Thu, 02 Apr 2009 16:27:29 +0200
copyright updated
.. -*- coding: utf-8 -*- ============= Description ============= The code is organized in 2 layers; a low-level communication layer, and a highter level which allows to describe precisely a GPIB device, communicate asynchronously with it, etc. Low level ========= The low level communication process is managed by the module ``pygpibtoolkit.prologix``, in which there is a class names ``GPIB`` that knows how to initialize the GPIB device, send commands and receive data from the bus, perform GPIB polls, etc. Example:: from pygpibtoolkit.prologix import GPIB cnx = GPIB() # by default, it is the controller in charge idn = cnx.send_command("*IDN?", 12) # sends the idn command to device at GPIBaddress 12 print idn cnx.set_address(12) # we will talk to this device 12 for a while datablock = cnx.send_command('DDBN') if cnx.check_srq(): print "A Service Request has been sent" But that's basically it. You can send commands to devices, wait for an answer, check SRQ line. High level ========== The high level API is organized around a GPIB controller class (``pygpibtoolkit.gpibcontroller.GPIBController``) which is responsible for managing every connection stuff. It will run a thread responsible for communication processes, will regularly check SRQ line (and respond accordingly, with ability to register callbacks), etc. It will also provide a ``send_command`` method, but this latter will have a much higher means: the operation can be done synchronously or asynchronously (with a callback to call upon completion), etc. It will also hold device managers for found devices on the GPIB bus. Each device manager is a class responsible for communication specifically with a specified device. It will provide (if the device manager has been written) simple ways to send GPIB commands of the device; every GPIB command will be presented as a method of the manager. Talking with a device can then be as simple as:: from pygpibtoolkit.gpibcontroller import GPIBController c = GPIBController() devices = c.detect_devices() # devices is a dict which keys are the GPIB addresses # and values, the managers for each device hp3562 = devices[3] # ok, let's tell the HP3562 to put channel 1 in AC couplig mode, hp3562.C1AC("AC") # and put it in linear measure mode hp3562.LNRS() #EMEAS("LINEAR RES") # and Freq response mode hp3562.FRQR() # set span freq and center freq hp3562.FRS("10khz") hp3562.CF("7212hz") # then get the resulting trace data block trace = hp3562.DDBN() # which we can easily display header, data = hp3562.decode_trace(trace) import pylab pylab.plot(data) pylab.show() # ok, let's stop gracefully our cession c.stop()