Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response

Komal Chawla; Vlastimil Kunc; Ahmed A. Hassen; Zhenpeng Xu; Xiaoyu Zheng; Pum Kim

doi:10.1117/12.3053520

Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response

Komal Chawla, Vlastimil Kunc, Ahmed A. Hassen, Zhenpeng Xu, Xiaoyu Zheng, Pum Kim

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

We present a novel approach to design an automotive bumper energy absorber using carbon fiber reinforced polymer composites, optimized to meet conflicting performance requirements for two distinct impact scenarios. The design must satisfy both a low-speed (2.5 mph) pendulum intrusion test, simulating vehicle-to-vehicle collisions, and a high-speed (25 mph) leg flexion test, replicating pedestrian impacts. These tests demand opposing deformation characteristics: high flexibility (deformation < 85 mm) for the former and high stiffness (deformation < 22 mm) for the latter. To address these contradictory requirements, we developed a machine learning (ML) framework for inverse optimization of lattice designs and material selection. Unlike traditional iterative design processes, our ML model directly outputs optimal design parameters and material choices based on target performance inputs. The energy absorber was fabricated using advanced additive manufacturing techniques, including extrusion deposition and digital light processing. The integration of carbon fibers provides multifunctionality to the bumper structure, enabling self-sensing capabilities through changes in electrical resistivity under compression. This electrical response demonstrates high repeatability under multiple cycles at 2% compression and exhibits distinct signatures during crack formation under high deformation. This research offers adaptive performance through innovative design methodologies and smart material integration. The approach has potential applications in various fields requiring adaptive energy absorption and real-time structural health monitoring.

Original language	English
Title of host publication	Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX
Editors	Tzuyang Yu, Andrew L. Gyekenyesi, Peter J. Shull, H. Felix Wu
Publisher	SPIE
ISBN (Electronic)	9781510686588
DOIs	https://doi.org/10.1117/12.3053520
State	Published - 2025
Event	Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX 2025 - Vancouver, Canada Duration: Mar 17 2025 → Mar 20 2025

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	13436
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX 2025
Country/Territory	Canada
City	Vancouver
Period	03/17/25 → 03/20/25

Funding

The research is sponsored by the Vehicle Technologies Office in the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Industrial Technologies Program, under contract DE-AC05-00OR22725 with UT-Battelle, LLC. This work was a collaborative effort involving teams from Oak Ridge National Laboratory (ORNL), the University of California, Berkeley (UCB), and Ford Motor Company. We extend our gratitude to D. Pokkalla, N. Garg, T. Smith, B. Rodriguez, and A. Hassen from ORNL; X. Zheng and D. Yao from UCB; and E. Lee, I. Farooq, and M. Rebandt from Ford Motor for their valuable contributions.

Keywords

additive manufacturing
carbon fibers
energy absorption
Machine learning for design
multifunctional composites
self-sensing

Access to Document

10.1117/12.3053520

Cite this

Chawla, K., Kunc, V., Hassen, A. A., Xu, Z., Zheng, X., & Kim, P. (2025). Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response. In T. Yu, A. L. Gyekenyesi, P. J. Shull, & H. F. Wu (Eds.), Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX Article 134360M (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13436). SPIE. https://doi.org/10.1117/12.3053520

Chawla, Komal ; Kunc, Vlastimil ; Hassen, Ahmed A. et al. / Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response. Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX. editor / Tzuyang Yu ; Andrew L. Gyekenyesi ; Peter J. Shull ; H. Felix Wu. SPIE, 2025. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{575b6ddc8a724a7d94a157c0b544d1b1,

title = "Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response",

abstract = "We present a novel approach to design an automotive bumper energy absorber using carbon fiber reinforced polymer composites, optimized to meet conflicting performance requirements for two distinct impact scenarios. The design must satisfy both a low-speed (2.5 mph) pendulum intrusion test, simulating vehicle-to-vehicle collisions, and a high-speed (25 mph) leg flexion test, replicating pedestrian impacts. These tests demand opposing deformation characteristics: high flexibility (deformation < 85 mm) for the former and high stiffness (deformation < 22 mm) for the latter. To address these contradictory requirements, we developed a machine learning (ML) framework for inverse optimization of lattice designs and material selection. Unlike traditional iterative design processes, our ML model directly outputs optimal design parameters and material choices based on target performance inputs. The energy absorber was fabricated using advanced additive manufacturing techniques, including extrusion deposition and digital light processing. The integration of carbon fibers provides multifunctionality to the bumper structure, enabling self-sensing capabilities through changes in electrical resistivity under compression. This electrical response demonstrates high repeatability under multiple cycles at 2\% compression and exhibits distinct signatures during crack formation under high deformation. This research offers adaptive performance through innovative design methodologies and smart material integration. The approach has potential applications in various fields requiring adaptive energy absorption and real-time structural health monitoring.",

keywords = "additive manufacturing, carbon fibers, energy absorption, Machine learning for design, multifunctional composites, self-sensing",

author = "Komal Chawla and Vlastimil Kunc and Hassen, \{Ahmed A.\} and Zhenpeng Xu and Xiaoyu Zheng and Pum Kim",

note = "Publisher Copyright: {\textcopyright} 2025 SPIE.; Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX 2025 ; Conference date: 17-03-2025 Through 20-03-2025",

year = "2025",

doi = "10.1117/12.3053520",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Tzuyang Yu and Gyekenyesi, \{Andrew L.\} and Shull, \{Peter J.\} and Wu, \{H. Felix\}",

booktitle = "Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX",

}

Chawla, K , Kunc, V , Hassen, AA, Xu, Z, Zheng, X & Kim, P 2025, Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response. in T Yu, AL Gyekenyesi, PJ Shull & HF Wu (eds), Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX., 134360M, Proceedings of SPIE - The International Society for Optical Engineering, vol. 13436, SPIE, Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX 2025, Vancouver, Canada, 03/17/25. https://doi.org/10.1117/12.3053520

Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response. / Chawla, Komal ; Kunc, Vlastimil ; Hassen, Ahmed A. et al.
Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX. ed. / Tzuyang Yu; Andrew L. Gyekenyesi; Peter J. Shull; H. Felix Wu. SPIE, 2025. 134360M (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13436).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response

AU - Chawla, Komal

AU - Kunc, Vlastimil

AU - Hassen, Ahmed A.

AU - Xu, Zhenpeng

AU - Zheng, Xiaoyu

AU - Kim, Pum

PY - 2025

Y1 - 2025

N2 - We present a novel approach to design an automotive bumper energy absorber using carbon fiber reinforced polymer composites, optimized to meet conflicting performance requirements for two distinct impact scenarios. The design must satisfy both a low-speed (2.5 mph) pendulum intrusion test, simulating vehicle-to-vehicle collisions, and a high-speed (25 mph) leg flexion test, replicating pedestrian impacts. These tests demand opposing deformation characteristics: high flexibility (deformation < 85 mm) for the former and high stiffness (deformation < 22 mm) for the latter. To address these contradictory requirements, we developed a machine learning (ML) framework for inverse optimization of lattice designs and material selection. Unlike traditional iterative design processes, our ML model directly outputs optimal design parameters and material choices based on target performance inputs. The energy absorber was fabricated using advanced additive manufacturing techniques, including extrusion deposition and digital light processing. The integration of carbon fibers provides multifunctionality to the bumper structure, enabling self-sensing capabilities through changes in electrical resistivity under compression. This electrical response demonstrates high repeatability under multiple cycles at 2% compression and exhibits distinct signatures during crack formation under high deformation. This research offers adaptive performance through innovative design methodologies and smart material integration. The approach has potential applications in various fields requiring adaptive energy absorption and real-time structural health monitoring.

AB - We present a novel approach to design an automotive bumper energy absorber using carbon fiber reinforced polymer composites, optimized to meet conflicting performance requirements for two distinct impact scenarios. The design must satisfy both a low-speed (2.5 mph) pendulum intrusion test, simulating vehicle-to-vehicle collisions, and a high-speed (25 mph) leg flexion test, replicating pedestrian impacts. These tests demand opposing deformation characteristics: high flexibility (deformation < 85 mm) for the former and high stiffness (deformation < 22 mm) for the latter. To address these contradictory requirements, we developed a machine learning (ML) framework for inverse optimization of lattice designs and material selection. Unlike traditional iterative design processes, our ML model directly outputs optimal design parameters and material choices based on target performance inputs. The energy absorber was fabricated using advanced additive manufacturing techniques, including extrusion deposition and digital light processing. The integration of carbon fibers provides multifunctionality to the bumper structure, enabling self-sensing capabilities through changes in electrical resistivity under compression. This electrical response demonstrates high repeatability under multiple cycles at 2% compression and exhibits distinct signatures during crack formation under high deformation. This research offers adaptive performance through innovative design methodologies and smart material integration. The approach has potential applications in various fields requiring adaptive energy absorption and real-time structural health monitoring.

KW - additive manufacturing

KW - carbon fibers

KW - energy absorption

KW - Machine learning for design

KW - multifunctional composites

KW - self-sensing

UR - https://www.scopus.com/pages/publications/105014755595

U2 - 10.1117/12.3053520

DO - 10.1117/12.3053520

M3 - Conference contribution

AN - SCOPUS:105014755595

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX

A2 - Yu, Tzuyang

A2 - Gyekenyesi, Andrew L.

A2 - Shull, Peter J.

A2 - Wu, H. Felix

PB - SPIE

T2 - Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX 2025

Y2 - 17 March 2025 through 20 March 2025

ER -

Chawla K , Kunc V , Hassen AA, Xu Z, Zheng X, Kim P. Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response. In Yu T, Gyekenyesi AL, Shull PJ, Wu HF, editors, Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XIX. SPIE. 2025. 134360M. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.3053520

Machine learning-driven design and self-sensing capabilities of automotive bumper lattices for adaptive impact response

Abstract

Publication series

Conference

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Cite this