Abstract
Biped robots have come a long way in imitating a human being's anatomy and posture. Standing balance and push recovery are some of the biggest challenges for such robots. This work presents a novel simplified model for a humanoid robot to recover from external disturbances. The proposed Linearized Double Inverted Pendulum, models the dynamics of a complex humanoid robot that can use ankle and hip recovery strategies while taking full advantage of the advances in controls theory research. To support this, an LQR based control architecture is also presented in this work. The joint torque signals are generated along with ankle torque constraints to ensure the Center of Pressure stays within the support polygon. Simulation results show that the presented model can successfully recover from external disturbances while using minimal effort when compared to other widely used simplified models. It optimally uses the the torso weight to generate angular momentum about the pelvis of the robot to counter-balance the effects of external disturbances. The proposed method was validated on simulated `TigerBot-VII', a humanoid robot.
Library of Congress Subject Headings
Robots--Dynamics--Mathematical models; Robots--Control systems
Publication Date
6-2020
Document Type
Thesis
Student Type
Graduate
Degree Name
Microelectronic Engineering (MS)
Department, Program, or Center
Microelectronic Engineering (KGCOE)
Advisor
Ferat Sahin
Advisor/Committee Member
Jamison Heard
Advisor/Committee Member
Gill R. Tsouri
Recommended Citation
Singh, Saurav, "Push Recovery for Humanoid Robots using Linearized Double Inverted Pendulum" (2020). Thesis. Rochester Institute of Technology. Accessed from
https://repository.rit.edu/theses/10512
Campus
RIT – Main Campus
Plan Codes
MCEE-MS
