Practical Design Methods for Aircraft and Rotorcraft Flight Control for Conventional Civil/Military, UAV, and AAM Applications with Hands-on Training using CONDUIT® – Online Short Course (Dec 9 – 12, 2024) 9 December - 12 December 2024 Online

COURSE OUTLINE

• Section 1. Introduction: The Flight Control Problem and Our Approach
  • Roles of Flight Control System and the Development Process
  • Flight Control System Design Challenges and Reference Material–Seven Key Do’s
  • Flight Control System Design Using Multi-Objective Parametric Optimization: Why is this a Good Approach?
• Section 2. Fundamentals of Control System Design Methodology Based on Multi-Objective Parametric Optimization
  • Roadmap of Multi-Objective Parametric Optimization Design Methodology
  • Typical Results Based on XV-15 Hover Case Study
  • Typical Results Based on XV-15 Forward Flight Case Study
• Section 3. Overview of CONDUIT® Software
  • The CONDUIT® Interface, Overview of CONDUIT® Workflow
  • Problem Setup, Modes of Operation, and Integration with Other Tools
• Section 4. Description of XV-15 Design Case Studies
  • XV-15 Hover and Forward Flight Case Studies
• Section 5. Quantitative Design Requirements for Flight Control
  • Importance and Sources of Design Requirements and the Cooper-Harper Scale
  • Specifications: Generic, Rotorcraft, Fixed-Wing, User Defined, and Performance Metrics
  • Flight control criteria for next generation high-speed military rotorcraft
  • Criteria Sets for XV-15 Hover and Forward Flight Case Studies
• Section 6. Simulation Requirements for Flight Control Design
  • Modeling Fidelity Requirements and Use of a Simplified Block Diagram
  • Linear Bare-Airframe Models, Additional Components, Nonlinearities and Analysis Validation
• Section 7. Conceptual and Preliminary Design of Flight Control Systems
  • Control Law Architectures
  • Preliminary Design of Feedback Compensation
• Section 8. Design Optimization
  • Need and Challenge of Numerical Optimization of Flight Control Design
  • Numerical Scores for the Specifications and Numerical Optimization of the Design
  • Guidelines for Flight Control Optimization Results for the XV-15 Hover and Forward Flight Case Studies
• Section 9. Sensitivity and Robustness Analyses
  • Sensitivity Analysis of the Design Solution and results for XV-15 Hover and Forward Flight
  • Assessing Robustness to Modeling Uncertainty
• Section 10. Design Trade-offs
  • Design Margin Optimization (DMO)
  • Nested-Loop Design Margin Optimization Strategy for the XV-15 Hover and Forward Flight
• Section 11. UH-60 FBW Flight Control Design Case Study using CONDUIT®: Flight Test Comparison of Alternate Strategies for Multi-Loop Control Law Optimization
  • Description of explicit model follow control system and design
  • Flight test validation of analysis model
  • Inner-Loop and Outer Loop Design Margin Optimization and flight test results
• Section 12. Optimization and Piloted Simulation Evaluation of Full-Flight Envelope Longitudinal Control Laws for a Business Jet
  • Aircraft Model, Control Laws, Specifications
  • Optimization Strategy and Results, Handling-Qualities Evaluation
• Section 13.Alternative Design Methods and Results for XV-15 Test Case using CONDUIT®
  • Liner-quadratic design method
  • Explicit model-following design method
  • Dynamic inversion design method
  • H∞mixed-sensitivity design method
  • Design comparisons
• Section 14. CONDUIT® Case Studies of UAV based on legacy rotorcraft, and eCTOL and eVTOL applications to surveillance, AAM, package delivery
  • Fixed wing case studies: design specifications, flight test validation, flight test results and comparison with legacy controller, design specification guidance.
  • Rotorcraft case studies: Full scale and small multi-copter configurations, design specifications, piloted simulation studies, flight test validation, flight test results and comparison with legacy controller, design specification guidance.
• Section 15. Research Directions and Upcoming CONDUIT® release features
  • Ongoing and Future Flight Control Research
  • CONDUIT® Upcoming Release Key Features

Course Delivery and Materials

• Zoom Meeting: The classes will be held via Zoom meetings. You can test your connection here: https://zoom.us/test
• Course Materials: All classes will be recorded and available for replay; lecture recordings will be available 1-2 business days after the live lecture occurs. Course notes and student software for hands-on exercises will be available for individual download.
• CIFER® Software: A 2-month Professional version of the CONDUIT® software will be provided for use. To receive the CONDUIT® software, students should register no later than November 13 with their institutional email address (e.g., company, research lab, academic) and not a personal email to ensure enough time for validation and installation. 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.
• eBook: All registrants will receive an eBook copy of the instructors’ AIAA textbook Practical Methods for Aircraft and Rotorcraft Flight Control Design: An Optimization Based Approach (Tischler et al., AIAA, 2017).
• No part of these materials may be reproduced, distributed, or transmitted, unless for course participants. All rights reserved.

Dr. Mark B. Tischler heads “Tischler Aeronautics,” with a focus on providing Engineering Support in Rotorcraft and Aircraft Flight Dynamics and Control. He retired in January 2021 as an Army Senior Technologist (ST) with the US Army Technology Development Directorate – Moffett Field, CA. His over 40-year career includes experience in aerospace industry and government. For 25 years, he led the US Army Flight Control Technology group that conducts handling qualities, flight dynamics and control research on a wide range of fixed-wing and rotary-wing aircraft and unmanned air vehicles (UAVs). Dr. Tischler headed the development of widely used tools for dynamics and control analysis and has been involved in numerous flight-test projects. He has published extensively in this field and is the author of Aircraft and Rotorcraft System Identification: Engineering Methods With Flight Test Examples, 2nd Edition (AIAA 2012), Practical Methods for Aircraft and Rotorcraft Flight Control Design: An Optimization-Based Approach (AIAA 2017), and Advances in Aircraft Flight Control (Ed) (AIAA and Taylor & Francis, 1996). Dr. Tischler has received many major awards for his work over the years. He has the rare distinction of twice receiving the Presidential Rank Award for Distinguished Senior Professional (2009, 2018), the highest recognition presented to public officials. Dr. Tischler received the Department of the Army Distinguished Civilian Service Medal in 2021, the highest award that may be bestowed by the Secretary of the Army for extraordinary contributions as a Senior Research Scientist.