Search

Your search keyword '"Federico Renda"' showing total 120 results
Start Over Author "Federico Renda"
120 results on '"Federico Renda"'

1. Inverse Dynamics Modeling as a State Estimation Aid for Underwater Robots Navigation

Author

Mohamed El Hanbaly, Saverio Iacoponi, Andrea Infanti, Cesare Stefanini, Giulia de Masi, and Federico Renda

Subjects
AUVs, underwater robotics, autonomous navigation, inertial navigation, swarm robotics, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Reliable navigation and localization systems are crucial for Autonomous Underwater Vehicles (AUVs). The limitations of electromagnetic signals underwater make the use of the Global Positioning System (GPS) impractical. As a result, real-time positioning often relies on expensive sensors like the Doppler Velocity Log (DVL) or acoustic ranging, integrated through sensor fusion techniques. This study investigates and compares three inverse dynamic models designed to estimate the velocity of AUVs using cost-effective Inertial Measurement Units (IMUs) and a model of thrust output based on Pulse Width Modulation (PWM) signals. These velocity estimates are then integrated with an Extended Kalman Filter (EKF) to determine the AUV’s state, and results are validated against ground truth data. Our findings demonstrate the feasibility and effectiveness of these models in providing a reliable and economical solution for low-cost AUV navigation, which is particularly interesting in swarm applications.

Published
2024
Full Text
View/download PDF

2. First-Order Dynamic Modeling and Control of Soft Robots

Author

Thomas George Thuruthel, Federico Renda, and Fumiya Iida

Subjects
soft robotics, control, machine learning, dynamic modeling, first-order dynamics, model reduction, Mechanical engineering and machinery, TJ1-1570, Electronic computers. Computer science, QA75.5-76.95
Abstract

Modeling of soft robots is typically performed at the static level or at a second-order fully dynamic level. Controllers developed upon these models have several advantages and disadvantages. Static controllers, based on the kinematic relations tend to be the easiest to develop, but by sacrificing accuracy, efficiency and the natural dynamics. Controllers developed using second-order dynamic models tend to be computationally expensive, but allow optimal control. Here we propose that the dynamic model of a soft robot can be reduced to first-order dynamical equation owing to their high damping and low inertial properties, as typically observed in nature, with minimal loss in accuracy. This paper investigates the validity of this assumption and the advantages it provides to the modeling and control of soft robots. Our results demonstrate that this model approximation is a powerful tool for developing closed-loop task-space dynamic controllers for soft robots by simplifying the planning and sensory feedback process with minimal effects on the controller accuracy.

Published
2020
Full Text
View/download PDF

3. Structural Dynamics of a Pulsed-Jet Propulsion System for Underwater Soft Robots

Author

Federico Renda, Francesco Giorgio Serchi, Frederic Boyer, and Cecilia Laschi

Subjects
Electronics, TK7800-8360, Electronic computers. Computer science, QA75.5-76.95
Abstract

This paper entails the study of the pulsed-jet propulsion inspired by cephalopods in the frame of underwater bioinspired robotics. This propulsion routine involves a sequence of consecutive cycles of inflation and collapse of an elastic bladder, which, in the robotics artefact developed by the authors, is enabled by a cable-driven actuation of a deformable shell composed of rubber-like materials. In the present work an all-comprehensive formulation is derived by resorting to a coupled approach that comprises of a model of the structural dynamics of the cephalopod-like elastic bladder and a model of the pulsed-jet thrust production. The bladder, or mantle, is modelled by means of geometrically exact, axisymmetric, nonlinear shell theory, which yields an accurate estimation of the forces involved in driving the deformation of the structure in water. By coupling these results with those from a standard thrust model, the behaviour of the vehicle propelling itself in water is derived. The constitutive laws of the shell are also exploited as control laws with the scope of replicating the muscle activation routine observed in cephalopods. The model is employed to test various shapes, material properties and actuation routines of the mantle. The results are compared in terms of speed performance in order to identify suitable design guidelines. Altogether, the model is tested in more than 50 configurations, eventually providing useful insight for the development of more advanced vehicles and bringing evidence of its reliability in studying the dynamics of both man-made cephalopod-inspired robots and live specimens.

Published
2015
Full Text
View/download PDF

49. Flagellate Underwater Robotics at Macroscale: Design, Modeling, and Characterization

Author

Madiha Farman, Costanza Armanini, Marcello Calisti, Cesare Stefanini, Francesco Giorgio-Serchi, and Federico Renda

Subjects
Computer science, Soft robotics, Mechanical engineering, Thrust, Ranging, Kinematics, Underwater robotics, H671 Robotics, Computer Science Applications, Characterization (materials science), Control and Systems Engineering, Electrical and Electronic Engineering, Underwater, Actuator
Abstract

Prokaryotic flagellum is considered as the only known example of a biological “wheel,” a system capable of converting the action of rotatory actuator into a continuous propulsive force. For this reason, flagella are an interesting case study in soft robotics and they represent an appealing source of inspiration for the design of underwater robots. A great number of flagellum-inspired devices exists, but these are all characterized by a size ranging in the micrometer scale and mostly realized with rigid materials. Here, we present the design and development of a novel generation of macroscale underwater propellers that draw their inspiration from flagellated organisms. Through a simple rotatory actuation and exploiting the capability of the soft material to store energy when interacting with the surrounding fluid, the propellers attain different helical shapes that generate a propulsive thrust. A theoretical model is presented, accurately describing and predicting the kinematic and the propulsive capabilities of the proposed solution. Different experimental trials are presented to validate the accuracy of the model and to investigate the performance of the proposed design. Finally, an underwater robot prototype propelled by four flagellar modules is presented.

Published
2022
Full Text
View/download PDF

50. SoRoSim: A MATLAB Toolbox for Hybrid Rigid-Soft Robots Based on the Geometric Variable-Strain Approach

Author

Anup Teejo Mathew, Ikhlas Mohamed Ben Hmida, Costanza Armanini, Frederic Boyer, and Federico Renda

Subjects
FOS: Computer and information sciences, Computer Science - Robotics, Control and Systems Engineering, FOS: Physical sciences, Physics - Applied Physics, Applied Physics (physics.app-ph), Electrical and Electronic Engineering, Robotics (cs.RO), Computer Science Applications
Abstract

Soft robotics has been a trending topic within the robotics community for almost two decades. However, available tools for the modeling and analysis of soft robots are still limited. This paper introduces a user-friendly MATLAB toolbox, Soft Robot Simulator (SoRoSim), that integrates the Geometric Variable Strain (GVS) model of Cosserat rods to facilitate the static and dynamic analysis of soft, rigid, or hybrid robotic systems. We present a brief overview of the design and structure of the toolbox and validate it by comparing its results with those published in the literature. To highlight the toolbox's potential to efficiently model, simulate, optimize, and control various robotic systems, we demonstrate four sample applications. The demonstrated applications explore different actuator and external loading conditions of single-, branched-, open-, and closed-chain robotic systems. We think that the soft-robotics research community will significantly benefit from the SoRoSim toolbox for a wide variety of applications., Comment: 17 pages including reference, 11 figures and 2 tables

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results