PXI

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This is the article about electronic instrumentation platform, PXI. For the comic by Dan Kim, see Paper Eleven.

PXI is one of several electronic instrumentation platforms in current use. These platforms are used as a basis for building electronic test equipment or automation systems, such as might be used in a mobile phone manufacturing test environment. Based on industry-standard computer buses and loaded up with extra features to facilitate electronic test, they permit a great deal of flexibility in building the exact test equipment or automation system required. Often they are fitted with custom software to manage the system.

1 PXI Systems Alliance
2 PXI Overview
3 PXI Express
4 References
5 External links

[edit] PXI Systems Alliance

PCI eXtensions for Instrumentation (PXI) is a modular instrumentation platform originally introduced in 1997 by National Instruments. PXI is promoted by the 59 member PXI Systems Alliance (PXISA), whose sponsor members are (in alphabetical order) ADLink, ASCOR, Geotest, National Instruments, Pickering Interfaces and Teradyne.

Executive Members of the alliance include Acqiris (acquired by Agilent Nov 2006[1]), Aeroflex, Alfautomazione, CHROMA ATE Inc, Elma Electronic, GOEPEL electronic, MAC Panel, PXIT (acquired by Agilent Nov 2006 [2]), EADS NA Defence, Virginia Panel Corp, and ZTEC. Another 40 associate member organizations that do not have voting rights are supporting PXI and use the PXI logo on their products and marketing material.

[edit] PXI Overview

PXI is designed for measurement and automation applications that require high-performance and a rugged industrial form-factor. With PXI, you can select the modules from a large number of vendors and easily integrate them into a single PXI system, over 1150 module types available in 2006. A typical 3U PXI module measures approximately 4x6 inches (100x160mm) in size, and a typical 8-slot PXI chassis is 4U high and half rack width, full width chassis contain up to 18 PXI slots.

PXI uses PCI-based technology and an industry standard governed by the PXI Systems Alliance (PXISA) to ensure standards compliance and system interoperability. There are PXI modules available for almost every conceivable test, measurement, and automation application, from the ubiquitous switching modules and DMMs of Pickering Interfaces, to high performance microwave vector signal generation and analysis capability provided by companies such as Aeroflex and National Instruments. There are also companies specializing in writing software for PXI modules, as well as companies providing PXI hardware-software integration services.

PXI is based on CompactPCI and it offers all of the benefits of the PCI architecture including performance, industry adoption, COTS technology. PXI adds a rugged CompactPCI mechanical form-factor, an industry consortium that defines hardware, electrical, software, power and cooling requirements, leaving nothing to chance. Then PXI adds integrated timing and synchronization that is used to route synchronization clocks, and triggers internally. PXI is a future-proof technology, and is designed to be simply and quickly reprogrammed as test, measurement, and automation requirements change.

Most PXI instrument modules are register-based products, which use software drivers hosted on a PC to configure them as useful instruments, taking advantage of the increasing power of PCs to improve hardware access and simplify embedded software in the modules. The open architecture allows hardware to be reconfigured to provide new facilities and features that are difficult to emulate in comparable bench instruments. PXI system data bandwidth performance easily exceeds the performance of the older VXI test standard. There is debate within the technical community as to whether newer standards such as LXI will surpass PXI in both performance and overall cost of ownership.

PXI modules providing the instrument functions are plugged into a PXI chassis which may include its own controller running an industry standard Operating System such as Windows XP, Windows 2000, or even Linux (which is not yet PXISA approved), or a PCI to PXI bridge that provides a high speed link to a desktop PC controller. Likewise, multiple PXI racks can be linked together with PCI bridge cards, to build very large systems such as multiple source microwave signal generator test stands for complex ATE applications.

CompactPCI and PXI products are interchangeable, i.e. they can be used in either CompactPCI or PXI chassis, but installation in the alternate chassis type may limit the functionality of certain bus-specific features. So for example you could mount a CompactPCI Network interface controller in a PXI rack to provide additional network interface functions to a test stand.

[edit] PXI Express

Image:PXI Express Hybrid Backplane Image.gif

PXI Express Hybrid Backplane.

The PXI Systems Alliance (PXISA) has passed specification PXI-5, which specifies how to integrate PCI Express performance into both CompactPCI and PXI while preserving backward compatibility. Because PXI is based on CompactPCI, work began first on CompactPCI Express in early 2004. The CompactPCI Express specification defines the fundamental mechanical and electrical features of CompactPCI Express systems and, therefore, PXI Express systems. This includes the selection of connectors to support PCI Express, definitions of slots and board mechanicals, definitions of slot/board electrical signals, and compliance-testing requirements. The CompactPCI Express specification was released on June 27, 2005 and the PXI Express specification was completed in August 2005. PXI Express incorporates CompactPCI Express technology with enhancements for PXI compatibility, timing and synchronization, and system software frameworks.

The attached figure shows the basic layout of a CompactPCI/PXI Express backplane and illustrates how PCI Express is integrated into backplanes while preserving compatibility with current PXI modules. PCI Express electrical lanes run from the system slot (either an embedded controller or MXI link) to the hybrid slots, providing a high-bandwidth path from the controller to the backplane slots. In addition, the installation of an inexpensive PCI Express-to-PCI bridge on backplanes provides PCI signaling to all PXI and PXI Express hybrid slots. This ensures compatibility with PXI modules on the backplane. The system controller slot is capable of supporting up to a x16 PCI Express link, plus a x8 link, providing a total of 6 GB/s bandwidth to the PXI backplane. This is a more than 45 times improvement in PXI backplane throughput.

A key new feature is the PXI Express hybrid slot, which delivers support for both PCI and PCI Express signaling by taking advantage of available pins on the high-density backplanes. This creates a level of backward compatibility not available in even desktop PC card-edge connectors. In this hybrid peripheral slot, you can install PXI modules that use PCI signaling, as well as future high-performance PXI Express modules, in the same slot. However PXI modules that have implemented the J2 backplane connector require minor factory modification by the instrument vendor to allow operation in the PXI Express hybrid slot (the majority of PXI cards implement J2)([3]).

PCI Express uses the same driver and OS model as PCI, which ensures complete software compatibility among PCI-based systems (such as PXI) and PCI Express-based systems (for example, PCI Express). Neither vendors nor customers need to revise driver software or application software for PCI Express-based systems. Therefore, in addition to providing hardware compatibility through the hybrid slot, PXI Express systems also help engineers preserve existing software investments.

Availability of PXI Express products is limited at present (Oct 2006) to less than 10 modules, chassis and controllers, however this is likely to rise when PXI Express gains momentum in high data bandwidth applications.