Source code for skrf.vi.vna.keysight_pna

import warnings
from collections import OrderedDict, Iterable

import numpy as np
import skrf
import pyvisa

from . import abcvna
from . import keysight_pna_scpi


[docs]class PNA(abcvna.VNA): """ Class for modern Keysight/Agilent Peformance Network Analyzers """ DEFAULT_VISA_ADDRESS = "GPIB::16::INSTR" NAME = "Keysight PNA" NPORTS = 2 NCHANNELS = 32 SCPI_VERSION_TESTED = 'A.09.20.08'
[docs] def __init__(self, address=DEFAULT_VISA_ADDRESS, **kwargs): """ initialization of PNA Class Parameters ---------- address : str visa resource string (full string or ip address) kwargs : dict interface (str), port (int), timeout (int), :param address: :param kwargs: """ super(PNA, self).__init__(address, **kwargs) self.resource.timeout = kwargs.get("timeout", 2000) self.scpi = keysight_pna_scpi.SCPI(self.resource) # self.use_binary() self.use_ascii()
[docs] def use_binary(self): """setup the analyzer to transfer in binary which is faster, especially for large datasets""" self.resource.write(':FORM:BORD SWAP') self.resource.write(':FORM:DATA REAL,64') self.resource.values_format.use_binary(datatype='d', is_big_endian=False, container=np.array)
[docs] def use_ascii(self): self.resource.write(':FORM:DATA ASCII') self.resource.values_format.use_ascii(converter='f', separator=',', container=np.array)
@property def echo(self): return self.scpi.echo @echo.setter def echo(self, onoff): if onoff in (1, True): self.scpi.echo = True elif onoff in (0, False): self.scpi.echo = False else: raise warnings.warn("echo must be a boolean") @property def active_channel(self): old_timeout = self.resource.timeout self.resource.timeout = 500 try: channel = self.scpi.query_active_channel() except pyvisa.VisaIOError: print("No channel active, using 1") channel = 1 finally: self.resource.timeout = old_timeout return channel @active_channel.setter def active_channel(self, channel): """ Set the active channel on the analyzer Parameters ---------- channel : int Notes ----- There is no specific command to activate a channel, so we ask which channel we want and then activate the first trace on that channel. We do this because if the analyzer gets into a state where it doesn't recognize any activated measurements, the get_snp_network method will fail, and possibly others as well. That is why in some methods you will see the fillowing line: self.active_channel = channel = kwargs.get("channel", self.active_channel) this way we force this property to be set, even if it just resets itself to the same value, but then a trace will become active and our get_snp_network method will succeed. """ # TODO: Good chance this will fail if no measurement is on the set channel, need to think about that... mnum = self.scpi.query_meas_number_list(channel)[0] self.scpi.set_selected_meas_by_number(channel, mnum) return
[docs] def sweep(self, **kwargs): """ Initialize a fresh sweep of data on the specified channels Parameters ---------- kwargs : dict channel ("all", int or list of channels), timeout (milliseconds) trigger a fresh sweep on the specified channels (default is "all" if no channel specified) Autoset timeout and sweep mode based upon the analyzers current averaging setting, and then return to the prior state of continuous trigger or hold. """ self.resource.clear() self.scpi.set_trigger_source("IMM") original_timeout = self.resource.timeout # expecting either an int or a list of ints for the channel(s) channels_to_sweep = kwargs.get("channels", None) if not channels_to_sweep: channels_to_sweep = kwargs.get("channel", "all") if not type(channels_to_sweep) in (list, tuple): channels_to_sweep = [channels_to_sweep] channels = self.scpi.query_available_channels() for i, channel in enumerate(channels): sweep_mode = self.scpi.query_sweep_mode(channel) was_continuous = "CONT" in sweep_mode.upper() sweep_time = self.scpi.query_sweep_time(channel) averaging_on = self.scpi.query_averaging_state(channel) averaging_mode = self.scpi.query_averaging_mode(channel) if averaging_on and "SWE" in averaging_mode.upper(): sweep_mode = "GROUPS" number_of_sweeps = self.scpi.query_averaging_count(channel) self.scpi.set_groups_count(channel, number_of_sweeps) number_of_sweeps *= self.nports else: sweep_mode = "SINGLE" number_of_sweeps = self.nports channels[i] = { "cnum": channel, "sweep_time": sweep_time, "number_of_sweeps": number_of_sweeps, "sweep_mode": sweep_mode, "was_continuous": was_continuous } self.scpi.set_sweep_mode(channel, "HOLD") timeout = kwargs.get("timeout", None) # recommend not setting this variable, as autosetting is preferred try: for channel in channels: import time if "all" not in channels_to_sweep and channel["cnum"] not in channels_to_sweep: continue # default for sweep is all, else if we specify, then sweep if not timeout: # autoset timeout based on sweep time sweep_time = channel["sweep_time"] * channel[ "number_of_sweeps"] * 1000 # convert to milliseconds, and double for buffer self.resource.timeout = max(sweep_time * 2, 5000) # give ourselves a minimum 5 seconds for a sweep else: self.resource.timeout = timeout self.scpi.set_sweep_mode(channel["cnum"], channel["sweep_mode"]) self.wait_until_finished() finally: self.resource.clear() for channel in channels: if channel["was_continuous"]: self.scpi.set_sweep_mode(channel["cnum"], "CONT") self.resource.timeout = original_timeout return
[docs] def upload_twoport_calibration(self, cal, port1=1, port2=2, **kwargs): """ upload a calibration to the vna, and set correction on all measurements Parameters ---------- cal : skrf.Calibration port1: int port2: int calibration error terms reference # forward = (1, 1), reverse = (2, 2) "directivity": "EDIR", "source match": "ESRM", "reflection tracking": "ERFT", # forward = (2, 1), reverse = (1, 2) "load match": "ELDM", "transmission tracking": "ETRT" "isolation": "EXTLK" """ self.active_channel = channel = kwargs.get("channel", self.active_channel) calname = kwargs.get("calname", "skrf_12term_cal") calibrations = self.scpi.query_calset_catalog(cnum=channel, form="NAME") if calname in calibrations: self.scpi.set_delete_calset(cnum=channel, calset_name=calname) self.scpi.set_create_calset(cnum=channel, calset_name=calname) cfs = dict() for coef, data in cal.coefs_12term.items(): cfs[coef] = skrf.mf.complex2Scalar(data) for eterm, coef in zip(("EDIR", "ESRM", "ERFT"), ("directivity", "source match", "reflection tracking")): self.scpi.set_calset_data(channel, eterm, port1, port1, eterm_data=cfs["forward " + coef]) self.scpi.set_calset_data(channel, eterm, port2, port2, eterm_data=cfs["reverse " + coef]) for eterm, coef in zip(("ELDM", "ETRT", "EXTLK"), ("load match", "transmission tracking", "isolation")): self.scpi.set_calset_data(channel, eterm, port2, port1, eterm_data=cfs["forward " + coef]) self.scpi.set_calset_data(channel, eterm, port1, port2, eterm_data=cfs["reverse " + coef]) self.scpi.set_active_calset(1, calname, True)
[docs] def get_snp_network(self, ports, **kwargs): """ return n-port network as an Network object Parameters ---------- ports : Iterable a iterable of integers designating the ports to query kwargs : dict channel(int), sweep(bool), name(str), f_unit(str), corrected(bool) Returns ------- Network general function to take in a list of ports and return the full snp network as a Network object """ self.resource.clear() # force activate channel to avoid possible errors: self.active_channel = channel = kwargs.get("channel", self.active_channel) sweep = kwargs.get("sweep", False) name = kwargs.get("name", "") f_unit = kwargs.get("f_unit", "GHz") raw_data = kwargs.get("raw_data", False) ports = [int(port) for port in ports] if type(ports) in (list, tuple) else [int(ports)] if not name: name = "{:}Port Network".format(len(ports)) if sweep: self.sweep(channel=channel) npoints = self.scpi.query_sweep_n_points(channel) snp_fmt = self.scpi.query_snp_format() self.scpi.set_snp_format("RI") if raw_data is True: if self.scpi.query_channel_correction_state(channel): self.scpi.set_channel_correction_state(channel, False) data = self.scpi.query_snp_data(channel, ports) self.scpi.set_channel_correction_state(channel, True) else: data = self.scpi.query_snp_data(channel, ports) else: data = self.scpi.query_snp_data(channel, ports) self.scpi.set_snp_format(snp_fmt) # restore the value before we got the RI data nrows = int(len(data) / npoints) nports = int(np.sqrt(nrows - 1)) data = data.reshape([nrows, -1]) fdata = data[0] sdata = data[1:] ntwk = skrf.Network() ntwk.frequency = skrf.Frequency.from_f(fdata, unit="Hz") ntwk.s = np.empty(shape=(sdata.shape[1], nports, nports), dtype=complex) for n in range(nports): for m in range(nports): i = n * nports + m ntwk.s[:, m, n] = sdata[i * 2] + 1j * sdata[i * 2 + 1] ntwk.frequency.unit = f_unit ntwk.name = name return ntwk
[docs] def get_list_of_traces(self, **kwargs): self.resource.clear() traces = [] channels = self.scpi.query_available_channels() for channel in channels: meas_list = self.scpi.query_meas_name_list(channel) if len(meas_list) == 1: continue # if there isnt a single comma, then there aren't any measurments parameters = dict([(meas_list[k], meas_list[k + 1]) for k in range(0, len(meas_list) - 1, 2)]) meas_numbers = self.scpi.query_meas_number_list() for mnum in meas_numbers: name = self.scpi.query_meas_name_from_number(mnum) item = {"name": name, "channel": channel, "measurement number": mnum, "parameter": parameters.get(name, name)} item["label"] = "{:s} - Chan{:},Meas{:}".format( item["parameter"], item["channel"], item["measurement number"]) traces.append(item) return traces
[docs] def get_traces(self, traces, **kwargs): """ retrieve traces as 1-port networks from a list returned by get_list_of_traces Parameters ---------- traces : list list of type that is exported by self.get_list_of_traces kwargs : dict sweep (bool), name_prefix (str) Returns ------- list a list of 1-port networks representing the desired traces Notes ----- There is no current way to distinguish between traces and 1-port networks within skrf """ self.resource.clear() sweep = kwargs.get("sweep", False) name_prefix = kwargs.get("name_prefix", "") if name_prefix: name_prefix += " - " channels = OrderedDict() for trace in traces: ch = trace["channel"] if ch not in channels.keys(): channels[ch] = { "frequency": None, "traces": list()} channels[ch]["traces"].append(trace) if sweep is True: self.sweep(channels=list(channels.keys())) traces = [] for ch, ch_data in channels.items(): frequency = ch_data["frequency"] = self.get_frequency() for trace in ch_data["traces"]: self.scpi.set_selected_meas_by_number(trace["channel"], trace["measurement number"]) sdata = self.scpi.query_data(trace["channel"], "SDATA") s = sdata[::2] + 1j * sdata[1::2] ntwk = skrf.Network() ntwk.s = s ntwk.frequency = frequency ntwk.name = name_prefix + trace.get("parameter", "trace") traces.append(ntwk) return traces
[docs] def get_frequency(self, **kwargs): """ get an skrf.Frequency object for the current channel Parameters ---------- kwargs : dict channel (int), f_unit (str) Returns ------- skrf.Frequency """ self.resource.clear() channel = kwargs.get("channel", self.active_channel) sweep_type = self.scpi.query_sweep_type(channel) if sweep_type in ["LIN", "LOG", "SEGM"]: freqs = self.scpi.query_sweep_data(channel) else: freqs = np.array([self.scpi.query_f_start(channel)]) frequency = skrf.Frequency.from_f(freqs, unit="Hz") frequency.unit = kwargs.get("f_unit", "Hz") return frequency
[docs] def set_frequency_sweep(self, f_start, f_stop, f_npoints, **kwargs): f_unit = kwargs.get("f_unit", "hz").lower() if f_unit != "hz": f_start = self.to_hz(f_start, f_unit) f_stop = self.to_hz(f_stop, f_unit) channel = kwargs.get("channel", self.active_channel) self.scpi.set_f_start(channel, f_start) self.scpi.set_f_stop(channel, f_stop) self.scpi.set_sweep_n_points(f_npoints)
[docs] def get_switch_terms(self, ports=(1, 2), **kwargs): self.resource.clear() p1, p2 = ports self.active_channel = channel = kwargs.get("channel", self.active_channel) measurements = self.get_meas_list() max_trace = len(measurements) for meas in measurements: # type: str try: trace_num = int(meas[0][-2:].replace("_", "")) if trace_num > max_trace: max_trace = trace_num except ValueError: pass forward_name = "CH{:}_FS_P{:d}_{:d}".format(channel, p1, max_trace + 1) reverse_name = "CH{:}_RS_P{:d}_{:d}".format(channel, p2, max_trace + 2) self.create_meas(forward_name, 'a{:}b{:},{:}'.format(p2, p2, p1)) self.create_meas(reverse_name, 'a{:}b{:},{:}'.format(p1, p1, p2)) self.sweep(channel=channel) forward = self.get_measurement(mname=forward_name, sweep=False) # type: skrf.Network forward.name = "forward switch terms" reverse = self.get_measurement(mname=reverse_name, sweep=False) # type: skrf.Network reverse.name = "reverse switch terms" self.scpi.set_delete_meas(channel, forward_name) self.scpi.set_delete_meas(channel, reverse_name) return forward, reverse
[docs] def get_measurement(self, mname=None, mnum=None, **kwargs): """ get a measurement trace from the analyzer, specified by either name or number Parameters ---------- mname : str the name of the measurement, e.g. 'CH1_S11_1' mnum : int the number of number of the measurement kwargs : dict channel (int), sweep (bool) Returns ------- skrf.Network """ if mname is None and mnum is None: raise ValueError("must provide either a measurement mname or a mnum") channel = kwargs.get("channel", self.active_channel) if type(mname) is str: self.scpi.set_selected_meas(channel, mname) else: self.scpi.set_selected_meas_by_number(channel, mnum) return self.get_active_trace_as_network(**kwargs)
[docs] def get_active_trace_as_network(self, **kwargs): """ get the active trace as a network object Parameters ---------- kwargs : dict channel (int), sweep (bool) Returns ------- skrf.Network """ channel = self.active_channel sweep = kwargs.get("sweep", False) if sweep: self.sweep(channel=channel) ntwk = skrf.Network() sdata = self.scpi.query_data(channel) ntwk.s = sdata[::2] + 1j * sdata[1::2] ntwk.frequency = self.get_frequency(channel=channel) return ntwk
[docs] def create_meas(self, mname, param, **kwargs): """ Create a new measurement trace on the analyzer Parameters ---------- mname: str name of the measurement **WARNING**, not all names behave well param: str analyzer parameter, e.g.: S11 ; a1/b1,1 ; A/R1,1 kwargs : dict channel(int) """ channel = kwargs.get("channel", self.active_channel) self.scpi.set_create_meas(channel, mname, param) self.display_trace(mname)
[docs] def display_trace(self, mname, **kwargs): """ Display measurement name on the analyzer display window Parameters: mname : str the name of the measurement, e.g. 'CH1_S11_1' kwargs : dict channel(int), window_n(int), trace_n(int), display_format(str) Keyword Arguments ---------------- display_format : str must be one of: MLINear, MLOGarithmic, PHASe, UPHase, IMAGinary, REAL, POLar, SMITh, SADMittance, SWR, GDELay, KELVin, FAHRenheit, CELSius """ channel = kwargs.get('channel', self.active_channel) window_n = kwargs.get("window_n", '') trace_n = kwargs.get("trace_n", max(self.scpi.query_window_trace_numbers(window_n)) + 1) display_format = kwargs.get('display_format', 'MLOG') self.scpi.set_display_trace(window_n, trace_n, mname) self.scpi.set_selected_meas(channel, mname) self.scpi.set_display_format(channel, display_format)
[docs] def get_meas_list(self, **kwargs): """ Convenience function to return a nicely arranged list of the measurement, parameter catalogue Parameters ---------- kwargs : dict channel : int Returns ------- list list of tuples of the form: (name, measurement) Return a list of measurement names on all channels. If channel is provided to kwargs, then only measurements for that channel are queried """ channel = kwargs.get("channel", self.active_channel) meas_list = self.scpi.query_meas_name_list(channel) if len(meas_list) == 1: return None # if there isnt a single comma, then there arent any measurments return [(meas_list[k], meas_list[k + 1]) for k in range(0, len(meas_list) - 1, 2)]
@property def ntraces(self): """ Get the number of traces on the active channel Returns ------- int The number of measurement traces that exist on the current channel Notes ----- Note that this may not be the same as the number of traces displayed because a measurement may exist, but not be associated with a trace. """ meas_list = self.scpi.query_meas_number_list(self.active_channel) return 0 if meas_list is None else len(meas_list)
class PNAX(PNA): NAME = "Keysight PNA-X" NPORTS = 4 NCHANNELS = 32