Feasibility of teleoperations with multi-fingered robotic hand for safe extravehicular manipulations

Saggio, Giovanni; Bizzarri, Mariano

doi:10.1016/j.ast.2014.05.018

Cited by 23 publications

(10 citation statements)

References 26 publications

(43 reference statements)

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“…Differently from piezoelectricity in which a mechanical deformation induces the generation of an electronic potential, [12] piezoresistivity is based on the spacing or the slippage of the conductive domains caused by the application of mechanical strain within the material structure, finally increasing the electrical resistance [13] . This property is fundamental for emerging applications of wearable electronics, [14] including electronics skins, [15] human motion detection, [16] human‐machine interface, [16a,17] and other ones [18] . In particular, bending sensors [19] represents one of the most technologically relevant.…”

Section: Introductionmentioning

confidence: 99%

Bending Sensors Based on Thin Films of Semitransparent Bithiophene‐Fulleropyrrolidine Bisadducts

et al. 2020

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A novel bithiophene-fulleropyrrolidine bisadducts system (bis-Th2PC 60) was synthesized and electropolymerized by chronoamperometry onto flexible ITO/PET substrates. The resulting semitransparent thin film was characterized by XPS, FT-IR, cyclic voltammetry and optical techniques, confirming the good outcome of the electropolymerization process. AFM investigations permitted to highlight an inherent disordered granular morphology, in which the grain-to-grain separation depends upon the application of bending. The electrical resistance of the thin film was characterized as a function of bending (in the range 0°-90°), showing promising responsivity to low bending angles (10°-30°). The ΔR/R 0 variations turn out to be 8 %,16 % and 20 % for bending angles equal to 10°, 20°and 30°, respectively. This study represents a first step towards the understanding of piezoresistive properties in electropolymerized fullerenes-based thin films, opening up applications as bending sensor.

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Section: Introductionmentioning

confidence: 99%

Bending Sensors Based on Thin Films of Semitransparent Bithiophene‐Fulleropyrrolidine Bisadducts

et al. 2020

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“…1) based on acquired experiences for nonsurgical purposes. [14][15][16][17][18] The glove was equipped with 14 flex sensors (by Flexpoint Sensor Systems, Inc., Draper, UT) and a 3-axis accelerometer (ADXL335, by Analog Devices, Inc., Norwood, MA) able to measure the flex/ extension capabilities of the finger joints of a human hand, plus the wrist movements. Flex sensors were placed on distal interphalangeal, proximal interphalangeal, and metacarpophalangeal finger joints, and the accelerometer was placed on backside of the hand (Fig.…”

Section: Methodsmentioning

confidence: 99%

Objective Surgical Skill Assessment: An Initial Experience by Means of a Sensory Glove Paving the Way to Open Surgery Simulation?

Saggio

Lazzaro

Sbernini

et al. 2015

Journal of Surgical Education

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“…Datagloves have been used since about 30 years to measure human hand movements for a number of applications [20], including the control of robot hands [10], [21]- [23]. In our experiments we use the Immersion CyberGlove-II dataglove [24], which is considered the state-of-the-art input device for recording human hand postures [20].…”

Section: B the Cyberglove-ii Dataglovementioning

confidence: 99%

Benchmarking the Grasping Capabilities of the iCub Hand With the YCB Object and Model Set

Jamone

Bernardino

Santos-Victor

2016

IEEE Robot. Autom. Lett.

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The paper reports an evaluation of the iCub grasping capabilities, performed using the YCB Object and Model Set. The goal is to understand what kind of objects the iCub dexterous hand can grasp, and with what degree of robustness and flexibility, given the best possible control strategy. Therefore, the robot fingers are directly controlled by a human expert using a dataglove: in other words, the human brain is employed as the best possible controller. Through this technique, we provide a baseline for researchers who want to evaluate the performance of their grasping controller. By using a widespread robotic platform and a publicly available set of objects, we believe that many researchers can directly benefit from this resource; moreover, what we propose is a general methodology for benchmarking of grasping and manipulation that can be applied to any dexterous robotic hand.

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Feasibility of teleoperations with multi-fingered robotic hand for safe extravehicular manipulations

Cited by 23 publications

References 26 publications

Bending Sensors Based on Thin Films of Semitransparent Bithiophene‐Fulleropyrrolidine Bisadducts

Bending Sensors Based on Thin Films of Semitransparent Bithiophene‐Fulleropyrrolidine Bisadducts

Objective Surgical Skill Assessment: An Initial Experience by Means of a Sensory Glove Paving the Way to Open Surgery Simulation?

Benchmarking the Grasping Capabilities of the iCub Hand With the YCB Object and Model Set

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