artiq/artiq/frontend/pdq2_client.py

138 lines
5.3 KiB
Python
Executable File

#!/usr/bin/env python3
# Based on code by Robert Jordens <jordens@gmail.com>, 2012
import argparse
import time
from scipy import interpolate
import numpy as np
from artiq.protocols.pc_rpc import Client
from artiq.tools import verbosity_args, init_logger
def get_argparser():
parser = argparse.ArgumentParser(description="""PDQ2 client.
Evaluates times and voltages, interpolates and uploads
them to the controller.""")
parser.add_argument("-s", "--server", default="::1",
help="hostname or IP of the controller to connect to")
parser.add_argument("--port", default=3252, type=int,
help="TCP port to use to connect to the controller")
parser.add_argument("-c", "--channel", default=0, type=int,
help="channel: 3*board_num+dac_num [%(default)s]")
parser.add_argument("-f", "--frame", default=0, type=int,
help="frame [%(default)s]")
parser.add_argument("-e", "--free", default=False,
action="store_true",
help="software trigger [%(default)s]")
parser.add_argument("-n", "--disarm", default=False,
action="store_true",
help="disarm group [%(default)s]")
parser.add_argument("-t", "--times",
default="np.arange(5)*1e-6",
help="sample times (s) [%(default)s]")
parser.add_argument("-u", "--voltages",
default="(1-np.cos(t/t[-1]*2*np.pi))/2",
help="sample voltages (V) [%(default)s]")
parser.add_argument("-o", "--order", default=3, type=int,
help="interpolation"
" (0: const, 1: lin, 2: quad, 3: cubic)"
" [%(default)s]")
parser.add_argument("-m", "--dcm", default=None, type=int,
help="choose fast 100MHz clock [%(default)s]")
parser.add_argument("-x", "--demo", default=False, action="store_true",
help="demo mode: pulse and chirp,"
" 1V*ch+0.1V*frame [%(default)s]")
parser.add_argument("-p", "--plot", help="plot to file [%(default)s]")
parser.add_argument("-r", "--reset", default=False,
action="store_true", help="do reset before")
parser.add_argument("-b", "--bit", default=False,
action="store_true", help="do bit test")
verbosity_args(parser)
return parser
def main():
args = get_argparser().parse_args()
init_logger(args)
dev = Client(args.server, args.port, "pdq2")
dev.init()
if args.reset:
dev.flush_escape()
dev.write_cmd("RESET_EN")
time.sleep(.1)
if args.dcm:
dev.write_cmd("DCM_EN")
dev.set_freq(100e6)
elif args.dcm == 0:
dev.write_cmd("DCM_DIS")
dev.set_freq(50e6)
dev.write_cmd("START_DIS")
num_channels = dev.get_num_channels()
num_frames = dev.get_num_frames()
times = eval(args.times, globals(), {})
voltages = eval(args.voltages, globals(), dict(t=times))
if args.demo:
# FIXME
channels = [args.channel] if args.channel < num_channels \
else range(num_channels)
frames = [args.frame] if args.frame < num_frames \
else range(num_frames)
for channel in channels:
f = []
for frame in frames:
vi = .1*frame + channel + voltages
pi = 2*np.pi*(.01*frame + .1*channel + 0*voltages)
fi = 10e6*times/times[-1]
f.append(b"".join([
dev.frame(times, vi, order=args.order, end=False),
dev.frame(2*times, voltages, pi, fi, trigger=False),
# dev.frame(2*times, 0*vi+.1, 0*pi, 0*fi+1e6),
# dev.frame(times, 0*vi, order=args.order, silence=True),
]))
board, dac = divmod(channel, dev.num_dacs)
dev.write_data(dev.add_mem_header(board, dac, dev.map_frames(f)))
elif args.bit:
map = [0] * num_frames
t = np.arange(2*16) * 1.
v = [-1, 0, -1]
for i in range(15):
vi = 1 << i
v.extend([vi - 1, vi])
v = np.array(v)*dev.get_max_out()/(1 << 15)
t, v = t[:3], v[:3]
# print(t, v)
for channel in range(num_channels):
dev.multi_frame([(t, v)], channel=channel, order=0, map=map,
shift=15, stop=False, trigger=False)
else:
tv = [(times, voltages)]
map = [None] * num_frames
map[args.frame] = 0
dev.multi_frame(tv, channel=args.channel, order=args.order, map=map)
dev.write_cmd("START_EN")
if not args.disarm:
dev.write_cmd("ARM_EN")
if args.free:
dev.write_cmd("TRIGGER_EN")
if args.plot:
from matplotlib import pyplot as plt
fig, ax0 = plt.subplots()
ax0.plot(times, voltages, "xk", label="points")
if args.order:
spline = interpolate.splrep(times, voltages, k=args.order)
ttimes = np.arange(0, times[-1], 1/dev.get_freq())
vvoltages = interpolate.splev(ttimes, spline)
ax0.plot(ttimes, vvoltages, ",b", label="interpolation")
fig.savefig(args.plot)
if __name__ == "__main__":
main()