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6 results on '"Laschi, C"'

2. Design concept and validation of a robotic arm inspired by the octopus

Author

Cianchetti, M., Arienti, A., Follador, M., Mazzolai, B., Dario, P., and Laschi, C.

Subjects
*BIONICS, *ROBOTICS, *OCTOPUSES, *ARTIFICIAL intelligence, *BIOMEDICAL materials, *MECHANICAL behavior of materials, *ROBOT motion
Abstract

Abstract: The octopus is an invertebrate sea animal, considered as an interesting model of inspiration in robotics, due to its high dexterity, variable stiffness, and very complex behaviours, if compared with its position in the evolutionary scale. This paper reports the design of an artificial muscular hydrostat for developing an octopus-like robot. The experimental study consists of the fabrication of a set of mock-ups demonstrating some of the key features and patterns of movement of the octopus arm. The experimental trials performed with the different mock-ups demonstrated the suitability of the silicone materials used and the patterns of actuators activation to replicate the typical octopus movements of elongation, shortening, bending, and reaching. They also confirm that control is simplified by the arrangement of muscles as well as by the mechanical properties of the muscular hydrostat. [Copyright &y& Elsevier]

Published
2011
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3. Sensing device for measuring infants’ grasping actions

Author

Del Maestro, M., Cecchi, F., Serio, S.M., Laschi, C., and Dario, P.

Subjects
*DETECTORS, *INFANTS, *PRESSURE transducers, *MECHANICAL models, *MOTOR ability in children, *VISCOELASTIC materials, *SILICONES
Abstract

Abstract: The study and measurement of grasping actions and forces in humans is important in a variety of contexts. In infants, it can give insights on the neuro-motor development and on pathological dysfunctions, while it poses functional and operative requirements that are not fully matched by current sensing technology. Novel approaches for measuring infants’ grasping actions are based on sensorized toys usable in natural settings. In this paper, we present a sensing device for measuring grasping force in 4–9-month-old infants. Starting from technical and clinical specifications, we designed and developed a novel device made by silicone, shaped as a ring toy and equipped with a pressure sensor, able to measure the pressure exerted by the infant''s hand in the range of 0–5psi. A mechanical model of the material has been developed and tensile compression tests have been executed in order to assess the mechanical and electrical characteristics of the sensing device. The proposed device complies with the (technical and clinical) specifications and results suitable for measuring the grasping forces of the targeted infants, and finally for monitoring infants’ motor development. The theoretical model developed and the methodology for designing and characterizing the sensing device allow for easy re-design and adaptation of the sensing device and consideration of a variety of possible applications. [Copyright &y& Elsevier]

Published
2011
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4. A new design methodology of electrostrictive actuators for bio-inspired robotics

Author

Cianchetti, M., Mattoli, V., Mazzolai, B., Laschi, C., and Dario, P.

Subjects
*ACTUATOR design & construction, *METALLIC films, *ELECTROCHEMICAL apparatus, *BIOMIMETIC chemicals, *ROBOTICS, *BIOSENSORS, *BIOLOGICAL mathematical modeling
Abstract

Abstract: At present advanced robotics concepts require new and more suitable components to be exploited, especially in the fields of the biomimetic and soft robotics. In this sense, the actuation system represents one of the most limiting factors for the realization of robots with bio-inspired features and performances. This paper presents a new soft actuators based on electroactive polymers (EAPs) technology. The actuator is composed of a pre-stretched silicone film sputtered with a very thin gold film on both sides, working as electrodes. A particular folded geometry, implemented through an innovative fabrication process, allows to exploit the electrostrictive effect and to develop soft actuators suitable in many applications where softness and flexibility are necessary. The manufactured prototypes were developed on the basis of a parametric model that takes into account all geometric parameters and material characteristics. The proposed model is useful to estimate the performances of the actuator and to improve them. [Copyright &y& Elsevier]

Published
2009
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5. I-Support: A robotic platform of an assistive bathing robot for the elderly population.

Author

Zlatintsi, A., Dometios, A.C., Kardaris, N., Rodomagoulakis, I., Koutras, P., Papageorgiou, X., Maragos, P., Tzafestas, C.S., Vartholomeos, P., Hauer, K., Werner, C., Annicchiarico, R., Lombardi, M.G., Adriano, F., Asfour, T., Sabatini, A.M., Laschi, C., Cianchetti, M., Güler, A., and Kokkinos, I.

Subjects
*FRAIL elderly, *HUMAN behavior, *USER-centered system design, *HUMAN activity recognition, *ROBOT motion, *ROBOTS, *HUMAN-robot interaction, *ROBOTICS
Abstract

In this paper we present a prototype integrated robotic system, the I-Support bathing robot, that aims at supporting new aspects of assisted daily-living activities on a real-life scenario. The paper focuses on describing and evaluating key novel technological features of the system, with the emphasis on cognitive human–robot interaction modules and their evaluation through a series of clinical validation studies. The I-Support project on its whole has envisioned the development of an innovative, modular, ICT-supported service robotic system that assists frail seniors to safely and independently complete an entire sequence of physically and cognitively demanding bathing tasks, such as properly washing their back and their lower limbs. A variety of innovative technologies have been researched and a set of advanced modules of sensing, cognition, actuation and control have been developed and seamlessly integrated to enable the system to adapt to the target population abilities. These technologies include: human activity monitoring and recognition, adaptation of a motorized chair for safe transfer of the elderly in and out the bathing cabin, a context awareness system that provides full environmental awareness, as well as a prototype soft robotic arm and a set of user-adaptive robot motion planning and control algorithms. This paper focuses in particular on the multimodal action recognition system, developed to monitor, analyze and predict user actions with a high level of accuracy and detail in real-time, which are then interpreted as robotic tasks. In the same framework, the analysis of human actions that have become available through the project's multimodal audio–gestural dataset, has led to the successful modeling of Human–Robot Communication, achieving an effective and natural interaction between users and the assistive robotic platform. In order to evaluate the I-Support system, two multinational validation studies were conducted under realistic operating conditions in two clinical pilot sites. Some of the findings of these studies are presented and analyzed in the paper, showing good results in terms of: (i) high acceptability regarding the system usability by this particularly challenging target group, the elderly end-users, and (ii) overall task effectiveness of the system in different operating modes. • Prototype robotic system supporting new aspects of assisted daily-living activities. • Presenting novel technologies regarding sensing, cognition, actuation and control. • Real-time multimodal action recognition system to monitor and predict user actions. • Multimodal audio–gestural dataset for learning of Human–Robot Communication. • Clinical validation studies showing high acceptability by the elderly end-users. [ABSTRACT FROM AUTHOR]

Published
2020
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