Zachary Goddard scite author profile

Zachary Goddard

5Publications

27Citation Statements Received

54Citation Statements Given

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Georgia Institute of Technology

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Dynamics of scattering in undulatory active collisions

et al. 2019

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Natural and artificial self-propelled systems must manage environmental interactions during movement. Such interactions, which we refer to as active collisions, are fundamentally different from momentum-conserving interactions studied in classical physics, largely because the internal driving of the locomotor can lead to persistent contact with heterogeneities. Here, we experimentally and numerically study the effects of active collisions on a laterally-undulating sensory-deprived robophysical model, whose dynamics are applicable to self-propelled systems across length scales and environments. The robot moves via spatial undulation of body segments, with a nearly-linear centerof-geometry trajectory. Interactions with a single rigid post scatter the robot, and these deflections are proportional to the head-post contact duration. The distribution of scattering angles is smooth and strongly-peaked directly behind the post. Interactions with a single row of evenly-spaced posts (with inter-post spacing d) produce distributions reminiscent of far-field diffraction patterns: as d decreases, distinct secondary peaks emerge as large deflections become more likely. Surprisingly, we find that the presence of multiple posts does not change the nature of individual collisions; instead, multi-modal scattering patterns arise from multiple posts altering the likelihood of individual collisions to occur. As d decreases, collisions near the leading edges of the posts become more probable, and we find that these interactions are associated with larger deflections. Our results, which highlight the surprising dynamics that can occur during active collisions of self-propelled systems, can inform control principles for locomotors in complex terrain and facilitate design of task-capable active matter.

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Utilizing Reinforcement Learning to Continuously Improve a Primitive-Based Motion Planner.

Goddard¹,

Wardlaw²,

Krishnan³

et al. 2020

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Automated Motion Libraries for Enhanced Data-Driven Intelligence (FY19 Technical Report)

Mazumdar¹,

Goddard²

2019

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Utilizing Reinforcement Learning to Continuously Improve a Primitive-Based Motion Planner

Goddard¹,

Wardlaw²,

Williams³

et al. 2022

Journal of Aerospace Information Systems

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Utilizing Reinforcement Learning to Continuously Improve a Primitive-Based Motion Planner

Goddard

Wardlaw

Krishnan

et al. 2021

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Zachary Goddard

Dynamics of scattering in undulatory active collisions

Utilizing Reinforcement Learning to Continuously Improve a Primitive-Based Motion Planner.

Automated Motion Libraries for Enhanced Data-Driven Intelligence (FY19 Technical Report)

Utilizing Reinforcement Learning to Continuously Improve a Primitive-Based Motion Planner

Utilizing Reinforcement Learning to Continuously Improve a Primitive-Based Motion Planner

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