Kinematics: Describing the Motions of Spacecraft

Kinematics: Describing the Motions of Spacecraft

This course is part of Spacecraft Dynamics and Control Specialization

Instructor: Hanspeter Schaub

What you'll learn

Differentiate a vector as seen by another rotating frame and derive frame dependent velocity and acceleration vectors
Apply the Transport Theorem to solve kinematic particle problems and translate between various sets of attitude descriptions
Add and subtract relative attitude descriptions and integrate those descriptions numerically to predict orientations over time
Derive the fundamental attitude coordinate properties of rigid bodies and determine attitude from a series of heading measurements

Skills you'll gain

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Assessments

36 assignments

Taught in English

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This course is part of the Spacecraft Dynamics and Control Specialization

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There are 4 modules in this course

The movement of bodies in space (like spacecraft, satellites, and space stations) must be predicted and controlled with precision in order to ensure safety and efficacy. Kinematics is a field that develops descriptions and predictions of the motion of these bodies in 3D space. This course in Kinematics covers four major topic areas: an introduction to particle kinematics, a deep dive into rigid body kinematics in two parts (starting with classic descriptions of motion using the directional cosine matrix and Euler angles, and concluding with a review of modern descriptors like quaternions and Classical and Modified Rodrigues parameters). The course ends with a look at static attitude determination, using modern algorithms to predict and execute relative orientations of bodies in space.

After this course, you will be able to... * Differentiate a vector as seen by another rotating frame and derive frame dependent velocity and acceleration vectors * Apply the Transport Theorem to solve kinematic particle problems and translate between various sets of attitude descriptions * Add and subtract relative attitude descriptions and integrate those descriptions numerically to predict orientations over time * Derive the fundamental attitude coordinate properties of rigid bodies and determine attitude from a series of heading measurements 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.

This module covers particle kinematics. A special emphasis is placed on a frame-independent vectorial notation. The position velocity and acceleration of particles are derived using rotating frames utilizing the transport theorem.

What's included

13 videos3 assignments

13 videosTotal 154 minutes

Professor Introduction6 minutesPreview module
Kinematics Course Introduction1 minute
Module One: Particle Kinematics Introduction0 minutes
1: Particle Kinematics13 minutes
Optional Review: Vectors, Angular Velocities, Coordinate Frames16 minutes
2: Angular Velocity Vector9 minutes
3: Vector Differentiation25 minutes
3.1: Examples of Vector Differentiation25 minutes
3.2: Example of Planar Particle Kinematics with the Transport Theorem16 minutes
3.3: Example of 3D Particle Kinematics with the Transport Theorem14 minutes
Optional Review: Angular Velocities, Coordinate Frames, and Vector Differentiation19 minutes
Optional Review: Angular Velocity Derivative1 minute
Optional Review: Time Derivatives of Vectors, Matrix Representations of Vector2 minutes

3 assignmentsTotal 125 minutes

Concept Check 1 - Particle Kinematics and Vector Frames30 minutes
Concept Check 2 - Angular Velocities30 minutes
Concept Check 3 - Vector Differentiation and the Transport Theorem65 minutes

This module provides an overview of orientation descriptions of rigid bodies. The 3D heading is here described using either the direction cosine matrix (DCM) or the Euler angle sets. For each set the fundamental attitude addition and subtracts are discussed, as well as the differential kinematic equation which relates coordinate rates to the body angular velocity vector.

What's included

18 videos1 reading10 assignments

18 videosTotal 209 minutes

Module Two: Rigid Body Kinematics Part 1 Introduction1 minutePreview module
1: Introduction to Rigid Body Kinematics18 minutes
2: Directional Cosine Matrices: Definitions18 minutes
3: DCM Properties7 minutes
4: DCM Addition and Subtraction5 minutes
5: DCM Differential Kinematic Equations8 minutes
Optional Review: Tilde Matrix Properties2 minutes
Optional Review: Rigid Body Kinematics and DCMs21 minutes
6: Euler Angle Definition17 minutes
7: Euler Angle / DCM Relation16 minutes
7.1: Example: Topographic Frame DCM Development9 minutes
8: Euler Angle Addition and Subtraction8 minutes
9: Euler Angle Differential Kinematic Equations25 minutes
10: Symmetric Euler Angle Addition20 minutes
Optional Review: Euler Angle Definitions4 minutes
Optional Review: Euler Angle Mapping to DCMs9 minutes
Optional Review: Euler Angle Differential Kinematic Equations1 minute
Optional Review: Integrating Differential Kinematic Equations10 minutes

1 readingTotal 10 minutes

Eigenvector Review10 minutes

10 assignmentsTotal 295 minutes

Concept Check 1 - Rigid Body Kinematics30 minutes
Concept Check 2 - DCM Definitions30 minutes
Concept Check 3 - DCM Properties30 minutes
Concept Check 4 - DCM Addition and Subtraction30 minutes
Concept Check 5 - DCM Differential Kinematic Equations (ODE)30 minutes
Concept Check 6 - Euler Angles Definitions30 minutes
Concept Check 7 - Euler Angle and DCM Relation30 minutes
Concept Check 8 - Euler Angle Addition and Subtraction10 minutes
Concept Check 9 - Euler Angle Differential Kinematic Equations45 minutes
Concept Check 10 - Symmetric Euler Angle Addition30 minutes

This module covers modern attitude coordinate sets including Euler Parameters (quaternions), principal rotation parameters, Classical Rodrigues parameters, modified Rodrigues parameters, as well as stereographic orientation parameters. For each set the concepts of attitude addition and subtraction is developed, as well as mappings to other coordinate sets.

What's included

29 videos18 assignments

29 videosTotal 250 minutes

Module Three: Rigid Body Kinematics Part 2 Introduction0 minutesPreview module
1: Principal Rotation Parameter Definition9 minutes
2: PRV Relation to DCM18 minutes
3: PRV Properties6 minutes
Optional Review: Principal Rotation Parameters6 minutes
4: Euler Parameter (Quaternion) Definition20 minutes
5: Mapping PRV to EPs1 minute
6: EP Relationship to DCM16 minutes
7: Euler Parameter Addition10 minutes
8: EP Differential Kinematic Equations5 minutes
Optional Review: Euler Parameters and Quaternions16 minutes
9: Classical Rodrigues Parameters Definitions8 minutes
10: CRP Stereographic Projection9 minutes
11: CRP Relation to DCM8 minutes
12: CRP Addition and Subtraction1 minute
13: CRP Differential Kinematic Equations1 minute
14: CRPs through Cayley Transform9 minutes
Optional Review: CRP Properties6 minutes
15: Modified Rodrigues Parameters Definitions9 minutes
16: MRP Stereographic Projection5 minutes
17: MRP Shadow Set Property7 minutes
18: MRP to DCM Relation4 minutes
19: MRP Addition and Subtraction4 minutes
20: MRP Differential Kinematic Equation14 minutes
21: MRP Form of the Cayley Transform7 minutes
Optional Review: MRP Definitions8 minutes
Optional Review: MRP Properties8 minutes
22: Stereographic Orientation Parameters Definitions6 minutes
Optional Review: SOPs14 minutes

18 assignmentsTotal 367 minutes

Concept Check 1 - Principal Rotation Definitions30 minutes
Concept Check 2 - Principal Rotation Parameter relation to DCM30 minutes
Concept Check 3 - Principal Rotation Addition12 minutes
Concept Check 4 - Euler Parameter Definitions15 minutes
Concept Check 5, 6 - Euler Parameter Relationship to DCM15 minutes
Concept Check 7 - Euler Parameter Addition10 minutes
Concept Check 8 - EP Differential Kinematic Equations20 minutes
Concept Check 9 - CRP Definitions30 minutes
Concept Check 10 - CRPs Stereographic Projection30 minutes
Concept Check 11, 12 - CRP Addition12 minutes
Concept Check 13 - CRP Differential Kinematic Equations20 minutes
Concept Check 15 - MRPs Definitions30 minutes
Concept Check 16 - MRP Stereographic Projection5 minutes
Concept Check 17 - MRP Shadow Set30 minutes
Concept Check 18 - MRP to DCM Relation8 minutes
Concept Check 19 - MRP Addition and Subtraction10 minutes
Concept Check 20 - MRP Differential Kinematic Equation30 minutes
Concept Quiz 22 – SOPs30 minutes

This module covers how to take an instantaneous set of observations (sun heading, magnetic field direction, star direction, etc.) and compute a corresponding 3D attitude measure. The attitude determination methods covered include the TRIAD method, Devenport's q-method, QUEST as well as OLAE. The benefits and computation challenges are reviewed for each algorithm.

What's included

13 videos5 assignments1 peer review

13 videosTotal 120 minutes

Module Four: Static Attitude Determination Introduction0 minutesPreview module
1: Attitude Determination Problem Statement17 minutes
2: TRIAD Method Definition11 minutes
2.1: TRIAD Method Numerical Example9 minutes
3: Wahba's Problem Definition11 minutes
4: Devenport's q-Method16 minutes
4.1: Example of Devenport's q-Method7 minutes
5: QUEST9 minutes
5.1: Example of QUEST3 minutes
6: Optimal Linear Attitude Estimator5 minutes
6.1: Example of OLAE2 minutes
Optional Review: Attitude Determination14 minutes
Optional Review: Attitude Estimation Algorithms10 minutes

5 assignmentsTotal 82 minutes

Concept Check 1 - Attitude Determination30 minutes
Concept Check 2 - TRIAD Method10 minutes
Concept Check 3, 4 - Devenport's q-Method15 minutes
Concept Check 5 - QUEST Method15 minutes
Concept Check 6 - OLAE Method12 minutes

1 peer reviewTotal 120 minutes

Kinematics Final Assignment120 minutes

Instructor

Instructor ratings

4.9 (103 ratings)

Hanspeter Schaub

University of Colorado Boulder

10 Courses33,909 learners

Offered by

University of Colorado Boulder

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Reviewed on Jun 2, 2019

if you are an aerospace engineering student and would like to get into orbital mechanics/ control and dynamics of satellites or celestial bodies, it's a decent course (series) to take.

Reviewed on Dec 26, 2018

Very good course! Few of the quizzes have the wrong answers marked as correct which can be confusing when learning the material (see the discussion forum for specifics).

Reviewed on Dec 10, 2019

Gives a good introduction to common attitude representations, along with how attitude can be determined from sensor measurements.

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