OVERVIEW

This comprehensive course will review the fundamental methods of Manned and UAV aircraft and rotorcraft system identification for determining flight dynamics and control models from test data with Hands-on Training using CIFER®. The course illustrates the benefits of the broad application of system identification throughout the flight vehicle development process and provides the attendees with an intensive hands-on training of the CIFER® interactive system identification software suite using flight-test data and extensive Lab exercises. Each lecture reviews the next step in the system identification process, covering key principles, flight-test methods and typical flight-test results. Then, the student uses the intuitive CIFER® software to conduct this step in a structured Lab Exercise using flight-test data. By the end of the 4-day course, the student will have completed the entire identification process of extracting and verifying a flight dynamics model of a rotorcraft or fixed-wing aircraft from flight-test data using CIFER®. New lecture material covers special considerations and typical system identification results for multi-copters, eVTOL/UAM configurations, how system identification results can be used to validate and update physics-based flight simulation models, and “model stitching” that combines identified point models and trim data into an accurate continuous full-flight envelope simulation. Students receive access to on-line course notes, a copy of the course text authored by the instructor, and access to the CIFER® software. Many presented examples from recent manned and UAV aircraft programs illustrate the effectiveness of this technology for rapidly solving difficult integration problems. The course will review key methods and computational tools but will not be overly mathematical in content.

The key objectives of this course are to: (1) review the fundamental methods of Manned and UAV aircraft and rotorcraft frequency-domain system identification methods and illustrate the benefits of the broad application of this system ID approach throughout the flight vehicle development process; (2) present many case studies and results for a range of aircraft and eVTOL configurations; (3) provide the attendees with comprehensive hands-on training of the CIFER® system identification software using flight test data, 10 Lab exercises that cover the entire process, and a demo copy of the CIFER® software. This requires the student to have a PC laptop running either Windows 10 or Windows 11, or a Mac laptop running macOS 10.14 (Mojave), macOS 10.15 (Catalina), macOS 11 (Big Sur), macOS 12 (Monterey), or macOS 13 (Ventura).

KEY TOPICS

• Overview of system identification methods and applications
• Flight testing and instrumentation for handling-qualities and manned/unmanned control system development
• System ID of manned and UAV aircraft and rotorcraft dynamics and control from flight test data
• Special aspects for system ID of multi-copter eVTOL/UAM configurations
• Model stitching to build an accurate continuous full flight envelope nonlinear model from system ID point models
• Use of system identification results for physics-based simulation model fidelity analysis and improvement
• Many case studies of system identification for a wide range of aircraft and rotorcraft
• Hands-on training in system identification training using CIFER^®
• Over the 4-day course students work 10 comprehensive labs on model identification and verification using flight-test data
• See detailed outline below

AUDIENCE
The course is intended for practicing engineers and students interested in learning the principles and applications of system identification for manned and unmanned aircraft and rotorcraft. The course assumes some basic knowledge of the concepts of dynamics, frequency-responses, transfer functions, and state-space representations. The course is not highly mathematical and no experience with other tools is a prerequisite.

MATERIALS

• 20+ Hours of Recorded Lectures: Stream the 20+ hours of video recordings anytime, 24/7.
• Course Materials: Download over 300 pages of course slides, ten hands-on CIFER® lab exercises, and additional references immediately.
• CIFER® Software: A 2-month Professional version of the CIFER® software will be provided for use. To receive the CIFER® software, students should register with their institutional email address(e.g., company, research lab, academic) and not a personal email. The software administrator will only distribute the CIFER® software to students' institutional email addresses for the students to install and validate. Please note that access to the software is at the discretion of the software distributor, and may be subject to international release limitations. Please submit your institutional email and country of origin to apply for access. Please email Lisa Le, Education Manager, with your registration confirmation and submit your institutional email address and country of origin to request the software.
• No part of these materials may be reproduced, distributed, or transmitted, unless for course participants. All rights reserved.
• Recommended Text: It is recommended to separately purchase the instructor’s AIAA textbook Aircraft and Rotorcraft System Identification: Engineering Methods With Flight Test Examples, 2nd Edition.

CERTIFICATE: Receive an AIAA Course Completion Certificate upon viewing all course recordings under your My Learning/Grades tab. Please contact Lisa Le for questions.