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"""
Created by Eugeniy E. Mikhailov 2024/07/18
"""
from qolab.hardware.basic import BasicInstrument
from qolab.hardware.scpi import SCPI_PROPERTY
from ._basic import ScopeSCPI
from qolab.data.trace import Trace, TraceXY
import numpy as np
import scipy.signal
from pyvisa.constants import InterfaceType
from pyvisa.errors import VisaIOError
class RigolDS1054z(ScopeSCPI):
"""Rigol 1054 scope"""
vertDivOnScreen = 8
horizDivOnScreen = 12
def __init__(self, resource, *args, **kwds):
super().__init__(resource, *args, **kwds)
self.config["Device model"] = "Rigol DS1054z"
self.resource.read_termination = "\n"
self.numberOfChannels = 4
self.maxRequiredPoints = 1200
self.resource.timeout = 500 # timeout in ms
# desired number of points per channel, can return twice more
TimePerDiv = SCPI_PROPERTY(
scpi_prfx=":TIMEBASE:MAIN:SCALE",
ptype=float,
doc="Scope Time per Division",
)
def getTimePerDiv(self):
return self.TimePerDiv
def setTimePerDiv(self, value):
self.TimePerDiv = value
TrigDelay = SCPI_PROPERTY(
scpi_prfx=":TIMEBASE:MAIN:OFFSET",
ptype=float,
doc="Scope Time Offset or Trigger Delay",
)
@BasicInstrument.tsdb_append
def getTrigDelay(self):
return self.TrigDelay
@BasicInstrument.tsdb_append
def setTrigDelay(self, value):
self.TrigDelay = value
@BasicInstrument.tsdb_append
def getChanVoltageOffset(self, chNum):
qstr = f":CHANnel{chNum}:OFFSet?"
rstr = self.query(qstr)
return float(rstr)
@BasicInstrument.tsdb_append
def setChanVoltageOffset(self, chNum, val):
cstr = f":CHANnel{chNum}:OFFSet {val}"
self.write(cstr)
@BasicInstrument.tsdb_append
def getChanVoltsPerDiv(self, chNum):
qstr = f":CHANnel{chNum}:SCALe?"
rstr = self.query(qstr)
return float(rstr)
@BasicInstrument.tsdb_append
def setChanVoltsPerDiv(self, chNum, vPerDiv):
cstr = f":CHANnel{chNum}:SCALe {vPerDiv}"
self.write(cstr)
@BasicInstrument.tsdb_append
def getTriggerStatus(self):
"""Get Trigger Status.
We expect TD, WAIT, RUN, AUTO, or STOP.
"""
res = self.query(":TRIGger:STATus?")
return res
@BasicInstrument.tsdb_append
def getTriggerMode(self):
"""Get trigger mode.
We expect AUTO, NORM, or SING (for Single)
"""
res = self.query(":TRIGger:SWEep?")
return res
@BasicInstrument.tsdb_append
def setTriggerMode(self, val):
"""Set trigger mode.
Takes AUTO, NORMal, or SINGle
"""
self.write(f"TRIGger:SWEep {val}")
def stop(self):
self.write(":STOP")
def run(self):
self.write(":RUN")
def getRawWaveform(
self, chNum, availableNpnts=None, maxRequiredPoints=None, decimate=True
):
"""
Get raw channel waveform in binary format.
Parameters
----------
chNum : int
Scope channel to use: 1, 2, 3, or 4
availableNpnts : int or None (default)
Available numnber of points. Do not set it if you want it auto detected.
maxRequiredPoints : int
Maximum number of required points, if we ask less than available
we well get sparse set which proportionally fills all available time range.
decimate : False or True (default)
Decimate should be read as apply the low pass filter or not, technically
for both setting we get decimation (i.e. smaller than available
at the scope number of points). The name came from
``scipy.signal.decimate`` filtering function.
If ``decimate=True`` is used, we get all available points
and then low-pass filter them to get ``maxRequiredPoints``
The result is less noisy then, but transfer time from the instrument
is longer.
If ``decimate=False``, then it we are skipping points to get needed number
but we might see aliasing, if there is a high frequency noise
and sparing > 1. Unless you know what you doing, it is recommended
to use ``decimate=True``.
"""
# if RAW is used the scope should be in STOP state
self.write(f":WAVeform:SOURce CHAN{chNum}")
self.write(":WAVeform:MODE RAW") # {NORMal|MAXimum|RAW} RAW gives maximum number of points
self.write(":WAVeform:FORMat BYTE") # {WORD|BYTE|ASCii}, scope is 8 bit, BYTE is enough
preamble = self.query(":WAVeform:PREamble?").split(",")
"""
Format is
<format>,<type>,<points>,<count>,<xincrement>,<xorigin>,<xreference>,<yincrement>,<yorigin>,<yreference>
Wherein,
<format>: 0 (BYTE), 1 (WORD) or 2 (ASC).
<type>: 0 (NORMal), 1 (MAXimum) or 2 (RAW).
<points>: an integer between 1 and 12000000. After the memory depth option is
installed, <points> is an integer between 1 and 24000000.
<count>: the number of averages in the average sample mode
and 1 in other modes.
<xincrement>: the time difference between two neighboring points
in the X direction.
<xorigin>: the start time of the waveform data in the X direction.
<xreference>: the reference time of the data point in the X direction.
<yincrement>: the waveform increment in the Y direction.
<yorigin>: the vertical offset relative
to the "Vertical Reference Position" in the Y direction.
<yreference>: the vertical reference position in the Y direction.
"""
Npnts = int(preamble[2])
wfRaw = np.zeros(Npnts, dtype=np.int8)
maxreadable = 250_000 # the maximum number of bytes readable in one go
chunk_size = 70_000 # unfortunately large chunk size prone to read errors
errCnt = 0
strt = 1
stp = min(maxreadable, Npnts)
errorFreeChunkSize = []
errorProneChunkSize = []
while (strt <= Npnts):
stp = strt - 1 + chunk_size
stp = min(stp, Npnts)
# reading requested number of points in chunks
self.write(f":WAVeform:STARt {strt}")
self.write(f":WAVeform:STOP {stp}")
qstr = ":WAVeform:DATA?"
try:
wfRawChunk = self.query_binary_values(
qstr,
datatype="b",
header_fmt="ieee",
container=np.array,
chunk_size=(chunk_size + 100),
)
if len(wfRawChunk) == 0:
continue # we need to repeat chunk read
wfRaw[strt-1:stp] = wfRawChunk
errorFreeChunkSize.append(chunk_size)
chunk_size = min(maxreadable, int(chunk_size*1.1))
strt += chunk_size
except VisaIOError:
errCnt += 1
errorProneChunkSize.append(chunk_size)
print(f"ERROR count is {errCnt} while reading raw chunk the scope")
print(f"Current pointers are {strt=} {stp=} with {chunk_size=}")
if len(errorFreeChunkSize) > 10:
chunk_size = int(np.mean(errorFreeChunkSize))
else:
chunk_size = max(1, int(np.mean(errorProneChunkSize)*0.8))
print(f"new {chunk_size=}")
pass # we repeat this loop iteration again
print(f"final {chunk_size=}")
if True:
return wfRaw
(
sparsing,
Npnts,
availableNpnts,
maxRequiredPoints,
) = self.calcSparsingAndNumPoints(availableNpnts, maxRequiredPoints)
if decimate:
Npnts = availableNpnts # get all of them and decimate later
if (sparsing == 1 and Npnts == availableNpnts) or decimate:
# We are getting all points of the trace
# Apparently sparsing has no effect with this command
# and effectively uses SP=1 for any sparsing
# but I want to make sure and force it
cstr = "WAVEFORM_SETUP NP,0,FP,0,SP,1"
# technically when we know Npnts and sparsing
# we can use command from the follow up 'else' clause
else:
# we just ask every point with 'sparsing' interval
# fast to grab but we could do better with more advance decimate
# method, which allow better precision for the price
# of longer acquisition time
cstr = f"WAVEFORM_SETUP SP,{sparsing},NP,{Npnts},FP,0"
# Note: it is not enough to provide sparsing (SP),
# number of points (NP) needed to be calculated properly too!
# From the manual
# WAVEFORM_SETUP SP,<sparsing>,NP,<number>,FP,<point>
# SP Sparse point. It defines the interval between data points.
# For example:
# SP = 0 sends all data points.
# SP = 1 sends all data points.
# SP = 4 sends every 4th data point
# NP — Number of points. It indicates how many points should be transmitted.
# For example:
# NP = 0 sends all data points.
# NP = 50 sends a maximum of 50 data points.
# FP — First point. It specifies the address of the first data point
# to be sent.
# For example:
# FP = 0 corresponds to the first data point.
# FP = 1 corresponds to the second data point
self.write(cstr)
trRaw = Trace(f"Ch{chNum}")
qstr = f"C{chNum}:WAVEFORM? DAT2"
# expected full reply: 'C1:WF DAT2,#9000000140.........'
try:
wfRaw = self.query_binary_values(
qstr,
datatype="b",
header_fmt="ieee",
container=np.array,
chunk_size=(Npnts + 100),
)
if self.resource.interface_type == InterfaceType.usb:
# Somehow on windows (at least with USB interface)
# there is a lingering empty string which we need to flush out
r = self.read()
if r != "":
print(f"WARNING: We expected an empty string but got {r=}")
trRaw.values = wfRaw.reshape(wfRaw.size, 1)
if decimate and sparsing != 1:
numtaps = 3
# not sure it is the best case
trRaw.values = scipy.signal.decimate(
trRaw.values, sparsing, numtaps, axis=0
)
except ValueError as err:
# most likely we get crazy number of points
# self.read() # flushing the bogus output of previous command
print(f"Error {err=}: getting waveform failed for {qstr=}")
wfRaw = np.array([])
trRaw.config["unit"] = "Count"
trRaw.config["tags"]["Decimate"] = decimate
return (trRaw, availableNpnts, Npnts)
def getWaveform(
self, chNum, availableNpnts=None, maxRequiredPoints=None, decimate=True
):
"""
For decimate use see ``getRawWaveform``.
In short decimate=True is slower but more precise.
"""
trRaw, availableNpnts, Npnts = self.getRawWaveform(
chNum,
availableNpnts=availableNpnts,
maxRequiredPoints=maxRequiredPoints,
decimate=decimate,
)
VoltageOffset = self.getChanVoltageOffset(chNum)
VoltsPerDiv = self.getChanVoltsPerDiv(chNum)
tr = trRaw
tr.values = (
trRaw.values * VoltsPerDiv * self.vertDivOnScreen / 250 - VoltageOffset
)
tr.config["unit"] = "Volt"
tr.config["tags"]["VoltageOffset"] = VoltageOffset
tr.config["tags"]["VoltsPerDiv"] = VoltsPerDiv
return (tr, availableNpnts)
def getTrace(
self, chNum, availableNpnts=None, maxRequiredPoints=None, decimate=True
):
old_trg_status = self.getTriggerStatus()
self.stop()
# to get synchronous channels
wfVoltage, availableNpnts = self.getWaveform(
chNum,
availableNpnts=availableNpnts,
maxRequiredPoints=maxRequiredPoints,
decimate=decimate,
)
t = self.getTimeTrace(
availableNpnts=availableNpnts, maxRequiredPoints=maxRequiredPoints
)
tr = TraceXY(f"Ch{chNum}")
tr.x = t
tr.y = wfVoltage
# restore scope to the before acquisition mode
if old_trg_mode != "STOP":
self.run()
return tr
if __name__ == "__main__":
import pyvisa
print("testing")
rm = pyvisa.ResourceManager()
print(rm.list_resources())
# instr = rm.open_resource("TCPIP::192.168.0.62::INSTR")
instr = rm.open_resource("USB0::0x1AB1::0x04CE::DS1ZA170502787::0::INSTR")
scope = RigolDS1054z(instr)
print(f"ID: {scope.idn}")
print(f"TimePerDiv = scope.TimePerDiv")
# print(f'Ch1 mean: {scope.mean(1)}')
print(f"Ch1 available points: {scope.getAvailableNumberOfPoints(1)}")
print(f"Sample Rate: {scope.getSampleRate()}")
print(f"Time per Div: {scope.getTimePerDiv()}")
print(f"Ch1 Volts per Div: {scope.getChanVoltsPerDiv(1)}")
print(f"Ch1 Voltage Offset: {scope.getChanVoltageOffset(1)}")
print("------ Header start -------------")
print(str.join("\n", scope.getHeader()))
print("------ Header ends -------------")
ch1 = scope.getTrace(1)
traces = scope.getAllTraces()
|
