A Multistate Friction Model for the Compensation of the Asymmetric Hysteresis in the Mechanical Response of Pneumatic Artificial Muscles

Capace, Alessia; Cosentino, Carlo; Amato, Francesco; Merola, Alessio

doi:10.3390/act8020049

Cited by 11 publications

(4 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This means that the iPPROM risk could be lowered if this instrument was used in a real TTTS procedure. However, the current basic hysteresis modeling approach should be improved by e.g., using hysteresis compensation (Mei et al, 2017;Capace et al, 2019) or deep learning algorithms (Li et al, 2019). This would probably encourage the operator to use the flexible feature of the instrument even more, since it would be more responsive to the user input.…”

Section: Discussionmentioning

confidence: 99%

“…In order to solve this problem, both friction and muscles hysteresis could be characterized in greater detail, by e.g., characterizing the hysteresis over different bending angle ranges. Another solution could make use of hysteresis compensation algorithms for the muscles, like suggested by Mei et al (2017) or Capace et al (2019). Even though this 10 • error is important, one should realize that this is a human-in-the-loop system.…”

Section: Verification Of Controllabilitymentioning

confidence: 99%

See 1 more Smart Citation

Handheld Active Add-On Control Unit for a Cable-Driven Flexible Endoscope

et al. 2019

View full text Add to dashboard Cite

The instruments currently used by surgeons for in utero treatment of the twin-to-twin transfusion syndrome (TTTS) are rigid or semi-rigid. Their poor dexterity makes this surgical intervention risky and the surgeon's work very complex. This paper proposes the design, assembly and quantitative evaluation of an add-on system intended to be placed on a commercialized cable-driven flexible endoscope. The add-on system is lightweight and easily exchangeable thanks to the McKibben muscle actuators embedded in its system. The combination of the flexible endoscope and the new add-on unit results in an easy controllable flexible instrument with great potential use in TTTS treatment, and especially for regions that are hard to reach with conventional instruments. The fetoscope has a precision of 7.4% over its entire bending range and allows to decrease the maximum planar force on the body wall of 6.15% compared to the original endoscope. The add-on control system also allows a more stable and precise actuation of the endoscope flexible tip.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Verification Of Controllabilitymentioning

confidence: 99%

Handheld Active Add-On Control Unit for a Cable-Driven Flexible Endoscope

et al. 2019

View full text Add to dashboard Cite

show abstract

“…Indeed, a PAM actuator is one of the most promising actuators for industrial application and devices because it can offer many merits, such as compliant behavior, soft and flexible structure, high power to weight ratio, lightweight, etc. However, there still exists significant drawbacks that are time-varying nonlinear dynamics and hysteresis characteristics [19,20] which may cause difficulties for applying traditional control algorithms such as Proportional Integral (PI), PID, linear control techniques or model-based controllers to manage the operation of PAM actuators. In recent years, the nonlinear control algorithms for PAM actuators have been proposed based on neural network [21,22], backstepping control [23].…”

Section: Introductionmentioning

confidence: 99%

An Adaptive Fast Terminal Sliding Mode Controller of Exercise-Assisted Robotic Arm for Elbow Joint Rehabilitation Featuring Pneumatic Artificial Muscle Actuator

Thọ

Trinh

2020

Actuators

View full text Add to dashboard Cite

Due to the time-varying nonlinear dynamic, uncertain model and hysteresis characteristics of the pneumatic artificial muscle (PAM) actuator, it is not easy to apply model-based control algorithms for monitoring, as well as controlling, the operation of systems driven by PAM actuators. Hence, the main aim of this work is to propose an intelligent controller named adaptive sliding controller adding compensator (ASC + C) to operate a robotic arm, featuring a pneumatic artificial muscle actuator, which assists rehabilitation exercise of the elbow joint function. The structure of the proposed controller is a combination between the fuzzy logic technique and Proportional Integral Derivative (PID) algorithm. In which, the input of fuzzy logic controller is the sliding surface, meanwhile, its output is the estimated value of the unknown nonlinear function, meaning that the model-based requirement is released. A PID controller works as a compensator with online learning ability and is designed to compensate because of the approximate error and hysteresis characteristic. Additionally, to improve convergence and to obtain stability, a fast terminal sliding manifold is introduced and online learning laws for parameters of the controller are attainted through the stable criterion of Lyapunov. Finally, an experimental apparatus is also fabricated to evaluate control response of the system. The experimental result confirmed strongly the ability of the proposed controller, which indicates that the ASC + C can obtain a steady state tracking error less than 5 degrees and a position response without overshoot.

show abstract

“…This model is used in feed forward, allowing an open-loop control of the muscle. Capace et al [9] introduced a multistate friction model in order to compensate for the muscle hysteresis. These methods do not require extra sensors and thus provides a compact system.…”

Section: Introductionmentioning

confidence: 99%

Integrated Capacitance Sensing for Miniature Artificial Muscle Actuators

et al. 2020

View full text Add to dashboard Cite

The use of McKibben pneumatic artificial muscles in surgical instruments is increasing due to their light weight, miniaturization potential, compliance and large actuation force. However, precise position and force control is still challenging due to the intrinsic muscle hysteresis. The present work proposes an easy-to-make integrated capacitance sensor for miniature artificial muscles by replacing two strands of the muscle braid with two conductive wires. By measuring the capacitance at high excitation frequency between both wires, the length of the muscle can be deduced. This new integrated sensor still allows the miniaturization of McKibben muscles. The miniature muscle with integrated capacitance sensing only loses 3% of its contraction length with regard to an original McKibben muscle. The sensor can predict the muscle length with a 0.31mm precision over 80% of the muscle total achievable contraction range in average.

show abstract

A Multistate Friction Model for the Compensation of the Asymmetric Hysteresis in the Mechanical Response of Pneumatic Artificial Muscles

Cited by 11 publications

References 27 publications

Handheld Active Add-On Control Unit for a Cable-Driven Flexible Endoscope

Handheld Active Add-On Control Unit for a Cable-Driven Flexible Endoscope

An Adaptive Fast Terminal Sliding Mode Controller of Exercise-Assisted Robotic Arm for Elbow Joint Rehabilitation Featuring Pneumatic Artificial Muscle Actuator

Integrated Capacitance Sensing for Miniature Artificial Muscle Actuators

Contact Info

Product

Resources

About