A new generation of IRS with innovative architecture based on HRG for satellite launch vehicles
https://doi.org/10.17285/0869-7035.2016.24.1.049-059
Abstract
The satellite launch vehicles’ evolution goes through a reduction of cost, weight and size of the IRS (Inertial Reference System), while keeping a very high level of performance and safety compatible with this kind of application. The classic approach leads to duplicate this equipment, so assuring a first level redundancy. But this solution is not favourable considering the previous criteria (cost, weight, size) and does not allow detecting a possible slow drift of performance of one of the two IRS because there is no possible majority vote. The approach proposed in this paper is based on a multisensor architecture, integrating 6 gyroscopes and 6 accelerometers, with a triplication of the common functions, which allows using a non-radiation hardened electronics. This integrated architecture facilitates the implementation of FDI techniques (Fault Detection and Isolation), and withstands straight failures and performance drifts of the inertial sensors, the whole being integrated into a single equipment, which allows reducing drastically cost, weight and size. In this context, the use of HRG (Hemispherical Resonant Gyroscope) is particularly relevant because of its low size and weight. As a result, the proposed architecture allows reaching high levels of accuracies, which makes it capable of a wide range of missions. This paper details the proposed inertial and electronic architecture, demonstrates the techniques used for the FDI function and shows the contribution of the HRG for this kind of architecture in terms of accuracy, safety and size.
About the Authors
C. NegriFrance
E. Labarre
France
C. Lignon
France
E. Brunstein
France
E. Salaün
France
References
1. Camberlein L., Nicaise, P. A redundant strapdown reference for advanced aircraft flight control systems, Gyro Symposium, Stuttgart, Germany, 1984.
2. Pittelkau M. E. Attitude Determination and Calibration with Redundant Inertial Measurement Units, Journal of Guidance, Control, and Dynamics, 2004, vol. 28, no.4.
3. Yuksel Y. Design and Analysis of Inertial Navigation Systems with Skew Redundant Inertial Sensors, Thesis, University of Calgary, 2011.
4. Schwank J. R., Ferlet-Cavrois V., Shanyfelt M. R., Paillet P., Dodd P. E. Radiation Effects in SOI Technologies, IEEE Transactions on Nuclear Science, 2003, vol. 50, no. 3.
5. Lignon C., Carre A. Measurement by gyroscopic system, Patent US7997134 B2, 2011.
6. Remillieux G., Delhaye F. Sagem Coriolis Vibrating Gyros: a vision realized, Inertial Sensors and Systems. Karlsruhe, Germany, 2014.
Review
For citations:
Negri C., Labarre E., Lignon C., Brunstein E., Salaün E. A new generation of IRS with innovative architecture based on HRG for satellite launch vehicles. Giroskopiya i Navigatsiya. 2016;24(1):49-59. (In Russ.) https://doi.org/10.17285/0869-7035.2016.24.1.049-059
JATS XML



