Leif P. Jentoft scite author profile

This paper introduces the i-HY Hand, an underactuated hand driven by 5 actuators that is capable of performing a wide range of grasping and in-hand manipulation tasks. This hand was designed to address the need for a durable, inexpensive, moderately dexterous hand suitable for use on mobile robots. The primary focus of this paper will be on the novel minimalistic design of i-HY, which was developed by choosing a set of target tasks around which the design of the hand was optimized. Particular emphasis is placed on the development of underactuated fingers that are capable of both firm power grasps and lowstiffness fingertip grasps using only the passive mechanics of the finger mechanism. Experimental results demonstrate successful grasping of a wide range of target objects, the stability of fingertip grasping, as well as the ability to adjust the force exerted on grasped objects using the passive finger mechanics.

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The Feel of MEMS Barometers: Inexpensive and Easily Customized Tactile Array Sensors

Tenzer

Jentoft

Howe

2014

IEEE Robot. Automat. Mag.

167

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Abstract-This paper presents a new approach to the construction of tactile array sensors based on barometric pressure sensor chips and standard printed circuit boards. The chips include tightly integrated instrumentation amplifiers, analog-todigital converters, pressure and temperature sensors, and control circuitry that provides excellent signal quality over standard digital bus interfaces. The resulting array electronics can be easily encapsulated with soft polymers to provide robust and compliant grasping surfaces for specific hand designs. The use of standard commercial-off-the-shelf technologies means that only basic electrical and mechanical skills are required to build effective tactile sensors for new applications. Performance evaluation of prototype arrays demonstrate excellent linearity (<1% typical) and low noise (<0.01 N). External addressing circuitry allows multiple sensors to communicate on the same bus at over 100 Hz per sensor element. Sensors can be mounted as close as 3x5 mm spacing, and spatial impulse response tests show that solid-mechanics based signal processing is feasible. This approach promises to make sensitive, robust, and inexpensive tactile sensing available for a wide range of robotics and humaninterface applications.

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Contact sensing and grasping performance of compliant hands

et al. 2009

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Limitations in modern sensing technologies result in large errors in sensed target object geometry and location in unstructured environments. As a result, positioning a robotic end-effector includes inherent error that will often lead to unsuccessful grasps. In previous work, we demonstrated that optimized configuration, compliance, viscosity, and adaptability in the mechanical structure of a robot hand facilitates reliable grasping in unstructured environments, even with purely feedforward control of the hand. In this paper we describe the addition of a simple contact sensor to the fingerpads of the SDM Hand (Shape Deposition Manufactured Hand), which, along with a basic control algorithm, significantly expands the grasp space of the hand and reduces contact forces during the acquisition phase of the grasp. The combination of the passive mechanics of the SDM Hand along with this basic sensor suite enables positioning errors of over 5cm in any direction. In the context of mobile manipulation, the performance demonstrated here may reduce the need for much of the complex array of sensing currently utilized on mobile platforms, greatly increase reliability, and speed task execution, which can often be prohibitively slow.

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Robust and Inexpensive Six-Axis Force–Torque Sensors Using MEMS Barometers

Guggenheim

Jentoft

Tenzer

et al. 2017

IEEE/ASME Trans. Mechatron.

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Flexible, stretchable tactile arrays from MEMS barometers

Jentoft

Tenzer

Vogt

et al. 2013

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Abstract-Many applications for tactile sensors require a flexible, stretchable array to allow installation on curved surfaces or to measure forces on deformable objects. This paper presents a sensor array created with barometers and flexible printed circuit boards that delivers high sensitivity on a flexible, stretchable package using commercial off-the-shelf (COTS) components: MEMS barometers and commercially-compatible flexible printed circuit boards. The array is demonstrated on the surface of a jamming gripper, where it provides the ability to sense grasping events and detect object shape.

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Leif P. Jentoft

A compliant, underactuated hand for robust manipulation

The Feel of MEMS Barometers: Inexpensive and Easily Customized Tactile Array Sensors

Contact sensing and grasping performance of compliant hands

Robust and Inexpensive Six-Axis Force–Torque Sensors Using MEMS Barometers

Flexible, stretchable tactile arrays from MEMS barometers

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