Top

Published in:

2016 | OriginalPaper | Chapter

71. Cognitive Human–Robot Interaction

Authors : Bilge Mutlu, Nicholas Roy, Selma Šabanović

Published in: Springer Handbook of Robotics

Publisher: Springer International Publishing

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

A key research challenge in robotics is to design robotic systems with the cognitive capabilities necessary to support human–robot interaction. These systems will need to have appropriate representations of the world; the task at hand; the capabilities, expectations, and actions of their human counterparts; and how their own actions might affect the world, their task, and their human partners. Cognitive human–robot interaction is a research area that considers human(s), robot(s), and their joint actions as a cognitive system and seeks to create models, algorithms, and design guidelines to enable the design of such systems. Core research activities in this area include the development of representations and actions that allow robots to participate in joint activities with people; a deeper understanding of human expectations and cognitive responses to robot actions; and, models of joint activity for human–robot interaction. This chapter surveys these research activities by drawing on research questions and advances from a wide range of fields including computer science, cognitive science, linguistics, and robotics.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Human–Robot Augmentation

next chapter Social Robotics

Available only for authorised users

71.1

T. Fong, C. Kunz, L.M. Hiatt, M. Bugajska: The human-robot interaction operating system, Proc. 1st ACM SIGCHI/SIGART Conf. HRI, Salt Lake City (2006) pp. 41–48

71.2

J.G. Trafton, A.C. Schultz, N.L. Cassimatis, L.M. Hiatt, D. Perzanowski, D.P. Brock, M.D. Bugajska, W. Adams: Communicating and collaborating with robotic agents. In: Cognition and Multi-Agent Interaction, ed. by R. Sun (Cambridge Univ. Press, New York 2006) pp. 252–278

71.3

C.-M. Huang, B. Mutlu: Robot behavior toolkit: Generating effective social behaviors for robots, Proc. 7th ACM/IEEE Intl. Conf. HRI, Boston (2012) pp. 25–32

71.4

A.H. Vera, H.A. Simon: Situated action: A symbolic interpretation, Cogn. Sci. 17(1), 7–48 (1993)CrossRef

71.5

T. Winograd, F. Flores: Understanding Computers and Cognition: A New Foundation for Design (Ablex Publ., New York 1986)MATH

71.6

L.A. Suchman: Plans and Situated Actions: The Problem of Human-Machine Communication (Cambridge Univ. Press, Cambridge 1987)

71.7

A.N. Leont'ev: The problem of activity in psychology, J. Russ. East Eur. Psychol. 13(2), 4–33 (1974)

71.8

E. Hutchins: The social organization of distributed cognition. In: Perspectives on Socially Shared Cognition, ed. by L.B. Resnick, J.M. Levine, S.D. Teasley (American Psychological Association, Wachington, DC 1991)

71.9

B. Gates: A robot in every home, Sci. Am. 296, 58–65 (2007)CrossRef

71.10

C. Pantofaru, L. Takayama, T. Foote, B. Soto: Exploring the role of robots in home organization, Proc. 7th Annu. ACM/IEEE Intl. Conf. HRI, Boston (2012) pp. 327–334

71.11

K.M. Tsui, M. Desai, H.A. Yanco, C. Uhlik: Exploring use cases for telepresence robots, ACM/IEEE 6th Int. Conf. HRI, Lausanne (2011) pp. 11–18

71.12

F. Tanaka, A. Cicourel, J.R. Movellan: Socialization between toddlers and robots at an early childhood education center, Proc. Natl. Acad. Sci. USA 104(46), 17954–17958 (2007)CrossRef

71.13

T. Kanda, R. Sato, N. Saiwaki, H. Ishiguro: A two-month field trial in an elementary school for long-term human-robot interaction, IEEE Trans. Robotics 23(5), 962–971 (2007)CrossRef

71.14

B. Reeves, C. Nass: The Media Equation: How People Treat Computers, Television and New Media Like Real People and Places (Cambridge University Press, Cambridge 1996)

71.15

S. Turkle, O. Daste, C. Breazeal, B. Scassellati: Encounters with Kismet and Cog: Children respond to relational artifacts, Proc. IEEE-RAS/RSJ Int. Conf. Humanoid Robots, Los Angeles (2004) pp. 1–20

71.16

S. Turkle: Alone Together: Why We Expect More from Technology and Less from Each Other (Basic Books, New York, 2011)

71.17

C. Nass, Y. Moon: Machines and mindlessness: Social responses to computers, J. Soc. Issues 56(1), 81–103 (2000)CrossRef

71.18

S. Turkle: Evocative Objects: Things We Think With (MIT Press, Cambridge 2011)

71.19

K. Wada, T. Shibata, Y. Kawaguchi: Long-term robot therapy in a health service facility for the aged – A case study for 5 years, Proc. 11th IEEE Int. Conf. Rehabil. Robotics, Kyoto (2009) pp. 930–933

71.20

B.R. Duffy: Anthropomorphism and the social robot, Robotics Auton. Syst. 42(3-4), 177–190 (2003)MATHCrossRef

71.21

S. Kiesler, A. Powers, S.R. Fussell, C. Torrey: Anthropomorphic interactions with a software agent and a robot, Soc. Cogn. 26(2), 168–180 (2008)CrossRef

71.22

S.R. Fussell, S. Kiesler, L.D. Setlock, V. Yew: How people anthropomorphize robots, Proc. 3rd ACM/IEEE Int. Conf. HRI, Amsterdam (2008) pp. 145–152

71.23

D.S. Syrdal, K. Dautenhahn, S.N. Woods, M.L. Walters, K.L. Koay: Looking good? Appearance preferences and robot personality inferences at zero acquaintance, AAAI Spring Symp.: Multidiscip. Collab. Socially Assist. Robotics, Stanford (2007) pp. 86–92

71.24

K.F. MacDorman, T. Minato, M. Shimada, S. Itakura, S. Cowley, H. Ishiguro: Assessing human likeness by eye contact in an android testbed, Proc. XXVII Annu. Meet. Conf. Cogn. Sci. Soc., Stresa (2005) pp. 1373–1378

71.25

F. Hegel, S. Krach, T. Kircher, B. Wrede, G. Sagerer: Understanding social robots: A user study on anthropomorphism, Proc. 17th IEEE Int. Symp. Robot Hum. Interact. Commun., Munich (2008) pp. 574–579

71.26

M. Mori: The uncanny valley, Energy 7(4), 33–35 (1970)

71.27

C. Bartneck, T. Kanda, H. Ishiguro, N. Hagita: My robotic Doppelganger – A critical look at the Uncanny Valley Theory, IEEE 18th Intl. Symp. Robot Hum. Interact. Commun., Toyama (2009) pp. 269–276

71.28

M.L. Walters, D.S. Syrdal, K. Dautenhahn, R. te Boekhorst, K.L. Koay: Avoiding the uncanny valley: Robot appearance, personality and consistency of behavior in an attention-seeking home scenario for a robot companion, Auton. Robots 24(2), 159–178 (2008)CrossRef

71.29

A.P. Saygin, T. Chaminade, H. Ishiguro, J. Driver, C. Frith: The thing that should not be: Predictive coding and the uncanny valley in perceiving human and humanoid robot actions, Soc. Cogn. Affect. Neurosci. 7(4), 413–422 (2012)CrossRef

71.30

W. Mitchell, K.A. Szerszen Sr., A.S. Lu, P.W. Schermerhorn, M. Scheutz, K.F. MacDorman: A mismatch in the human realism of face and voice produces an uncanny valley, i-Perception 2, 10–12 (2011)CrossRef

71.31

C. Breazeal: Designing Sociable Robots (MIT Press, Cambridge 2002)MATH

71.32

N. Matsumoto, H. Fujii, M. Okada: Minimal design for human-agent communication, Artif. Life Robotics 10(1), 49–54 (2006)CrossRef

71.33

H. Kozima, H. Yano: A Robot that Learns to Communicate with Human Caregivers, Proc. 1st Int. Workshop Epigenetic Robotics, Lund (2001) pp. 47–52

71.34

A. Powers, A.D.I. Kramer, S. Lim, J. Kuo, S-l. Lee, S. Kiesler: Eliciting information from people with a gendered humanoid robot, IEEE 14th Int. Workshop Robot Hum. Interact. Commun., Nashville (2005) pp. 158–163

71.35

K.M. Lee, N. Park, H. Song: Can a robot be perceived as a developing creature?: Effects of a robot's long-term cognitive developments on its social presence and people's social responses toward it, Human Commun. Res. 31(4), 538–563 (2005)

71.36

J. Goetz, S. Kiesler, A. Powers: Matching robot appearance and behavior to tasks to improve human–robot cooperation, Proc. 12th IEEE Int. Workshop Robot Hum. Interact. Commun., Silicon Valley (2003) pp. 55–60

71.37

M.K. Lee, S. Kiesler, J. Forlizzi, S. Srinivasa, P. Rybski: Gracefully mitigating breakdowns in robotic services, Proc. 6th ACM/IEEE Int. Conf. HRI, Lausanne (2010) pp. 203–210

71.38

B. Shore: Culture in Mind: Cognition, Culture, and the Problem of Meaning (Oxford Univ. Press, Oxford 1996)

71.39

V. Evers, H. Maldonado, T. Brodecki, P. Hinds: Relational vs. group self-construal: Untangling the role of national culture in HRI, Proc. 3rd ACM/IEEE Int. Conf. HRI, Amsterdam (2008)

71.40

L. Wang, P.-L.P. Rau, V. Evers, B.K. Robinson, P. Hinds: When in Rome: The role of culture and context in adherence to robot recommendations, Proc. 5th ACM/IEEE Int. Conf. HRI, Osaka (2010) pp. 359–366

71.41

S. Sabanovic: Robots in society, society in robots – Mutual shaping of society and technology as a framework for social robot design, Int. J. Soc. Robotics 2(4), 439–450 (2010)CrossRef

71.42

G. Shaw-Garlock: Looking forward to sociable robots, Int. J. Soc. Robotics 1(3), 249–260 (2009)CrossRef

71.43

P.H. Kahn, A.L. Reichert, H.E. Gary, T. Kanda, H. Ishiguro, S. Shen, J.H. Ruckert, B. Gill: The new ontological category hypothesis in human–robot interaction, Proc. 6th ACM/IEEE Int. Conf. HRI, Lausanne (2011) pp. 159–160

71.44

P.H. Kahn, N.G. Freier, B. Friedman, R.L. Severson, E.N. Feldman: Social and moral relationships with robotic others?, IEEE 13th Int. Workshop Robot Hum. Interact. Commun., Kurashiki (2004) pp. 545–550

71.45

S. Turkle: A Nascent Robotics Culture: New Complicities for Companionship (AAAI, Boston 2006)

71.46

B. Scassellati: How developmental psychology and robotics complement each other, NSF/DARPA Workshop Dev. Learn. (MIT Press, CSAIL, Cambridge 2006)

71.47

H. Ishiguro: Android science – toward a new cross-interdisciplinary framework, ICCS/CogSci Workshop Toward Soc. Mech. Android Sci., Stresa (2005) pp. 1–6

71.48

K.F. MacDorman, H. Ishiguro: The uncanny advantage of using androids in cognitive and social science research, Interact. Stud. 7(3), 297–337 (2006)CrossRef

71.49

M. Stanley, J. Sabini: On maintaining social norms: A field experiment in the subway. In: Advances in Environmental Psychology: The Urban Environment, ed. by A. Baum, J.E. Singer, S. Valins (Erlbaum Associates, Hillsdale 1978) pp. 31–40

71.50

H. Kozima, M.P. Michalowski, C. Nakagawa: Keepon: A playful robot for research, therapy, and entertainment, Int. J. Soc. Robotics 1(1), 3–18 (2009)CrossRef

71.51

K.F. MacDorman: Introduction to the special issue on android science, Connect. Sci. 18(4), 313–317 (2006)CrossRef

71.52

J.J. Gibson: The Ecological Approach to Visual Perception (Houghton Mifflin, Boston 1979)

71.53

E.S. Reed: Encountering the World: Toward an Ecological Psychology (Oxford Univ. Press, Oxford 1996)

71.54

Y. Yamaji, T. Miyake, Y. Yoshiike, P.R.S. De Silva, M. Okada: STB: Human-dependent sociable trash box, Proc. 5th ACM/IEEE Int. Conf. HRI, Osaka (2010) pp. 197–198

71.55

H. Ishiguro: Android science: Conscious and subconscious recognition, Connect. Sci. 18(4), 319–332 (2006)CrossRef

71.56

S. Nishio, H. Ishiguro, N. Hagita: Geminoid: Teleoperated android of an existing person. In: Humanoid Robots, New Developments, ed. by A.C. De Pina Filho (InTech, Vienna 2007) pp. 343–352

71.57

S. Nishio, H. Ishiguro, N. Hagita: Can a teleoperated robot represent personal presence? – A case study with children, Psychologia 50(4), 330–342 (2007)CrossRef

71.58

M. Shimada, K. Yamauchi, T. Minato, H. Ishiguro, S. Itakura: Studying the influence of the chameleon effect on humans using an android, IEEE/RSJ Int. Conf. Intell. Robots Syst. (IROS), Nice (2008)

71.59

J. Wainer, D.J. Feil-Seifer, D.A. Shell, M.J. Mataric: Embodiment and human-robot interaction: A taskbased perspective, Proc. 2nd ACM/IEEE Int. Conf. HRI, Washington (2007) pp. 872–877

71.60

P. Schermerhorn, M. Scheutz: Disentangling the effects of robot affect, embodiment, and autonomy on human team members in a mixed-initiative task, Proc. 4th Int. Conf. Adv. Comput.–Hum. Interact., Gosier (2011) pp. 235–241

71.61

W.A. Bainbridge, J.W. Hart, E.S. Kim, B. Scassellati: The benefits of interactions with physically present robots over video-displayed agents, Int. J. Soc. Robotics 1(2), 41–52 (2010)

71.62

B. Mutlu: Designing embodied cues for dialog with robots, AI Magazine 32(4), 17–30 (2011)CrossRef

71.63

E.T. Hall: The Hidden Dimension (Anchor Books, New York 1966)

71.64

L. Takayama, C. Pantofaru: Influences on proxemic behaviors in human–robot interaction, IEEE/RSJ Int. Conf. Intell. Robots Syst. (IROS), St. Louis (2009) pp. 5495–5502

71.65

D.S. Syrdal, K.L. Koay, M.L. Walters, K. Dautenhahn: A personalized robot companion? The role of individual differences on spatial preferences in HRI scenarios, Proc. 16th IEEE Int. Symp. Robot Hum. Interact. Commun., Jeju Island (2007) pp. 1143–1148

71.66

J. Mumm, B. Mutlu: Human-robot proxemics: Physical and psychological distancing in human-robot interaction, Proc. 6th ACM/IEEE Int. Conf. HRI, Lausanne (2011) pp. 331–338

71.67

M.L. Walters, M.A. Oskoei, D.S. Syrdal, K. Dautenhahn: A long-term human–robot proxemic study, Proc. 20th IEEE Int. Symp. Robot Hum. Interact. Commun., Atlanta (2011) pp. 137–142

71.68

C. Yu, M. Scheutz, P. Schermerhorn: Investigating multimodal real-time patterns of joint attention in an HRI word learning task, Proc. 5th ACM/IEEE Int. Conf. HRI, Osaka (2010) pp. 309–316

71.69

T. Yonezawa, H. Yamazoe, A. Utsumi, S. Abe: Gaze-communicative behavior of stuffed-toy robot with joint attention and eye contact based on ambient gaze-tracking, Proc. 9th Int. Conf. Multimodal Interfaces, Nagoya (2007) pp. 140–145CrossRef

71.70

Y. Yoshikawa, K. Shinozawa, H. Ishiguro, N. Hagita, T. Miyamoto: Responsive robot gaze to interaction partner, Robotics Sci. Syst., Philadelphia (2006)

71.71

B. Mutlu, T. Shiwa, T. Kanda, H. Ishiguro, N. Hagita: Footing in human-robot conversations: How robots might shape participant roles using gaze cues, Proc. 4th ACM/IEEE Int. Conf. HRI, San Diego, California (2009) pp. 61–68

71.72

M. Staudte, M.W. Crocker: Visual attention in spoken human-robot interaction, Proc. 4th ACM/IEEE Int. Conf. HRI, San Diego (2009) pp. 77–84

71.73

B. Mutlu, J. Forlizzi, J.K. Hodgins: A storytelling robot: Modeling and evaluation of human-like gaze behavior, IEEE-RAS Conf. Humanoid Robots, Genoa (2006) pp. 518–523

71.74

C. Yu, P. Schermerhorn, M. Scheutz: Adaptive eye gaze patterns in interactions with human and artificial agents, ACM Trans. Interact. Intell. Syst. 1(2), 1–25 (2012)CrossRef

71.75

H. Admoni, C. Bank, J. Tan, M. Toneva, B. Scassellati: Robot gaze does not reflexively cue human attention, Proc. 33rd Annu. Conf. Cogn. Sci. Soc., Boston (2011) pp. 1983–1988

71.76

W.S. Condon: Cultural microrhythms. In: Interaction Rhythms: Periodicity in Communicative Behavior, ed. by M. Davis (Human Sciences Press, New York 1982) pp. 53–76

71.77

E. Goffman: Some context for content analysis: A view of the origins of structural studies of face-to-face interaction. In: Conducting Interaction: Patterns of Behavior in Focused Encounters, ed. by A. Kendon (Cambridge Univ. Press, Cambridge 1990) pp. 15–49

71.78

C. Trevarthen: Can a robot hear music? Can a robot dance? Can a robot tell what it knows or intends to do? Can it feel pride or shame in company? – Questions of the nature of human vitality, Proc. 2nd Int. Workshop Epigenet. Robotics, Edinburgh (2002)

71.79

M. Michalowski, S. Sabanovic, H. Kozima: A dancing robot for rhythmic social interaction, Proc. 2nd ACM/IEEE Int. Conf. HRI, Washington DC (2007) pp. 89–96

71.80

M.P. Michalowski, R. Simmons, H. Kozima: Rhythmic attention in child-robot dance play, Proc. 18th IEEE Int. Symp. Robot Hum. Interact. Commun., Toyama (2009) pp. 816–821

71.81

E. Avrunin, J. Hart, A. Douglas, B. Scassellati: Effects related to synchrony and repertoire in perceptions of robot dance, Proc. 6th ACM/IEEE Int. Conf. HRI, Lausanne (2011) pp. 93–100

71.82

G. Hoffman, C. Breazeal: Anticipatory perceptual simulation for human-robot joint practice: Theory and application study, Proc. 23rd AAAI Conf. Artif. Intell., Chicago (2008) pp. 1357–1362

71.83

G. Hoffman, G. Weinberg: Interactive improvisation with a robotic marimba player, Auton. Robots 31(2-3), 133–153 (2011)CrossRef

71.84

G. Deàk, I. Fasel, J. Movellan: The emergence of shared attention: Using robots to test developmental theories, Proc. 1st Int. Workshop Epigenet. Robotics, Lund (2001) pp. 95–104

71.85

K. Dautenhahn: Roles and functions of robots in human society: Implications from research in autism therapy, Robotica 21(4), 443–452 (2003)CrossRef

71.86

H. Kozima, C. Nakagawa, Y. Yasuda: Wowing together: What facilitates social interactions in children with autistic spectrum disorders, Proc. 6th Int. Workshop Epigenet. Robotics Model. Cogn. Dev. Robotics Syst., Paris (2006) p. 177

71.87

B. Scassellati: How social robots will help us to diagnose, treat, and understand autism, Proc. 12th Int. Symp. Robotics Res., San Francisco, ed. by S. Thrun, R.A. Brooks, H. Durrant-Whyte (Springer, Berlin, Heidelberg 2005) pp. 552–563

71.88

D.J. Feil-Seifer, M.J. Mataric: B3IA: An architecture for autonomous robot-assisted behavior intervention for children with autism spectrum disorders, Proc. 17th IEEE Int. Workshop Robot Hum. Interact. Commun., Munich (2008) pp. 328–333

71.89

H. Kozima, C. Nakagawa, Y. Yasuda: Interactive robots for communication-care: A case-study in autism therapy, Proc. 14th IEEE Int. Workshop Robot Hum. Interact. Commun., Nashville (2005) pp. 341–346

71.90

H. Kozima, Y. Yasuda, C. Nakagawa: Social interaction facilitated by a minimally-designed robot: Findings from longitudinal therapeutic practices for autistic children, Proc. 16th IEEE Int. Symp. Robot Hum. interact. Commun., Jeju Island (2007) pp. 599–604

71.91

H.A. Simon: The Sciences of the Artificial (MIT Press, Cambridge 1969)

71.92

B. Adams, C.L. Breazeal, R.A. Brooks, B. Scassellati: Humanoid robots: A new kind of tool, IEEE Intell. Syst. Appl. 15(4), 25–31 (2000)CrossRef

71.93

L.W. Barsalou, C. Breazeal, L.B. Smith: Cognition as coordinated non-cognition, Cogn. Process. 8(2), 79–91 (2007)CrossRef

71.94

A.L. Thomaz, M. Berlin, C. Breazeal: An embodied computational model of social referencing, Proc. 14th IEEE Int. Workshop Robot Hum. Interact. Commun., Nashville (2005) pp. 591–598

71.95

G. Hoffman, C. Breazeal: Robotic partners? Bodies and minds: An embodied approach to fluid human-robot collaboration, Proc. 5th Int. Workshop Cogn. Robotics, Boston (2006) pp. 95–102

71.96

G. Hoffman: Effects of anticipatory action on human-robot teamwork efficiency, fluency, and perception of team, Proc. 2nd ACM/IEEE Int. Conf. HRI, Washington D.C. (2007) pp. 1–8

71.97

Y. Demiris, A. Meltzoff: The robot in the crib: A developmental analysis of imitation skills in infants and robots, Infant Child Dev. 17(1), 43–53 (2008)CrossRef

71.98

C. Nehaniv, K. Dautenhahn (Eds.): Imitation and Social Learning in Robots, Humans and Animals: Behavioural, Social and Communicative Dimensions (Cambridge Univ. Press, Cambridge 2009)

71.99

B. Scassellati: Imitation and mechanisms of joint attention: A developmental structure for building social skills on a humanoid robot, Lect. Notes Comput. Sci. 1562, 176–195 (1999)CrossRef

71.100

Y. Nagai, K. Hosoda, A. Morita, M. Asada: A constructive model for the development of joint attention, Connect. Sci. 15(4), 211–229 (2003)CrossRef

71.101

F. Kaplan, V. Hafner: The challenges of joint attention, Proc. 4th Int. Workshop Epigenet. Robotics, Lund (2004) pp. 67–74

71.102

C. Crick, M. Munz, B. Scassellati: Synchronization in social tasks: Robotic drumming, Proc. 15th IEEE Int. Workshop Robot Hum. Interact. Commun., Hatfield (2006) pp. 97–102

71.103

P. Bakker, Y. Kuniyoshi: Robot see, robot do: An overview of robot imitation, AISB-96 Workshop Learn. Robots Animals, Brighton (1996) pp. 3–11

71.104

R.S. Jackendoff: On beyond zebra: The relation of linguistic and visual information, Cognition 26, 89–114 (1987)CrossRef

71.105

B. Landau, R.S. Jackendoff: What and where in spatial language and spatial cognition, Behav. Brain Sci. 16, 217–265 (1993)CrossRef

71.106

L. Talmy: The fundamental system of spatial schemas in language. In: From Perception to Meaning: Image Schemas in Cognitive Linguistics, ed. by B. Hamp (Mouton de Gruyter, Berlin 2005)

71.107

T.P. Regier: The Acquisition of Lexical Semantics for Spatial Terms: A Connectionist Model of Perceptual Categorization, Ph.D. Thesis (University of California at Berkeley, Berkeley 1992)

71.108

J.D. Kelleher, F.J. Costello: Applying computational models of spatial prepositions to visually situated dialog, Comput. Linguist. 35(2), 271–306 (2008)CrossRef

71.109

T.P. Regier, L.A. Carlson: Grounding spatial language in perception: An empirical and computational investigation, J. Exp. Psychol. 130(2), 273–298 (2001)CrossRef

71.110

G. Bugmann, E. Klein, S. Lauria, T. Kyriacou: Corpus-based robotics: A route instruction example, Proc. 8th Conf. Intell. Auton. Syst. (IAS-8), Amsterdam (2004) pp. 96–103

71.111

M. Levit, D. Roy: Interpretation of spatial language in a map navigation task, IEEE Trans. Syst. Man Cybern. B 37(3), 667–679 (2007)CrossRef

71.112

M. MacMahon, B. Stankiewicz, B. Kuipers: Walk the talk: Connecting language, knowledge, and action in route instructions, Proc. Natl. Conf. Artif. Intell., Boston (2006) pp. 1475–1482

71.113

H. Kress-Gazit, G.E. Fainekos: Translating structured English to robot controllers, Adv. Robotics 22, 1343–1359 (2008)CrossRef

71.114

C. Matuszek, D. Fox, K. Koscher: Following directions using statistical machine translation, Proc. 5th ACM/IEEE Int. Conf. HRI, Nara (2010) pp. 251–258

71.115

A. Vogel, D. Jurafsky: Learning to follow navigational directions, Proc. 48th Annu. Meet. Assoc. Comput. Linguist., Uppsala (2010) pp. 806–814

71.116

S. Harnad: The symbol grounding problem, Physica D 43, 335–346 (1990)MathSciNetCrossRef

71.117

T. Winograd: Procedures as a Representation for Data in a Computer Program for Understanding Natural Language, MIT Tech. Rep. TMAC-TR-84 (MIT, Cambridge 1971)

71.118

K.Y. Hsiao, N. Mavridis, D. Roy: Coupling perception and simulation: Steps towards conversational robotics, Proc. IEEE/RSJ Int. Conf. Intell. Robots Syst. (IROS), Las Vegas (2003) pp. 928–933

71.119

D. Roy, K.Y. Hsiao, N. Mavridis: Conversational Robots: Building blocks for grounding word meanings, Proc. HLT-NAACL 2003 Workshop Learn. Word Mean. Non-Linguist. Data, Stroudsburg (2003) pp. 70–77

71.120

D. Roy: Semiotic schemas: A framework for grounding language in action and perception, Artif. Intell. 167(1-2), 170–205 (2005)CrossRef

71.121

J. Dzifcak, M. Scheutz, C. Baral, P. Schermerhorn: What to do and how to do it: Translating natural language directives into temporal and dynamic logic representation for goal management and action execution, IEEE Int. Conf. Robotics Autom. (ICRA), Kobe (2009) pp. 4163–4168

71.122

Y. Sugita, J. Tani: Learning semantic combinatoriality from the interaction between linguistic and behavioral processes, Adapt. Behav. – Animals Animat. Softw. Agents Robots Adapt. Syst. 13(1), 33–52 (2005)

71.123

J. Modayil, B. Kuipers: Autonomous development of a grounded object ontology by a learning robot, Proc. 22nd AAAI Conf. Artif. Intell., Vancouver (2007) pp. 1095–1101

71.124

D. Marocco, A. Cangelosi, K. Fischer, T. Belpaeme: Grounding action words in the sensorimotor interaction with the world: Experiments with a simulated iCub humanoid robot, Front. Neurorobotics 4, 1–15 (2010)

71.125

R. Ge, R.J. Mooney: A statistical semantic parser that integrates syntax and semantics, Proc. 9th Conf. Comput. Nat. Lang. Learn., Ann Arbor (2005) pp. 9–16

71.126

N. Shimizu, A. Haas: Learning to follow navigational route instructions, Proc. 21st Int. Jt. Conf. Artif. Intell., Pasadena (2009) pp. 1488–1493

71.127

S.R.K. Branavan, H. Chen, L.S. Zettlemoyer, R. Barzilay: Reinforcement learning for mapping instructions to actions, Proc. 47th Jt. Conf. Annu. Meet. Assoc. Comput. Linguist. 4th Int. Jt. Conf. Nat. Lang. Process. (AFNLP), Singapore (2009) pp. 82–90

71.128

S.R.K. Branavan, D. Silver, R. Barzilay: Learning to win by reading manuals in a Monte-Carlo framework, Proc. 49th Annu. Meet. Assoc. Comput. Linguist. Hum. Lang. Technol., Portland (2011)

71.129

T. Kollar, S. Tellex, D. Roy, N. Roy: Toward understanding natural language directions, Proc. 5th ACM/IEEE Int. Conf. HRI, Osaka (2010) pp. 259–266

71.130

D. Bailey: When Push Comes to Shove: A Computational Model of the Role of Motor Control in the Acquisition of Action Verbs, Ph.D. Thesis (Univ. of California, Berkeley 1997)

71.131

T. Kollar, S. Tellex, D. Roy, N. Roy: Grounding verbs of motion in natural language commands to robots, Proc. Int. Symp. Exp. Robotics, New Delhi (2010) pp. 31–47

71.132

S. Tellex, T. Kollar, S. Dickerson, M.R. Walter, A.G. Banerjee, S. Teller, N. Roy: Understanding natural language commands for robotic navigation and mobile manipulation, Proc. Natl. Conf. Artif. Intell., San Francisco (2011)

71.133

J.L. Burke, R.R. Murphy, M.D. Coovert, D.L. Riddle: Moonlight in Miami: Field study of human-robot interaction in the context of an urban search and rescue disaster response training exercise, Hum.–Comput. Interact. 19(1/2), 85–116 (2004)CrossRef

71.134

K. Stubbs, P.J. Hinds, D. Wettergreen: Autonomy and common ground in human-robot interaction: A field study, IEEE Intell. Syst. 22(2), 42–50 (2007)CrossRef

71.135

S. Kiesler: Fostering common ground in human-robot interaction, Proc. 14th IEEE Int. Workshop Robot Hum. Interact. Commun., Nashville (2005) pp. 729–734

71.136

T. Fong, C. Thorpe, C. Baur: Collaboration, dialogue, human-robot interaction, Robotics Res. 6, 255–266 (2003)CrossRef

71.137

M.E. Foster, T. By, M. Rickert, A. Knoll: Human-robot dialogue for joint construction tasks, Proc. 8th Int. Conf. Mulltimodal Interfaces, Banff (2006) pp. 68–71

71.138

S. Li, B. Wrede, G. Sagerer: A computational model of multi-modal grounding for human robot interaction, Proc. 7th SIGdial Workshop Discourse Dialogue, Sydney (2009) pp. 153–160

71.139

P.R. Cohen, H.J. Levesque: Teamwork, Nous 25(4), 487–512 (1991)CrossRef

71.140

J. Peltason, B. Wrede: Pamini: A framework for assembling mixed-initiative human-robot interaction from generic interaction patterns, Proc. 11th SIGdial Annu. Meet. Special Interest Group Discourse Dialogue, Tokyo (2010) pp. 229–232

71.141

J. Peltason, B. Wrede: The curious robot as a case-study for comparing dialog systems, AI Magazine 32(4), 85–99 (2011)CrossRef

71.142

M.F. Schober: Spatial perspective-taking in conversation, Cognition 47(1), 1–24 (1993)CrossRef

71.143

J.E. Hanna, M.K. Tanenhaus, J.C. Trueswell: The effects of common ground and perspective on domains of referential interpretation, J. Mem. Lang. 49(1), 43–61 (2003)CrossRef

71.144

J.G. Trafton, N.L. Cassimatis, M.D. Bugajska, D.P. Brock, F.E. Mintz, A.C. Schultz: Enabling effective human–robot interaction using perspective-taking in robots, IEEE Trans. Syst. Man Cybern. A 35(4), 460–470 (2005)CrossRef

71.145

M. Berlin, J. Gray, A.L. Thomaz, C. Breazeal: Perspective taking: An organizing principle for learning in human–robot interaction, Proc. 21st Natl. Conf. Artif. Intell., Boston (2006) p. 1444

71.146

R. Moratz, K. Fischer, T. Tenbrink: Cognitive modeling of spatial reference for human-robot interaction, Int. J. Artif. Intell. Tools 10(04), 589–611 (2001)CrossRef

71.147

R. Ros, S. Lemaignan, E.A. Sisbot, R. Alami, J. Steinwender, K. Hamann, F. Warneken: Which one? Grounding the referent based on efficient human-robot interaction, Proc. 19th IEEE Int. Symp. Robot Hum. Interact. Commun., Viareggio (2010) pp. 570–575

71.148

A. Holroyd, C. Rich, C.L. Sidner, B. Ponsler: Generating connection events for human-robot collaboration, Proc. 20th IEEE Int. Symp. Robot Hum. Interact. Commun., Atlanta (2011) pp. 241–246

71.149

G. Butterworth, L. Grover: Joint visual attention, manual pointing, and preverbal communication in human infancy. In: Attention and Performance, Vol. 13: Motor Representation and Control, ed. by M. Jeannerod (Lawrence Erlbaum Assoc., Mahwah 1990) pp. 605–624

71.150

C. Rich, P. Ponsler, A. Holroyd, C.L. Sidner: Recognizing engagement in human-robot interaction, Proc. 5th ACM/IEEE Int. Conf. HRI, Osaka (2010) pp. 375–382

71.151

V. Gallese, A. Goldman: Mirror neurons and the simulation theory of mind-reading, Trends Cogn. Sci. 2(12), 493–501 (1998)CrossRef

71.152

E. Bicho, W. Erlhagen, L. Louro, E. Costa e Silva: Neuro-cognitive mechanisms of decision making in joint action: A human–robot interaction study, Hum. Mov. Sci. 30(5), 846–868 (2011)CrossRef

71.153

J. Gray, C. Breazeal, M. Berlin, A. Brooks, J. Lieberman: Action parsing and goal inference using self as simulator, Proc. 14th IEEE Int. Workshop Robot Hum. Interact. Commun., Nashville (2005) pp. 202–209

71.154

M.N. Nicolescu, M.J. Mataric: Linking perception and action in a control architecture for human-robot domains, Proc. 36th Annu. Hawaii Int. Conf. Syst. Sci., Big Island (2003) pp. 10–20

71.155

C. Breazeal, G. Hoffman, A. Lockerd: Teaching and working with robots as a collaboration, Proc. 3rd Int. Jt. Conf. Auton. Agents Multiagent Syst., New York, Vol. 3 (2004) pp. 1030–1037

71.156

R. Alami, A. Clodic, V. Montreuil, E.A. Sisbot, R. Chatila: Task planning for human–robot interaction, Proc. 2005 Jt. Conf. Smart Obj. Ambient Intell. Innov. Context-Aware Serv. Usages Technol., Grenoble (2005) pp. 81–85

71.157

R. Alami, A. Clodic, V. Montreuil, E.A. Sisbot, R. Chatila: Toward human-aware robot task planning, AAAI Spring Symp.: To Boldly Go where No Human-Robot Team Has Gone Before, Palo Alto (2006) pp. 39–46

71.158

R. Bellman: Dynamic Programming (Princeton Univ. Press, Princeton 1957)MATH

71.159

N. Roy, J. Pineau, S. Thrun: Spoken dialog management for robots, Proc. Assoc. Comput. Linguist., Hong Kong (2000) pp. 93–100

71.160

J. Hoey, P. Poupart, C. Boutilier, A. Mihailidis: POMDP models for assistive technology, Proc. AAAI Fall Symp. Caring Mach., AI in Eldercare (2005)

71.161

J. Williams, S. Young: Scaling up POMDPs for dialogue management: The summary POMDP method, Proc. IEEE Autom. Speech Recognit. Underst. Workshop, Cancun (2005)

71.162

D. Litman, S. Singh, M. Kearns, M. Walker: NJFun: A reinforcement learning spoken dialogue system, Proc. ANLP/NAACL 2000 Workshop Conversat. Syst., Seattle (2000) pp. 17–20CrossRef

71.163

F. Broz, I. Nourbakhsh, R. Simmons: Planning for human-robot interaction using time-state aggregated POMDPs, Proc. 23rd Conf. Artif. Intell., Chicago (2008) pp. 1339–1344

71.164

F. Doshi, N. Roy: The permutable POMDP: Fast solutions to POMDPs for preference elicitation, Proc. 7th Int. Conf. Auton. Agents Multiagent Syst., Estoril (2008) pp. 493–500

71.165

R. Wilcox, S. Nikolaidis, J. Shah: Optimization of temporal dynamics for adaptive human-robot interaction in assembly manufacturing, Proc. Robotics Sci. Syst., Sydney (2012) p. 441

71.166

T. Prommer, H. Holzapfel, A. Waibel: Rapid simulation-driven reinforcement learning of multimodal dialog strategies in human–robot interaction, 9th Int. Conf. Spoken Lang. Process., Pittsburgh (2006)

71.167

J.M. Porta, N. Vlassis, M. Spaan, P. Poupart: Point-based value iteration for continuous POMDP, J. Mach. Learn. Res. 7, 2329–2367 (2006)MathSciNetMATH

71.168

F. Doshi, N. Roy: Efficient model learning for dialog management, Proc. 2nd ACM/IEEE Int. Conf. HRI, Arlington (2007) pp. 65–72

71.169

F. Doshi, N. Roy: Spoken language interaction with model uncertainty: An adaptive human-robot interaction system, Connect. Sci. 20(4), 299–319 (2008)CrossRef

71.170

M. Cakmak, A.L. Thomaz: Designing robot learners that ask good questions, Proc. 7th Annu. ACM/IEEE Int. Conf. HRI, Boston (2012) pp. 17–24

71.171

M.A. Goodrich, D.R. Olsen: Seven principles of efficient human robot interaction, IEEE Int. Conf. Syst. Man Cybern., Washington D.C. (2003) pp. 3942–3948

71.172

J.W. Crandall, M.A. Goodrich, D.R. Olsen, C.W. Nielsen: Validating human-robot interaction schemes in multitasking environments, IEEE Trans. Syst. Man Cybern. A 35(4), 438–449 (2005)CrossRef

71.173

R. Sun (Ed.): Cognition and Multiagent Interaction: From Cognitive Modeling to Social Simulation (Cambridge Univ. Press, Cambridge 2005)

Title: Cognitive Human–Robot Interaction
Authors: Bilge Mutlu
Nicholas Roy
Selma Šabanović
Publisher: Springer International Publishing
Book: Springer Handbook of Robotics
Print ISBN: 978-3-319-32550-7

Electronic ISBN: 978-3-319-32552-1

Copyright Year: 2016
DOI: https://doi.org/10.1007/978-3-319-32552-1_71

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Springer Professional "Wirtschaft"