Marcello Bonfè scite author profile

Introducing some form of autonomy in robotic surgery is being considered by the medical community to better exploit the potential of robots in the operating room. However, significant technological steps have to occur before even the smallest autonomous task is ready to be presented to the regulatory authorities. In this paper, we address the initial steps of this process, in particular the development of control concepts satisfying the basic safety requirements of robotic surgery, i.e., providing the robot with the necessary dexterity and a stable and smooth behavior of the surgical tool. Two specific situations are considered: the automatic adaptation to changing tissue stiffness and the transition from autonomous to teleoperated mode. These situations replicate real-life cases when the surgeon adapts the stiffness of her/his arm to penetrate tissues of different consistency and when, due to an unexpected event, the surgeon has to take over the control of the surgical robot. To address the first case, we propose a passivity-based interactive control architecture that allows us to implement stable time-varying interactive behaviors. For the second case, we present a two-layered bilateral control architecture that ensures a stable behavior during the transition between autonomy and teleoperation and, after the switch, limits the effect of initial mismatch between master and slave poses. The proposed solutions are validated in the realistic surgical scenario developed within the EU-funded I-SUR project, using a surgical robot prototype specifically designed for the autonomous execution of surgical tasks like the insertion of needles into the human body

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A variable admittance control strategy for stable physical human–robot interaction

Ferraguti

Landi

Sabattini

et al. 2019

The International Journal of Robotics Research

132

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Admittance control allows a desired dynamic behavior to be reproduced on a non-backdrivable manipulator and it has been widely used for interaction control and, in particular, for human–robot collaboration. Nevertheless, stability problems arise when the environment (e.g. the human) the robot is interacting with becomes too stiff. In this paper, we investigate the stability issues related to a change of stiffness of the human arm during the interaction with an admittance-controlled robot. We propose a novel method for detecting the rise of instability and a passivity-preserving strategy for restoring a stable behavior. The results of the paper are validated on two robotic setups and with 50 users performing two tasks that emulate industrial operations.

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Design of residual generators and adaptive filters for the FDI of aircraft model sensors

Castaldi

Geri

Bonfè

et al. 2010

Control Engineering Practice

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A SysML-Based Methodology for Manufacturing Machinery Modeling and Design

Bassi

Secchi

Bonfè

et al. 2011

IEEE/ASME Trans. Mechatron.

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This paper describes a modeling methodology to support the design process of complex systems. The main challenge in modern industrial applications is the sheer volume of data involved in the design process. While using high-level abstraction is necessary to manage this data and analyze the system “as a whole”, designers need also to retain all the lowlevel information of the system, in order to be able to perform optimizations and modifications at later times. The solution proposed here is to use a hierarchy of models, each one describing the system at different levels of abstraction, and arrange them in such a way that it is possible to easily “map” each level onto the others. The topmost layer of the system description is expressed in System Modeling Language (SysML), a generalpurpose modeling language based on UML

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Design patterns for model-based automation software design and implementation

Bonfè

Fantuzzi

Secchi

2013

Control Engineering Practice

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Marcello Bonfè

An Energy Tank-Based Interactive Control Architecture for Autonomous and Teleoperated Robotic Surgery

A variable admittance control strategy for stable physical human–robot interaction

Design of residual generators and adaptive filters for the FDI of aircraft model sensors

A SysML-Based Methodology for Manufacturing Machinery Modeling and Design

Design patterns for model-based automation software design and implementation

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