Inactive-Reserved Standard

IEEE 1431-2004

IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros

Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis CVG is provided. A compilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation.

Sponsor Committee
AES/GA - Gyro Accelerometer Panel
Status
Inactive-Reserved Standard
PAR Approval
2003-10-30
Corrigendum
1431-2004/Cor 1-2008
Board Approval
2004-03-25
History
ANSI Approved:
2004-07-08
Published:
2004-12-20
Reaffirmed:
2010-03-25
Inactivated Date:
2021-03-25

Working Group Details

Society
IEEE Aerospace and Electronic Systems Society
Sponsor Committee
AES/GA - Gyro Accelerometer Panel
Working Group
SENSR_WG - Sensors Working Group
IEEE Program Manager
Malia Zaman
Contact Malia Zaman
Working Group Chair
Jason Bingham

Other Activities From This Working Group

Current projects that have been authorized by the IEEE SA Standards Board to develop a standard.


P1431
Standard for Specifying and Testing Coriolis Vibratory Gyros

This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation.

Learn More About P1431

P836
Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers

This recommended practice describes the conduct and analysis of precision tests for linear accelerometers using centrifuge techniques. The term “precision,” in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to tests conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer's model equation, except for bias and scale factor, which are most accurately determined by static multiposition tests. Alternatively, evaluation may establish only that the accelerometer output complies with specific error limit criteria.

Learn More About P836

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These standards have been replaced with a revised version of the standard, or by a compilation of the original active standard and all its existing amendments, corrigenda, and errata.


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