SLIP-Based Control of Bipedal Walking Based on Two-Level Control Strategy

Authors: Dadash Zadeh, B. and Macnab, C.

Journal: Robotica

Volume: 38

Issue: 8

Pages: 1434-1449

Publisher: Cambridge University Press

ISSN: 0263-5747

DOI: 10.1017/S0263574719001553

Abstract:

In this research, we propose a two-level control strategy for simultaneous gait generation and stable control of planar walking of the Assume The Robot Is A Sphere (ATRIAS) biped robot with unlocked torso, utilizing active spring-loaded inverted pendulum (ASLIP) as reference models. The upper level consists of an energy-regulating control calculated using the ASLIP model, producing reference ground reaction forces (GRFs) for the desired gait. In the lower level controller, PID force controllers for the motors ensure tracking of the reference GRFs for ATRIAS direct dynamics. Meanwhile, ATRIAS torso angle is controlled stably to make it able to follow a point mass template model. Advantages of the proposed control strategy include simplicity and efficiency. Simulation results using ATRIAS’s complete dynamic model show that the proposed two-level controller can reject initial condition disturbances while generating stable and steady walking motion.

https://eprints.bournemouth.ac.uk/39626/

Source: Manual

SLIP-Based Control of Bipedal Walking Based on Two-Level Control Strategy

Authors: Dadash Zadeh, B. and Macnab, C.J.B.

Journal: Robotica

Volume: 38

Issue: 8

Pages: 1434-1449

Publisher: Cambridge University Press

ISSN: 0263-5747

Abstract:

In this research, we propose a two-level control strategy for simultaneous gait generation and stable control of planar walking of the Assume The Robot Is A Sphere (ATRIAS) biped robot with unlocked torso, utilizing active spring-loaded inverted pendulum (ASLIP) as reference models. The upper level consists of an energy-regulating control calculated using the ASLIP model, producing reference ground reaction forces (GRFs) for the desired gait. In the lower level controller, PID force controllers for the motors ensure tracking of the reference GRFs for ATRIAS direct dynamics. Meanwhile, ATRIAS torso angle is controlled stably to make it able to follow a point mass template model. Advantages of the proposed control strategy include simplicity and efficiency. Simulation results using ATRIAS’s complete dynamic model show that the proposed two-level controller can reject initial condition disturbances while generating stable and steady walking motion.

https://eprints.bournemouth.ac.uk/39626/

Source: BURO EPrints