PhD Defense by Matteo Carrara

Event Details
  • Date/Time:
    • Friday December 11, 2015 - Saturday December 12, 2015
      3:00 pm - 4:59 pm
  • Location: Montgomery Knight Building, Room 317
  • Phone:
  • URL:
  • Email:
  • Fee(s):
  • Extras:
No contact information submitted.

Summary Sentence: Fourier-based Design of Acoustic Transducers

Full Summary: No summary paragraph submitted.

Ph.D. Thesis Defense


Matteo Carrara

Advisor: Dr. Massimo Ruzzene

Friday, December 11th, 2015 11:00 AM

Montgomery Knight Building, Room 317


Fourier-based Design of Acoustic Transducers

The work presented in this thesis investigates novel transducers implementations that take advantage of directional sensing and generation of acoustic waves. These transducers are conceived by exploiting a Fourier-based design methodology. The proposed devices find application in the broad field of Structural Health Monitoring (SHM), which is a very active research area devoted to the assessment of the structural integrity of critical components in aerospace, civil and mechanical systems. Among SHM schemes, Guided Waves (GWs) testing has emerged as a prominent option for inspection of plate-like structures using permanently attached piezoelectric transducers.

GWs-based methods rely on the generation and sensing of elastic waves to evaluate structural integrity. They offer an effective method to estimate location, severity and type of damage. It is widely acknowledged among the GWs-SHM community that effective monitoring of structural health is facilitated by sensors and actuators designed with ad hoc engineered capabilities. The objective of this research is to design innovative piezoelectric transducers by specifying their electrode patterns in the Fourier domain. Taking advantage of the Fourier framework, transducer design procedures are outlined and tailored to relevant SHM applications, such as (i) directional actuation and sensing of GWs, (ii) simultaneous sensing of multiple strain components with a single device, and (iii) estimation of the location of impact sites on structural components. The proposed devices enable significant reductions in cost, hardware, and power requirements for advanced SHM schemes when compared to current technologies.


Committee members:

Dr. Massimo Ruzzene (AE)

Dr. Julian J. Rimoli (AE)

Dr. Min-Feng Yu (AE)

Dr. Alper Erturk (ME)

Dr. Karim Sabra (ME)


Additional Information

In Campus Calendar

Graduate Studies

Invited Audience
Phd Defense
  • Created By: Tatianna Richardson
  • Workflow Status: Published
  • Created On: Dec 4, 2015 - 10:04am
  • Last Updated: Oct 7, 2016 - 10:15pm