Passive and dynamic gait measures for biped mechanism: formulation and simulation analysis

Mummolo, Carlotta; Kim, Joo H.

doi:10.1017/s0263574712000586

Cited by 27 publications

(21 citation statements)

References 50 publications

(213 reference statements)

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“…A further way of assessing the energetic aspects of locomotion has been recently introduced with the concept of "passivity", defined as the ability of optimizing the use of gravity and inertia to move the body forward. The resulting Passivity Gait Measure (PGM) [14], appears to be a potential benchmark because of its practical use in robotic and human scenarios. Another aspect of efficiency is the ability of reacting promptly to an external command or perturbation, usually referred to as reaction time.…”

Section: Benchmarks Of Performancementioning

confidence: 99%

“…Therefore the Froude number can be taken as a compact way to describe dynamic similarity between a robot and human, irrespective to size [26]. Mummolo et al [14] recently proposed an indicator of "dynamicity", i.e. the dynamic gait measure (DGM), defined as the ability of a legged system to maintain dynamic stability while statically unbalanced, therefore useful to distinguish between ZMP-based control approaches vs. natural dynamics systems (e.g.…”

Section: Benchmarks Of Human Likenessmentioning

confidence: 99%

See 1 more Smart Citation

Benchmarking Bipedal Locomotion: A Unified Scheme for Humanoids, Wearable Robots, and Humans

Torricelli

González-Vargas

Veneman

et al. 2015

IEEE Robot. Automat. Mag.

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Section: Benchmarks Of Performancementioning

confidence: 99%

Section: Benchmarks Of Human Likenessmentioning

confidence: 99%

Benchmarking Bipedal Locomotion: A Unified Scheme for Humanoids, Wearable Robots, and Humans

Torricelli

González-Vargas

Veneman

et al. 2015

IEEE Robot. Automat. Mag.

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“…Its powered plantar flexion allows the human operator to navigate various environments, such as stairs and ramps, as demonstrated during the 2016 Cybathlon competition, and to reliably achieve a conservative walking speed of 0.29 m/s (Griffin et al, 2017 ). These recent advancements could progress toward robot-assisted gait that requires reduced effort from the user (Griffin et al, 2017 ) and has desired dynamic walking characteristics, e.g., similar to normal or load-carrying human walking (Mummolo and Kim, 2013 ; Mummolo et al, 2013 , 2016 ). The effort of translating human locomotion principles into robotic solutions requires quantitative benchmarks to evaluate the human-like performance of robotic assistive devices (Neuhaus et al, 2011 ).…”

Section: Introductionmentioning

confidence: 99%

Stability of Mina v2 for Robot-Assisted Balance and Locomotion

et al. 2018

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The assessment of the risk of falling during robot-assisted locomotion is critical for gait control and operator safety, but has not yet been addressed through a systematic and quantitative approach. In this study, the balance stability of Mina v2, a recently developed powered lower-limb robotic exoskeleton, is evaluated using an algorithmic framework based on center of mass (COM)- and joint-space dynamics. The equivalent mechanical model of the combined human-exoskeleton system in the sagittal plane is established and used for balance stability analysis. The properties of the Linear Linkage Actuator, which is custom-designed for Mina v2, are analyzed to obtain mathematical models of torque-velocity limits, and are implemented as constraint functions in the optimization formulation. For given feet configurations of the robotic exoskeleton during flat ground walking, the algorithm evaluates the maximum allowable COM velocity perturbations along the fore-aft directions at each COM position of the system. The resulting velocity extrema form the contact-specific balance stability boundaries (BSBs) of the combined system in the COM state space, which represent the thresholds between balanced and unbalanced states for given contact configurations. The BSBs are obtained for the operation of Mina v2 without crutches, thus quantifying Mina v2's capability of maintaining balance through the support of the leg(s). Stability boundaries in single and double leg supports are used to analyze the robot's stability performance during flat ground walking experiments, and provide design and control implications for future development of crutch-less robotic exoskeletons.

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“…Mathematical models of robotic EE are usually functions of kinematic (joint angles and velocities or center of mass velocity) and dynamic (joint torques or ground reaction forces) variables. While mathematical models of EE can be used for prediction, simulation, and optimization of EE for robotic systems, incomplete proxies are often used in the literature, such as actuator torques or squared actuator torques, 10,11 mechanical energy or work, 12,13 and their combinations with other terms, 4,14 which are overly simplified and do not accurately quantify the actual EE. For instance, mechanical energy, work, or their rates of change alone do not fully characterize the EE, particularly during phases of negative or zero mechanical work.…”

Section: Introductionmentioning

confidence: 99%

“…Biped walking is a common human task, and normal human walking is commonly characterized as passive dynamic walking, [31][32][33][34] in which humans tend to choose a gait that minimizes EE 35 at the expense of static instability. 11 Since robotic walking is inspired by that of humans, benchmarking human gait to resolve the conflict between stability and energetic efficiency is a logical approach. 36 For instance, an energy-related passivity index was introduced and its inverse relationship with a stability index was compared between robotic and human walking.…”

Section: Introductionmentioning

confidence: 99%

Energy expenditure of a biped walking robot: instantaneous and degree-of-freedom-based instrumentation with human gait implications

Roberts

Quacinella

Kim³

2016

Robotica

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SUMMARYEnergy expenditure (EE) is an important criterion for design and control of biped walking robots. However, the cause-effect analyses enabled by total EE, which is lumped over a time duration and all system degrees-of-freedom (DOFs), are limited. In this study, robotic gait energetics is evaluated through a DOF-based instrumentation system designed for instantaneous evaluation of bidirectional current and applied voltage at each joint actuator. The instrumentation system includes a dual-module arrangement of buffers and attenuators, and accommodates and synchronizes the voltage and current measurements from multiple actuators. For illustrative purposes, this system is implemented at each DC servomotor in a biped robot, DARwIn-OP, to analyze the electrical EE rates for walking at various speeds. In addition, a DOF-based model of instantaneous human EE rate is employed to enable quantitative characterization of robotic walking EE relative to that of humans. The robot's instantaneous lower-body EE rates are consistent with its periodic walking cycle, and their relative trends between single and double support phases are analogous to those of humans. The robotic cost of transport (COT) curve as a function of normalized speed is also consistent with the human COT in terms of its convexity. Conversely, the contrasting distributions of EE throughout the robot and human DOFs and the robotic COT curve's considerably larger magnitudes, smaller speed ranges, and higher sensitivity to speed illustrate the energetic consequences of stable but inefficient static walking in the biped robot relative to the more efficient dynamic walking of humans. These energetic characteristics enable the identification of the joints and gait cycle phases associated with inefficiency in biped robotic gait, and reflect the noticeable differences in the system parameters (rigid and flat versus segmented feet) and gait control strategies (bent versus straight knees, instants of peak ankle actuator torques, static versus dynamic balance stability). The proposed general instrumentation provides a quantitative approach to benchmarking human gait as well as general guidelines for the development of energy-efficient walking robots.

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Passive and dynamic gait measures for biped mechanism: formulation and simulation analysis

Cited by 27 publications

References 50 publications

Benchmarking Bipedal Locomotion: A Unified Scheme for Humanoids, Wearable Robots, and Humans

Benchmarking Bipedal Locomotion: A Unified Scheme for Humanoids, Wearable Robots, and Humans

Stability of Mina v2 for Robot-Assisted Balance and Locomotion

Energy expenditure of a biped walking robot: instantaneous and degree-of-freedom-based instrumentation with human gait implications

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