A full Python driver for the Keithley 2600B series of source measurement units. An accompanying GUI is provided by the sister project keithleygui. Documentation is available at https://keithley2600.readthedocs.io.
This driver provides access to base commands and higher level functions such as IV measurements, transfer and output curves, etc. Base commands replicate the functionality and syntax from the Keithley's internal TSP Lua functions. This is possible because the Lua programming language has a very limited syntax which can be represented by a subset of Python syntax.
All Keithley commands are dynamically queried from the Keithley itself after a successful connection. This means that essentially all Keithley instruments which use TSP scripting are supported and any commands introduced in the future will be recognised automatically (barring changes to the Lua syntax itself). Please refer to the respective reference manuals for a list of commands available on a particular model, for instance the Keithley 2600B reference manual.
This dynamic approach however means that most attributes will only be defined after connecting to an instrument. Several higher level functions for current-voltage sweeps are defined by the driver itself and may use functionality which is not available on some models. They have been tested with a Keithley 2612B.
Warning: There are currently no checks for allowed arguments by the driver itself.
Passing invalid arguments to a Keithley command will fail silently in Python but will
display an error message on the Keithley itself. To enable command checking, set the
keyword argument raise_keithley_errors = True
in the constructor. When set, most
Keithley errors will be raised as Python errors. This is done by reading the Keithley's
error queue after every command and will therefore result in some communication
overhead.
Install the stable version from PyPi by running
$ pip install keithley2600
or the latest development version from GitHub:
$ pip install git+https://github.com/OE-FET/keithley2600
Connect to the Keithley 2600 and perform some base commands:
from keithley2600 import Keithley2600
k = Keithley2600('TCPIP0::192.168.2.121::INSTR')
k.smua.source.output = k.smua.OUTPUT_ON # turn on SMUA
k.smua.source.levelv = -40 # sets SMUA source level to -40V
v = k.smua.measure.v() # measures and returns the SMUA voltage
i = k.smua.measure.i() # measures current at smuA
k.smua.measure.v(k.smua.nvbuffer1) # measures the voltage, stores the result in buffer
k.smua.nvbuffer1.clear() # clears nvbuffer1 of SMUA
Higher level commands defined in the driver:
data = k.read_buffer(k.smua.nvbuffer1) # reads all entries from nvbuffer1 of SMUA
errs = k.read_error_queue() # gets all entries from error queue
k.set_integration_time(k.smua, 0.001) # sets integration time in sec
k.apply_voltage(k.smua, 10) # turns on and applies 10V to SMUA
k.apply_current(k.smub, 0.1) # sources 0.1A from SMUB
k.ramp_to_voltage(k.smua, 10, delay=0.1, stepSize=1) # ramps SMUA to 10V in steps of 1V
# sweep commands
k.voltage_sweep_single_smu(
k.smua, range(0, 61), t_int=0.1, delay=-1, pulsed=False
)
k.voltage_sweep_dual_smu(
smu1=k.smua,
smu2=k.smub,
smu1_sweeplist=range(0, 61),
smu2_sweeplist=range(0, 61),
t_int=0.1,
delay=-1,
pulsed=False,
)
k.transfer_measurement( ... )
k.output_measurement( ... )
Singleton behaviour:
Once a Keithley2600 instance with a visa address 'address'
has been created, repeated
calls to Keithley2600('address')
will return the existing instance instead of creating
a new one. This prevents the user from opening multiple connections to the same
instrument simultaneously and allows easy access to a Keithley2600 instance from
different parts of a program. For example:
>>> from keithley2600 import Keithley2600
>>> k1 = Keithley2600('TCPIP0::192.168.2.121::INSTR')
>>> k2 = Keithley2600('TCPIP0::192.168.2.121::INSTR')
>>> print(k1 is k2)
True
Data structures:
The methods voltage_sweep_single_smu
and voltage_sweep_dual_smu
return lists with
the measured voltages and currents. The higher level commands transfer_measurement
and
output_measurement
return ResultTable
objects which are somewhat similar to pandas
dataframes but include support for column units. ResultTable
stores the measurement
data internally as a numpy array and provides information about column titles and units.
It also provides a dictionary-like interface to access columns by name, methods to load
and save the data to text files, and live plotting of the data (requires matplotlib).
For example:
import time
from keithley2600 import Keithley2600, ResultTable
k = Keithley2600('TCPIP0::192.168.2.121::INSTR')
# create ResultTable with two columns
rt = ResultTable(
column_titles=['Voltage', 'Current'],
units=['V', 'A'],
params={'recorded': time.asctime(), 'sweep_type': 'iv'},
)
# create live plot which updates as data is added
rt.plot(live=True)
# measure some currents
for v in range(0, 20):
k.apply_voltage(k.smua, 10)
i = k.smua.measure.i()
rt.append_row([v, i])
# save the data
rt.save('~/iv_curve.txt')
See the documentation for all available methods.
keithley2600 uses PyVISA to connect to instruments.
PyVISA supports both proprietray IVI libraries such as NI-VISA, Keysight VISA, R&S VISA,
tekVISA etc. and the purely Python backend PyVISA-py.
You can select a specific backend by giving its path to the Keithley2600
constructor
in the visa_library
argument. For example:
from keithley2600 import Keithley2600
k = Keithley2600('TCPIP0::192.168.2.121::INSTR', visa_library='/usr/lib/libvisa.so.7')
keithley2600 defaults to using the PyVISA-py backend, selected by visa_library='@py'
,
since this is only a pip-install away. If you pass an empty string, keithley2600 will
use an installed IVI library if it can find one in standard locations or fall back to
PyVISA-py otherwise.
You can find more information about selecting the backend in the PyVISA docs.
- Python 3.6 or higher
-
API documentation of keithley2600: https://keithley2600.readthedocs.io/en/latest/
-
Keithley 2600 reference manual with all commands: https://www.tek.com/keithley-source-measure-units/smu-2600b-series-sourcemeter-manual-8