A flat rigid plate is a universal planar manipulator

Reznik, Dan; Canny, John

doi:10.1109/robot.1998.677313

Cited by 57 publications

(29 citation statements)

References 7 publications

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“…For instance, we do such a manipulation when manipulating a disc using two simple manipulators. Other, examples include control of an object by rolling it between two plates [2,3], manipulation of objects in a tilting tray [4] or on a vibrating plate [5], manipulation of parts on a conveyor belt with a single-joint robot [6], pushing with point contact [7], dynamic rolling [8], snatching, rolling, and throwing [9], manipulation of planar objects dynamically with simple robots [10], reorientating parts using a manufacturing arm with a passive joint on its end [11] and manipulation of planar shapes using two palms [12] or a series of one degree of freedom arm [34]. Above mentioned robotic systems are much simpler than conventional general purpose manipulators however; they can manipulate a variety of parts without grasping.…”

Section: Related Workmentioning

confidence: 99%

A dynamic object manipulation approach to dynamic biped locomotion

Beigzadeh

Ahmadabadi

Meghdari

et al. 2008

Robotics and Autonomous Systems

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Section: Related Workmentioning

confidence: 99%

A dynamic object manipulation approach to dynamic biped locomotion

Beigzadeh

Ahmadabadi

Meghdari

et al. 2008

Robotics and Autonomous Systems

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“…The UPM consists of a single rigid horizontal plate that moves with three degrees-of-freedom (two translational and one rotational). Systems that restrict the plate motion to the horizontal plane, such as the UPM, can only generate frictional force fields with zero divergence [12]. Therefore, position sensing is required to orient and position parts.…”

Section: Introductionmentioning

confidence: 99%

“…In [17], Lynch and Umbanhowar derived optimal plate motions that maximize part speed on one-and two-DoF translating rigid plates. The three-DoF UPM is capable of generating certain position-dependent force fields [12] including localized ones [18].…”

Section: Introductionmentioning

confidence: 99%

Friction-Induced Velocity Fields for Point Parts Sliding on a Rigid Oscillated Plate

Vose¹,

Umbanhowar²,

Lynch³

2008

Robotics: Science and Systems IV

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Abstract-We show that small-amplitude periodic motion of a rigid plate causes point parts on the plate to move as if they are in a position-dependent velocity field. Further, we prove that every periodic plate motion maps to a unique velocity field. By allowing a plate to oscillate with six-degrees-of-freedom, we can create a large family of programmable velocity fields. We examine in detail sinusoidal plate motions that generate fields with either isolated sinks or squeeze lines. These fields can be exploited to perform tasks such as sensorless part orientation.

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“…While the system can communicate system constraints through graphics and object actuation, it is limited in its ability to manifest mechanical constraints; only the user can create those. Other techniques for moving objects on a 2D surface include vibration [36] and robotics [22].…”

Section: Actuated and Dynamically Controlled Objectsmentioning

confidence: 99%

inFORM

Follmer

Leithinger

Olwal

et al. 2013

Proceedings of the 26th Annual ACM Symposium on User Interface Software and Technology

472

123

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Figure 1: inFORM enables new interaction techniques for shape-changing UIs. Left to right: On-demand UI elements through Dynamic Affordances; Guiding interaction with Dynamic Constraints; Object actuation; Physical rendering of content and UI. ABSTRACTPast research on shape displays has primarily focused on rendering content and user interface elements through shape output, with less emphasis on dynamically changing UIs. We propose utilizing shape displays in three different ways to mediate interaction: to facilitate by providing dynamic physical affordances through shape change, to restrict by guiding users with dynamic physical constraints, and to manipulate by actuating physical objects. We outline potential interaction techniques and introduce Dynamic Physical Affordances and Constraints with our inFORM system, built on top of a stateof-the-art shape display, which provides for variable stiffness rendering and real-time user input through direct touch and tangible interaction. A set of motivating examples demonstrates how dynamic affordances, constraints and object actuation can create novel interaction possibilities.

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A flat rigid plate is a universal planar manipulator

Cited by 57 publications

References 7 publications

A dynamic object manipulation approach to dynamic biped locomotion

A dynamic object manipulation approach to dynamic biped locomotion

Friction-Induced Velocity Fields for Point Parts Sliding on a Rigid Oscillated Plate

inFORM

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