A survey on artificial intelligence trends in spacecraft guidance dynamics and control

Izzo, Dario; Märtens, Marcus; Pan, Binfeng

doi:10.1007/s42064-018-0053-6

Cited by 186 publications

(69 citation statements)

References 63 publications

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“…For a spacecraft, this could arise from orbit determination uncertainties or thruster misalignment. There is significant interest in the applications of RL for mission design, operations, guidance and control to navigation and even the prediction of the dynamics [20]. However, little work has combined RL with existing control laws for trajectory design, which would result in powerful state-dependent learning process on top of an intelligent controller.…”

Section: B Reinforcement Learning Overviewmentioning

confidence: 99%

“…One method of achieving this is using evolutionary algorithms (EAs). The multi-objective nature of spacecraft trajectory design lends itself to EAs and they still provide many of the benchmarks in the area [20]. Both Lee et al 2005 [8] and Varga et al 2016 [9] used a multi-objective genetic algorithm to optimise the Q-law design parameters for a variety of Earth orbit transfers, with the design parameters remaining fixed throughout the transfer.…”

Section: Introductionmentioning

confidence: 99%

“…Reinforcement learning is a promising alternative increasingly used in astrodynamics [20]. Gaudet, Furfaro and Linares have demonstrated the capability of RL for use in Mars landers [22] and asteroid hovering missions [23].…”

Section: Introductionmentioning

confidence: 99%

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Low-Thrust Trajectory Design Using Closed-Loop Feedback-Driven Control Laws and State-Dependent Parameters

Holt

Armellín

Scorsoglio

et al. 2020

AIAA Scitech 2020 Forum

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Low-thrust many-revolution trajectory design and orbit transfers are becoming increasingly important with the development of high specific impulse, low-thrust engines. Closed-loop feedback-driven (CLFD) control laws can be used to solve these trajectory design problems with minimal computational cost and offer potential for autonomous guidance. However, they have user-defined parameters which limit their optimality. In this work, an actor-critic reinforcement learning framework is proposed to make the parameters of the Lyapunov-based Q-law state-dependent, ensuring the controller can adapt as the dynamics evolve during a transfer. The proposed framework should be independent of the particular CLFD control law and provides improved solutions for mission analysis. There is also potential for future on-board autonomous use, as trajectories are closed-form and can be generated without an initial guess. The current results focus on GTO-GEO transfers in Keplerian dynamics and later with eclipse and J 2 effects. Both time-optimal and mass-optimal transfers are presented, and the stability to uncertainties in orbit determination are discussed. The task of handling orbit perturbations is left to future work.

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Section: B Reinforcement Learning Overviewmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Low-Thrust Trajectory Design Using Closed-Loop Feedback-Driven Control Laws and State-Dependent Parameters

Holt

Armellín

Scorsoglio

et al. 2020

AIAA Scitech 2020 Forum

View full text Add to dashboard Cite

show abstract

“…Tracking space targets is beneficial for orbital garbage removal, recovery of important components, and early warning of space threats [1]. However, with the continuous development of space techniques, the targets in space have been expanded from non-maneuverable ones to maneuverable ones.…”

Section: Introductionmentioning

confidence: 99%

A Pre-Trained Fuzzy Reinforcement Learning Method for the Pursuing Satellite in a One-to-One Game in Space

Wang

Shi

Zhao

et al. 2020

Sensors

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In order to help the pursuer find its advantaged control policy in a one-to-one game in space, this paper proposes an innovative pre-trained fuzzy reinforcement learning algorithm, which is conducted in the x, y, and z channels separately. Compared with the previous algorithms applied in ground games, this is the first time reinforcement learning has been introduced to help the pursuer in space optimize its control policy. The known part of the environment is utilized to help the pursuer pre-train its consequent set before learning. An actor-critic framework is built in each moving channel of the pursuer. The consequent set of the pursuer is updated through the gradient descent method in fuzzy inference systems. The numerical experimental results validate the effectiveness of the proposed algorithm in improving the game ability of the pursuer.

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“…The use of deep neural networks (DNNs) for the guidance navigation and control of space systems (spacecraft, landers, etc..) is a prolific area of research as witnessed by the increasing number of results that appeared recently on these topics [9,11,3,12,4,6,14]. Most of this body of work can be divided into DNNs approximating the optimal policy u (e.g.…”

Section: Introductionmentioning

confidence: 99%

Interplanetary transfers via deep representations of the optimal policy and/or of the value function

Izzo

Öztürk

Märtens

2019

Proceedings of the Genetic and Evolutionary Computation Conference Companion

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A number of applications have been recently proposed based on deep networks and interplanetary trajectories. These approaches often rely on the availability of a large number of optimal trajectories to learn from. In this paper we introduce a new method to quickly create millions of optimal spacecraft trajectories from a single nominal trajectory. Apart from the generation of the nominal trajectory, no additional optimal control problems need to be solved as all the trajectories, by construction, satisfy Pontryagin's minimum principle and the relevant transversality conditions. We then consider deep feed forward neural networks and benchmark three learning methods on the created dataset: policy imitation, value function learning and value function gradient learning. Our results are shown for the case of the interplanetary trajectory optimization problem of reaching Venus orbit, with the nominal trajectory starting from the Earth. We find that both policy imitation and value function gradient learning are able to learn the optimal state feedback, while in the case of value function learning the optimal policy is not captured, only the final value of the optimal propellant mass is.

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A survey on artificial intelligence trends in spacecraft guidance dynamics and control

Cited by 186 publications

References 63 publications

Low-Thrust Trajectory Design Using Closed-Loop Feedback-Driven Control Laws and State-Dependent Parameters

Low-Thrust Trajectory Design Using Closed-Loop Feedback-Driven Control Laws and State-Dependent Parameters

A Pre-Trained Fuzzy Reinforcement Learning Method for the Pursuing Satellite in a One-to-One Game in Space

Interplanetary transfers via deep representations of the optimal policy and/or of the value function

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