Flying probe

In the testing of printed circuit boards, a flying probe test or fixtureless in-circuit test (FICT) system may be used for testing low to mid volume production, prototypes, and boards that present accessibility problems. A traditional "bed of nails" tester for testing a PCB requires a custom fixture to hold the PCBA and the Pogo pins which make contact with the PCBA. In contrast, FICT uses two or more flying probes, which may be moved based on software instruction.^[1] The flying probes are electro-mechanically controlled to access components on printed circuit assemblies (PCAs). The probes are moved around the board under test using an automatically operated two-axis system, and one or more test probes contact components of the board or test points on the printed circuit board. ^[2]

Flying probe testing is commonly used for test of analog components, analog signature analysis, and short/open circuits. They can be classified as in-circuit test (ICT) systems or as Manufacturing Defects Analyzers (MDAs). They provide an alternative to the bed-of-nails technique for contacting the components on printed circuit boards. The precision movement can probe points on integrated circuit packages without expensive fixturing or programming required.

The main advantage of flying probe testing is the substantial cost of a bed-of-nails fixture, costing on the order of US $20,000, is not required. The flying probes also allow easy modification of the test fixture when the PCBA design changes. FICT may be used on both bare or assembled PCB's.^[3] However, since the tester makes measurements serially, instead of making many measurements at once, the test cycle may become much longer than for a bed-of-nails fixture. A test cycle that may take 30 seconds on such a system, may take an hour with flying probes. Test coverage may not be as comprehensive as a bed of nails tester, because fewer points are tested at one time. ^[4]

Uses

4-wire Kelvin measurements
Analog component testing
Analog signature analysis
ATE diagnostics
Bare board test
Boundary scan testing
Flash programming
Functional test
Low Value Component testing
New Product Introduction
Open/short detection
Optical Inspection
Power-off testing
Power-on testing

Benefits of fixtureless in-circuit test

Automatic optical inspection for presence of components, correct polarity, and letters or numbers on ICs.
Value measurements on resistors, capacitors, Zener diodes and inductors.
IC open circuit checker finds lifted legs and dry joints on ICs.
Can test fine pitch printed circuit boards down to 0.3 mm with a repeatable accuracy of probe placement of ±0.05mm.
Test program is rapidly prepared from printed circuit board CAD data.
All major CAD platforms support FICT.

References

↑ Stephen F. Scheiber (2001). Building a Successful Board-test Strategy. Newnes. pp. 303–. ISBN 978-0-7506-7280-1.
↑ R. S. Khandpur, Printed Circuit Boards:Design, Fabrication, Assembly and Testing, Tata-McGraw Hill, ISBN 0070588147, 2005, page 572
↑ Keith Brindley (22 October 2013). Automatic Test Equipment. Elsevier. pp. 12–. ISBN 978-1-4831-0115-6.
↑ Alec Cohen, Prototype to Product: A Practical Guide for Getting to Market, O'Reilly, 2015, ISBN 1449362281, pp. 83, 84

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[Scheiber2001-1] Stephen F. Scheiber (2001). Building a Successful Board-test Strategy. Newnes. pp. 303–. ISBN 978-0-7506-7280-1.

[2] R. S. Khandpur, Printed Circuit Boards:Design, Fabrication, Assembly and Testing, Tata-McGraw Hill, ISBN 0070588147, 2005, page 572

[Brindley2013-3] Keith Brindley (22 October 2013). Automatic Test Equipment. Elsevier. pp. 12–. ISBN 978-1-4831-0115-6.

[4] Alec Cohen, Prototype to Product: A Practical Guide for Getting to Market, O'Reilly, 2015, ISBN 1449362281, pp. 83, 84