LEARNING OBJECTIVES / OUTLINE

• Learn about the fundamentals of the Periodic structure theory.
• Learn how to predict the natural frequencies of periodically stiffened beams and plates.
• Learn how to predict the response and sound transmission through a periodically stiffened structure exposed to a convected pressure field, e.g., an acoustic plane wave or a turbulent boundary layer pressure fluctuation.
• Learn how to combine the Finite Element Method (FEM) with the Periodic Structure (PS) theory for prediction of the structural-acoustic natural frequencies and response of an aircraft fuselage section in a cost-effective manner, compared to application of traditional FEM.
• Learn about Intrinsic Structural Tuning to reduce the structural-acoustic response of a periodically stiffened structure.
• Learn about the effects of deviations from periodicity.
• Learn how to predict the flutter characteristics of a periodic structure exposed to a supersonic flow.
• Learn about examples of other applications, e.g., vibration of circular rings on periodic support, wave propagation in a periodically supported pipe carrying fluid, vibration of heat exchanger tube banks of nuclear reactors, application to composite materials, dynamics of rotationally periodic structures, vibration control of periodic railroad tracks etc.

WHO SHOULD ATTEND

Aerospace Engineers, Professors and graduate students involved in design and vibration analysis of stiffened structures subjected to dynamic excitations e.g., jet noise and boundary layer turbulence excitations, supersonic or hypersonic flow, structural dynamics, acoustics and aeroelasticity.

COURSE FEES (Sign-In To Register)

- AIAA Member Price: $995 USD

- Non-Member Price: $1195 USD

- AIAA Student Member Price: $495 USD

INSTRUCTOR

Dr. Gautam SenGupta received his PhD from the University of Southampton (UK), where he developed a unique method for predicting the natural frequencies of periodic structures. He worked as a Specialist Engineer in Acoustic Fatigue at the Royal Aeronautical Society of England, and at NASA-Langley as a Research Associate. He joined Boeing in 1973, where he applied the Periodic Structure Theory to predict and control the structural acoustic characteristics of an airplane fuselage in a cost-effective manner. He retired in 2016 as a Technical Fellow of the Boeing Company in Seattle, where he was also involved in developing methods for predicting airframe noise, and transonic flutter characteristics of airplanes. He is an Affiliate Professor at the University of Washington, where he teaches courses on Structural Dynamics and related subjects.

Classroom Hours / CEUs: 24 classroom hours /2.4 CEU/PDH

COURSE DELIVERY AND MATERIALS

• The course lectures will be delivered via Zoom. Access to the Zoom classroom will be provided to registrants near to the course start date.
• All sessions will be available on-demand within 1-2 days of the lecture. Once available, you can stream the replay video anytime, 24/7.
• All slides will be available for download after each lecture. No part of these materials may be reproduced, distributed, or transmitted, unless for course participants. All rights reserved.
• Recommended, optional textbook for purchase at a discount: Vibration of Periodic Structures - 1st Edition
• Between lectures during the course, the instructor(s) will be available via email for technical questions and comments.

Cancellation Policy: A refund less a $50.00 cancellation fee will be assessed for all cancellations made in writing prior to 5 days before the start of the event. After that time, no refunds will be provided.

Contact:  Please contact Lisa Le  or Customer Service if you have any questions about the course or group discounts.

Frequently Asked Questions