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Main Authors: Kerimoglu, Deniz, Naclerio, Nicholas D., Chu, Sean, Krohn, Andrew, Kupunaram, Vineet, Schepelmann, Alexander, Goldman, Daniel I., Hawkes, Elliot W.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.10901
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author Kerimoglu, Deniz
Naclerio, Nicholas D.
Chu, Sean
Krohn, Andrew
Kupunaram, Vineet
Schepelmann, Alexander
Goldman, Daniel I.
Hawkes, Elliot W.
author_facet Kerimoglu, Deniz
Naclerio, Nicholas D.
Chu, Sean
Krohn, Andrew
Kupunaram, Vineet
Schepelmann, Alexander
Goldman, Daniel I.
Hawkes, Elliot W.
contents Most engineered pilings require substantially more force to be driven into the ground than they can resist during extraction. This requires relatively heavy equipment for insertion, which is problematic for anchoring in hard-to-access sites, including in extraterrestrial locations. In contrast, for tree roots, the external reaction force required to extract is much greater than required to insert--little more than the weight of the seed initiates insertion. This is partly due to the mechanism by which roots insert into the ground: tip extension. Proof-of-concept robotic prototypes have shown the benefits of using this mechanism, but a rigorous understanding of the underlying granular mechanics and how they inform the design of a robotic anchor is lacking. Here, we study the terradynamics of tip-extending anchors compared to traditional piling-like intruders, develop a set of design insights, and apply these to create a deployable robotic anchor. Specifically, we identify that to increase an anchor's ratio of extraction force to insertion force, it should: (i) extend beyond a critical depth; (ii) include hair-like protrusions; (iii) extend near-vertically, and (iv) incorporate multiple smaller anchors rather than a single large anchor. Synthesizing these insights, we developed a lightweight, soft robotic, root-inspired anchoring device that inserts into the ground with a reaction force less than its weight. We demonstrate that the 300 g device can deploy a series of temperature sensors 45 cm deep into loose Martian regolith simulant while anchoring with an average of 120 N, resulting in an anchoring-to-weight ratio of 40:1.
format Preprint
id arxiv_https___arxiv_org_abs_2511_10901
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Terradynamics and design of tip-extending robotic anchors
Kerimoglu, Deniz
Naclerio, Nicholas D.
Chu, Sean
Krohn, Andrew
Kupunaram, Vineet
Schepelmann, Alexander
Goldman, Daniel I.
Hawkes, Elliot W.
Robotics
Soft Condensed Matter
Most engineered pilings require substantially more force to be driven into the ground than they can resist during extraction. This requires relatively heavy equipment for insertion, which is problematic for anchoring in hard-to-access sites, including in extraterrestrial locations. In contrast, for tree roots, the external reaction force required to extract is much greater than required to insert--little more than the weight of the seed initiates insertion. This is partly due to the mechanism by which roots insert into the ground: tip extension. Proof-of-concept robotic prototypes have shown the benefits of using this mechanism, but a rigorous understanding of the underlying granular mechanics and how they inform the design of a robotic anchor is lacking. Here, we study the terradynamics of tip-extending anchors compared to traditional piling-like intruders, develop a set of design insights, and apply these to create a deployable robotic anchor. Specifically, we identify that to increase an anchor's ratio of extraction force to insertion force, it should: (i) extend beyond a critical depth; (ii) include hair-like protrusions; (iii) extend near-vertically, and (iv) incorporate multiple smaller anchors rather than a single large anchor. Synthesizing these insights, we developed a lightweight, soft robotic, root-inspired anchoring device that inserts into the ground with a reaction force less than its weight. We demonstrate that the 300 g device can deploy a series of temperature sensors 45 cm deep into loose Martian regolith simulant while anchoring with an average of 120 N, resulting in an anchoring-to-weight ratio of 40:1.
title Terradynamics and design of tip-extending robotic anchors
topic Robotics
Soft Condensed Matter
url https://arxiv.org/abs/2511.10901