@article {3679, title = {Design and proof of concept for multi degree of freedom hydrostatically coupled dielectric elastomer actuators with roto-translational kinematics for object handling}, journal = {Smart Materials and Structures}, year = {2018}, author = {A. De Acutis and L. Calabrese and A. Bau and V. Tincani and N. M. Pugno and A. Bicchi and D. De Rossi} } @article {3223, title = {A Multimodal Perception Framework for Users Emotional State Assessment in Social Robotics}, journal = {FUTURE INTERNET}, volume = {9}, year = {2017}, keywords = {human-robot interaction, multimodality, perception framework, physiological signal acquisition, social robotics}, doi = {10.3390/fi9030042}, author = {Cominelli, L. and N. Carbonaro and D. Mazzei and R. Garofalo and A. Tognetti and D. De Rossi} } @inbook {3221, title = {Strain and angular sensing fabrics for human motion analysis in daily life}, booktitle = {Smart textiles : fundamentals, design, and interaction}, year = {2017}, pages = {49{\textendash}70}, publisher = {Springer International Publishing}, organization = {Springer International Publishing}, address = {Dordrecht}, author = {F. Lorussi and N. Carbonaro and D. De Rossi and A. Tognetti} } @article {3235, title = {A bi-articular model for scapular-humeral rhythm reconstruction through data from wearable sensors}, journal = {JOURNAL OF NEUROENGINEERING AND REHABILITATION}, volume = {13}, year = {2016}, pages = {1{\textendash}13}, keywords = {Hand posture estimation, Reaching activity, Scapular girdle movement, Scapular-humeral rhythm, Wearable sensing}, doi = {10.1186/s12984-016-0149-2}, url = {https://jneuroengrehab.biomedcentral.com/articles/10.1186/s12984-016-0149-2}, author = {F. Lorussi and N. Carbonaro and D. De Rossi and A. Tognetti} } @conference {3232, title = {A preliminary framework for a social robot {\quotesinglbase}{\"A}{\'u}sixth sense{\quotesinglbase}{\"A}{\`u}}, booktitle = {Biomimetic and Biohybrid Systems 5th International Conference, Living Machines 2016, Edinburgh, UK, July 19-22, 2016. Proceedings}, volume = {9793}, year = {2016}, pages = {58{\textendash}70}, publisher = {Springer Verlag}, organization = {Springer Verlag}, address = {Dordrecht}, keywords = {Affective computing, Behaviour monitoring, Computer Science (all), human-robot interaction, social robotics, Synthetic tutor, Theoretical Computer Science}, doi = {10.1007/978-3-319-42417-0_6}, url = {http://springerlink.com/content/0302-9743/copyright/2005/}, author = {Cominelli, L. and D. Mazzei and N. Carbonaro and R. Garofalo and A. Zaraki and A. Tognetti and D. De Rossi} } @article {3233, title = {Wearable Textile Platform for Assessing Stroke Patient Treatment in Daily Life Conditions}, journal = {FRONTIERS IN BIOENGINEERING AND BIOTECHNOLOGY}, volume = {4}, year = {2016}, pages = {1{\textendash}28}, keywords = {ambulatory monitoring, data fusion, gait, Grasping, reaching, stroke rehabilitation, wearable sensors}, doi = {10.3389/fbioe.2016.00028}, author = {F. Lorussi and N. Carbonaro and D. De Rossi and R. Paradiso and Veltink, P. and A. Tognetti} } @conference {2495, title = {Damasio{\textquoteright}s Somatic Marker for Social Robotics: Preliminary Implementation and Test}, booktitle = {Living Machines - The 4th International Conference on Biomimetic and Biohybrid Systems}, year = {2015}, pages = {316-328}, publisher = {Springer}, organization = {Springer}, address = {Barcelona, Spain, 28 - 31 July 2015}, keywords = {Bioengineering}, url = {http://link.springer.com/chapter/10.1007/978-3-319-22979-9_31$\#$page-1}, author = {Cominelli, L. and D. Mazzei and M. Pieroni and A. Zaraki and R. Garofalo and D. De Rossi} } @conference {2718, title = {Evaluation of wearable KPF goniometers in knee flexion-extension measurement for daily-life applications}, booktitle = {Proceedings of Wireless EAI 4th International Conference on Mobile Communication and Healthcare (Mobihealth)}, year = {2015}, pages = {1-4}, publisher = {ICST (Institute for Computer Sciences, Social-Informatics and Telecommunications Engineering}, organization = {ICST (Institute for Computer Sciences, Social-Informatics and Telecommunications Engineering}, keywords = {Bioengineering}, doi = {10.4108/eai.14-10-2015.2261613}, url = {http://dl.acm.org/citation.cfm?id=2897477}, author = {F. Lorussi and N. Carbonaro and D. De Rossi and A. Tognetti} } @article {2717, title = {Neuro-fuzzy physiological computing to assess stress levels in virtual reality therapy}, journal = {INTERACTING WITH COMPUTERS}, volume = {27}, year = {2015}, pages = {521{\textendash}533}, keywords = {Bioengineering}, issn = {0953-5438}, doi = {10.1093/iwc/iwv010}, url = {http://dx.medra.org/10.1093/iwc/iwv010}, author = {Tartarisco, G. and N. Carbonaro and A. Tonacci and G. M. Bernava and A. Arnao and G. Crifaci and P. Cipresso and G. Riva and A. Gaggioli and D. De Rossi and A. Tognetti and G. Pioggia} } @conference {2512, title = {P2SF: Physically-based Point Spread Function for digital image processing}, booktitle = {Imaging Systems and Applications}, year = {2015}, pages = {IT3A{\textendash}5}, publisher = {Optical Society of America}, organization = {Optical Society of America}, keywords = {Bioengineering}, author = {M. Pieroni and B. Wandell and P. Catrysse and D. De Rossi} } @article {2715, title = {Wearable goniometer and accelerometer sensory fusion for knee joint angle measurement in daily-life}, journal = {SENSORS}, volume = {15}, year = {2015}, pages = {28435{\textendash}28455}, keywords = {Bioengineering}, issn = {1424-8220}, doi = {10.3390/s151128435}, url = {http://dx.medra.org/10.3390/s151128435}, author = {A. Tognetti and F. Lorussi and N. Carbonaro and D. De Rossi} } @conference {2214, title = {Daily-Life Monitoring of Stroke Survivors Motor Performance: The INTERACTION Sensing System}, year = {2014}, abstract = {

The objective of the INTERACTION Eu project is to develop and validate an unobtrusive and modular system for monitoring daily life activities, physical interactions with the environment and for training upper and lower extremity motor function in stroke subjects. This paper describes the development and preliminary testing of the project sensing platform made of sensing shirt, trousers, gloves and shoes. Modular prototypes were designed and built considering the minimal set of inertial, force and textile sensors that may enable an efficient monitoring of stroke patients. The single sensing elements are described and the results of their preliminary lab-level testing are reported.

}, author = {A. Tognetti and F. Lorussi and N. Carbonaro and D. De Rossi and De Toma, G. and Mancuso, C. and Paradiso, R. and Luinge, H. and Reenalda, J. and Droog, E. and Veltink, P.} } @article {2228, title = {A Decision Support System for Real-Time Stress Detection During Virtual Reality Exposure}, year = {2014}, pages = {114{\textendash}120}, abstract = {

Virtual Reality (VR) is increasingly being used in combination with psycho-physiological measures to improve assessment of distress in mental health research and therapy. However, the analysis and interpretation of multiple physiological measures is time consuming and requires specific skills, which are not available to most clinicians. To address this issue, we designed and developed a Decision Support System (DSS) for automatic classification of stress levels during exposure to VR environments. The DSS integrates different biosensor data (ECG, breathing rate, EEG) and behavioral data (body gestures correlated with stress), following a training process in which self-rated and clinical-rated stress levels are used as ground truth. Detected stress events for each VR session are reported to the therapist as an aggregated value (ranging from 0 to 1) and graphically displayed on a diagram accessible by the therapist through a web-based interface.

}, doi = {10.3233/978-1-61499-375-9-114}, author = {A. Gaggioli and P. Cipresso and Serino, S. and G. Pioggia and Tartarisco, G. and Baldus, G. and Corda, D. and M. Ferro and N. Carbonaro and A. Tognetti and D. De Rossi and Giakoumis, D. and Tzovaras, D. and Riera, A. and G. Riva} } @article {2184, title = {Designing and Evaluating a Social Gaze-Control System for a Humanoid Robot }, journal = {IEEE Transactions on Human-Machine Systems }, volume = {44}, year = {2014}, pages = {157-168}, keywords = {Robotics}, author = {A. Zaraki and D. Mazzei and Giuliani, M. and D. De Rossi} } @article {2189, title = { Development and Testing of a Multimodal Acquisition Platform for Human-Robot Interaction Affective Studies}, journal = {Journal of Human robot Interaction }, volume = {3}, year = {2014}, pages = {1-24}, keywords = {Robotics}, doi = { http://dx.doi.org/10.5898/JHRI.3.2.Lazzeri}, url = {http://humanrobotinteraction.org/journal/index.php/HRI/article/view/142/pdf_3}, author = {Lazzeri, N. and D. Mazzei and D. De Rossi} } @article {2242, title = {Enabling variable-stiffness hand rehabilitation orthoses with dielectric elastomer transducers}, journal = {Medical Engineering and Physics}, volume = {36}, year = {2014}, pages = {205{\textendash}211}, abstract = {

Patients affected by motor disorders of the hand and having residual voluntary movements of fingers or wrist can benefit from self-rehabilitation exercises performed with so-called dynamic hand splints. These systems consist of orthoses equipped with elastic cords or springs, which either provide a sustained stretch or resist voluntary movements of fingers or wrist. These simple systems are limited by the impossibility of modulating the mechanical stiffness. This limitation does not allow for customizations and real-time control of the training exercise, which would improve the rehabilitation efficacy. To overcome this limitation, {\textquoteright}active{\textquoteright} orthoses equipped with devices that allow for electrical control of the mechanical stiffness are needed. Here, we report on a solution that relies on compact and light-weight electroactive elastic transducers that replace the passive elastic components. We developed a variable-stiffness transducer made of dielectric elastomers, as the most performing types of electromechanically active polymers. The transducer was manufactured with a silicone film and tested with a purposely-developed stiffness control strategy that allowed for electrical modulations of the force-elongation response. Results showed that the proposed new technology is a promising and viable solution to develop electrically controllable dynamic hand orthoses for hand rehabilitation. ? 2013 IPEM.

}, doi = {10.1016/j.medengphy.2013.10.015}, author = {F. Carpi and G. Frediani and C. Gerboni and J. Gemignani and D. De Rossi} } @conference {2186, title = {An Experimental Eye-Tracking Study for the Design of a Context-Dependent Social Robot Blinking Model}, booktitle = {Living Machines 2014}, year = {2014}, pages = {356-366}, publisher = {Springer-Verlag}, organization = {Springer-Verlag}, address = {Milan, Italy, July 30 {\textendash} August 1}, abstract = {

uman gaze and blinking behaviours have been recently considered, to empower humanlike robots to convey a realistic behaviour in a social human-robot interaction. This paper reports the findings of our investigation on human eye-blinking behaviour in relation to human gaze behaviour, in a human-human interaction. These findings then can be used to design a humanlike eye-blinking model for a social humanlike robot. In an experimental eye-tracking study, we showed to 11 participants, a 7-minute video of social interactions of two people, and collected their eye-blinking and gaze behaviours with an eye-tracker. Analysing the collected data, we measured information such as participants{\textquoteright} blinking rate, maximum and minimum blinking duration, number of frequent (multiple) blinking, as well as the participants{\textquoteright} gaze directions on environment. The results revealed that participants{\textquoteright} blinking rate in a social interaction are qualitatively correlated to the gaze behaviour, as higher number of gaze shift increased the blinking rate. Based on the findings of this study, we can propose a context-dependent blinking model as an important component of the robot{\textquoteright}s gaze control system that can empower our robot to mimic human blinking behaviour in a multiparty social interaction.

}, keywords = {Robotics}, doi = {10.1007/978-3-319-09435-9_31}, url = {http://link.springer.com/chapter/10.1007/978-3-319-09435-9_31}, author = {A. Zaraki and Dehkordi, M. B. and D. Mazzei and D. De Rossi} } @conference {2233, title = {Exploiting hand kinematic synergies and wearable under-sensing for hand functional grasp recognition}, booktitle = { 4th International Conference on Wireless Mobile Communication and Healthcare - "Transforming healthcare through innovations in mobile and wireless technologies" }, year = {2014}, address = {November 3{\textendash}5, 2014 Athens, Greece}, keywords = {Haptics, Robotics}, doi = { http://dx.doi.org/10.4108/icst.mobihealth.2014.257228}, author = {M. Bianchi and N. Carbonaro and E. Battaglia and F. Lorussi and A. Bicchi and D. De Rossi and A. Tognetti} } @article {2211, title = {Exploiting wearable goniometer technology for motion sensing gloves}, journal = {IEEE JOURNAL OF BIOMEDICAL AND HEALTH INFORMATICS}, year = {2014}, abstract = {

This paper presents an innovative wearable kinesthetic glove realized with knitted piezoresistive fabric (KPF) sensor technology. The glove is conceived to capture hand movement and gesture by using KPF in a double layer configuration working as angular sensors (electro-goniometers). The sensing glove prototype is endowed by three KPF goniometers, used to track flexion and extension movement of metacarpo-phalangeal joint of thumb, index and middle fingers. The glove is devoted to the continuous monitoring of patients during their daily life activities, in particular for stroke survivors during their rehabilitation. The prototype performances have been evaluated in comparison with an optical tracking system considered as a gold standard both for relieving static and dynamic posture and gesture of the hand. The introduced prototype has shown very interesting figures of merit. The angular error, evaluated through the standard Bland Altman analysis, has been estimated in ? 3? which is slightly less accurate than commercial electro-goniometers. Moreover, a new conceptual prototype design, preliminary evaluated within this work, is presented and discussed in order to solve actual limitations in terms of number and type of sensor connections, avoiding mechanical constraints given by metallic inextensible wires and improving user comfort.

}, doi = {10.1109/JBHI.2014.2324293}, author = {N. Carbonaro and Dalle Mura, G. and F. Lorussi and Paradiso, R. and D. De Rossi and A. Tognetti} } @article {2240, title = {For every thing there is a season and a time ? the construction of a humanoid. A tribute to Vincenzo Tagliasco}, journal = {Frontiers in Bioengineering and Biotechnology}, volume = {2}, year = {2014}, abstract = {

"There is a time to be born, and a time to die; a time to break down, and a time to build up; a time to weep, and a time to laugh; a time to keep silence, and a time to speak" (Ecclesiastes 3, 2?7). There was a time when automata were designed like clocks. Androids will have the time of their creators, the state of the art in technology, a wealth of experience to draw from, as well as the capacity to carry out actions as being endowed with meaning. The machine will undergo a long period of nurturing, from which it will learn to shape some sort of identity.

}, keywords = {Bioengineering}, doi = {10.3389/fbioe.2014.00019}, url = {http://journal.frontiersin.org/Journal/10.3389/fbioe.2014.00019/abstract}, author = {D. De Rossi and A. D{\textquoteright}Ursi} } @conference {2185, title = {I-CLIPS Brain: A Hybrid Cognitive System for Social Robots }, booktitle = { Living Machines 2014}, year = {2014}, pages = {213-224}, publisher = {Springer-Verlag}, organization = {Springer-Verlag}, address = { Milan, Italy, July 30 {\textendash} August 1}, abstract = {

Sensing and interpreting the interlocutor{\textquoteright}s social behaviours is a core challenge in the development of social robots. Social robots require both an innovative sensory apparatus able to perceive the {\textquotedblleft}social and emotional world{\textquotedblright} in which they act and a cognitive system able to manage this incoming sensory information and plan an organized and pondered response. In order to allow scientists to design cognitive models for this new generation of social machines, it is necessary to develop control architectures that can be easily used also by researchers without technical skills of programming such as psychologists and neuroscientists. In this work an innovative hybrid deliberative/reactive cognitive architecture for controlling a social humanoid robot is presented. Design and implementation of the overall architecture take inspiration from the human nervous system. In particular, the cognitive system is based on the Damasio{\textquoteright}s thesis. The architecture has been preliminary tested with the FACE robot. A social behaviour has been modeled to make FACE able to properly follow a human subject during a basic social interaction task and perform facial expressions as a reaction to the social context.

}, keywords = {Robotics}, isbn = {978-3-319-09434-2}, doi = {10.1007/978-3-319-09435-9_19}, url = {http://link.springer.com/chapter/10.1007/978-3-319-09435-9_19}, author = {D. Mazzei and Cominelli, L. and Lazzeri, N. and A. Zaraki and D. De Rossi} } @article {2209, title = {Inference of Human Affective States from Psychophysiological Measurements Extracted under Ecologically Valid Conditions}, journal = {FRONTIERS IN NEUROSCIENCE}, volume = {8}, year = {2014}, abstract = {

Compared to standard laboratory protocols, the measurement of psychophysiological signals in real world experiments poses technical and methodological challenges due to external factors that cannot be directly controlled. To address this problem, we propose a hybrid approach based on an immersive and human accessible space called the eXperience Induction Machine (XIM), that incorporates the advantages of a laboratory within a life-like setting. The XIM integrates unobtrusive wearable sensors for the acquisition of psychophysiological signals suitable for ambulatory emotion research. In this paper, we present results from two different studies conducted to validate the XIM as a general-purpose sensing infrastructure for the study of human affective states under ecologically valid conditions. In the first investigation, we recorded and classified signals from subjects exposed to pictorial stimuli corresponding to a range of arousal levels, while they were free to walk and gesticulate. In the second study, we designed an experiment that follows the classical conditioning paradigm, a well-known procedure in the behavioral sciences, with the additional feature that participants were free to move in the physical space, as opposed to similar studies measuring physiological signals in constrained laboratory settings. Our results indicate that, by using our sensing infrastructure, it is indeed possible to infer human event-elicited affective states through measurements of psychophysiological signals under ecological conditions.

}, doi = {10.3389/fnins.2014.00286}, author = {A. Betella and R. Zucca and Cetnarski, A and A. Greco and A Lanata and D. Mazzei and A. Tognetti and X. D. Arsiwalla and P Omedas and D. De Rossi and Verschure, P} } @conference {2213, title = {Interpreting Psychophysiological States Using Unobtrusive Wearable Sensors in Virtual Reality}, booktitle = {Proc. of The Seventh International Conference on Advances in Computer-Human Interactions}, year = {2014}, abstract = {

One of the main challenges in the study of human be- havior is to quantitatively assess the participants? affective states by measuring their psychophysiological signals in ecologically valid conditions. The quality of the acquired data, in fact, is often poor due to artifacts generated by natural interactions such as full body movements and gestures. We created a technology to address this problem. We enhanced the eXperience Induction Machine (XIM), an immersive space we built to conduct experiments on human behavior, with unobtrusive wearable sensors that measure electrocardiogram, breathing rate and electrodermal response. We conducted an empirical validation where participants wearing these sensors were free to move in the XIM space while exposed to a series of visual stimuli taken from the International Affective Picture System (IAPS). Our main result consists in the quan- titative estimation of the arousal range of the affective stimuli through the analysis of participants? psychophysiological states. Taken together, our findings show that the XIM constitutes a novel tool to study human behavior in life-like conditions.

}, author = {A. Betella and Pacheco, D. and R. Zucca and X. D. Arsiwalla and P Omedas and A Lanata and D. Mazzei and A. Tognetti and A. Greco and N. Carbonaro and Wagner, J. and Lingenfelser, F. and Andr{\`e}, E. and D. De Rossi and Verschure, P.} } @article {2212, title = {New generation of wearable goniometers for motion capture systems}, journal = {JOURNAL OF NEUROENGINEERING AND REHABILITATION}, volume = {11}, year = {2014}, abstract = {

Background Monitoring joint angles through wearable systems enables human posture and gesture to be reconstructed as a support for physical rehabilitation both in clinics and at the patient{\textquoteright}s home. A new generation of wearable goniometers based on knitted piezoresistive fabric (KPF) technology is presented. Methods KPF single-and double-layer devices were designed and characterized under stretching and bending to work as strain sensors and goniometers. The theoretical working principle and the derived electromechanical model, previously proved for carbon elastomer sensors, were generalized to KPF. The devices were used to correlate angles and piezoresistive fabric behaviour, to highlight the differences in terms of performance between the single layer and the double layer sensors. A fast calibration procedure is also proposed. Results The proposed device was tested both in static and dynamic conditions in comparison with standard electrogoniometers and inertial measurement units respectively. KPF goniometer capabilities in angle detection were experimentally proved and a discussion of the device measurement errors of is provided. The paper concludes with an analysis of sensor accuracy and hysteresis reduction in particular configurations. Conclusions Double layer KPF goniometers showed a promising performance in terms of angle measurements both in quasi-static and dynamic working mode for velocities typical of human movement. A further approach consisting of a combination of multiple sensors to increase accuracy via sensor fusion technique has been presented.

}, doi = {10.1186/1743-0003-11-56}, author = {A. Tognetti and F. Lorussi and Dalle Mura, G. and N. Carbonaro and Pacelli, M. and Paradiso, R. and D. De Rossi} } @conference {1996, title = {Piezoresistive Goniometer Network for Sensing Gloves}, booktitle = {Proceedings of the XIII Mediterranean Conference on Medical and Biological Engineering and Computing}, year = {2014}, pages = {1547{\textendash}1550}, publisher = {Springer International Publishing}, organization = {Springer International Publishing}, doi = {10.1007/978-3-319-00846-2_382}, url = {http://dx.medra.org/10.1007/978-3-319-00846-2_382}, author = {Dalle Mura, G. and F. Lorussi and A. Tognetti and G. Anania and N. Carbonaro and M. Pacelli and R. Paradiso and D. De Rossi} } @article {2210, title = {Psychometric Assessment of Cardio-Respiratory Activity Using a Mobile Platform}, journal = {INTERNATIONAL JOURNAL OF HANDHELD COMPUTING RESEARCH}, volume = {5}, year = {2014}, pages = {13{\textendash}29}, abstract = {

Stress is an increasingly recognized phenomenon that has negative effects on growing numbers of people. Stress assessment is a complex issue, but different studies have shown that monitoring user psychophysi- ological parameter during daily life can be greatly helpful in stress evaluation. In this context, the European Collaborative Project INTERSTRESS is aimed at designing and developing advanced simulation and sensing technologies for the assessment and treatment of psychological stress, based on mobile biosensors.In this study a wearable biosensor platform able to collect physiological and behavioral parameters is reported. The developed mobile platform, in terms of hardware and processing algorithms, is described. Moreover the use of this wearable biosensor platform in combination with advanced simulation technologies, such as virtual reality, offer interesting opportunities for innovative personal health-care solutions to stress.

}, doi = {10.4018/ijhcr.2014010102}, author = {N. Carbonaro and Cipresso, P and A. Tognetti and G. Anania and D. De Rossi and Pallavicini, F and A. Gaggioli and Riva, G} } @conference {2187, title = {Recognition and Expression of Emotions by a Symbiotic Android Head}, booktitle = {IEEE-RAS International Conference on Humanoid Robots (HUMANOIDS 2014)}, year = {2014}, pages = {134 - 139 }, publisher = {IEEE}, organization = {IEEE}, address = {Madrid, Spain, November 18 - 20}, keywords = {Bioengineering, Robotics}, doi = {10.1109/HUMANOIDS.2014.7041349}, author = {D. Mazzei and A. Zaraki and Lazzeri, N. and D. De Rossi} } @conference {2188, title = {An RGB-D Based Social Behavior Interpretation System for a Humanoid Social Robot}, booktitle = {IEEE-RSI International Conference on Robotics and Mechatronics 2014 }, year = {2014}, pages = {185 - 190}, publisher = {IEEE}, organization = {IEEE}, address = {Tehran, Iran, October 15-17}, keywords = {Bioengineering, Robotics}, doi = {10.1109/ICRoM.2014.6990898}, author = {A. Zaraki and Giuliani, M. and Dehkordi, M. B. and D. Mazzei and D{\textquoteright}Ursi, A. and D. De Rossi} } @article {2241, title = {Wearable Wireless Tactile Display for Virtual Interactions with Soft Bodies}, journal = {Frontiers in Bioengineering and Biotechnology}, volume = {2}, year = {2014}, abstract = {

We describe here a wearable, wireless, compact, and lightweight tactile display, able to mechanically stimulate the fingertip of users, so as to simulate contact with soft bodies in virtual environments. The device was based on dielectric elastomer actuators, as high-performance electromechanically active polymers. The actuator was arranged at the user{\textquoteright}s fingertip, integrated within a plastic case, which also hosted a compact high-voltage circuitry. A custom-made wireless control unit was arranged on the forearm and connected to the display via low-voltage leads. We present the structure of the device and a characterization of it, in terms of electromechanical response and stress relaxation. Furthermore, we present results of a psychophysical test aimed at assessing the ability of the system to generate different levels of force that can be perceived by users.

}, keywords = {Bioengineering}, doi = {10.3389/fbioe.2014.00031}, url = {http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4150388/}, author = {G. Frediani and D. Mazzei and D. De Rossi and F. Carpi} } @conference {2226, title = {XIM-Engine: a software framework to support the development of interactive applications that uses conscious and unconscious reactions in immersive mixed reality}, booktitle = {VIRTUAL REALITY INTERNATIONAL CONFERENCE}, year = {2014}, abstract = {

The development of systems that allow multimodal interpretation of human-machine interaction is crucial to advance our understanding and validation of theoretical models of user behavior. In particular, a system capable of collecting, perceiving and interpreting unconscious behavior can provide rich contextual information for an interactive system. One possible application for such a system is in the exploration of complex data through immersion, where massive amounts of data are generated every day both by humans and computer processes that digitize information at different scales and resolutions thus exceeding our processing capacity. We need tools that accelerate our understanding and generation of hypotheses over the datasets, guide our searches and prevent data overload. We describe XIM- engine, a bio-inspired software framework designed to capture and analyze multi-modal human behavior in an immersive environment. The framework allows performing studies that can advance our understanding on the use of conscious and unconscious reactions in interactive systems.

}, author = {P. Omedas and A. Betella and Zucca, R. and X. D. Arsiwalla and Pacheco, D. and J. Wagner and F. Lingenfelser and D. Mazzei and A Lanata and A. Tognetti and Goldhoorn, A. and Guerra, E. and Alqu{\`\i}zar, R. and Grau, A. and Sanfeliu, A. and D. De Rossi and E. Andr{\'e} and P. F. M. J. Verschure} } @conference {1812, title = {Advanced Interfaces to Stem the Data Deluge in Mixed Reality: Placing Human (un)consciuosness in the Loop}, booktitle = {ACM SIGGRAPH 2013}, year = {2013}, address = {New York, NY, USA}, keywords = {Bioengineering}, url = {10.1145/2503385.2503460}, author = {A. Betella and E. Mart{\`\i}nez and R. Zucca and X. D. Arsiwalla and P Omedas and S. Wierenga and A. Mura and J. Wagner and F. Lingenfelser and E. Andr{\'e} and D. Mazzei and A. Tognetti and A Lanata and D. De Rossi and P. F. M. J. Verschure} } @article {1809, title = {Grand Challenges in Bionics}, journal = {Frontiers in Bioengineering and Biotechnology}, volume = {1}, year = {2013}, keywords = {Bioengineering}, doi = {10.3389/fbioe.2013.00003}, author = {D. De Rossi and M. Pieroni} } @conference {1995, title = {An Innovative Multisensor Controlled Prosthetic Hand}, booktitle = {Proceedings of the XIII Mediterranean Conference on Medical and Biological Engineering and Computing}, year = {2013}, pages = {93{\textendash}96}, publisher = {Springer International Publishing}, organization = {Springer International Publishing}, doi = {10.1007/978-3-319-00846-2_23}, url = {http://dx.medra.org/10.1007/978-3-319-00846-2_23}, author = {N. Carbonaro and G. Anania and Bacchereti, M. and Donati, G. and Ferretti, G. and Pellicci, L. and Parrini, G. and Vitetta, N. and D. De Rossi and A. Tognetti} } @conference {1814, title = {A Mobile Biosensor to detect Cardiorespiratory Activity for Stress Tracking}, booktitle = {IEEE 7th International Conference on Pervasive Computing Technologies for Healthcare (PervasiveHealth)}, year = {2013}, pages = {440 - 445 }, address = {Venice, Italy}, abstract = {

Stress is an increasingly recognized phenomenon that has negative effects on growing numbers of people. Stress assessment is a complex issue, but different studies have shown that monitoring user psychophysiological parameter during daily life can be greatly helpful in stress evaluation. In this study a wearable biosensor platform able to collect physiological and behavioral parameters is reported. The developed wearable platform, in terms of hardware and processing algorithms, is described. Moreover the use of this wearable biosensor platform in combination with advanced simulation technologies, such as virtual reality offer interesting opportunities for innovative personal health-care solutions to stress. A recently founded European project, "INTERSTRESS - Interreality in the management and treatment of stress-related disorders," will take into account these relevant aspects.

}, keywords = {Bioengineering}, issn = {978-1-4799-0296-5 }, author = {N. Carbonaro and A. Tognetti and G. Anania and D. De Rossi and P. Cipresso and A. Gaggioli and G. Riva} } @article {1808, title = {Modeling and Characterization of Extensible Wearable Textile-Based electrogoniometers}, journal = {IEEE Sensors Journal}, volume = {13}, year = {2013}, pages = {217 - 228}, abstract = {

Measuring and monitoring through wearable technology parameters related to human movement, posture, and gesture are gaining momentum because of their wide range of potential applications in daily-life conditions. In previous studies, carbon elastomers (CEs) have been used as strain sensors. Recent developments of CE sensors mathematical modeling demonstrated that the CEs can be used as electrogoniometers. It was proved that for small local curvatures of CE layers, the resistance of a strip constituting a layer depends only on the total curvature of the same layer and not on the particular shape that the sensor keeps in adherence with a surface. Further, it was proved, theoretically and experimentally, that a double-layer configuration provides better accuracy with respect to a single-layer configuration. These results have been obtained under the hypothesis that the device was bent, but not extended. In this paper, we substituted the inextensible insulating layer in the sensors with an elastic one, allowing the system to extend its length. This improvement required further study to make it fit for biomechanical applications following epithelial deformations produced by joint movements and minimizes skin motion artifacts.

}, keywords = {Bioengineering}, issn = {1530-437X}, doi = {10.1109/JSEN.2012.2211099}, author = {F. Lorussi and S. Galatolo and R. Bartalesi and D. De Rossi} } @conference {1813, title = {Novel Spiking Neuron-Astrocyte Networks based on NoNlinearTransistor-Like Models of Tripartite Synapses}, booktitle = {Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC{\textquoteright}13)}, year = {2013}, address = {Osaka, Japan}, abstract = {

In this paper a novel and efficient computational implementation of a Spiking Neuron-Astrocyte Network (SNAN) is reported. Neurons are modeled according to the Izhikevich formulation and the neuron-astrocyte interactions are intended as tripartite synapsis and modeled with the previ- ously proposed nonlinear transistor-like model. Concerning the learning rules, the original spike-timing dependent plasticity is used for the neural part of the SNAN whereas an ad-hoc rule is proposed for the astrocyte part. SNAN performances are compared with a standard spiking neural network (SNN) and evaluated using the polychronization concept, i.e., number of co-existing groups that spontaneously generate patterns of polychronous activity. The astrocyte-neuron ratio is the biologically inspired value of 1.5. The proposed SNAN shows higher number of polychronous groups than SNN, remarkably achieved for the whole duration of simulation (24 hours).

}, keywords = {Bioengineering}, author = {G. Valenza and L. Tedesco and A Lanata and D. De Rossi and E. P. Scilingo} } @conference {2243, title = {Piezoresistive Goniometer Network for Sensing Gloves}, booktitle = {Proceedings of the XIII Mediterranean Conference on Medical and Biological Engineering and Computing}, year = {2013}, pages = {1547{\textendash}1550}, publisher = {Springer International Publishing}, organization = {Springer International Publishing}, abstract = {

This paper presents a kinesthetic glove realized with knitted piezoresistive fabric (KPF) sensor technology. The glove forefinger area is sensorized by two KPF goniometers obtained on the same piezoresistive substrate. The piezoresistive textile is used for the realization of both electrogoniometers and connections, thus avoiding mechanical constraints due to metallic wires. Sensors are characterized in comparison with commercial goniometers. The glove behavior is pointed out in terms of methacarpal-phalangeal and interphalangeal joint movement reconstruction.

}, keywords = {Bioengineering}, doi = {10.1007/978-3-319-00846-2_382}, author = {G. Dalle Mura and F. Lorussi and A. Tognetti and G. Anania and N. Carbonaro and M. Pacelli and R. Paradiso and D. De Rossi} } @inbook {1810, title = {Preliminary Implementation of Context-Aware Attention System for Humanoid Robots}, booktitle = {Biomimetic and Biohybrid Systems (Proc. Second International Conference, Living Machines 2013)}, volume = {8064}, number = {Lecture Notes in Computer Science}, year = {2013}, pages = {457-459}, publisher = {Springer-Verlag}, organization = {Springer-Verlag}, abstract = {

A context-aware attention system is fundamental for regulating the robot behaviour in a social interaction since it enables social robots to actively select the right environmental stimuli at the right time during a multiparty social interaction. This contribution presents a modular context-aware attention system which drives the robot gaze. It is composed by two modules: the scene analyzer module manages incoming data flow and provides a human-like understanding of the information coming from the surrounding environment; the attention module allows the robot to select the most important target in the perceived scene on the base of a computational model. After describing the motivation, we report the proposed system and the preliminary test.

}, keywords = {Bioengineering}, issn = {978-3-642-39801-8}, doi = {10.1007/978-3-642-39802-5_65}, author = {A. Zaraki and D. Mazzei and Lazzeri, N. and M. Pieroni and D. De Rossi} } @conference {1998, title = {A Sensing Architecture for Empathetic Data Systems}, booktitle = {ACM International Conference Proceeding Series}, year = {2013}, month = {7-8 March}, pages = {{\textendash}}, publisher = {ACM Digital Library}, organization = {ACM Digital Library}, doi = {10.1145/2459236.2459253}, url = {http://dx.medra.org/10.1145/2459236.2459253}, author = {J. Wagner and F. Lingenfelser and E. Andr{\'e} and D. Mazzei and A. Tognetti and D. De Rossi and A. Betella and R. Zucca and P Omedas and P. F. M. J. Verschure} } @inbook {1811, title = {Towards a Believable Social Robot}, booktitle = {Biomimetic and Biohybrid Systems (Proc. Second International Conference, Living Machines 2013)}, number = {Lecture Notes in Computer Science}, year = {2013}, pages = {393-395}, publisher = {Springer-Verlag}, organization = {Springer-Verlag}, abstract = {

Two perspectives define a human being in his social sphere: appearance and behaviour. The aesthetic aspect is the first significant element that impacts a communication while the behavioural aspect is a crucial factor in evaluating the ongoing interaction. In particular, we have more expectations when interacting with anthropomorphic robots and we tend to define them believable if they respect human social conventions. Therefore researchers are focused both on increasingly anthropomorphizing the embodiment of the robots and on giving the robots a realistic behaviour.This paper describes our research on making a humanoid robot socially interacting with human beings in a believable way.

}, keywords = {Bioengineering}, issn = {978-3-642-39801-8}, doi = {10.1007/978-3-642-39802-5_45}, author = {Lazzeri, N. and D. Mazzei and A. Zaraki and D. De Rossi} } @conference {1265, title = {HEFES: an Hybrid Engine for Facial Expressions Synthesis to control human-like androids and avatars}, booktitle = {BIOROB2012}, year = {2012}, pages = {195 - 200}, address = {Rome, Italy}, keywords = {Bioengineering}, author = {D. Mazzei and Lazzeri, N. and Hanson, D. and D. De Rossi} } @inbook {2002, title = {Immersive Multimodal Interactive Presence}, booktitle = {Immersive Multimodal Interactive Presence}, year = {2012}, pages = {215{\textendash}228}, publisher = {SPRINGER-VERLAG}, organization = {SPRINGER-VERLAG}, chapter = {FMRI Compatible Sensing Glove for Hand Gesture Monitoring}, address = {LONDON {\textendash} GBR}, isbn = {9781447127536}, doi = {10.1007/978-1-4471-2754-3_12}, url = {http://dx.medra.org/10.1007/978-1-4471-2754-3_12}, author = {N. Vanello and V. Hartwig and E. P. Scilingo and D. Bonino and E. Ricciardi and A. Tognetti and P. Pietrini and D. De Rossi and L. Landini and A. Bicchi} } @conference {2003, title = {INTERACTION, Training and monitoring of daily-life physical interaction with the environment after stroke}, booktitle = {Proceedings of XII International Symposium on 3D Analysis of Human Movement}, year = {2012}, pages = {{\textendash}}, author = {Veltink, PH and van Meulen, FB and van Beijnum, BJF and Hermens, HJ and D. De Rossi and F. Lorussi and A. Tognetti and Buurke, JH and Reenalda, J and Baten, CTM and Simons, CDM and Luft, AR L and Schepers, HM and Luinge, HJ and R. Paradiso and Orselli, R} } @conference {2005, title = {Personal Biomonitoring System: a real-time physiological and behavioural parameter monitoring system for stress correlation}, booktitle = {17th Annual CyberPsychology \& CyberTherapy Conference (CYBER17)}, year = {2012}, month = {September 25-28,}, pages = {{\textendash}}, author = {N. Carbonaro and A. Tognetti and G. Anania and Dalle Mura, G. and D. De Rossi} } @conference {1264, title = {Realistic Humanlike Robots for Treatment of ASD, Social Training, and Research; Shown to Appeal to Youths with ASD, Cause Physiological Arousal, and Increase Human-to-Human Social Engagement}, booktitle = {Realistic Humanlike Robots for Treatment of Autism, PETRA 2012}, year = {2012}, pages = {1-7}, keywords = {Bioengineering}, author = {Hanson, D. and D. Mazzei and Garver, C. and D. De Rossi and Stevenson, M.} } @article {1491, title = {Small-Strain Modeling of Helical Dielectric Elastomer Actuators}, journal = {IEEE/ASME TRANSACTIONS ON MECHATRONICS}, volume = {17}, year = {2012}, pages = {318{\textendash}325}, keywords = {Bioengineering}, issn = {1083-4435}, author = {F. Carpi and D. De Rossi} } @conference {2006, title = {Unobtrusive Physiological and Gesture Wearable Acquisition System: A Preliminary Study on Behavioral and Emotional Correlations}, booktitle = {GLOBAL HEALTH 2012 : The First International Conference on Global Health Challenges}, year = {2012}, month = {21-26 October}, pages = {88{\textendash}92}, author = {N. Carbonaro and A. Greco and G. Anania and G. Dalle Mura and A. Tognetti and E. P. Scilingo and D. De Rossi and A Lanata} } @conference {2004, title = {Wearable systems for e-health: Telemonitoring and telerehabilitation}, booktitle = {Proceedings of the IASTED African Conference on Health Informatics, AfricaHI 2012}, year = {2012}, pages = {335{\textendash}338}, doi = {10.2316/P.2012.763-004}, url = {http://dx.medra.org/10.2316/P.2012.763-004}, author = {D. De Rossi and F. Lorussi and A. Tognetti} } @conference {1272, title = {Development and evaluation of a social robot platform for therapy in autism}, booktitle = {Proc. Annual Int Engineering in Medicine and Biology Society,EMBC Conf. of the IEEE}, year = {2011}, pages = {4515{\textendash}4518}, keywords = {Bioengineering}, doi = {10.1109/IEMBS.2011.6091119}, author = {D. Mazzei and Lazzeri, N. and Billeci, L. and Igliozzi, R. and A Mancini and A. Ahluwalia and Muratori, F. and D. De Rossi} } @conference {2012, title = {Electroactive polymer patches for wearable haptic interfaces}, booktitle = {Annual International Conference of the IEEE Engineering in Medicine and Biology Society EMBC{\textquoteright}11}, year = {2011}, pages = {8369{\textendash}8372}, doi = {10.1109/IEMBS.2011.6092064}, url = {http://dx.medra.org/10.1109/IEMBS.2011.6092064}, author = {D. De Rossi and F. Carpi and N. Carbonaro and A. Tognetti and E. P. Scilingo} } @conference {2014, title = {Enhancing the performance of upper limb gesture reconstruction through sensory fusion}, booktitle = {Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society, EMBS}, year = {2011}, pages = {3496{\textendash}3499}, publisher = {IEEE}, organization = {IEEE}, address = {USA}, doi = {10.1109/IEMBS.2011.6090944}, url = {http://dx.medra.org/10.1109/IEMBS.2011.6090944}, author = {F. Lorussi and A. Tognetti and N. Carbonaro and G. Anania and D. De Rossi} } @article {1466, title = {Motor imagery effectiveness for mirror reversed movements}, journal = {Cognitive, Affective, \& Behavioral Neuroscience}, volume = {11}, year = {2011}, pages = {22{\textendash}31}, keywords = {Bioengineering}, author = {Debarnot, U. and G. Valenza and Champely, S. and E. P. Scilingo and D. De Rossi and Guillot, A.} } @article {1473, title = {A neuron-astrocyte transistor-like model for neuromorphic dressed neurons}, journal = {Neural Networks}, year = {2011}, keywords = {Bioengineering}, author = {G. Valenza and G. Pioggia and Armato, A. and M. Ferro and E. P. Scilingo and D. De Rossi} } @article {2007, title = {SoC CMOS UWB Pulse Radar Sensor for Contactless Respiratory Rate Monitoring}, journal = {IEEE TRANSACTIONS ON BIOMEDICAL CIRCUITS AND SYSTEMS}, volume = {5}, year = {2011}, pages = {503{\textendash}510}, issn = {1932-4545}, doi = {10.1109/TBCAS.2011.2176937}, url = {http://dx.medra.org/10.1109/TBCAS.2011.2176937}, author = {D. Zito and D. Pepe and M. Mincica and F. Zito and A. Tognetti and A Lanata and D. De Rossi} } @conference {2013, title = {Wearable biomonitoring system for stress management: A preliminary study on robust ECG signal processing}, booktitle = {2011 IEEE International Symposium on a World of Wireless, Mobile and Multimedia Networks, WoWMoM 2011}, year = {2011}, month = {20-24 June}, pages = {{\textendash}}, doi = {10.1109/WoWMoM.2011.5986192}, url = {http://dx.medra.org/10.1109/WoWMoM.2011.5986192}, author = {N. Carbonaro and G. Anania and G. Dalle Mura and M. Tesconi and A. Tognetti and G. Zupone and D. De Rossi} } @article {2008, title = {Wearable Systems for Brain body Reading and Mind Healing}, journal = {CYBER THERAPY AND REHABILITATION MAGAZINE}, year = {2011}, pages = {39{\textendash}40}, issn = {1784-9926}, author = {A. Tognetti and E. P. Scilingo and G. Anania and N. Carbonaro and A Lanata and F. Lorussi and D. Mazzei and G. Valenza and D. De Rossi} } @article {1468, title = {074 EARLY EVALUATION OF THE CONNECTIONS BETWEEN AUTISM AND ALTERATIONS OF MOVEMENT}, journal = {Parkinsonism \& Related Disorders}, volume = {16}, year = {2010}, pages = {S22}, keywords = {Bioengineering}, author = {Nardini, E. and G. Valenza and Mancuso, C. and Armato, A. and A Lanata and E. P. Scilingo and D. De Rossi} } @conference {2023, title = {Enabling technology for heart health wireless assistance}, booktitle = {12th IEEE International conference on e-Health networking, application and services}, year = {2010}, month = {1-3 July}, pages = {36{\textendash}42}, doi = {10.1109/HEALTH.2010.5556540}, url = {http://dx.medra.org/10.1109/HEALTH.2010.5556540}, author = {M. Mincica and D. Pepe and A. Tognetti and A Lanata and D. De Rossi and D. Zito} } @conference {1271, title = {The FACE of autism}, booktitle = {Proc. IEEE RO-MAN}, year = {2010}, pages = {791{\textendash}796}, keywords = {Bioengineering}, doi = {10.1109/ROMAN.2010.5598683}, author = {D. Mazzei and Billeci, L. and Armato, A. and Lazzeri, N. and Cisternino, A. and G. Pioggia and Igliozzi, R. and Muratori, F. and A. Ahluwalia and D. De Rossi} } @article {2015, title = {Heart Rate and Accelerometer data fusion for activity assessment of rescuers during emergency interventions}, journal = {IEEE TRANSACTIONS ON INFORMATION TECHNOLOGY IN BIOMEDICINE}, volume = {14}, year = {2010}, pages = {702{\textendash}710}, issn = {1089-7771}, doi = {10.1109/TITB.2010.2047727}, url = {http://dx.medra.org/10.1109/TITB.2010.2047727}, author = {Curone, D. and A. Tognetti and Secco, E. L. and G. Anania and N. Carbonaro and D. De Rossi and G. Magenes} } @conference {2024, title = {Interreality: The use of advanced technologies in the assessment and treatement of psychological stress}, booktitle = {Proceedings of the 2010 10th International Conference on Intelligent Systems Design and Applications ISDA{\textquoteright}10}, year = {2010}, month = {29 Nov- 1 Dec}, pages = {1047{\textendash}1051}, doi = {10.1109/ISDA.2010.5687047}, url = {http://dx.medra.org/10.1109/ISDA.2010.5687047}, author = {G. Pioggia and N. Carbonaro and G. Anania and A. Tognetti and Tartarisco, G. and M. Ferro and D. De Rossi and G. Riva} } @conference {2021, title = {A MR Compatible Sensing Glove for Brain Studies}, booktitle = {Proceedings of the 16th Annual Meeting of the Organization for Human Brain Mapping}, year = {2010}, month = {6-10 Giugno}, pages = {1262 MT{\textendash}PM{\textendash}}, author = {N. Vanello and V. Hartwig and M. Tesconi and E. Ricciardi and G. Zupone and A. Tognetti and D. Bonino and E. P. Scilingo and F. Cutolo and G. Giovannetti and P. Pietrini and D. De Rossi and L. Landini} } @conference {2022, title = {Neural Correlates of Human-Robot Handshaking}, booktitle = {Proc. of the 19th IEEE International Symposium in Robot and Human Interactive Communication}, year = {2010}, note = {

http://www.scopus.com/inward/record.url?eid=2-s2.0-78649822141\&partnerID=40\&md5=e485b7dd908e69afd535dc7792a8e5b3

}, month = {13-15, Settembre}, pages = {555{\textendash}561}, publisher = {IEEE}, organization = {IEEE}, address = {NEW YORK {\textendash} USA}, doi = {10.1109/ROMAN.2010.5598624}, url = {http://dx.medra.org/10.1109/ROMAN.2010.5598624}, author = {N. Vanello and D. Bonino and E. Ricciardi and M. Tesconi and E. P. Scilingo and V. Hartwig and A. Tognetti and G. Zupone and F. Cutolo and G. Giovannetti and P. Pietrini and D. De Rossi and L. Landini} } @inbook {2018, title = {Pervasive Computing: Innovations in Intelligent Multimedia and Applications}, year = {2010}, pages = {97{\textendash}115}, publisher = {Springer London}, organization = {Springer London}, chapter = {Sensorized garment augmented 3d pervasive virtual reality system}, isbn = {9781848825987}, doi = {10.1007/978-1-84882-599-4_5}, url = {http://dx.medra.org/10.1007/978-1-84882-599-4_5}, author = {Gulrez, T and A. Tognetti and D. De Rossi} } @conference {1465, title = {Towards a smart glove: Arousal recognition based on textile electrodermal response}, booktitle = {Engineering in Medicine and Biology Society (EMBC), 2010 Annual International Conference of the IEEE}, year = {2010}, pages = {3598{\textendash}3601}, publisher = {IEEE}, organization = {IEEE}, keywords = {Bioengineering}, author = {G. Valenza and A Lanata and E. P. Scilingo and D. De Rossi} } @conference {2025, title = {Wearable monitoring of lumbar spine curvature by inertial and e-textile sensory fusion}, booktitle = {2010 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, EMBC{\textquoteright}10}, year = {2010}, pages = {6373{\textendash}6376}, publisher = {IEEE}, organization = {IEEE}, address = {USA}, doi = {10.1109/IEMBS.2010.5627294}, url = {http://dx.medra.org/10.1109/IEMBS.2010.5627294}, author = {R. Bartalesi and F. Lorussi and D. De Rossi and M. Tesconi and A. Tognetti} } @article {2016, title = {A WEARABLE SYSTEM FOR MONITORING GESTURE, POSTURE AND PHYSIOLOGICAL CORRELATES OF EMOTION}, journal = {PARKINSONISM \& RELATED DISORDERS}, year = {2010}, pages = {{\textendash}}, issn = {1353-8020}, author = {Debarnot, U. and F. Lorussi and E. P. Scilingo and A. Tognetti and D. De Rossi} } @conference {2029, title = {Event Related Biometrics: Towards an Unobtrusive Sensing Seat System for Continuous Human Authentication}, booktitle = {Proceedings of the ISDA 2009 - 9th International Conference on Intelligent Systems Design and Applications}, year = {2009}, pages = {679{\textendash}682}, doi = {10.1109/ISDA.2009.256}, url = {http://dx.medra.org/10.1109/ISDA.2009.256}, author = {M. Ferro and G. Pioggia and A. Tognetti and Dalle Mura, G. and D. De Rossi} } @conference {1462, title = {An FPGA based arrhythmia recognition system for wearable applications}, booktitle = {Intelligent Systems Design and Applications, 2009. ISDA{\textquoteright}09. Ninth International Conference on}, year = {2009}, pages = {660{\textendash}664}, publisher = {IEEE}, organization = {IEEE}, keywords = {Bioengineering}, author = {Armato, A. and Nardini, E. and A Lanata and G. Valenza and Mancuso, C. and E. P. Scilingo and D. De Rossi} } @conference {2027, title = {ntegrating hands-free interface into 3d virtual reality environments}, booktitle = {ARO Non-Manual Control Devices Symposium}, year = {2009}, pages = {{\textendash}}, author = {A. Tognetti and Gulrez, T and N. Carbonaro and G. Dalle Mura and G. Zupone and D. De Rossi} } @article {2026, title = {A SENSING SEAT FOR HUMAN AUTHENTICATION}, journal = {IEEE TRANSACTIONS ON INFORMATION FORENSICS AND SECURITY}, volume = {4}, year = {2009}, pages = {451{\textendash}459}, issn = {1556-6013}, author = {M. Ferro and G. Pioggia and A. Tognetti and N. Carbonaro and D. De Rossi} } @conference {2031, title = {A sensorized glove for hand rehabilitation}, booktitle = {Proceedings of the Annual Northeast Bioengineering Conference}, year = {2009}, month = {3-5 April}, pages = {139{\textendash}140}, doi = {10.1109/NEBC.2009.4967775}, url = {http://dx.medra.org/10.1109/NEBC.2009.4967775}, author = {F. Cutolo and C. Mancinelli and S. Patel and N. Carbonaro and M. Schmid and A. Tognetti and D. De Rossi and P. Bonato} } @conference {2030, title = {Wearable Kinesthetic Systems and Emerging Technologies in Actuation for Upperlimb Neurorehabilitation}, booktitle = {Proc. of the IEEE EMBC 2009}, year = {2009}, month = {02/09/ - 06/09/}, pages = {6830{\textendash}6833}, doi = {10.1109/IEMBS.2009.5334481}, url = {http://dx.medra.org/10.1109/IEMBS.2009.5334481}, author = {D. De Rossi and F. Carpi and F. Lorussi and E. P. Scilingo and A. Tognetti} } @article {1630, title = {Electroactive Carbon Nanotube Actuators: Soft-Lithographic Fabrication and Electro-chemical Modelling}, journal = {MATERIALS SCIENCE AND ENGINEERING. C, BIOMIMETIC MATERIALS, SENSORS AND SYSTEMS}, year = {2008}, pages = {{\textendash}}, keywords = {Bioengineering}, issn = {0928-4931}, author = {A. Mazzoldi and M. Tesconi and A. Tognetti and W. Rocchia and G. Vozzi and G. Pioggia and A. Ahluwalia and D. De Rossi} } @article {1558, title = {A New Bio-Inspired Robot Based on Senseless Motion: Theoretical study and Preliminary Technological Results}, journal = {MULTIDISCIPLINE MODELING IN MATERIALS AND STRUCTURES}, year = {2008}, keywords = {Bioengineering}, issn = {1573-6105}, author = {COTRONEO, A and G. Vozzi and GEROVASI, L and D. De Rossi} } @article {VHTRTZGCSSGPSBPDRL08, title = {Sensing Glove for Brain Studies: Design and assessment of its Compatibility for fMRI with a Robust Test}, journal = {IEEE - ASME Transactions on Mechatronics}, volume = {13}, number = {3}, year = {2008}, pages = {345-354}, abstract = {

In this paper, we describe a biomimetic-fabric-based sensing glove that can be used tomonitor hand posture and gesture. Our device is made of a distributed sensor network of piezoresistive conductive elastomers integrated into an elastic fabric. This solution does not affect natural movement and hand gestures, and can be worn for a long time with no discomfort. The glove could be fruitfully employed in behavioral and functional studies with functional MRI (fMRI) during specific tactile or motor tasks. To assess MR compatibility of the system, a statistical test on phantoms is introduced. This test can also be used for testing the compatibility of mechatronic devices designed to produce different stimuli inside the MR environment. We propose a statistical test to evaluate changes in SNR and time-domain standard deviations between image sequences acquired under different experimental conditions. fMRI experiments on subjects wearing the glove are reported. The reproducibility of fMRIresults obtained with andwithout the glove was estimated. A good similarity between the activated regions was found in the two conditions.

}, keywords = {Haptics, Robotics}, author = {N. Vanello and V. Hartwig and M. Tesconi and E. Ricciardi and A. Tognetti and G. Zupone and R. Gassert and D. Chapuis and N. Sgambelluri and E. P. Scilingo and G. Giovannetti and V. Positano and M. F. Santarelli and A. Bicchi and P. Pietrini and D. De Rossi and L. Landini} } @conference {1470, title = {An Artificial Neural Network approach for Haptic Discrimination in Minimally Invasive Surgery}, booktitle = {Robot and Human interactive Communication, 2007. RO-MAN 2007. The 16th IEEE International Symposium on}, year = {2007}, pages = {25{\textendash}30}, publisher = {IEEE}, organization = {IEEE}, keywords = {Haptics}, author = {N. Sgambelluri and G. Valenza and M. Ferro and G. Pioggia and E. P. Scilingo and D. De Rossi and A. Bicchi} } @conference {VHTZSTRSBPDRL07, title = {An MRI Compatibility Study of a Fabric Sensing Glove for Sensory-Motor Brain Activity Exploration}, booktitle = {The 10th Annual International Workshop on Presence}, year = {2007}, pages = {79-83}, keywords = {Haptics}, author = {N. Vanello and V. Hartwig and M. Tesconi and G. Zupone and N. Sgambelluri and A. Tognetti and E. Ricciardi and E. P. Scilingo and A. Bicchi and P. Pietrini and D. De Rossi and L. Landini}, editor = {Laura Moreno, Starlab Barcelona, S.L.} } @conference {LSFD-06, title = {Bi-modal Transducer-based Wearable System for Cardiac Monitoring}, booktitle = {Fourth IASTED International Conference on Biomedical Engineering}, year = {2006}, month = {February}, pages = {92-97}, address = {Innsbruck, Austria}, keywords = {Bioengineering}, author = {A Lanata and E. P. Scilingo and R. Francesconi and D. De Rossi} } @inbook {DS06, title = {Skin-like sensor arrays}, booktitle = {Encyclopedia of Sensors}, year = {2006}, pages = {535-556}, publisher = {American Scientific Publishers}, organization = {American Scientific Publishers}, keywords = {Bioengineering, Haptics}, author = {D. De Rossi and E. P. Scilingo} } @inbook {DLMS01, title = {Wearable Mechanosensing and Emerging Technologies in Fabric-based Actuation}, booktitle = {Intelligent Textiles for Personal Protection and Safety}, volume = {3}, year = {2006}, pages = {55-64}, publisher = {IOS Press}, organization = {IOS Press}, edition = { }, keywords = {Bioengineering}, author = {D. De Rossi and F. Carpi and F. Lorussi and E. P. Scilingo and A. Tognetti} } @inbook {DCLPST05, title = {Electroactive fabrics and wearable man-machine interfaces}, booktitle = {Wearable Electronics and Photonics}, year = {2005}, pages = {59-80}, publisher = {Woodhead Publishing Ltd}, organization = {Woodhead Publishing Ltd}, keywords = {Bioengineering}, author = {D. De Rossi and F. Carpi and F. Lorussi and R. Paradiso and E. P. Scilingo and A. Tognetti} } @article {SGPTGD05, title = {Performance evaluation of Sensing Fabrics for Monitoring Physiological and Biomechanical Variables}, journal = {IEEE Transactions on Information Technology in BioMedicine}, volume = {9}, number = {3}, year = {2005}, month = {September}, pages = {345-352}, keywords = {Bioengineering}, author = {E. P. Scilingo and A. Gemignani and R. Paradiso and N. Taccini and B. Ghelarducci and D. De Rossi} } @article {DCS05, title = {Polymers based interfaces as bioninspired {\textquoteright}smart skins{\textquoteright}}, journal = {Advances in Colloids and Interface Science}, volume = {116}, year = {2005}, month = {August}, pages = {165-178}, keywords = {Bioengineering}, author = {D. De Rossi and F. Carpi and E. P. Scilingo} } @article {LSTTD05, title = {Strain sensing fabric for hand posture and gesture monitoring}, journal = {IEEE Transactions on Information Technology in BioMedicine}, volume = {9}, number = {3}, year = {2005}, month = {September}, pages = {372-381}, keywords = {Bioengineering}, author = {F. Lorussi and E. P. Scilingo and M. Tesconi and A. Tognetti and D. De Rossi} } @inbook {DLSCTT04, title = {Artificial kinesthetic systems for telerehabilitation}, booktitle = {Wearable eHealth Systems for Personalised Health Management}, year = {2004}, pages = {209-213}, publisher = {IOS Press}, organization = {IOS Press}, keywords = {Bioengineering}, author = {D. De Rossi and F. Lorussi and E. P. Scilingo and Carpi, F and A. Tognetti and Tesconi, M} } @conference {CPTSLDGGBVG-04, title = {Development of a Wearable System Based on Smart Textiles and GPRS Transmission for Remote Multiparametric Monitoring of Cardiac Patients: Preliminary Results of the WEALTHY Project}, booktitle = {THE 5th International Heart Health Conference}, year = {2004}, month = {June}, address = {Milan, Italy}, keywords = {Bioengineering}, author = {S. Coli and R. Paradiso and N. Taccini and E. P. Scilingo and G. Loriga and D. De Rossi and A. Gemignani and B. Ghelarducci and L. Bourdon and A. Ditmar and T. Vavouras and B. Gros and J. Luprano and M. Jaenecke and C. Coucke and G. Delhomme and D. Cianflone} } @conference {GSLTPD-04, title = {A sensing shirt for monitoring behavioral and autonomic parameters}, booktitle = {55}, year = {2004}, month = {February}, pages = {83}, address = {Innsbruck, Austria}, keywords = {Bioengineering}, author = {A. Gemignani and E. P. Scilingo and G. Loriga and N. Taccini and R. Paradiso and D. De Rossi and B. Ghelarducci} } @conference {DLSCTTO-04, title = {An Upper Limb Kinesthetic-Like System For Tele-Rehabilitation}, booktitle = {Mediterranean Conference on Medical and Biological Engineering}, year = {2004}, month = {August}, address = {Island of Ischia, Italy}, keywords = {Bioengineering}, author = {D. De Rossi and F. Lorussi and E. P. Scilingo and F. Carpi and M. Tesconi and A. Tognetti and P. Orsini} } @article {LRSTD04, title = {Wearable, Redundant Fabric-Based Sensor Arrays for Reconstruction of Body Segment Posture}, journal = {IEEE Sensors Journal}, volume = {4}, number = {6}, year = {2004}, month = {December}, pages = {807-818}, keywords = {Bioengineering}, author = {F. Lorussi and W. Rocchia and E. P. Scilingo and A. Tognetti and D. De Rossi} } @inbook {DLMOS03, title = {Active dressware: wearable kinesthetic systems}, booktitle = {Sensor and sensing in biology and engineering}, year = {2003}, pages = {379-392}, publisher = {Springer Wien}, organization = {Springer Wien}, keywords = {Bioengineering}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and P. Orsini and E. P. Scilingo} } @conference {DLS-03, title = {Artificial kinesthetic systems for telerehabilitation}, booktitle = {International Workshop in New generation of wearable systems for e-Health: towards a revolution of citizen{\textquoteright} health and life style management?}, year = {2003}, month = {December}, pages = {129-133}, address = {Lucca, Italy}, keywords = {Bioengineering}, author = {D. De Rossi and F. Lorussi and E. P. Scilingo} } @article {DCLMPS03, title = {Electroactive Fabrics And Wearable Biomonitoring Devices}, journal = {AUTEX Research Journal}, volume = {3}, number = {4}, year = {2003}, month = {December}, pages = {180-185}, keywords = {Bioengineering}, author = {D. De Rossi and F. Carpi and F. Lorussi and A. Mazzoldi and R. Paradiso and E. P. Scilingo and A. Tognetti} } @conference {SSDRB03, title = {Haptic Displays Based on Magnetorheological Fluids: Design, Realization and Psychophysical Validation}, booktitle = {Proc. 11th Symp. on Haptic Interfaces for Virtual Environment and Teleoperator Systems}, year = {2003}, pages = {10{\textendash}15}, abstract = {

In this paper we explore the possibility of using magnetorheological (MR) fluids in haptic interfaces, exploiting their property of changing the rheological behaviour by tuning an external magnetic field. In particular, we propose two different prototypes of haptic display, for pinch grasp and for whole-hand immersive exploration. We briefly report on the design of these devices, describe few psychophysical experiments to assess their performance, and report on the experimental results. Such investigation is rather encouraging, and provides reliable cues as to how MR fluid based devices can be designed for haptic display applications.

}, keywords = {Haptics}, author = {E. P. Scilingo and N. Sgambelluri and D. De Rossi and A. Bicchi} } @conference {PGSD-03, title = {Knitted Bioclothes for Cardiopulmonary Monitoring}, booktitle = {25th Annual International Conference of the IEEE Engineering in Medicine and Biology Society}, year = {2003}, month = {September}, pages = {3720-3723}, address = {Cancun,Mexico}, keywords = {Bioengineering}, author = {R. Paradiso and A. Gemignani and E. P. Scilingo and D. De Rossi} } @article {SLMD03, title = {Strain-Sensing Fabrics for Wearable Kinaesthetic-Like Systems}, journal = {IEEE Sensors Journal}, volume = {3}, number = {4}, year = {2003}, month = {August}, pages = {460-467}, keywords = {Bioengineering}, author = {E. P. Scilingo and F. Lorussi and A. Mazzoldi and D. De Rossi} } @conference {SSDRB03, title = {Towards a Haptic Black Box: Magnetorheological fluid based display for softness and shape discrimination}, booktitle = {Proc. IEEE Int. Conf. on Robotics and Automation}, year = {2003}, month = {May}, pages = {2412-2417}, address = {Taipei, Taiwan}, abstract = {

In this paper we propose an innovative prototype of a haptic display for whole-hand immersive exploration. We envision a new concept of haptic display, the Haptic Black Box concept, which can be imagined as a box where the operator can poke his/her bare hand, and interact with the virtual object by freely moving the hand without mechanical constraints. In this way sensory receptors on the whole operator{\textquoteright}s hand would be excited, rather than restricting to just one or few fingertips or phalanges. To progress towards such a challenging goal, magnetorheological (MR) fluids represent a very interesting technology. These fluids are composed of micron-sized, magnetizable particles immersed in a synthetic oil. Exposure to an external magnetic field induces in the fluid a change in rheological behaviour turning it into a near-solid in few milliseconds. By removing the magnetic field, the fluid quickly returns to its liquid state. We briefly report on the design of this device, describe psychophysical experiments to assess performance for softness and shape exploration, and report on the experimental results.

}, keywords = {Haptics}, author = {E. P. Scilingo and N. Sgambelluri and D. De Rossi and A. Bicchi} } @conference {LSTTD-03, title = {Wearable Sensing Garment For Posture Detection, Rehabilitation And Tele-Medicine}, booktitle = {4th International IEEE EMBS Special Topic Conference on Information Technology Applications in Biomedicine}, year = {2003}, month = {April}, pages = {287-290}, address = {Birmingham,UK}, keywords = {Bioengineering}, author = {F. Lorussi and E. P. Scilingo and M. Tesconi and A. Tognetti and D. De Rossi} } @conference {TCLMOSTD-03, title = {Wearable Sensory-Motor Orthoses for Tele-Rehabilitation}, booktitle = {25th Annual International Conference of the IEEE Engineering in Medicine and Biology Society}, year = {2003}, month = {September}, pages = {3724-3727}, address = {Cancun,Mexico}, keywords = {Bioengineering}, author = {A. Tognetti and F. Carpi and F. Lorussi and A. Mazzoldi and P. Orsini and E. P. Scilingo and M. Tesconi and D. De Rossi} } @conference {DLMOS-02, title = {Active dressware: Wearable kinestetic system}, booktitle = {International Interactive Textiles for the Warrior Conference}, year = {2002}, month = {July}, address = {Boston, USA}, keywords = {Bioengineering}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and P. Orsini and E. P. Scilingo} } @conference {DCLMST-02, title = {Electroactive Fabrics for Distributed, Conformable and Interactive Systems}, booktitle = {The first IEEE International Conference on Sensors}, year = {2002}, month = {June}, pages = {1608-1613}, address = {Orlando, Florida}, keywords = {Bioengineering}, author = {D. De Rossi and F. Carpi and F. Lorussi and A. Mazzoldi and E. P. Scilingo and A. Tognetti} } @conference {DCLMST-02, title = {Electroactive Fibers and Fabrics for Distributed, Conformable and Interactive Systems}, booktitle = {Proceedings of the First European Workshop on Structural Health Monitoring}, year = {2002}, month = {July}, address = {Cachan, France}, keywords = {Bioengineering}, author = {D. De Rossi and F. Carpi and F. Lorussi and A. Mazzoldi and E. P. Scilingo and A. Tognetti} } @conference {BSSDR02, title = {Haptic Interfaces Based on Magnetorheological Fluids}, booktitle = {Proc.2th Int. Conf. Eurohaptics 2002}, year = {2002}, month = {July}, pages = {6-11}, abstract = {

In this paper we present an innovative application of magnetorheological (MR) fluids to haptic interfaces. These materials consist of a suspension of a micron-sized, magnetizable particles in a synthetic oil. Exposure to an external magnetic field induces in the fluid a change in rheological behaviour turning it into a near-solid in few milliseconds. Just as quickly, the fluid can be returned to its liquid state by the removal of the field. MR fluids are already present on the market, used in devices such as valves, brakes, clutches, and dampers. In this paper we investigate the possibility of using MR fluids to mimic the compliance, damping, creep (in other terms, the rheology) of materials in order to realize a haptic display and we propose two different implementations. Here we only outline the first scheme, whose experimental results have been reported in our previous work, and will describe the second one. In this latter scheme we set up a psychophysical protocol where a group of volunteers were asked to interact with the MR fluid duly excited and qualitative results are discussed.

}, keywords = {Haptics}, author = {A. Bicchi and E. P. Scilingo and N. Sgambelluri and D. De Rossi} } @conference {SLDPGPAGG-02, title = {A Sensing Shirt for Monitoring Body Kinematic and Vital Signs}, booktitle = {Symposium on Telemedicine In Care Delivery, Technology and Application}, year = {2002}, month = {June}, pages = {57-67}, address = {Pisa, Italy}, keywords = {Bioengineering}, author = {E. P. Scilingo and F. Lorussi and D. De Rossi and R. Paradiso and M. Ghignoli and M. Pacelli and G. Anerdi and A. Gemignani and B. Ghelarducci} } @article {MDLSP02, title = {Smart textiles for wearable motion capture systems}, journal = {AUTEX Research Journal}, volume = {2}, number = {4}, year = {2002}, month = {December}, pages = {199-203}, keywords = {Bioengineering}, author = {A. Mazzoldi and D. De Rossi and F. Lorussi and E. P. Scilingo and R. Paradiso} } @conference {PGPALSDO-02, title = {A wearable motion capture system for multimedia applications}, booktitle = {Avantex Symposium - International Forum for Textiles and Technology in the Future}, year = {2002}, month = {May}, address = {Frankfurt, Germany}, keywords = {Bioengineering}, author = {R. Paradiso and M. Ghignoli and M. Pacelli and G. Anerdi and F. Lorussi and E. P. Scilingo and D. De Rossi and P. Orsini} } @conference {DLMOS-01, title = {Active dressware: wearable haptics systems}, booktitle = {Proc. Int. Worksh. on Electroactive Polymers and Biosystems}, year = {2001}, month = {July}, pages = {155-158}, address = {Lucca, Italy}, keywords = {Biomechanics, Smart Textiles}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and P. Orsini and E. P. Scilingo} } @conference {DLMSO-01, title = {Active dressware :wearable proprioceptive system based on electroactive polymers}, booktitle = {5th International Symposium on Wearable Computers}, year = {2001}, month = {October}, pages = {161-162}, address = {Zurich, Switzerland}, keywords = {Biomechanics, Smart Textiles}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and E. P. Scilingo and P. Orsini} } @conference {SBDR-01, title = {Haptic devices for minimally invasive surgery}, booktitle = {Proc. Int. Worksh. on Electroactive Polymers and Biosystems}, year = {2001}, month = {July}, pages = {194-198}, address = {Lucca, Italy}, keywords = {Haptics}, author = {E. P. Scilingo and A. Bicchi and D. De Rossi} } @conference {DLMPS-01, title = {Haptic smart skins: from biomimetics reasoning to wearing technology}, booktitle = {Fifth Workshop on Multifunctional Polymer and Smart Polymer Systems}, year = {2001}, month = {January}, address = {Wollongong, Australia}, keywords = {Biomechanics, Smart Textiles}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and R. Paradiso and E. P. Scilingo} } @conference {ADLMOS-01, title = {Piezoresistive fabrics for monitoring body kinematics and gesture}, booktitle = {First International Symposium on Measurement, Analysis and Modeling of Human Functions}, year = {2001}, month = {September}, pages = {395-399}, address = {Sapporo, Japan}, keywords = {Biomechanics, Smart Textiles}, author = {A. Ahluwalia and D. De Rossi and F. Lorussi and A. Mazzoldi and P. Orsini and E. P. Scilingo} } @conference {PPACGLSDGB-01, title = {Sensing Threads and Fabrics for Monitoring Body Kinematic and Vital Signs}, booktitle = {Fibres and Textiles for the Future}, year = {2001}, month = {August}, pages = {55-63}, address = {Tampere, Finland}, keywords = {Smart Textiles, Vital Signs}, author = {M. Pacelli and R. Paradiso and G. Anerdi and S. Ceccarini and M. Ghignoli and F. Lorussi and E. P. Scilingo and D. De Rossi and A. Gemignani and B. Ghelarducci} } @conference {DLMWS-01, title = {Strain-amplified electroactive polymer actuator for haptic interfaces}, booktitle = {Proceedings of SPIE}, year = {2001}, month = {July}, pages = {43-53}, address = {Newport Beach, USA}, keywords = {Bioengineering, Haptics}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and W. Rocchia and E. P. Scilingo} } @conference {PPDLMSO-01, title = {Wearable technology for multisensory expressive gesture applications}, booktitle = {5th International Symposium on Wearable Computers}, year = {2001}, month = {October}, address = {Zurich, Switzerland}, keywords = {Biomechanics, Smart Textiles}, author = {R. Paradiso and M. Pacelli and D. De Rossi and F. Lorussi and A. Mazzoldi and E. P. Scilingo and P. Orsini} } @inbook {DLMS01, title = {Wearable thermo- and piezoresistive sensors: realization and properties}, booktitle = {Sensors and Microsystems}, year = {2001}, pages = {195-200}, publisher = {World Scientific}, organization = {World Scientific}, keywords = {Piezoresistive sensor, Smart Textiles}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and E. P. Scilingo} } @inbook {BSDR00, title = {Experimental Validation of a Psychophysical Conjecture on a Simplified Model of the Haptic Perceptual Channel}, booktitle = {Robotics Research IX}, year = {2000}, publisher = {Springer-Verlag}, organization = {Springer-Verlag}, keywords = {Haptics, Robotics}, author = {A. Bicchi and E. P. Scilingo and D. De Rossi} } @article {BDS00, title = {Haptic discrimination of softness in teleoperation: the role of the contact area spread rate}, journal = {IEEE Trans. on Robotics and Automation}, volume = {16}, number = {5}, year = {2000}, month = {October}, pages = {496-504}, abstract = {

Many applications in teleoperation and virtual reality call for the implementation of effective means of displaying to the human operator information on the softness and other mechanical properties of objects being touched. The ability of humans to detect softness of different objects by tactual exploration is intimately related to both kinesthetic and cutaneous perception, and haptic displays should be designed so as to address such multimodal perceptual channel. Unfortunately, accurate detection and replication of cutaneous information in all its details appears to be a formidable task for current technology, causing most of today{\textquoteright}s haptic displays to merely address the kinesthetic part of haptic information. In this paper we investigate the possibility of surrogating detailed tactile information for softness discrimination, with information on the rate of spread of the contact area between the finger and the specimen as the contact force increases. Devices for implementing such a perceptual channel are described, and a pratical application to a mini-invasive surgery tool is presented. Psychophysical test results are reported, validating the effectiveness and practicality of the proposed approach.

}, keywords = {Haptic Sensing, Haptics, Tactile Flow}, author = {A. Bicchi and D. De Rossi and E. P. Scilingo} } @conference {SBDRS-00, title = {A magnetorheological fluid as a haptic display to replicate perceived compliance of biological tissues}, booktitle = {Proc. IEEE-EMBS Conference on Microtechnologies in Medicine and Biology}, year = {2000}, month = {October}, pages = {229-233}, address = {Lyon, France}, keywords = {Haptic Displays, Haptics, Tools for Minimally Invasive Surgery}, author = {E. P. Scilingo and A. Bicchi and D. De Rossi and A. Scotto} } @conference {DLMOS-00, title = {Monitoring Body Kinematics and Gesture Through Sensing Fabrics}, booktitle = {1st Annual International IEEE-EMBS Special Topic Conference on Microtechnologies in Medicine AND Biology}, year = {2000}, month = {October}, pages = {587-592}, address = {Lyon, France}, keywords = {Biomechanics, Smart Textiles}, author = {D. De Rossi and F. Lorussi and A. Mazzoldi and P. Orsini and E. P. Scilingo} } @conference {BDRS99, title = {Psychophysical Evaluation of Simplified Haptic Perception Media}, booktitle = {Proc. Int. Workshop on Robot and Human Interaction}, year = {1999}, month = {September}, address = {Pisa}, abstract = {

Detection of softness by tactile exploration in humans is based on both kinesthetic and cutaneous perception, and haptic displays should be designed so as to address such multimodal perceptual channel. Unfortunately, accurate detection and replication of cutaneous information in all its details is difficlt and costly. In this paper we discuss a simplified model of haptic detection of softness (whereby only information on the rate of spread of the contact area between the finger and the specimen as the contact force increases is transmitted). We provide a thorough set of psychophysical tests, to support the feasibility (in at least some contexts) of a reduced-complicacy display of haptic features.

}, keywords = {Bioengineering, Haptics, Robotics}, author = {A. Bicchi and D. De Rossi and E. P. Scilingo} } @conference {ABDRS99, title = {The Role of Contact Area Spread Rate in Haptic Discrimination of Softness}, booktitle = {Proc. IEEE Int. Conf. on Robotics and Automation}, year = {1999}, pages = {305-310}, abstract = {

Many applications in teleoperation and virtual reality call for the implementation of effective means of displaying to the human operator information on the softness and other mechanical properties of objects being touched. The ability of humans to detect softness of different objects by tactual exploration is intimately related to both kinesthetic and cutaneous perception, and haptic displays should be designed so as to address such multimodal perceptual channel. Unfortunately, accurate detection and replication of cutaneous information in all its details appears to be a formidable task for current technology, causing most of today{\textquoteright}s haptic displays to merely address the kinesthetic part of haptic information. In this paper we investigate the possibility of surrogating detailed tactile information for softness discrimination, with information on the rate of spread of the contact area between the finger and the specimen. Devices for implementing this new perceptual channel are described, and some preliminary psychophysical test results are reported, validating the effectiveness and practicality of the proposed approach.

}, keywords = {Bioengineering, Haptics, Robotics}, author = {G. Ambrosi and A. Bicchi and D. De Rossi and E. P. Scilingo} } @conference {SBDRI-98, title = {Haptic display able to replicate the rheological behaviour of surgical tissues}, booktitle = {Proc. 20th International Conference IEEE/EMBS}, year = {1998}, pages = {1738-1741}, address = {Hong Kong}, keywords = {Bioengineering, Haptics, Robotics}, author = {E. P. Scilingo and A. Bicchi and D. De Rossi and P. Iacconi} } @conference {SDRBI97-ASME, title = {Haptic display for replication of rheological behaviour of surgical tissues: modelling, control, and experiments}, booktitle = {Proc. Annual ASME Symp. on Haptic Interfaces for Virtual Environments and Teleoperator Systems}, year = {1997}, address = {Dallas}, keywords = {Bioengineering, Haptics, Robotics}, author = {E. P. Scilingo and D. De Rossi and A. Bicchi and P. Iaccone} } @conference {SDRBI97-EMB, title = {Sensors and devices to enhance the performance of a minimally invasive surgery tool for replicating surgeons{\textquoteright} haptic percetion of manipulated tissues}, booktitle = {Proc. IEEE Int. Conf. Engineering in Medicine and Biology}, year = {1997}, address = {Chicago}, keywords = {Haptics, Sensors}, author = {E. P. Scilingo and D. De Rossi and A. Bicchi and P. Iaccone} } @conference {BCDRIS96, title = { A sensor-based minimally invasive surgery tool for detecting tissue elastic properties }, booktitle = {Proc. IEEE Int. Conf. on Robotics and Automation}, year = {1996}, pages = {884-888}, keywords = {Haptics, Tools for Minimally Invasive Surgery}, author = {A. Bicchi and G. Canepa and D. De Rossi and P. Iacconi and E. P. Scilingo} } @article {1417, title = {TOWARDS THE REALIZATION OF AN ARTIFICIAL TACTILE SYSTEM - FINE-FORM DISCRIMINATION BY A TENSORIAL TACTILE SENSOR ARRAY AND NEURAL INVERSION ALGORITHMS}, journal = {IEEE TRANSACTION ON SYSTEMS MAN AND CYBERNETICS}, volume = {25}, year = {1995}, pages = {933{\textendash}946}, issn = {0018-9472}, doi = {10.1109/21.384256}, url = {http://dx.medra.org/10.1109/21.384256}, author = {A. Caiti and G. Canepa and D. De Rossi and F. Germagnoli and G. Magenes and T. Parisini} } @article {1422, title = {Skin-like tactile sensor arrays for contact stress field extraction}, journal = {MATERIALS SCIENCE AND ENGINEERING. C, BIOMIMETIC MATERIALS, SENSORS AND SYSTEMS}, volume = {1}, year = {1993}, pages = {23{\textendash}36}, issn = {0928-4931}, author = {D. De Rossi and G. Canepa and G. Magenes and F. Germagnoli and A. Caiti and T. Parisini} } @article {1777, title = {Need better sensor: try using polymers}, journal = {RESEARCH \& DEVELOPMENT}, year = {1989}, pages = {66{\textendash}70}, keywords = {Bioengineering}, issn = {0746-9179}, author = {D. De Rossi} } @article {1776, title = {Shear stress detection in an elastic layer by a piezoelectric polymer tactile sensor}, journal = {IEEE TRANSACTIONS ON ELECTRICAL INSULATION}, volume = {24}, year = {1989}, pages = {1077{\textendash}1081}, keywords = {Bioengineering}, issn = {0018-9367}, author = {C. Domenici and D. De Rossi and A. Bacci and S. Bennati} } @article {1775, title = {Tactile sensing by an electromechanochemical skin analog}, journal = {SENSORS AND ACTUATORS}, volume = {17}, year = {1989}, pages = {107{\textendash}114}, keywords = {Bioengineering}, issn = {0250-6874}, author = {D. De Rossi and L. Lazzeri and C. Domenici and A. Nannini and P. Basser} } @article {1774, title = {Artificial sensing skin mimicking mechanoelectrical conversion properties of human dermis}, journal = {IEEE TRANSACTIONS ON BIOMEDICAL ENGINEERING}, volume = {35}, year = {1988}, pages = {83{\textendash}92}, keywords = {Bioengineering}, issn = {0018-9294}, author = {D. De Rossi and A. Nannini and C. Domenici} } @article {1773, title = {Determination of mechanical parameters related to the kinetics of swelling in an electrically activated contractile gel}, journal = {PROGRESS IN COLLOID \& POLYMER SCIENCE}, volume = {78}, year = {1988}, pages = {4{\textendash}8}, keywords = {Bioengineering}, issn = {0340-255X}, author = {Chiarelli, P and D. De Rossi} } @article {1772, title = {Sensori per applicazioni biomediche}, journal = {FISICA E TECNOLOGIA}, volume = {11}, year = {1988}, pages = {{\textendash}}, issn = {0391-9757}, author = {P. Dario and D. De Rossi} } @article {1770, title = {A Biomimetic tactile array with stress-component-selective sensing capabilities}, journal = {MATERIALS SCIENCE}, volume = {13}, year = {1987}, pages = {47{\textendash}50}, keywords = {Bioengineering}, issn = {0137-1339}, author = {D. De Rossi and C. Domenici and A. Nannini and R. Francesconi} } @article {1769, title = {Biomimetic tactile sensor with stress-component-discrimination capability}, journal = {JOURNAL OF MOLECULAR ELECTRONICS}, volume = {3}, year = {1987}, pages = {173{\textendash}181}, keywords = {Bioengineering}, issn = {0748-7991}, author = {D. De Rossi and A. Nannini and C. Domenici} } @article {1768, title = {Measurement of the hydrostatic piezoelectric, coefficient using a {\^A}{\textmu}P based apparatus}, journal = {FERROELECTRICS}, volume = {76}, year = {1987}, pages = {283{\textendash}290}, keywords = {Bioengineering}, issn = {0015-0193}, author = {C. Domenici and A. Nannini and D. De Rossi} } @article {1771, title = {NTIR Optical Immunosensor}, journal = {MEDICINE BIOLOGIE ENVIRONMENT}, volume = {15}, year = {1987}, pages = {49{\textendash}54}, keywords = {Bioengineering}, author = {M. Monici and A. Nannini and D. De Rossi} } @article {1765, title = {Approccio bionico allo sviluppo di trasduttori tattili ed attuatori lineari per robotica avanzata}, journal = {ALTA FREQUENZA}, volume = {55}, year = {1986}, pages = {55{\textendash}62}, keywords = {Bioengineering}, issn = {0002-6557}, author = {D. De Rossi and C. Domenici and Chiarelli, P} } @article {1763, title = {Contractile behaviour of electrically activated mechanochemical polymer actuators}, journal = {ASAIO TRANSACTIONS}, volume = {32}, year = {1986}, pages = {157{\textendash}162}, keywords = {Robotics}, issn = {0889-7190}, author = {D. De Rossi and Chiarelli, P and G. Buzzigoli and C. Domenici and L. Lazzeri} } @article {1764, title = {Design criteria for ferroelectric polymer sensors and their applications to artificial organ technology}, journal = {ASAIO TRANSACTIONS}, volume = {32}, year = {1986}, pages = {697{\textendash}701}, keywords = {Bioengineering}, issn = {0889-7190}, author = {D. De Rossi} } @article {1766, title = {Effetti di osteosintesi endomidollari a polimeri piezoelettrico: ricerca sperimentale}, journal = {ORTOPEDIA E TRAUMATOLOGIA OGGI}, volume = {4}, year = {1986}, pages = {229{\textendash}232}, keywords = {Bioengineering}, issn = {0392-1417}, author = {F. Carlucci and P. Puntoni and ARISPICI, M and M. Cecconi and C. Domenici and P. Dario and D. De Rossi} } @article {1762, title = {Indwelling acoustic sensors for early detection of total artificial heart failure}, journal = {LIFE SUPPORT SYSTEMS}, volume = {4}, year = {1986}, pages = {239{\textendash}248}, keywords = {Bioengineering}, issn = {0261-989X}, author = {Y. L. Sheng and D. De Rossi and P. Dario and P.M. Galletti} } @article {1767, title = {Piezoelectric properties of dry human skin}, journal = {IEEE TRANSACTIONS ON ELECTRICAL INSULATION}, volume = {EI-21}, year = {1986}, pages = {511{\textendash}517}, keywords = {Bioengineering}, issn = {0018-9367}, author = {D. De Rossi and C. Domenici and P. Pastacaldi} } @article {1749, title = {Electrically induced contractile phenomena in charged polymer networks: preliminary study on the feasibility of muscle-like structures}, journal = {TRANSACTIONS - AMERICAN SOCIETY FOR ARTIFICIAL INTERNAL ORGANS}, volume = {31}, year = {1985}, pages = {60{\textendash}65}, keywords = {Bioengineering}, issn = {0066-0078}, author = {D. De Rossi and P. Parrini and Chiarelli, P and G. Buzzigoli} } @article {1750, title = {Tactile sensors and the gripping challenge}, journal = {IEEE SPECTRUM}, volume = {22}, year = {1985}, pages = {46{\textendash}52}, keywords = {Bioengineering}, issn = {0018-9235}, author = {P. Dario and D. De Rossi} } @article {1747, title = {Alcuni fenomeni di traduzione meccanoelettrica in materiali organici di sintesi: propriet{\~A} e analogie con meccanismi di origine biologica}, journal = {L{\textquoteright}ELETTROTECNICA}, volume = {80}, year = {1984}, pages = {619{\textendash}631}, keywords = {Bioengineering}, issn = {0013-6131}, author = {D. De Rossi and P. Dario and C. Domenici and P. Parrini} } @article {1743, title = {Ferroelectric polymer tactile sensors for prostheses}, journal = {FERROELECTRICS}, volume = {60}, year = {1984}, pages = {199{\textendash}214}, keywords = {Bioengineering}, issn = {0015-0193}, author = {P. Dario and D. De Rossi and C. Giannotti and F. Vivaldi and P. C. Pinotti} } @article {1744, title = {Multisensor piezoelectric polymer insole for pedobarography}, journal = {FERROELECTRICS}, volume = {60}, year = {1984}, pages = {163{\textendash}174}, keywords = {Bioengineering}, issn = {0015-0193}, author = {A. Pedotti and R. Assente and G. Fusi and D. De Rossi and P. Dario and C. Domenici} } @article {1741, title = {Piezoelectric properties and dielectric losses in PVDF-PMMA blends}, journal = {FERROELECTRICS}, volume = {60}, year = {1984}, pages = {61{\textendash}70}, keywords = {Bioengineering}, issn = {0015-0193}, author = {C. Domenici and D. De Rossi and A. Nannini and R. Verni} } @article {1742, title = {Prime esperienze sull{\textquoteright}impiego di un polimero piezoelettrico (PVF2) nella riparazione di fratture sperimentali nel ratto}, journal = {ANNALI DELLE FACOLT{\~A}? DI MEDICINA VETERINARIA}, volume = {34}, year = {1984}, pages = {47{\textendash}60}, keywords = {Bioengineering}, issn = {0390-4660}, author = {F. Carlucci and P. Puntoni and ARISPICI, M and M. Cecconi and C. Domenici and P. Dario and D. De Rossi} } @article {1740, title = {Prosthetic vascular graft monitoring by ultrasound using piezoelectric polymers (PZP)}, journal = {TRANSACTIONS - AMERICAN SOCIETY FOR ARTIFICIAL INTERNAL ORGANS}, volume = {30}, year = {1984}, pages = {{\textendash}}, keywords = {Bioengineering}, issn = {0066-0078}, author = {P. Dario and P.D. Richardson and M. Bertoncini and D. De Rossi and L.A. Trudell and P.M. Galletti} } @article {1745, title = {PVF2 Catheter-tip transducers for pressure, sound and flow measurement}, journal = {FERROELECTRICS}, volume = {60}, year = {1984}, pages = {149{\textendash}162}, keywords = {Bioengineering}, issn = {0015-0193}, author = {P. Dario and D. De Rossi and R. Bedini and R. Francesconi and M.G. Tivella} } @article {1748, title = {Pyroelectric sensing station for automatic recognition of position and orientation of objects}, journal = {INTERNATIONAL JOURNAL OF MACHINE TOOL DESIGN \& RESEARCH}, volume = {24}, year = {1984}, pages = {145{\textendash}160}, keywords = {Bioengineering}, issn = {0020-7357}, author = {L.R Wang and P. Dario and D. De Rossi and R. Francesconi and P. C. Pinotti} } @article {1746, title = {Sensori tattili a polimeri ferroelettrici}, journal = {TECNICHE DELL{\textquoteright}AUTOMAZIONE \& ROBOTICA}, volume = {7-8}, year = {1984}, pages = {25{\textendash}29}, keywords = {Bioengineering}, issn = {1721-7563}, author = {P. Dario and D. De Rossi and C. Domenici and P. C. Pinotti} } @article {1738, title = {Biomedical applications of piezoelectric and pyroelectric polymers}, journal = {FERROELECTRICS}, volume = {49}, year = {1983}, pages = {49{\textendash}58}, keywords = {Bioengineering}, issn = {0015-0193}, author = {D. De Rossi and P. Dario} } @article {1739, title = {The electromechanical connection: piezoelectric polymers in artificial organs}, journal = {TRANSACTIONS - AMERICAN SOCIETY FOR ARTIFICIAL INTERNAL ORGANS}, volume = {6}, year = {1983}, pages = {1{\textendash}11}, keywords = {Bioengineering}, issn = {0066-0078}, author = {D. De Rossi and P.M. Galletti and P. Dario and P.D. Richardson} } @article {1737, title = {Method of evaluating the thermal stability of the pyroelectric properties of polyvinylidene fluoride: effects of poling temperature and field}, journal = {JOURNAL OF APPLIED PHYSICS}, volume = {53}, year = {1982}, pages = {6520{\textendash}6525}, keywords = {Bioengineering}, issn = {0021-8979}, author = {D. De Rossi and A. S. De Reggi and M. G. Broadhurst and S. C. Roth and G. T. Davis} } @article {1735, title = {Recent developments in biomedical signal transduction techniques}, journal = {ELETTROMEDICALI}, volume = {2}, year = {1982}, pages = {76{\textendash}91}, keywords = {Bioengineering}, issn = {0393-7070}, author = {P. Dario and D. De Rossi} } @article {1736, title = {Techniques and transducers for non-invasive measurement of physiological parameters}, journal = {ELETTROMEDICALI}, volume = {2}, year = {1982}, pages = {59{\textendash}75}, keywords = {Bioengineering}, issn = {0393-7070}, author = {D. De Rossi} } @article {1733, title = {Touch-sensitive polymer skin uses piezoelectric properties to recognize orientation of objects}, journal = {SENSOR REVIEW}, volume = {4}, year = {1982}, pages = {194{\textendash}198}, keywords = {Bioengineering}, issn = {0260-2288}, author = {P. Dario and R. Bardelli and D. De Rossi and L.R Wang and P. C. Pinotti} } @article {1734, title = {Trasduttori acustici a polimeri piezoelettrici}, journal = {RIVISTA ITALIANA DI ACUSTICA}, volume = {4}, year = {1982}, pages = {121{\textendash}141}, keywords = {Bioengineering}, issn = {0393-1110}, author = {D. De Rossi and R. Bardelli and P. Dario and C. Domenici and F. Pedrini} } @article {1732, title = {Modular hydropneumatic mock circulatory system for the evaluation of cardiovascular prostheses,}, journal = {TRANSACTIONS - AMERICAN SOCIETY FOR ARTIFICIAL INTERNAL ORGANS}, volume = {4}, year = {1981}, pages = {139{\textendash}148}, keywords = {Bioengineering}, issn = {0066-0078}, author = {G. Nardi and S. Cicconardi and P. Dario and D. De Rossi} } @article {1731, title = {A new fibre-optic liquid crystal catheter for oxygen saturation and blood flow measurement in the coronary sinus}, journal = {JOURNAL OF BIOMEDICAL ENGINEERING}, volume = {2}, year = {1980}, pages = {257{\textendash}264}, keywords = {Bioengineering}, issn = {0141-5425}, author = {D. De Rossi and A. Benassi and A. L{\textquoteright}Abbate and P. Dario} } @article {1730, title = {A liquid crystal fiberoptic catheter for blood flow measurement by thermodilution}, journal = {JOURNAL OF NUCLEAR MEDICINE AND ALLIED SCIENCES}, volume = {23}, year = {1979}, pages = {173{\textendash}177}, keywords = {Bioengineering}, issn = {0392-0208}, author = {P. Dario and D. De Rossi and A. Riva and A. Benassi and A. L{\textquoteright}Abbate} } @article {1728, title = {Dispositivo a cristalli liquidi per la realizzazione di maschere ad oscuramento pilotato nella saldatura elettrica}, journal = {RIVISTA ITALIANA DELLA SALDATURA}, volume = {6}, year = {1978}, pages = {359{\textendash}366}, keywords = {Bioengineering}, issn = {0035-6794}, author = {R. Bedini and D. De Rossi} } @article {1729, title = {Electro-optic behaviour of a field-induced twisted structure with quasi homeotropic boundary conditions}, journal = {JOURNAL OF APPLIED PHYSICS}, volume = {49}, year = {1978}, pages = {1139{\textendash}1142}, keywords = {Bioengineering}, issn = {0021-8979}, author = {D. De Rossi and J. Robert} } @article {1727, title = {An introduction to medical thermography}, journal = {JOURNAL OF NUCLEAR MEDICINE AND ALLIED SCIENCES}, volume = {21}, year = {1977}, pages = {5{\textendash}6}, keywords = {Bioengineering}, issn = {0392-0208}, author = {D. De Rossi} }