Aerospace Engineering Lectures
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This course includes
- 22.3 hours of video
- Certificate of completion
- Access on mobile and TV
Course content
1 modules • 82 lessons • 22.3 hours of video
Aerospace Engineering Lectures
82 lessons
• 22.3 hours
Aerospace Engineering Lectures
82 lessons
• 22.3 hours
- Flight Vehicles, Aerospace Engineering Lecture 1 17:44
- Geopotential Altitude, Aerospace Engineering: Lecture 2 13:19
- Standard Atmosphere, Aerospace Engineering Lecture 3 18:43
- Aerodynamic Flow Field, Aerospace Engineering Lecture 4 12:24
- Aerodynamic Pressure and Shear Force, Aerospace Engineering Lecture 5 07:06
- Equations of Aerodynamics, Aerospace Engineering Lecture 6 24:47
- Isentropic Flow, Aerospace Engineering Lecture 7 18:21
- Bernoulli's Equation for Compressible Flow, Aerospace Engineering Lecture 8 20:27
- Mach Number, Aerospace Engineering Lecture 9 18:50
- Low Speed Wind Tunnel, Aerospace Engineering Lecture 10 14:07
- Pitot Static Tube, Aerospace Engineering Lecture 11 11:16
- Compressible Flow, Aerospace Engineering Lecture 12 16:17
- Incompressible vs Compressible Flow, Aerospace Engineering Lecture 13 08:57
- Boundary Layer, Aerospace Engineering Lecture 15 13:58
- Reynolds Number, Aerospace Engineering Lecture 16 12:36
- Flow Separation, Aerospace Engineering Lecture 17 11:56
- Airfoil, Aerospace Engineering, Lecture 18 11:05
- Lift and Drag Coefficients, Aerospace Engineering Lecture 19 17:31
- Similarity Parameters, Aerospace Engineering Lecture 20 14:31
- Airfoil Aerodynamics, Aerospace Engineering Lecture 21 20:41
- Finite Wings, Aerospace Engineering Lecture 22 13:30
- Induced Drag, Aerospace Engineering Lecture 23 16:04
- Flaps and High Lift Devices, Aerospace Engineering Lecture 24 10:17
- Kutta-Joukowski Theorem, Aerospace Engineering Lecture 25 10:30
- Critical Mach Number, Aerospace Engineering Lecture 26 18:05
- Drag Divergence Mach Number, Aerospace Engineering Lecture 27 12:38
- Supersonic Flow, Aerospace Engineering Lecture 28 19:05
- Airplane Drag Polar, Aerospace Engineering Lecture 29 14:53
- Airplane Equation of Motion, Aerospace Engineering Lecture 30 17:04
- Airplane Thrust Required, Aerospace Engineering Lecture 31 21:34
- Airplane Power Required, Aerospace Engineering Lecture 32 21:53
- Altitude and Airplane Performance, Aerospace Engineering Lecture 33 11:37
- Rate of Climb of Airplane, Aerospace Engineering Lecture 34 18:01
- Gliding Flight, Aerospace Engineering Lecture 36 10:42
- Aircraft Flight Ceiling, Aerospace Engineering Lecture 35 08:42
- Time to Climb for Airplane, Aerospace Engineering Lecture 37 06:10
- Range of Propeller Aircraft, Aerospace Engineering Lecture 39 12:12
- Endurance of Propeller Aircraft, Aerospace Engineering Lecture 40 12:54
- Airplane Range and Endurance, Aerospace Engineering Lecture 38 12:09
- Endurance of Jet Airplane, Aerospace Engineering Lecture 41 11:59
- Range of Jet Airplane, Aerospace Engineering Lecture 42 14:35
- Best Lift to Drag Ratio for Airplane, Aerospace Engineering Lecture 43 14:56
- Airplane Takeoff Performance, Aerospace Engineering Lecture 44 23:28
- Airplane Landing Performance, Aerospace Engineering Lecture 45 20:50
- Best Textbook for Starting Study of Aerospace Engineering 09:16
- Airplane Level Turn, Aerospace Engineering Lecture 46 18:50
- Airplane Pull-Up Maneuver, Aerospace Engineering Lecture 47 18:13
- V-n Diagram for Airplane Explained, Aerospace Engineering Lecture 48 13:22
- Accelerated Climb of Airplane, Aerospace Engineering, Lecture 49 14:05
- Airplane Control Surfaces, Aerospace Engineering Lecture 50 12:32
- Static and Dynamic Stability, Aerospace Engineering Lecture 51 14:08
- Airplane Longitudinal Stability, Aerospace Engineering Lecture 52 18:21
- Airplane Longitudinal Stability Derivation, Aerospace Engineering, Lecture 53 25:25
- Neutral Point and Static Margin, Aerospace Engineering Lecture 54 14:24
- Longitudinal Control of Airplane, Aerospace Engineering Lecture 55 20:15
- Airplane Stick-Free Static Stability, Aerospace Engineering Lecture 56 13:32
- Directional and Lateral Stability, Aerospace Engineering Lecture 57 14:28
- Mastering Space Vehicle Motion with the Orbit Equation, Aerospace Engineering Lecture 58 21:10
- The Orbit Equation, Aerospace Engineering Lecture 59 16:47
- Trajectory of Spacecraft, Aerospace Engineering Lecture 60 14:23
- Circular and Escape Velocity, Aerospace Engineering Lecture 61 23:19
- Conic Sections, Aerospace Engineering Lecture 62 21:18
- Kepler's Laws of Planetary Motion, Aerospace Engineering Lecture 63 19:54
- Ballistic Entry, Aerospace Engineering Lecture 64 25:32
- Ballistic Entry of Spacecraft into Earth, Aerospace Engineering Lecture 65 20:38
- Area Velocity Relation, Aerospace Engineering Lecture 14 13:11
- Ballistic Entry and Heating, Aerospace Engineering Lecture 66 20:09
- Structures and Materials, Aerospace Engineering Lecture 67 29:07
- Stress and Strain, Aerospace Engineering Lecture 68 18:47
- Metals and Composite Materials, Aerospace Engineering Lecture 69 16:39
- Principal stress, Aerospace Engineering Lecture 70 14:58
- Tresca and von Mises Failure Theory, Aerospace Engineering Lecture 71 15:28
- Plane stress and Plane strain, Aerospace Engineering Lecture 72 22:36
- Strain and Displacement, Aerospace Engineering Lecture 73 14:07
- Equilibrium of Stress, Aerospace Engineering Lecture 74 14:41
- The Propeller, Aerospace Engineering Lecture 75 24:27
- Reciprocating Piston Engine, Aerospace Engineering Lecture 76 20:44
- The Jet Engine, Aerospace Engineering Lecture 77 25:52
- The Rocket Engine, Aerospace Engineering Lecture 78 18:44
- The Rocket Equation, Aerospace Engineering Lecture 79 17:36
- Efficient Propulsion, Aerospace Engineering Lecture 80 17:48
- Understanding The Challenges Of Hypersonic Flight At Mach 5, Aerospace Engineering Lecture 81 16:38
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