Stochastic approach to robust flight control design using hierarchy-structured dynamic inversion

Jun'Ichiro Kawaguchi; Tetsujiro Ninomiya; Yoshikazu Miyazawa

doi:10.2514/1.53257

Stochastic approach to robust flight control design using hierarchy-structured dynamic inversion

Jun'Ichiro Kawaguchi, Tetsujiro Ninomiya, Yoshikazu Miyazawa

Flight Dynamics Lab

Research output: Contribution to journal › Article › peer-review

15 Citations (Scopus)

Abstract

The stochastic approach to robust flight control design using hierarchy-structured dynamic inversion (HSDI) was examined. Intensive robustness evaluation by root sum square (RSS) and Monte Carlo simulation (MCS) was performed using an elaborate nonlinear model of a subscale reentry vehicle, which revealed the HSDI autoland controller to be as robust as the baseline linear robust controller. Touchdown robustness was finally enhanced by a stochastic optimization scheme using the downhill simplex method combined with MCS evaluation. The optimization results showed that the HSDI autoland controller realized better touchdown robustness due to the simultaneous tuning of its guidance and control parameters. An HSDI-based flight control design methodology reduces design cost due to its easy-to-tune control structure and has sufficient robustness for practical applications in industry.

Original language	English
Pages (from-to)	1573-1577
Number of pages	5
Journal	Journal of Guidance, Control, and Dynamics
Volume	34
Issue number	5
DOIs	https://doi.org/10.2514/1.53257
Publication status	Published - 2011

All Science Journal Classification (ASJC) codes

Control and Systems Engineering
Aerospace Engineering
Space and Planetary Science
Electrical and Electronic Engineering
Applied Mathematics

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10.2514/1.53257

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abstract = "The stochastic approach to robust flight control design using hierarchy-structured dynamic inversion (HSDI) was examined. Intensive robustness evaluation by root sum square (RSS) and Monte Carlo simulation (MCS) was performed using an elaborate nonlinear model of a subscale reentry vehicle, which revealed the HSDI autoland controller to be as robust as the baseline linear robust controller. Touchdown robustness was finally enhanced by a stochastic optimization scheme using the downhill simplex method combined with MCS evaluation. The optimization results showed that the HSDI autoland controller realized better touchdown robustness due to the simultaneous tuning of its guidance and control parameters. An HSDI-based flight control design methodology reduces design cost due to its easy-to-tune control structure and has sufficient robustness for practical applications in industry.",

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AU - Kawaguchi, Jun'Ichiro

AU - Ninomiya, Tetsujiro

AU - Miyazawa, Yoshikazu

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AB - The stochastic approach to robust flight control design using hierarchy-structured dynamic inversion (HSDI) was examined. Intensive robustness evaluation by root sum square (RSS) and Monte Carlo simulation (MCS) was performed using an elaborate nonlinear model of a subscale reentry vehicle, which revealed the HSDI autoland controller to be as robust as the baseline linear robust controller. Touchdown robustness was finally enhanced by a stochastic optimization scheme using the downhill simplex method combined with MCS evaluation. The optimization results showed that the HSDI autoland controller realized better touchdown robustness due to the simultaneous tuning of its guidance and control parameters. An HSDI-based flight control design methodology reduces design cost due to its easy-to-tune control structure and has sufficient robustness for practical applications in industry.

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Stochastic approach to robust flight control design using hierarchy-structured dynamic inversion

Abstract

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