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International Journal of Social Robotics

Erschienen in:

01.11.2016

Measuring the Effectiveness of Readability for Mobile Robot Locomotion

verfasst von: Daniel Carton, Wiktor Olszowy, Dirk Wollherr

Erschienen in: International Journal of Social Robotics | Ausgabe 5/2016

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Abstract

The inclusion of social and human-like behaviors is recently emphasized within mobile robot locomotion. These behaviors are required to support the seamless integration of mobile robots into environments which they share with humans. This work demonstrates a distinct benefit of these behaviors, which goes beyond positive apperception. It is shown that human-like robot locomotion reduces the planning effort for all agents within an environment. This effect is revealed in an experiment that compares human locomotion during avoidance of an oncoming human or wheeled robot. In order to evaluate recorded data, a framework for the analysis of human trajectories is proposed. Confidence intervals based on a spline regression model are used to account for variance in the data. This qualitative method is complemented by a comparative analysis, that quantifies differences and analogies within the data. Thus, the framework allows for a statistically feasible qualitative and quantitative analysis of trajectories. Results show, that extra planning effort for the avoidance is prevented by readable human-like robot locomotion. The study indicates that locomotion planning requires less effort from subjects if the mutual trajectory prediction is facilitated by robots that externalize intentions and comply with human-like behaviors.

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Albrecht S, Basili P, Glasauer S, Leibold (Sobotka) M, Ulbrich M (2012) Modeling and analysis of human navigation with crossing interferer using inverse optimal control. In: International conference on mathematical modelling, pp 158–163

Allgöwer G, Badgwell T, Qin J, Rawlings J, Wright S (1999) Nonlinear predictive control and moving horizon estimationan introductory overview. Advances in contro. Springer, London

Althoff D, Kuffner J, Wollherr D, Buss M (2012) Safety assessment of robot trajectories for navigation in uncertain and dynamic environments. Auton Robots 32(3):285–302

Arechavaleta G, Laumond J, Hicheur H, Berthoz A (2006) The nonholonomic nature of human locomotion: a modeling study. In: International conference on biomedical robotics and biomechatronics, pp 158–163

Arechavaleta G, Laumond JP, Hicheur H, Berthoz A (2008) An optimality principle governing human walking. Trans Robot 24(1):5–14CrossRef

Basili P, Huber M, Kourakos O, Lorenz T, Brandt T, Hirche S, Glasauer S (2012) Inferring the goal of an approaching agent: a human-robot study. In: International Workshop on Robots and Human Interactive Communications, pp 527–532

Basili P, Sağlam M, Kruse T, Huber M, Kirsch A, Glasauer S (2013) Strategies of locomotor collision avoidance. Gait Posture 37(3):385–390CrossRef

van Basten B, Jansen S, Karamouzas I (2009) Exploiting motion capture to enhance avoidance behaviour in games. Motion Games 5884:29–40CrossRef

Bitgood S, Dukes S (2006) Not another step! economy of movement and pedestrian choice point behavior in shopping malls. Environ Behav 38(3):394–405CrossRef

10.

Breazeal C, Kidd C, Thomaz A, Hoffman G, Berlin M (2005) Effects of nonverbal communication on efficiency and robustness in human-robot teamwork. In: International Conference on Intelligent Robots and Systems, pp 708–713

11.

Buchin K, Buchin M, Van Kreveld M, Luo J (2011) Finding long and similar parts of trajectories. Comput Geom 44(9):465–476MathSciNetCrossRefMATH

12.

Buchin K, Buchin M, Van Kreveld M, Löffler M, Silveira RI, Wenk C, Wiratma L (2013) Median trajectories. Algorithmica 66(3):595–614MathSciNetCrossRefMATH

13.

Buss M, et al (2011) Towards proactive human-robot interaction in human environments. In: International Conference on Cognitive Infocommunications, pp 1–6

14.

Buss M, et al (2015) Iuro—Soziale Mensch-Roboter-Interaktion in den Straßen von München. at – Automatisierungstechnik

15.

Caraian S, Kirchner N, Colborne-Veel P (2015) Moderating a robot’s ability to influence people through its level of sociocontextual interactivity. In: International Conference on Human-Robot Interaction, pp 149–156

16.

Carton D, Turnwald A, Wollherr D, Buss M (2012) Proactively approaching pedestrians with an autonomous mobile robot in urban environments. In: International symposium on experimental robotics, Springer, pp 199–214

17.

Carton D, Turnwald A, Olszowy W, Wollherr D, Buss M (2014) Using penalized spline regression to calculate mean trajectories including confidence intervals of human motion data. In: Workshop on advanced robotics and its social impacts, pp 76–81

18.

Cassisi C, Montalto P, Pulvirenti A (2012) Similarity measures and dimensionality reduction techniques for time series data mining. In: Advances in Data Mining, Knowledge Discovery and Applications, INTECH, chap 3

19.

Cohen J (1988) Statistical power analysis for the behavioral sciences. Lawrence Erlbaum Associates, Hillsdale, NJMATH

20.

Cox D, Hinkley D (1974) Theoretical statistics. Chapman & Hal, Boca RatonCrossRefMATH

21.

Csibra G, Gergely G (2007) Obsessed with goals: functions and mechanisims of teleological interpretation of action in humans. Acta Psychol 124(1):60–78CrossRef

22.

Dragan A, Srinivasa S (2013) Generating legible motion. In: Robotics: Science and Systems

23.

Dragan A, Srinivasa S (2014) Familiarization to robot motion. In: International conference on human-robot interaction, pp 366–373

24.

Dragan A, Bauman S, Forlizzi J, Srinivasa S (2015) Effects of robot motion on human-robot collaboration. In: International conference on human-robot interaction, pp 51–58

25.

Duffy BR (2003) Anthropomorphism and the social robot. Robot Auton Syst 42(3):177–190CrossRefMATH

26.

Efron B, Tibshirani R (1993) An introduction to the bootstrap. Chapman & Hall, boca ratonCrossRefMATH

27.

Fahrmeir L, Kneib T, Lang S (2009) Regression. Springer, BerlinCrossRefMATH

28.

Fajen B, Warren W (2003) Behavioral dynamics of steering, obstacle avoidance, and route selection. Exp Psychol 29(2):343

29.

Fink P, Foo P, Warren W (2007) Obstacle avoidance during walking in real and virtual environments. Trans Appl Percept 4(1):2CrossRef

30.

Frith U, Frith C (2010) The social brain: allowing humans to boldly go where no other species has been. Philos Trans R Soc Lond B 365(1537):165–176CrossRef

31.

Goffman E (1971) Relations in public: microstudies of the public order. Harper and Row, New York

32.

Gudmundsson J, van Kreveld M, Speckmann B (2007) Efficient detection of patterns in 2d trajectories of moving points. Geoinformatica 11(2):195–215CrossRef

33.

Hall ET (1966) The hidden dimension: man’s use of space in public and private. The Bodley Head Ltd, London

34.

Hartnett J, Bailey K, Hartley C (1974) Body height, position, and sex as determinants of personal space. J Psychol 87:129–136CrossRef

35.

Helbing D, Molnar P (1995) Social force model for pedestrian dynamics. Phys Rev E 51(5):4282CrossRef

36.

Hicheur H, Pham Q, Arechavaleta G, Laumond J, Berthoz A (2007) The formation of trajectories during goal-oriented locomotion in humans. i. a. stereotyped behaviour. Eur J Neurosci 26(8):2376–2390CrossRef

37.

Houska B, Ferreau HJ, Diehl M (2011) Acado toolkit—an open-source framework for automatic control and dynamic optimization. Optim Control Appl Methods 32(3):298–312

38.

Huber M, Su YH, Krüger M, Faschian K, Glasauer S, Hermsdörfer J (2014) Adjustments of speed and path when avoiding collisions with another pedestrian. PLoS One 9(2): e89589. doi:10.1371/journal.pone.0089589

39.

Karamouzas I, Overmars MH (2010) Simulating human collision avoidance using a velocity-based approach. VRIPHYS 10:125–134

40.

Kato Y, Kanda T, Ishiguro H (2015) May i help you? Design of human-like polite approaching behavior. In: International conference on human-robot interaction, pp 35–42

41.

Keogh E, Pazzani M (2000) Scaling up dynamic time warping for datamining applications. In: International conference on knowledge discovery and data mining, pp 285–289

42.

Kim B, Pineau J (2015) Socially adaptive path planning in human environments using inverse reinforcement learning. Int J Soc Robot 8(1):51–66CrossRef

43.

Kirby R, Simmons R, Forlizzi J (2009) Companion: A constraint-optimizing method for person-acceptable navigation. In: International symposium on robot and human interactive communication, pp 607–612

44.

Kirchner N, Alempijevic A (2012) A robot centric perspective on the HRI paradigm. Human-Robot Interact 1(2):135–157

45.

van Kreveld M, Luo J (2007) The definition and computation of trajectory and subtrajectory similarity. In: International symposium on advances in geographic information systems, p 44

46.

Kruse T, Basili P, Glasauer S, Kirsch A (2012) Legible robot navigation in the proximity of moving humans. In: International workshop on advanced robotics and its social impacts, pp 83–88

47.

Kruse T, Kirsch A, Khambhaita H, Alami R (2014) Evaluating directional cost models in navigation. In: International conference on human-robot interaction, pp 350–357

48.

Kuderer M, Kretzschmar H, Sprunk C, Burgard W (2012) Feature-based prediction of trajectories for socially compliant navigation. In: Robotics: science and systems, pp 193 – 200

49.

Li Z, Deng J, Lu R, Xu Y, Bai J, Su CY (2015) Trajectory-tracking control of mobile robot systems incorporating neural-dynamic optimized model predictive approach. TransSyst Man Cybernet 99:1

50.

Li Z, Xiao H, Yang C, Zhao Y (2015) Model predictive control of nonholonomic chained systems using general projection neural networks optimization. Trans Syst Man Cybernet Syst 45(10):1313–1321CrossRef

51.

Lichtenthäler C, Kirsch A (2013) Towards legible robot navigation—how to increase the intend expressiveness of robot navigation behavior. ICSR

52.

Lichtenthäler C, Lorenz T, Kirsch A (2012) Influence of legibility on perceived safety in a virtual human-robot path crossing task. In: International symposium on robot and human interactive communication, pp 676–681

53.

McNeill Alexander R (2002) Energetics and optimization of human walking and running: the 2000 raymond pearl memorial lecture. Hum Biol 14(5):641–648CrossRef

54.

Mombaur K, Truong A, Laumond JP (2009) From human to humanoid locomotion—an inverse optimal control approach. Autonom Robot 28(3):369–383CrossRef

55.

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

56.

Nilsson NJ (1984) Shakey the robot. SRI International Technical Note 325

57.

Olivier AH, Kulpa R, Pettré J, Crétual A (2009) Motion in games, lecture notes in computer science. In: Egges A, Geraerts R, Overmars M (eds) A velocity-curvature space approach for walking motions analysis, vol 5884. Springer, Berlin, pp 104–115

58.

Olivier AH, Marin A, Crétual A, Pettré J (2012) Minimal predicted distance: a common metric for collision avoidance during pairwise interactions between walkers. Gait Posture 36(3):399–404CrossRef

59.

Olivier AH, Marin A, Crétual A, Berthoz A, Pettré J (2013) Collision avoidance between two walkers: role-dependent strategies. Gait Posture 38(4):751–756CrossRef

60.

Pacchierotti E, Christensen H, Jensfelt P (2006) Evaluation of passing distance for social robots. In: International symposim on robot and human interactive communication (ROMAN), pp 315–320

61.

Papadopoulos AV, Bascetta L, Ferretti G (2014) A comparative evaluation of human motion planning policies. In: IFAC world congress

62.

Paris S, Pettr J, Donikian S (2007) Pedestrian reactive navigation for crowd simulation: a predictive approach. Comput Graph Forum 26(3):665–674CrossRef

63.

Pellegrini S, Ess A, Schindler K, Van Gool L (2009) You’ll never walk alone: modeling social behavior for multi-target tracking. In: International conference on computer vision, pp 261–268

64.

Pettré J, Ondrej J, Olivier AH, Crtual, Donikian S (2009) Experiment-based modeling, simulation and validation of interactions between virtual walkers. In: Eurographics symposium on computer animation

65.

Prassler E, Scholz J, Fiorini P (1999) Navigating a robotic wheelchair in a railway station during rush hour. Int J Robot Res 18(7):711–727CrossRef

66.

Ratanamahatana CA, Lin J, Gunopulos D, Keogh E, Vlachos M, Das G (2010) Mining time series data. Springer, New York

67.

Reeves B, Nass C (1996) The media equation: how people treat computers, television, and new media like real people and places. cambridge University Press, Cambridge

68.

Reynolds C (1999) Steering behaviors for autonomous characters. In: Game developers conference, pp 763–782

69.

Rios-Martinez J, Spalanzani A, Laugier C (2014) From proxemics theory to socially-aware navigation: a survey. Int J Soc Robot 7(2):137–153CrossRef

70.

Shiomi M, Zanlungo F, Hayashi K, Kanda T (2014) Towards a socially acceptable collision avoidance for a mobile robot navigating among pedestrians using a pedestrian model. Int J Soc Robot 6(3):443–455CrossRef

71.

Sobel R, Lillith N (1975) Determinant of nonstationary personal space invasion. J Psychol 97:39–45

72.

Sparrow W, Newell K (1998) Metabolic energy expenditure and the regulation of movement economy. Psychon Bull Rev 5(2):173–196CrossRef

73.

Su J, Kurtek S, Klassen E, Srivastava A (2014) Statistical analysis of trajectories on riemannian manifolds: bird migration, hurricane tracking and video surveillance. Ann Appl Stat 8(1):530–552MathSciNetCrossRefMATH

74.

Takayama L, Dooley D, Ju W (2011) Expressing thought: improving robot readability with animation principles. In: International conference on human-robot interaction, pp 69–76

75.

Turnwald A, Olszowy W, Wollherr D, Buss M (2014) Interactive navigation of humans from a game theoretic perspective. In: International conference on intelligent robots and systems, pp 703–708

76.

Turnwald A, Althoff D, Wollherr D, Buss M (2016) Understanding human avoidance behavior: interaction-aware decision making based on game theory. Int J Soc Robot 8(2):331–351CrossRef

77.

Van Den Berg J, Guy S, Lin M, Manocha D (2011) Reciprocal n-body collision avoidance. Robot Res 70:3–19

78.

Vlachos M, Kollios G, Gunopulos D (2002) Discovering similar multidimensional trajectories. In: International conference on data engineering, pp 673–684

79.

Wilkie D, Van Den Berg J, Manocha D (2009) Generalized velocity obstacles. In: International conference on intelligent robots and systems, pp 5573–5578

80.

Wolff M (1973) Notes on the behaviour of pedestrians. In: Silverman D (ed) People in places: the sociology of the familiar. Praeger, New York, pp 35–48

81.

Wolfinger N (1995) Passing moments: some social dynamics of pedestrian interaction. J Contemp Ethnogr 24(3):323–340CrossRef

Titel: Measuring the Effectiveness of Readability for Mobile Robot Locomotion
verfasst von: Daniel Carton
Wiktor Olszowy
Dirk Wollherr
Publikationsdatum: 01.11.2016
Verlag: Springer Netherlands
Erschienen in: International Journal of Social Robotics / Ausgabe 5/2016
Print ISSN: 1875-4791
Elektronische ISSN: 1875-4805
DOI: https://doi.org/10.1007/s12369-016-0358-7

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