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from artiq.experiment import *
from pyLIAF.artiq.controllers import UrukulCh
#from artiq.coredevice.ad9910 import PHASE_MODE_ABSOLUTE
import time
import numpy as np
from time import sleep
import socket
client_socket = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
address = ('10.99.34.95', 6001)
class FrontalBeamProfile(EnvExperiment):
"""Sweeps picomotor of frontal IR beam and measures fluorescence retrieving beam profile"""
def build(self):
# Agrego kernel invariants a ver si mejoro algo de la performance
#kernel_invariants = getattr(self, 'kernel_invariants', set())
#self.kernel_invariants = kernel_invariants | {"no_measures", "t_cool", "t_trans", "t_readout"}
self.setattr_device("core")
self.setattr_device("ccb")
self.pmt = self.get_device("ttl0")
#self.laserUV = UrukulCh(self, ch=2, freq=110.0, amp=0.3, name="UV") #corresponde a 0.7 Vpp
#self.laserIR1 = UrukulCh(self, ch=1, freq=208.0, amp=0.35, name="IR1") #corresponde a 0.8 Vpp
#self.laserIR2 = UrukulCh(self, ch=3, freq=80.0, amp=0.2, name="IR2") #corresponde a 0.8 Vpp
#self.laserIR2shift = UrukulCh(self, ch=0, freq=270.0, amp=0.7, name="IR2shift") #corresponde a 0.8 Vpp
self.setattr_argument(f"IR2_freq",
NumberValue(85*MHz, unit='MHz', scale=MHz, min=1*MHz, max=400*MHz),
"Measurement params")
self.setattr_argument(f"IR2_amp",
NumberValue(0.3, min=0., max=0.8),
"Measurement params")
self.setattr_argument(f"t_readout",
NumberValue(300*ms, unit='ms', scale=ms, min=1*ms),
"Measurement params")
self.setattr_argument(f"IR2_final_freq",
NumberValue(85*MHz, unit='MHz', scale=MHz, min=1*MHz, max=400*MHz),
"Final params")
self.setattr_argument(f"IR2_final_amp",
NumberValue(0.3, min=0.0, max=0.35),
"Final params")
self.setattr_argument("Channel",
EnumerationValue(["1", "2"]),
"Motor params")
self.setattr_argument(f"Steps",
NumberValue(50, min=-1000, max=1000),
"Motor params")
self.setattr_argument(f"Measurements",
NumberValue(100, min=1, max=100000),
"Motor params")
self.setattr_argument("Return", BooleanValue(1==0), "Motor params")
self.setattr_argument("Comments", StringValue(" "), "General comments")
@rpc
def create_datasets(self):
#self.set_dataset("no_measures", self.no_measures, broadcast=True, archive=True)
#self.set_dataset("no_frequencies", len(self.UV_Freqs.sequence), broadcast=True, archive=True)
self.set_dataset("IR2_freq", self.IR2_freq, broadcast=False, archive=True)
self.set_dataset("IR2_amp", self.IR2_amp, broadcast=False, archive=True)
self.set_dataset("t_readout", self.t_readout, broadcast=False, archive=True)
self.set_dataset("Channel", self.Channel, broadcast=False, archive=True)
self.set_dataset("Steps", self.Steps, broadcast=False, archive=True)
self.set_dataset("Measurements", self.Measurements, broadcast=False, archive=True)
self.set_dataset("array_steps", np.linspace(0,int(self.Steps*self.Measurements),int(self.Measurements)), broadcast=True, archive=True)
self.set_dataset("counts_spectrum", np.zeros(int(self.Measurements), dtype=int), broadcast=True, archive=True)
self.set_dataset("Comments", self.Comments, broadcast=False, archive=True)
@rpc(flags={"async"})
def create_applets(self):
self.ccb.issue("create_applet", "Beam_profile",
"${python} -m pyLIAF.artiq.applets.plot_xy "
"counts_spectrum "
"--x array_steps")
@rpc
def initialize_motor_com(self):
client_socket.connect(address)
print('motor comm initialized')
sleep(1)
@rpc
def change_motor_value(self):
client_socket.sendall(f"{self.Channel} {int(self.Steps)}".encode())
response = client_socket.recv(1024)
sleep(0.2)
@rpc
def end_motor_com(self):
client_socket.sendall(b'exit')
response = client_socket.recv(1024)
print(response.decode())
client_socket.close()
print('todo concluye al fin')
@rpc
def return_motor_value(self):
client_socket.sendall(f"{self.Channel} {-1*int(self.Steps)}".encode())
response = client_socket.recv(1024)
sleep(0.2)
@kernel
def run(self):
self.initialize_motor_com()
#t_cool_mu = self.core.seconds_to_mu(self.t_cool) # Precomputo esto para despues
self.create_datasets()
self.create_applets()
#self.init_kernel()
delay(10*ms)
# self.laserIR2.on()
for runN in range(int(self.Measurements)):
delay(10*ms)
self.change_motor_value()
cuentas = self.readout() # Hago la medicion y vuelvo con las cuentas
self.mutate_dataset("counts_spectrum", runN, cuentas)
if self.Return:
for runN in range(int(self.Measurements)):
delay(10*ms)
self.return_motor_value()
#cuentas = self.readout() # Hago la medicion y vuelvo con las cuentas
#self.mutate_dataset("counts_spectrum", runN, cuentas)
self.core.break_realtime()
delay(50*ms)
self.end_motor_com()
print("jose maria listorti")
@kernel
def init_kernel(self):
self.core.reset()
self.pmt.input()
#self.laserUV.initialize_channel()
#self.laserIR.initialize_channel()
delay(1*ms)
# Seteo los perfiles 0 y 1 con los mismos valores
# el 0 va a ser el de ENFRIADO, el 1 va a ser el de MEDICION y el 2 va a ser de CALENTAMIENTO
#self.laserIR1.set_channel()
#self.laserUV.set_channel()
#self.laserIR2.set_channel()
#self.laserIR2shift.set_channel()
#self.laserIR1.set_frequency(self.IR1_cooling_freq, self.IR1_cooling_amp, profile=0)
#self.laserIR2shift.set_frequency(270*MHz, 0.7, profile=0)
#self.laserUV.set_frequency(self.UV_cooling_freq, self.UV_cooling_amp, profile=0)
#self.laserIR2.set_frequency(self.IR2_cooling_freq, self.IR2_cooling_amp, profile=0)
#self.laserIR1.set_channel(profile=1)
#self.core.break_realtime()
#self.laserUV.set_channel(profile=1)
#self.core.break_realtime()
#self.laserIR2shift.set_channel(profile=1)
self.core.break_realtime()
self.laserIR2.set_channel(profile=1)
self.core.break_realtime()
self.laserUV.set_frequency(self.UV_CPT_freq, self.UV_CPT_amp, profile=1)
#self.laserUV.set_frequency(self.UV_CPT_freq, 0.07, profile=1)
self.core.break_realtime()
self.laserIR2.set_frequency(self.IR2_CPT_freq, self.IR2_CPT_amp, profile=1)
self.core.break_realtime()
self.laserIR2shift.set_frequency(270*MHz, 0.7, profile=1)
#self.laserTISA.set_frequency(self.TISA_CPT_freq, 0.035, profile=1)
self.core.break_realtime()
#self.laserIR1.set_channel(profile=2)
#self.core.break_realtime()
#self.laserUV.set_channel(profile=2)
#self.core.break_realtime()
#self.laserIR2.set_channel(profile=2)
#self.core.break_realtime()
#self.laserIR2shift.set_channel(profile=2)
#self.core.break_realtime()
#self.laserIR1.set_frequency(self.IR1_cooling_freq, self.IR1_cooling_amp, profile=2)
#self.core.break_realtime()
#self.laserIR2shift.set_frequency(270*MHz, 0.7, profile=2)
#self.core.break_realtime()
#self.laserUV.set_frequency(self.UV_cooling_freq, self.UV_cooling_amp, profile=2)
#self.core.break_realtime()
#self.laserIR2.set_frequency(self.IR2_cooling_freq, self.IR2_cooling_amp, profile=2)
# Me aseguro que todo termine antes de seguir
self.core.break_realtime()
self.core.wait_until_mu(now_mu())
@kernel
def readout(self) -> TInt64:
"""Registro de cuentas emitidas"""
self.core.break_realtime()
delay(50*ms)
here = self.pmt.gate_rising(self.t_readout) # Que mida durante t_readout
return self.pmt.count(here) # recupero las cuentas medidas