Difference between revisions of "ME 449 Robotic Manipulation"

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* Instructor: Prof. Kevin Lynch
* Instructor: Prof. Kevin Lynch
* Course assistants: Luke Batteas, LukeBatteas2027@u.northwestern.edu; Yuxuan Mao, yuxuanmao2024@u.northwestern.edu; and Alex Soto, AlexanderTorresSoto2024@u.northwestern.edu
* Course assistants: Luke Batteas, LukeBatteas2027@u.northwestern.edu; Yuxuan Mao, yuxuanmao2024@u.northwestern.edu; and Alex Soto, AlexanderTorresSoto2024@u.northwestern.edu
* Office hours: Mon 3-4 Tech B252 (Alex), Tues 3-4 Tech M434 (Yuxuan), Fri 1-2 Tech M434 (Luke)
* Office hours: TBA
<!--4-5 PM Tuesday (TAs) and 2-3 PM Thursday (Lynch) by Zoom invitation in Canvas. '''Finals week only:''' TA office hours will be 4-5 PM Tuesday, as usual, and Lynch's office hours will be 1:30-2:30 Wednesday Dec 8 (office hours Thursday canceled)
<!--4-5 PM Tuesday (TAs) and 2-3 PM Thursday (Lynch) by Zoom invitation in Canvas. '''Finals week only:''' TA office hours will be 4-5 PM Tuesday, as usual, and Lynch's office hours will be 1:30-2:30 Wednesday Dec 8 (office hours Thursday canceled)
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Do the following things as soon as possible:
Do the following things as soon as possible:


* [[Modern Robotics#Book|Buy the book "Modern Robotics" or download the electronic preprint version]]. (Though the Cambridge-published version is the "official" version, the differences are mostly layout and either will work for this course.)
* [[Modern Robotics#Book|Buy the book "Modern Robotics" or download the free electronic preprint version]]. (Though the Cambridge-published print version is the "official" version, the differences are mostly layout and either will work for this course.)
* [[Getting Started with the Modern Robotics Code Library|Download the Modern Robotics software]]. You can program in Python, MATLAB, or Mathematica. Most students use Python or MATLAB, but any of these is fine.
* [[Getting Started with the Modern Robotics Code Library|Download the Modern Robotics software]]. You can program in Python, MATLAB, or Mathematica. Most students use Python or MATLAB, but any of these is fine.
* [[Getting Started with the CoppeliaSim Simulator|Download, install, and test the CoppeliaSim robot simulation software.]]
* [[Getting Started with the CoppeliaSim Simulator|Download, install, and test the CoppeliaSim robot simulation software.]]
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* Mon Oct 14: finish Chapter 4 (quiz, Chapters 3.3 and 3.4; 3 videos and 3 LCs on product of exponentials formula, space and e-e frame) '''[[Media:MRslides-ch04a.pdf|CLASS SLIDES]]'''
* Mon Oct 14: finish Chapter 4 (quiz, Chapters 3.3 and 3.4; 3 videos and 3 LCs on product of exponentials formula, space and e-e frame) '''[[Media:MRslides-ch04a.pdf|CLASS SLIDES]]'''
'''Chapter 5, Velocity Kinematics and Statics'''
'''Chapter 5, Velocity Kinematics and Statics'''
* Wed Oct 16: '''ASST 1, DUE 1:30 PM'''. New material: through Chapter 5.1 (quiz, Chapter 4; 3 videos and 3 LCs on space Jacobian, body Jacobian) '''[[Media:MRslides-ch05a.pdf|CLASS SLIDES]]'''
* Wed Oct 16: <s>'''ASST 1, DUE 1:30 PM'''.</s> New material: through Chapter 5.1 (quiz, Chapter 4; 3 videos and 3 LCs on space Jacobian, body Jacobian) '''[[Media:MRslides-ch05a.pdf|CLASS SLIDES]]'''
* Fri Oct 18: through Chapter 5.2 1 video and 1 LC on statics of open chains) '''[[Media:MRslides-ch05b.pdf|CLASS SLIDES]]'''
* Fri Oct 18: '''ASST 1, DUE 1:30 PM'''. New material: through Chapter 5.2 1 video and 1 LC on statics of open chains) '''[[Media:MRslides-ch05b.pdf|CLASS SLIDES]]'''
* Mon Oct 21: through Chapter 5.4 (2 videos and 2 LCs on singularity analysis, manipulability) '''[[Media:MRslides-ch05c.pdf|CLASS SLIDES]]'''
* Mon Oct 21: through Chapter 5.4 (2 videos and 2 LCs on singularity analysis, manipulability) '''[[Media:MRslides-ch05c.pdf|CLASS SLIDES]]'''
'''Chapter 6, Inverse Kinematics (focus on section 6.2)'''
'''Chapter 6, Inverse Kinematics (focus on section 6.2)'''
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* Fri Oct 25: through Chapter 8.1.2 (quiz, Chapter 6; 2 videos and 2 LCs on Lagrangian dynamics) '''[[Media:MRslides-ch08a.pdf|CLASS SLIDES]]'''
* Fri Oct 25: through Chapter 8.1.2 (quiz, Chapter 6; 2 videos and 2 LCs on Lagrangian dynamics) '''[[Media:MRslides-ch08a.pdf|CLASS SLIDES]]'''
* Mon Oct 28: New material: Chapter 8.1.3 (1 video and 1 LC on understanding the mass matrix) '''[[Media:MRslides-ch08b.pdf|CLASS SLIDES]]'''
* Mon Oct 28: New material: Chapter 8.1.3 (1 video and 1 LC on understanding the mass matrix) '''[[Media:MRslides-ch08b.pdf|CLASS SLIDES]]'''
* Wed Oct 30: '''MIDTERM''', chapters 2-5 (no electronic devices allowed [calculator, laptop, tablet, etc.]; study sheets and book allowed) '''[[Media:ME449-midterm-2022.pdf|2022 midterm]]''' and '''[[Media:ME449-midterm-solutions-2022.pdf|solutions]]''' (average score 22.9/32); '''[[Media:ME449-midterm-2023.pdf|2023 midterm]]''' and '''[[Media:ME449-midterm-solutions-2023.pdf|solutions]]'''
* Wed Oct 30: '''MIDTERM''', chapters 2-5 (no electronic devices allowed [calculator, laptop, tablet, etc.]; study sheets and book allowed) '''[[Media:ME449-midterm-2022.pdf|2022 midterm]]''' and '''[[Media:ME449-midterm-solutions-2022.pdf|solutions]]''' (average score 22.9/32); '''[[Media:ME449-midterm-2023.pdf|2023 midterm]]''' and '''[[Media:ME449-midterm-solutions-2023.pdf|solutions]]'''; '''[[Media:ME449-midterm-2024.pdf|2024 midterm]]''' and '''[[Media:ME449-midterm-solutions-2024.pdf|solutions]]'''
* Fri Nov 1: Chapter 8.2 (2 videos and 2 LCs on dynamics of a single rigid body) '''[[Media:MRslides-ch08c.pdf|CLASS SLIDES]]'''
* Fri Nov 1: Guest lecture by Dan L. Chapter 8.2 (2 videos and 2 LCs on dynamics of a single rigid body) '''[[Media:MRslides-ch08c.pdf|CLASS SLIDES]]'''
* Mon Nov 4: Chapter 8.3 and 8.5 (2 videos and 2 LCs on Newton-Euler inverse dynamics, forward dynamics; quiz, Chapter 8 through 8.3) '''[[Media:MRslides-ch08d.pdf|CLASS SLIDES]]'''
* Mon Nov 4: Chapter 8.3 and 8.5 (2 videos and 2 LCs on Newton-Euler inverse dynamics, forward dynamics; quiz, Chapter 8 through 8.3) '''[[Media:MRslides-ch08d.pdf|CLASS SLIDES]]'''
'''Chapter 9, Trajectory Generation'''
'''Chapter 9, Trajectory Generation'''
* Wed Nov 6: '''ASST 2, DUE 1:30 PM'''. New material: through Chapter 9.3 (3 videos and 3 LCs on point-to-point trajectories, polynomial via point trajectories) '''[[Media:MRslides-ch09a.pdf|CLASS SLIDES]]'''
* Wed Nov 6: <s>'''ASST 2, DUE 1:30 PM'''.</s> New material: through Chapter 9.3 (3 videos and 3 LCs on point-to-point trajectories, polynomial via point trajectories) '''[[Media:MRslides-ch09a.pdf|CLASS SLIDES]]'''
* Fri Nov 8: CLASS CANCELED. Chapter 9.4 (quiz, Chapter 9 through 9.3; 3 videos and 3 LCs on time-optimal time scaling) '''[[Media:MRslides-ch09b.pdf|CLASS SLIDES]]'''
* Fri Nov 8: '''ASST 2, DUE 1:30 PM'''. Chapter 9.4 (quiz, Chapter 9 through 9.3; 3 videos and 3 LCs on time-optimal time scaling) '''[[Media:MRslides-ch09b.pdf|CLASS SLIDES]]'''
* Mon Nov 11: Chapter 9.4 recap.
* Mon Nov 11: Chapter 9.4 recap.
* Wed Nov 13: '''ASST 3, DUE 1:30 PM'''; final project discussion
* Wed Nov 13: <s>'''ASST 3, DUE 1:30 PM.'''</s> Final project discussion
'''Chapter 11, Robot Control (focus on sections 11.1 through 11.4)'''
'''Chapter 11, Robot Control (focus on sections 11.1 through 11.4)'''
* Fri Nov 15: up to (not including) Chapter 11.2.2.1 (quiz, Chapter 9.4; 3 videos and 3 LCs on linear error dynamics) '''[[Media:MRslides-ch11a.pdf|CLASS SLIDES]]'''
* Fri Nov 15: '''ASST 3, DUE 1:30 PM.''' New material: up to (not including) Chapter 11.2.2.1 (quiz, Chapter 9.4; 3 videos and 3 LCs on linear error dynamics) '''[[Media:MRslides-ch11a.pdf|CLASS SLIDES]]'''
* Mon Nov 18: finish Chapter 11.2.2 (2 videos and 2 LCs on first- and second-order error dynamics) '''[[Media:MRslides-ch11b.pdf|CLASS SLIDES]]'''
* Mon Nov 18: finish Chapter 11.2.2 (2 videos and 2 LCs on first- and second-order error dynamics) '''[[Media:MRslides-ch11b.pdf|CLASS SLIDES]]'''
* Wed Nov 20: through Chapter 11.3 (3 videos and 3 LCs on motion control with velocity inputs) '''[[Media:MRslides-ch11c.pdf|CLASS SLIDES]]'''
* Wed Nov 20: through Chapter 11.3 (3 videos and 3 LCs on motion control with velocity inputs) '''[[Media:MRslides-ch11c.pdf|CLASS SLIDES]]'''
* Fri Nov 22: Chapter 11.4 (quiz, Chapter 11 through 11.3; 3 videos and 3 LCs on motion control with torque or force inputs) '''[[Media:MRslides-ch11d.pdf|CLASS SLIDES]]'''
* Fri Nov 22: '''CLASS CANCELED. Coursera material is still due.''' Chapter 11.4 (quiz, Chapter 11 through 11.3; 3 videos and 3 LCs on motion control with torque or force inputs) '''[[Media:MRslides-ch11d.pdf|CLASS SLIDES]]'''
'''Chapter 13, Wheeled Mobile Robots (skip section 13.3)'''
'''Chapter 13, Wheeled Mobile Robots (skip section 13.3)'''
* Mon Nov 25: '''FINAL PROJECT MILESTONE 2, DUE 1:30 PM'''; new material through Chapter 13.2 (quiz, Chapter 11.4; 3 videos and 3 LCs on omnidirectional wheeled mobile robots) '''[[Media:MRslides-ch13a.pdf|CLASS SLIDES]]'''
* Mon Nov 25: '''FINAL PROJECT MILESTONE 2, DUE 1:30 PM'''; new material through Chapter 13.2 (quiz, Chapter 11.4; 3 videos and 3 LCs on omnidirectional wheeled mobile robots) '''[[Media:MRslides-ch13a.pdf|CLASS SLIDES]]'''
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== Practice Tests ==
== Practice Tests ==
* [[Media:ME449-midterm-2024.pdf|2024 midterm]] and [[Media:ME449-midterm-solutions-2024.pdf|2024 midterm solutions]]
* [[Media:ME449-midterm-2023.pdf|2023 midterm]] and [[Media:ME449-midterm-solutions-2023.pdf|2023 midterm solutions]]
* [[Media:ME449-midterm-2022.pdf|2022 midterm]] and [[Media:ME449-midterm-2022-solutions.pdf|2022 midterm solutions]]
* [[Media:ME449-midterm-2022.pdf|2022 midterm]] and [[Media:ME449-midterm-2022-solutions.pdf|2022 midterm solutions]]
* [[Media:ME449-quiz1-solutions-2019.pdf|Quiz 1, 2019]]
* [[Media:ME449-quiz1-solutions-2019.pdf|Quiz 1, 2019]]
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* '''Upload on time! Late submissions are not accepted.'''
* '''Upload on time! Late submissions are not accepted.'''
* For every assignment, you should upload exactly one pdf file, named FamilyName_GivenName_asst#.pdf. This pdf file should have answers to all the questions, including screen shots, text logs of code running, etc. Always include output of your code running on the exercises, so the grader can see what you got when you ran your code. You may scan handwritten solutions (provided they are neat!), but in any case, all answers should be in a single pdf file. DO NOT UPLOAD SCANS AS JPGS! THEY MUST ALL BE COMPILED INTO A SINGLE PDF FILE.
* For every assignment, you should submit a single zip file, named FamilyName_GivenName_asst#.zip. This zip file should include a single pdf file with answers to all the questions, including screen shots, text logs of code running, etc. Always include output of your code running on the exercises, so the grader can see what you got when you ran your code. You may scan handwritten solutions (provided they are neat!), but in any case, all answers should be in a single pdf file. DO NOT UPLOAD SCANS AS JPGS! THEY MUST ALL BE COMPILED INTO A SINGLE PDF FILE.
* If required by the assignment, in addition you may be asked to provide a zip file including all source code in their original forms, such as .m, .py, or .nb. This zip file should be named FamilyName_GivenName_asst#.zip. Always create a script that the grader can easily invoke to run your code for a particular exercise. Don't expect the grader to search through your code to find sample code to cut-and-paste. Make it as easy as possible for the grader (you can include a "README.txt" file in your zip file, for example, to tell the grader how everything works). Your code should be commented well enough that it is easy for someone else to pick it up and understand more or less how it works. All student-written code must be submitted; do not submit any standard MR code.
* You may be asked to include in your zip file all source code in their original forms, such as .m, .py, or .nb. Always create a script that the grader can easily invoke to run your code for a particular exercise. Don't expect the grader to search through your code to find sample code to cut-and-paste. Make it as easy as possible for the grader (you can include a "README.txt" file in your zip file, for example, to tell the grader how everything works). Your code should be commented well enough that it is easy for someone else to pick it up and understand more or less how it works. All student-written code must be submitted; do not submit any standard MR code.
* If you record a movie, keep it short and clear. It should only be a few MB in size. For example, you don't need super high resolution, 60 fps, etc.
* If you include movies, keep them short and clear. They should only be a few MB in size. For example, you don't need super high resolution, 60 fps, etc.
* All plots should be labeled (axes, legends, titles) with appropriate units.
* All plots should be labeled (axes, legends, titles) with appropriate units.


'''[http://hades.mech.northwestern.edu/index.php/ME_449_Assignment_1 Assignment 1]''', due 1:30 PM CT Wednesday October 11 on Canvas.
'''[http://hades.mech.northwestern.edu/index.php/ME_449_Assignment_1 Assignment 1]''', due 1:30 PM CT <s>Wednesday October 16</s> Friday October 18 on Canvas.


'''[[Media:ME449-asst2-2023.pdf|Assignment 2]]''', due 1:30 PM CT <s>Monday October 30</s> '''Wednesday November 1''' on Canvas.
'''[[Media:ME449-asst2-2024.pdf|Assignment 2]]''', due 1:30 PM CT <s>Wednesday November 6</s> Friday November 8 on Canvas.

'''[[Media:ME449-asst3-2023.pdf|Assignment 3]]''', due 1:30 PM CT Wednesday November 8 on Canvas.


'''[[Media:ME449-asst3-2024.pdf|Assignment 3]]''', due 1:30 PM CT Friday November 15 on Canvas.


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The final project is described [http://hades.mech.northwestern.edu/index.php/Mobile_Manipulation_Capstone_2023 '''on this page''']. It is due in Canvas on Thursday December 7 at noon.
The final project is described [http://hades.mech.northwestern.edu/index.php/Mobile_Manipulation_Capstone_2024 '''on this page''']. It is due in Canvas on Thursday December 12 at noon.


* '''Due Monday November 20 at 1:30 PM on Canvas''': Milestone 2. ''(You will do milestone 2 first! Milestone 1 will come next.)'' You will turn in a single zip file named FamilyName_GivenName_milestone2.zip with your solution to milestone 2. The zip file should include a README.pdf file with a brief summary of your solution and how to use it, and if your code is not working properly, it should correctly point out the problems. The zip file should also include a directory with the commented code you wrote, including a cut-and-pastable comment at the beginning showing how to execute the code to generate the csv file included in the submission; a CoppeliaSim video showing your reference trajectory of the end-effector (similar to [https://www.youtube.com/watch?v=8d_cYwV58lI&feature=youtu.be this video]); and the csv file that your code generated to create the video.
* '''Due Monday November 25 at 1:30 PM on Canvas''': Milestone 2. ''(You will do milestone 2 first! Milestone 1 will come next.)'' You will turn in a single zip file named FamilyName_GivenName_milestone2.zip with your solution to milestone 2. The zip file should include a README.pdf file with a brief summary of your solution and how to use it, and if your code is not working properly, it should correctly point out the problems. The zip file should also include a directory with the commented code you wrote, including a cut-and-pastable comment at the beginning showing how to execute the code to generate the csv file included in the submission; a CoppeliaSim video showing your reference trajectory of the end-effector (similar to [https://www.youtube.com/watch?v=8d_cYwV58lI&feature=youtu.be this video]); and the csv file that your code generated to create the video.
* ''' Due Thursday December 7 at 12:00 PM (noon) on Canvas''': The entire final writeup, as described [https://hades.mech.northwestern.edu/index.php/Mobile_Manipulation_Capstone_2023#Final_Step:_Completing_the_Project_and_Your_Submission '''at this page'''], in a single zip file named FamilyName_GivenName_capstone.zip. '''You may earn up to 10% extra credit on the capstone project by implementing singularity and self-collision avoidance.''' See the description of the final project writeup.
* ''' Due Thursday December 12 at 12:00 PM (noon) on Canvas''': The entire final writeup in a single zip file named FamilyName_GivenName_capstone.zip. '''You may earn up to 10% extra credit on the capstone project by implementing singularity and self-collision avoidance.''' See the description of the final project writeup.


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Latest revision as of 13:50, 20 November 2024

Fall Quarter 2024

Supportive Class Environment

All members of this class (instructors, TAs, students) are expected to contribute to a respectful, inclusive, and supportive environment for every other member of the class.

We are partners in your education; help us help you get the most out of this class. Please engage as much as possible during our class meetings!

Honor Code

You are encouraged to discuss the material with the instructor, course assistants, and your classmates, but you are not allowed to copy answers or code from others in the class or other sources, nor are you allowed to share your answers or code with others. If you use generative AI to help you with your work, you are obligated to cite the source and nature of the help; for example, if you turn in code generated in whole or in part by generative AI, you must cite the AI software in the comments, and you are required to understand how and why the code works. (Note also that electronics are not available during tests, so submitting code you do not understand will not help you prepare for tests.) Anyone copying answers or code, or providing answers or code, or becoming aware of others doing so without reporting to the instructor, is in violation of the honor code.

Accessible NU

If you need accommodation in this course because of a disability, contact Accessible NU immediately.

Religious Holidays

Provost's statement on accommodations for religious holidays.


Getting Started

Do the following things as soon as possible:

Course Summary

Representations of the configuration and spatial motion of rigid bodies and robots based on modern screw theory. Forward, inverse, and differential kinematics. Robot dynamics, trajectory planning, and motion control. Wheeled mobile robots and mobile manipulation.

Prerequisites

Linear algebra, first-order linear ODEs, freshman-level physics/mechanics, a bit of programming background.

Grading

50% of your final grade will be from your Coursera grades (which I expect will be close to perfect) and 50% from the midterm and assignments outside of Coursera, including 15% midterm, 5% for asst 1, 5% for asst 2, 10% for asst 3, and 15% for asst 4 (the capstone project).

Course Text and Software

This course uses the textbook Modern Robotics: Mechanics, Planning, and Control, Kevin M. Lynch and Frank C. Park, Cambridge University Press 2017. If you find an error or typo in the book, please report it here.

Get the book, install and test the Modern Robotics code library, and install and test the CoppeliaSim robot simulator. You will program in Python, Mathematica, or MATLAB in this course.

Here is a linear algebra refresher appendix to accompany the book.

Approximate Syllabus and Schedule

Here is a summary of the structure of the course. All items are due 30 minutes before the associated class time (1:30 PM Central). The deadlines are controlled by Coursera, so do not be late! You may work ahead if you wish, but then you won't get as much out of the classes.

  • Coursera refers to "weeks," but ignore this; our course modules are not a week long.
  • Before some classes, you should complete a quiz on earlier material.
  • Before most classes, you will watch the associated videos on Coursera and answer the "lecture comprehension" (LC) questions. (Designed to be relatively quick, to solidify your understanding.)
  • You are encouraged to read the corresponding portions of the textbook after watching the videos. I suggest you watch first, then read, then possibly re-watch, but you can determine what works best for your learning style.
  • During the class period after you watch those videos, I will typically summarize what we learned, work a problem, take any questions you have about the material, and possibly assign you a problem to work on.
  • There are two kinds of assessments on Coursera (Coursera refers to both of them as "quizzes"): "lecture comprehension" questions (LCs), which are short and immediately follow lectures, and summative quizzes, which are usually longer assessments/assignments occurring at the middle or end of a chapter.
  • Within Coursera there are also "discussion prompts," open-ended group questions that you should reply to (responses can be simple) and forums where you can post questions and reply to other students' questions.
  • Assignments outside Coursera will be submitted through Canvas.

Below is the approximate syllabus and schedule. Next to each date is the Coursera material that should have been covered at least 30 minutes before that class. "LC" refers to brief lecture comprehension questions that should be completed before that class, and "quiz" is a longer summative quiz on earlier material.

Chapter 2, Configuration Space

  • Wed Sept 25: welcome to the course and syllabus review; intro to Coursera. The schedule for completing Coursera items is set by this wiki!
  • Fri Sept 27: check for working CoppeliaSim implementation and summarize installation process for each OS; make sure Coursera invitation is accepted; material through Chapter 2.2 (3 videos and 2 LCs on dof of a robot) CLASS SLIDES
  • Mon Sept 30: meet the class; and material through Chapter 2.3 (quiz, Chapter 2 through 2.2; 2 videos and 2 LCs on C-space topology and representation) CLASS SLIDES
  • Wed Oct 2: finish Chapter 2 (2 videos and 2 LCs on configuration and velocity constraints, task space and workspace) CLASS SLIDES

Chapter 3, Rigid-Body Motions

  • Fri Oct 4: through Chapter 3.2.1 (quiz, Chapter 2.3 through 2.5; 3 videos and 3 LCs on rotation matrices SO(3)) CLASS SLIDES
  • Mon Oct 7: finish Chapter 3.2 (3 videos and 3 LCs on angular velocities, so(3), exponential coordinates) CLASS SLIDES
  • Wed Oct 9: Asst 1 assigned, due Wed Oct 11. New material: through Chapter 3.3.2 (quiz, Chapter 3 through 3.2; 3 videos and 3 LCs on transform matrices SE(3) and twists) CLASS SLIDES
  • Fri Oct 11: finish Chapter 3 (2 videos and 2 LCs on se(3), exponential coordinates, and wrenches) CLASS SLIDES

Chapter 4, Forward Kinematics (skip section 4.2 on URDF)

  • Mon Oct 14: finish Chapter 4 (quiz, Chapters 3.3 and 3.4; 3 videos and 3 LCs on product of exponentials formula, space and e-e frame) CLASS SLIDES

Chapter 5, Velocity Kinematics and Statics

  • Wed Oct 16: ASST 1, DUE 1:30 PM. New material: through Chapter 5.1 (quiz, Chapter 4; 3 videos and 3 LCs on space Jacobian, body Jacobian) CLASS SLIDES
  • Fri Oct 18: ASST 1, DUE 1:30 PM. New material: through Chapter 5.2 1 video and 1 LC on statics of open chains) CLASS SLIDES
  • Mon Oct 21: through Chapter 5.4 (2 videos and 2 LCs on singularity analysis, manipulability) CLASS SLIDES

Chapter 6, Inverse Kinematics (focus on section 6.2)

  • Wed Oct 23: Chapter 6 (quiz, Chapter 5; 3 videos and 3 LCs on numerical inverse kinematics) CLASS SLIDES

Chapter 8, Dynamics of Open Chains (skip sections 8.4, 8.7, 8.8, and 8.9)

  • Fri Oct 25: through Chapter 8.1.2 (quiz, Chapter 6; 2 videos and 2 LCs on Lagrangian dynamics) CLASS SLIDES
  • Mon Oct 28: New material: Chapter 8.1.3 (1 video and 1 LC on understanding the mass matrix) CLASS SLIDES
  • Wed Oct 30: MIDTERM, chapters 2-5 (no electronic devices allowed [calculator, laptop, tablet, etc.]; study sheets and book allowed) 2022 midterm and solutions (average score 22.9/32); 2023 midterm and solutions; 2024 midterm and solutions
  • Fri Nov 1: Guest lecture by Dan L. Chapter 8.2 (2 videos and 2 LCs on dynamics of a single rigid body) CLASS SLIDES
  • Mon Nov 4: Chapter 8.3 and 8.5 (2 videos and 2 LCs on Newton-Euler inverse dynamics, forward dynamics; quiz, Chapter 8 through 8.3) CLASS SLIDES

Chapter 9, Trajectory Generation

  • Wed Nov 6: ASST 2, DUE 1:30 PM. New material: through Chapter 9.3 (3 videos and 3 LCs on point-to-point trajectories, polynomial via point trajectories) CLASS SLIDES
  • Fri Nov 8: ASST 2, DUE 1:30 PM. Chapter 9.4 (quiz, Chapter 9 through 9.3; 3 videos and 3 LCs on time-optimal time scaling) CLASS SLIDES
  • Mon Nov 11: Chapter 9.4 recap.
  • Wed Nov 13: ASST 3, DUE 1:30 PM. Final project discussion

Chapter 11, Robot Control (focus on sections 11.1 through 11.4)

  • Fri Nov 15: ASST 3, DUE 1:30 PM. New material: up to (not including) Chapter 11.2.2.1 (quiz, Chapter 9.4; 3 videos and 3 LCs on linear error dynamics) CLASS SLIDES
  • Mon Nov 18: finish Chapter 11.2.2 (2 videos and 2 LCs on first- and second-order error dynamics) CLASS SLIDES
  • Wed Nov 20: through Chapter 11.3 (3 videos and 3 LCs on motion control with velocity inputs) CLASS SLIDES
  • Fri Nov 22: CLASS CANCELED. Coursera material is still due. Chapter 11.4 (quiz, Chapter 11 through 11.3; 3 videos and 3 LCs on motion control with torque or force inputs) CLASS SLIDES

Chapter 13, Wheeled Mobile Robots (skip section 13.3)

  • Mon Nov 25: FINAL PROJECT MILESTONE 2, DUE 1:30 PM; new material through Chapter 13.2 (quiz, Chapter 11.4; 3 videos and 3 LCs on omnidirectional wheeled mobile robots) CLASS SLIDES
  • Wed Nov 27: CLASS CANCELED (Happy Thanksgiving!)
  • Mon Dec 2: Chapter 13.4 (quiz, Chapter 13 through 13.2; 1 video and 1 LC on odometry) CLASS SLIDES
  • Wed Dec 4: Chapter 13.5 (1 video and 1 LC on mobile manipulation) CLASS SLIDES
  • Fri Dec 6: wrap-up
  • Thurs Dec 12, noon: final project due

Practice Exercises

Sample exercises and their solutions, useful for practicing your understanding of the material.

Practice Tests

Assignments

As mentioned above, in the Honor Code: You are encouraged to discuss the material with the instructor, course assistants, and your classmates, but you are not allowed to share your answers or code with others. Anyone asking for answers or code, or providing answers or code, or becoming aware of others doing so without reporting to the instructor, is considered in violation of the honor code.

Assignments are graded based on correctness, how well you organize your homework (it should be easy to understand your thinking and easy to find your responses), and how well you follow the submission instructions below. You will lose points if you don't follow these instructions. If more detailed submission instructions are given with a particular assignment, make sure to follow those, too.

You will not receive credit if you just give an answer. Your solution must demonstrate how you got the answer. It must be easy to follow.

If you ever think a problem is stated incorrectly, not enough information is given, or it is impossible to solve, don't panic! Simply make a reasonable assumption that will allow you to solve the problem (but clearly state what this assumption is), or indicate why it is not possible to solve the problem.

Instructions for uploading assignments to Canvas:

  • Upload on time! Late submissions are not accepted.
  • For every assignment, you should submit a single zip file, named FamilyName_GivenName_asst#.zip. This zip file should include a single pdf file with answers to all the questions, including screen shots, text logs of code running, etc. Always include output of your code running on the exercises, so the grader can see what you got when you ran your code. You may scan handwritten solutions (provided they are neat!), but in any case, all answers should be in a single pdf file. DO NOT UPLOAD SCANS AS JPGS! THEY MUST ALL BE COMPILED INTO A SINGLE PDF FILE.
  • You may be asked to include in your zip file all source code in their original forms, such as .m, .py, or .nb. Always create a script that the grader can easily invoke to run your code for a particular exercise. Don't expect the grader to search through your code to find sample code to cut-and-paste. Make it as easy as possible for the grader (you can include a "README.txt" file in your zip file, for example, to tell the grader how everything works). Your code should be commented well enough that it is easy for someone else to pick it up and understand more or less how it works. All student-written code must be submitted; do not submit any standard MR code.
  • If you include movies, keep them short and clear. They should only be a few MB in size. For example, you don't need super high resolution, 60 fps, etc.
  • All plots should be labeled (axes, legends, titles) with appropriate units.

Assignment 1, due 1:30 PM CT Wednesday October 16 Friday October 18 on Canvas.

Assignment 2, due 1:30 PM CT Wednesday November 6 Friday November 8 on Canvas.

Assignment 3, due 1:30 PM CT Friday November 15 on Canvas.


Final Project: Mobile Manipulation

The final project is described on this page. It is due in Canvas on Thursday December 12 at noon.

  • Due Monday November 25 at 1:30 PM on Canvas: Milestone 2. (You will do milestone 2 first! Milestone 1 will come next.) You will turn in a single zip file named FamilyName_GivenName_milestone2.zip with your solution to milestone 2. The zip file should include a README.pdf file with a brief summary of your solution and how to use it, and if your code is not working properly, it should correctly point out the problems. The zip file should also include a directory with the commented code you wrote, including a cut-and-pastable comment at the beginning showing how to execute the code to generate the csv file included in the submission; a CoppeliaSim video showing your reference trajectory of the end-effector (similar to this video); and the csv file that your code generated to create the video.
  • Due Thursday December 12 at 12:00 PM (noon) on Canvas: The entire final writeup in a single zip file named FamilyName_GivenName_capstone.zip. You may earn up to 10% extra credit on the capstone project by implementing singularity and self-collision avoidance. See the description of the final project writeup.