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first working version for aramis undulators

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augustin_s
2022-03-01 11:07:15 +01:00
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from time import sleep
import numpy as np
from epics import PV
from logzero import logger as log
from slic.core.adjustable import Adjustable, PVAdjustable, PVEnumAdjustable
from slic.core.scanner.scanbackend import wait_for_all #, stop_all
UND_NAME_FMT = "SARUN{:02}-UIND030"
N_UND_CHIC = None
N_UNDS = list(range(3, 15+1))
#N_UNDS.remove(N_UND_CHIC) # does not exist
energy_offset = 20.37839
class Undulators(Adjustable):
"""
for n_und_ref=None (default), the reference undulator currently used by the machine will be used
"""
def __init__(self, n_unds=N_UNDS, n_und_ref=None, scaled=True, ID="ARAMIS_UNDULATORS", name="Aramis Undulators", units="eV"):
# # don't allow setting these since there's no chic :)
# chic_fudge_offset = 0
# adjust_chic = False
super().__init__(ID, name=name, units=units)
machine_n_und_ref = get_machine_n_und_ref()
if n_und_ref is None:
if machine_n_und_ref is None:
raise ValueError(f"could not read reference undulator currently used by the machine, please specify n_und_ref")
n_und_ref = machine_n_und_ref
if n_und_ref != machine_n_und_ref:
log.warning(f"the chosen reference undulator ({n_und_ref}) is not the reference undulator currently used by the machine ({machine_n_und_ref})")
n_unds = list(n_unds)
if N_UND_CHIC in n_unds:
log.warning(f"the CHIC ({N_UND_CHIC}) is in the list of active undulators: {n_unds}, and will be ignored/removed")
n_unds.remove(N_UND_CHIC)
if n_und_ref not in n_unds:
raise ValueError(f"the reference undulator ({n_und_ref}) is not in the list of active undulators: {n_unds}")
self.n_unds = n_unds
self.n_und_ref = n_und_ref
self.und_names = und_names = [UND_NAME_FMT.format(n) for n in n_unds]
self.und_name_cal = und_name_cal = UND_NAME_FMT.format(n_und_ref)
self.adjs = {name: Undulator(name) for name in und_names}
# self.chic = CHIC(chic_fudge_offset, name, units)
# self.phases = Phases(n_unds)
# self.adjust_chic = adjust_chic
self.scaled = scaled
self.convert = ConverterEK()
a = self.adjs[und_name_cal]
self.scale = ScalerEK(a)
def set_target_value(self, value, hold=False):
value = value + energy_offset
k = self.convert.K(value)
if np.isnan(k):
print("K is nan for", value)
return
print(f"{k} <- {value}")
ks_current = [a.get_current_value(readback=False) for a in self.adjs.values()]
if self.scaled:
header = "scaled: "
ks_target = self.scale.K(value, ks_current)
else:
header = "all equal:"
ks_target = k * np.ones_like(ks_current)
print(header, ks_target)
print()
def change():
#TODO: replace by set_all_target_values_and_wait when print not needed anymore
tasks = []
for (name, a), k_old, k_new in zip(self.adjs.items(), ks_current, ks_target):
delta = k_old - k_new
print(f"{name}: {k_old}\t->\t{k_new}\t({delta})")
if np.isnan(k_new):
print(f"{name} skipped since target K is nan")
continue
t = a.set_target_value(k_new, hold=False)
tasks.append(t)
wait_for_all(tasks)
# # make sure new K values have been written TODO: needed?
# sleep(2) # check if this can be shortened back to 0.5
# # switching on radial motors ...
# wait_for_all([
# a.adj_radial_on.set_target_value(1, hold=False) for a in self.adjs.values()
# ])
# # press a few times
# for _ in range(3):
# # ... and pushing go to ensure proper movements
# wait_for_all([
# a.adj_radial_go.set_target_value(1, hold=False) for a in self.adjs.values()
# ])
# sleep(0.2)
# # make sure the undulators finished moving TODO: needed?
# sleep(5)
# if self.adjust_chic:
# print("CHIC adjustment follows")
## self.chic.set_target_value(value, hold=False).wait() #TODO: test whether an additional sleep is needed
# self.phases.set(value)
# print("CHIC adjustment done")
# else:
# print("CHIC adjustment skipped")
# make sure the undulators and phases finished moving TODO: needed?
sleep(5)
return self._as_task(change, hold=hold)
def get_current_value(self):
n = self.und_name_cal
a = self.adjs[n]
k = a.get_current_value()
energy = self.convert.E(k) - energy_offset
# all_ks = [a.get_current_value() for a in self.adjs.values()]
# checks = np.isclose(all_ks, k, rtol=0, atol=0.001)
# if not all(checks):
# print(f"Warning: Ks are not all close to {k}:")
# for name, k, chk in zip(self.adjs.keys(), all_ks, checks):
# if not chk:
# print(name, k)
return energy # if we need to fudge the number to match the mono, do it here!
def is_moving(self):
return any(a.is_moving() for a in self.adjs)
class Undulator(PVAdjustable):
def __init__(self, name, accuracy=0.0005):
pvname_setvalue = name + ":K_SET"
pvname_readback = pvname_setvalue # name + ":K_READ" #TODO: there are no readback values?
super().__init__(pvname_setvalue, pvname_readback=pvname_readback, accuracy=accuracy, active_move=True, name=name, internal=True)
self.adj_energy = PVAdjustable(name + ":FELPHOTENE", internal=True)
# self.adj_radial_on = PVAdjustable(name + ":RADIAL-ON", internal=True) #TODO: do not exist
# self.adj_radial_go = PVAdjustable(name + ":RADIAL-GO", internal=True) #TODO: do not exist
# self.adj_radial_on_proc = PVAdjustable(name + ":RADIAL-ON.PROC", internal=True)
# self.adj_radial_go_proc = PVAdjustable(name + ":RADIAL-GO.PROC", internal=True)
@property
def energy(self):
return self.adj_energy.get_current_value() * 1000
class ConverterEK:
h = 4.135667696e-15 # eV * s
c = 299792458 # m / s
lambda_u = 15e-3 # m
const = 2 * h * c / lambda_u # eV
electron_rest_energy = 0.51099895 # MeV
# was: pvname_electron_energy="SATCL01-MBND100:P-READ"
# was: pvname_electron_energy="SATCB01:ENE-FILT-OP"
def __init__(self, pvname_electron_energy="SARCL02-MBND100:P-READ"): #S30CB13:ENE-FILT-OP
self.pv_electron_energy = PV(pvname_electron_energy)
def K(self, energy):
f = self.get_factor()
v = f / energy - 1
return np.sqrt(2 * v)
def E(self, k_value):
f = self.get_factor()
v = 1 + k_value**2 / 2
return f / v
def get_factor(self):
return self.const * self.get_gamma_squared()
def get_gamma_squared(self):
electron_energy = self.pv_electron_energy.get()
gamma = electron_energy / self.electron_rest_energy
return gamma**2
class ScalerEK:
def __init__(self, und_reference):
self.und = und_reference
def K(self, energy_target, K_current=None):
if K_current is None:
K_current = self.und.get_current_value()
K_current = np.asarray(K_current)
energy_current = self.und.energy
energy_ratio = energy_current / energy_target
K_target_squared = energy_ratio * (K_current**2 + 2) - 2
return np.sqrt(K_target_squared)
#class CHIC(PVAdjustable):
#
# def __init__(self, fudge_offset, name, units):
# self.fudge_offset = fudge_offset
# name += " CHIC Energy"
# super().__init__("SATUN-CHIC:PHOTON-ENERGY", name=name)
# self.pvs.start = PV("SATUN-CHIC:APPLY-DELAY-OFFSET-PHASE")
# self.units = units
#
#
# def set_target_value(self, value, hold=False):
# fudge_offset = self.fudge_offset
# print("CHIC fudge offset is", fudge_offset)
# value -= fudge_offset
# value /= 1000
#
# def change():
# sleep(1)
# print("CHIC setvalue")
# self.pvs.setvalue.put(value, wait=True)
# print("CHIC start")
# self.pvs.start.put(1, wait=True)
# #TODO: test whether an additional sleep is needed
# sleep(1)
#
# return self._as_task(change, hold=hold)
#
#
# def get_current_value(self):
# return super().get_current_value() * 1000
#class TwoColorChicane(PVAdjustable):
#
# def __init__(self, name):#, t0=0):
## self.t0 = t0
## name += " Two Color Chicane"
# super().__init__("SATUN14-MBND100:I-SET", "SATUN14-MBND100:I-READ", process_time=1, name=name)
#
## def set_target_value(self, value, hold=False):
## super().set_target_value(value)
#
## def get_current_value(self):
## return super().get_current_value()
#class Phases:
#
# def __init__(self, n_unds=N_UNDS):
# # 22 does not have a chicane
# n_unds = n_unds.copy()
# if 22 in n_unds:
# n_unds.remove(22)
#
# # 22 does not have a chicane
# n_unds_all = N_UNDS.copy()
# if 22 in n_unds_all:
# n_unds_all.remove(22)
#
# self.cb_auto_good = {i: PV(f"SATUN{i:02}-CHIC:AUTO-PHASING") for i in n_unds}
# self.cb_auto_bad = {i: PV(f"SATUN{i:02}-CHIC:AUTO-PHASING") for i in set(n_unds_all) - set(n_unds)}
#
# self.pv_fixed_energy = PV("SATUN-CHIC:FIX_PHOTON_ENERGY")
# self.pv_energy = PV("SATUN-CHIC:PHOTON-ENERGY")
#
#
# def set(self, energy):
# for cb in self.cb_auto_good.values(): cb.put(int(False))
# for cb in self.cb_auto_bad.values(): cb.put(int(False))
# sleep(0.1)
#
# pv_fixed_energy = self.pv_fixed_energy
#
# current_state = pv_fixed_energy.get()
# pv_fixed_energy.put(int(True)) # enforce fixed energy
#
# self.pv_energy.put(energy / 1000) # in keV
# sleep(0.1)
#
# for cb in self.cb_auto_good.values(): cb.put(int(True))
# sleep(0.1)
#
# for cb in self.cb_auto_good.values(): cb.put(int(False))
# for cb in self.cb_auto_bad.values(): cb.put(int(False))
# sleep(0.1)
#
## pv_fixed_energy.put(current_state) # reset to original state
#class Phases:
# def __init__(self, n_unds=N_UNDS):
# # 22 does not have a chicane
# n_unds = n_unds.copy()
# if 22 in n_unds:
# n_unds.remove(22)
# self.pv_energy = PV("SATUN-CHIC:PHOTON-ENERGY")
# self.pv_fixed_energy = PV("SATUN-CHIC:FIX_PHOTON_ENERGY")
# self.adjs_apply = {i: PVAdjustable(f"SATUN{i:02}-CHIC:APPLY-DOP", internal=True) for i in n_unds}
# def set(self, energy):
# pv_energy = self.pv_energy
# pv_fixed_energy = self.pv_fixed_energy
# current_state = pv_fixed_energy.get()
# pv_fixed_energy.put(int(True)) # enforce fixed energy
# pv_energy.put(energy / 1000) # in keV
# sleep(0.1)
# self.update()
## sleep(10)
# pv_fixed_energy.put(current_state) # reset to original state
# def update(self):
# wait_for_all([
# adj_apply.set_target_value(1) for adj_apply in self.adjs_apply.values()
# ])
def get_machine_n_und_ref():
res = PVEnumAdjustable("SARUN:REF-UND").get()
if not res.startswith("SARUN"):
return None
n = len("SARUN")
res = res[n:]
try:
res = int(res)
except ValueError:
return None
return res