Your search keyword '"Dario Paolo"' showing total 75 results

1. A review on the evolvement trend of robotic interaction control

Author

Leylavi Shoushtari, Ali, Dario, Paolo, and Mazzoleni, Stefano

Published

2016

2. Bio-inspired kinematical control of redundant robotic manipulators

Author

Leylavi Shoushtari, Ali, Mazzoleni, Stefano, and Dario, Paolo

Published

2016

3. Teleoperated assembly of a micro‐lens system by means of a micro‐manipulation workstation

Author

Eisinberg, Anna, Menciassi, Arianna, Dario, Paolo, Seyfried, Joerg, Estana, Ramon, Woern, Heinz, and Dr. Karjalainen, Ilpo

Published

2007

4. Recognition of Daily Gestures with Wearable Inertial Rings and Bracelets

Author

Moschetti, Alessandra, Fiorini, Laura, Esposito, Dario, Dario, Paolo, and Cavallo, Filippo

Subjects

Engineering, Movement, Decision tree, Wearable computer, Monitoring, Ambulatory, Context (language use), 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, Pattern Recognition, Automated, Activity recognition, Human–computer interaction, 0202 electrical engineering, electronic engineering, information engineering, Humans, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Aged, sensor fusion, Gestures, business.industry, Electromyography, gesture recognition, wearable sensors, 010401 analytical chemistry, Signal Processing, Computer-Assisted, Wrist, Sensor fusion, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Support vector machine, machine learning, Gesture recognition, activities of daily living, 020201 artificial intelligence & image processing, Artificial intelligence, business, Algorithms, Gesture

Abstract

Recognition of activities of daily living plays an important role in monitoring elderly people and helping caregivers in controlling and detecting changes in daily behaviors. Thanks to the miniaturization and low cost of Microelectromechanical systems (MEMs), in particular of Inertial Measurement Units, in recent years body-worn activity recognition has gained popularity. In this context, the proposed work aims to recognize nine different gestures involved in daily activities using hand and wrist wearable sensors. Additionally, the analysis was carried out also considering different combinations of wearable sensors, in order to find the best combination in terms of unobtrusiveness and recognition accuracy. In order to achieve the proposed goals, an extensive experimentation was performed in a realistic environment. Twenty users were asked to perform the selected gestures and then the data were off-line analyzed to extract significant features. In order to corroborate the analysis, the classification problem was treated using two different and commonly used supervised machine learning techniques, namely Decision Tree and Support Vector Machine, analyzing both personal model and Leave-One-Subject-Out cross validation. The results obtained from this analysis show that the proposed system is able to recognize the proposed gestures with an accuracy of 89.01% in the Leave-One-Subject-Out cross validation and are therefore promising for further investigation in real life scenarios.

Published

2016

5. Can educational robotics introduce young children to robotics and how can we measure it?

Author

Castro, Emanuela, Cecchi, Francesca, Valente, Massimiliano, Buselli, Elisa, Salvini, Pericle, and Dario, Paolo

Subjects

ENGINEERING, HEALTH occupations students, MATHEMATICS, RESEARCH methodology, MEDICAL protocols, QUESTIONNAIRES, RESEARCH funding, ROBOTICS, SCIENCE, SEX distribution, STATISTICS, STUDENT assistance programs, STUDENTS, TEACHERS, TECHNOLOGY, DATA analysis, TEACHING methods, PRE-tests & post-tests, MANN Whitney U Test, ADOLESCENCE

Abstract

Studies have shown that educational robotics (ER) may impact student learning, especially in relation to STEM (science, technology, engineering, and mathematics) areas. In the STEM framework, particularly for younger children, the "E" and the "T" are considered to be missing letters, because few studies have concentrated on teaching and evaluating technology and engineering through ER activities. This study aimed to develop and test the efficacy of an ER protocol to teach robotics in a sample of 389 students, hypothesizing that girls would be as successful as boys. A Robotics Questionnaire assessing the basics of robotics was developed for this study. A Wilcoxon nonparametric test was performed in order to evaluate improvements (p < 0.05). A Mann–Whitney nonparametric test was performed in order to test the presence of gender differences (p < 0.05). Data indicated significant improvements for all the age ranges considered. No gender differences were found. In order to evaluate the efficacy of a didactic intervention utilizing ER, it is important to assess the impact on children's technological and engineering (robotics, in particular) knowledge. Lay Description: What is already known about this topic: Studies have shown that educational robotics (ER) has a potential impact on student learning.In the STEM framework, the "E" and the "T" are considered the STEM missing letters.What this paper adds: This study aims at developing and testing the efficacy of an ER protocol to teach robotics.The hypothesis that girls will be equally successful than boys is explored too, and no gender differences were found.Implications for practice and/or policy: Our results suggest that ER can be utilized to learn robotics, bringing technology in the schools.ER could be considered as a tool able to contribute to girl's involvement in STEM. [ABSTRACT FROM AUTHOR]

Published

2018

6. A Vestibular Interface for Natural Control of Steering in the Locomotion of Robotic Artifacts: Preliminary Experiments.

Author

Siciliano, Bruno, Khatib, Oussama, Groen, Frans, Thrun, Sebastian, Brooks, Rodney, Durrant-Whyte, Hugh, Laschi, Cecilia, Maini, Eliseo Stefano, Patane', Francesco, Ascari, Luca, Ciaravella, Gaetano, Bertocchi, Ulisse, Stefanini, Cesare, Dario, Paolo, and Berthoz, Alain

Abstract

This work addresses the problem of developing novel interfaces for robotic systems that can allow the most natural transmission of control commands and sensory information, in the two directions. A novel approach to the development of natural interfaces is based on the detection of the human's motion intention, instead of the movement itself, as in traditional interfaces. Based on recent findings in neuroscience, the intention can be detected from anticipatory movements that naturally accompany more complex motor behaviors. [ABSTRACT FROM AUTHOR]

Published

2007

7. Modeling and Experiments on a Legged Microrobot Locomoting in a Tubular, Compliant and Slippery Environment.

Author

Ang, Marcelo H., Khatib, Oussama, Dario, Paolo, Stefanini, Cesare, and Menciassi, Arianna

Abstract

This paper presents the concept and preliminary modeling of a legged microrobot locomoting in a tubular, compliant and slippery environment. The application field is the one of endoscopic microcapsules intended to navigate inside the gastrointestinal tract for diagnosis and therapy. After introducing and discussing the issue of autonomous locomotion of endoscopic devices, with reference to worldwide ongoing research in the field, the legged solution is proposed and peculiarities of this approach are described. The importance of simulation means for such a device is discussed and a modeling for this particular kind of locomotion is presented. Experimental results are also described for the definition of biomechanical parameters necessary in the model. [ABSTRACT FROM AUTHOR]

Published

2006

8. Safe Robot Driving in Cluttered Environments.

Author

Dario, Paolo, Chatila, Raja, Thorpe, Chuck, Carlson, Justin, Duggins, Dave, Gowdy, Jay, MacLachlan, Rob, Mertz, Christoph, Suppe, Arne, and Wang, Bob

Abstract

The Navlab group at Carnegie Mellon University has a long history of development of automated vehicles and intelligent systems for driver assistance. The earlier work of the group concentrated on road following, cross-country driving, and obstacle detection. The new focus is on short-range sensing, to look all around the vehicle for safe driving. The current system uses video sensing, laser rangefinders, a novel light-stripe rangefinder, software to process each sensor individually, and a map-based fusion system. The complete system has been demonstrated on the Navlab 11 vehicle for monitoring the environment of a vehicle driving through a cluttered urban environment, detecting and tracking fixed objects, moving objects, pedestrians, curbs, and roads.* [ABSTRACT FROM AUTHOR]

Published

2005

9. Lessons from the Past 50 Years of Robotics.

Author

Dario, Paolo, Chatila, Raja, and Roth, Bernard

Abstract

In this session the three participants presented a short overview of what they believe to be key issues and milestones that have brought us to the present. They then give their perspective as to the major issues for the future. Personally, I feel the major lesson from the past is that the notion of general purpose robotic devices proved to be too ambitious, and flawed as a generating principle. Instead, versatile special purpose devices have proved to be the key to successful robot development. I believe this is the major lesson from the past 50 years, and it will continue to be the case into the foreseeable future. [ABSTRACT FROM AUTHOR]

Published

2005

10. A Statistic Model of Embodied Symbol Emergence.

Author

Dario, Paolo, Chatila, Raja, Nakamura, Yoshihiko, Inamura, Tetsunari, and Tanie, Hiroaki

Abstract

Mimesis theory is one of the primitive skill of imitative learning which is regarded as an origin of human intelligence because imitation is fundamental function for communication and symbol manipulation When the mimesis is adopted as learning method for humanoids loads for designing full body behavior would be decrease because bottom up learning approaches from robot side and top down teaching approaches from user side involved each other. Therefore we propose a behavior acquisition and understanding system for humanoids based on the mime sis theory. This system is able to abstract observed others behaviors into symbols to recognize others behavior using the symbols and to generate motion patterns using the symbols. In this paper we extend the mimesis model to geometric symbol space which contains relative distance information among symbols We also discuss how to generate complex behavior by geometric symbol manipulation in the symbol space and how to recognize novel behavior using combination of symbols by known symbols. [ABSTRACT FROM AUTHOR]

Published

2005

11. Learning Movement Primitives.

Author

Dario, Paolo, Chatila, Raja, Schaal, Stefan, Peters, Jan, Nakanishi, Jun, and Ijspeert, Auke

Abstract

This paper discusses a comprehensive framework for modular motor control based on a recently developed theory of dynamic movement primitives (DMP). DMPs are a formulation of movement primitives with autonomous nonlinear differential equations, whose time evolution creates smooth kinematic control policies. Model-based control theory is used to convert the outputs of these policies into motor commands. By means of coupling terms, on-line modifications can be incorporated into the time evolution of the differential equations, thus providing a rather flexible and reactive framework for motor planning and execution. The linear parameterization of DMPs lends itself naturally to supervised learning from demonstration. Moreover, the temporal, scale, and translation invariance of the differential equations with respect to these parameters provides a useful means for movement recognition. A novel reinforcement learning technique based on natural stochastic policy gradients allows a general approach of improving DMPs by trial and error learning with respect to almost arbitrary optimization criteria. We demonstrate the different ingredients of the DMP approach in various examples, involving skill learning from demonstration on the humanoid robot DB, and learning biped walking from demonstration in simulation, including self-improvement of the movement patterns towards energy efficiency through resonance tuning. [ABSTRACT FROM AUTHOR]

Published

2005

12. Learning from Observation and from Practice Using Behavioral Primitives.

Author

Dario, Paolo, Chatila, Raja, Bentivegna, Darrin, Cheng, Gordon, and Atkeson, Christopher

Abstract

We describe a memory-based approach to learning how to select and provide sub-goals for behavioral primitives, given an existing library of primitives. We demonstrate both learning from observation and learning from practice on a marble maze task, Labyrinth. [ABSTRACT FROM AUTHOR]

Published

2005

13. A Biologically Inspired Passive Antenna for Steering Control of a Running Robot.

Author

Dario, Paolo, Chatila, Raja, Cowan, Noah J., Ma, Emily J., Cutkosky, Mark, and Full, Robert J.

Abstract

Inspired by nature's effective use of tactile feedback for rapid maneuvering, we designed a passive, highly compliant tactile sensor for Sprawlette, a hexapedal running robot. To bridge the gap between biology and design, we took initial steps toward understanding how the cockroach, Periplaneta americana, uses antenna feedback to control its orientation during a rapid wall following behavior. First, we developed a simple template model for antenna-based wall following. Second, we collected initial cockroach data that supports the idea that the rate of convergence to the wall or "tactile flow" is being used, in part, for controlling body orientation. Based on these steps, we designed and calibrated a prototype tactile sensor to measure Sprawlette's angle and distance relative to a straight wall, and employed a simple bio-inspired control law that can stabilize the template dynamics. Finally, we integrated the sensor and controller on Sprawlette and showed empirically that stabilizing Sprawlette during wall following does indeed require tactile flow, as predicted. [ABSTRACT FROM AUTHOR]

Published

2005

14. Variable Stiffness Actuators for Fast and Safe Motion Control.

Author

Dario, Paolo, Chatila, Raja, Bicchi, Antonio, Tonietti, Giovanni, Bavaro, Michele, and Piccigallo, Marco

Abstract

In this paper we propose Variable Stiffness actuation [1] as a viable mechanical/control co-design approach for guaranteeing control performance for robot arms that are inherently safe to humans in their environment. A new actuator under development in our Lab is then proposed, which incorporate the possibility to vary transmission stiffness during motion execution, thus allowing substantial motion speed-up while maintaining low injury risk levels. [ABSTRACT FROM AUTHOR]

Published

2005

15. The 100G Capturing Robot — Too Fast to See.

Author

Dario, Paolo, Chatila, Raja, Kaneko, Makoto, Higashimori, Mitsuru, Namiki, Akio, and Ishikawa, Masatoshi

Abstract

This paper discusses the 100G Capturing Robot that can produce the maximum acceleration of 100G in design specification. To achieve such a high acceleration, we utilize spring energy with a light arm/gripper. The Arm/Gripper Coupling Mechanism (AGCM) is newly introduced so that we can efficiently transmit a single energy resource for finally closing the gripper. Experimental results show that the developed robot can capture a dropping ball with the maximum acceleration of 91G and the capturing time of roughly 25ms. We also discuss various technical issues to be considered when designing such a high speed capturing robot. [ABSTRACT FROM AUTHOR]

Published

2005

16. UntetheredMicro-Actuators for Autonomous Micro-robot Locomotion: Design, Fabrication, Control, and Performance.

Author

Dario, Paolo, Chatila, Raja, Donald, Bruce R., Levey, Christopher G., McGray, Craig D., Rus, Daniela, and Sinclair, Mike

Abstract

This paper presents a micro-actuator that operates free of any physically restraining tethers. We show how capacitive coupling can be used to deliver power to untethered MEMS (micro-electromechanical systems) devices, independently of their position and orientation. Our novel power delivery and actuation mechanisms are designed for use in autonomous mobile robots whose dimensions can be measured in tens to hundreds of micrometers. Test devices utilizing these mechanisms have been fabricated at scale using MEMS technology, and have been shown capable of untethered locomotion at speeds exceeding 1.5 mm/sec. The corresponding speed, scaled to a car-sized robot would be over 100 km/hr. The possibility of autonomous (untethered) microactuators and microrobots less than 80 μm in length opens the door to novel applications in distributed and parallel robotics. Scratch-drive actuators (SDAs) [1,2] are capable of both high speed and nanometer-scale precision, making them a promising choice for the actuators of mobile microrobots. We developed a novel kind of SDA that walks without the physically-restraining electrical tethers, rails, stators, or springs required in previous work. Our power delivery mechanism operates through a capacitive coupling with a silicon substrate that underlies the mobile device. This allows the device actuation mechanism to use electrostatic forces without requiring any physical connection or wire that would restrain the motion of the device. Through appropriate design of the substrate wiring and actuator geometries, the power delivered to the device can be shown to be independent of the device's position and orientation. For this reason, this power delivery mechanism is appropriate for fully two-dimensional (x, y) and (x, y, θ) mobile microrobots. [ABSTRACT FROM AUTHOR]

Published

2005

17. Multisensory Interaction: Real and Virtual.

Author

Dario, Paolo, Chatila, Raja, and Pai, Dinesh K.

Abstract

Human physical interaction is inherently multisensory, using vision, touch, hearing, and other senses. We discuss the constraints and opportunities for constructing computational models for multisensory interaction. Such models could be used to develop better robots and human interfaces, and to understand human interaction. [ABSTRACT FROM AUTHOR]

Published

2005

18. A Model for Machine Perception in Natural Environments.

Author

Dario, Paolo, Chatila, Raja, Durrant-Whyte, Hugh, Kumar, Suresh, Guivant, Jose, and Scheding, Steve

Abstract

This paper proposes a new model for machine perception in natural outdoor environments. The goal is to find a method of describing and fusing information obtained from a diverse array of sensors, and to provide a robust interpretation of unstructured outdoor scenes, primarily for the purpose of autonomous navigation. The model has three key components: First,it is based around a high- dimensional sensor-centric description of the environment and deliberately avoids the fragile process of feature extraction from any one sensor. Second, the description is itself embedded in a probabilistic structure allowing Bayes Theorem to be used for temporal fusion of information. Finally, a task-directed process of nonlinear dimensionality reduction, abstraction or compression is used to identify low-dimensional high-contrast features embedded in the high-dimensional sensor space. Such features are the "sensors own view" of what constitutes important information for the task at hand. The paper provides a number of preliminary experimental results of applying this model to combinations of mm-wave radar, laser and night-vision sensors. [ABSTRACT FROM AUTHOR]

Published

2005

19. Multi-contact Haptic Interaction with Deformable Objects: A Multi-rate Approach.

Author

Dario, Paolo, Chatila, Raja, Barbagli, Federico, Prattichizzo, Domenico, and Salisbury, Kenneth

Abstract

This paper describes anew solution for stable haptic interaction with deformable object simulations featuring low servo rates and computational delays. The proposed solution is a combination of the local model and the virtual coupling concepts proposed in the past. More specifically we propose a local model structure that adapts to the deformable object local geometry and impedance characteristics. By doing so we are able to run a haptic interaction loop at high update rates,thus maximizing the Z-width of the simulation, while obtaining overall stable behavior without using any added damping. Furthermore the local model is always computed using the current deformable object surface, thus allowing for real multi-point contact interaction. The proposed solution is presented and analyzed in a multi-rate setting. Some experimental results employing a PHANTOM haptic interface are proposed for a simple one-dimensional example. [ABSTRACT FROM AUTHOR]

Published

2005

20. Perception of Curvature and Object Motion Via Contact Location Feedback.

Author

Dario, Paolo, Chatila, Raja, Provancher, William R., Kuchenbecker, Katherine J., Niemeyer, Günter, and Cutkosky, Mark R.

Abstract

We describe a new tactile display for use in dexterous telemanipulation and virtual reality. Our system renders the changing location of a remote or virtual contact by moving a tactile element along the user's fingertip. Mounted at the endpoint of a haptic mechanism, our thimble-sized device concurrently displays contact location and interaction forces. We believe such a design will enable more versatile object manipulation for haptic interactions. To evaluate this display concept, we conducted two perceptual experiments. First, human subjects judged object curvature though direct manipulation of physical models and virtual manipulation with the device. Results show similar levels of discrimination in real and virtual interactions, indicating the device can effectively portray contact information. Second, we investigated virtual interactions with rolling and anchored objects and demonstrated that users can distinguish the interaction type using our device. These experiments provide insight into the sensitivity of human perception and suggest that even a simple display of the contact centroid location may significantly enhance telerobotic and virtual grasping tasks. [ABSTRACT FROM AUTHOR]

Published

2005

21. Multi-resolution SLAM for Real World Navigation.

Author

Dario, Paolo, Chatila, Raja, Martinelli, Agostino, Tapus, Adriana, Arras, Kai Olivier, and Siegwart, Roland

Abstract

In this paper a hierarchical multi-resolution approach allowing for high precision and distinctiveness is presented. The method combines topological and metric paradigm. The metric approach, based on the Kalman Filter, uses a new concept to avoid the problem of the drift in odometry. For the topological framework the fingerprint sequence approach is used. During the construction of the topological map, a communication between the two paradigms is established. The fingerprint used for topological navigation enables also the re-initialization of the metric localization. The experimentation section will validate the multi-resolution-representation maps approach and presents different steps of the method. [ABSTRACT FROM AUTHOR]

Published

2005

22. Building Blocks for SLAM in Autonomous Compliant Motion.

Author

Dario, Paolo, Chatila, Raja, Bruyninckx, H., Schutter, J., Lefebvre, T., Gadeyne, K., Soetens, P., Rutgeerts, J., Slaets, P., and Meeussen, W.

Abstract

This paper presents our research group's latest results in autonomous force-controlled manipulation tasks: (i) advanced non-linear estimators for simultaneous parameter estimation and contact formation "map building" for 6D contact tasks (with active sensing integrated into the task planner), and (ii) the application of these results to programming by human demonstration, for tasks involving contacts. [ABSTRACT FROM AUTHOR]

Published

2005

23. Towards Lazy Data Association in SLAM.

Author

Dario, Paolo, Chatila, Raja, Hähnel, Dirk, Thrun, Sebastian, Wegbreit, Ben, and Burgard, Wolfram

Abstract

We present a lazy data association algorithm for the simultaneous localization and mapping (SLAM) problem. Our approach uses a tree-structured Bayesian representation of map posteriors that makes it possible to revise data association decisions arbitrarily far into the past. We describe a criterion for detecting and repairing poor data association decisions. This technique makes it possible to acquire maps of large-scale environments with many loops, with a minimum of computational overhead for the management of multiple data association hypotheses. A empirical comparison with the popular FastSLAM algorithm shows the advantage of lazy over proactive data association. [ABSTRACT FROM AUTHOR]

Published

2005

24. Towards Constant-Time SLAM on an Autonomous Underwater Vehicle Using Synthetic Aperture Sonar.

Author

Dario, Paolo, Chatila, Raja, Newman, Paul M., Leonard, John J., and Rikoski, Richard J.

Abstract

This paper applies a new constant-time, consistent and convergent Simultaneous Localization and Mapping (SLAM) algorithm to synthetic aperture sonar (SAS) data acquired by an autonomous underwater vehicle (AUV). Using a novel target detection strategy, data gathered from a 40 minute survey is processed and the results compared to both a ground truth and the "gold standard" quadratic time full covariance SLAM algorithm. [ABSTRACT FROM AUTHOR]

Published

2005

25. Recasting SLAM - Towards Improving Efficiency and Platform Independency.

Author

Dario, Paolo, Chatila, Raja, Kim, Jong Hyuk, and Sukkarieh, Salah

Abstract

This paper provides an alternative solution to solving SLAM's computational complexity in Inertial Navigation System (INS) application, not from the perspective of map management techniques, but by focusing on the filter's structure and model, and re-casting the SLAM algorithm into what is known as an "indirect" implementation. In doing so we provide a navigation structure which is computationally efficient in even for highly non-linear, highly dynamic systems. [ABSTRACT FROM AUTHOR]

Published

2005

26. Exploiting the Global Dynamics Structure of Whole-Body Humanoid Motion - Getting the "Knack" of Roll-and-Rise Motion.

Author

Dario, Paolo, Chatila, Raja, Kuniyoshi, Yasuo, Ohmura, Yoshiyuki, Terada, Koji, Yamamoto, Tomoyuki, and Nagakubo, Akihiko

Abstract

Dexterity of human behavior arises from the ability to discover and ex-ploit so-called "knacks", or the essential reference frames (coordinates in the phase space) for successful control under unknown perturbations. This strategy differs from the traditional robot control in that it only partially specifies/controls the phase space trajectory, pushing the system into a desired natural dynamics, letting it do the job. As the first example of such a strategy, we investigated a "roll-and-rise" motion, a fully dynamic whole-body motion with unpredictable perturbations due to multiple contacts with the ground. The "knacks" of the motion are identified and analyzed by a systematic search of the phase space. A successful experiment with an adult-size whole body humanoid robot is presented; it rose from a flat-lying posture to a crouching posture within 2 seconds. [ABSTRACT FROM AUTHOR]

Published

2005

27. The Human-Size Humanoid Robot That Can Walk, Lie Down and Get Up.

Author

Dario, Paolo, Chatila, Raja, Hirukawa, Hirohisa, Kajita, Shuuji, Kanehiro, Fumio, Kaneko, Kenji, and Isozumi, Takakatsu

Abstract

This paper present a humanoid robot, called HRP-2, that can walk, lie down and get up. We believe that HRP-2, 154[cm] height an 58[kg] weight, is the first humanoid robot that has the human-size and can lie down and get up. The biped walking is realized by a walking pattern generator using a preview control and by a feedback control. The lying down and getting up motions were made possible by HRP2's compact body with a waist joint and a novel motion controller. [ABSTRACT FROM AUTHOR]

Published

2005

28. Motion Planning for Humanoid Robots.

Author

Dario, Paolo, Chatila, Raja, Kuffner, James, Nishiwaki, Koichi, Kagami, Satoshi, Inaba, Masayuki, and Inoue, Hirochika

Abstract

Humanoid robotics hardware and control techniques have advanced rapidly during the last five years. Presently, several companies have announced the commercial availability of various humanoid robot prototypes. In order to improve the autonomy and overall functionality of these robots, reliable sensors, safety mechanisms, and general integrated software tools and techniques are needed. We believe that the development of practical motion planning algorithms and obstacle avoidance software for humanoid robots represents an important enabling technology. This paper gives an overview of some of our recent efforts to develop motion planning methods for humanoid robots for application tasks involving navigation, object grasping and manipulation, footstep placement, and dynamically-stable full-body motions. We show experimental results obtained by implementations running within a simulation environment as well as on actual humanoid robot hardware. [ABSTRACT FROM AUTHOR]

Published

2005

29. SDR-4X II: A Small Humanoid as an Entertainer in Home Environment.

Author

Dario, Paolo, Chatila, Raja, Fujita, Masahiro, Sabe, Kohtaro, Kuroki, Yoshihiro, Ishida, Tatsuzo, and Doi, Toshi T.

Abstract

In this paper we describe the autonomous behavior control architecture of SDR-4X II, which serves to integrate multi-modal recognition and motion control technologies. We overview the entire software architecture of SDR-4X II, which is composed of perception, short and long term memory, behavior control, and motion control parts. Regarding autonomous behavior control, we further focus on issues such as spontaneous behavior generation using a homeostasis regulation mechanism, and a behavior control/selection mechanism with tree-structured situated behavior modules. In the autonomous behavior control architecture, we achieve three basic requirements, which are the concurrent evaluation of the situation of each behavior module, concurrent execution of multiple behavior modules, and preemption (behavior interruption/resume capability). Using the autonomous behavior control architecture described, we demonstrate that SDR-4X II can spontaneously and passively interact with a human. [ABSTRACT FROM AUTHOR]

Published

2005

30. Seeing Through Bad Weather.

Author

Dario, Paolo, Chatila, Raja, Nayar, Shree K., and Narasimhan, Srinivasa G.

Abstract

Current vision systems are designed to perform in clear weather. Needless to say, in any outdoor application, there is no escape from bad weather. Ultimately, computer vision systems must include mechanisms that enable them to function (even if somewhat less reliably) in the presence of haze, fog, rain, hail and snow. We begin by studying the visual manifestations of different weather conditions. For this, we draw on what is already known about atmospheric optics, and identify effects caused by bad weather that can be turned to our advantage; we are not only interested in what bad weather does TO vision but also what it can do FOR vision. [ABSTRACT FROM AUTHOR]

Published

2005

31. Applying Active Vision and SLAM to Wearables.

Author

Dario, Paolo, Chatila, Raja, Mayol, Walterio W., Davison, Andrew J., Tordoff, Ben J., and Murray, David W.

Abstract

This paper reviews aspects of the design and construction of an active wearable camera, and describes progress in equipping it with visual processing for reactive tasks like orientation stabilisation, slaving from head movements, and 2D tracking. The paper goes on to describe a first application of frame-rate simultaneous localisation and mapping (SLAM) to the wearable camera. Though relevant for any single camera undergoing general motion, the approach has particular benefits in wearable vision, allowing extended periods of purposive fixation followed by controlled redirection of gaze to other parts of the scene. [ABSTRACT FROM AUTHOR]

Published

2005

32. Simultaneous Localization and Mapping with Stereovision.

Author

Dario, Paolo, Chatila, Raja, Jung, Il-Kyun, and Lacroix, Simon

Abstract

This paper presents a simultaneous localization and mapping approach based on an extended kalman filter, using only a set of non-registered stereovision image pairs. Invariant image point features are used to detect 3D landmarks and to provide local motion estimates. The 3D coordinates of each point feature are computed by stereovision, and an interest point matching algorithm solves the data association problem. The estimation of the errors on the local motion estimations, on the landmark initialisations and on the landmark observations are depicted, and results with low altitude aerial images are presented. [ABSTRACT FROM AUTHOR]

Published

2005

33. Visual Tracking of Multiple Objects Using Binary Space Partitioning Trees.

Author

Dario, Paolo, Chatila, Raja, Caccavale, Fabrizio, Lippiello, Vincenzo, Siciliano, Bruno, and Villani, Luigi

Abstract

The use of visual sensors may have high impact in robotic applications where it is required to measure the pose (position and orientation) and the visual features of objects moving in unstructured environments. In this paper, the problem of real-time estimation of the position and orientation of of multiple objects is considered. Special emphasis is devoted to the case when two or more objects overlap with respect to the visual system causing occlusion. The algorithm is based on the Kalman filtering and Binary Space Partition (BSP) tree representations of the objects geometry. The real-time implementation of the algorithm is experimentally tested for the case of visual tracking of two objects using two cameras. [ABSTRACT FROM AUTHOR]

Published

2005

34. Obstacle Detection in Foliage with Ladar and Radar.

Author

Dario, Paolo, Chatila, Raja, Matthies, Larry, Bergh, Chuck, Castano, Andres, Macedo, Jose, and Manduchi, Roberto

Abstract

Autonomous off-road navigation is central to several important applications of unmanned ground vehicles. This requires the ability to detect obstacles in vegetation. We examine the prospects for doing so with scanning ladar and with a linear array of 2.2 GHz micro-impulse radar transceivers. For ladar, we summarize our work to date on algorithms for detecting obstacles in tall grass with single-axis ladar, then present a simple probabilistic model of the distance into tall grass that ladar-based obstacle detection is possible. This model indicates that the ladar "penetration depth" can range from on the order of 10 cm to several meters, depending on the plant type. We also present an experimental investigation of mixed pixel phenomenology for a time-of-flight, SICK ladar and discuss briefly how this bears on the problem. For radar, we show results of applying an existing algorithm for multi-frequency diffraction tomography to a set of 45 scans taken with one sensor translating laterally 4 cm/scan to mimic a linear array of transceivers. This produces a high resolution, 2-D map of scattering surfaces in front of the array and clearly reveals a large tree trunk behind over 2.5 m of thick foliage. Both types of sensor warrant further development and exploitation for this problem. [ABSTRACT FROM AUTHOR]

Published

2005

35. Feedback Control of Underactuated Systems via Sequential Composition: Visually Guided Control of a Unicycle.

Author

Dario, Paolo, Chatila, Raja, Kantor, George, and Rizzi, Alfred A.

Abstract

We present a newapproach to developing hybrid feedback policies for the control of systems with nonholonomic constraints. We extend the idea of sequential composition and use it to to switch between controllers in a state based manner, resulting in a globally convergent, pure feedback policy. Individual controllers in the palette are inspired by variable constraint control. We solve a vision guided unicycle navigation problem and present experimental results. [ABSTRACT FROM AUTHOR]

Published

2005

36. Multi-robot SLAM with Sparse Extended Information Filers.

Author

Dario, Paolo, Chatila, Raja, Thrun, Sebastian, and Liu, Yufeng

Abstract

We present an algorithm for the multi-robot simultaneous localization and map-ping (SLAM) problem. Our algorithm enables teams of robots to build joint maps, even if their relative starting locations are unknown and landmarks are ambiguous—which is presently an open problem in robotics. It achieves this capability through a sparse information filter technique, which represents maps and robot poses by Gaussian Markov random fields. The alignment of local maps into a single global maps is achieved by a tree-based algorithm for searching similar-looking local landmark configurations, paired with a hill climbing algorithm that maximizes the overall likelihood by search in the space of correspondences. We report favorable results obtained with a real-world benchmark data set. [ABSTRACT FROM AUTHOR]

Published

2005

37. A Multi Agent Distributed Sensing Architecture with Application to Planetary Cliff Exploration.

Author

Dario, Paolo, Chatila, Raja, Sujan, Vivek A., Dubowsky, Steven, Huntsberger, Terry, Aghazarian, Hrand, Cheng, Yang, and Schenker, Paul

Abstract

Future planetary exploration missions will use cooperative robots to explore and sample rough terrain. To succeed robots will need to cooperatively acquire and share data. Here a cooperative multi-agent sensing architecture is presented and applied to the mapping of a cliff surface. This algorithm efficiently repositions the systems' sensing agents using an information theoretic approach and fuses sensory information using physical models to yield a geometrically consistent environment map. This map is then distributed among the agents using an information based relevant data reduction scheme. Experimental results for cliff face mapping using the JPL Sample Return Rover (SRR) are presented. The method is shown to significantly improve mapping efficiency over conventional methods. [ABSTRACT FROM AUTHOR]

Published

2005

38. Networked Robots: Flying Robot Navigation using a Sensor Net.

Author

Dario, Paolo, Chatila, Raja, Corke, Peter, Peterson, Ron, and Rus, Daniela

Abstract

This paper introduces the application of a sensor network to navigate a flying robot. We have developed distributed algorithms and efficient geographic routing techniques to incrementally guide one or more robots to points of interest based on sensor gradient fields, or along paths defined in terms of Cartesian coordinates. The robot itself is an integral part of the localization process which establishes the positions of sensors which are not known a priori. We use this system in a large-scale outdoor experiment with Mote sensors to guide an autonomous helicopter along a path encoded in the network. [ABSTRACT FROM AUTHOR]

Published

2005

39. Abstraction and Control for Swarms of Robots.

Author

Dario, Paolo, Chatila, Raja, Belta, Calin, Pereira, Guilherme A.S., and Kumar, Vijay

Abstract

This paper addresses the design of simple robot behaviors that realize emergent group behaviors. We present a method to coordinate a large number of under-actuated robots by designing control laws on a small dimensional abstraction manifold, independent of the number and ordering of the robots. The abstraction manifold has a product structure consisting of elements of a Lie group that capture the position and orientation of the ensemble in the world frame, and elements of a shape manifold that provide an intrinsic description of the distribution of team members relative to one another. We design decoupled controls for regulating the group and the shape variables. The realization of the controller on each robot requires the feedback of the robot state, and the state on the abstraction manifold. We present experimental results with a team of five car-like robots equipped with omnidirectional cameras and IEEE 802.11b networking. [ABSTRACT FROM AUTHOR]

Published

2005

40. Session Summary.

Author

Dario, Paolo, Chatila, Raja, and Hollerbach, John

Abstract

This session's papers deal with the coordination and integration of information from multiple robots to map and navigate their environments. [ABSTRACT FROM AUTHOR]

Published

2005

41. Robot-Robot and Human-Robot Cooperation in Commercial Robotics Applications.

Author

Dario, Paolo, Chatila, Raja, Koeppe, R., Engelhardt, D., Hagenauer, A., Heiligensetzer, P., Kneifel, B., Knipfer, A., and K.Stoddard

Abstract

Robot-Robot and Human-Robot cooperation technologies are about to mature in commercial robotics applications. In this paper we outline KUKA's cooperating robot technology and show its potential benefit in automotive production. A major step in demonstrating human-robot coexistence has been achieved by the KUKA RoboCoaster, a robotic entertainment system. Further steps are discussed by showing potential technologies for safeguarded human-robot interaction in production. Keywords robot-robot cooperation, human-robot cooperation, entertainment robotics, robotics safety, capacitive proximity sensors, haptic devices. [ABSTRACT FROM AUTHOR]

Published

2005

42. Face Recognition Using Multi-viewpoint Patterns for Robot Vision.

Author

Dario, Paolo, Chatila, Raja, Fukui, Kazuhiro, and Yamaguchi, Osamu

Abstract

This paper introduces a novel approach for face recognition using multiple face patterns obtained in various views for robot vision. A face pattern may change dramatically due to changes in the relation between the positions of a robot, a subject and light sources. As a robot is not generally able to ascertain such changes by itself, face recognition in robot vision must be robust against variations caused by the changes. Conventional methods using a single face pattern are not capable of dealing with the variations of face pattern. In order to overcome the problem, we have developed a face recognition method based on the constrained mutual subspace method (CMSM) using multi-viewpoint face patterns attributable to the movement of a robot or a subject. The effectiveness of our method for robot vision is demonstrated by means of a preliminary experiment. [ABSTRACT FROM AUTHOR]

Published

2005

43. Designing an Encountered-Type Haptic Display for Multiple Fingertip Contacts based on the Observation of Human Grasping Behavior.

Author

Dario, Paolo, Chatila, Raja, Yokokohji, Yasuyoshi, Muramori, Nobuhiko, Sato, Yuji, and Yoshikawa, Tsuneo

Abstract

Unlike conventional haptic devices, an encountered-type device is not held by a user all the time. Instead, the device stays at the location of a virtual object and waits for the user to encounter it. In this paper, we extend this concept to fingertip contacts and design an encountered-type haptic display for multiple fingertip contacts to simulate tasks of grasping an object with any shape and size. Before designing the device, we intensively observed human grasping behaviors. This observation was very helpful to determine the mechanism of the device. An encountered-type device for three-fingered grasping was actually prototyped based on our design. [ABSTRACT FROM AUTHOR]

Published

2005

44. Intuitive Human-Robot Interaction Through Active 3D Gaze Tracking.

Author

Dario, Paolo, Chatila, Raja, Atienza, Rowel, and Zelinsky, Alexander

Abstract

One of the biggest obstacles facing humans and robots is the lack of means for natural and meaningful interaction. Robots find it difficult to understand human intentions since our way of communication is different from the way machines exchange their information. Our aim is to remove this barrier by creating systems that react and respond to natural human actions. In this research, we present a robotic system that identifies and picks up an arbitrary object in 3D space that a person is looking at. It is done through an active vision system that is able to understand the focus of attention of a user. Whenever the person is close enough, the gaze direction is determined and used to find the object of interest which is of unknown size, shape and color. A robot arm responds by picking up this object and handing it over to the person. [ABSTRACT FROM AUTHOR]

Published

2005

45. Human-Machine Collaborative Systems for Microsurgical Applications.

Author

Dario, Paolo, Chatila, Raja, Kragic, D., Marayong, P., Li, M., Okamura, A.M., and Hager, G.D.

Abstract

We describe our current progress in developing Human-Machine Collaborative Systems (HMCSs) for microsurgical applications such as vitreo-retinal eye surgery. Three specific problems considered here are (1) developing of systems tools for describing and implementing an HMCS, (2) segmentation of complex tasks into logical components given sensor traces of a human performing the task, and (3) measuring HMCS performance. Our goal is to integrate these into a full microsurgical workstation with the ability to automatically "parse" traces of user execution into a task model which is then loaded into the execution environment, providing the user with assistance using online recognition of task state. The major contributions of our work to date include an XML task graph modeling framework and execution engine, an algorithm for real-time segmentation of user actions using continuous Hidden Markov Models, and validation techniques for analyzing the performance of HMCSs. [ABSTRACT FROM AUTHOR]

Published

2005

46. Surgical Robots at TIMC: Where We Are and Where We Go.

Author

Dario, Paolo, Chatila, Raja, Troccaz, Jocelyne, Cinquin, Philippe, Berkelman, Peter, Vilchis-Gonzales, Adriana, and Boidard, Eric

Abstract

Grenoble was one of the first places worldwide where a robot was used in clinical routine. In 1989, the first robot-assisted procedure on a patient took place in the neurosurgery department of the Grenoble University Hospital. An industrial robot modified to satisfy to the clinical constraints was used as a positioning device for guiding minimally invasively the surgical tool to a planned target. Based on that experience and on our knowledge of the clinical domain, we progressively re-directed our activity towards the design of specific robotic devices answering important issues among which safety, interactivity and clinical suitability. In this paper, we describe in more details our view of what surgical robotics is and should be and we illustrate our approach by the description and discussion of research in progress at TIMC: the PADyC arm, a passive device constraining the surgeon's motions in function of a pre-planned surgical protocol - the TER system a non rigid and portable robot for tele-echography - and LER a portable endoscope holder. We will discuss the specificities of medical robotics. Finally, we will draw the perspectives that we foresee for this domain. [ABSTRACT FROM AUTHOR]

Published

2005

47. Assisted Teleoperation Through the Merging of Real and Virtual Images.

Author

Dario, Paolo, Chatila, Raja, and Casals, Alícia

Abstract

The execution of teleoperated tasks is based on the visual feedback of the working scene through TV cameras located adequately in the working environment. Common problems in many applications are the lack of visibility produced by the task conditions and poor dexterity. With the aim of increasing the users' perception capabilities, as well as, their precision ability, a set of teleoperation aids have been studied and developed. These aids are based on visual information and other sensor data or on some knowledge about the working environment. [ABSTRACT FROM AUTHOR]

Published

2005

48. Modeling of Brain Mechanical Properties for Computer-Integrated Medicine.

Author

Dario, Paolo, Chatila, Raja, Miller, Karol, and Nowinski, Wieslaw L.

Abstract

Many modern applications of technology to medicine, such as robotic surgery, non-rigid registration, virtual reality operation planning and surgeon training systems, and surgical simulators, require knowledge of mechanical properties of very soft tissues. In this paper we describe and identify a model of mechanical properties of brain tissue aimed in particular at integration with interactive brain atlases. A non-linear, viscoelastic model based on the generalization of the Ogden strain energy hyperelastic constitutive equation is proposed. The material parameters are identified using in-vitro experimental results. The model accounts well for brain tissue deformation behavior in both tension and compression (natural strain $\in\langle -0.3, 0.2\rangle$) for strain rates typical for surgical procedures. It can be immediately applied in large-scale finite element simulations and, therefore, offers the possibility of incorporating mechanics into surgical planning and training systems such as NeuroPlanner and BrainBench. Finally we show that the brain model identified based on in-vitro experiments can be applied in the more realistic in-vivo setting. [ABSTRACT FROM AUTHOR]

Published

2005

49. Microrobotics for Molecular Biology: Manipulating Deformable Objects at the Microscale.

Author

Dario, Paolo, Chatila, Raja, Nelson, Bradley J., Sun, Yu, and Greminger, Michael A.

Abstract

Recent advances in molecular biology such as cloning demonstrate that increasingly complex micromanipulation strategies for manipulating individual biological cells are required. From a robotics standpoint, the manipulation of biological cells, sometimes referred to as biomanipulation, presents several interesting research issues that extend well beyond cell manipulation. Biological cells are highly deformable objects, and the material properties of these objects are not well quantified, so developing strategies for manipulating deformable objects must be addressed. Most biological cells are between 1μm and 100μm in diameter, depending on the cell type, so micromanipulation issues must be explored, including the appropriate use of high resolution, low depth-of-field vision feedback and very low magnitude multi-axis force feedback. By pursuing robotic manipulation of biological cells, many interesting robotics research avenues in micromanipulation, deformable object handling, multi-sensor integration, and force and vision feedback assimilation must be explored. This paper explores the visual tracking of biological cells using physics-based models and the measurement of applied force fields using a new cell deformation model with visual feedback. A multi-axis MEMS-based force sensor is used to determine applied forces and develop models of cell deformation. Robust tracking of cell deformation is shown and real-time determination of applied force fields is demonstrated. In addition, the system developed has been used to quantitate for the first time a phenomenon known as "zona hardening" during mouse oocyte fertilization. [ABSTRACT FROM AUTHOR]

Published

2005

50. aSyMov:A Planner That Deals with Intricate Symbolic and Geometric Problems.

Author

Dario, Paolo, Chatila, Raja, Gravot, Fabien, Cambon, Stephane, and Alami, Rachid

Abstract

We propose an original approach to integrate symbolic task planning, and geometric motion and manipulation planning. We focus more particularly on one key aspect: the relation between the symbolic positions and their geometric counterparts. Indeed, we have developed an instantiation process that is able to propagate incrementally task-dependent as well as 3D environment-dependent constraints and to guide efficiently the search until valid geometric configurations are found that satisfy the plan at both levels. The overall process is discussed and illustrated through an implemented example. [ABSTRACT FROM AUTHOR]

Published

2005