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Perfect vision: adoption of the Camera Link standard addresses challenges for machine vision designers.

In many quality control operations, the human eye has been replaced by the unblinking lens of the digital camera. A machine vision (MV) system is intended for non-contact optical sensing and is ideal for use in quality control (QC) systems for quality assurance (QA). Industries exploiting MV include automotive component manufacturing, electronics assembly, semiconductor production, food processing and pharmaceuticals manufacturing.

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An electronic MV system consists of hardware and software, which automatically receives and interprets images of an object against a pre-determined standard. A camera captures the image. The camera is connected by a cable to a frame grabber--a logic board that turns the data stream received from the camera into a format suitable for image processing. The frame grabber is often PCIbus so that it can be used in a standard PC, but it can also be designed for a card cage system, such as VME. A display shows the images in real time to the human operator.

However, in an industrial setting, machine vision presents challenges unique and separate from traditional camera or PC applications. An industrial machine vision system may endure incessant vibration. Cables connecting the camera to the frame grabber board may have to span long distances. The system elements (camera, frame grabber, PC) may be far apart yet run on low voltage without a separate power source. And the designer often runs into interconnect compatibility issues.

A Solution to Design Challenges

Some of those design challenges have been addressed by the creation of an industry standard for machine vision connectivity. Until recently, most cameras and frame grabber boards were equipped with proprietary interfaces. Even if the camera shared the same style of physical interface as the frame grabber board, such as D-Sub connectors, the pin-out and wiring configuration between equipment may not have been compatible. The result was systems that sometimes party functioned or not at all, and a need for ongoing support by the system integration or maintenance/repair organization.

To address this issue, the Automated Imaging Association (AIA) began work in the late 1990s to establish a standard. The result of that industry-wide collaboration was the Camera Link standard, which provides a common communication interface for makers and users of cameras and frame grabbers for MV systems. Version 1.1 of the Camera Link standard was published in January 2004.

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Defining the Standard

The standard prescribes the transmission method (video data, control signals, communications and power) and the connectors and cabling (pin assignments, mechanical and electrical characteristics) for digital cameras and frame grabbers. The primary benefit of using a common interface is the assured interoperability between compatible equipment from different vendors, reducing support time and cost.

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The Camera Link standard is based on the low-voltage differential signaling (LVDS) protocol defined in ANSI/TIA/EIA-644, approved in 196 and popularized as National Semiconductor's Channel Link platform. LVDS enables engineers to design systems able to deliver clean, high-speed signals over long distances with a low power budget. Channel Link chipsets are capable of data transmission rates up to 2.380 Gigabits per second.

The standard provides for three configurations:

* Base: one Channel Link chip plus camera control plus serial communications (full duplex communication channel, four high speed data lines, four slow speed camera control lines, clocks for LVDS signals) supporting A, B and C ports;

* Medium: two Channel Link chips (full duplex serial channel, eight high speed channels, four drain wires, no camera control) supporting A, B, C, D, E and F ports;

* Full: same as medium but supporting A, B, C, D, E, F, G and H ports.

Applying the Standard

The Camera Link standard requires fewer conductors to transfer data. Just five pairs of wires can transmit up to 28 bits of data. The low number of wires enabled the AIA to reduce the size of the connector. In collaborating on the development of the Camera Link standard, 3M Company and National Semiconductor worked closely to test and define the performance of high-speed connectors and cables for LVDS transmission.

Appendix D (V1.2) of January 2007 of the standard defines two Camera Link connectors:

* Standard: a 26-position two-row shielded ribbon style connector on 1.270 mm (0.050") spacing;

* Miniature (popularly referred to as Mini Camera Link [TM]): a 26-position two-row shielded ribbon style connector on 0.800 mm (0.031") spacing.

Both styles of connector have 360[degrees] D-shaped metal shells that provide protection from EMI/RFI and assure correct orientation prior to mating. The receptacle connectors feature twp jacksockets, which receive thumbscrews on the mating plugs, to assure a robust connection in high vibration environments.

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Conclusion

Wide industry support of the AIA Camera Link standard by vendors and users greatly simplifies the process of selecting equipment and setting up MV system. QC managers having modest budgets can use the base configuration to build good MV systems, while those with greater means can implement the full configuration to collect and analyze a variety of information in real time. Both can benefit from the availability of off-the-shelf equipment and cables, safe in the knowledge that the Camera Link standard assures interoperability and that the results will be picture perfect.

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by P. Lindsay Powell, 3M Electronic Solutions Division

Lindsay Powell is a graduate of the University of Aston in Birmingham, England. He has worked for 3M in the electronics industry for over 20 years in Europe and the United States. Contact 3M at 800-328-1368; interconnectsinquiry@mmm.com; www.3m.com/interconnects.
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Title Annotation:Industrial Communications
Author:Powell, P. Lindsay
Publication:ECN-Electronic Component News
Date:Nov 15, 2008
Words:920
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