Bernard Roth scite author profile

This paper deals with several of the basic concepts in the kinematics of mechanical hands. Several different types of finger contacts are modeled and used in a number synthesis of three-fingered hands. Screw theory is used to show which finger configurations allow complete immobilization of the gripped object relative to the fingers, and also allow for the manipulation of the object by the fingers while maintaining the grasp. Shown in this paper is how to determine the forces applied by the fingers on the object, and also how to compute the velocities of the fingers and the object. The analysis developed in this paper is shown to lead to a hand with three fingers, each with three turning joints, and having friction contacts with an object at three separate points.

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Analysis of Multifingered Hands

Kerr

Roth

1986

The International Journal of Robotics Research

817

303

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This paper discusses three fundamental problems relating to grasping and manipulating objects within an articulated, multifingered hand: determining how hard to squeeze an ob ject in order to ensure a secure grasp, determining the finger- joint motions required to produce a desired motion of the object, and determining the workspace of the hand. Squeezing the object, or the application of internal grasp forces, is reduced to a linear programming problem which considers friction and joint torque limit constraints. The relationship between the finger-joint motions and the motion of the object, for the case of pure rolling between the finger tips and the object, is formulated as a set of differential equa tions. The total workspace for a hand is determinedfor spe cial cases of planar and spatial hands.

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A New Actuation Approach for Human Friendly Robot Design

Zinn

Roth

Khatib

et al. 2004

The International Journal of Robotics Research

410

205

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Sleep Disorders and Associated Medical Comorbidities in Active Duty Military Personnel

et al. 2013

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A new actuation approach for human friendly robot design

Khatib²,

2004

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AbsIracr-In recent years, many successful robotic manipulator designs have been introduced. However, there remains the challenge of designing a manipulator that possesses the inherent safety characteristics necessary for human-centered robotics. In this paper, we present a new actuation approach that has the requisite characteristics for inherent safety while maintaining the performance expected of modern designs. By drastically reducing the effectire impedance of the manipulator while maintaining high frequency torque capability, we show that the competing design requirements of performance and safety can be successfully integrated into a single manipulation system.

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Bernard Roth

Kinematic and Force Analysis of Articulated Mechanical Hands

Analysis of Multifingered Hands

A New Actuation Approach for Human Friendly Robot Design

Sleep Disorders and Associated Medical Comorbidities in Active Duty Military Personnel

A new actuation approach for human friendly robot design

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