusing mirror
focusingMirror = namedtuple('focusingMirror', ['name', 'center',
'surfaceToroid', 'materialToroid', 'surfaceFlat', 'materialFlat',
'limPhysXToroid', 'limPhysYToroid', 'limPhysXFlat', 'limPhysYFlat',
'limOptXToroid', 'limOptYToroid', 'limOptXFlat', 'limOptYFlat',
'R', 'pitch', 'r', 'xToroid', 'xFlat', 'hToroid', 'jack1', 'jack2', 'jack3',
'tx1', 'tx2'])
fm = focusingMirror(
name='OP-FM',
center=[0., 15670, sourceHeight], # nominal height 58 mm above ring, SLS1!
surfaceToroid=('Rh', 'Pt'),
materialToroid=(stripeRh, stripePt),
surfaceFlat=('Rh', 'Pt'),
materialFlat=(stripeRh, stripePt),
limPhysXToroid=(-79., 79.),
limPhysYToroid=(-575., 575.),
limPhysXFlat=(-79., 79.),
limPhysYFlat=(-575., 575.),
limOptXToroid=((-38, 66), (-66, 31)),
limOptYToroid=((-500., -500.), (500., 500.)),
limOptXFlat=((-11.45, 23.55), (-30.45, -6.45)),
limOptYFlat=((-500., -500.), (500., 500.)),
R=[3e6, 15e6],
pitch=[-5.0e-3, 0e-3],
r=[35.510, 24.986],
xToroid=[-52, 48.5], # offset in local x
xFlat = [-20.95, 8.55],
hToroid=[2.88, 7.15], # depth of the cylinder at x = xCylinder1 and x = xCylinder2.
jack1=[-130., 15535-538., 0.],
jack2=[130., 15535+538., 0.],
jack3=[0., 15535+538., 0.],
tx1=[0., -575.], # X-Stage 1 [x, y]
tx2=[0., 575.],) # X-Stage 2 [x, y]
# EH Window
ehWindow = filt(
name='EH-WINDOW',
center=(0., 19998.3, sourceHeight),
pitch=np.pi/2,
limPhysX=(-20., 20.),
limPhysY=(-4, 4),
surface='None',
material=filterSi3N4,
thickness=0.002,)
ehWindow = ehWindow._replace(surface=f'Beryllium window {ehWindow.thickness*1e3:0.0f} $\\mu$m')
# Sample
sample = namedtuple('sample', ['name', 'center'])
smpl = sample(
name='EH-SMPL',
center=[0, 23365, sourceHeight],)
smpl2 = sample(
name='EH-SMPL2',
center=[0, 27500, sourceHeight],)
# Vacuum pipes
# DN40CF ID = 35 mm oder 37 mm
# DN50CF ID = 47.5 mm
# DN63CF ID = 60.2 mm oder 66 mm
# DN100CF ID = 97.4 mm oder 104 mm
pipe = namedtuple('pipes', ['center', 'diameter', 'start', 'end'])
vacuum_pipes = pipe(
center= [27.5, (37.5+27.5)/2, 37.5, 62.5, 72.5],
diameter=[97.4, 97.4, 97.4, 97.4, 97.4],
start= [10952.88, 11750+250, mo2.center[1]+250, 14000, fm.center[1]],
end= [11750-250, mo2.center[1]-250, 14000, fm.center[1], ehWindow.center[1]],
)
Walls = namedtuple('walls', ['start', 'end', 'height'])
walls = Walls(
start= [13999.30],
end= [13999+75.5+30],
height= [[-20, 25]],
)
debye_bec/device_configs/x01da_experimental_hutch.yaml
+87 -27
View File
@@ -5,7 +5,7 @@
ot_tryu:
readoutPriority: baseline
description: Optical Table Y-Translation Upstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES-OT:TRYU
onFailure: retry
@@ -15,7 +15,7 @@ ot_tryu:
ot_tryd:
readoutPriority: baseline
description: Optical Table Y-Translation Downstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES-OT:TRYD
onFailure: retry
@@ -25,7 +25,7 @@ ot_tryd:
ot_es1_trz:
readoutPriority: baseline
description: Optical Table ES1 Z-Translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-OT:TRZ
onFailure: retry
@@ -35,7 +35,7 @@ ot_es1_trz:
ot_es2_trz:
readoutPriority: baseline
description: Optical Table ES2 Z-Translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES2-OT:TRZ
onFailure: retry
@@ -45,17 +45,17 @@ ot_es2_trz:
ot_try:
readoutPriority: baseline
description: Optical Table Y-Translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES-OT:TRY
onFailure: retry
enabled: true
softwareTrigger: false
ot_pitch:
ot_rotx:
readoutPriority: baseline
description: Optical Table Pitch
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES-OT:ROTX
onFailure: retry
@@ -69,7 +69,7 @@ ot_pitch:
es0wi_try:
readoutPriority: baseline
description: End Station 0 Exit Window Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-WI:TRY
onFailure: retry
@@ -97,7 +97,7 @@ es0filter:
es0sl_trxr:
readoutPriority: baseline
description: End Station slits X-translation Ring-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:TRXR
onFailure: retry
@@ -107,7 +107,7 @@ es0sl_trxr:
es0sl_trxw:
readoutPriority: baseline
description: End Station slits X-translation Wall-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:TRXW
onFailure: retry
@@ -117,7 +117,7 @@ es0sl_trxw:
es0sl_tryb:
readoutPriority: baseline
description: End Station slits Y-translation Bottom-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:TRYB
onFailure: retry
@@ -127,7 +127,7 @@ es0sl_tryb:
es0sl_tryt:
readoutPriority: baseline
description: End Station slits X-translation Top-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:TRYT
onFailure: retry
@@ -137,7 +137,7 @@ es0sl_tryt:
es0sl_center:
readoutPriority: baseline
description: End Station slits X-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:CENTERX
onFailure: retry
@@ -147,7 +147,7 @@ es0sl_center:
es0sl_gapx:
readoutPriority: baseline
description: End Station slits X-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:GAPX
onFailure: retry
@@ -157,7 +157,7 @@ es0sl_gapx:
es0sl_centery:
readoutPriority: baseline
description: End Station slits Y-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:CENTERY
onFailure: retry
@@ -167,7 +167,7 @@ es0sl_centery:
es0sl_gapy:
readoutPriority: baseline
description: End Station slits Y-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES0-SL:GAPY
onFailure: retry
@@ -195,7 +195,7 @@ es1_alignment_laser:
es1man_trx:
readoutPriority: baseline
description: End Station sample manipulator X-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-MAN1:TRX
onFailure: retry
@@ -205,7 +205,7 @@ es1man_trx:
es1man_try:
readoutPriority: baseline
description: End Station sample manipulator Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-MAN1:TRY
onFailure: retry
@@ -215,7 +215,7 @@ es1man_try:
es1man_trz:
readoutPriority: baseline
description: End Station sample manipulator Z-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-MAN1:TRZ
onFailure: retry
@@ -225,7 +225,7 @@ es1man_trz:
es1man_roty:
readoutPriority: baseline
description: End Station sample manipulator Y-rotation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-MAN1:ROTY
onFailure: retry
@@ -239,7 +239,7 @@ es1man_roty:
es1arc_roty:
readoutPriority: baseline
description: End Station segmented arc Y-rotation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-ARC:ROTY
onFailure: retry
@@ -249,7 +249,7 @@ es1arc_roty:
es1det1_trx:
readoutPriority: baseline
description: End Station SDD 1 X-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-DET1:TRX
onFailure: retry
@@ -259,7 +259,7 @@ es1det1_trx:
es1bm1_trx:
readoutPriority: baseline
description: End Station X-ray Eye X-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-BM1:TRX
onFailure: retry
@@ -269,7 +269,7 @@ es1bm1_trx:
es1det2_trx:
readoutPriority: baseline
description: End Station SDD 2 X-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-DET2:TRX
onFailure: retry
@@ -283,7 +283,7 @@ es1det2_trx:
es2ma2_try:
readoutPriority: baseline
description: End Station ionization chamber 1+2 Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES2-MA2:TRY
onFailure: retry
@@ -293,7 +293,7 @@ es2ma2_try:
es2ma2_trz:
readoutPriority: baseline
description: End Station ionization chamber 1+2 Z-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES2-MA2:TRZ
onFailure: retry
@@ -307,7 +307,7 @@ es2ma2_trz:
es2ma3_try:
readoutPriority: baseline
description: End Station XRD detector Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES2-MA3:TRY
onFailure: retry
@@ -386,4 +386,64 @@ es_light_toggle:
read_pv: "X01DA-EH-LIGHT:TOGGLE"
onFailure: retry
enabled: true
softwareTrigger: false
es_gas_sensor_o2:
readoutPriority: baseline
description: ES Gas Sensor O2
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-KIMESSA2:EH-O2"
onFailure: retry
enabled: true
softwareTrigger: false
es_gas_sensor_h2s:
readoutPriority: baseline
description: ES Gas Sensor H2S
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-KIMESSA2:EH-H2S"
onFailure: retry
enabled: true
softwareTrigger: false
es_gas_sensor_no2:
readoutPriority: baseline
description: ES Gas Sensor NO2
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-KIMESSA2:EH-NO2"
onFailure: retry
enabled: true
softwareTrigger: false
es_gas_sensor_co:
readoutPriority: baseline
description: ES Gas Sensor CO
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-KIMESSA2:EH-CO"
onFailure: retry
enabled: true
softwareTrigger: false
es_gas_sensor_h2:
readoutPriority: baseline
description: ES Gas Sensor H2
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-KIMESSA2:EH-H2"
onFailure: retry
enabled: true
softwareTrigger: false
es_gas_sensor_nh3:
readoutPriority: baseline
description: ES Gas Sensor NH3
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-KIMESSA2:EH-NH3"
onFailure: retry
enabled: true
softwareTrigger: false
debye_bec/device_configs/x01da_frontend.yaml
+46 -21
View File
@@ -1,4 +1,18 @@
###################################
## Frontend Absorber ##
###################################
abs:
readoutPriority: baseline
description: Frontend Absorber
deviceClass: debye_bec.devices.absorber.Absorber
deviceConfig:
prefix: "X01DA-FE-ABS1:"
onFailure: retry
enabled: true
softwareTrigger: false
###################################
## Frontend Slits ##
###################################
@@ -6,7 +20,7 @@
sldi_trxr:
readoutPriority: baseline
description: Front-end slit diaphragm X-translation Ring-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:TRXR
onFailure: retry
@@ -16,7 +30,7 @@ sldi_trxr:
sldi_trxw:
readoutPriority: baseline
description: Front-end slit diaphragm X-translation Wall-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:TRXW
onFailure: retry
@@ -26,7 +40,7 @@ sldi_trxw:
sldi_tryb:
readoutPriority: baseline
description: Front-end slit diaphragm Y-translation Bottom-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:TRYB
onFailure: retry
@@ -36,7 +50,7 @@ sldi_tryb:
sldi_tryt:
readoutPriority: baseline
description: Front-end slit diaphragm X-translation Top-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:TRYT
onFailure: retry
@@ -46,7 +60,7 @@ sldi_tryt:
sldi_centerx:
readoutPriority: baseline
description: Front-end slit diaphragm X-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:CENTERX
onFailure: retry
@@ -56,7 +70,7 @@ sldi_centerx:
sldi_gapx:
readoutPriority: baseline
description: Front-end slit diaphragm X-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:GAPX
onFailure: retry
@@ -66,7 +80,7 @@ sldi_gapx:
sldi_centery:
readoutPriority: baseline
description: Front-end slit diaphragm Y-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:CENTERY
onFailure: retry
@@ -76,7 +90,7 @@ sldi_centery:
sldi_gapy:
readoutPriority: baseline
description: Front-end slit diaphragm Y-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-SLDI:GAPY
onFailure: retry
@@ -90,7 +104,7 @@ sldi_gapy:
cm_trxu:
readoutPriority: baseline
description: Collimating Mirror X-translation upstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:TRXU
onFailure: retry
@@ -100,7 +114,7 @@ cm_trxu:
cm_trxd:
readoutPriority: baseline
description: Collimating Mirror X-translation downstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:TRXD
onFailure: retry
@@ -110,7 +124,7 @@ cm_trxd:
cm_tryu:
readoutPriority: baseline
description: Collimating Mirror Y-translation upstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:TRYU
onFailure: retry
@@ -120,7 +134,7 @@ cm_tryu:
cm_trydr:
readoutPriority: baseline
description: Collimating Mirror Y-translation downstream ring
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:TRYDR
onFailure: retry
@@ -130,7 +144,7 @@ cm_trydr:
cm_trydw:
readoutPriority: baseline
description: Collimating Mirror Y-translation downstream wall
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:TRYDW
onFailure: retry
@@ -140,17 +154,28 @@ cm_trydw:
cm_bnd:
readoutPriority: baseline
description: Collimating Mirror bender
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:BND
onFailure: retry
enabled: true
softwareTrigger: false
cm_bnd_radius:
readoutPriority: baseline
description: Collimating Mirror Bending Radius
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: X01DA-CPCL-CM:BNDFORCE
onFailure: retry
readOnly: true
enabled: true
softwareTrigger: false
cm_rotx:
readoutPriority: baseline
description: Collimating Morror Pitch
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:ROTX
onFailure: retry
@@ -160,7 +185,7 @@ cm_rotx:
cm_roty:
readoutPriority: baseline
description: Collimating Morror Yaw
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:ROTY
onFailure: retry
@@ -170,7 +195,7 @@ cm_roty:
cm_rotz:
readoutPriority: baseline
description: Collimating Morror Roll
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:ROTZ
onFailure: retry
@@ -180,7 +205,7 @@ cm_rotz:
cm_trx:
readoutPriority: baseline
description: Collimating Morror Center Point X
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:XTCP
onFailure: retry
@@ -190,7 +215,7 @@ cm_trx:
cm_try:
readoutPriority: baseline
description: Collimating Morror Center Point Y
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:YTCP
onFailure: retry
@@ -200,7 +225,7 @@ cm_try:
cm_ztcp:
readoutPriority: baseline
description: Collimating Morror Center Point Z
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:ZTCP
onFailure: retry
@@ -210,7 +235,7 @@ cm_ztcp:
cm_xstripe:
readoutPriority: baseline
description: Collimating Morror X Stripe
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-FE-CM:XSTRIPE
onFailure: retry
debye_bec/device_configs/x01da_hutch_cameras.yaml
+34
View File
@@ -0,0 +1,34 @@
###################################
## Hutch Cameras ##
###################################
hutch_cam_1:
readoutPriority: baseline
description: Hutch Camera 1
deviceClass: debye_bec.devices.cameras.hutch_cam.HutchCam
deviceConfig:
prefix: "pcp085420"
onFailure: retry
enabled: true
softwareTrigger: false
hutch_cam_2:
readoutPriority: baseline
description: Hutch Camera 2
deviceClass: debye_bec.devices.cameras.hutch_cam.HutchCam
deviceConfig:
prefix: "pcp085436"
onFailure: retry
enabled: true
softwareTrigger: false
hutch_cam_3:
readoutPriority: baseline
description: Hutch Camera 3
deviceClass: debye_bec.devices.cameras.hutch_cam.HutchCam
deviceConfig:
prefix: "pcp085435"
onFailure: retry
enabled: true
softwareTrigger: false
debye_bec/device_configs/x01da_optics.yaml
+54 -38
View File
@@ -3,30 +3,30 @@
## Monochromator ##
###################################
mo_try:
mo1_try:
readoutPriority: baseline
description: Monochromator Y Translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-MO1:TRY
onFailure: retry
enabled: true
softwareTrigger: false
mo_trx:
mo1_trx:
readoutPriority: baseline
description: Monochromator X Translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-MO1:TRX
onFailure: retry
enabled: true
softwareTrigger: false
mo_roty:
mo1_roty:
readoutPriority: baseline
description: Monochromator Yaw
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-MO1:ROTY
onFailure: retry
@@ -40,7 +40,7 @@ mo_roty:
sl1_trxr:
readoutPriority: baseline
description: Optics slits 1 X-translation Ring-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:TRXR
onFailure: retry
@@ -53,7 +53,7 @@ sl1_trxr:
sl1_trxw:
readoutPriority: baseline
description: Optics slits 1 X-translation Wall-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:TRXW
onFailure: retry
@@ -66,7 +66,7 @@ sl1_trxw:
sl1_tryb:
readoutPriority: baseline
description: Optics slits 1 Y-translation Bottom-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:TRYB
onFailure: retry
@@ -79,7 +79,7 @@ sl1_tryb:
sl1_tryt:
readoutPriority: baseline
description: Optics slits 1 X-translation Top-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:TRYT
onFailure: retry
@@ -92,7 +92,7 @@ sl1_tryt:
bm1_try:
readoutPriority: baseline
description: Beam Monitor 1 Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-BM1:TRY
onFailure: retry
@@ -105,7 +105,7 @@ bm1_try:
sl1_centerx:
readoutPriority: baseline
description: Optics slits 1 X-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:CENTERX
onFailure: retry
@@ -118,7 +118,7 @@ sl1_centerx:
sl1_gapx:
readoutPriority: baseline
description: Optics slits 1 X-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:GAPX
onFailure: retry
@@ -131,7 +131,7 @@ sl1_gapx:
sl1_centery:
readoutPriority: baseline
description: Optics slits 1 Y-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:CENTERY
onFailure: retry
@@ -144,7 +144,7 @@ sl1_centery:
sl1_gapy:
readoutPriority: baseline
description: Optics slits 1 Y-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL1:GAPY
onFailure: retry
@@ -161,62 +161,78 @@ sl1_gapy:
fm_trxu:
readoutPriority: baseline
description: Focusing Mirror X-translation upstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:TRXU
onFailure: retry
enabled: true
softwareTrigger: false
fm_trxd:
readoutPriority: baseline
description: Focusing Mirror X-translation downstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:TRXD
onFailure: retry
enabled: true
softwareTrigger: false
fm_tryd:
readoutPriority: baseline
description: Focusing Mirror Y-translation downstream
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:TRYD
onFailure: retry
enabled: true
softwareTrigger: false
fm_tryur:
readoutPriority: baseline
description: Focusing Mirror Y-translation upstream ring
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:TRYUR
onFailure: retry
enabled: true
softwareTrigger: false
fm_tryuw:
readoutPriority: baseline
description: Focusing Mirror Y-translation upstream wall
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:TRYUW
onFailure: retry
enabled: true
softwareTrigger: false
fm_bnd:
readoutPriority: baseline
description: Focusing Mirror bender
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:BND
onFailure: retry
enabled: true
softwareTrigger: false
fm_bnd_radius:
readoutPriority: baseline
description: Focusing Mirror Bending Radius
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: X01DA-CPCL-FM:BNDFORCE
onFailure: retry
readOnly: true
enabled: true
softwareTrigger: false
fm_rotx:
readoutPriority: baseline
description: Focusing Morror Pitch
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:ROTX
onFailure: retry
@@ -226,7 +242,7 @@ fm_rotx:
fm_roty:
readoutPriority: baseline
description: Focusing Morror Yaw
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:ROTY
onFailure: retry
@@ -236,27 +252,27 @@ fm_roty:
fm_rotz:
readoutPriority: baseline
description: Focusing Morror Roll
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:ROTZ
onFailure: retry
enabled: true
softwareTrigger: false
fm_xctp:
fm_trx:
readoutPriority: baseline
description: Focusing Morror Center Point X
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:XTCP
onFailure: retry
enabled: true
softwareTrigger: false
fm_ytcp:
fm_try:
readoutPriority: baseline
description: Focusing Morror Center Point Y
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:YTCP
onFailure: retry
@@ -266,7 +282,7 @@ fm_ytcp:
fm_ztcp:
readoutPriority: baseline
description: Focusing Morror Center Point Z
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-FM:ZTCP
onFailure: retry
@@ -280,7 +296,7 @@ fm_ztcp:
sl2_trxr:
readoutPriority: baseline
description: Optics slits 2 X-translation Ring-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:TRXR
onFailure: retry
@@ -293,7 +309,7 @@ sl2_trxr:
sl2_trxw:
readoutPriority: baseline
description: Optics slits 2 X-translation Wall-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:TRXW
onFailure: retry
@@ -306,7 +322,7 @@ sl2_trxw:
sl2_tryb:
readoutPriority: baseline
description: Optics slits 2 Y-translation Bottom-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:TRYB
onFailure: retry
@@ -319,7 +335,7 @@ sl2_tryb:
sl2_tryt:
readoutPriority: baseline
description: Optics slits 2 X-translation Top-edge
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:TRYT
onFailure: retry
@@ -332,7 +348,7 @@ sl2_tryt:
bm2_try:
readoutPriority: baseline
description: Beam Monitor 2 Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-BM2:TRY
onFailure: retry
@@ -345,7 +361,7 @@ bm2_try:
sl2_centerx:
readoutPriority: baseline
description: Optics slits 2 X-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:CENTERX
onFailure: retry
@@ -358,7 +374,7 @@ sl2_centerx:
sl2_gapx:
readoutPriority: baseline
description: Optics slits 2 X-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:GAPX
onFailure: retry
@@ -371,7 +387,7 @@ sl2_gapx:
sl2_centery:
readoutPriority: baseline
description: Optics slits 2 Y-center
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:CENTERY
onFailure: retry
@@ -384,7 +400,7 @@ sl2_centery:
sl2_gapy:
readoutPriority: baseline
description: Optics slits 2 Y-gap
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-OP-SL2:GAPY
onFailure: retry
debye_bec/device_configs/x01da_standard_config.yaml
+17 -12
View File
@@ -25,7 +25,7 @@ frontend_config:
## Bragg Monochromator
mo1_bragg:
readoutPriority: monitored
readoutPriority: baseline
description: Positioner for the Monochromator
deviceClass: debye_bec.devices.mo1_bragg.mo1_bragg.Mo1Bragg
deviceConfig:
@@ -34,14 +34,14 @@ mo1_bragg:
enabled: true
softwareTrigger: false
mo1_bragg_angle:
readoutPriority: baseline
description: Positioner for the Monochromator
deviceClass: debye_bec.devices.mo1_bragg.mo1_bragg_angle.Mo1BraggAngle
deviceConfig:
prefix: "X01DA-OP-MO1:BRAGG:"
onFailure: retry
enabled: true
softwareTrigger: false
readoutPriority: baseline
description: Positioner for the Monochromator
deviceClass: debye_bec.devices.mo1_bragg.mo1_bragg_angle.Mo1BraggAngle
deviceConfig:
prefix: "X01DA-OP-MO1:BRAGG:"
onFailure: retry
enabled: true
softwareTrigger: false
## Remaining optics hutch
optics_config:
@@ -51,7 +51,7 @@ optics_config:
## Experimental Hutch ##
###################################
## NIDAQ
# ## NIDAQ
nidaq:
readoutPriority: monitored
description: NIDAQ backend for data reading for debye scans
@@ -67,8 +67,13 @@ xas_config:
- !include ./x01da_xas.yaml
## XRD (Pilatus, pinhole, beamstop)
xrd_config:
- !include ./x01da_xrd.yaml
#xrd_config:
# - !include ./x01da_xrd.yaml
# Commented out because too slow
## Hutch cameras
# hutch_cams:
# - !include ./x01da_hutch_cameras.yaml
## Remaining experimental hutch
es_config:
debye_bec/device_configs/x01da_xas.yaml
+37 -27
View File
@@ -3,35 +3,45 @@
## Ionization Chambers ##
###################################
# ic0:
# readoutPriority: baseline
# description: Ionization chamber 0
# deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.IonizationChamber0
# deviceConfig:
# prefix: "X01DA-"
# onFailure: retry
# enabled: true
# softwareTrigger: false
ic0:
readoutPriority: baseline
description: Ionization chamber 0
deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.IonizationChamber0
deviceConfig:
prefix: "X01DA-"
onFailure: retry
enabled: true
softwareTrigger: false
# ic1:
# readoutPriority: baseline
# description: Ionization chamber 1
# deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.IonizationChamber1
# deviceConfig:
# prefix: "X01DA-"
# onFailure: retry
# enabled: true
# softwareTrigger: false
ic1:
readoutPriority: baseline
description: Ionization chamber 1
deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.IonizationChamber1
deviceConfig:
prefix: "X01DA-"
onFailure: retry
enabled: true
softwareTrigger: false
# ic2:
# readoutPriority: baseline
# description: Ionization chamber 2
# deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.IonizationChamber2
# deviceConfig:
# prefix: "X01DA-"
# onFailure: retry
# enabled: true
# softwareTrigger: false
ic2:
readoutPriority: baseline
description: Ionization chamber 2
deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.IonizationChamber2
deviceConfig:
prefix: "X01DA-"
onFailure: retry
enabled: true
softwareTrigger: false
pips:
readoutPriority: baseline
description: Pips diode
deviceClass: debye_bec.devices.ionization_chambers.ionization_chamber.Pips
deviceConfig:
prefix: "X01DA-"
onFailure: retry
enabled: true
softwareTrigger: false
###################################
## Reference Foil Changer ##
debye_bec/device_configs/x01da_xrd.yaml
+16 -16
View File
@@ -6,7 +6,7 @@
pin1_trx:
readoutPriority: baseline
description: Pinhole X-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-PIN1:TRX
onFailure: retry
@@ -17,7 +17,7 @@ pin1_trx:
pin1_try:
readoutPriority: baseline
description: Pinhole Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-PIN1:TRY
onFailure: retry
@@ -28,7 +28,7 @@ pin1_try:
pin1_rotx:
readoutPriority: baseline
description: Pinhole X-rotation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-PIN1:ROTX
onFailure: retry
@@ -39,7 +39,7 @@ pin1_rotx:
pin1_roty:
readoutPriority: baseline
description: Pinhole Y-rotation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES1-PIN1:ROTY
onFailure: retry
@@ -54,7 +54,7 @@ pin1_roty:
es2bs_trx:
readoutPriority: baseline
description: End Station beamstop X-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES2-BS:TRX
onFailure: retry
@@ -64,7 +64,7 @@ es2bs_trx:
es2bs_try:
readoutPriority: baseline
description: End Station beamstop Y-translation
deviceClass: ophyd.EpicsMotor
deviceClass: ophyd_devices.EpicsMotorEC
deviceConfig:
prefix: X01DA-ES2-BS:TRY
onFailure: retry
@@ -86,7 +86,7 @@ pilatus_curtain:
softwareTrigger: false
pilatus:
readoutPriority: async
readoutPriority: baseline
description: Pilatus
deviceClass: debye_bec.devices.pilatus.pilatus.Pilatus
deviceTags:
@@ -97,12 +97,12 @@ pilatus:
enabled: true
softwareTrigger: true
# sampl_pil:
# readoutPriority: baseline
# description: Sample to pilatus distance
# deviceClass: ophyd.EpicsSignalRO
# deviceConfig:
# read_pv: "X01DA-SAMPL-PIL"
# onFailure: retry
# enabled: true
# softwareTrigger: false
pilatus_smpl:
readoutPriority: baseline
description: Sample to pilatus distance
deviceClass: ophyd.EpicsSignalRO
deviceConfig:
read_pv: "X01DA-ES2-DET:SMPLDIST"
onFailure: retry
enabled: true
softwareTrigger: false
debye_bec/devices/absorber.py
+72
View File
@@ -0,0 +1,72 @@
"""Frontend Absorber"""
from __future__ import annotations
import enum
from typing import TYPE_CHECKING
from ophyd import Component as Cpt
from ophyd import EpicsSignal, EpicsSignalRO
from ophyd_devices import CompareStatus, DeviceStatus
from ophyd_devices.interfaces.base_classes.psi_device_base import PSIDeviceBase
if TYPE_CHECKING:
from bec_lib.devicemanager import ScanInfo
class AbsorberError(Exception):
"""Absorber specific exception"""
class STATUS(int, enum.Enum):
"""Absorber States"""
MOVING_CLOSE = 0
OPEN = 1
MOVING_OPEN = 2
CLOSED = 3
NOT_ENABLED = 4
TIMEOUT_CLOSE = 5
TIMEOUT_OPEN = 6
CLOSE_LS_LOST = 7
OPEN_LS_LOST = 8
CLOSE_LS_NOT_FREE = 9
OPEN_LS_NOT_FREE = 10
ERROR_LS = 11
TO_CONNECT = 12
MAN_OPEN = 13
UNDEFINED = 14
class Absorber(PSIDeviceBase):
"""Class for the Frontend Absorber"""
USER_ACCESS = ["open", "close"]
request = Cpt(EpicsSignal, suffix="REQUEST", kind="config", doc="Open/Close Absorber")
status = Cpt(EpicsSignalRO, suffix="STATUS", kind="normal", doc="Absorber Status")
status_string = Cpt(EpicsSignalRO, suffix="STATUS", kind="normal", string=True, doc="Absorber Status")
def __init__(self, *, name: str, prefix: str = "", scan_info: ScanInfo | None = None, **kwargs):
super().__init__(name=name, prefix=prefix, scan_info=scan_info, **kwargs)
self.timeout_for_move = 10
# Wait for connection on all components, ensure IOC is connected
self.wait_for_connection(all_signals=True, timeout=5)
def open(self) -> DeviceStatus | None:
"""Open the Absorber"""
if self.status.get() == STATUS.CLOSED:
self.request.put(1)
status_open = CompareStatus(self.status, STATUS.OPEN, timeout=self.timeout_for_move)
status = status_open
return status
else:
return None
def close(self) -> DeviceStatus | None:
"""Close the Absorber"""
if self.status.get() == STATUS.OPEN:
self.request.put(1)
status_close = CompareStatus(self.status, STATUS.CLOSED, timeout=self.timeout_for_move)
status = status_close
return status
else:
return None
debye_bec/devices/cameras/basler_cam.py
+11 -1
View File
@@ -4,7 +4,7 @@ from __future__ import annotations
from typing import TYPE_CHECKING
from ophyd import ADBase
from ophyd import ADBase, EpicsSignalRO
from ophyd import ADComponent as ADCpt
from ophyd import Component as Cpt
from ophyd_devices import PreviewSignal
@@ -20,6 +20,16 @@ if TYPE_CHECKING: # pragma: no cover
class BaslerCamBase(ADBase):
"""BaslerCam Base class."""
cam_detector_state_string = Cpt(EpicsSignalRO, suffix="cam1:DetectorState_RBV", string=True)
_default_configuration_attrs = [
'cam1.acquire_time',
'cam1.detector_state',
'cam_detector_state_string',
'cam1.gain',
'cam1.model',
]
cam1 = ADCpt(AravisDetectorCam, "cam1:")
image1 = ADCpt(ImagePlugin_V35, "image1:")
debye_bec/devices/cameras/hutch_cam.py
+79
View File
@@ -0,0 +1,79 @@
"""EH Hutch Cameras"""
from __future__ import annotations
import cv2
import threading
from typing import TYPE_CHECKING
from bec_lib.logger import bec_logger
from bec_lib.file_utils import get_full_path
from ophyd_devices.interfaces.base_classes.psi_device_base import PSIDeviceBase
from ophyd_devices import DeviceStatus
if TYPE_CHECKING: # pragma: no cover
from bec_lib.devicemanager import ScanInfo
from bec_lib.messages import ScanStatusMessage
logger = bec_logger.logger
CAM_USERNAME = "camera_user"
CAM_PASSWORD = "camera_user1"
CAM_PORT = 554
class HutchCam(PSIDeviceBase):
"""Class for the Hutch Cameras"""
# image = Cpt(Signal, name='image', kind='config')
def __init__(self, *, name: str, prefix: str = "", scan_info: ScanInfo | None = None, **kwargs):
super().__init__(name=name, scan_info=scan_info, **kwargs)
self.hostname = prefix
self.status = None
# pylint: disable=E1101
def on_connected(self) -> None:
"""
Called after the device is connected and its signals are connected.
Default values for signals should be set here.
"""
rtsp_url = f"rtsp://{CAM_USERNAME}:{CAM_PASSWORD}@{self.hostname}.psi.ch:{CAM_PORT}/rtpstream/config1"
cap = cv2.VideoCapture(f"{rtsp_url}?tcp")
if not cap.isOpened():
logger.error(self, "Connection Failed", "Could not connect to the camera stream.")
return
cap.release()
def on_stage(self) -> DeviceStatus:
"""Called while staging the device."""
scan_msg: ScanStatusMessage = self.scan_info.msg
file_path = get_full_path(scan_msg, name='hutch_cam_' + self.hostname).removesuffix('h5')
self.status = DeviceStatus(self)
thread = threading.Thread(target=self._save_picture, args=(file_path, self.status), daemon=True)
thread.start()
return self.status
def _save_picture(self, file_path, status):
try:
logger.info(f'Capture from camera {self.hostname}')
rtsp_url = f"rtsp://{CAM_USERNAME}:{CAM_PASSWORD}@{self.hostname}.psi.ch:{CAM_PORT}/rtpstream/config1"
cap = cv2.VideoCapture(f"{rtsp_url}?tcp")
if not cap.isOpened():
logger.error("Connection Failed", "Could not connect to the camera stream.")
return
logger.info(f'Connection to camera {self.hostname} established')
ret, frame = cap.readAsync()
cap.release()
if not ret:
logger.error("Capture Failed", "Failed to capture image from camera.")
return
cv2.imwrite(file_path + 'png', frame)
status.set_finished()
logger.info(f'Capture from camera {self.hostname} done')
except Exception as e:
status.set_exception(e)
debye_bec/devices/cameras/prosilica_cam.py
+11 -1
View File
@@ -4,7 +4,7 @@ from __future__ import annotations
from typing import TYPE_CHECKING
from ophyd import ADBase
from ophyd import ADBase, EpicsSignalRO
from ophyd import ADComponent as ADCpt
from ophyd import Component as Cpt
from ophyd_devices import PreviewSignal
@@ -20,6 +20,16 @@ if TYPE_CHECKING: # pragma: no cover
class ProsilicaCamBase(ADBase):
"""Base class for Prosilica cameras."""
cam_detector_state_string = Cpt(EpicsSignalRO, suffix="cam1:DetectorState_RBV", string=True)
_default_configuration_attrs = [
'cam1.acquire_time',
'cam1.detector_state',
'cam_detector_state_string',
'cam1.gain',
'cam1.model',
]
cam1 = ADCpt(ProsilicaDetectorCam, "cam1:")
image1 = ADCpt(ImagePlugin_V35, "image1:")
debye_bec/devices/ionization_chambers/ionization_chamber.py
+115 -8
View File
@@ -33,22 +33,24 @@ class EpicsSignalSplit(EpicsSignal):
class GasMixSetupControl(Device):
"""GasMixSetup Control for Inonization Chamber 0"""
gas1_req = Cpt(EpicsSignalWithRBV, suffix="Gas1Req", kind="config", doc="Gas 1 requirement")
gas1_req = Cpt(EpicsSignalWithRBV, suffix="Gas1Req", kind="omitted", doc="Gas 1 requirement")
conc1_req = Cpt(
EpicsSignalWithRBV, suffix="Conc1Req", kind="config", doc="Concentration 1 requirement"
EpicsSignalWithRBV, suffix="Conc1Req", kind="omitted", doc="Concentration 1 requirement"
)
gas2_req = Cpt(EpicsSignalWithRBV, suffix="Gas2Req", kind="config", doc="Gas 2 requirement")
gas2_req = Cpt(EpicsSignalWithRBV, suffix="Gas2Req", kind="omitted", doc="Gas 2 requirement")
conc2_req = Cpt(
EpicsSignalWithRBV, suffix="Conc2Req", kind="config", doc="Concentration 2 requirement"
EpicsSignalWithRBV, suffix="Conc2Req", kind="omitted", doc="Concentration 2 requirement"
)
press_req = Cpt(
EpicsSignalWithRBV, suffix="PressReq", kind="config", doc="Pressure requirement"
EpicsSignalWithRBV, suffix="PressReq", kind="omitted", doc="Pressure requirement"
)
fill = Cpt(EpicsSignal, suffix="Fill", kind="config", doc="Fill the chamber")
status = Cpt(EpicsSignalRO, suffix="Status", kind="config", doc="Status")
gas1 = Cpt(EpicsSignalRO, suffix="Gas1", kind="config", doc="Gas 1")
gas1_string = Cpt(EpicsSignalRO, suffix="Gas1", kind="config", doc="Gas 1", string=True)
conc1 = Cpt(EpicsSignalRO, suffix="Conc1", kind="config", doc="Concentration 1")
gas2 = Cpt(EpicsSignalRO, suffix="Gas2", kind="config", doc="Gas 2")
gas2_string = Cpt(EpicsSignalRO, suffix="Gas2", kind="config", doc="Gas 2", string=True)
conc2 = Cpt(EpicsSignalRO, suffix="Conc2", kind="config", doc="Concentration 2")
press = Cpt(EpicsSignalRO, suffix="PressTransm", kind="config", doc="Current Pressure")
@@ -84,10 +86,25 @@ class IonizationChamber0(PSIDeviceBase):
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}"},
),
"cOnOff_string": (
EpicsSignal,
(f"ES:AMP5004.cOnOff{num}"),
{"kind": "config", "doc": f"Enable ch{num} -> IC{num-1}", "string": True},
),
"cGain_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cGain{num}_ENUM"),
{"kind": "config", "doc": f"Gain of ch{num} -> IC{num-1}", "string": True},
),
"cFilter_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}", "string": True},
),
}
amp = Dcpt(amp_signals)
gmes = Cpt(GasMixSetupControl, suffix=f"ES-GMES:IC{num-1}")
gmes_status = Cpt(EpicsSignalRO, suffix="ES-GMES:StatusMsg0", kind="config", doc="Status")
gmes_status_msg = Cpt(EpicsSignalRO, suffix="ES-GMES:StatusMsg0", kind="config", doc="Status")
hv = Cpt(HighVoltageSuppliesControl, suffix=f"ES1-IC{num-1}:")
hv_en_signals = {
"ext_ena": (
@@ -275,10 +292,25 @@ class IonizationChamber1(IonizationChamber0):
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}"},
),
"cOnOff_string": (
EpicsSignal,
(f"ES:AMP5004.cOnOff{num}"),
{"kind": "config", "doc": f"Enable ch{num} -> IC{num-1}", "string": True},
),
"cGain_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cGain{num}_ENUM"),
{"kind": "config", "doc": f"Gain of ch{num} -> IC{num-1}", "string": True},
),
"cFilter_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}", "string": True},
),
}
amp = Dcpt(amp_signals)
gmes = Cpt(GasMixSetupControl, suffix=f"ES-GMES:IC{num-1}")
gmes_status = Cpt(EpicsSignalRO, suffix="ES-GMES:StatusMsg0", kind="config", doc="Status")
gmes_status_msg = Cpt(EpicsSignalRO, suffix="ES-GMES:StatusMsg0", kind="config", doc="Status")
hv = Cpt(HighVoltageSuppliesControl, suffix=f"ES2-IC{num-1}:")
hv_en_signals = {
"ext_ena": (
@@ -311,10 +343,25 @@ class IonizationChamber2(IonizationChamber0):
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}"},
),
"cOnOff_string": (
EpicsSignal,
(f"ES:AMP5004.cOnOff{num}"),
{"kind": "config", "doc": f"Enable ch{num} -> IC{num-1}", "string": True},
),
"cGain_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cGain{num}_ENUM"),
{"kind": "config", "doc": f"Gain of ch{num} -> IC{num-1}", "string": True},
),
"cFilter_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}", "string": True},
),
}
amp = Dcpt(amp_signals)
gmes = Cpt(GasMixSetupControl, suffix=f"ES-GMES:IC{num-1}")
gmes_status = Cpt(EpicsSignalRO, suffix="ES-GMES:StatusMsg0", kind="config", doc="Status")
gmes_status_msg = Cpt(EpicsSignalRO, suffix="ES-GMES:StatusMsg0", kind="config", doc="Status")
hv = Cpt(HighVoltageSuppliesControl, suffix=f"ES2-IC{num-1}:")
hv_en_signals = {
"ext_ena": (
@@ -325,3 +372,63 @@ class IonizationChamber2(IonizationChamber0):
"ena": (EpicsSignal, "ES2-IC12:HV-Ena", {"kind": "config", "doc": "Enable signal of HV"}),
}
hv_en = Dcpt(hv_en_signals)
class Pips(IonizationChamber0):
"""Pips, prefix should be 'X01DA-'."""
USER_ACCESS = ["set_gain", "set_filter"]
num = 4
amp_signals = {
"cOnOff": (
EpicsSignal,
(f"ES:AMP5004.cOnOff{num}"),
{"kind": "config", "doc": f"Enable ch{num} -> IC{num-1}"},
),
"cGain_ENUM": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cGain{num}_ENUM"),
{"kind": "config", "doc": f"Gain of ch{num} -> IC{num-1}"},
),
"cFilter_ENUM": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}"},
),
"cOnOff_string": (
EpicsSignal,
(f"ES:AMP5004.cOnOff{num}"),
{"kind": "config", "doc": f"Enable ch{num} -> IC{num-1}", "string": True},
),
"cGain_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cGain{num}_ENUM"),
{"kind": "config", "doc": f"Gain of ch{num} -> IC{num-1}", "string": True},
),
"cFilter_ENUM_string": (
EpicsSignalWithRBV,
(f"ES:AMP5004:cFilter{num}_ENUM"),
{"kind": "config", "doc": f"Filter of ch{num} -> IC{num-1}", "string": True},
),
}
amp = Dcpt(amp_signals)
gmes = None
gmes_status_msg = None
hv = None
hv_en_signals = None
hv_en = None
@typechecked
def set_hv(self, *_) -> None:
"""Not available for the PIPS"""
return None
@typechecked
def set_grid(self, *_) -> None:
"""Not available for the PIPS"""
return None
@typechecked
def fill(self, *_) -> None:
"""Not available for the PIPS"""
return None
debye_bec/devices/mo1_bragg/mo1_bragg_devices.py
+29 -13
View File
@@ -76,8 +76,14 @@ class Mo1BraggEncoder(Device):
class Mo1BraggCrystal(Device):
"""Mo1 Bragg PVs to set the crystal parameters"""
offset_si111 = Cpt(EpicsSignalWithRBV, suffix="offset_si111", kind="config")
offset_si311 = Cpt(EpicsSignalWithRBV, suffix="offset_si311", kind="config")
bragg_off_si111 = Cpt(EpicsSignalWithRBV, suffix="bragg_off_si111", kind="config")
bragg_off_si311 = Cpt(EpicsSignalWithRBV, suffix="bragg_off_si311", kind="config")
phi_off_si111 = Cpt(EpicsSignalWithRBV, suffix="phi_off_si111", kind="config")
phi_off_si311 = Cpt(EpicsSignalWithRBV, suffix="phi_off_si311", kind="config")
azm_off_si111 = Cpt(EpicsSignalWithRBV, suffix="azm_off_si111", kind="config")
azm_off_si311 = Cpt(EpicsSignalWithRBV, suffix="azm_off_si311", kind="config")
miscut_si111 = Cpt(EpicsSignalWithRBV, suffix="miscut_si111", kind="config")
miscut_si311 = Cpt(EpicsSignalWithRBV, suffix="miscut_si311", kind="config")
xtal_enum = Cpt(EpicsSignalWithRBV, suffix="xtal_ENUM", kind="config")
d_spacing_si111 = Cpt(EpicsSignalWithRBV, suffix="d_spacing_si111", kind="config")
d_spacing_si311 = Cpt(EpicsSignalWithRBV, suffix="d_spacing_si311", kind="config")
@@ -85,13 +91,21 @@ class Mo1BraggCrystal(Device):
current_d_spacing = Cpt(
EpicsSignalRO, suffix="current_d_spacing_RBV", kind="normal", auto_monitor=True
)
current_offset = Cpt(
EpicsSignalRO, suffix="current_offset_RBV", kind="normal", auto_monitor=True
current_bragg_off = Cpt(
EpicsSignalRO, suffix="current_bragg_off_RBV", kind="normal", auto_monitor=True
)
current_phi_off = Cpt(
EpicsSignalRO, suffix="current_phi_off_RBV", kind="normal", auto_monitor=True
)
current_azm_off = Cpt(
EpicsSignalRO, suffix="current_azm_off_RBV", kind="normal", auto_monitor=True
)
current_miscut = Cpt(
EpicsSignalRO, suffix="current_miscut_RBV", kind="normal", auto_monitor=True
)
current_xtal = Cpt(
EpicsSignalRO, suffix="current_xtal_ENUM_RBV", kind="normal", auto_monitor=True
)
current_xtal_string = Cpt(
EpicsSignalRO, suffix="current_xtal_ENUM_RBV", kind="normal", auto_monitor=True, string=True
)
@@ -240,6 +254,8 @@ class Mo1BraggPositioner(Device, PositionerBase):
high_lim = Cpt(EpicsSignalRO, suffix="hi_lim_pos_energy_RBV", kind="config", auto_monitor=True)
velocity = Cpt(EpicsSignalWithRBV, suffix="move_velocity", kind="config", auto_monitor=True)
angle = Cpt(EpicsSignalRO, suffix="feedback_pos_angle_RBV", kind="normal", auto_monitor=True)
########## Move Command PVs ##########
move_abs = Cpt(EpicsSignal, suffix="move_abs", kind="config", put_complete=True)
@@ -392,8 +408,8 @@ class Mo1BraggPositioner(Device, PositionerBase):
def set_xtal(
self,
xtal_enum: Literal["111", "311"],
offset_si111: float = None,
offset_si311: float = None,
bragg_off_si111: float = None,
bragg_off_si311: float = None,
d_spacing_si111: float = None,
d_spacing_si311: float = None,
) -> None:
@@ -401,15 +417,15 @@ class Mo1BraggPositioner(Device, PositionerBase):
Args:
xtal_enum (Literal["111", "311"]) : Enum to set the crystal orientation
offset_si111 (float) : Offset for the 111 crystal
offset_si311 (float) : Offset for the 311 crystal
bragg_off_si111 (float) : Offset for the 111 crystal
bragg_off_si311 (float) : Offset for the 311 crystal
d_spacing_si111 (float) : d-spacing for the 111 crystal
d_spacing_si311 (float) : d-spacing for the 311 crystal
"""
if offset_si111 is not None:
self.crystal.offset_si111.put(offset_si111)
if offset_si311 is not None:
self.crystal.offset_si311.put(offset_si311)
if bragg_off_si111 is not None:
self.crystal.bragg_off_si111.put(bragg_off_si111)
if bragg_off_si311 is not None:
self.crystal.bragg_off_si311.put(bragg_off_si311)
if d_spacing_si111 is not None:
self.crystal.d_spacing_si111.put(d_spacing_si111)
if d_spacing_si311 is not None:
debye_bec/devices/nidaq/nidaq.py
+244 -69
View File
@@ -33,6 +33,107 @@ class NidaqControl(Device):
"""Nidaq control class with all PVs"""
### Readback PVs for EpicsEmitter ###
energy = Cpt(SetableSignal, value=0, kind=Kind.normal)
smpl_abs = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream sample absorption"
)
smpl_fluo = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream sample fluorescence"
)
ref_abs = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream reference absorption"
)
cisum = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter sum"
)
ai0_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 0, MEAN"
)
ai1_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 1, MEAN"
)
ai2_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 2, MEAN"
)
ai3_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 3, MEAN"
)
ai4_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 4, MEAN"
)
ai5_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 5, MEAN"
)
ai6_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 6, MEAN"
)
ai7_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 7, MEAN"
)
di0_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 0, MAX")
di1_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 1, MAX")
di2_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 2, MAX")
di3_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 3, MAX")
di4_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 4, MAX")
ci0_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 0, MEAN"
)
ci1_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 1, MEAN"
)
ci2_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 2, MEAN"
)
ci3_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 3, MEAN"
)
ci4_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 4, MEAN"
)
ci5_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 5, MEAN"
)
ci6_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 6, MEAN"
)
ci7_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 7, MEAN"
)
ci8_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 8, MEAN"
)
ci9_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 9, MEAN"
)
ci10_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 10, MEAN"
)
ci11_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 11, MEAN"
)
ci12_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 12, MEAN"
)
ci13_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 13, MEAN"
)
ci14_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 14, MEAN"
)
ci15_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 15, MEAN"
)
ci16_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 16, MEAN"
)
ci17_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 17, MEAN"
)
ai0 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-AI0",
@@ -146,6 +247,76 @@ class NidaqControl(Device):
doc="EPICS counter input 7",
auto_monitor=True,
)
ci8 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI8",
kind=Kind.normal,
doc="EPICS counter input 8",
auto_monitor=True,
)
ci9 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI9",
kind=Kind.normal,
doc="EPICS counter input 9",
auto_monitor=True,
)
ci10 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI10",
kind=Kind.normal,
doc="EPICS counter input 0",
auto_monitor=True,
)
ci11 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI11",
kind=Kind.normal,
doc="EPICS counter input 1",
auto_monitor=True,
)
ci12 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI12",
kind=Kind.normal,
doc="EPICS counter input 2",
auto_monitor=True,
)
ci13 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI13",
kind=Kind.normal,
doc="EPICS counter input 3",
auto_monitor=True,
)
ci14 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI14",
kind=Kind.normal,
doc="EPICS counter input 4",
auto_monitor=True,
)
ci15 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI15",
kind=Kind.normal,
doc="EPICS counter input 5",
auto_monitor=True,
)
ci16 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI16",
kind=Kind.normal,
doc="EPICS counter input 6",
auto_monitor=True,
)
ci17 = Cpt(
EpicsSignalRO,
suffix="NIDAQ-CI17",
kind=Kind.normal,
doc="EPICS counter input 7",
auto_monitor=True,
)
di0 = Cpt(
EpicsSignalRO,
@@ -200,32 +371,6 @@ class NidaqControl(Device):
)
### Readback for BEC emitter ###
ai0_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 0, MEAN"
)
ai1_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 1, MEAN"
)
ai2_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 2, MEAN"
)
ai3_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 3, MEAN"
)
ai4_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 4, MEAN"
)
ai5_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 5, MEAN"
)
ai6_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 6, MEAN"
)
ai7_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 7, MEAN"
)
ai0_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 0, STD"
)
@@ -251,31 +396,6 @@ class NidaqControl(Device):
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream analog input 7, STD"
)
ci0_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 0, MEAN"
)
ci1_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 1, MEAN"
)
ci2_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 2, MEAN"
)
ci3_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 3, MEAN"
)
ci4_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 4, MEAN"
)
ci5_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 5, MEAN"
)
ci6_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 6, MEAN"
)
ci7_mean = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 7, MEAN"
)
ci0_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 0. STD"
)
@@ -300,44 +420,95 @@ class NidaqControl(Device):
ci7_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 7. STD"
)
ci8_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 8. STD"
)
ci9_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 9. STD"
)
ci10_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 10. STD"
)
ci11_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 11. STD"
)
ci12_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 12. STD"
)
ci13_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 13. STD"
)
ci14_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 14. STD"
)
ci15_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 15. STD"
)
ci16_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 16. STD"
)
ci17_std_dev = Cpt(
SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream counter input 17. STD"
)
xas_timestamp = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream XAS timestamp")
xrd_timestamp = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream XRD timestamp")
xrd_angle = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream XRD angle")
xrd_energy = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream XRD energy")
di0_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 0, MAX")
di1_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 1, MAX")
di2_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 2, MAX")
di3_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 3, MAX")
di4_max = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream digital input 4, MAX")
xrd_ai0_mean = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream XRD ai0 mean")
xrd_ai0_std_dev = Cpt(SetableSignal, value=0, kind=Kind.normal, doc="NIDAQ stream XRD ai0 std dev")
enc = Cpt(SetableSignal, value=0, kind=Kind.normal)
energy = Cpt(SetableSignal, value=0, kind=Kind.normal)
rle = Cpt(SetableSignal, value=0, kind=Kind.normal)
### Control PVs ###
enable_compression = Cpt(EpicsSignal, suffix="NIDAQ-EnableRLE", kind=Kind.config)
enable_compression = Cpt(EpicsSignal, suffix="NIDAQ-EnableRLE", kind=Kind.config, auto_monitor=True)
enable_dead_time_correction = Cpt(EpicsSignal, suffix="NIDAQ-EnableDTC", kind=Kind.config, auto_monitor=True)
kickoff_call = Cpt(EpicsSignal, suffix="NIDAQ-Kickoff", kind=Kind.config)
stage_call = Cpt(EpicsSignal, suffix="NIDAQ-Stage", kind=Kind.config)
state = Cpt(EpicsSignal, suffix="NIDAQ-FSMState", kind=Kind.config, auto_monitor=True)
server_status = Cpt(EpicsSignalRO, suffix="NIDAQ-ServerStatus", kind=Kind.config)
compression_ratio = Cpt(EpicsSignalRO, suffix="NIDAQ-CompressionRatio", kind=Kind.config)
scan_type = Cpt(EpicsSignal, suffix="NIDAQ-ScanType", kind=Kind.config)
sampling_rate = Cpt(EpicsSignal, suffix="NIDAQ-SamplingRateRequested", kind=Kind.config)
scan_type_string = Cpt(EpicsSignal, suffix="NIDAQ-ScanType", kind=Kind.config, string=True)
sampling_rate = Cpt(EpicsSignal, suffix="NIDAQ-SamplingRateRequested", kind=Kind.config, auto_monitor=True)
sampling_rate_string = Cpt(EpicsSignal, suffix="NIDAQ-SamplingRateRequested", kind=Kind.config, string=True, auto_monitor=True)
scan_duration = Cpt(EpicsSignal, suffix="NIDAQ-SamplingDuration", kind=Kind.config)
readout_range = Cpt(EpicsSignal, suffix="NIDAQ-ReadoutRange", kind=Kind.config)
encoder_factor = Cpt(EpicsSignal, suffix="NIDAQ-EncoderFactor", kind=Kind.config)
readout_range = Cpt(EpicsSignal, suffix="NIDAQ-ReadoutRange", kind=Kind.config, auto_monitor=True)
readout_range_string = Cpt(EpicsSignal, suffix="NIDAQ-ReadoutRange", kind=Kind.config, string=True, auto_monitor=True)
encoder_factor = Cpt(EpicsSignal, suffix="NIDAQ-EncoderFactor", kind=Kind.config, auto_monitor=True)
encoder_factor_string = Cpt(EpicsSignal, suffix="NIDAQ-EncoderFactor", kind=Kind.config, string=True, auto_monitor=True)
stop_call = Cpt(EpicsSignal, suffix="NIDAQ-Stop", kind=Kind.config)
power = Cpt(EpicsSignal, suffix="NIDAQ-Power", kind=Kind.config)
heartbeat = Cpt(EpicsSignal, suffix="NIDAQ-Heartbeat", kind=Kind.config, auto_monitor=True)
time_left = Cpt(EpicsSignalRO, suffix="NIDAQ-TimeLeft", kind=Kind.config, auto_monitor=True)
ai_chans = Cpt(EpicsSignal, suffix="NIDAQ-AIChans", kind=Kind.config)
ci_chans = Cpt(EpicsSignal, suffix="NIDAQ-CIChans", kind=Kind.config)
di_chans = Cpt(EpicsSignal, suffix="NIDAQ-DIChans", kind=Kind.config)
ai_chans = Cpt(EpicsSignal, suffix="NIDAQ-AIChans", kind=Kind.config, auto_monitor=True)
ci_chans = Cpt(EpicsSignal, suffix="NIDAQ-CIChans", kind=Kind.config, auto_monitor=True)
di_chans = Cpt(EpicsSignal, suffix="NIDAQ-DIChans", kind=Kind.config, auto_monitor=True)
add_chans = Cpt(EpicsSignal, suffix="NIDAQ-AddChans", kind=Kind.config, auto_monitor=True)
smpl_abs_ln = Cpt(EpicsSignal, suffix="NIDAQ-smpl_abs_ln", kind=Kind.config, auto_monitor=True)
ref_abs_ln = Cpt(EpicsSignal, suffix="NIDAQ-ref_abs_ln", kind=Kind.config, auto_monitor=True)
smpl_abs_no = Cpt(EpicsSignal, suffix="NIDAQ-smpl_abs_no", kind=Kind.config, auto_monitor=True)
smpl_abs_no_string = Cpt(EpicsSignal, suffix="NIDAQ-smpl_abs_no", kind=Kind.config, string=True, auto_monitor=True)
smpl_abs_de = Cpt(EpicsSignal, suffix="NIDAQ-smpl_abs_de", kind=Kind.config, auto_monitor=True)
smpl_abs_de_string = Cpt(EpicsSignal, suffix="NIDAQ-smpl_abs_de", kind=Kind.config, string=True, auto_monitor=True)
smpl_fluo_no = Cpt(EpicsSignal, suffix="NIDAQ-smpl_fluo_no", kind=Kind.config, auto_monitor=True)
smpl_fluo_no_string = Cpt(EpicsSignal, suffix="NIDAQ-smpl_fluo_no", kind=Kind.config, string=True, auto_monitor=True)
smpl_fluo_de = Cpt(EpicsSignal, suffix="NIDAQ-smpl_fluo_de", kind=Kind.config, auto_monitor=True)
smpl_fluo_de_string = Cpt(EpicsSignal, suffix="NIDAQ-smpl_fluo_de", kind=Kind.config, string=True, auto_monitor=True)
ref_abs_no = Cpt(EpicsSignal, suffix="NIDAQ-ref_abs_no", kind=Kind.config, auto_monitor=True)
ref_abs_no_string = Cpt(EpicsSignal, suffix="NIDAQ-ref_abs_no", kind=Kind.config, string=True, auto_monitor=True)
ref_abs_de = Cpt(EpicsSignal, suffix="NIDAQ-ref_abs_de", kind=Kind.config, auto_monitor=True)
ref_abs_de_string = Cpt(EpicsSignal, suffix="NIDAQ-ref_abs_de", kind=Kind.config, string=True, auto_monitor=True)
class Nidaq(PSIDeviceBase, NidaqControl):
@@ -357,7 +528,7 @@ class Nidaq(PSIDeviceBase, NidaqControl):
super().__init__(name=name, prefix=prefix, scan_info=scan_info, **kwargs)
self.scan_info: ScanInfo
self.timeout_wait_for_signal = 5 # put 5s firsts
self._timeout_wait_for_pv = 3 # 3s timeout for pv calls
self._timeout_wait_for_pv = 5 # 5s timeout for pv calls. editted due to timeout issues persisting
self.valid_scan_names = [
"xas_simple_scan",
"xas_simple_scan_with_xrd",
@@ -556,7 +727,11 @@ class Nidaq(PSIDeviceBase, NidaqControl):
# Stage call to IOC
status = CompareStatus(self.state, NidaqState.STAGE)
self.cancel_on_stop(status)
self.stage_call.set(1).wait(timeout=self._timeout_wait_for_pv)
# TODO 11.11.25/HS64
# Switched from set to put in the hope to get rid of the rare event where nidaq is stopped at the start of a scan
# Problems consistently persisting, testing changing back to set, unconvinced this is the actual cause 14.11.25/AHC
# self.stage_call.set(1).wait(timeout=self._timeout_wait_for_pv)
self.stage_call.put(1)
status.wait(timeout=self.timeout_wait_for_signal)
if self.scan_info.msg.scan_name != "nidaq_continuous_scan":
status = self.on_kickoff()
debye_bec/devices/pilatus/pilatus.py
+63 -70
View File
@@ -6,13 +6,13 @@ import enum
import threading
import time
import traceback
from typing import TYPE_CHECKING
from typing import TYPE_CHECKING, Tuple
import numpy as np
from bec_lib.file_utils import get_full_path
from bec_lib.logger import bec_logger
from ophyd import Component as Cpt
from ophyd import EpicsSignal, Kind
from ophyd import EpicsSignal, EpicsSignalRO, Kind
from ophyd.areadetector.cam import ADBase, PilatusDetectorCam
from ophyd.areadetector.plugins import HDF5Plugin_V22 as HDF5Plugin
from ophyd.areadetector.plugins import ImagePlugin_V22 as ImagePlugin
@@ -145,6 +145,19 @@ class Pilatus(PSIDeviceBase, ADBase):
# USER_ACCESS = ["start_live_mode", "stop_live_mode"]
cam_gain_menu_string = Cpt(EpicsSignalRO, suffix='cam1:GainMenu', string=True)
_default_configuration_attrs = [
'cam.threshold_energy',
'cam.threshold_auto_apply',
'cam.gain_menu',
'cam_gain_menu_string',
'cam.pixel_cut_off',
'cam.acquire_time',
'cam.num_exposures',
'cam.model',
]
cam = Cpt(PilatusDetectorCam, "cam1:")
hdf = Cpt(HDF5Plugin, "HDF1:")
image1 = Cpt(ImagePlugin, "image1:")
@@ -203,22 +216,11 @@ class Pilatus(PSIDeviceBase, ADBase):
PreviewSignal,
name="preview",
ndim=2,
num_rotation_90=0, # Check this
num_rotation_90=3,
doc="Preview signal for the Pilatus Detector",
)
file_event = Cpt(FileEventSignal, name="file_event")
@property
def baseline_signals(self):
"""Define baseline signals"""
return [
self.cam.acquire_time,
self.cam.num_exposures,
self.cam.threshold_energy,
self.cam.gain_menu,
self.cam.pixel_cut_off,
]
def __init__(
self,
*,
@@ -366,68 +368,51 @@ class Pilatus(PSIDeviceBase, ADBase):
status = status_acquire & status_writing & status_cam_server
return status
def _calculate_trigger(self, scan_msg: ScanStatusMessage):
def _calculate_trigger(self, scan_msg: ScanStatusMessage) -> Tuple[float, float]:
self._update_scan_parameter()
total_osc = 0
calc_duration = 0
total_trig_lo = 0
total_trig_hi = 0
calc_duration = 0
n_trig_lo = 1
n_trig_hi = 1
init_lo = 1
init_hi = 1
lo_done = 0
hi_done = 0
if not self.scan_parameter.break_enable_low:
lo_done = 1
if not self.scan_parameter.break_enable_high:
hi_done = 1
start_time = time.time()
while True:
# TODO, we should not use infinite loops, for now let's add the escape Timeout of 20s, but should eventually be reviewed.
if time.time() - start_time > 20:
raise RuntimeError(
f"Calculating the number of triggers for scan {scan_msg.scan_name} took more than 20 seconds, aborting."
)
# Switching high/low is intended as angle is inverse to energy and settings in BEC are always in energy
loc_break_enable_low = self.scan_parameter.break_enable_high
loc_break_time_low = self.scan_parameter.break_time_high
loc_cycle_low = self.scan_parameter.cycle_high
loc_break_enable_high = self.scan_parameter.break_enable_low
loc_break_time_high = self.scan_parameter.break_time_low
loc_cycle_high = self.scan_parameter.cycle_low
if not loc_break_enable_low:
loc_break_time_low = 0
loc_cycle_low = 1
if not loc_break_enable_high:
loc_break_time_high = 0
loc_cycle_high = 1
total_osc = self.scan_parameter.scan_duration / (
self.scan_parameter.scan_time +
loc_break_time_low / (2 * loc_cycle_low) +
loc_break_time_high / (2 * loc_cycle_high)
)
total_osc = np.ceil(total_osc)
total_osc = total_osc + total_osc % 2 # round up to the next even number
if loc_break_enable_low:
total_trig_lo = np.floor(total_osc / (2 * loc_cycle_low))
if loc_break_enable_high:
total_trig_hi = np.floor(total_osc / (2 * loc_cycle_high))
calc_duration = total_osc * self.scan_parameter.scan_time + total_trig_lo * loc_break_time_low + total_trig_hi * loc_break_time_high
if calc_duration < self.scan_parameter.scan_duration:
# Due to inaccuracy in formula, this can happen, we then need to manually add two oscillations and recalculate the triggers
total_osc = total_osc + 2
calc_duration = calc_duration + 2 * self.scan_parameter.scan_time
if loc_break_enable_low:
total_trig_lo = np.floor(total_osc / (2 * loc_cycle_low))
if loc_break_enable_high:
total_trig_hi = np.floor(total_osc / (2 * loc_cycle_high))
calc_duration = total_osc * self.scan_parameter.scan_time + total_trig_lo * loc_break_time_low + total_trig_hi * loc_break_time_high
if self.scan_parameter.break_enable_low and n_trig_lo >= self.scan_parameter.cycle_low:
n_trig_lo = 1
calc_duration = calc_duration + self.scan_parameter.break_time_low
if init_lo:
lo_done = 1
init_lo = 0
else:
n_trig_lo += 1
if (
self.scan_parameter.break_enable_high
and n_trig_hi >= self.scan_parameter.cycle_high
):
n_trig_hi = 1
calc_duration = calc_duration + self.scan_parameter.break_time_high
if init_hi:
hi_done = 1
init_hi = 0
else:
n_trig_hi += 1
if lo_done and hi_done:
n = np.floor(self.scan_parameter.scan_duration / calc_duration)
total_osc = total_osc * n
if self.scan_parameter.break_enable_low:
total_trig_lo = n + 1
if self.scan_parameter.break_enable_high:
total_trig_hi = n + 1
calc_duration = calc_duration * n
lo_done = 0
hi_done = 0
if calc_duration >= self.scan_parameter.scan_duration:
break
return total_trig_lo + total_trig_hi
return total_trig_lo, total_trig_hi
########################################
# Beamline Specific Implementations #
@@ -480,6 +465,14 @@ class Pilatus(PSIDeviceBase, ADBase):
"""
# self.stop_live_mode() # Make sure that live mode is stopped if scan runs
# If user has activated alignment mode on qt panel, switch back to multitrigger and stop acquisition
if self.cam.trigger_mode.get() != TRIGGERMODE.MULT_TRIGGER.value:
self.cam.trigger_mode.set(TRIGGERMODE.MULT_TRIGGER.value).wait(5)
if self.cam.acquire.get() == ACQUIREMODE.ACQUIRING.value:
self.cam.acquire.put(0)
status_cam = CompareStatus(self.cam.acquire, ACQUIREMODE.DONE.value)
status_cam.wait(timeout=5)
scan_msg: ScanStatusMessage = self.scan_info.msg
if scan_msg.scan_name in self.xas_xrd_scan_names:
self._update_scan_parameter()
debye_bec/devices/pilatus_curtain.py
+2 -2
View File
@@ -69,11 +69,11 @@ class PilatusCurtain(PSIDeviceBase):
def on_unstage(self) -> DeviceStatus | None:
"""Called while unstaging the device."""
return self.close()
# return self.close()
def on_stop(self) -> DeviceStatus | None:
"""Called when the device is stopped."""
return self.close()
# return self.close()
def open(self) -> DeviceStatus | None:
"""Open the cover"""
debye_bec/devices/reffoilchanger.py
+6
View File
@@ -52,9 +52,15 @@ class Reffoilchanger(PSIDeviceBase):
status = Cpt(
EpicsSignal, suffix="ES2-REF:SELN-FilterState-ENUM_RBV", kind="config", doc="Status"
)
status_string = Cpt(
EpicsSignal, suffix="ES2-REF:SELN-FilterState-ENUM_RBV", kind="config", doc="Status", string=True
)
op_mode = Cpt(
EpicsSignalWithRBV, suffix="ES2-REF:SELN-OpMode-ENUM", kind="config", doc="Status"
)
op_mode_string = Cpt(
EpicsSignalWithRBV, suffix="ES2-REF:SELN-OpMode-ENUM", kind="config", doc="Status", string=True
)
ref_set = Cpt(EpicsSignal, suffix="ES2-REF:SELN-SET", kind="config", doc="Requested reference")
ref_rb = Cpt(
EpicsSignalRO, suffix="ES2-REF:SELN-RB", kind="config", doc="Currently set reference"
debye_bec/file_writer/debye_nexus_structure.py
+324 -96
View File
@@ -1,5 +1,6 @@
from bec_server.file_writer.default_writer import DefaultFormat
import debye_bec.bec_widgets.widgets.x01da_parameters as bl
class DebyeNexusStructure(DefaultFormat):
"""Nexus Structure for Debye"""
@@ -12,102 +13,6 @@ class DebyeNexusStructure(DefaultFormat):
instrument = entry.create_group(name="instrument")
instrument.attrs["NX_class"] = "NXinstrument"
###################
## mo1_bragg specific information
###################
# Logic if device exist
if "mo1_bragg" in self.device_manager.devices:
monochromator = instrument.create_group(name="monochromator")
monochromator.attrs["NX_class"] = "NXmonochromator"
crystal = monochromator.create_group(name="crystal")
crystal.attrs["NX_class"] = "NXcrystal"
# Create a dataset
chemical_formular = crystal.create_dataset(name="chemical_formular", data="Si")
chemical_formular.attrs["NX_class"] = "NX_CHAR"
# Create a softlink
d_spacing = crystal.create_soft_link(
name="d_spacing",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_d_spacing/value",
)
d_spacing.attrs["NX_class"] = "NX_FLOAT"
offset = crystal.create_soft_link(
name="offset",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_offset/value",
)
offset.attrs["NX_class"] = "NX_FLOAT"
reflection = crystal.create_soft_link(
name="reflection",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_xtal_string/value",
)
reflection.attrs["NX_class"] = "NX_CHAR"
##################
## cm mirror specific information
###################
collimating_mirror = instrument.create_group(name="collimating_mirror")
collimating_mirror.attrs["NX_class"] = "NXmirror"
cm_substrate_material = collimating_mirror.create_dataset(
name="substrate_material", data="Si"
)
cm_substrate_material.attrs["NX_class"] = "NX_CHAR"
cm_bending_radius = collimating_mirror.create_soft_link(
name="sagittal radius",
target="/entry/collection/devices/cm_bnd_radius/cm_bnd_radius/value",
)
cm_bending_radius.attrs["NX_class"] = "NX_FLOAT"
cm_bending_radius.attrs["units"] = "km"
cm_incidence_angle = collimating_mirror.create_soft_link(
name="incidence angle", target="/entry/collection/devices/cm_rotx/cm_rotx/value"
)
cm_incidence_angle.attrs["NX_class"] = "NX_FLOAT"
cm_yaw_angle = collimating_mirror.create_soft_link(
name="incident angle", target="/entry/collection/devices/cm_roty/cm_roty/value"
)
cm_yaw_angle.attrs["NX_class"] = "NX_FLOAT"
##################
## fm mirror specific information
###################
focusing_mirror = instrument.create_group(name="focusing_mirror")
focusing_mirror.attrs["NX_class"] = "NXmirror"
fm_substrate_material = focusing_mirror.create_dataset(name="substrate_material", data="Si")
fm_substrate_material.attrs["NX_class"] = "NX_CHAR"
fm_bending_radius = focusing_mirror.create_soft_link(
name="sagittal radius",
target="/entry/collection/devices/fm_bnd_radius/fm_bnd_radius/value",
)
fm_bending_radius.attrs["NX_class"] = "NX_FLOAT"
fm_incidence_angle = focusing_mirror.create_soft_link(
name="incidence angle",
target="/entry/collection/devices/fm_incidence_angle/fm_incidence_angle/value",
)
fm_incidence_angle.attrs["NX_class"] = "NX_FLOAT"
fm_yaw_angle = focusing_mirror.create_soft_link(
name="yaw angle", target="/entry/collection/devices/fm_roty/fm_roty/value"
)
fm_yaw_angle.attrs["NX_class"] = "NX_FLOAT"
fm_roll_angle = focusing_mirror.create_soft_link(
name="roll angle", target="/entry/collection/devices/fm_rotz/fm_rotz/value"
)
fm_roll_angle.attrs["NX_class"] = "NX_FLOAT"
##################
## source specific information
###################
@@ -123,3 +28,326 @@ class DebyeNexusStructure(DefaultFormat):
probe = source.create_dataset(name="probe", data="X-ray")
probe.attrs["NX_class"] = "NX_CHAR"
if "curr" in self.device_manager.devices:
ring_current = source.create_soft_link(
name="ring_current",
target="/entry/collection/devices/curr/curr/value",
)
ring_current.attrs["NX_class"] = "NX_FLOAT"
ring_current.attrs["units"] = "mA"
###################
## mo1_bragg specific information
###################
## Logic if device exist
if "mo1_bragg" in self.device_manager.devices:
monochromator = instrument.create_group(name="monochromator")
monochromator.attrs["NX_class"] = "NXmonochromator"
crystal = monochromator.create_group(name="crystal")
crystal.attrs["NX_class"] = "NXcrystal"
# Create a dataset
chemical_formular = crystal.create_dataset(name="chemical_formular", data="Si")
chemical_formular.attrs["NX_class"] = "NX_CHAR"
reflection = crystal.create_soft_link(
name="reflection",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_xtal_string/value",
)
reflection.attrs["NX_class"] = "NX_CHAR"
# Create a softlink
d_spacing = crystal.create_soft_link(
name="d_spacing",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_d_spacing/value",
)
d_spacing.attrs["NX_class"] = "NX_FLOAT"
d_spacing.attrs["units"] = "angstrom"
bragg_offset = crystal.create_soft_link(
name="bragg_offset",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_bragg_off/value",
)
bragg_offset.attrs["NX_class"] = "NX_FLOAT"
bragg_offset.attrs["units"] = "degree"
phi_offset = crystal.create_soft_link(
name="phi_offset",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_phi_off/value",
)
phi_offset.attrs["NX_class"] = "NX_FLOAT"
phi_offset.attrs["units"] = "degree"
## Logic if device exist
if "mo1_roty" in self.device_manager.devices:
# Create a softlink
azimuthal_angle = crystal.create_soft_link(
name="azimuthal_angle",
target="/entry/collection/devices/mo1_roty/mo1_roty/value",
)
azimuthal_angle.attrs["NX_class"] = "NX_FLOAT"
azimuthal_angle.attrs["units"] = "degree"
azm_offset = crystal.create_soft_link(
name="azm_offset",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_azm_off/value",
)
azm_offset.attrs["NX_class"] = "NX_FLOAT"
azm_offset.attrs["units"] = "degree"
miscut = crystal.create_soft_link(
name="miscut",
target="/entry/collection/devices/mo1_bragg/mo1_bragg_crystal_current_miscut/value",
)
miscut.attrs["NX_class"] = "NX_FLOAT"
miscut.attrs["units"] = "degree"
###################
### cm mirror specific information
####################
collimating_mirror = instrument.create_group(name="collimating_mirror")
collimating_mirror.attrs["NX_class"] = "NXmirror"
cm_substrate_material = collimating_mirror.create_dataset(
name="substrate_material", data="Si"
)
cm_substrate_material.attrs["NX_class"] = "NX_CHAR"
#previous error due to space in name field
if "cm_bnd_radius" in self.device_manager.devices:
cm_bending_radius = collimating_mirror.create_soft_link(
name="sagittal_radius",
target="/entry/collection/devices/cm_bnd_radius/cm_bnd_radius/value",
)
cm_bending_radius.attrs["NX_class"] = "NX_FLOAT"
cm_bending_radius.attrs["units"] = "km"
if "cm_rotx" in self.device_manager.devices:
cm_incidence_angle = collimating_mirror.create_soft_link(
name="incidence_angle", target="/entry/collection/devices/cm_rotx/cm_rotx/value"
)
cm_incidence_angle.attrs["NX_class"] = "NX_FLOAT"
cm_incidence_angle.attrs["units"] = "mrad"
if "cm_roty" in self.device_manager.devices:
cm_yaw_angle = collimating_mirror.create_soft_link(
name="yaw_angle", target="/entry/collection/devices/cm_roty/cm_roty/value"
)
cm_yaw_angle.attrs["NX_class"] = "NX_FLOAT"
cm_yaw_angle.attrs["units"] = "mrad"
if "cm_rotz" in self.device_manager.devices:
cm_roll_angle = collimating_mirror.create_soft_link(
name="roll_angle", target="/entry/collection/devices/cm_rotz/cm_rotz/value"
)
cm_roll_angle.attrs["NX_class"] = "NX_FLOAT"
cm_roll_angle.attrs["units"] = "mrad"
if 'cm_trx' in self.device_manager.devices:
cm_trx = - self.device_manager.devices.cm_trx.read(cached=True).get('cm_trx').get('value')
stripe = 'Unknown'
for name, low, high in zip(bl.cm.surface, bl.cm.limOptX[0], bl.cm.limOptX[1]):
if low <= cm_trx <= high:
stripe = name
cm_stripe = collimating_mirror.create_dataset(
name="stripe", data=stripe
)
cm_stripe.attrs["NX_class"] = "NX_CHAR"
###################
### fm mirror specific information
####################
focusing_mirror = instrument.create_group(name="focusing_mirror")
focusing_mirror.attrs["NX_class"] = "NXmirror"
fm_substrate_material = focusing_mirror.create_dataset(
name="substrate_material", data="Si"
)
fm_substrate_material.attrs["NX_class"] = "NX_CHAR"
if "fm_bnd_radius" in self.device_manager.devices:
fm_bending_radius = focusing_mirror.create_soft_link(
name="sagittal_radius",
target="/entry/collection/devices/fm_bnd_radius/fm_bnd_radius/value",
)
fm_bending_radius.attrs["NX_class"] = "NX_FLOAT"
fm_bending_radius.attrs["units"] = "km"
if "fm_rotx" in self.device_manager.devices:
fm_incidence_angle = focusing_mirror.create_soft_link(
name="incidence_angle", target="/entry/collection/devices/fm_rotx/fm_rotx/value"
)
fm_incidence_angle.attrs["NX_class"] = "NX_FLOAT"
fm_incidence_angle.attrs["units"] = "mrad"
if "fm_roty" in self.device_manager.devices:
fm_yaw_angle = focusing_mirror.create_soft_link(
name="yaw_angle", target="/entry/collection/devices/fm_roty/fm_roty/value"
)
fm_yaw_angle.attrs["NX_class"] = "NX_FLOAT"
fm_yaw_angle.attrs["units"] = "mrad"
if "fm_rotz" in self.device_manager.devices:
fm_roll_angle = focusing_mirror.create_soft_link(
name="roll_angle", target="/entry/collection/devices/fm_rotz/fm_rotz/value"
)
fm_roll_angle.attrs["NX_class"] = "NX_FLOAT"
fm_roll_angle.attrs["units"] = "mrad"
if 'fm_trx' in self.device_manager.devices:
fm_trx = - self.device_manager.devices.fm_trx.read(cached=True).get('fm_trx').get('value')
stripe = 'Unknown'
for name, low, high in zip(bl.fm.surfaceFlat, bl.fm.limOptXFlat[1], bl.fm.limOptXFlat[0]):
if low <= fm_trx <= high:
stripe = name + ' (flat)'
for name, low, high in zip(bl.fm.surfaceToroid, bl.fm.limOptXToroid[1], bl.fm.limOptXToroid[0]):
if low <= fm_trx <= high:
stripe = name + ' (toroid)'
fm_stripe = focusing_mirror.create_dataset(
name="stripe", data=stripe
)
fm_stripe.attrs["NX_class"] = "NX_CHAR"
###################
## nidaq specific information
###################
## Logic if device exist
if "nidaq" in self.device_manager.devices:
#ai_chans_bits = self.device_manager.devices.nidaq.ai_chans.read(cached=True).get("nidaq_ai_chans").get("value")
ai_chans_bits = self.configuration.get("nidaq", {}).get("nidaq_ai_chans", {}).get("value")
ci_chans_bits = self.configuration.get("nidaq", {}).get("nidaq_ci_chans", {}).get("value")
#add_chans_bits = self.device_manager.devices.nidaq.add_chans.read(cached=True).get("nidaq_add_chans").get("value")
add_chans_bits = self.configuration.get("nidaq", {}).get("nidaq_add_chans", {}).get("value")
measurement_mode = entry.create_group(name="mode")
measurement_mode.attrs["NX_class"] = "NX_CHAR"
if (int(ci_chans_bits) & 0x7F) != 0:
# Create a dataset
rayspec_sdd_active = measurement_mode.create_group(name="Multi_Element_Partial_Fluorescence_Yield")
me_sdd = rayspec_sdd_active.create_dataset(name="Detector", data="Rayspec 7 element Silicon Drift Detector")
me_sdd.attrs["NX_class"] = "NX_CHAR"
if (int(ci_chans_bits) & (1<<8)) != 0:
# Create a dataset
ketek_sdd_active = measurement_mode.create_group(name="Single_Element_Partial_Fluorescence_Yield")
se_sdd = ketek_sdd_active.create_dataset(name="Detector", data="Ketex mini single element Silicon Drift Detector")
se_sdd.attrs["NX_class"] = "NX_CHAR"
if ((int(ai_chans_bits) & (1<<6)) != 0):
# Create a dataset
pips_active = measurement_mode.create_group(name="Total_Flourescence_Yield")
tfy = pips_active.create_dataset(name="Detector", data="Mirion Technologies Partially Depeleted PIPS Detector")
tfy.attrs["NX_class"] = "NX_CHAR"
if ((int(ai_chans_bits) & (1<<0)) != 0) & ((int(ai_chans_bits) & (1<<2)) != 0):
# Create a dataset
ai0ai2_active = measurement_mode.create_group(name="Sample_Transmission")
sam_trans = ai0ai2_active.create_dataset(name="Detector", data="Ionitec 15 cm gas filled Ionisation Chambers")
sam_trans.attrs["NX_class"] = "NX_CHAR"
if ((int(ai_chans_bits) & (1<<2)) != 0) & ((int(ai_chans_bits) & (1<<4)) != 0):
# Create a dataset
ai2ai4_active = measurement_mode.create_group(name="Reference_Transmission")
ref_trans = ai2ai4_active.create_dataset(name="Detector", data="Ionitec 15 cm gas filled Ionisation Chambers")
ref_trans.attrs["NX_class"] = "NX_CHAR"
main_data = entry.create_group(name="data")
main_data.attrs["NX_class"] = "NXdata"
##################
## energy, test whether the signal exists. how to check from config?
###################
energy = main_data.create_group(name="energy")
energy.attrs["NX_class"] = "NXdata"
energy.attrs["units"] = "eV"
main_data.create_soft_link(name="energy", target="/entry/collection/readout_groups/async/nidaq/nidaq_energy/value")
##################
## i0
###################
if (int(ai_chans_bits) & (1<<0)) !=0:
i0 = main_data.create_group(name="i0")
i0.attrs["NX_class"] = "NXdata"
i0.attrs["units"] = "V"
main_data.create_soft_link(name="i0", target="/entry/collection/readout_groups/async/nidaq/nidaq_ai0_mean/value")
##################
## i1
###################
if (int(ai_chans_bits) & (1<<2)) !=0:
i1 = main_data.create_group(name="i1")
i1.attrs["NX_class"] = "NXdata"
i1.attrs["units"] = "V"
main_data.create_soft_link(name="i1", target="/entry/collection/readout_groups/async/nidaq/nidaq_ai2_mean/value")
##################
## i2
###################
if (int(ai_chans_bits) & (1<<4)) !=0:
i2 = main_data.create_group(name="i2")
i2.attrs["NX_class"] = "NXdata"
i2.attrs["units"] = "V"
main_data.create_soft_link(name="i2", target="/entry/collection/readout_groups/async/nidaq/nidaq_ai4_mean/value")
##################
## ci sum
###################
if int(ci_chans_bits) > 0:
ci_sum = main_data.create_group(name="Fluorescence_Sum")
ci_sum.attrs["NX_class"] = "NXdata"
ci_sum.attrs["units"] = "counts"
main_data.create_soft_link(name="Fluorescence_Sum", target="/entry/collection/readout_groups/async/nidaq/nidaq_cisum/value")
##################
## mu sample, test whether the signal exists. how to check from config?
###################
if (int(add_chans_bits) & (1<<0)) !=0:
mu_sample = main_data.create_group(name="mu_sample")
mu_sample.attrs["NX_class"] = "NXdata"
main_data.create_soft_link(name="mu_sample", target="/entry/collection/readout_groups/async/nidaq/nidaq_smpl_abs/value")
##################
## fluo sample, test whether the signal exists. how to check from config?
###################
if (int(add_chans_bits) & (1<<1)) !=0:
mu_sample = main_data.create_group(name="fluo_sample")
mu_sample.attrs["NX_class"] = "NXdata"
main_data.create_soft_link(name="fluo_sample", target="/entry/collection/readout_groups/async/nidaq/nidaq_smpl_fluo/value")
##################
## mu reference, test whether the signal exists. how to check from config?
###################
if (int(add_chans_bits) & (1<<2)) !=0:
mu_reference = main_data.create_group(name="mu_reference")
mu_reference.attrs["NX_class"] = "NXdata"
main_data.create_soft_link(name="mu_reference", target="/entry/collection/readout_groups/async/nidaq/nidaq_ref_abs/value")
pyproject.toml
+9 -1
View File
@@ -12,7 +12,15 @@ classifiers = [
"Programming Language :: Python :: 3",
"Topic :: Scientific/Engineering",
]
dependencies = ["numpy", "scipy", "bec_lib", "h5py", "ophyd_devices"]
dependencies = [
"numpy",
"scipy",
"bec_lib",
"h5py",
"ophyd_devices",
"opencv-python==4.11.0.86",
"xrt",
]
[project.optional-dependencies]
dev = [
tests/tests_devices/test_mo1_bragg.py
+6 -6
View File
@@ -52,7 +52,7 @@ def test_init(mock_bragg):
dev = mock_bragg
assert dev.name == "bragg"
assert dev.prefix == "X01DA-OP-MO1:BRAGG:"
assert dev.crystal.offset_si111._read_pvname == "X01DA-OP-MO1:BRAGG:offset_si111_RBV"
assert dev.crystal.bragg_off_si111._read_pvname == "X01DA-OP-MO1:BRAGG:bragg_off_si111_RBV"
assert dev.move_abs._read_pvname == "X01DA-OP-MO1:BRAGG:move_abs"
@@ -106,14 +106,14 @@ def test_set_xtal(mock_bragg):
dev = mock_bragg
dev.set_xtal("111")
# Default values for mock
assert dev.crystal.offset_si111.get() == 0
assert dev.crystal.offset_si311.get() == 0
assert dev.crystal.bragg_off_si111.get() == 0
assert dev.crystal.bragg_off_si311.get() == 0
assert dev.crystal.d_spacing_si111.get() == 0
assert dev.crystal.d_spacing_si311.get() == 0
assert dev.crystal.xtal_enum.get() == 0
dev.set_xtal("311", offset_si111=1, offset_si311=2, d_spacing_si111=3, d_spacing_si311=4)
assert dev.crystal.offset_si111.get() == 1
assert dev.crystal.offset_si311.get() == 2
dev.set_xtal("311", bragg_off_si111=1, bragg_off_si311=2, d_spacing_si111=3, d_spacing_si311=4)
assert dev.crystal.bragg_off_si111.get() == 1
assert dev.crystal.bragg_off_si311.get() == 2
assert dev.crystal.d_spacing_si111.get() == 3
assert dev.crystal.d_spacing_si311.get() == 4
assert dev.crystal.xtal_enum.get() == 1
tests/tests_scans/test_mono_bragg_scans.py
-4
View File
@@ -66,7 +66,6 @@ def test_xas_simple_scan(scan_assembler, ScanStubStatusMock):
device=None,
action="open_scan",
parameter={
"scan_motors": [],
"readout_priority": {
"monitored": [],
"baseline": [],
@@ -168,7 +167,6 @@ def test_xas_simple_scan_with_xrd(scan_assembler, ScanStubStatusMock):
device=None,
action="open_scan",
parameter={
"scan_motors": [],
"readout_priority": {
"monitored": [],
"baseline": [],
@@ -263,7 +261,6 @@ def test_xas_advanced_scan(scan_assembler, ScanStubStatusMock):
device=None,
action="open_scan",
parameter={
"scan_motors": [],
"readout_priority": {
"monitored": [],
"baseline": [],
@@ -366,7 +363,6 @@ def test_xas_advanced_scan_with_xrd(scan_assembler, ScanStubStatusMock):
device=None,
action="open_scan",
parameter={
"scan_motors": [],
"readout_priority": {
"monitored": [],
"baseline": [],
tests/tests_scans/test_nidaq_continous_scan.py
-1
View File
@@ -60,7 +60,6 @@ def test_xas_simple_scan(scan_assembler, ScanStubStatusMock):
device=None,
action="open_scan",
parameter={
"scan_motors": [],
"readout_priority": {
"monitored": [],
"baseline": [],