An architecture for online affordance-based perception and whole-body planning

Maurice Fallon; Scott Kuindersma; Sisir Kurumanchi; Matthew Antone; Toby Schneider; Hongkai Dai; Claudia Pérez D'Arpino; Robin Deits; Matt DiCicco; Dehann Fourie; Twan Koolen; Pat Marion; Michael Posa; Andrés Valenzuela; Kuan-Ting Yu; Julie Shah; Karl Iagnemma; Russ Tedrake; Seth Teller

doi:10.1002/rob.21546

An architecture for online affordance-based perception and whole-body planning

Maurice Fallon, Scott Kuindersma, Sisir Kurumanchi, Matthew Antone, Toby Schneider, Hongkai Dai, Claudia Pérez D'Arpino, Robin Deits, Matt DiCicco, Dehann Fourie, Twan Koolen, Pat Marion, Michael Posa, Andrés Valenzuela, Kuan-Ting Yu, Julie Shah, Karl Iagnemma, Russ Tedrake, Seth Teller

Research output: Contribution to journal › Article › peer-review

Abstract

The DARPA Robotics Challenge Trials held in December 2013 provided a landmark demonstration of dexterous mobile robots executing a variety of tasks aided by a remote human operator using only data from the robot's sensor suite transmitted over a constrained, field-realistic communications link. We describe the design considerations, architecture, implementation, and performance of the software that Team MIT developed to command and control an Atlas humanoid robot. Our design emphasized human interaction with an efficient motion planner, where operators expressed desired robot actions in terms of affordances fit using perception and manipulated in a custom user interface. We highlight several important lessons we learned while developing our system on a highly compressed schedule.

Original language	English
Pages (from-to)	229-254
Number of pages	25
Journal	Journal of Field Robotics
Volume	32
Issue number	2
Early online date	25 Oct 2014
DOIs	https://doi.org/10.1002/rob.21546
Publication status	Published - Mar 2015

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http://onlinelibrary.wiley.com/doi/10.1002/rob.21546/abstract

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Fallon, M., Kuindersma, S., Kurumanchi, S., Antone, M., Schneider, T., Dai, H., D'Arpino, C. P., Deits, R., DiCicco, M., Fourie, D., Koolen, T., Marion, P., Posa, M., Valenzuela, A., Yu, K.-T., Shah, J., Iagnemma, K., Tedrake, R., & Teller, S. (2015). An architecture for online affordance-based perception and whole-body planning. Journal of Field Robotics, 32(2), 229-254. https://doi.org/10.1002/rob.21546

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title = "An architecture for online affordance-based perception and whole-body planning",

abstract = "The DARPA Robotics Challenge Trials held in December 2013 provided a landmark demonstration of dexterous mobile robots executing a variety of tasks aided by a remote human operator using only data from the robot's sensor suite transmitted over a constrained, field-realistic communications link. We describe the design considerations, architecture, implementation, and performance of the software that Team MIT developed to command and control an Atlas humanoid robot. Our design emphasized human interaction with an efficient motion planner, where operators expressed desired robot actions in terms of affordances fit using perception and manipulated in a custom user interface. We highlight several important lessons we learned while developing our system on a highly compressed schedule.",

author = "Maurice Fallon and Scott Kuindersma and Sisir Kurumanchi and Matthew Antone and Toby Schneider and Hongkai Dai and D'Arpino, \{Claudia P{\'e}rez\} and Robin Deits and Matt DiCicco and Dehann Fourie and Twan Koolen and Pat Marion and Michael Posa and Andr{\'e}s Valenzuela and Kuan-Ting Yu and Julie Shah and Karl Iagnemma and Russ Tedrake and Seth Teller",

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Fallon, M, Kuindersma, S, Kurumanchi, S, Antone, M, Schneider, T, Dai, H, D'Arpino, CP, Deits, R, DiCicco, M, Fourie, D, Koolen, T, Marion, P, Posa, M, Valenzuela, A, Yu, K-T, Shah, J, Iagnemma, K, Tedrake, R & Teller, S 2015, 'An architecture for online affordance-based perception and whole-body planning', Journal of Field Robotics, vol. 32, no. 2, pp. 229-254. https://doi.org/10.1002/rob.21546

TY - JOUR

T1 - An architecture for online affordance-based perception and whole-body planning

AU - Fallon, Maurice

AU - Kuindersma, Scott

AU - Kurumanchi, Sisir

AU - Antone, Matthew

AU - Schneider, Toby

AU - Dai, Hongkai

AU - D'Arpino, Claudia Pérez

AU - Deits, Robin

AU - DiCicco, Matt

AU - Fourie, Dehann

AU - Koolen, Twan

AU - Marion, Pat

AU - Posa, Michael

AU - Valenzuela, Andrés

AU - Yu, Kuan-Ting

AU - Shah, Julie

AU - Iagnemma, Karl

AU - Tedrake, Russ

AU - Teller, Seth

PY - 2015/3

Y1 - 2015/3

N2 - The DARPA Robotics Challenge Trials held in December 2013 provided a landmark demonstration of dexterous mobile robots executing a variety of tasks aided by a remote human operator using only data from the robot's sensor suite transmitted over a constrained, field-realistic communications link. We describe the design considerations, architecture, implementation, and performance of the software that Team MIT developed to command and control an Atlas humanoid robot. Our design emphasized human interaction with an efficient motion planner, where operators expressed desired robot actions in terms of affordances fit using perception and manipulated in a custom user interface. We highlight several important lessons we learned while developing our system on a highly compressed schedule.

AB - The DARPA Robotics Challenge Trials held in December 2013 provided a landmark demonstration of dexterous mobile robots executing a variety of tasks aided by a remote human operator using only data from the robot's sensor suite transmitted over a constrained, field-realistic communications link. We describe the design considerations, architecture, implementation, and performance of the software that Team MIT developed to command and control an Atlas humanoid robot. Our design emphasized human interaction with an efficient motion planner, where operators expressed desired robot actions in terms of affordances fit using perception and manipulated in a custom user interface. We highlight several important lessons we learned while developing our system on a highly compressed schedule.

U2 - 10.1002/rob.21546

DO - 10.1002/rob.21546

M3 - Article

SN - 1556-4959

VL - 32

SP - 229

EP - 254

JO - Journal of Field Robotics

JF - Journal of Field Robotics

IS - 2

ER -

An architecture for online affordance-based perception and whole-body planning

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