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Cyber-Physical Systems Virtual Organization
Read-only archive of site from September 29, 2023.
CPS-VO
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Projects
CPS/Synergy/Collaborative Research: Cybernizing Mechanical Structures through Integrated Sensor-Structure Fabrication
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Submitted by Yu Ding on Sat, 09/24/2016 - 3:55pm
Project Details
Lead PI:
Yu Ding
Performance Period:
01/01/16
-
12/31/18
Institution(s):
Texas A&M Engineering Experiment Station
Sponsor(s):
National Science Foundation
Award Number:
1545038
1007 Reads. Placed 377 out of 804 NSF CPS Projects based on total reads on all related artifacts.
Abstract:
The timely and accurate in-service identification of faults in mechanical structures, such as airplanes, can play a vitally important role in avoiding catastrophes. One major challenge, however, is that the sensing system relies on high frequency signals, the coordination of which is difficult to achieve throughout a large structure. To tackle this fundamental issue, the research team will take advantage of 3D printing technology to fabricate integrated sensor-structure components. Specifically, the team plans to innovate a novel printing scheme that can embed piezoelectric transducers (namely, sensor/actuator coupled elements) into layered composites. As the transducers are densely distributed throughout the entire structure, they function like a nerve system embedded into the structure. Such a sensor nerve system, when combined with new control and command systems and advanced data and signal processing capability, can fully unleash the latest computing power to pinpoint the fault location. The new framework of utilizing emerging additive manufacturing technology to produce a structural system with integrated, densely distributed active sensing elements will potentially lead to paradigm-shifting progress in structural self-diagnosis. This advancement may allow the acquisition of high-quality, active interrogation data throughout the entire structure, which can then be used to facilitate highly accurate and robust decision-making. It will lead to intellectual contributions including: 1) development of a new sensing modality with mechanical-electrical dual-field adaptivity, that yields rich and high-quality data throughout the structure; 2) design of an additive manufacturing scheme that inserts piezoelectric micro transducer arrays throughout the structure to enable active interrogation; and 3) formulation of new data analytics and inverse analysis that can accurately identify the fault location/severity and guide the fine-tuning of the sensor system.
Related Artifacts
Posters
Cybernizing Mechanical Structures Through Integrated Sensor-Structure Fabrication
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Cybernizing Mechanical Structures Through Integrated Sensor-Structure Fabrication
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CPS/Synergy/Collab: CybernizingMechanical Structures through Integrated Sensor-Structure Fabrication–The Data Science Aspects
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Publications
Unsupervised anomaly detection based on minimum spanning tree approximated distance measures and its application to hydropower turbines
Local calibration of computer experiments
Guided undersampling using ensemble filtering and normalized cuts for imbalanced data classification
Sequential design for functional calibration of computer models
Videos
CPS/Synergy/Collaborative Research: Cybernizing mechanical structures through integrated sensor-structure fabrication
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CPS/Synergy/Collaborative Research: Cybernizing mechanical structures through integrated sensor-structure fabrication
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CPS Domains
3-D Printing
Wireless Sensing and Actuation
Manufacturing
CPS Technologies