论文信息 - LINEAR-QUADRATIC-REGULATOR POINTING CONTROL SYSTEM FOR A HIGH-ALTITUDE BALLOON PAYLOAD

LINEAR-QUADRATIC-REGULATOR POINTING CONTROL SYSTEM FOR A HIGH-ALTITUDE BALLOON PAYLOAD

A pointing control system design for the science package of a NASA high-altitude research balloon is described. The balloon assembly consists of a single helium balloon connected to a payload recovery parachute, payload gondola, and ballast hopper. Pointing of the scientific payload is accomplished via an arrangement of drive motors and a flywheel. Linear quadratic regulator (LQR) synthesis techniques are employed to produce the azimuth and elevation controller designs. The use of LQR synthesis is motivated by the azimuthal dynamic coupling encountered between the balloon and gondola. Two control devices are employed in azimuth, one of which is a decoupler motor and the other a flywheel. The decoupler motor is intended to isolate the gondola from the balloon such that the flywheel can be accelerated or decelerated about a steady-state angular velocity to provide precise azimuthal pointing. The multiple-input/multiple-output nature of the azimuth pointing problem is best handled in a matrix synthesis procedure such as LQR. The controller design methodology is explained, and a combination of time responses and singular value analyses are used to analytically evaluate the performance of the control system. 11 refs., 17 figs.

John E. White | Jerry R. Etter | J. White | J. Etter

[1] Michael Athans,et al. Correspondence item: On the design of P-I-D controllers using optimal linear regulator theory , 1971 .

[2] Michael K. Sain,et al. Guest editorial: On linear multivariable control systems , 1981 .

[3] G. Stein,et al. Multivariable feedback design: Concepts for a classical/modern synthesis , 1981 .

[4] Michael Athans,et al. Gain and phase margin for multiloop LQG regulators , 1976, 1976 IEEE Conference on Decision and Control including the 15th Symposium on Adaptive Processes.

[5] M. Safonov,et al. Exact calculation of the multiloop stability margin , 1988 .

[6] M. Athans,et al. Robustness results in linear-quadratic Gaussian based multivariable control designs , 1981 .

[7] Arthur E. Bryson,et al. Applied Optimal Control , 1969 .

[8] J. E. White,et al. Stability augmentation for a free flying ducted fan , 1987 .

[9] Jason L. Speyer,et al. Multi-input/multi-output controller design for longitudinal decoupled aircraft motion , 1984 .

[10] Blaise Morton. New applications of mu to real-parameter variation problems , 1985, 1985 24th IEEE Conference on Decision and Control.