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March 26-28, 2012 Columbia, Maryland May 1-3, 2012 Laurel, Maryland $1795 (8:30am - 4:00pm) Register 3 or More & Receive $100 00 Each Off The Course Tuition. Summary This three-day short course covers the fundamentals of missile design, development, and system engineering. The course provides a system-level, integrated method for missile aerodynamic configuration/propulsion design and analysis. It addresses the broad range of alternatives in meeting cost, performance and risk requirements. The methods presented are generally simple closed-form analytical expressions that are physics-based, to provide insight into the primary driving parameters. Configuration sizing examples are presented for rocketpowered, ramjet-powered, and turbo-jet powered baseline missiles. Typical values of missile parameters and the characteristics of current operational missiles are discussed as well as the enabling subsystems and technologies for missiles and the current/projected state-of-the-art. Sixty-six videos illustrate missile development activities and missile performance. Daily roundtable discussion. Attendees will vote on the relative emphasis of the material to be presented. Attendees receive course notes as well as the textbook, Tactical Missile Design, 2nd edition. Instructor Eugene L. Fleeman has 47 years of government, industry, academia, and consulting experience in missile system and technology development. Formerly a manager of missile programs at Air Force Research Laboratory, Rockwell International, Boeing, and Georgia Tech, he is an international lecturer on missiles and the author of over 100 publications, including the AIAA textbook, Tactical Missile Design. 2nd Ed. What You Will Learn • Key drivers in the missile design and system engineering process. • Critical tradeoffs, methods and technologies in subsystems, aerodynamic, propulsion, and structure sizing. • Launch platform-missile integration. • Robustness, lethality, guidance navigation & control, accuracy, observables, survivability, reliability, and cost considerations. • Missile sizing examples. • Missile development process. Who Should Attend The course is oriented toward the needs of missile engineers, systems engineers, analysts, marketing personnel, program managers, university professors, and others working in the area of missile systems and technology development. Attendees will gain an understanding of missile design, missile technologies, launch platform integration, missile system measures of merit, and the missile system development process. Missile System Design Video! www.aticourses.com/tactical_missile_design.htm Course Outline 1. Introduction/Key Drivers in the Missile Design and System Engineering Process: Overview of missile design process. Examples of system-of-systems integration. Unique characteristics of missiles. Key aerodynamic configuration sizing parameters. Missile conceptual design synthesis process. Examples of processes to establish mission requirements. Projected capability in command, control, communication, computers, intelligence, surveillance, reconnaissance (C4ISR). Example of Pareto analysis. Attendees vote on course emphasis. 2. Aerodynamic Considerations in Missile Design and System Engineering: Optimizing missile aerodynamics. Shapes for low observables. Missile configuration layout (body, wing, tail) options. Selecting flight control alternatives. Wing and tail sizing. Predicting normal force, drag, pitching moment, stability, control effectiveness, lift-to-drag ratio, and hinge moment. Maneuver law alternatives. 3. Propulsion Considerations in Missile Design and System Engineering: Turbojet, ramjet, scramjet, ducted rocket, and rocket propulsion comparisons. Turbojet engine design considerations, prediction and sizing. Selecting ramjet engine, booster, and inlet alternatives. Ramjet performance prediction and sizing. High density fuels. Solid propellant alternatives. Propellant grain cross section trade-offs. Effective thrust magnitude control. Reducing propellant observables. Rocket motor performance prediction and sizing. Motor case and nozzle materials. 4. Weight Considerations in Missile Design and System Engineering: How to size subsystems to meet flight performance requirements. Structural design criteria factor of safety. Structure concepts and manufacturing processes. Selecting airframe materials. Loads prediction. Weight prediction. Airframe and motor case design. Aerodynamic heating prediction and insulation trades. Dome material alternatives and sizing. Power supply and actuator alternatives and sizing. 5. Flight Performance Considerations in Missile Design and System Engineering: Flight envelope limitations. Aerodynamic sizing-equations of motion. Accuracy of simplified equations of motion. Maximizing flight performance. Benefits of flight trajectory shaping. Flight performance prediction of boost, climb, cruise, coast, steady descent, ballistic, maneuvering, and homing flight. 6. Measures of Merit and Launch Platform Integration / System Engineering: Achieving robustness in adverse weather. Seeker, navigation, data link, and sensor alternatives. Seeker range prediction. Counter-countermeasures. Warhead alternatives and lethality prediction. Approaches to minimize collateral damage. Fusing alternatives and requirements for fuze angle and time delay. Alternative guidance laws. Proportional guidance accuracy prediction. Time constant contributors and prediction. Maneuverability design criteria. Radar cross section and infrared signature prediction. Survivability considerations. Insensitive munitions. Enhanced reliability. Cost drivers of schedule, weight, learning curve, and parts count. EMD and production cost prediction. Designing within launch platform constraints. Internal vs. external carriage. Shipping, storage, carriage, launch, and separation environment considerations. Launch platform interfaces. Cold and solar environment temperature prediction. 7. Sizing Examples and Sizing Tools: Trade-offs for extended range rocket. Sizing for enhanced maneuverability. Developing a harmonized missile. Lofted range prediction. Ramjet missile sizing for range robustness. Ramjet fuel alternatives. Ramjet velocity control. Correction of turbojet thrust and specific impulse. Turbojet missile sizing for maximum range. Turbojet engine rotational speed. Computer aided sizing tools for conceptual design. Soda straw rocket design-build-fly competition. House of quality process. Design of experiment process. 8. Missile Development Process: Design validation/technology development process. Developing a technology roadmap. History of transformational technologies. Funding emphasis. Alternative proposal win strategies. New missile follow-on projections. Examples of development tests and facilities. Example of technology demonstration flight envelope. Examples of technology development. New technologies for missiles. 9. Summary and Lessons Learned. 10 – Vol. 111 Register online at www.ATIcourses.com or call ATI at 888.501.2100 or 410.956.8805
Modern Missile Analysis Propulsion, Guidance, Control, Seekers, and Technology March 19-22, 2012 Columbia, Maryland $1890 (8:30am - 4:00pm) Register 3 or More & Receive $100 00 Each Off The Course Tuition. Video! www.aticourses.com/missile_systems_analysis.htm Summary This four-day course presents a broad introduction to major missile subsystems and their integrated performance, explained in practical terms, but including relevant analytical methods. While emphasis is on today’s homing missiles and future trends, the course includes a historical perspective of relevant older missiles. Both endoatmospheric and exoatmospheric missiles (missiles that operate in the atmosphere and in space) are addressed. Missile propulsion, guidance, control, and seekers are covered, and their roles and interactions in integrated missile operation are explained. The types and applications of missile simulation and testing are presented. Comparisons of autopilot designs, guidance approaches, seeker alternatives, and instrumentation for various purposes are presented. The course is recommended for analysts, engineers, and technical managers who want to broaden their understanding of modern missiles and missile systems. The analytical descriptions require some technical background, but practical explanations can be appreciated by all students. Instructor Dr. Walter R. Dyer is a graduate of UCLA, with a Ph.D. degree in Control Systems Engineering and Applied Mathematics. He has over thirty years of industry, government and academic experience in the analysis and design of tactical and strategic missiles. His experience includes Standard Missile, Stinger, AMRAAM, HARM, MX, Small ICBM, and ballistic missile defense. He is currently a Senior Staff Member at the Johns Hopkins University Applied Physics Laboratory and was formerly the Chief Technologist at the Missile Defense Agency in Washington, DC. He has authored numerous industry and government reports and published prominent papers on missile technology. He has also taught university courses in engineering at both the graduate and undergraduate levels. What You Will Learn You will gain an understanding of the design and analysis of homing missiles and the integrated performance of their subsystems. • Missile propulsion and control in the atmosphere and in space. • Clear explanation of homing guidance. • Types of missile seekers and how they work. • Missile testing and simulation. • Latest developments and future trends. Course Outline 1. Introduction. Brief history of Missiles. Types of guided missiles. Introduction to ballistic missile defense. - Endoatmospheric and exoatmospheric missile operation. Missile basing. Missile subsystems overview. Warheads, lethality and hit-to-kill. Power and power conditioning. 2. Missile Propulsion. The rocket equation. Solid and liquid propulsion. Single stage and multistage boosters. Ramjets and scramjets. Axial propulsion. Divert and attitude control systems. Effects of gravity and atmospheric drag. 3. Missile Airframes, Autopilots And Control. Phases of missile flight. Purpose and functions of autopilots. Missile control configurations. Autopilot design. Open-loop autopilots. Inertial instruments and feedback. Autopilot response, stability, and agility. Body modes and rate saturation. Roll control and induced roll in high performance missiles. Radomes and their effects on missile control. Adaptive autopilots. Rolling airframe missiles. 4. Exoatmospheric Missiles For Ballistic Missile Defense. Exoatmospheric missile autopilots, propulsion and attitude control. Pulse width modulation. Exoatmospheric missile autopilots. Limit cycles. 5. Missile Guidance. Seeker types and operation for endo- and exo-atmospheric missiles. Passive, active and semi active missile guidance. Radar basics and radar seekers. Passive sensing basics and passive seekers. Scanning seekers and focal plane arrays. Seeker comparisons and tradeoffs for different missions. Signal processing and noise reduction 6. Missile Seekers. Boost and midcourse guidance. Zero effort miss. Proportional navigation and augmented proportional navigation. Biased proportional navigation. Predictive guidance. Optimum homing guidance. Guidance filters. Homing guidance examples and simulation results. Miss distance comparisons with different homing guidance laws. Sources of miss and miss reduction. Beam rider, pure pursuit, and deviated pursuit guidance. 7. Simulation And Its Applications. Current simulation capabilities and future trends. Hardware in the loop. Types of missile testing and their uses, advantages and disadvantages of testing alternatives. Register online at www.ATIcourses.com or call ATI at 888.501.2100 or 410.956.8805 Vol. 111 – 11
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