论文信息 - Optimal phase angle design for the lunar lander

Optimal phase angle design for the lunar lander

To design the optimal lunar landing trajectory, the periapsis of de-orbit burn phase is usually used as a starting point of the powered descent phase. And the optimal problem is constructed based on the initial states at this point. For this optimal problem, some kinds of result trajectories have the increase in their own altitude at the early stage to earn the enough time to reduce their huge horizontal velocity for the low thrust, and this phenomenon increase the consumption of the propellant mass. For this reason, it is possible to exist another phase angle to reduce this phenomenon instead of zero for periapsis of de-orbit burn phase because the vertical velocity is not zero at this point. To find out this optimal phase angle, in this paper, the initial free state optimal problem method is applied without any additional assumption and change of hardware for the traditional optimal lunar landing problem. Using this approach, it shows that the optimal phase angle does not always equal to the periapsis for some cases, and it is possible to reduce the fuel consumption of the lunar lander.

Dong-Hyun Cho | Hae-Dong Kim

[1] Xinglong Liu,et al. Nonlinear optimal control for the soft landing of lunar lander , 2006, 2006 1st International Symposium on Systems and Control in Aerospace and Astronautics.

[2] Colin R. McInnes. Path shaping guidance for terminal lunar descent , 1995 .

[3] Alisa Michelle Hawkins. Constrained trajectory optimization of a soft lunar landing from a parking orbit , 2005 .

[4] Guang-Ren Duan,et al. Optimal soft landing control for moon lander , 2008, Autom..

[5] Dong-Hyun Cho,et al. An optimal trajectory design for the lunar vertical landing , 2016 .

[6] Guangren Duan,et al. Study on the optimal fuel consumption of the singularity condition for lunar soft landing , 2007, 2007 IEEE International Conference on Robotics and Biomimetics (ROBIO).

[7] R. Ramanan,et al. Analysis of optimal strategies for soft landing on the Moon from lunar parking orbits , 2005 .

[8] Hyochoong Bang,et al. Optimal Perilune Altitude of Lunar Landing Trajectory , 2009 .

[9] Kok Lay Teo,et al. Optimal Guidance for Lunar Module Soft Landing , 2009 .

[10] Min-Jea Tahk,et al. Two-Dimensional Trajectory Optimization for Soft Lunar Landing Considering a Landing Site , 2011 .

[11] David G. Hull,et al. Optimal Control Theory for Applications , 2003 .