Predicting the mean first passage time (MFPT) to reach any state for a passive dynamic walker with steady state variability.

Isuri Wijesundera,Thrishantha Nanayakkara,Malka N Halgamuge,Ampalavanapillai Nirmalathas

doi:10.1371/journal.pone.0207665

Isuri Wijesundera, Thrishantha Nanayakkara + Show 2 more

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https://doi.org/10.1371/journal.pone.0207665

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Abstract

Idealized passive dynamic walkers (PDW) exhibit limit cycle stability at steady state. Yet in reality, uncertainty in ground interaction forces result in variability in limit cycles even for a simple walker known as the Rimless Wheel (RW) on seemingly even slopes. This class of walkers is called metastable walkers in that they usually walk in a stable limit cycle, though guaranteed to eventually fail. Thus, control action is only needed if a failure state (i.e. RW stopping down the ramp) is imminent. Therefore, efficiency of estimating the time to reach a failure state is key to develop a minimal intervention controller to inject just enough energy to overcome a failure state when required. Current methods use what is known as a Mean First Passage Time (MFPT) from current state (rotary speed of RW at the most recent leg collision) to an arbitrary state deemed to be a failure in the future. The frequently used Markov chain based MFPT prediction requires an absorbing state, which in this case is a collision where the RW comes to a stop without an escape. Here, we propose a novel method to estimate an MFPT from current state to an arbitrary state which is not necessarily an absorbing state. This provides freedom to a controller to adaptively take action when deemed necessary. We demonstrate the proposed MFPT predictions in a minimal intervention controller for a RW. Our results show that the proposed method is useful in controllers for walkers showing up to 44.1% increase of time-to-fail compared to a PID based closed-loop controller.

Highlights

A passive walker is a simple form of legged locomotion which can move down a slope without actuation [1]
The proposed method is an extension of a powerful technique proposed in [17], and further allows estimating Mean First Passage Time (MFPT) to reach an arbitrary state from any given state even if the state transition probability distribution is biased in the state space
We present the predictions of the MFPT to reach failure for the Rimless Wheel (RW)’s experimental dataset as well as data-sets for two simulated scenarios using the proposed method and the results compared with the actual numerical averages of the labelled data-set as well as predictions using the well-established method of using Transition Probability Matrices (TPMs)

Summary

Introduction

A passive walker is a simple form of legged locomotion which can move down a slope without actuation [1]. Its only source of energy is gravity. The energetics of these walkers are such that the energy lost in friction and collisions are balanced by the conversion of potential energy to kinetic energy as the walker moves down a slope [2]. In a previous study we have shown that passive dynamic walkers have state space attractor’s that can be efficiently used to arrive at this. Predicting the MFPT to reach any state for a passive dynamic walker with steady state variability energy equilibrium despite different initial conditions [3]. The dynamics of a passive walker, though seemingly deterministic, is highly complex due to the inevitable variability of punctuated state transitions at every impact with the ground even under idealized conditions

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