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Modeling and Simulation of Aerospace Vehicle Dynamics Peter H. Zipfel University of Florida Gainesville, Florida AIAA EDUCATION SERIES J. S. Przemieniecki Series Editor-in-Chief Air Force Institute of Technology Wright-Patterson Air Force Base, Ohio Published by American Institute of Aeronautics and Astronautics, Inc. 1081 Alexander Bell Drive, Reston, AV 20191-4344 American Institute of Aeronautics and Astronautics, Inc., Reston, Virginia 2 3 4 5 Library of Congress Cataloging-in-Publication Data Zipfel, Peter H. Modeling and simulation of aerospace vehicle dynamics / Peter H. Zipfel. p. cm.--(AIAA education series) Includes bibliographical references and index. .1 Aerodynamics-Mathematics. .2 Airplanes-Mathematical models. .3 Space vehicles-Dynamics-Mathematical model. I. Title. II. Series. TL573.Z64 2000 629.132'3'0151~1c21 00-046444 ISBN 1-56347-456-5 (alk. paper) Copyright © 2000 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved. Printed in the United States of America. No part of this publication may be reproduced, distributed, or transmitted, in any form or by any means, or stored in a database or retrieval system, without the prior written permission of the publisher. Data and information appearing in this book are for informational purposes only. AIAA is not responsible for any injury or damage resulting from use or reliance, nor does AIAA warrant that use or reliance will be free from privately owned rights. "To Him who sits on the throne and to the Lamb be praise and honor and glory and power, for ever and ever!" Revelation 5:13b (NIV) AIAA Education Series Editor-in-Chief John S. Przemieniecki Air Force Institute of ygolonhceT (retired) Editorial Board Earl H. Dowell Michael L. Smith Duke University .S.U Air Force Academy Eric J. Jumper Peter J. Turchi University of Notre Dame Ohio State University Robert G. Loewy David M. Van Wie Georgia Institute of ygolonhceT Johns Hopkins University Michael N. Mohaghegh Anthony J. Vizzini The Boeing Company University of Maryland Conrad E Newberry Jerry Wallick Naval Postgraduate School Institute for Defense Analysis Terrence A. Weisshaar Purdue University Foreword Modeling and Simulation of Aerospace elciheV Dynamics by Peter H. Zipfel is an excellent introduction to the important subject of computer modeling and simu- lation of dynamics of aerospace vehicles that in recent years has evolved into a major discipline. This new discipline is used not only in the design process but also in the development and improvement of performance and operation of civil and military aircraft and missiles. The text is divided into two parts: Part 1 Modeling of Flight Dynamics and Part 2 Simulation of Aerospace Vehicles. Part 1 discusses the theoretical concepts that provide mathematical foundation for the simulation of aerospace systems. This includes frames of reference and coordinate systems, kinematics of translation and rotation, translational and attitude dynamics, as well as perturbation techniques used for modeling. In Part 2 the author describes in great detail the various types of simulations for aerospace vehicles for three-, five-, and six-degree-of-freedom systems, including real-time simulators. Many of the AIAA Education Series texts include now either CDs or diskettes for computer programs, problem exercises, and any additional information. This author has introduced a novel approach of providing an Internet service for dis- tributing such materials directly. This additional material for the present text can be obtained from the CADAC Web site, which can be accessed through the AIAA home page (www.aiaa.org) by selecting Market Pulse and then Web Links, where CADAC is listed. The advantage of this approach is obvious: it proves to be an easy avenue for disseminating any future new or updated materials (e.g., new classroom problems for the basic text). In writing this text, the author drew on his many years of experience as an educator at the University of Florida and as a research scientist with the U.S. Army and Air Force. This experience allowed him to produce an out- standing teaching text and a practical reference book on modeling and simulation of aerospace vehicles. The AIAA Education Series of textbooks and monographs, inaugurated in 1984, embraces a broad spectrum of theory and application of different disciplines in aeronautics and astronautics, including aerospace design practice. The series also includes texts on defense science, engineering, and management. The books serve both as teaching texts for students and reference materials for practicing engineers, scientists, and managers. The complete list of textbooks published in the series (over 60 titles) can be found on the end pages of this volume. J. S. Przemieniecki Editor-in-Chief AIAA Education Series Preface The time has come to give an account of modeling and simulation to aerospace students and professionals. What has languished in notebooks, papers, and re- ports should be made available to a wider audience. With modeling and sim- ulation (M&S) penetrating technical disciplines at every level, engineers must understand its role and be able to exploit its strength. If you aspire to acquire a working knowledge of modeling and simulation of aerospace vehicle dynamics, this book is for you. It approaches modeling of flight dynamics in a novel way, covers many types of aerospace vehicles, and gives you hands-on experience with simulations. The genesis of this text goes back to the years when the term M&S was still unknown. The challenges then were as great as today. Every new generation of com- puters was pressed into service as soon as it came on line. With analog computers, we could solve linear differential equations. Later, digital computers empowered us to master also nonlinear differential equations. Concurrently, flight dynam- ics evolved from Etkin's linearized equations to today's dominance of nonlinear equations of motion. As computers became more powerful, the tasks grew more complex. The fidelity of models increased, the number of vehicles multiplied, and coordinate systems abounded. In the late 1960s, as I worked on my dissertation, it became clear that these complex models called for compact computer coding. Matrices are the conduit, and tensors are the theoretical underpinning. Thus evolved the invariant modeling of flight dynamics, my contribution to M&S. In the late 1970s, I began to teach this approach at the University of Florida. What was first called "Advanced Flight Mechanics I and Ir' became in the 1990s "Modeling and Simulation of Aerospace Vehicles" In the meantime, as I worked for the U.S. Army and Air Force, I had the opportunity to apply these techniques to rockets, missiles, aircraft, and spacecraft. Thus matured the two tracks of this book: invariant modeling of flight dynamics and computer simulations of aerospace vehicles theory and praxis. The first part lays out the mathematical foundation of modeling with Cartesian tensors, matrices, and coordinate systems. Replacing the ordinary time derivative with the rotational time derivative and using the Euler transformation of frames enables the formu- lation of the equations of motions in tensor form, invariant under time-dependent coordinate transformations. Newton's law yields the translational equations, and Euler's law produces the attitude equations. Perturbation equations and aerody- namic derivatives complete the modeling of flight dynamics. The second part applies these concepts to aerospace vehicles. Simple three degree-of-freedom (three-DoF) trajectory simulations are built for hypersonic air- craft, rockets, and single-stage-to-orbit vehicles. Adding two attitude degrees of freedom forms the five-degree-of-freedom (five-DoF) simulations. Cruise missiles, xiii xiv air intercept missiles, and aircraft simulations are introduced with flight controllers and guidance and navigation systems, culminating with six-degree-of-freedom (six-DoF) simulations of hypersonic aircraft, and missiles. Their components are modeled in greater detail. Aerodynamics, autopilots, actuators, inertial navigation systems, and seekers are matched with the full translational and attitude equations of motion. Real-time flight simulators and a glimpse at wargames round out the second part. The aerospace vehicles discussed in this book find their actualization in the computer code stored on the CADAC Web site, which can be accessed through the AIAA home page (www.aiaa.org). Under the category Market Pulse, select Web Links to find CADAC among a list of Aerospace-related links. There you can locate eight complete simulations and four data sets for your own projects. The download is free of charge. I chose the Internet over the CD-ROM media because software is ever changing. A CD-ROM is stale and would be outdated at the time of publication, whereas the Web site is being updated periodically. You can use the book in a formal class environment, or, with proper motivation, for self-study; some of you experts may just keep it as a reference manual. The following table gives suggestions for a one- or two-semester course. Chapters 2-7 can serve as a comprehensive study of flight dynamics with the complete nonlinear and linearized equations of motion. It could be followed by a second semester of immersion into flight vehicle simulations, using Chapters 8-11. If the students already have a solid foundation in flight dynamics, one semester could be devoted to just flight simulations, preceded by some familiarization with the notation. Frequently, I use a third option. During a three-credit-hour course, I cover the essentials of modeling, Chapters 2-6, and introduce the students to simple simula- tions in a two-hour lab that meets every other week. The CADAC Primer, Appendix B, jumpstarts the computer orientation. Once Newton's law has been discussed, the students are prepared to work one of the projects of Chapters 8 or 9. For those who want to pursue six-DoF simulations in independent study, I assign Chapter 10 and one of its projects. A similar path can be chosen for self-study. Suggestions for a one-/two-semester course One semester Chapter 1st semester 2nd semester with lab )1 Overview Introductory reading Part 1 2) Mathematical concepts )3 Coordinate systems Course in flight 4) Kinematics Lecture dynamics 5) Translational equations )6 Attitude equations )7 Perturbation equations Optional study Part 2 )8 Three DoF simulations Training in Lab 9) Five DoF simulations flight-vehicle )01 Six DoF simulations simulations Independent study 11) Real-time simulations Optional reading XV The problems at the end of each chapter are more than just exercises. Most of them relate to applications found in aerospace simulations. Within each chapter they increase in difficulty while also keeping pace with the development of the material. Some of them, labeled "Projects," are quite time consuming. Particularly the problems of Chapters 8-10 are better suited as semester projects. They chal- lenge you to work with actual computer code and explore new designs. I trust the troika of instructional text, realistic problems, and prototype simulations delivers to you a complete learning environment. I teach the course to aerospace (AE), operations research (OR), and electrical engineering (EE) students at the graduate level. Once in a while even a physicist may attend. The AE students come prepared with the prerequisite of a stability and control course, and the EE students, majoring in control systems, succeed also if they are willing to study the plant-to-be-controlled through some additional read- ing. Even physicists manage to make honorable grades. Part 1 can also be taught at the advanced undergraduate level, after the students have had an introductory course in dynamics. Part 2 requires some specialized knowledge in subsystem tech- nologies. Particularly, Chapter 10 assumes familiarity with aerodynamics, classical and modem control, and stochastic effects. If you are a practicing engineer in the aerospace industry, you should be able to master the book even without a tutor. I am indebted to my teachers Hermann Stuemke and Bertrand Fang who stirred in me the enthusiasm for flight mechanics and modeling techniques with tensors and matrices. My students are always an inspiration to me with their probing questions. Hopefully, they will find all the answers here. I must name four of them for their diligent review of the manuscript: Becky Hundley, Phil Webb, Chris Dennison, and Vy Nguyen. They rose to the challenge to spill red ink over the professor's work for the promise of better grades. Pat Sforza, my director, at the Research Center, was always ready with encouragement and useful suggestions. I thank him and 1A Baker, my faithful colleague over two decades, for their cover- to-cover review of the manuscript. I extend also my thanks to Lynn Deibler, who reviewed the sections on radars and electro-optical sensors and made sure that I would not mistreat the radar range equation. The members of my family were my cheerleaders. My daughter Heidi baked a bountiful supply of German Lebkuchen as "brain food" and my daughter Erika provided the champagne for our celebrations. Giving his dad some sorely needed advice, Jacob refereed the usage of the English language so that it would not come across like a German translation. Above all, my wife Barbara sustained me with her humor, despite my neglecting our nightly chess game. Peter H. Zipfel August 2000 List of Acronyms AGL advanced guidance law AMRAAM advanced medium range air-to-air missile ARDC Air Research and Development Command ASRAAM advanced short-range air-to-air missile BOGAG bunch of guys and gals BVR beyond visual range c.g. center of gravity center of mass c.m. CAD computer aided design CADAC Computer Aided Design of Aerospace Concepts CEO chief executive officer CEP circular error probable CIC close-in combat CRT cathode ray tube DEP deflection error probable DIS distributed interactive simulation DoF degrees of freedom EO electro-optical GPS global positioning system HIL hardware-in-the-loop HLA high level architecture IMU inertial measuring unit INS inertial navigation system IP initial point IR infrared ISO International Standards Organization LAR launch acceptable region LOA line-of-attack LOS line-of-sight M&S modeling and simulation MC Monte Carlo MOI moment of inertia MRAAM medium range air-to-air missile MRE mean error probable NASP National Aerospace Plane NOAA National Oceanographic and Atmospheric Agency PN proportional navigation RCS reaction control system RF radio frequency S/N signal to noise ratio xix XX SRAAM short-range air-to-air missile SSTO single stage to orbit TF/OA terrain following/obstacle avoidance TM transformation matrix TVC thrust vector control wrt with respect to WVR within visual range

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This book unifies all aspects of flight dynamics for the efficient development of aerospace vehicle simulations. It provides the reader with a complete set of tools to build, program, and execute simulations. Unlike other books, it uses tensors for modeling flight dynamics in a form invariant under
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