I have not taken the earlier classes on Spacecraft Dynamics and Control, can I jump right into this class?

This course does stand on its on. It is still recommended that you have a strong foundation in particle dynamics, rotating frames, rigid body kinematics, etc.

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What will I get if I subscribe to this Specialization?

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Analytical Mechanics for Spacecraft Dynamics

Analytical Mechanics for Spacecraft Dynamics

This course is part of Advanced Spacecraft Dynamics and Control Specialization

Instructor: Hanspeter Schaub

1,512 already enrolled

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3 modules

Gain insight into a topic and learn the fundamentals.

12 reviews

Advanced level

Recommended experience

3 weeks to complete

at 10 hours a week

Flexible schedule

Learn at your own pace

3 modules

Gain insight into a topic and learn the fundamentals.

12 reviews

Advanced level

Recommended experience

3 weeks to complete

at 10 hours a week

Flexible schedule

Learn at your own pace

What you'll learn

Use virtual work methods to develop equations of motion of mechanical systems.
Understand how to use Lagrange multipliers to study constrained dynamical systems.
Be able to derive the equations of motion of a spacecraft with flexible sub-components.

Skills you'll gain

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Assessments

23 assignments

Taught in English

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This course is part of the Advanced Spacecraft Dynamics and Control Specialization

When you enroll in this course, you'll also be enrolled in this Specialization.

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There are 3 modules in this course

This course is part 2 of the specialization Advanced Spacecraft Dynamics and Control. It assumes you have a strong foundation in spacecraft dynamics and control, including particle dynamics, rotating frame, rigid body kinematics and kinetics. The focus of the course is to understand key analytical mechanics methodologies to develop equations of motion in an algebraically efficient manner. The course starts by first developing D’Alembert’s principle and how the associated virtual work and virtual displacement concepts allows us to ignore non-working force terms. Unconstrained systems and holonomic constrains are investigated. Next Kane's equations and the virtual power form of D'Alembert's equations are briefly reviewed for particles.

Next Lagrange’s equations are developed which still assume a finite set of generalized coordinates, but can be applied to multiple rigid bodies as well. Lagrange multipliers are employed to apply Pfaffian constraints. Finally, Hamilton’s extended principle is developed to allow us to consider a dynamical system with flexible components. Here there are an infinite number of degrees of freedom. The course focuses on how to develop spacecraft related partial differential equations, but does not study numerically solving them. The course ends comparing the presented assumed mode methods to classical final element solutions. The material covered is taking from the book "Analytical Mechanics of Space Systems" available at https://arc.aiaa.org/doi/book/10.2514/4.105210.

Module details

Learn the methodology of developing equations of motion using D'Alembert's principle, virtual power forms, Lagrange's equations as well as the Boltzmann-Hamel equations. These methods allow for more efficient equations of motion development where state based (holonomic) and rate based (Pfaffian constraints) are considered.

What's included

24 videos1 reading10 assignments

24 videosTotal 288 minutes

Welcome to the Course!4 minutes
Motivation for Analytical Mechanics22 minutes
Introduction1 minute
Virtual Displacements16 minutes
Taking First Order Variations17 minutes
Virtual Work11 minutes
Example: Circularly Orbiting Particle8 minutes
Example: Planar Spinning Body5 minutes
Classical Form of D'Alembert's Principle20 minutes
Example: Falling Rod Revisited15 minutes
Example: Generalized Forces on Particle14 minutes
Virtual Power Form of D'Alembert's Equations16 minutes
Example: Cart-Pendulum System23 minutes
Example: Planar Orbital Motion14 minutes
Torques Acting on a Rigid Body9 minutes
Example: Generalized Force on 2-Link System13 minutes
Holonomic Constraints8 minutes
Example: Spherical Pendulum7 minutes
Example: Constrained 3D Particle Motion17 minutes
Multiple Constraints7 minutes
Pfaffian Constraints11 minutes
General Constrained Optimization8 minutes
Example: Extremum on Circles5 minutes
Discussion on Constrainted Optimization18 minutes

1 readingTotal 1 minute

Course Updates and Accessibility Support1 minute

10 assignmentsTotal 400 minutes

Quiz 1 - Virtual Displacements15 minutes
Quiz 2 - Taking First Order Variations30 minutes
Quiz 3 - Virtual Work60 minutes
Quiz 4 - Classical Form of D'Alembert's Principle90 minutes
Quiz 5 - Virtual Power Form of D'Alembert's Equations60 minutes
Quiz 6 - Torques Acting on a Rigid Body30 minutes
Quiz 7 - Holonomic Constraints60 minutes
Quiz 8 - Multiple Constraints10 minutes
Quiz 9 - Pfaffian Constraints15 minutes
Quiz 10 - Constrained Optimization30 minutes

Derive methods to develop the equations of motion of a dynamical system with finite degrees of freedom based on energy expressions.

What's included

19 videos6 assignments

19 videosTotal 185 minutes

Derivation of Basic Lagrange's Equations13 minutes
Review: Lagrangian Dynamics8 minutes
Example: Particle in a Plane10 minutes
Lagrange's Equations with Conservative Forces7 minutes
Example: Cart-Pendulum revisited with Lagrange's equationsrev10 minutes
Constrained Lagrange's Equations14 minutes
Example: Particle in Rotating Tube11 minutes
Example: Rolling Wheel27 minutes
Example: Falling Ring6 minutes
Compact Matrix Form of Lagrange's Equations11 minutes
Cyclic Coordinates5 minutes
Example: Falling Planar Particle3 minutes
Example: Planar Particle on a Spring4 minutes
Routhian Reduction11 minutes
Example: Falling Planar Particle With Routhian5 minutes
Motivation for Boltzmann Hamel Equations14 minutes
Quasi Velocity Coordinates3 minutes
Boltzmann Hamel Equation Development11 minutes
Example: Rigid Body Motion in Free Space13 minutes

6 assignmentsTotal 450 minutes

Quiz 1 - Basic Lagrange's Equations30 minutes
Quiz 2 - Lagrange's Equations with Conservative Forces90 minutes
Quiz 3 - Constrained Lagrange's Equations150 minutes
Quiz 4 - Compact Matrix Form of Lagrange's Equations60 minutes
Quiz 5 - Cyclic Coordinates60 minutes
Quiz 1 - Boltzmann Hamel Equations60 minutes

Learn to develop the equations of motion for a dynamical system with deformable shapes. Such systems have infinite degrees of freedom and lead to partial differential equations.