Adaptive synergies for the design and control of the Pisa/IIT SoftHand

Catalano, Manuel G.; Grioli, Giorgio; Farnioli, Edoardo; Serio, Alessandro; Piazza, Cristina; Bicchi, Antonio

doi:10.1177/0278364913518998

Cited by 552 publications

(390 citation statements)

References 29 publications

(38 reference statements)

Supporting

Mentioning

388

Contrasting

Unclassified

Order By: Relevance

“…The SDM hand (Dollar and Howe, 2010), the Velo gripper (Ciocarlie et al, 2013), the i-HY hand (Odhner et al, 2014), and the Pisa/IIT SoftHand (Catalano et al, 2014) couple the actuation of degrees of freedom using tendonpulley systems, adapting the shape of the hand to the object while equalizing contact forces.…”

Section: Interactions Between Hand and Objectmentioning

confidence: 99%

Exploitation of Environmental Constraints in Human and Robotic Grasping

Deimel¹,

Eppner²,

Álvarez-Ruiz³

et al. 2016

Springer Tracts in Advanced Robotics

View full text Add to dashboard Cite

We investigate the premise that robust grasping performance is enabled by exploiting constraints present in the environment. These constraints, leveraged through motion in contact, counteract uncertainty in state variables relevant to grasp success. Given this premise, grasping becomes a process of successive exploitation of environmental constraints, until a successful grasp has been established. We present support for this view found through the analysis of human grasp behavior and by showing robust robotic grasping based on constraint-exploiting grasp strategies. Furthermore, we show that it is possible to design robotic hands with inherent capabilities for the exploitation of environmental constraints.

show abstract

Section: Interactions Between Hand and Objectmentioning

confidence: 99%

Exploitation of Environmental Constraints in Human and Robotic Grasping

Deimel¹,

Eppner²,

Álvarez-Ruiz³

et al. 2016

Springer Tracts in Advanced Robotics

View full text Add to dashboard Cite

show abstract

“…The motors can spin in opposite directions to tighten or loosen the band on the arm, thus conveying normal force and pressure cues; they can also spin in the same direction in order to slide the band around the arm, thus inducing skin stretch cues that can easily be associated with directional and navigation information (see Figure 5). In the first mode, CUFF was used in association with Pisa/IIT SoftHand (SH), an anthropomorphic robotic hand, actuated through a single motor, but capable of adapting for grasping different objects [64]. Because the SH has no built-in force sensors, an estimation of applied force can be obtained based on the current the motor draws.…”

Section: Cuffmentioning

confidence: 99%

“…This is because residual current is proportional to grasp force (see Figure 6). This approach is motivated by the fact that there is a net difference in the In the first mode, CUFF was used in association with Pisa/IIT SoftHand (SH), an anthropomorphic robotic hand, actuated through a single motor, but capable of adapting for grasping different objects [64]. Because the SH has no built-in force sensors, an estimation of applied force can be obtained based on the current the motor draws.…”

Section: Cuffmentioning

confidence: 99%

A Fabric-Based Approach for Wearable Haptics

Bianchi

2016

Electronics

View full text Add to dashboard Cite

Abstract:In recent years, wearable haptic systems (WHS) have gained increasing attention as a novel and exciting paradigm for human-robot interaction (HRI). These systems can be worn by users, carried around, and integrated in their everyday lives, thus enabling a more natural manner to deliver tactile cues. At the same time, the design of these types of devices presents new issues: the challenge is the correct identification of design guidelines, with the two-fold goal of minimizing system encumbrance and increasing the effectiveness and naturalness of stimulus delivery. Fabrics can represent a viable solution to tackle these issues. They are specifically thought "to be worn", and could be the key ingredient to develop wearable haptic interfaces conceived for a more natural HRI. In this paper, the author will review some examples of fabric-based WHS that can be applied to different body locations, and elicit different haptic perceptions for different application fields. Perspective and future developments of this approach will be discussed.

show abstract

“…Employing the outlined control basis framework to realize approaching motions for grasping and exploiting the passive compliance of modern, often underactuated hands [18,19], grasp planning is extremely simplified: The fingers will automatically wrap around the object due to the inherent compliance of the hand. Thus, the only task for grasp planning is to choose a suitable grasp prototype and to align the hand to the object during the approach phase.…”

Section: Vision-based Grasp Selectionmentioning

confidence: 99%

Grasping and Manipulation of Unknown Objects Based on Visual and Tactile Feedback

Haschke

2015

Motion and Operation Planning of Robotic Systems

View full text Add to dashboard Cite

The sense of touch allows humans and higher animals to perform coordinated and efficient interactions within their environment. Recently, tactile sensor arrays providing high force, spatial, and temporal resolution became available for robotics, which allows us to consider new control strategies to exploit this important and valuable sensory channel for grasping and manipulation tasks. Successful dexterous manipulation strongly depends on tight feedback loops integrating proprioceptive, visual, and tactile feedback. We introduce a framework for tactile servoing that can realize specific tactile interaction patterns, for example to establish and maintain contact (grasping) or to explore and manipulate objects. We demonstrate and evaluate the capabilities of the proposed control framework in a series of preliminary experiments employing a 16 × 16 tactile sensor array attached to a Kuka LWR arm as a large fingertip.

show abstract

Adaptive synergies for the design and control of the Pisa/IIT SoftHand

Cited by 552 publications

References 29 publications

Exploitation of Environmental Constraints in Human and Robotic Grasping

Exploitation of Environmental Constraints in Human and Robotic Grasping

A Fabric-Based Approach for Wearable Haptics

Grasping and Manipulation of Unknown Objects Based on Visual and Tactile Feedback

Contact Info

Product

Resources

About