Dynamic Simulation of Modifiable Bipedal Walking on Uneven Terrain with Unknown Height

Hong, Young-Dae; Lee, Ki-Baek

doi:10.5370/jeet.2016.11.3.733

Cited by 2 publications

(1 citation statement)

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“…Nevertheless, the biped robot will not lose its stability if the ZMP exceeds the stable region in a very short time. This situation can also be seen in other references, such as [35][36][37]. From Figure 22, it is observed that the biped can walk stably with no sliding.…”

Section: Walking On Uneven Groundsupporting

confidence: 74%

Trajectory Planning of Flexible Walking for Biped Robots Using Linear Inverted Pendulum Model and Linear Pendulum Model

Xie

Luo

et al. 2021

Sensors

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Linear inverted pendulum model (LIPM) is an effective and widely used simplified model for biped robots. However, LIPM includes only the single support phase (SSP) and ignores the double support phase (DSP). In this situation, the acceleration of the center of mass (CoM) is discontinuous at the moment of leg exchange, leading to a negative impact on walking stability. If the DSP is added to the walking cycle, the acceleration of the CoM will be smoother and the walking stability of the biped will be improved. In this paper, a linear pendulum model (LPM) for the DSP is proposed, which is similar to LIPM for the SSP. LPM has similar characteristics to LIPM. The dynamic equation of LPM is also linear, and its analytical solution can be obtained. This study also proposes different trajectory-planning methods for different situations, such as periodic walking, adjusting walking speed, disturbed state recovery, and walking terrain-blind. These methods have less computation and can plan trajectory in real time. Simulation results verify the effectiveness of proposed methods and that the biped robot can walk stably and flexibly when combining LIPM and LPM.

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Section: Walking On Uneven Groundsupporting

confidence: 74%