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1. DexSkills: Skill Segmentation Using Haptic Data for Learning Autonomous Long-Horizon Robotic Manipulation Tasks

Author

Mao, Xiaofeng, Giudici, Gabriele, Coppola, Claudio, Althoefer, Kaspar, Farkhatdinov, Ildar, Li, Zhibin, and Jamone, Lorenzo

Subjects
Computer Science - Robotics
Abstract

Effective execution of long-horizon tasks with dexterous robotic hands remains a significant challenge in real-world problems. While learning from human demonstrations have shown encouraging results, they require extensive data collection for training. Hence, decomposing long-horizon tasks into reusable primitive skills is a more efficient approach. To achieve so, we developed DexSkills, a novel supervised learning framework that addresses long-horizon dexterous manipulation tasks using primitive skills. DexSkills is trained to recognize and replicate a select set of skills using human demonstration data, which can then segment a demonstrated long-horizon dexterous manipulation task into a sequence of primitive skills to achieve one-shot execution by the robot directly. Significantly, DexSkills operates solely on proprioceptive and tactile data, i.e., haptic data. Our real-world robotic experiments show that DexSkills can accurately segment skills, thereby enabling autonomous robot execution of a diverse range of tasks.

Published
2024

2. Finding safe 3D robot grasps through efficient haptic exploration with unscented Bayesian optimization and collision penalty

Author

Castanheira, Joao, Vicente, Pedro, Martinez-Cantin, Ruben, Jamone, Lorenzo, and Bernardino, Alexandre

Subjects
Computer Science - Robotics
Abstract

Robust grasping is a major, and still unsolved, problem in robotics. Information about the 3D shape of an object can be obtained either from prior knowledge (e.g., accurate models of known objects or approximate models of familiar objects) or real-time sensing (e.g., partial point clouds of unknown objects) and can be used to identify good potential grasps. However, due to modeling and sensing inaccuracies, local exploration is often needed to refine such grasps and successfully apply them in the real world. The recently proposed unscented Bayesian optimization technique can make such exploration safer by selecting grasps that are robust to uncertainty in the input space (e.g., inaccuracies in the grasp execution). Extending our previous work on 2D optimization, in this paper we propose a 3D haptic exploration strategy that combines unscented Bayesian optimization with a novel collision penalty heuristic to find safe grasps in a very efficient way: while by augmenting the search-space to 3D we are able to find better grasps, the collision penalty heuristic allows us to do so without increasing the number of exploration steps., Comment: 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

Published
2024
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3. Robotics for poultry farming: challenges and opportunities

Author

Ozenturk, Ugur, Chen, Zhengqi, Jamone, Lorenzo, and Versace, Elisabetta

Subjects
Computer Science - Robotics
Abstract

Poultry farming plays a pivotal role in addressing human food demand. Robots are emerging as promising tools in poultry farming, with the potential to address sustainability issues while meeting the increasing production needs and demand for animal welfare. This review aims to identify the current advancements, limitations and future directions of development for robotics in poultry farming by examining existing challenges, solutions and innovative research, including robot-animal interactions. We cover the application of robots in different areas, from environmental monitoring to disease control, floor eggs collection and animal welfare. Robots not only demonstrate effective implementation on farms but also hold potential for ethological research on collective and social behaviour, which can in turn drive a better integration in industrial farming, with improved productivity and enhanced animal welfare., Comment: 50 pages

Published
2023

4. World Models and Predictive Coding for Cognitive and Developmental Robotics: Frontiers and Challenges

Author

Taniguchi, Tadahiro, Murata, Shingo, Suzuki, Masahiro, Ognibene, Dimitri, Lanillos, Pablo, Ugur, Emre, Jamone, Lorenzo, Nakamura, Tomoaki, Ciria, Alejandra, Lara, Bruno, and Pezzulo, Giovanni

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Creating autonomous robots that can actively explore the environment, acquire knowledge and learn skills continuously is the ultimate achievement envisioned in cognitive and developmental robotics. Their learning processes should be based on interactions with their physical and social world in the manner of human learning and cognitive development. Based on this context, in this paper, we focus on the two concepts of world models and predictive coding. Recently, world models have attracted renewed attention as a topic of considerable interest in artificial intelligence. Cognitive systems learn world models to better predict future sensory observations and optimize their policies, i.e., controllers. Alternatively, in neuroscience, predictive coding proposes that the brain continuously predicts its inputs and adapts to model its own dynamics and control behavior in its environment. Both ideas may be considered as underpinning the cognitive development of robots and humans capable of continual or lifelong learning. Although many studies have been conducted on predictive coding in cognitive robotics and neurorobotics, the relationship between world model-based approaches in AI and predictive coding in robotics has rarely been discussed. Therefore, in this paper, we clarify the definitions, relationships, and status of current research on these topics, as well as missing pieces of world models and predictive coding in conjunction with crucially related concepts such as the free-energy principle and active inference in the context of cognitive and developmental robotics. Furthermore, we outline the frontiers and challenges involved in world models and predictive coding toward the further integration of AI and robotics, as well as the creation of robots with real cognitive and developmental capabilities in the future., Comment: 28 pages, 3 figures

Published
2023

6. Visuo-Haptic Object Perception for Robots: An Overview

Author

Navarro-Guerrero, Nicolás, Toprak, Sibel, Josifovski, Josip, and Jamone, Lorenzo

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

The object perception capabilities of humans are impressive, and this becomes even more evident when trying to develop solutions with a similar proficiency in autonomous robots. While there have been notable advancements in the technologies for artificial vision and touch, the effective integration of these two sensory modalities in robotic applications still needs to be improved, and several open challenges exist. Taking inspiration from how humans combine visual and haptic perception to perceive object properties and drive the execution of manual tasks, this article summarises the current state of the art of visuo-haptic object perception in robots. Firstly, the biological basis of human multimodal object perception is outlined. Then, the latest advances in sensing technologies and data collection strategies for robots are discussed. Next, an overview of the main computational techniques is presented, highlighting the main challenges of multimodal machine learning and presenting a few representative articles in the areas of robotic object recognition, peripersonal space representation and manipulation. Finally, informed by the latest advancements and open challenges, this article outlines promising new research directions., Comment: published in Autonomous Robots

Published
2022
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8. Feeling Good: Validation of Bilateral Tactile Telemanipulation for a Dexterous Robot

Author

Giudici, Gabriele, Omarali, Bukeikhan, Bonzini, Aramis Augusto, Althoefer, Kaspar, Farkhatdinov, Ildar, Jamone, Lorenzo, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Iida, Fumiya, editor, Maiolino, Perla, editor, Abdulali, Arsen, editor, and Wang, Mingfeng, editor

Published
2023
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11. Robust and fast generation of top and side grasps for unknown objects

Author

Denoun, Brice, Leon, Beatriz, Zito, Claudio, Stolkin, Rustam, Jamone, Lorenzo, and Hansard, Miles

Subjects
Computer Science - Robotics, Computer Science - Computer Vision and Pattern Recognition
Abstract

In this work, we present a geometry-based grasping algorithm that is capable of efficiently generating both top and side grasps for unknown objects, using a single view RGB-D camera, and of selecting the most promising one. We demonstrate the effectiveness of our approach on a picking scenario on a real robot platform. Our approach has shown to be more reliable than another recent geometry-based method considered as baseline [7] in terms of grasp stability, by increasing the successful grasp attempts by a factor of six., Comment: Extended abstract

Published
2019

12. Metrics and Benchmarks for Remote Shared Controllers in Industrial Applications

Author

Zito, Claudio, Adjigble, Maxime, Denoun, Brice D., Jamone, Lorenzo, Hansard, Miles, and Stolkin, Rustam

Subjects
Computer Science - Robotics
Abstract

Remote manipulation is emerging as one of the key robotics tasks needed in extreme environments. Several researchers have investigated how to add AI components into shared controllers to improve their reliability. Nonetheless, the impact of novel research approaches in real-world applications can have a very slow in-take. We propose a set of benchmarks and metrics to evaluate how the AI components of remote shared control algorithms can improve the effectiveness of such frameworks for real industrial applications. We also present an empirical evaluation of a simple intelligent share controller against a manually operated manipulator in a tele-operated grasping scenario.

Published
2019

13. Beyond the Self: Using Grounded Affordances to Interpret and Describe Others' Actions

Author

Saponaro, Giovanni, Jamone, Lorenzo, Bernardino, Alexandre, and Salvi, Giampiero

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

We propose a developmental approach that allows a robot to interpret and describe the actions of human agents by reusing previous experience. The robot first learns the association between words and object affordances by manipulating the objects in its environment. It then uses this information to learn a mapping between its own actions and those performed by a human in a shared environment. It finally fuses the information from these two models to interpret and describe human actions in light of its own experience. In our experiments, we show that the model can be used flexibly to do inference on different aspects of the scene. We can predict the effects of an action on the basis of object properties. We can revise the belief that a certain action occurred, given the observed effects of the human action. In an early action recognition fashion, we can anticipate the effects when the action has only been partially observed. By estimating the probability of words given the evidence and feeding them into a pre-defined grammar, we can generate relevant descriptions of the scene. We believe that this is a step towards providing robots with the fundamental skills to engage in social collaboration with humans., Comment: code available at https://github.com/gsaponaro/tcds-gestures, IEEE Transactions on Cognitive and Developmental Systems

Published
2019
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14. Soft three-axial tactile sensors with integrated electronics for robot skin

Author

Schmitz, Alexander, primary, Somlor, Sophon, additional, Pradhono Tomo, Tito, additional, Jamone, Lorenzo, additional, Hartanto, Richard Sahala, additional, Kristanto, Harris, additional, Wong, Wai Keat, additional, Hwang, Jinsun, additional, Sarazin, Alexandre, additional, Hashimoto, Shuji, additional, and Sugano, Shigeki, additional

Published
2022
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15. Learning at the Ends: From Hand to Tool Affordances in Humanoid Robots

Author

Saponaro, Giovanni, Vicente, Pedro, Dehban, Atabak, Jamone, Lorenzo, Bernardino, Alexandre, and Santos-Victor, José

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Learning, Statistics - Machine Learning
Abstract

One of the open challenges in designing robots that operate successfully in the unpredictable human environment is how to make them able to predict what actions they can perform on objects, and what their effects will be, i.e., the ability to perceive object affordances. Since modeling all the possible world interactions is unfeasible, learning from experience is required, posing the challenge of collecting a large amount of experiences (i.e., training data). Typically, a manipulative robot operates on external objects by using its own hands (or similar end-effectors), but in some cases the use of tools may be desirable, nevertheless, it is reasonable to assume that while a robot can collect many sensorimotor experiences using its own hands, this cannot happen for all possible human-made tools. Therefore, in this paper we investigate the developmental transition from hand to tool affordances: what sensorimotor skills that a robot has acquired with its bare hands can be employed for tool use? By employing a visual and motor imagination mechanism to represent different hand postures compactly, we propose a probabilistic model to learn hand affordances, and we show how this model can generalize to estimate the affordances of previously unseen tools, ultimately supporting planning, decision-making and tool selection tasks in humanoid robots. We present experimental results with the iCub humanoid robot, and we publicly release the collected sensorimotor data in the form of a hand posture affordances dataset., Comment: dataset available at htts://vislab.isr.tecnico.ulisboa.pt/, IEEE International Conference on Development and Learning and on Epigenetic Robotics (ICDL-EpiRob 2017)

Published
2018
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16. Anticipation in Human-Robot Cooperation: A Recurrent Neural Network Approach for Multiple Action Sequences Prediction

Author

Schydlo, Paul, Rakovic, Mirko, Jamone, Lorenzo, and Santos-Victor, José

Subjects
Computer Science - Human-Computer Interaction, Computer Science - Artificial Intelligence, Computer Science - Robotics
Abstract

Close human-robot cooperation is a key enabler for new developments in advanced manufacturing and assistive applications. Close cooperation require robots that can predict human actions and intent, and understand human non-verbal cues. Recent approaches based on neural networks have led to encouraging results in the human action prediction problem both in continuous and discrete spaces. Our approach extends the research in this direction. Our contributions are three-fold. First, we validate the use of gaze and body pose cues as a means of predicting human action through a feature selection method. Next, we address two shortcomings of existing literature: predicting multiple and variable-length action sequences. This is achieved by introducing an encoder-decoder recurrent neural network topology in the discrete action prediction problem. In addition, we theoretically demonstrate the importance of predicting multiple action sequences as a means of estimating the stochastic reward in a human robot cooperation scenario. Finally, we show the ability to effectively train the prediction model on a action prediction dataset, involving human motion data, and explore the influence of the model's parameters on its performance. Source code repository: https://github.com/pschydlo/ActionAnticipation, Comment: IEEE International Conference on Robotics and Automation (ICRA) 2018, Accepted

Published
2018
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17. Symbol Emergence in Cognitive Developmental Systems: a Survey

Author

Taniguchi, Tadahiro, Ugur, Emre, Hoffmann, Matej, Jamone, Lorenzo, Nagai, Takayuki, Rosman, Benjamin, Matsuka, Toshihiko, Iwahashi, Naoto, Oztop, Erhan, Piater, Justus, and Wörgötter, Florentin

Subjects
Computer Science - Artificial Intelligence, Computer Science - Robotics
Abstract

Humans use signs, e.g., sentences in a spoken language, for communication and thought. Hence, symbol systems like language are crucial for our communication with other agents and adaptation to our real-world environment. The symbol systems we use in our human society adaptively and dynamically change over time. In the context of artificial intelligence (AI) and cognitive systems, the symbol grounding problem has been regarded as one of the central problems related to {\it symbols}. However, the symbol grounding problem was originally posed to connect symbolic AI and sensorimotor information and did not consider many interdisciplinary phenomena in human communication and dynamic symbol systems in our society, which semiotics considered. In this paper, we focus on the symbol emergence problem, addressing not only cognitive dynamics but also the dynamics of symbol systems in society, rather than the symbol grounding problem. We first introduce the notion of a symbol in semiotics from the humanities, to leave the very narrow idea of symbols in symbolic AI. Furthermore, over the years, it became more and more clear that symbol emergence has to be regarded as a multifaceted problem. Therefore, secondly, we review the history of the symbol emergence problem in different fields, including both biological and artificial systems, showing their mutual relations. We summarize the discussion and provide an integrative viewpoint and comprehensive overview of symbol emergence in cognitive systems. Additionally, we describe the challenges facing the creation of cognitive systems that can be part of symbol emergence systems., Comment: 23 pages, 6 figures. Submitted to IEEE Transactions on Cognitive and Developmental Systems

Published
2018
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18. Interactive Robot Learning of Gestures, Language and Affordances

Author

Saponaro, Giovanni, Jamone, Lorenzo, Bernardino, Alexandre, and Salvi, Giampiero

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Learning
Abstract

A growing field in robotics and Artificial Intelligence (AI) research is human-robot collaboration, whose target is to enable effective teamwork between humans and robots. However, in many situations human teams are still superior to human-robot teams, primarily because human teams can easily agree on a common goal with language, and the individual members observe each other effectively, leveraging their shared motor repertoire and sensorimotor resources. This paper shows that for cognitive robots it is possible, and indeed fruitful, to combine knowledge acquired from interacting with elements of the environment (affordance exploration) with the probabilistic observation of another agent's actions. We propose a model that unites (i) learning robot affordances and word descriptions with (ii) statistical recognition of human gestures with vision sensors. We discuss theoretical motivations, possible implementations, and we show initial results which highlight that, after having acquired knowledge of its surrounding environment, a humanoid robot can generalize this knowledge to the case when it observes another agent (human partner) performing the same motor actions previously executed during training., Comment: code available at https://github.com/gsaponaro/glu-gestures

Published
2017
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19. Discovering Stable Robot Grasps for Unknown Objects in Presence of Uncertainty Using Bayesian Models

Author

Siddiqui, Muhammad Sami, Coppola, Claudio, Solak, Gokhan, Jamone, Lorenzo, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Fox, Charles, editor, Gao, Junfeng, editor, Ghalamzan Esfahani, Amir, editor, Saaj, Mini, editor, Hanheide, Marc, editor, and Parsons, Simon, editor

Published
2021
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20. Touch It, Rub It, Feel It! Haptic Rendering of Physical Textures with a Low Cost Wearable System

Author

Junput, Burathat, Farkhatdinov, Ildar, Jamone, Lorenzo, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Mohammad, Abdelkhalick, editor, Dong, Xin, editor, and Russo, Matteo, editor

Published
2020
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21. Unscented Bayesian Optimization for Safe Robot Grasping

Author

Nogueira, José, Martinez-Cantin, Ruben, Bernardino, Alexandre, and Jamone, Lorenzo

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Learning, Computer Science - Systems and Control
Abstract

We address the robot grasp optimization problem of unknown objects considering uncertainty in the input space. Grasping unknown objects can be achieved by using a trial and error exploration strategy. Bayesian optimization is a sample efficient optimization algorithm that is especially suitable for this setups as it actively reduces the number of trials for learning about the function to optimize. In fact, this active object exploration is the same strategy that infants do to learn optimal grasps. One problem that arises while learning grasping policies is that some configurations of grasp parameters may be very sensitive to error in the relative pose between the object and robot end-effector. We call these configurations unsafe because small errors during grasp execution may turn good grasps into bad grasps. Therefore, to reduce the risk of grasp failure, grasps should be planned in safe areas. We propose a new algorithm, Unscented Bayesian optimization that is able to perform sample efficient optimization while taking into consideration input noise to find safe optima. The contribution of Unscented Bayesian optimization is twofold as if provides a new decision process that drives exploration to safe regions and a new selection procedure that chooses the optimal in terms of its safety without extra analysis or computational cost. Both contributions are rooted on the strong theory behind the unscented transformation, a popular nonlinear approximation method. We show its advantages with respect to the classical Bayesian optimization both in synthetic problems and in realistic robot grasp simulations. The results highlights that our method achieves optimal and robust grasping policies after few trials while the selected grasps remain in safe regions., Comment: conference paper

Published
2016

23. Feel It on Your Fingers: Dataglove with Vibrotactile Feedback for Virtual Reality and Telerobotics

Author

Junput, Burathat, Wei, Xuyi, Jamone, Lorenzo, Hutchison, David, Editorial Board Member, Kanade, Takeo, Editorial Board Member, Kittler, Josef, Editorial Board Member, Kleinberg, Jon M., Editorial Board Member, Mattern, Friedemann, Editorial Board Member, Mitchell, John C., Editorial Board Member, Naor, Moni, Editorial Board Member, Pandu Rangan, C., Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Terzopoulos, Demetri, Editorial Board Member, Tygar, Doug, Editorial Board Member, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Althoefer, Kaspar, editor, Konstantinova, Jelizaveta, editor, and Zhang, Ketao, editor

Published
2019
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33. Tactile Transfer Learning and Object Recognition With a Multifingered Hand Using Morphology Specific Convolutional Neural Networks

Author

Funabashi, Satoshi, Yan, Gang, Hongyi, Fei, Schmitz, Alexander, Jamone, Lorenzo, Ogata, Tetsuya, and Sugano, Shigeki

Abstract

Multifingered robot hands can be extremely effective in physically exploring and recognizing objects, especially if they are extensively covered with distributed tactile sensors. Convolutional neural networks (CNNs) have been proven successful in processing high dimensional data, such as camera images, and are, therefore, very well suited to analyze distributed tactile information as well. However, a major challenge is to organize tactile inputs coming from different locations on the hand in a coherent structure that could leverage the computational properties of the CNN. Therefore, we introduce a morphology-specific CNN (MS-CNN), in which hierarchical convolutional layers are formed following the physical configuration of the tactile sensors on the robot. We equipped a four-fingered Allegro robot hand with several uSkin tactile sensors; overall, the hand is covered with 240 sensitive elements, each one measuring three-axis contact force. The MS-CNN layers process the tactile data hierarchically: at the level of small local clusters first, then each finger, and then the entire hand. We show experimentally that, after training, the robot hand can successfully recognize objects by a single touch, with a recognition rate of over 95%. Interestingly, the learned MS-CNN representation transfers well to novel tasks: by adding a limited amount of data about new objects, the network can recognize nine types of physical properties.

Published
2024
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34. Statistical Stratification and Benchmarking of Robotic Grasping Performance

Author

Denoun, Brice, Hansard, Miles, Leon, Beatriz, and Jamone, Lorenzo

Abstract

Robotic grasping is fundamental to many real-world applications, and new approaches must be systematically evaluated. However, in most cases, the performance of a specific approach is assessed by simply counting the number of successful attempts in a given task, and this success rate is then compared to those of other solutions, without taking into account the random variability across different experiments (e.g. due to sensor noise or variations in object placement). In order to address this issue, we classify the observed performance into qualitatively ordered outcomes, thereby stratifying the results. We then show how to analyze these results in a statistical framework, which accounts for the variability between experiments. The advantages of our approach are demonstrated in the practical comparison of four grasp planning algorithms. In particular, we show that the proposed approach allows us to carry out several distinct evaluations from a single set of experiments, without having to repeat the data collection process. We demonstrate that differences between the algorithms, which would not be apparent from overall success rates, can be identified and evaluated.

Published
2023
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38. Probabilistic modelling of microtiming perception

Author

Kaplan, Thomas, Pearce, Marcus, and Jamone, Lorenzo

Abstract

Music performances are rich in systematic temporal irregularities called "microtiming", too fine-grained to be notated in a musical score but important for musical expression and communication. Several studies have examined listeners' preference for rhythms varying in microtiming, but few have addressed precisely how microtiming is perceived, especially in terms of cognitive mechanisms, making the empirical evidence difficult to interpret. Here we provide evidence that microtiming perception can be simulated as a process of probabilistic prediction. Participants performed an XAB discrimination test, in which an archetypal popular drum rhythm was presented with different microtiming. The results indicate that listeners could implicitly discriminate the mean and variance of stimulus microtiming. Furthermore, their responses were effectively simulated by a Bayesian model of entrainment, using a distance function derived from its dynamic posterior estimate over phase. Wide individual differences in participant sensitivity to microtiming were predicted by a model parameter likened to noisy timekeeping processes in the brain. Overall, this suggests that the cognitive mechanisms underlying perception of microtiming reflect a continuous inferential process, potentially driving qualitative judgements of rhythmic feel.

Published
2022

46. Learning Deep Features for Robotic Inference From Physical Interactions

Author

Dehban, Atabak, Zhang, Shanghang, Cauli, Nino, Jamone, Lorenzo, and Santos, Jose

Abstract

In order to effectively handle multiple tasks that are not predefined, a robotic agent needs to automatically map its high-dimensional sensory inputs into useful features. As a solution, feature learning has empirically shown substantial improvements in obtaining representations that are generalizable to different tasks, compared to feature engineering approaches, but it requires a large amount of data and computational capacity. These challenges are specifically relevant in robotics due to the low signal-to-noise ratios inherent to robotic data, and to the cost typically associated with collecting this type of input. In this article, we propose a deep probabilistic method based on convolutional variational autoencoders (CVAEs) to learn visual features suitable for interaction and recognition tasks. We run our experiments on a self-supervised robotic sensorimotor data set. Our data were acquired with the iCub humanoid and are based on a standard object collection, thus being readily extensible. We evaluated the learned features in terms of usability for: 1) object recognition; 2) capturing the statistics of the effects; and 3) planning. In addition, where applicable, we compared the performance of the proposed architecture with other state-of-the-art models. These experiments demonstrate that our model is capable of capturing the functional statistics of action and perception (i.e., images) which performs better than existing baselines, without requiring millions of samples or any hand-engineered features.

Published
2023
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48. Cross-cultural study on human-robot greeting interaction: acceptance and discomfort by Egyptians and Japanese

Author

Trovato Gabriele, Zecca Massimiliano, Sessa Salvatore, Jamone Lorenzo, Ham Jaap, Hashimoto Kenji, and Takanishi Atsuo

Subjects
human-robot interaction, humanoid robots, cultural differences, technology social factors, social robotics, Technology
Abstract

As witnessed in several behavioural studies, a complex relationship exists between people’s cultural background and their general acceptance towards robots. However, very few studies have investigated whether a robot’s original language and gesture based on certain culture have an impact on the people of the different cultures. The purpose of this work is to provide experimental evidence which supports the idea that humans may accept more easily a robot that can adapt to their specific culture. Indeed, improving acceptance and reducing discomfort is fundamental for future deployment of robots as assistive, health-care or companion devices into a society. We conducted a Human- Robot Interaction experiment both in Egypt and in Japan. Human subjects were engaged in a simulated video conference with robots that were greeting and speaking either in Arabic or in Japanese. The subjects completed a questionnaire assessing their preferences and their emotional state, while their spontaneous reactions were recorded in different ways. The results suggest that Egyptians prefer the Arabic robot, while they feel a sense of discomfort when interacting with the Japanese robot; the opposite is also true for the Japanese. These findings confirm the importance of the localisation of a robot in order to improve human acceptance during social human-robot interaction.

Published
2013
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