Advances in aerospace science and technology / editors, Parvathy Rajendran, M.Z. Abdullah.

Format:

Book

Contributor:

Rajendran, Parvathy, editor.

Abdullah, M. Z., editor.

Series:

Mechanical engineering theory and applications.

Mechanical Engineering Theory and Applications

Standardized Title:

Advances in aerospace science and technology (New York, N.Y.)

Language:

English

Subjects (All):

Aerospace engineering.

Physical Description:

1 online resource (286 pages).

Place of Publication:

Hauppauge, New York : Nova Science Publishers, Inc., 2017.

Summary:

Editor Biography: Dr. Parvathy has been a lecturer of aerospace engineering at Universiti Sains Malaysia since 2013. She completed her Ph.D. degree in aerospace engineering at Cranfield University, UK, in October 2012. Her research includes UAV design, development, and flight testing and UAV system development and testing. She has served as a systems and flight test engineer in various UAV projects in the UK, and all of these UAVs were successfully flown. Her appointment as the head of System and Design Research Cluster and as the laboratory manager of UAV Laboratory in the School of Aerospace Engineering is further recognition of her credibility. As a young research academician, she has produced numerous high-impact publications. She was appointed by a few international journals as the editor in chief, international advisor, and reviewer board member. She has also served on the technical conference committee of various international conferences. In addition, she has maintained various grants amounting to a total of more than RM 1 million. She has contributed much to the development of human capital. Her active involvement in teaching, research, consultancy, and service to the university and community emphasize her enthusiastic academician nature and her high potential to contribute to the field of aerospace engineering. Book Description: Aerospace science and technology have made remarkable progress in the last century. Although a few publications have been written on this topic, most are inadequate in elucidating the various advanced technologies developed in recent years. For this reason, publishing a book in which prominent researchers elaborate and discuss their research efforts in conjunction with other efforts seems logical. In this book, the most accurate and current materials were gathered, reviewed, and presented by an exceptional group of experts. This book presents state-of-the-art, current developments and applications in aerospace. This is an edited book composed of the following chapters: *Chapter One: Aeroelasticity: An Overview *Chapter Two: Nanocomposites in Aerospace Structure *Chapter Three: Fire Structural Behavior of Aerospace Composites *Chapter Four: Implementation of Biofuel in Aircraft Engines *Chapter Five: Aircraft Mission Profile Analysis and Trajectory Optimization *Chapter Six: Controller Design for a Hybrid UAV *Chapter Seven: Magnetic Attitude Control of a Small Satellite *Chapter Eight: CubeSat Technology in Satellite Development *Chapter Nine: Ionosphere Perturbation Modeling in an Equatorial Region through Electromagnetic Wave Propagation *Chapter Ten: Computer Simulation of Membrane Airfoil with Fluid/Structure Interaction Target Audience: This book provides a quick read for experts, researchers as well as novices in the field of aerospace research, science, technology, applications, theory and trends in research. The relevant subjects' areas includes mechanical engineering, material sciences, computational engineering and system design.

Contents:

Preface; Aeroelasticity: An Overview; Abstract; 1. Introduction; 1.1. Static Aeroelasticity; 1.2. Dynamic Aeroelasticity; 1.3. History; 2. Aerodynamic Models; 2.1. Reduced Frequency; 2.2. Steady Aerodynamic Models; 2.3. Quasi-Steady Aerodynamic Model; 2.4. Unsteady Aerodynamic Model; 2.4.1. Wagner's Effect; 2.4.2. Theodorsen's Aerodynamic Model; 3. Bending Torsion Flutter; 3.1. Binary Flutter Model; 4. Wind Tunnel Test; 5. Flight Flutter Test; 6. Flutter Suppression; 6.1. Active Flutter Suppression; 7. Common Practices and State-of-the-Art Materials; Conclusion; Acknowledgement. 4. Thermal Response of Composites5. Composites in Fire under Tensile Loading; 6. Composites in Fire under Compressive Loading; Conclusion; References; The Implementation of Biofuel in Aircraft Engines; Abstract; 1. Introduction; 2. Need for Biofuels; 3. Challenges; 4. Feedstock and the Production Process of Jet Fuel; 4.1. Processes to Produce Bio-Kerosene; 4.1.1. Alcohol-to-Jet (ATJ) Fuel; 4.1.2. Oil-to-Jet (OTJ) Fuel; 4.1.3. Gas-to-Jet (GTJ) Fuel; 4.1.4. Sugar-to-Jet Fuel; 5. Effect of Fuel Properties on Emission Generation; 6. Compatibility of Biofuel with the Aircraft Engine. Conclusion Acknowledgments; References; Aircraft Mission Profile Analysis and Trajectory Optimization; Abstract; 1. Introduction; 2. Classification of UAS Platforms; 2.1. Micro (or Miniature) Air Vehicles (MAVs) or Nano Air Vehicles (NAVs); 2.2. UAS with Vertical Takeoff and Landing (VTOL); 2.3. Low-Altitude, Short-Endurance (LASE) and Low-Altitude, Long-Endurance (LALE) UAS; 2.4. Medium-Altitude, Long-Endurance (MALE) UAS; 2.5. High-Altitude, Long-Endurance (HALE) UAS; 3. Desired Flight Maneuvers; 3.1. Efficient Cruise; 3.2. Minimum Sink Soaring; 3.3. Direction Reversal. 3.4. Minimum Radius Turn3.5. Steepest Descent; 3.6. Maximum Speed Dash; 4. Trajectory Optimization; 5. Optimization Yielding Desired Flight Maneuvers; 6. Applications of Trajectory Planning and Optimization; 6.1. Minimizing Environmental Effects; 6.2. Aerobatic Air Race; 6.3. Collision Avoidance and Hazardous Terrains; 6.4. Air Traffic Management; Conclusion; References; Controller Design for a Hybrid UAV; Abstract; 1. Introduction; 2. Coordinate Frames; 3. Hardware Configurations; 4. Mathematical Modeling; 5. Brushless Motor Model; 6. System Linearization; 7. System Input

Notes:

Includes bibliographical references and index.

Description based on print version record.

ISBN:

1-5361-1230-5