Extending The Lossy Spring-Loaded Inverted Pendulum Model with a Slider-Crank Mechanism

TL;DR

This paper introduces an extended SLIP model with a slider-crank mechanism, enabling stable vertical limit-cycle locomotion in lossy systems, and provides an analytical stability analysis.

Contribution

It proposes a novel SLIP model extension with a slider-crank mechanism, addressing height control issues in lossy systems and offering an analytical approach for stability analysis.

Findings

The SLIP-SCM model can generate stable limit-cycles.

Analytical solutions characterize the system's behavior.

The model exhibits stability within the studied range.

Abstract

Spring Loaded Inverted Pendulum (SLIP) model has a long history in describing running behavior in animals and humans as well as has been used as a design basis for robots capable of dynamic locomotion. Anchoring the SLIP for lossy physical systems resulted in newer models which are extended versions of original SLIP with viscous damping in the leg. However, such lossy models require an additional mechanism for pumping energy to the system to control the locomotion and to reach a limit-cycle. Some studies solved this problem by adding an actively controllable torque actuation at the hip joint and this actuation has been successively used in many robotic platforms, such as the popular RHex robot. However, hip torque actuation produces forces on the COM dominantly at forward direction with respect to ground, making height control challenging especially at slow speeds. The situation becomes more severe when the horizontal speed of the robot reaches zero, i.e. steady hoping without moving in horizontal direction, and the system reaches to singularity in which vertical degrees of freedom is completely lost. To this end, we propose an extension of the lossy SLIP model with a slider-crank mechanism, SLIP- SCM, that can generate a stable limit-cycle when the body is constrained to vertical direction. We propose an approximate analytical solution to the nonlinear system dynamics of SLIP- SCM model to characterize its behavior during the locomotion. Finally, we perform a fixed-point stability analysis on SLIP-SCM model using our approximate analytical solution and show that proposed model exhibits stable behavior in our range of interest.