Your search keyword '"Robotics"' showing total 1,849 results

101. Friction-Inclusive Modeling of Sliding Contact Transmission Systems in Robotics

Author

Christos Bergeles, Anestis Mablekos-Alexiou, and Lyndon da Cruz

Subjects

Worm drive, Framing (visual arts), business.product_category, business.industry, Computer science, Robotics, Transmission system, Computer Science Applications, Nonlinear programming, Computer Science::Robotics, Transmission (telecommunications), Control and Systems Engineering, Control theory, Coulomb, Robot, Artificial intelligence, Electrical and Electronic Engineering, business

Abstract

This article presents a unified mathematical approach for modeling, identifying, and solving the friction-inclusive dynamics of robotic mechanisms driven by sliding contact transmission systems. This approach is applied to the most common industrial screw-based drives: 1) the worm drive, 2) the simple lead screw drive, and 3) the antibacklash lead screw drive. The resulting dynamics, handily transferable to single and multiple degree of freedom (DoF) manipulators, are complemented with an algorithm for the solution of the forward dynamics problem as well as a framework for friction identification based on nonlinear optimization. The presented theory is experimentally tested on single-DoF screw-based drives for a variety of payloads and at different operation speeds. Simulation and parameter identification results using the classical Coulomb model, the Coulomb model with Stribeck friction, and the Armstrong model with Stribeck friction, rising static friction, and frictional memory are compared with experimental data, showcasing the effectiveness of the presented approach toward framing the concepts of friction and motion transmission into a robotics setting.

Published

2021

102. Trajectory Planning for Quadrotor Swarms.

Author

Honig, Wolfgang, Preiss, James A., Kumar, T. K. Satish, Sukhatme, Gaurav S., and Ayanian, Nora

Subjects

*QUADROTOR helicopters, *DRONE aircraft, *ROBOTICS, *TRAJECTORIES (Mechanics), *ROBOTS, *WAREHOUSES

Abstract

We describe a method for multirobot trajectory planning in known, obstacle-rich environments. We demonstrate our approach on a quadrotor swarm navigating in a warehouse setting. Our method consists of following three stages: 1) roadmap generation that generates sparse roadmaps annotated with possible interrobot collisions; 2) discrete planning that finds valid execution schedules in discrete time and space; 3) continuous refinement that creates smooth trajectories. We account for the downwash effect of quadrotors, allowing safe flight in dense formations. We demonstrate computational efficiency in simulation with up to 200 robots and physical plausibility with an experiment on 32 nano-quadrotors. Our approach can compute safe and smooth trajectories for hundreds of quadrotors in dense environments with obstacles in a few minutes. [ABSTRACT FROM AUTHOR]

Published

2018

103. A Distributed Control Approach to Formation Balancing and Maneuvering of Multiple Multirotor UAVs.

Author

Liu, Yuyi, Montenbruck, Jan Maximilian, Zelazo, Daniel, Odelga, Marcin, Rajappa, Sujit, Bulthoff, Heinrich H., Allgower, Frank, and Zell, Andreas

Subjects

*DRONE aircraft, *ROBOTICS, *ALGORITHMS, *MULTIAGENT systems, *HUMAN-robot interaction, *FLIGHT control systems, *PREDICTIVE control systems

Abstract

In this paper, we propose and experimentally verify a distributed formation control algorithm for a group of multirotor unmanned aerial vehicles (UAVs). The algorithm brings the whole group of UAVs simultaneously to a prescribed submanifold that determines the formation shape in an asymptotically stable fashion in two- and three-dimensional environments. The complete distributed control framework is implemented with the combination of a fast model predictive control method executed at 50 Hz on low-power computers onboard multirotor UAVs and validated via a series of hardware-in-the-loop simulations and real-robot experiments. The experiments are configured to study the control performance in various formation cases of arbitrary time-varying (e.g., expanding, shrinking, or moving) shapes. In the actual experiments, up to four multirotors have been implemented to form arbitrary triangular, rectangular, and circular shapes drawn by the operator via a human–robot interaction device. We also carry out hardware-in-the-loop simulations using up to six onboard computers to achieve spherical formations and a formation moving through obstacles. [ABSTRACT FROM AUTHOR]

Published

2018

104. A Survey on Aerial Swarm Robotics.

Author

Chung, Soon-Jo, Paranjape, Aditya Avinash, Dames, Philip, Shen, Shaojie, and Kumar, Vijay

Subjects

*ROBOTICS, *DRONE aircraft, *TRAJECTORIES (Mechanics), *ALGORITHMS, *DEGREES of freedom, *HARDWARE

Abstract

The use of aerial swarms to solve real-world problems has been increasing steadily, accompanied by falling prices and improving performance of communication, sensing, and processing hardware. The commoditization of hardware has reduced unit costs, thereby lowering the barriers to entry to the field of aerial swarm robotics. A key enabling technology for swarms is the family of algorithms that allow the individual members of the swarm to communicate and allocate tasks amongst themselves, plan their trajectories, and coordinate their flight in such a way that the overall objectives of the swarm are achieved efficiently. These algorithms, often organized in a hierarchical fashion, endow the swarm with autonomy at every level, and the role of a human operator can be reduced, in principle, to interactions at a higher level without direct intervention. This technology depends on the clever and innovative application of theoretical tools from control and estimation. This paper reviews the state of the art of these theoretical tools, specifically focusing on how they have been developed for, and applied to, aerial swarms. Aerial swarms differ from swarms of ground-based vehicles in two respects: they operate in a three-dimensional space and the dynamics of individual vehicles adds an extra layer of complexity. We review dynamic modeling and conditions for stability and controllability that are essential in order to achieve cooperative flight and distributed sensing. The main sections of this paper focus on major results covering trajectory generation, task allocation, adversarial control, distributed sensing, monitoring, and mapping. Wherever possible, we indicate how the physics and subsystem technologies of aerial robots are brought to bear on these individual areas. [ABSTRACT FROM AUTHOR]

Published

2018

105. Robotic Herding of a Flock of Birds Using an Unmanned Aerial Vehicle.

Author

Paranjape, Aditya A., Chung, Soon-Jo, Kim, Kyunam, and Shim, David Hyunchul

Subjects

*ROBOTICS, *DRONE aircraft, *ROBOTS, *ALGORITHMS, *AIRPORT bird control, *HEURISTIC, *COMPUTER simulation

Abstract

In this paper, we derive an algorithm for enabling a single robotic unmanned aerial vehicle to herd a flock of birds away from a designated volume of space, such as the air space around an airport. The herding algorithm, referred to as the $m$ -waypoint algorithm, is designed using a dynamic model of bird flocking based on Reynolds’ rules. We derive bounds on its performance using a combination of reduced-order modeling of the flock's motion, heuristics, and rigorous analysis. A unique contribution of the paper is the experimental demonstration of several facets of the herding algorithm on flocks of live birds reacting to a robotic pursuer. The experiments allow us to estimate several parameters of the flocking model, and especially the interaction between the pursuer and the flock. The herding algorithm is also demonstrated using numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2018

106. Informed Sampling for Asymptotically Optimal Path Planning.

Author

Gammell, Jonathan D., Barfoot, Timothy D., and Srinivasa, Siddhartha S.

Subjects

*ROBOTIC path planning, *ROBOTICS, *HEURISTIC, *EUCLIDEAN distance, *ALGORITHMS

Abstract

Anytime almost-surely asymptotically optimal planners, such as RRT*, incrementally find paths to every state in the search domain. This is inefficient once an initial solution is found, as then only states that can provide a better solution need to be considered. Exact knowledge of these states requires solving the problem but can be approximated with heuristics. This paper formally defines these sets of states and demonstrates how they can be used to analyze arbitrary planning problems. It uses the well-known $L^2$ norm (i.e., Euclidean distance) to analyze minimum-path-length problems and shows that existing approaches decrease in effectiveness factorially (i.e., faster than exponentially) with state dimension. It presents a method to address this curse of dimensionality by directly sampling the prolate hyperspheroids (i.e., symmetric $n$ -dimensional ellipses) that define the $L^2$ informed set. The importance of this direct informed sampling technique is demonstrated with Informed RRT*. This extension of RRT* has less theoretical dependence on state dimension and problem size than existing techniques and allows for linear convergence on some problems. It is shown experimentally to find better solutions faster than existing techniques on both abstract planning problems and HERB, a two-arm manipulation robot. [ABSTRACT FROM AUTHOR]

Published

2018

107. Robust Tactile Descriptors for Discriminating Objects From Textural Properties via Artificial Robotic Skin.

Author

Kaboli, Mohsen and Cheng, Gordon

Subjects

*ROBOTICS, *TACTILE sensors, *ACCELEROMETERS, *CAPACITIVE sensors, *PRESSURE sensors, *SENSORY perception

Abstract

In this paper, we propose a set of novel tactile descriptors to enable robotic systems to extract robust tactile information during tactile object explorations, regardless of the number of the tactile sensors, sensing technologies, type of exploratory movements, and duration of the objects’ surface exploration. The performance and robustness of the tactile descriptors are verified by testing on four different sensing technologies (dynamic pressure sensors, accelerometers, capacitive sensors, and impedance electrode arrays) with two robotic platforms (one anthropomorphic hand and one humanoid), and with a large set of objects and materials. Using our proposed tactile descriptors, the Shadow Hand, which has multimodal robotic skin on its fingertips, successfully classified 120 materials (100% accuracy) and 30 in-hand objects (98% accuracy) with regular and irregular textural structure by executing human-like active exploratory movements on their surface. The robustness of the proposed descriptors was assessed further during the large object discrimination with a humanoid. With a large sensing area on its upper body, the humanoid classified 120 large objects with multiple weights and various textures while the objects slid between its sensitive hands, arms, and chest. The achieved 90% recognition rate shows that the proposed tactile descriptors provided robust tactile information from the large number of tactile signals for identifying large objects via their surface texture regardless of their weight. [ABSTRACT FROM AUTHOR]

Published

2018

108. Considering Uncertainty in Optimal Robot Control Through High-Order Cost Statistics.

Author

Medina, Jose R. and Hirche, Sandra

Subjects

*ROBOT control systems, *ROBOTICS, *STOCHASTIC control theory, *SENSORIMOTOR cortex, *NEUROSCIENTISTS, *CUMULANTS

Abstract

As the application of probabilistic models in robotic applications increases, a systematic robot control approach considering the effects of uncertainty becomes indispensable. Inspired by human sensorimotor findings, in this paper, we study the stochastic optimal control problem with high-order cost statistics in order to synthesize uncertainty-dependent actions in robotic scenarios with multiple uncertainty sources. We present locally optimal risk-sensitive and cost-cumulant solutions for settings with nonlinear dynamics, multiple additive uncertainty sources, and nonquadratic costs. The influence of each uncertainty source on the cost can be individually parameterized offering additional flexibility in the control design. We further analyze the case in which the static uncertain parameters are involved. The simulations of several linear and nonlinear settings with nonquadratic costs and an experiment on a real robotic platform validate our approach and illustrate its peculiarities. [ABSTRACT FROM AUTHOR]

Published

2018

109. Fast Gait Mode Detection and Assistive Torque Control of an Exoskeletal Robotic Orthosis for Walking Assistance.

Author

Huo, Weiguang, Mohammed, Samer, Amirat, Yacine, and Kong, Kyoungchul

Subjects

*GAIT in humans, *ROBOTICS, *TORQUE control, *HUMAN locomotion, *ROBOTIC exoskeletons, *ELECTROMYOGRAPHY, *LEG, *ACTUATORS

Abstract

Gait modes, such as level walking, stair ascent/descent, and ramp ascent/descent, show different lower-limb kinematic and kinetic characteristics. Therefore, an accurate detection of these modes is critical for a wearable robot to provide appropriate power assistance. In this paper, a fast gait-mode-detection method based on a body sensor system is proposed. A fuzzy logic algorithm is used to estimate the likelihoods of gait modes in real time. Since the proposed fast gait mode detection makes it possible to select appropriate kinematic and kinetic models for each gait mode, assistive torques required for assisting the human motions can be obtained more naturally and immediately. The proposed methods are all verified by experiments with a lower-limb exoskeletal assistive robot with transparent actuation by series elastic actuators, called the exoskeletal robotic orthosis for walking assistance. Four healthy subjects participated in the experiments. All subjects were asked to perform different gait modes using their normal and simulated abnormal gaits, i.e., blocking the knee joint of one leg during walking. Latency and success rate of gait mode detection are selected as performance criteria. The effectiveness of the proposed gait-mode-based assistive strategy is evaluated using electromyography muscular activities. [ABSTRACT FROM AUTHOR]

Published

2018

110. Zero Step Capturability for Legged Robots in Multicontact.

Author

Del Prete, Andrea, Tonneau, Steve, and Mansard, Nicolas

Subjects

*ROBOTICS, *HUMANOID robots, *CENTER of mass, *ANGULAR momentum (Mechanics), *ALGORITHMS, *VELOCITY

Abstract

The ability to anticipate a fall is fundamental for any robot that has to balance. Currently, fast fall-prediction algorithms only exist for simple models, such as the linear inverted pendulum model (LIPM), whose validity breaks down in multicontact scenarios (i.e., when contacts are not limited to a flat ground). This paper presents a fast fall-prediction algorithm based on the point-mass model, which remains valid in multicontact scenarios. The key assumption of our algorithm is that, in order to come to a stop without changing its contacts, a robot only needs to accelerate its center of mass in the direction opposite to its velocity. This assumption allows us to predict the fall by means of a convex optimal control problem, which we solve with a fast custom algorithm (less than 11 ms of computation time). We validated the approach through extensive simulations with the humanoid robot HRP-2 in randomly-sampled scenarios. Comparisons with standard LIPM-based methods demonstrate the superiority of our algorithm in predicting the fall of the robot, when controlled with a state-of-the-art balance controller. This paper lays the foundations for the solution of the challenging problem of push recovery in multicontact scenarios. [ABSTRACT FROM AUTHOR]

Published

2018

111. Joint Coverage, Connectivity, and Charging Strategies for Distributed UAV Networks.

Author

Trotta, Angelo, Felice, Marco Di, Montori, Federico, Chowdhury, Kaushik R., and Bononi, Luciano

Subjects

*ROBOTICS, *DRONE aircraft, *SENSOR networks, *ALGORITHMS, *STORAGE batteries, *GAME theory

Abstract

This paper proposes deployment strategies for consumer unmanned aerial vehicles (UAVs) to maximize the stationary coverage of a target area and to guarantee the continuity of the service through energy replenishment operations at ground charging stations. The three main contributions of our work are as follows. 1) A centralized optimal solution is proposed for the joint problem of UAV positioning for a target coverage ratio and scheduling the charging operations of the UAVs that involves travel to the ground station. 2) A distributed game-theory-based scheduling strategy is proposed using normal-form games with rigorous analysis on performance bounds. Furthermore, a bio-inspired scheme using attractive/repulsive spring actions are used for distributed positioning of the UAVs. 3) The cost-benefit tradeoffs of different levels of cooperation among the UAVs for the distributed charging operations is analyzed. This paper demonstrates that the distributed deployment using only 1-hop messaging achieves approximation of the centrally computed optimum, in terms of coverage and lifetime. [ABSTRACT FROM AUTHOR]

Published

2018

112. Physically Plausible Wrench Decomposition for Multieffector Object Manipulation.

Author

Donner, Philine, Endo, Satoshi, and Buss, Martin

Subjects

*HAPTIC devices, *ROBOTICS, *HUMAN-robot interaction, *WRENCHES, *TORQUE, *OBJECT manipulation

Abstract

When manipulating an object with multiple effectors such as in multidigit grasping or multiagent collaboration, forces and torques (i.e., wrench) applied to the object at different contact points generally do not fully contribute to the resultant object wrench, but partly compensate each other. The current literature, however, lacks a physically plausible decomposition of the applied wrench into its manipulation and internal components. We formulate the wrench decomposition as a convex optimization problem, minimizing the Euclidean norms of manipulation forces and torques. Physical plausibility in the optimization solution is ensured by constraining the internal and manipulation wrench by the applied wrench. We analyze specific cases of three-fingered grasping and 2-D beam manipulation, and show the applicability of our method to general object manipulation with multiple effectors. The wrench decomposition method is then extended to quantification of measures that are important in evaluating physical human–human and human–robot interaction tasks. We validate our approach via comparison to the state of the art in simulation and via application to a human–human object transport study. [ABSTRACT FROM AUTHOR]

Published

2018

113. Resilient, Provably-Correct, and High-Level Robot Behaviors.

Author

Wong, Kai Weng, Ehlers, Rudiger, and Kress-Gazit, Hadas

Subjects

*ROBOTS, *ROBOTICS, *AUTONOMOUS vehicles, *ALGORITHMS, *PROGRAMMABLE controllers

Abstract

Whether robot controllers are manually designed or synthesized from high-level task specifications, assumptions about the environment need to be made, which can involve adversarial events or cooperative robots. In either case, if these assumptions are violated at runtime, the robot will fail to fulfill its task and will likely do something unexpected. In this paper, we focus on controllers synthesized from linear temporal logic. We tackle the problem of making these controllers robust against environment assumption violations that are common in robot execution. Our solution is a three-layer system: first, we propose an offline approach that accounts for transient violations such that the robot can still complete its task after temporary anomalies; the second layer is an online approach that automatically relaxes the environment assumptions to better capture environment behaviors and that allows the robot to react accordingly; and, finally, we automatically modify the actual environment behaviors, when possible, through negotiation with one of the environment robots operating in the workspace, such that our assumptions are met by the other robot and both robots accomplish their tasks. [ABSTRACT FROM AUTHOR]

Published

2018

114. Resolving Occlusion in Active Visual Target Search of High-Dimensional Robotic Systems.

Author

Radmard, Sina, Meger, David, Little, James J., and Croft, Elizabeth A.

Subjects

*ALGORITHMS, *ROBOTICS, *SYSTEMS design, *HIGH-dimensional model representation, *MATHEMATICAL models

Abstract

The article discusses an algorithm designed to address visual occlusions that disrupt visual tracking of high-dimensional eye-in-hand robotic systems. It provides the capabilities of the algorithm through a simulation and real-world experiment, showing that the solvers outperform common approaches.

Published

2018

115. Grasping Without Squeezing: Design and Modeling of Shear-Activated Grippers.

Author

Hawkes, Elliot Wright, Jiang, Hao, Christensen, David L., Han, Amy K., and Cutkosky, Mark R.

Subjects

*SHEAR (Mechanics), *ROBOT control systems, *FRICTION, *MECHANICAL loads, *ADHESIVES, *ROBOTICS

Abstract

Grasping objects that are too large to envelop is traditionally achieved using friction that is activated by squeezing. We present a family of shear-activated grippers that can grasp such objects without the need to squeeze. When a shear force is applied to the gecko-inspired material in our grippers, adhesion is turned on; this adhesion in turn results in adhesion-controlled friction, a friction force that depends on adhesion rather than a squeezing normal force. Removal of the shear force eliminates adhesion, allowing easy release of an object. A compliant shear-activated gripper without active sensing and control can use the same light touch to lift objects that are soft, brittle, fragile, light, or very heavy. We present three grippers, the first two designed for curved objects, and the third for nearly any shape. Simple models describe the grasping process, and empirical results verify the models. The grippers are demonstrated on objects with a variety of shapes, materials, sizes, and weights. [ABSTRACT FROM AUTHOR]

Published

2018

116. General Lagrange-Type Jacobian Inverse for Nonholonomic Robotic Systems.

Author

Tchon, Krzysztof and Ratajczak, Joanna

Subjects

*LAGRANGE equations, *JACOBIAN matrices, *ROBOTICS, *NONHOLONOMIC dynamical systems, *ALGORITHMS

Abstract

This paper discusses the nonholonomic robotic systems whose motion constraints assume the Pfaffian form, and the equations of motion are represented by driftless control systems with outputs. By reference to the end point map of such a control system, we define the system's Jacobian and study Jacobian motion-planning algorithms. A new Lagrange-type Jacobian inverse, referred to as the General Lagrangian Jacobian Inverse (GLJI), is designed as the solution of an optimal control problem with a Lagrange-type objective function. Singularities of GLJI are examined. A special choice of the objective function illustrates features of GLJI. A new motion-planning algorithm based on GLJI is proposed. Theoretical arguments are illustrated with a motion-planning problem of a space robot. [ABSTRACT FROM PUBLISHER]

Published

2018

117. Fail-Safe Motion Planning for Online Verification of Autonomous Vehicles Using Convex Optimization

Author

Christian Pek and Matthias Althoff

Subjects

0209 industrial biotechnology, Computer science, Autonomous vehicles, 02 engineering and technology, On-line verifications, Urban traffic, Verification techniques, Motion (physics), Trajectories, Task (project management), 020901 industrial engineering & automation, In-depth analysis, fail-safe operation, Motion planning, Electrical and Electronic Engineering, formal verification, Control engineering, Agricultural robots, Robotics, motion planning, Convex optimization, Computer Science Applications, Real time, set-based computation, Robotteknik och automation, Control and Systems Engineering, Accidents, Fail safes, Premise, Trajectory, Robot, Fail-safe, safe states

Abstract

Safe motion planning for autonomous vehicles is a challenging task, since the exact future motion of other traffic participant is usually unknown. In this article, we present a verification technique ensuring that autonomous vehicles do not cause collisions by using fail-safe trajectories. Fail-safe trajectories are executed if the intended motion of the autonomous vehicle causes a safety-critical situation. Our verification technique is real-time capable and operates under the premise that intended trajectories are only executed if they have been verified as safe. The benefits of our proposed approach are demonstrated in different scenarios on an actual vehicle. Moreover, we present the first in-depth analysis of our verification technique used in dense urban traffic. Our results indicate that fail-safe motion planning has the potential to drastically reduce accidents while not resulting in overly conservative behaviors of the autonomous vehicle. QC 20210720

Published

2021

118. Autonomous Learning of the Robot Kinematic Model

Author

Ruggero Carli, Alberto Dalla Libera, Nicola Castaman, and Stefano Ghidoni

Subjects

Calibration and identification, kinematics, learning and adaptive systems, modular robots, 0209 industrial biotechnology, Forward kinematics, business.industry, Computer science, Context (language use), Robotics, 02 engineering and technology, Kinematics, Solid modeling, Revolute joint, Computer Science Applications, Computer Science::Robotics, 020901 industrial engineering & automation, Control and Systems Engineering, Polynomial kernel, Robot, Artificial intelligence, Electrical and Electronic Engineering, business, Algorithm

Abstract

Robotics systems are becoming more and more autonomous and reconfigurable. In this context, the design of algorithms capable of deriving kinematics and dynamics models directly from data could be particularly useful. In this article, we present an algorithm that learns a forward kinematics model of a robot starting from a time series of visual observations. Our strategy can be applied to any robot with serial kinematics composed of revolute and prismatics joints. First, the algorithm identifies the robot kinematic structure, i.e., a high-level description of the robot geometry that defines the connections between the rigid-bodies composing the robot. Then, the algorithm derives the forward kinematics relying on a Gaussian process (GP) model. More precisely, the GP model is based on a polynomial kernel, defined exploiting the kinematic structure previously identified. The effectiveness of the proposed solution has been tested via extensive Monte Carlo simulations, as well as via experiments on a real UR10 robot.

Published

2021

119. Dynamics of Continuum and Soft Robots: A Strain Parameterization Based Approach

Author

Vincent Lebastard, Fabien Candelier, Frédéric Boyer, Federico Renda, Laboratoire des Sciences du Numérique de Nantes (LS2N), Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), Université de Nantes (UN)-Université de Nantes (UN)-École Centrale de Nantes (ECN)-Centre National de la Recherche Scientifique (CNRS)-IMT Atlantique Bretagne-Pays de la Loire (IMT Atlantique), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT), Robotique Et Vivant (ReV), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT)-Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), Département Automatique, Productique et Informatique (IMT Atlantique - DAPI), IMT Atlantique Bretagne-Pays de la Loire (IMT Atlantique), Institut universitaire des systèmes thermiques industriels (IUSTI), Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU), Khalifa University for Science Technology [Abou Dabi], Université de Nantes (UN)-Université de Nantes (UN)-École Centrale de Nantes (ECN)-Centre National de la Recherche Scientifique (CNRS)-IMT Atlantique (IMT Atlantique), Robotique Et Vivant (LS2N - équipe ReV), IMT Atlantique (IMT Atlantique), and Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0209 industrial biotechnology, Computer science, business.industry, Soft robotics, Robotics, 02 engineering and technology, Kinematics, Finite element method, [SPI.AUTO]Engineering Sciences [physics]/Automatic, Computer Science Applications, Nonlinear system, 020901 industrial engineering & automation, Control and Systems Engineering, Ordinary differential equation, Applied mathematics, Robot, Artificial intelligence, Electrical and Electronic Engineering, business, Statics

Abstract

International audience; In this article we propose a new solution to the forward dynamics of Cosserat beams with in perspective, its application to continuum and soft robotics manipulation and locomotion. In contrast to usual approaches, it is based on the non-linear parametrization of the beam shape by its strain fields and their discretization on a functional basis of strain modes. While remaining geometrically exact, the approach provides a minimal set of ordinary differential equations in the usual Lagrange matrix form that can be solved with standard explicit time-integrators. Inspired from rigid robotics, the calculation of the matrices of the Lagrange model is performed with a continuous inverse Newton-Euler algorithm. The approach is tested on several numerical benches of non-linear structural statics, as well as further examples illustrating its capabilities for dynamics.

Published

2021

120. Collinear Mecanum Drive: Modeling, Analysis, Partial Feedback Linearization, and Nonlinear Control

Author

Tony J. Prescott, Daniel T. Gladwin, and Matthew T. Watson

Subjects

0209 industrial biotechnology, Robot kinematics, business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Robotics, Mobile robot, 02 engineering and technology, Nonlinear control, Computer Science Applications, law.invention, Controllability, 020901 industrial engineering & automation, Control and Systems Engineering, law, Control theory, Backstepping, Mecanum wheel, Artificial intelligence, Electrical and Electronic Engineering, business, Robot locomotion

Abstract

The collinear Mecanum drive (CMD) is a novel robot locomotion system, capable of generating omnidirectional motion while simultaneously dynamically balancing, achieved using a collinear arrangement of three or more Mecanum wheels. The CMD has a significantly thinner ground footprint than existing omnidirectional locomotion methods, which does not need to be enlarged with increasing robot height as to avoid toppling during acceleration or external disturbance. This combination of omnidirectional manoeuvrability and a thin ground footprint allows for the creation of tall robots that are able to navigate through much narrower gaps between obstacles than existing omnidirectional locomotion methods. This allows for greater manoeuvrability in confined and cluttered environments, such as that encountered in the personal service and automated warehousing robotics sectors. This article derives the kinematics and dynamics models of the CMD, analyzes controllability and accessibility, and determines the degree to which a CMD can be linearized by feedback. A partial feedback linearization is then performed, and three practically useful nonlinear controllers are derived using a backstepping design approach, all with convergence and stability guarantees for the fully coupled nonlinear model. These are demonstrated both in simulation and on a real-world CMD experimental prototype.

Published

2021

121. Real-Time Temporal and Rotational Calibration of Heterogeneous Sensors Using Motion Correlation Analysis

Author

Shaojie Shen, Siqi Liu, Tong Qin, Jie Pan, and Kejie Qiu

Subjects

0209 industrial biotechnology, Offset (computer science), business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Astrophysics::Instrumentation and Methods for Astrophysics, Rotation around a fixed axis, Robotics, 02 engineering and technology, Sensor fusion, Computer Science Applications, 020901 industrial engineering & automation, Odometry, Control and Systems Engineering, Inertial measurement unit, Scalability, Motion correlation, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business

Abstract

Accurate and robust calibration is crucial to a multisensor fusion-based system. The calibration of heterogeneous sensors is particularly challenging because of the huge difference of the captured sensor data. On the other hand, many calibration approaches ignore temporal calibration that is in fact as important as spatial calibration. In this article, we focus on the temporal calibration of heterogeneous sensors, and the corresponding extrinsic rotation is also derived. Most existing methods are specialized for a certain sensor combination, such as an inertial measurement unit (IMU) camera or a camera-Lidar system. However, heterogeneous multisensor fusion is a tendency in the robotics area, so a unified calibration method is desired. To this end, we leverage the 3-D rotational motion feature for calibration, and auxiliary calibration boards are not needed since multiple odometry methods are available to capture 3-D sensor motion. Using a high-frequency IMU as the calibration reference, an IMU-centric scheme is designed to achieve a unified framework that adapts to various target sensors that can independently estimate 3-D rotational motion. By combining independent IMU-centric calibration pairs, an arbitrary pair of sensors can also be calibrated using the same reference IMU. Due to a novel 3-D motion correlation quantification and analysis mechanism, the temporal offset can be first estimated in real time. Given temporally aligned sensor motion, the extrinsic rotation can be derived in closed-form in the same 3-D motion correlation mechanism. Experimental results of certain sensor combinations show the accuracy and robustness of the proposed method through comparison with state-of-the-art calibration approaches, and the calibration result of a heterogeneous multisensor set demonstrates the scalability and versatility of our method.

Published

2021

122. Toward a Unified Approximate Analytical Representation for Spatially Running Spring-Loaded Inverted Pendulum Model

Author

Zongquan Deng, Haibo Gao, and Haitao Yu

Subjects

0209 industrial biotechnology, business.industry, Computer science, Robotics, 02 engineering and technology, Slip (materials science), Computer Science Applications, Inverted pendulum, Numerical integration, Computer Science::Robotics, Nonlinear system, 020901 industrial engineering & automation, Control and Systems Engineering, Control theory, Trajectory, Motion planning, Artificial intelligence, Electrical and Electronic Engineering, Representation (mathematics), business

Abstract

As a versatile template characterizing the center of mass movements in legged locomotion, the sagittal spring-loaded inverted pendulum (SLIP) model has been extensively explored in both biomechanics and robotics. Despite concise in mathematical formulation, the accurate analytical representation of the SLIP model is unaccessible due to its intrinsic nonlinearity. This article extends the traditional SLIP model from sagittal hopping into spatially running. A novel perturbation-based approach is proposed to obtain an analytical approximate solution for the 3-D-SLIP model, resulting in a straight-forward closed-form formulation wherein the numerical integration or iteration is avoided. The derived solution does not rely on the negligible gravity assumption as conventional simplification reported in the existing literature and offers satisfactory prediction performance in a wide range of model parameter combinations. The merits of the acquired approximate solution in both critical state of the apex return map and trajectory prediction with high accuracy have been demonstrated via performance evaluation, endowing this approximation the potential in motion planning and gait control for legged robots.

Published

2021

123. Vector Field Control Methods for Discretely Variable Passive Robotic Devices

Author

R. Brent Gillespie and Emma Treadway

Subjects

0209 industrial biotechnology, Computer science, business.industry, Constraint (computer-aided design), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Robotics, 02 engineering and technology, Manifold, Computer Science Applications, 020901 industrial engineering & automation, Operator (computer programming), Dimension (vector space), Transmission (telecommunications), Control and Systems Engineering, Control theory, Robot, Vector field, Artificial intelligence, Electrical and Electronic Engineering, business, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

Passive transmission-based robotic devices are capable of providing motion guidance while ensuring user safety and engagement. To circumvent some of the drawbacks associated with steering continuously variable transmissions based on rolling contacts, we are exploring a class of discretely variable devices, based on brakes and hydrostatic transmissions. Previously available control methods for discretely variable devices were built on velocity fields and only developed to stabilize a one-dimensional (1-D) target manifold. For $n$ -DOF devices, methods to stabilize target manifolds of dimensions 1 to $n-$ 1 are of interest. In this article, we contribute constraint field methods that stabilize n $-$ 1 dimensional target manifolds while leaving the orthogonal subspace free to the control of the operator. We also contribute force-modulated single degree of freedom (DOF) velocity fields, which add between 1 and $n-$ 2 virtual DOFs to the motion of devices whose physical constraints leave one DOF. Control performance is demonstrated in simulation for 3-DOF devices capable of imposing 1-D or 2-D constraints and in experiment for 2-DOF devices imposing 1-D constraints. Our experimental apparatus features digital hydraulic transmissions that are easily configured for an n -dimensional space and capable of imposing constraints of any dimension, thus motivating the contributed methods.

Published

2021

124. Toward Orientation Learning and Adaptation in Cartesian Space

Author

Fares J. Abu-Dakka, Yanlong Huang, João Silvério, Darwin G. Caldwell, University of Leeds, Intelligent Robotics, IDIAP Research Institute, Istituto Italiano di Tecnologia, Department of Electrical Engineering and Automation, Aalto-yliopisto, and Aalto University

Subjects

0209 industrial biotechnology, Angular acceleration, Computer science, Trajectory, 02 engineering and technology, law.invention, Computer Science::Robotics, 020901 industrial engineering & automation, Angular velocity, law, Cartesian coordinate system, Electrical and Electronic Engineering, Quaternion, Probabilistic logic, business.industry, Orientation (computer vision), Robotics, Collaboration, Computer Science Applications, Jerk, Control and Systems Engineering, Task analysis, Robot, Artificial intelligence, Quaternions, business, Robots

Abstract

As a promising branch of robotics, imitation learning emerges as an important way to transfer human skills to robots, where human demonstrations represented in Cartesian or joint spaces are utilized to estimate task/skill models that can be subsequently generalized to new situations. While learning Cartesian positions suffices for many applications, the end-effector orientation is required in many others. Despite recent advances in learning orientations from demonstrations, several crucial issues have not been adequately addressed yet. For instance, how can demonstrated orientations be adapted to pass through arbitrary desired points that comprise orientations and angular velocities? In this article, we propose an approach that is capable of learning multiple orientation trajectories and adapting learned orientation skills to new situations (e.g., via-points and end-points), where both orientation and angular velocity are considered. Specifically, we introduce a kernelized treatment to alleviate explicit basis functions when learning orientations, which allows for learning orientation trajectories associated with high-dimensional inputs. In addition, we extend our approach to the learning of quaternions with angular acceleration or jerk constraints, which allows for generating smoother orientation profiles for robots. Several examples including experiments with real 7-DoF robot arms are provided to verify the effectiveness of our method.

Published

2021

125. Towards Generalization in Target-Driven Visual Navigation by Using Deep Reinforcement Learning

Author

Giacomo Mezzetti, Paolo Valigi, Gabriele Costante, Mario Luca Fravolini, and Alessandro Devo

Subjects

0209 industrial biotechnology, Computer science, business.industry, Deep Learning in Robotics and Automation, Robotics, 02 engineering and technology, Simultaneous localization and mapping, Computer Science Applications, Task (project management), Visualization, 020901 industrial engineering & automation, Target-Driven Visual Navigation, Control and Systems Engineering, Human–computer interaction, Visual-Based Navigation, Generalization (learning), Task analysis, Reinforcement learning, Artificial intelligence, Target-Driven Visual Navigation, Visual-Based Navigation, Deep Learning in Robotics and Automation, Visual Learning, Electrical and Electronic Engineering, business, Visual learning, Visual Learning

Abstract

Among the main challenges in robotics, target-driven visual navigation has gained increasing interest in recent years. In this task, an agent has to navigate in an environment to reach a user specified target, only through vision. Recent fruitful approaches rely on deep reinforcement learning, which has proven to be an effective framework to learn navigation policies. However, current state-of-the-art methods require to retrain, or at least fine-tune, the model for every new environment and object. In real scenarios, this operation can be extremely challenging or even dangerous. For these reasons, we address generalization in target-driven visual navigation by proposing a novel architecture composed of two networks, both exclusively trained in simulation. The first one has the objective of exploring the environment, while the other one of locating the target. They are specifically designed to work together, while separately trained to help generalization. In this article, we test our agent in both simulated and real scenarios, and validate its generalization capabilities through extensive experiments with previously unseen goals and unknown mazes, even much larger than the ones used for training.

Published

2020

126. A Distributed Version of the Hungarian Method for Multirobot Assignment.

Author

Chopra, Smriti, Notarstefano, Giuseppe, Rice, Matthew, and Egerstedt, Magnus

Subjects

*ROBOT kinematics, *HEURISTIC algorithms, *ROBOTICS, *COMMUNICATION, *PEER-to-peer architecture (Computer networks)

Abstract

In this paper, we propose a distributed version of the Hungarian method to solve the well-known assignment problem. In the context of multirobot applications, all robots cooperatively compute a common assignment that optimizes a given global criterion (e.g., the total distance traveled) within a finite set of local computations and communications over a peer-to-peer network. As a motivating application, we consider a class of multirobot routing problems with “spatiotemporal” constraints, i.e., spatial targets that require servicing at particular time instants. As a means of demonstrating the theory developed in this paper, the robots cooperatively find online suboptimal routes by applying an iterative version of the proposed algorithm in a distributed and dynamic setting. As a concrete experimental test bed, we provide an interactive “multirobot orchestral” framework, in which a team of robots cooperatively plays a piece of music on a so-called orchestral floor. [ABSTRACT FROM PUBLISHER]

Published

2017

127. Bayesian Nonparametric Learning of Cloth Models for Real-Time State Estimation.

Author

Koganti, Nishanth, Tamei, Tomoya, Ikeda, Kazushi, and Shibata, Tomohiro

Subjects

*BAYESIAN field theory, *ROBOTICS, *MOTOR ability, *PERSONAL robotics, *ENERGY consumption

Abstract

Robotic solutions to clothing assistance can significantly improve quality of life for the elderly and disabled. Real-time estimation of the human–cloth relationship is crucial for efficient learning of motor skills for robotic clothing assistance. The major challenge involved is cloth-state estimation due to inherent nonrigidity and occlusion. In this study, we present a novel framework for real-time estimation of the cloth state using a low-cost depth sensor, making it suitable for a feasible social implementation. The framework relies on the hypothesis that clothing articles are constrained to a low-dimensional latent manifold during clothing tasks. We propose the use of manifold relevance determination (MRD) to learn an offline cloth model that can be used to perform informed cloth-state estimation in real time. The cloth model is trained using observations from a motion capture system and depth sensor. MRD provides a principled probabilistic framework for inferring the accurate motion-capture state when only the noisy depth sensor feature state is available in real time. The experimental results demonstrate that our framework is capable of learning consistent task-specific latent features using few data samples and has the ability to generalize to unseen environmental settings. We further present several factors that affect the predictive performance of the learned cloth-state model. [ABSTRACT FROM PUBLISHER]

Published

2017

128. Criterion for the Design of Low-Power Variable Stiffness Mechanisms.

Author

Chalvet, Vincent and Braun, David J.

Subjects

*ROBOTICS, *STIFFNESS (Mechanics), *ACTUATORS, *PHYSICAL measurements, *ENERGY consumption, *POWER measurement (Electricity)

Abstract

Designing robotic systems capable of low-power operation, inherent to their compliant actuation, has been elusive in practical application. In this paper, we propose a physical measure to mathematically define mechanical designs that are suitable to realize stiffness modulation with low power cost. Using this measure, we present a mathematical formulation of an ideal variable stiffness mechanism unaffected by the external load during its operation. We then analyze several existing mechanisms from the literature to relate design features with analytical conditions inherent to low power stiffness modulation in practical designs. Through this analysis, we identify an approximate practical realization of an ideal actuator capable of stiffness modulation with inherently low power cost. Similar to a number of existing efficient variable stiffness mechanisms, this mechanism is able to hold a given stiffness setting with zero input force under no external load. However, unlike many other previously designed mechanisms, it enables infinite range stiffness modulation using finite control forces. A practical variable stiffness mechanism that is capable of infinite range stiffness modulation using finite control forces leads to lower power cost and reduced energy consumption. [ABSTRACT FROM PUBLISHER]

Published

2017

129. Obstacle Avoidance Strategy using Onboard Stereo Vision on a Flapping Wing MAV.

Author

Tijmons, Sjoerd, de Croon, Guido C. H. E., Remes, Bart D. W., De Wagter, Christophe, and Mulder, Max

Subjects

*MICROROBOTS, *MICRO air vehicles, *ENERGY consumption, *ROBOTICS, *POWER resources

Abstract

The development of autonomous lightweight MAVs, capable of navigating in unknown indoor environments, is one of the major challenges in robotics. The complexity of this challenge comes from constraints on weight and power consumption of onboard sensing and processing devices. In this paper, we propose the “Droplet” strategy, an avoidance strategy based on stereo vision inputs that outperforms reactive avoidance strategies by allowing constant speed maneuvers while being computationally extremely efficient, and which does not need to store previous images or maps. The strategy deals with nonholonomic motion constraints of most fixed and flapping wing platforms, and with the limited field-of-view of stereo camera systems. It guarantees obstacle-free flight in the absence of sensor and motor noise. We first analyze the strategy in simulation, and then show its robustness in real-world conditions by implementing it on a 20-gram flapping wing MAV. [ABSTRACT FROM PUBLISHER]

Published

2017

130. Dual REPS: A Generalization of Relative Entropy Policy Search Exploiting Bad Experiences.

Author

Colome, Adria and Torras, Carme

Subjects

*ROBOTICS, *REINFORCEMENT learning, *MATHEMATICAL optimization, *GAUSSIAN distribution, *ARTIFICIAL intelligence

Abstract

Policy search (PS) algorithms are widely used for their simplicity and effectiveness in finding solutions for robotic problems. However, most current PS algorithms derive policies by statistically fitting the data from the best experiments only. This means that experiments yielding a poor performance are usually discarded or given too little influence on the policy update. In this paper, we propose a generalization of the relative entropy policy search (REPS) algorithm that takes bad experiences into consideration when computing a policy. The proposed approach, named dual REPS (DREPS) following the philosophical interpretation of the duality between good and bad, finds clusters of experimental data yielding a poor behavior and adds them to the optimization problem as a repulsive constraint. Thus, considering that there is a duality between good and bad data samples, both are taken into account in the stochastic search for a policy. Additionally, a cluster with the best samples may be included as an attractor to enforce faster convergence to a single optimal solution in multimodal problems. We first tested our proposed approach in a simulated reinforcement learning setting and found that DREPS considerably speeds up the learning process, especially during the early optimization steps and in cases where other approaches get trapped in between several alternative maxima. Further experiments in which a real robot had to learn a task with a multimodal reward function confirm the advantages of our proposed approach with respect to REPS. [ABSTRACT FROM PUBLISHER]

Published

2017

131. Modeling Robotic Manipulators Powered by Variable Stiffness Actuators: A Graph-Theoretic and Port-Hamiltonian Formalism.

Author

Groothuis, Stefan S., Stramigioli, Stefano, and Carloni, Raffaella

Subjects

*MANIPULATORS (Machinery), *ACTUATORS, *GRAPH theory, *ROBOTICS, *EULER-Lagrange system, *SYMMETRIC matrices

Abstract

This paper proposes a modeling method for generic compliant robotic manipulators. It is based on graph theory and the port-Hamiltonian formalism, which allows a modular approach to the interconnection of rigid bodies with compliant actuators by means of kinematic pairs. This modularity enables a simple and straight-forward adaption the model when a manipulator's actuator morphology is changed. An example of a spatial three degree-of-freedom manipulator shows that this modeling method is more suitable for modeling changes in actuator placement than the traditional Euler–Lagrange method. [ABSTRACT FROM PUBLISHER]

Published

2017

132. Fault-Tolerant Rendezvous of Multirobot Systems.

Author

Park, Hyongju and Hutchinson, Seth A.

Subjects

*FAULT-tolerant computing, *DECENTRALIZED control systems, *ROBOT control systems, *ELECTRIC network topology, *ROBOTICS

Abstract

In this paper, we propose a distributed control policy to achieve rendezvous by a set of robots even when some robots in the system do not follow the prescribed policy. These nonconforming robots correspond to faults in the multirobot system, and our control policy is thus a fault-tolerant policy. Each robot has a limited sensing range and is able to directly estimate the state of only those robots within that sensing range, which induces a network topology for the multirobot system. We assume that it is not possible for the fault-free robots to identify the faulty robots, and thus our approach is robust even to undetected faults in the system. The main contribution of this paper is a fault-tolerant distributed control algorithm that is guaranteed to converge to consensus under certain reasonable connectivity conditions. We first present a general algorithm that exploits the notion of a Tverberg partition of a point set in \mathbb R^d, and give a proof of convergence. We then provide three instantiations of this algorithm, based on three different sensing models. For each case, we analyze performance via extensive simulations. The effectiveness and performance of our algorithms on real platforms are demonstrated through experiments on a multirobot testbed. [ABSTRACT FROM PUBLISHER]

Published

2017

133. On the Control and Properties of Supercoiled Polymer Artificial Muscles.

Author

Yip, Michael C. and Niemeyer, Gunter

Subjects

*ROBOTICS, *ACTUATORS, *ARTIFICIAL muscles, *ROBOT control systems, *SHAPE memory polymers

Abstract

Robotics have long sought an actuation technology comparable to or as capable as biological muscle tissue. Natural muscles exhibit a high power-to-weight ratio, inherent compliance and damping, fast action, and a high dynamic range. They also produce joint displacements and forces without the need for gearing or additional hardware. Recently, supercoiled commercially available polymer threads (sewing thread or nylon fishing lines) have been used to create significant mechanical power in a muscle-like form factor. Heating and cooling the polymer threads causes contraction and expansion, which can be utilized for actuation. In this paper, we describe the working principle of supercoiled polymer (SCP) actuation and explore the controllability and properties of these threads. We show that under appropriate environmental conditions, the threads are suitable as a building block for a controllable artificial muscle. We leverage off-the-shelf silver-coated threads to enable rapid electrical heating while the low thermal mass allows for rapid cooling. We utilize both thermal and thermomechanical models for feed-forward and feedback control. The resulting SCP actuator regulates to desired force levels in as little as 28 ms. Together with its inherent stiffness and damping, this is sufficient for a position controller to execute large step movements in under 100 ms. This controllability, high performance, the mechanical properties, and the extremely low material cost are indicative of a viable artificial muscle. [ABSTRACT FROM PUBLISHER]

Published

2017

134. Kinematic Cartography and the Efficiency of Viscous Swimming.

Author

Hatton, Ross L., Dear, Tony, and Choset, Howie

Subjects

*KINEMATICS, *CARTOGRAPHY, *LOCOMOTION, *ROBOTICS, *ENGINEERING design

Abstract

The apparent “distance” between two configurations of a system and the “length” of trajectories through its configuration space can be significantly distorted by plots that use “natural” or intuitively selected coordinates. This effect is similar to the way that a latitude–longitude plot of the Earth distorts the size and shape of the continents. In this paper, we explore how ideas from cartography can be used to identify system parameterizations that better reflect the effort costs of changing configuration. We then apply these new parameters to provide geometric insight about two aspects of moving in dissipative environments such as low Reynolds number fluids: The shape of the optimal gait cycle for a three-link swimmer and the fundamentally superior efficiency of a serpenoid swimmer as compared to the classic three-link system. [ABSTRACT FROM PUBLISHER]

Published

2017

135. Proprioceptive Actuator Design in the MIT Cheetah: Impact Mitigation and High-Bandwidth Physical Interaction for Dynamic Legged Robots.

Author

Wensing, Patrick M., Wang, Albert, Seok, Sangok, Otten, David, Lang, Jeffrey, and Kim, Sangbae

Subjects

*ACTUATOR design & construction, *BANDWIDTHS, *ROBOTICS, *ENGINEERING design, *ROBOT control systems

Abstract

Designing an actuator system for highly dynamic legged robots has been one of the grand challenges in robotics research. Conventional actuators for manufacturing applications have difficulty satisfying design requirements for high-speed locomotion, such as the need for high torque density and the ability to manage dynamic physical interactions. To address this challenge, this paper suggests a proprioceptive actuation paradigm that enables highly dynamic performance in legged machines. Proprioceptive actuation uses collocated force control at the joints to effectively control contact interactions at the feet under dynamic conditions. Modal analysis of a reduced leg model and dimensional analysis of DC motors address the main principles for implementation of this paradigm. In the realm of legged machines, this paradigm provides a unique combination of high torque density, high-bandwidth force control, and the ability to mitigate impacts through backdrivability. We introduce a new metric named the “impact mitigation factor” (IMF) to quantify backdrivability at impact, which enables design comparison across a wide class of robots. The MIT Cheetah leg is presented, and is shown to have an IMF that is comparable to other quadrupeds with series springs to handle impact. The design enables the Cheetah to control contact forces during dynamic bounding, with contact times down to 85 ms and peak forces over 450 N. The unique capabilities of the MIT Cheetah, achieving impact-robust force-controlled operation in high-speed three-dimensional running and jumping, suggest wider implementation of this holistic actuation approach. [ABSTRACT FROM PUBLISHER]

Published

2017

136. RGB-D Object Recognition and Grasp Detection Using Hierarchical Cascaded Forests.

Author

Asif, Umar, Bennamoun, Mohammed, and Sohel, Ferdous A.

Subjects

*OBJECT recognition (Computer vision), *VISUAL perception, *ROBOTICS, *HUMAN-robot interaction

Abstract

This paper presents an efficient framework to perform recognition and grasp detection of objects from RGB-D images of real scenes. The framework uses a novel architecture of hierarchical cascaded forests, in which object-class and grasp-pose probabilities are computed at different levels of an image hierarchy (e.g., patch and object levels) and fused to infer the class and the grasp of unseen objects. We introduce a novel training objective function that minimizes the uncertainties of the class labels and the grasp ground truths at the leaves of the forests, thereby enabling the framework to perform the recognition and grasp detection of objects. Our objective function is learned from features that are extracted from RGB-D point clouds of the objects. For that, we propose a novel method to encode an RGB-D point cloud into a representation that facilitates the use of large convolution neural networks to extract discriminative features from RGB-D images. We evaluate our framework on challenging object datasets, where we demonstrate that our framework outperforms the state-of-the-art methods in terms of object-recognition and grasp-detection accuracies. We also show experiments by using live video streams from a Kinect mounted on our in-house robotic platform. [ABSTRACT FROM PUBLISHER]

Published

2017

137. The Impact of Diversity on Optimal Control Policies for Heterogeneous Robot Swarms.

Author

Prorok, Amanda, Kumar, Vijay, and Hsieh, M. Ani

Subjects

*ROBOTICS, *SPECIES diversity, *EMBEDDED computer systems, *STOCHASTIC systems, *TASK performance

Abstract

We consider the problem of distributing a large group of heterogeneous robots among a set of tasks that require specialized capabilities in order to be completed. We model the system of heterogeneous robots as a community of species, in which each species (robot type) is defined by the traits (capabilities) that it owns. In order to solve the distribution problem, we develop centralized as well as decentralized methods to efficiently control the heterogeneous swarm of robots. Our methods assume knowledge of the underlying task topology and are based on a continuous model of the system that defines transition rates to and from tasks, for each robot species. Our optimization of the transition rates is fully scalable with respect to the number of robots, number of species, and number of traits. Building on this result, we propose a real-time optimization method that enables an online adaptation of transition rates as a function of the state of the current robot distribution. We also show how the robot distribution can be approximated based on local information only, consequently enabling the development of a decentralized controller. We evaluate our methods by means of microscopic simulations and show how the performance of the latter is well predicted by the macroscopic equations. Importantly, our framework also includes a diversity metric that enables an evaluation of the impact of swarm heterogeneity on performance. The metric defines the notion of minspecies, i.e., the minimum set of species that are required to achieve a given goal. We show that two distinct goal functions lead to two specializations of minspecies, which we term as eigenspecies and coverspecies. Quantitative results show the relation between diversity and performance. [ABSTRACT FROM PUBLISHER]

Published

2017

138. Do You Need Help? A Robot Providing Information to People Who Behave Atypically.

Author

Brscic, Drazen, Ikeda, Tetsushi, and Kanda, Takayuki

Subjects

*ROBOTICS, *HUMAN-robot interaction, *PEDESTRIANS, *PUBLIC spaces, SOCIAL aspects

Abstract

In this work, we were interested in creating a robot service for offering help to people who appear to be in need for guidance. In order to achieve that, we first developed a technique to detect pedestrians who walk in an atypical way (e.g., people who do not know their way). In our approach, a motion model of typical pedestrians developed in our previous work was used, and a novel predictability feature was defined that quantifies how well can a person's future position be predicted using that model. The classification method based on this feature gave accurate results and outperformed alternative methods. Using this detection method, we created a robot service for offering guidance to people who were classified as atypical. Experiments done in a shopping mall have shown that the robot was successful in choosing the people to approach, and the reactions from users in the interviews were very positive. [ABSTRACT FROM PUBLISHER]

Published

2017

139. Passive Particle Jamming and Its Stiffening of Soft Robotic Grippers.

Author

Li, Yingtian, Chen, Yonghua, Yang, and Wei, Ying

Subjects

*STIFFNESS (Mechanics), *ROBOTICS, *SHAPE memory alloys, *MATERIALS handling, *GRIP strength

Abstract

The compliance of soft grippers contributes to their great superiority over rigid grippers in grasping irregularly shaped objects and forming soft contact with environments. Due to a relatively small pressure, soft grippers lack the stiffness required for wider applications. Particle jamming has been frequently reported as a means of stiffness control. Unlike previous research using vacuum for particle jamming, this paper proposes a novel passive particle jamming principle that does not need any vacuum power or other control means. The proposed method is by simply patching a silicone rubber soft actuator and a pack (made of strain-limiting membrane) of particles to form an integral gripping finger. The inflation of the soft actuator applies a pressure to the particle pack causing particles inside it to jam. A larger squeezing pressure will result in tighter particle jamming, thus increasing the stiffness of the finger. The stiffness of the finger is controllable as it is proportional to the actuator's air pressure, which has been verified by experiments in this research. The stiffness can increase more than six fold when air pressure changes from 20 to 80 kPa in the experimental studies. The reported discovery may enhance the capabilities of soft robotic grippers so that more robotic picking operations could be performed by soft grippers. [ABSTRACT FROM PUBLISHER]

Published

2017

140. Automatic Sample Alignment Under Microscopy for 360? Imaging Based on the Nanorobotic Manipulation System.

Author

Shen, Yajing, Wan, Wenfeng, Lu, Haojian, Fukuda, Toshio, and Shang, Wanfeng

Subjects

*MICROSCOPY, *IMAGING systems, *NANOROBOTICS, *NANOTECHNOLOGY, *ROBOTICS

Abstract

Microscopy has been an indispensable tool for micro/nanosample imaging, manipulation, and characterization. However, viewing the micro/nanosample from multidirection is still a big challenge for current microscopy. To address the above issue, this paper proposes a novel nanorobotic manipulation system for the automatic alignment and multidirectional imaging under microscopes. First, a miniature rotation robot with three degrees of freedom is designed and integrated with a microscope. Then, a forward-backward alignment strategy containing three loops, i.e., position shift loop, angle loop, and magnification loop, is proposed to align the sample to the rotation axis of the robot automatically. After that, the sample is imaged from multidirection by rotating the robot with one revolution (360°). Finally, the alignment accuracy is evaluated and multi-directional images of various samples are implemented. This study provides a new way for the microscopic imaging, which is expected to exert a significant impact in multiple fields on a small scale, including microscopy imaging, microdefect detection, micromanipulation, in situ characterization, and so on. [ABSTRACT FROM AUTHOR]

Published

2017

141. Guiding Elastic Rods With a Robot-Manipulated Magnet for Medical Applications.

Author

Kratchman, Louis B., Bruns, Trevor L., Abbott, Jake J., and Webster, Robert J.

Subjects

*CATHETERS, *ROBOTICS, *OPERATIVE surgery, *ROBOTS, *ELASTIC rods & wires, *MAGNETIC fields

Abstract

Magnet-tipped, elastic rods can be steered by an external magnetic field to perform surgical tasks. Such rods could be useful for a range of new medical applications because they do not require either pull wires or other bulky mechanisms that are problematic in small anatomical regions. However, current magnetic rod steering systems are large and expensive. Here, we describe a method to guide a rod using a robot-manipulated magnet located near a patient. We solve for rod deflections by combining permanent-magnet models with a Kirchhoff elastic rod model and use a resolved-rate approach to compute trajectories. Experiments show that three-dimensional trajectories can be executed accurately without feedback and that the system's redundancy can be exploited to avoid obstacles. [ABSTRACT FROM AUTHOR]

Published

2017

142. Resonance Principle for the Design of Flapping Wing Micro Air Vehicles.

Author

Zhang, Jian and Deng, Xinyan

Subjects

*RESONANCE, *DRONE aircraft, *MICRO air vehicles, *ROBOTICS, *AUTOMATION, *FLIGHT control systems, *AUTOMATIC control systems

Abstract

Achieving resonance in flapping wings has been recognized as one of the most important principles to enhance power efficiency, lift generation, and flight control performance of high-frequency flapping wing micro air vehicles (MAVs). Most work on the development of such vehicles have attempted to achieve wing flapping resonance. However, the theoretical understanding of its effects on the response and energetics of flapping motion has lagged behind, leading to suboptimal design decisions and misinterpretations of experimental results. In this work, we systematically model the dynamics of flapping wing as a forced nonlinear resonant system, using both nonlinear perturbation method and linear approximation approach. We derived an analytic solution for steady-state flapping amplitude, energetics, and characteristic frequencies including natural frequency, damped natural frequency, and peak frequency. Our results showed that both aerodynamic lift and power efficiency are maximized by driving the wing at natural frequency, instead of other frequencies. Interestingly, the flapping velocity is maximized at natural frequency as well, which can lead to an easy experimental approach to identify natural frequency and validate the resonance design. Our models and analysis were validated with both simulations and experiments on ten different wings mounted a direct-motor-drive flapping wing MAV. The result can serve as a systematic design principle and guidance in the interpretations of empirical results. [ABSTRACT FROM AUTHOR]

Published

2017

143. Two-Stage Focused Inference for Resource-Constrained Minimal Collision Navigation.

Author

Mu, Beipeng, Paull, Liam, Agha-Mohammadi, Ali-Akbar, Leonard, John J., and How, Jonathan P.

Subjects

*MOBILE robots, *ROBOTIC path planning, *ROBOTICS, *BIPEDALISM, *ELECTRONICS

Abstract

The operation of mobile robots in unknown environments typically requires building maps during exploration. As the exploration time and environment size increase, the amount of data collected and the number of variables required to represent these maps both grow, which is problematic since all real robots have finite resources. The solution proposed in this paper is to only retain the variables and measurements that are most important to achieve the robot's task. The variable and measurement selection approach is demonstrated on the task of navigation with a low risk of collision. Our approach has two stages: first, a subset of the variables is selected that is most useful for minimizing the uncertainty of navigation (termed the “focused variables”). And second, a task-agnostic method is used to select a subset of the measurements that maximizes the information over these focused variables (“focused inference”). Detailed simulations and hardware experiments show that the two-stage approach constrains the number of variables and measurements. It can generate much sparser maps than existing approaches in the literature, while still achieving a better task performance—in this case (fewer collisions). An incremental and iterative approach is further presented, in which the two-stage procedure is performed on subsets of the data, and thus, avoids the necessity of performing a resource-intensive batch selection on large datasets. [ABSTRACT FROM AUTHOR]

Published

2017

144. Metrics for Evaluating Feature-Based Mapping Performance.

Author

Barrios, Pablo, Adams, Martin, Leung, Keith, Inostroza, Felipe, Naqvi, Ghayur, and Orchard, Marcos E.

Subjects

*ROBOTICS, *MATHEMATICAL mappings, *ENGINEERING, *ROBOTS, *AUTOMATION

Abstract

In robotic mapping and simultaneous localization and mapping, the ability to assess the quality of estimated maps is crucial. While concepts exist for quantifying the error in the estimated trajectory of a robot, or a subset of the estimated feature locations, the difference between all current estimated and ground-truth features is rarely considered jointly. In contrast to many current methods, this paper analyzes metrics, which automatically evaluate maps based on their joint detection and description uncertainty. In the tracking literature, the optimal subpattern assignment (OSPA) metric provided a solution to the problem of assessing target tracking algorithms and has recently been applied to the assessment of robotic maps. Despite its advantages over other metrics, the OSPA metric can saturate to a limiting value irrespective of the cardinality errors and it penalizes missed detections and false alarms in an unequal manner. This paper therefore introduces the cardinalized optimal linear assignment (COLA) metric, as a complement to the OSPA metric, for feature map evaluation. Their combination is shown to provide a robust solution for the evaluation of map estimation errors in an intuitive manner. [ABSTRACT FROM AUTHOR]

Published

2017

145. ZMP Support Areas for Multicontact Mobility Under Frictional Constraints.

Author

Caron, Stephane, Pham, Quang-Cuong, and Nakamura, Yoshihiko

Subjects

*HUMANOID robots, *ROBOTICS, *LOCOMOTION, *ROBOT motion, *OSCILLATIONS, *AUTOMATION

Abstract

We propose a method for checking and enforcing multicontact stability based on the zero-tilting moment point (ZMP). The key to our development is the generalization of ZMP support areas to take into account: 1) frictional constraints and 2) multiple noncoplanar contacts. We introduce and investigate two kinds of ZMP support areas. First, we characterize and provide a fast geometric construction for the support area generated by valid contact forces, with no other constraint on the robot motion. We call this set the full support area. Next, we consider the control of humanoid robots by using the linear pendulum mode (LPM). We observe that the constraints stemming from the LPM induce a shrinking of the support area, even for walking on horizontal floors. We propose an algorithm to compute the new area, which we call the pendular support area. We show that, in the LPM, having the ZMP in the pendular support area is a necessary and sufficient condition for contact stability. Based on these developments, we implement a whole-body controller and generate feasible multicontact motions where an HRP-4 humanoid locomotes in challenging multicontact scenarios. [ABSTRACT FROM AUTHOR]

Published

2017

146. Adaptive Human?Robot Interaction Control for Robots Driven by Series Elastic Actuators.

Author

Li, Xiang, Pan, Yongping, Chen, Gong, and Yu, Haoyong

Subjects

*ADAPTIVE control systems, *ROBOTS, *ARTIFICIAL intelligence, *ROBOTICS, *SELF-organizing systems, *ACTUATORS

Abstract

Series elastic actuators (SEAs) are known to offer a range of advantages over stiff actuators for human–robot interaction, such as high force/torque fidelity, low impedance, and tolerance to shocks. While a variety of SEAs have been developed and implemented in initiatives that involve physical interactions with humans, relatively few control schemes were proposed to deal with the dynamic stability and uncertainties of robotic systems driven by SEAs, and the open issue of safety that resolves the conflicts of motion between the human and the robot has not been systematically addressed. In this paper, a novel continuous adaptive control method is proposed for SEA-driven robots used in human–robot interaction. The proposed method provides a unified formulation for both the robot-in-charge mode, where the robot plays a dominant role to follow a desired trajectory, and the human-in-charge mode, in which the human plays a dominant role to guide the movement of robot. Instead of designing multiple controllers and switching between them, both typical modes are integrated into a single controller, and the transition between two modes is smooth and stable. Therefore, the proposed controller is able to detect the human motion intention and guarantee the safe human–robot interaction. The dynamic stability of the closed-loop system is theoretically proven by using the Lyapunov method, with the consideration of uncertainties in both the robot dynamics and the actuator dynamics. Both simulation and experimental results are presented to illustrate the performance of the proposed controller. [ABSTRACT FROM AUTHOR]

Published

2017

147. Energy-Efficient Monopod Running With a Large Payload Based on Open-Loop Parallel Elastic Actuation.

Author

Guenther, Fabian and Iida, Fumiya

Subjects

*ROBOTICS, *ENGINEERING, *ROCKET payloads, *ELASTICITY, *LOCOMOTION

Abstract

Despite intensive investigations in the past, energetic efficiency is still one of the most important unsolved challenges in legged robot locomotion. This paper presents an unconventional approach to the problem of energetically efficient legged locomotion by applying actuation for spring mass running. This approach makes use of mechanical springs incorporated in parallel with relatively low-torque actuation, which is capable of both accommodating large payload and locomotion with low power input by exploiting self-excited vibration. For a systematic analysis, this paper employs both simulation models and physical platforms. The experiments show that the proposed approach is scalable across different payload between 0 and 150 kg, and is able to achieve a total cost of transport of 0.10, which is significantly lower than the previous locomotion robots and most of the biological systems in the similar scale, when actuated with the near-to natural frequency with the maximum payload. [ABSTRACT FROM AUTHOR]

Published

2017

148. A Small-Gain Approach for Nonpassive Bilateral Telerobotic Rehabilitation: Stability Analysis and Controller Synthesis.

Author

Atashzar, Seyed Farokh, Polushin, Ilia G., and Patel, Rajnikant V.

Subjects

*ROBOTICS, *TELEROBOTICS, *HUMAN-robot interaction, *REMOTE control, *TOUCH

Abstract

In this paper, the design of a novel bilateral telerobotic architecture for rehabilitation purposes is proposed and the related feasibility, stability, and control challenges are studied. The objective is to incorporate the supervision of a local/remote human physiotherapist into haptics-enabled rehabilitation systems and allow the therapist to provide nonpassive nonlinear assistive/resistive forces in response to the patient's movements. This can address a challenge of conventional software-based rehabilitation systems, i.e., limited capability in adjusting the therapy. To guarantee human–robot interaction safety, a new design framework and a stabilizing controller are developed based on the small-gain approach. System stability and transparency are analyzed in the presence of the nonpassive, nonlinear, and nonautonomous behavior of the terminals (the therapist and the patient) and time-varying delays for the case of remote and cloud-based therapy. Several practical considerations have been taken into account to match the clinical needs and minimize the implementation cost. Simulation studies, practical implementation, and experimental evaluations are presented. [ABSTRACT FROM AUTHOR]

Published

2017

149. Optimizing Tube Precurvature to Enhance the Elastic Stability of Concentric Tube Robots.

Author

Ha, Junhyoung, Park, Frank C., and Dupont, Pierre E.

Subjects

*ROBOTS, *ROBOTICS, *LOCOMOTION, *ELASTICITY, *OPTIMAL designs (Statistics), *CURVATURE

Abstract

Robotic instruments based on concentric tube technology are well suited to minimally invasive surgery since they are slender, can navigate inside small cavities, and can reach around sensitive tissues by taking on shapes of varying curvatures. Elastic instabilities can arise, however, when rotating one precurved tube inside another. In contrast to prior work that considered only tubes of piecewise constant precurvature, we allow precurvature to vary along the tube's arc length. Stability conditions for a planar tube pair are derived and used to formulate an optimal design problem. An analytic formulation of the optimal precurvature function is derived, which achieves a desired tip orientation range while maximizing stability and respecting bending strain limits. This formulation also includes straight transmission segments at the proximal ends of the tubes. The result, confirmed by both numerical and physical experiment, enables designs with enhanced stability in comparison to designs of constant precurvature. [ABSTRACT FROM AUTHOR]

Published

2017

150. Continuous Legged Locomotion Planning.

Author

Perrin, Nicolas, Ott, Christian, Englsberger, Johannes, Stasse, Olivier, Lamiraux, Florent, and Caldwell, Darwin G.

Subjects

*ROBOTS, *ELECTRONIC navigation, *ROBOTICS, *BIPEDALISM, *LOCOMOTION

Abstract

While only continuous motions are possible, the way in which contacts appear and disappear confers to legged locomotion a characteristic discontinuous nature that is traditionally shared by the algorithms used for legged locomotion planning. In this paper, we show that this discontinuous nature can disappear if the notion of collision is well redefined and we efficiently solve two different practical problems of legged locomotion planning with algorithms based on an approach that establishes a bridge between discrete and continuous planning. The first problem consists of reactive footstep planning with a biped robot and the second one consists of nongaited locomotion planning with a hexapod. [ABSTRACT FROM AUTHOR]

Published

2017