Enhanced predictor–corrector Mars entry guidance approach with atmospheric uncertainties

Due to the long-range data communication and complex Mars environment, the Mars lander needs to promote the ability to autonomously adapt uncertain situations ensuring high precision landing in future Mars missions. Based on the analysis of multiple disturbances, this study demonstrates an enhanced...

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Bibliographic Details
Published in:IET control theory & applications Vol. 13; no. 11; pp. 1612 - 1618
Main Authors: Jianwei, Xu, Jianzhong, Qiao, Lei, Guo, Wenhua, Chen
Format: Journal Article
Language:English
Published: The Institution of Engineering and Technology 23.07.2019
Subjects:
aerospace control
atmospheric uncertainties
complex Mars environment
composite guidance method
enhanced predictor–corrector guidance method
enhanced predictor–corrector Mars entry guidance approach
entry, descent and landing (spacecraft)
future Mars missions
high precision landing
long‐range data communication
Mars
Mars lander entry guidance system
Mars lander guidance system
Mars landing
predictor‐corrector methods
predictor–corrector guidance algorithm
Research Article
space vehicles
long-range data communication
Mars lander guidance system
entry, descent and landing (spacecraft)
composite guidance method
high precision landing
aerospace control
space vehicles
atmospheric uncertainties
predictor–corrector guidance algorithm
enhanced predictor–corrector guidance method
enhanced predictor–corrector Mars entry guidance approach
Mars
complex Mars environment
future Mars missions
Mars lander entry guidance system
Mars landing
predictor-corrector methods
ISSN:1751-8644, 1751-8652
Online Access:Get full text
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Summary:Due to the long-range data communication and complex Mars environment, the Mars lander needs to promote the ability to autonomously adapt uncertain situations ensuring high precision landing in future Mars missions. Based on the analysis of multiple disturbances, this study demonstrates an enhanced predictor–corrector guidance method to deal with the effect of atmospheric uncertainties during the entry phase of the Mars landing. In the proposed method, the predictor–corrector guidance algorithm is designed to autonomously drive the Mars lander to the parachute deployment. Meanwhile, the disturbance observer is designed to onboard estimate the effect of fiercely varying atmospheric uncertainties resulting from rapidly height decreasing. Then, with the estimation of atmospheric uncertainties compensated in the feed-forward channel, the composite guidance method is put forward such that both anti-disturbance and autonomous performance of the Mars lander guidance system are improved. Convergence of the proposed composite method is analysed. Simulations for a Mars lander entry guidance system demonstrates that the proposed method outperforms the baseline method in consideration of the atmospheric uncertainties.
ISSN:1751-8644
1751-8652
DOI:10.1049/iet-cta.2018.5782