Simulation of upward jump control for one‐legged robot based on qp optimization

Dingkui Tian, Junyao Gao*, Chuzhao Liu, Xuanyang Shi

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

5 Citations (Scopus)

Abstract

An optimization framework for upward jumping motion based on quadratic program-ming (QP) is proposed in this paper, which can simultaneously consider constraints such as the zero moment point (ZMP), limitation of angular accelerations, and anti‐slippage. Our approach com-prises two parts: the trajectory generation and real‐time control. In the trajectory generation for the launch phase, we discretize the continuous trajectories and assume that the accelerations between the two sampling intervals are constant and transcribe the problem into a nonlinear optimization problem. In the real‐time control of the stance phase, the over‐constrained control objectives such as the tracking of the center of moment (CoM), angle, and angular momentum, and constraints such as the anti‐slippage, ZMP, and limitation of joint acceleration are unified within a framework based on QP optimization. Input angles of the actuated joints are thus obtained through a simple iteration. The simulation result reveals that a successful upward jump to a height of 16.4 cm was achieved, which confirms that the controller fully satisfies all constraints and achieves the control objectives.

Original languageEnglish
Article number1893
Pages (from-to)1-20
Number of pages20
JournalSensors
Volume21
Issue number5
DOIs
Publication statusPublished - 1 Mar 2021

Keywords

  • Angular momentum
  • Anti‐slippage
  • CoM
  • QP
  • Upward jumping
  • ZMP

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