Just Accepted
Meet the motivational robot that predicts your future feelings
Accepted on 12 November 2024
Abstract
This study explores the potential benefits of robots having the capability to anticipate people’s mental states in an exercise context. We designed 80 utterances for a robot with associated gestures that exhibit a range of emotional characteristics and then performed a 23-person data collection to investigate the effects of these robot behaviors on human mental states during exercise. The results of cluster analysis revealed that 1) utterances with similar meanings had the same effect and 2) the effects of a certain cluster on different people depend on their emotional state. On the basis of these findings, we proposed a robotic system that anticipates the effect of utterances on the individual’s future mental state, thereby choosing utterances that can positively impact the individual. This system incorporates three main features: 1) associating the relevant events detected by sensors with a user’s emotional state; 2) anticipating the effects of robot behavior on the user’s future mental state to choose the next behavior that maximizes the anticipated gain; and 3) determining appropriate times to provide coaching feedback, using predefined rules in the motion module for timing decisions. To evaluate the proposed system’s overall performance comprehensively, we compare robots equipped with the system’s unique features to those lacking these features. We design the baseline condition that lacks these unique features, opting for periodic random selection of utterances for interaction based on the current context. We conducted a 21-person experiment to evaluate the system’s performance. We found that participants perceived the robot to have a good understanding of their mental states and that they enjoyed the exercises more and put in more effort due to the robot’s encouragement.
References
[1]
Augustine Ajibo, Carlos Ishi, and Hiroshi Ishiguro. 2021. Advocating Attitudinal Change through Android Robot’s Intention-Based Expressive Behaviors: Toward WHO COVID-19 Guidelines Adherence. IEEE Robotics and Automation Letters PP (07 2021), 1–1. https://doi.org/10.1109/LRA.2021.3094783
[2]
Omri Avioz-Sarig, Samuel Olatunji, Vardit Sarne-Fleischmann, and Yael Edan. 2021. Robotic system for physical training of older adults. International Journal of Social Robotics 13, 5 (2021), 1109–1124.
[3]
Luca Bascetta, Gianni Ferretti, Paolo Rocco, Håkan Ardö, Herman Bruyninckx, Eric Demeester, and Enrico Di Lello. 2011. Towards safe human-robot interaction in robotic cells: An approach based on visual tracking and intention estimation. In 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems. 2971–2978. https://doi.org/10.1109/IROS.2011.6094642
[4]
Cynthia Breazeal. 2003. Emotion and sociable humanoid robots. International journal of human-computer studies 59, 1-2 (2003), 119–155.
[5]
Paul Adam Bremner, Oya Celiktutan, and Hatice Gunes. 2017. Personality perception of robot avatar teleoperators in solo and dyadic tasks. Frontiers in Robotics and AI 4 (2017), 16.
[6]
Elizabeth Broadbent, Vinayak Kumar, Xingyan Li, John Sollers 3rd, Rebecca Q Stafford, Bruce A MacDonald, and Daniel M Wegner. 2013. Robots with display screens: a robot with a more humanlike face display is perceived to have more mind and a better personality. PloS one 8, 8 (2013), e72589.
[7]
Joost Broekens, Marcel Heerink, Henk Rosendal, et al. 2009. Assistive social robots in elderly care: a review. Gerontechnology 8, 2 (2009), 94–103.
[8]
Emily A Butler, Boris Egloff, Frank H Wlhelm, Nancy C Smith, Elizabeth A Erickson, and James J Gross. 2003. The social consequences of expressive suppression. Emotion 3, 1 (2003), 48.
[9]
Laurianne Charrier, Alisa Rieger, Alexandre Galdeano, Amélie Cordier, Mathieu Lefort, and Salima Hassas. 2019. The RoPE Scale: a Measure of How Empathic a Robot is Perceived. In 2019 14th ACM/IEEE International Conference on Human-Robot Interaction (HRI). 656–657. https://doi.org/10.1109/HRI.2019.8673082
[10]
Marcus Cheetham, Lingdan Wu, Paul Pauli, and Lutz Jancke. 2015. Arousal, valence, and the uncanny valley: psychophysiological and self-report findings. Frontiers in Psychology 6 (2015). https://doi.org/10.3389/fpsyg.2015.00981
[11]
Nikhil Churamani, Pablo Barros, Hatice Gunes, and Stefan Wermter. 2022. Affect-driven learning of robot behaviour for collaborative human-robot interactions. Frontiers in Robotics and AI 9 (2022), 717193.
[12]
J Cohen. 1988. Statistical Power Analysis for the Behavioral Sciences, 2nd Edn. Hillsdale, NJ: Erlbaum. (1988).
[13]
Jacob Cohen. 1992. Quantitative methods in psychology: A power primer. Psychol. Bull. 112 (1992), 1155–1159.
[14]
Shayn Davidson, Joseph Keebler, Tianxin Zhang, Barbara Chaparro, James Szalma, and Christina Frederick. 2022. The development and validation of a universal enjoyment measure: The enjoy scale. Current Psychology (03 2022), 1–13. https://doi.org/10.1007/s12144-022-02967-6
[15]
Malcolm Doering, Phoebe Liu, Dylan F Glas, Takayuki Kanda, Dana Kulić, and Hiroshi Ishiguro. 2019. Curiosity did not kill the robot: A curiosity-based learning system for a shopkeeper robot. ACM Transactions on Human-Robot Interaction (THRI) 8, 3 (2019), 1–24.
[16]
Juan Fasola and Maja Mataric. 2013. Socially Assistive Robot Exercise Coach: Motivating Older Adults to Engage in Physical Exercise. Vol. 88. 463–479. https://doi.org/10.1007/978-3-319-00065-7_32
[17]
Juan Fasola and Maja J Matarić. 2013. A Socially Assistive Robot Exercise Coach for the Elderly. J. Hum.-Robot Interact. 2, 2 (jun 2013), 3–32. https://doi.org/10.5898/JHRI.2.2.Fasola
[18]
Juan Fasola and Maja J Matarić. 2013. A socially assistive robot exercise coach for the elderly. Journal of Human-Robot Interaction 2, 2 (2013), 3–32.
[19]
D. Feil-Seifer and M.J. Mataric. 2005. Defining socially assistive robotics. In 9th International Conference on Rehabilitation Robotics, 2005. ICORR 2005. 465–468. https://doi.org/10.1109/ICORR.2005.1501143
[20]
Changzeng Fu, Qi Deng, Jingcheng Shen, Hamed Mahzoon, and Hiroshi Ishiguro. 2022. A preliminary study on realizing human–robot mental comforting dialogue via sharing experience emotionally. Sensors 22, 3 (2022), 991.
[21]
T. Fukuda, Y. Nakauchi, K. Noguchi, and T. Matsubara. 2005. Time Series Action Support by Mobile Robot in Intelligent Environment. In Proceedings of the 2005 IEEE International Conference on Robotics and Automation. 2897–2902. https://doi.org/10.1109/ROBOT.2005.1570553
[22]
Adam D Galinsky, William W Maddux, Debra Gilin, and Judith B White. 2008. Why it pays to get inside the head of your opponent: The differential effects of perspective taking and empathy in negotiations. Psychological science 19, 4 (2008), 378–384.
[23]
Rachel Gockley and Maja J MatariĆ. 2006. Encouraging physical therapy compliance with a hands-off mobile robot. In Proceedings of the 1st ACM SIGCHI/SIGART conference on Human-robot interaction. 150–155.
[24]
Jennifer Goetz, Sara Kiesler, and Aaron Powers. 2003. Matching robot appearance and behavior to tasks to improve human-robot cooperation. In The 12th IEEE International Workshop on Robot and Human Interactive Communication, 2003. Proceedings. ROMAN 2003. Ieee, 55–60.
[25]
Binnur Görer, Albert Ali Salah, and H Levent Akın. 2013. A robotic fitness coach for the elderly. In Ambient Intelligence: 4th International Joint Conference, AmI 2013, Dublin, Ireland, December 3-5, 2013. Proceedings 4. Springer, 124–139.
[26]
Arzu Guneysu and Bert Arnrich. 2017. Socially assistive child-robot interaction in physical exercise coaching. In 2017 26th IEEE international symposium on robot and human interactive communication (RO-MAN). IEEE, 670–675.
[27]
Xingzhi Guo, Yu-Cian Huang, Edwinn Gamborino, Shih-Huan Tseng, Li-Chen Fu, and Su-Ling Yeh. 2019. Inferring Human Feelings and Desires for Human-Robot Trust Promotion. 365–375. https://doi.org/10.1007/978-3-030-22577-3_26
[28]
Sooyeon Jeong, Laura Aymerich-Franch, Kika Arias, Sharifa Alghowinem, Agata Lapedriza, Rosalind Picard, Hae Won Park, and Cynthia Breazeal. 2023. Deploying a robotic positive psychology coach to improve college students’ psychological well-being. User Modeling and User-Adapted Interaction 33, 2 (2023), 571–615.
[29]
Yanli Ji, Yang Yang, Fumin Shen, Heng Tao Shen, and Xuelong Li. 2020. A Survey of Human Action Analysis in HRI Applications. IEEE Transactions on Circuits and Systems for Video Technology 30, 7 (2020), 2114–2128. https://doi.org/10.1109/TCSVT.2019.2912988
[30]
Rose-Marie Johansson-Pajala and Christine Gustafsson. 2022. Significant challenges when introducing care robots in Swedish elder care. Disability and Rehabilitation: Assistive Technology 17, 2 (2022), 166–176.
[31]
Iolanda Leite, Ginevra Castellano, André Pereira, Carlos Martinho, and Ana Paiva. 2012. Long-Term Interactions with Empathic Robots: Evaluating Perceived Support in Children. In Proceedings of the 4th International Conference on Social Robotics (Chengdu, China) (ICSR’12). Springer-Verlag, Berlin, Heidelberg, 298–307. https://doi.org/10.1007/978-3-642-34103-8_30
[32]
Iolanda Leite, André Pereira, Samuel Mascarenhas, Ginevra Castellano, Carlos Martinho, Rui Prada, and Ana Paiva. 2010. Closing the loop: from affect recognition to empathic interaction. (01 2010). https://doi.org/10.1145/1877826.1877839
[33]
Alexandru Litoiu and Brian Scassellati. 2015. Robotic coaching of complex physical skills. In Proceedings of the Tenth Annual ACM/IEEE International Conference on Human-Robot Interaction Extended Abstracts. 211–212.
[34]
Roderick JA Little and Donald B Rubin. 2019. Statistical analysis with missing data. Vol. 793. John Wiley & Sons.
[35]
Phoebe Liu, Dylan F Glas, Takayuki Kanda, and Hiroshi Ishiguro. 2018. Learning proactive behavior for interactive social robots. Autonomous Robots 42, 5 (2018), 1067–1085.
[36]
Maja J Matarić, Jon Eriksson, David J Feil-Seifer, and Carolee J Winstein. 2007. Socially assistive robotics for post-stroke rehabilitation. Journal of neuroengineering and rehabilitation 4, 1 (2007), 1–9.
[37]
Cristina Mele, T Russo Spena, Marco Tregua, Cesare Laddaga, Angelo Ranieri, Andrea Ruggiero, and Roberta Gargiulo. 2020. Understanding robot acceptance/rejection: The SAR model. In 2020 29th IEEE international conference on robot and human interactive communication (RO-MAN). IEEE, 470–475.
[38]
Kazuki Mizumaru, Satoru Satake, Takayuki Kanda, and Tetsuo Ono. 2019. Stop doing it! Approaching strategy for a robot to admonish pedestrians. In 2019 14th ACM/IEEE International Conference on Human-Robot Interaction (HRI). IEEE, 449–457.
[39]
Daichi Morimoto, Jani Even, and Takayuki Kanda. 2020. Can a robot handle customers with unreasonable complaints?. In Proceedings of the 2020 ACM/IEEE International Conference on Human-Robot Interaction. 579–587.
[40]
Jamie S. North, Ed. Hope, and A. Mark Williams. 2016. The relative importance of different perceptual-cognitive skills during anticipation. Human Movement Science 49 (2016), 170–177. https://doi.org/10.1016/j.humov.2016.06.013
[41]
David Premack and Guy Woodruff. 1978. Does the chimpanzee have a theory of mind? Behavioral and Brain Sciences 1, 4 (1978), 515–526. https://doi.org/10.1017/S0140525X00076512
[42]
Daniel J. Rea, Sebastian Schneider, and Takayuki Kanda. 2021. ”Is This All You Can Do? Harder!”: The Effects of (Im)Polite Robot Encouragement on Exercise Effort. In Proceedings of the 2021 ACM/IEEE International Conference on Human-Robot Interaction (Boulder, CO, USA) (HRI ’21). Association for Computing Machinery, New York, NY, USA, 225–233. https://doi.org/10.1145/3434073.3444660
[43]
Michael D. Robinson and Gerald L. Clore. 2002. Belief and feeling: evidence for an accessibility model of emotional self-report. Psychological bulletin 128 6 (2002), 934–60.
[44]
J.A. Russell. 1980. A circumplex model of affect. Journal of personality and social psychology 39, 6 (1980), 1161–1178.
[45]
Nicole Salomons, Tom Wallenstein, Debasmita Ghose, and Brian Scassellati. 2022. The Impact of an In-Home Co-Located Robotic Coach in Helping People Make Fewer Exercise Mistakes. In 2022 31st IEEE International Conference on Robot and Human Interactive Communication (RO-MAN). IEEE, 149–154.
[46]
Sebastian Schneider and Franz Kummert. 2016. Motivational Effects of Acknowledging Feedback from a Socially Assistive Robot. In ICSR.
[47]
Ruth Maria Stock and Wayne D Hoyer. 2005. An attitude-behavior model of salespeople’s customer orientation. Journal of the academy of marketing science 33, 4 (2005), 536–552.
[48]
Ruth Stock-Homburg. 2021. Survey of Emotions in Human–Robot Interactions: Perspectives from Robotic Psychology on 20 Years of Research. International Journal of Social Robotics 14, 2 (jun 2021), 389–411. https://doi.org/10.1007/s12369-021-00778-6
[49]
Adriana Tapus and Maja J Mataric. 2008. Socially Assistive Robots: The Link between Personality, Empathy, Physiological Signals, and Task Performance. In AAAI spring symposium: emotion, personality, and social behavior. 133–140.
[50]
Adriana Tapus, Cristian Ţăpuş, and Maja J Matarić. 2008. User—robot personality matching and assistive robot behavior adaptation for post-stroke rehabilitation therapy. Intelligent Service Robotics 1 (2008), 169–183.
[51]
Valeria Villani, Beatrice Capelli, Cristian Secchi, Cesare Fantuzzi, and Lorenzo Sabattini. 2020. Humans interacting with multi-robot systems: a natural affect-based approach. Autonomous Robots 44 (2020), 601–616.
[52]
Cynthia S Wang, Tai Kenneth, Gillian Ku, and Adam D Galinsky. 2014. Perspective-taking increases willingness to engage in intergroup contact. PloS one 9, 1 (2014), e85681.
[53]
Zhikun Wang, Abdeslam Boularias, Katharina Mülling, Bernhard Schölkopf, and Jan Peters. 2017. Anticipatory action selection for human–robot table tennis. Artificial Intelligence 247 (2017), 399–414. https://doi.org/10.1016/j.artint.2014.11.007 Special Issue on AI and Robotics.
[54]
Katie Winkle, Séverin Lemaignan, Praminda Caleb-Solly, Paul Bremner, Ailie J Turton, and Ute Leonards. 2020. In-Situ Learning from a Domain Expert for Real World Socially Assistive Robot Deployment. In Robotics: Science and Systems.
[55]
Wanja Wolff, Christian Weich, and Ursula Fischer. 2023. Boredom in Sports and Exercise. (2023).
[56]
Jakub Złotowski, Hidenobu Sumioka, Shuichi Nishio, Dylan F Glas, Christoph Bartneck, and Hiroshi Ishiguro. 2016. Appearance of a robot affects the impact of its behaviour on perceived trustworthiness and empathy. Paladyn, Journal of Behavioral Robotics 7, 1 (2016), 000010151520160005.
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Association for Computing Machinery
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Publication History
Online AM: 06 December 2024
Accepted: 12 November 2024
Revised: 17 October 2024
Received: 14 July 2023
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