Independently Commanding Size, Shape and Orientation of Robot Endpoint Stiffness in Tele-Impedance by Virtual Ellipsoid Interface

We used a robotic device to test the idea that impedance control involves a process of learning or adaptation that is acquired over time and permits the voluntary control of the pattern of stiffness at the hand. The tests were conducted in statics. Subjects were trained over the course of 3 successive days to resist the effects of one of three different kinds of mechanical loads: single axis loads acting in the lateral direction, single axis loads acting in the forward/backward direction, and isotropic loads that perturbed the limb in eight directions about a circle. We found that subjects in contact with single axis loads voluntarily modified their hand stiffness orientation such that changes to the direction of maximum stiffness mirrored the direction of applied load. In the case of isotropic loads, a uniform increase in endpoint stiffness was observed. Using a physiologically realistic model of two-joint arm movement, the experimentally determined pattern of impedance change could be replicated by assuming that coactivation of elbow and double joint muscles was independent of coactivation of muscles at the shoulder. Moreover, using this pattern of coactivation control we were able to replicate an asymmetric pattern of rotation of the stiffness ellipse that was observed empirically. These findings are consistent with the idea that arm stiffness is controlled through the use of at least two independent co-contraction commands.

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sEMG-based Endpoint Stiffness Estimation of Human Arm using Gene Expression Programming

Journal of Physics Conference Series ◽

10.1088/1742-6596/1267/1/012016 ◽

2019 ◽

Vol 1267 ◽

pp. 012016

Author(s):

Jiang Zainan ◽

Yang Fan ◽

Li Chongyang ◽

Liu Daxiang ◽

Wang Chenliang ◽

...

Keyword(s):

Gene Expression ◽

Gene Expression Programming ◽

Human Arm ◽

Endpoint Stiffness

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Reduced-complexity representation of the human arm active endpoint stiffness for supervisory control of remote manipulation

The International Journal of Robotics Research ◽

10.1177/0278364917744035 ◽

2017 ◽

Vol 37 (1) ◽

pp. 155-167 ◽

Cited By ~ 10

Author(s):

Arash Ajoudani ◽

Cheng Fang ◽

Nikos Tsagarakis ◽

Antonio Bicchi

Keyword(s):

Robotic Arm ◽

Model Parameters ◽

Time Model ◽

Remote Manipulation ◽

Proposed Model ◽

Human Arm ◽

Human Motor ◽

Reduced Complexity ◽

Stiffness Profile ◽

Endpoint Stiffness

In this paper, a reduced-complexity model of the human arm endpoint stiffness is introduced and experimentally evaluated for the teleimpedance control of a compliant robotic arm. The modeling of the human arm endpoint stiffness behavior is inspired by human motor control principles on the predominant use of the arm configuration in directional adjustments of the endpoint stiffness profile, and the synergistic effect of muscular activations, which contributes to a coordinated modification of the task stiffness in all Cartesian directions. Calibration and identification of the model parameters are carried out experimentally, using perturbation-based arm endpoint stiffness measurements in different arm configurations and cocontraction levels of the chosen muscles. Consequently, the real-time model is used for the remote control of a compliant robotic arm while executing a drilling task, a representative example of tool use in environments with constraints and dynamic uncertainties. The results of this study illustrate that the proposed model enables the master to execute the remote task by modulation of the directions of the major axes of the endpoint stiffness ellipsoid and its volume using natural arm configurations and the cocontraction of the involved muscles, respectively.

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Effects of Upper-Limb Posture on Endpoint Stiffness during Force Targeting Tasks

IFMBE Proceedings - 13th International Conference on Biomedical Engineering ◽

10.1007/978-3-540-92841-6_462 ◽

2009 ◽

pp. 1862-1865

Author(s):

Pei-Rong Wang ◽

Ju-Ying Chang ◽

Kao-Chi Chung

Keyword(s):

Upper Limb ◽

Limb Posture ◽

Endpoint Stiffness

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Design of a parallel compliance device with variable stiffness

Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science ◽

10.1177/0954406220932596 ◽

2020 ◽

pp. 095440622093259

Author(s):

Yong Zhao ◽

Kunyong Chen ◽

Jue Yu ◽

Shunzhou Huang

Keyword(s):

Mechanical Characteristics ◽

Variable Stiffness ◽

Spring Stiffness ◽

Synthesis Algorithm ◽

Stiffness Properties ◽

Linear Spring ◽

Endpoint Stiffness ◽

Stiffness Adjustment ◽

Translational Stiffness

This paper presents a parallel compliance device with variable translational stiffness properties. The variation of endpoint stiffness depends on the change of the spring stiffness in each limb. A synthesis algorithm for realizing the desired force compliance performance is built. Based on the proposed algorithm, a group of optimal spring stiffness can be derived. For the implementation of this device, an electromagnetic linear spring with current-controlled stiffness is developed. After testing the mechanical characteristics of the electromagnetic spring, a prototype of the parallel compliance device is built. The endpoint stiffness under different combinations of spring stiffness values is exhibited in the form of stiffness ellipsoids. A case is studied and verifies the ability of the presented compliance device to realize the desired endpoint stiffness. As the stiffness adjustment range of electromagnetic spring is limited, the bound of physically realizable stiffness of the presented compliance device is also discussed.

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Interactions Between Limb and Environmental Mechanics Influence Stretch Reflex Sensitivity in the Human Arm

Journal of Neurophysiology ◽

10.1152/jn.00679.2009 ◽

2010 ◽

Vol 103 (1) ◽

pp. 429-440 ◽

Cited By ~ 61

Author(s):

Matthew A. Krutky ◽

Vengateswaran J. Ravichandran ◽

Randy D. Trumbower ◽

Eric J. Perreault

Keyword(s):

Mechanical Properties ◽

Tool Use ◽

Stretch Reflex ◽

Negative Stiffness ◽

Reflex Modulation ◽

Stretch Reflexes ◽

Human Arm ◽

Environmental Instability ◽

Increased Sensitivity ◽

Endpoint Stiffness

Stretch reflexes contribute to arm impedance and longer-latency stretch reflexes exhibit increased sensitivity during interactions with compliant or unstable environments. This increased sensitivity is consistent with a regulation of arm impedance to compensate for decreased stability of the environment, but the specificity of this modulation has yet to be investigated. Many tasks, such as tool use, compromise arm stability along specific directions, and stretch reflexes tuned to those directions could present an efficient mechanism for regulating arm impedance in a task-appropriate manner. To be effective, such tuning should adapt not only to the mechanical properties of the environment but to those properties in relation to the arm, which also has directionally specific mechanical properties. The purpose of this study was to investigate the specificity of stretch reflex modulation during interactions with mechanical environments that challenge arm stability. The tested environments were unstable, having the characteristics of a negative stiffness spring. These were either aligned or orthogonal to the direction of maximal endpoint stiffness for each subject. Our results demonstrate preferential increases in reflexes, elicited within 50–100 ms of perturbation onset, to perturbations applied specifically along the direction of the destabilizing environments. This increase occurred only when the magnitude of the environmental instability exceeded endpoint stiffness along the same direction. These results are consistent with task-specific reflex modulation tuned to the mechanical properties of the environment relative to those of the human arm. They demonstrate a highly adaptable, involuntary mechanism that may be used to modulate limb impedance along specific directions.

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