Optimization-based locomotion planning, estimation, and control
design for the atlas humanoid robot

Scott Kuindersma; Robin Deits; Maurice Fallon; Andrés Valenzuela; Hongkai Dai; Frank  Permenter; Twan Koolen; Pat Marion; Russ Tedrake

doi:10.1007/s10514-015-9479-3

Optimization-based locomotion planning, estimation, and control design for the atlas humanoid robot

Scott Kuindersma, Robin Deits, Maurice Fallon, Andrés Valenzuela, Hongkai Dai, Frank Permenter, Twan Koolen, Pat Marion, Russ Tedrake

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

Abstract

This paper describes a collection of optimization algorithms for achieving dynamic planning, control, and state estimation for a bipedal robot designed to operate reliably in complex environments. To make challenging locomotion tasks tractable, we describe several novel applications of convex, mixed-integer, and sparse nonlinear optimization to problems ranging from footstep placement to whole-body planning and control. We also present a state estimator formulation that, when combined with our walking controller, permits highly precise execution of extended walking plans over non- at terrain. We describe our complete system integration and experiments carried out on Atlas, a full-size hydraulic humanoid robot built by Boston Dynamics, Inc.

Original language	English
Pages (from-to)	429-455
Number of pages	27
Journal	Autonomous Robots
Volume	40
Issue number	3
Early online date	31 Jul 2015
DOIs	https://doi.org/10.1007/s10514-015-9479-3
Publication status	Published - Mar 2016

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title = "Optimization-based locomotion planning, estimation, and control design for the atlas humanoid robot",

abstract = "This paper describes a collection of optimization algorithms for achieving dynamic planning, control, and state estimation for a bipedal robot designed to operate reliably in complex environments. To make challenging locomotion tasks tractable, we describe several novel applications of convex, mixed-integer, and sparse nonlinear optimization to problems ranging from footstep placement to whole-body planning and control. We also present a state estimator formulation that, when combined with our walking controller, permits highly precise execution of extended walking plans over non- at terrain. We describe our complete system integration and experiments carried out on Atlas, a full-size hydraulic humanoid robot built by Boston Dynamics, Inc.",

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AU - Kuindersma, Scott

AU - Deits, Robin

AU - Fallon, Maurice

AU - Valenzuela, Andrés

AU - Dai, Hongkai

AU - Permenter, Frank

AU - Koolen, Twan

AU - Marion, Pat

AU - Tedrake, Russ

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AB - This paper describes a collection of optimization algorithms for achieving dynamic planning, control, and state estimation for a bipedal robot designed to operate reliably in complex environments. To make challenging locomotion tasks tractable, we describe several novel applications of convex, mixed-integer, and sparse nonlinear optimization to problems ranging from footstep placement to whole-body planning and control. We also present a state estimator formulation that, when combined with our walking controller, permits highly precise execution of extended walking plans over non- at terrain. We describe our complete system integration and experiments carried out on Atlas, a full-size hydraulic humanoid robot built by Boston Dynamics, Inc.

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JO - Autonomous Robots

JF - Autonomous Robots

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ER -

Optimization-based locomotion planning, estimation, and control design for the atlas humanoid robot

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