ME CS 133 2018-19

From Robotics
Revision as of 14:41, 11 February 2019 by Jwb (Talk | contribs) (Intro to Estimation/SLAM)

Jump to: navigation, search

This is a homepage for ME/CS 133(a) (Introduction to Robotics) for Fall/Winter 2018-19. We will also use the Caltech Moodle" system for submitting homeworks, lab assignments, and final project reports.


Course Staff, Hours, Location

Position Name Office Office Hours (changing weekly) Email Phone
Instructor Joel Burdick 245 Gates-Thomas send mail for an appointment jwb at robotics dot caltech dot edu 626-395-4139
Teach Asst. Amanda Bouman 205 Gates-Thomas TBD me133tas at robotics dot caltech dot edu 626-395-4470
Teach Asst. Anushri Dixit 205 Gates-Thomas TBD me133tas at robotics dot caltech dot edu 626-395-4470
Teach Asst. Andrew Singletary Gates-Thomas TBD me133tas at robotics dot caltech dot edu 626-395-????
Administrative Sonya Lincoln 250 Gates-Thomas 7:30am-noon; 1:00pm-4:30pm lincolns at caltech dot edu 626-395-3385


Lecture Schedule: Monday, Wednesday, Friday, 3:00-3:55 pm, 135 Gates-Thomas

Announcements For ME/CS 133(a,b)

  • 01/18/19: Lab 1b is due on MONDAY. The T.A.s should have emailed to your group the data from your lab scripts.
  • Lab 1b, additional code:
    • Run this file before sending any commands to check your trajectory. Open rviz in another terminal and add the marker from the published topic. The marker will follow the /bebop/cmd_vel commands.
    • In case you are missing your files from Lab 1, they are missing some values or they are corrupted, you can do the analysis on the files in this zip directory. It includes the output file bebop.csv, python script that generated the file, the matlab script to read the output file lab_csv_analysis.m. Run this file to get a comparison between the commanded path, the path bebop though it was doing and the true path from Optitrack
  • 12/07/2018: Please mail a copy of your lab 2 report to Andrew Singletary ( drewsingletary1@gmail.com )
  • 11/30/2018: The Final Project Instructions were distributed in class.

Course Text and References

The main course text for ME/CS 133(a) is:

We will refer to this text as MLS (the initials of the authors' last names). While the course topics will follow the text, additional material will often be presented in class. Additional course handouts covering this material will be posted on this website

A main text for the ME/CS 133(b) is: Planning Algorithms by Steve LaValle (UIUC).

The following two books are recommended (but not required) for ME/CS 133(b):

  • Principles of Robot Motion: Theory, Algorithms, and Implementations, by Howie Choset, Kevin Lynch, Seth Hutchinson, George Kantor, Wolfram Burgard, Lydia Kavraki, and Sebastian Thrun.
  • Probabilistic Robotics, S. Thrun, W. Burgard, D. Fox, MIT Press, 2006.

This first text is available at Amazon in both new and used versions. The probabilistic robotics text has an associated website, and is similarly available on Amazon.

Grading

For ME/CS 133(b), the final grade will be based on a few homework sets, laboratories, and a final project:

  • Homework (20%): Homework sets are due at 5 pm on the due date (which will always coincide with a class meeting). Homeworks can be dropped off in class, or deposited in the box outside of 245 Gates-Thomas. Some homeworks will require computation. MATLAB or Mathematica should be sufficient to solve every homework posed in ME/CS 133(a), though students can choose their favorite programming language. Code is considered part of your solution and should be included in with the problem set when appropriate. ME/CS 133(b) will require a bit more knowledge of coding in C++ or python.
  • Laboratory (40%): Lab reports are due at 5 pm on the due date (which will usually coincide with a class meeting). Labs can be dropped off in class, or deposited in the box outside of 245 Gates-Thomas. The first labs will familiarize students with the class robots. Subsequent labs will focus on how to translate the lecture material to the lab robots, and will often involve the use of software systems such as ROS and OOMPL.
  • Final project (40%): The final project must incorporate some aspect of the course, and the topic and scope my be approved by the course instructor. The final exam will due at 5:00 pm the last day of finals. The final project is similarly due at 5:00 pm on the last day of finals.
  • Late Homework Policy: Students may automatically take a 2-day extension on two homeworks or labs during each quarter.

Collaboration Policy

Collaboration on homework assignments is encouraged. You may consult outside reference materials, other students, the TA, or the instructor, but you must cite any use of material from outside references. All solutions that are handed in should be written up individually and should reflect your own understanding of the subject matter. Computer code and graphical plots are considered part of your homework solution, and therefore should be done individually (you can share ideas, but not code).

Laboratory assignments will be performed in small teams. Collaboration on laboratory assignments is different. Each team need only submit one laboratory report.

Course Lecture Schedule for ME/CS 133(b)

Week Date Topic Reading Optional Reading Homework
1
Review of Quadcopters, Intro to Motion Planning
7 Jan. (Mon.) ME 133(b) Class Overview,
Quadcopter Review,
Intro to Motion Planning
Course Overview,
Brief Review of Quadcopter Mechanics/Control
-Lab 1b -
Python Template
9 Jan. (W) Motion Planning Intro (continued) Lavalle, Chapter 1
11 Jan. (F) Motion Planning problems, and c-space intro
2
Intro to Motion Planning
14 Jan. (Mon.) Configuration Space Obstacles Lavalle Chapter 3.1, Visualization of C-obstacles Wolfram 2R c-obstacle demo - N/A-
16 Jan. (W) Motion Planning Intro & Road Maps Lavalle Chapter 3.1 on c-obstacles
17 Jan. (F) Road Maps Continued Lavalle Chapter 6.1, 6.2
3
RoadMap Motion Planning Methods
21 Jan. (Mon.) No Class, Institute MLK Holiday Homework #1b
23 Jan. (W) Generalized Voronoi Graphs Lavalle Chapters 6.1 and 6.2 on Roadmaps
25 Jan. (F) Intro to Sample-Based Planners
4
Sample-Based Planners, Cellular Decomposition
28 Jan. (Mon.) No Class, Burdick sick -N/A-
30 Jan. (W) Random Dense Trees Lavalle Chapter 5
1 Feb. (F) Cellular Decomposition Lavalle Chapt. 6.3
5
Inertial Navigation, Odometry
4 Feb. (Mon.) Inertial Navigation Notes on the Kinematics of Inertial Navigation Lab 2 Instructions
(Due Feb. 20, 2019)
6 Feb. (W) Inertia Navigation continued
8 Feb. (F) Visual Odometry Laser Scan Matching by Lu and Milsios
6
Intro to Estimation/SLAM
11 Feb. (Mon.) Scan Matching
Probability Review
-N/A-
13 Feb. (W) More probability
Intro to Occupancy Grid Mapping
15 Feb. (F) Occupancy Grid Mapping

Course Lecture Schedule for ME/CS 133(a)

Week Date Topic Reading Optional Reading Homework
1
Introduction and Review of Rigid Body Kinematics
1 Oct. (Mon.) Class Overview Course Overview,
Chapter 1 of MLS,
Introduction to the DARPA Subterranean Challenge
History of Kinematics Through 1900 (Introductory chapter from Kinematic Synthesis of Linkages) -No Homework-
3 Oct. (W) Planar Rigid Body Kinematics,
Planar displacements
MLS Ch 2.1, Pages 19-23 Wikipedia Page on the Peaucellier Mechanism
5 Oct. (F) Planar Rigid Body Displacements (continued),
Displacement groups
MLS Ch 2.1,

Change of Reference in Planar Displacements (PowerPoint)

-N/A-
2
From Planar Rigid Body Kinematics to Spherical Kinematics
08 Oct. (M) poles, Centrodes, elliptic Trammel
Notes on the Elliptical Trammel Archemides Trammel (Wikipedia)
Trammel, V 1, V 2, compliation,
Linkages Synthesized Using Cardan Motion Along Radial Lines
Homework 1,
(Due Wed. Oct. 17)
Solution 1
10 Oct. (W) Intro to Spherical Kinematics MLS Pages 22-26,
Notes on the Classical Matrix Groups
-N/A-
12 Oct. (F) Spherical Kinematics (continued),
Classical Matrix Groups
MLS Ch 2.2, 2.3,
Notes on Rotations
Herman Weyl's book on the classical groups
3
Spherical Kinematics
15 Oct. (M) Cayley's Theorem, Euler's Theorem MLS 27-31 Wikipedia Page on Cayley Transform Homework 2
(Due Oct. 26)
Solution #2
17 Oct. (W) Angle-Axis Representation, Rodriguez Formula, Matrix Exponential, -N/A-
19 Oct. (F) Euler Angles MLS 31-34 -N/A-
4
Spherical Kinematics
22 Oct. (M) Quaternions MLS 33-34 Notes On Algebras -N/A-
24 Oct. (W) Quaternion Wrap-Up,
Intro to Spatial Kinematics,
Homogeneous Coordinates,
MLS 34-39 -N/A-
26 Oct. (F) Spatial Exponential Coordinates,
Intro to screws
MLS 39-45
MLS 45-50
-N/A-


5
Spatial Kinematics and Velocities
29 Oct. (M) Motion Capture Using Rodriguez' Displacement Equation,
Quaternion-Based Displacement Estimation
MLS 51-56
Horn paper on Quaternion-Based Displacement Estimation Lab 1
Zip File with lab1 data and MATLAB scripts
31 Oct. (W) Rigid Body Velocities
MLS 57-64 -N/A-
2 Nov. (F) Rigid Body Velocities and Coordinate Transformations MLS 51-56 -N/A-
6
Multi-Body Kinematics
5 Nov. (M) Wrenches MLS Chapter 2, Sections 5.1 and 5.2
7 Nov. (W) Joints -N/A-
10 NOV. (F) Multi-Body Kinematics MLS Chapter 3, Sections 1 and 2 -N/A-
7
ROS Tutorials
12 Nov. (M) ROS Tutorial ROS Tutorial Python script for ROS Tutorial
14 Nov. (W) In-class tutorial on Running ROS -N/A-
16 NOV. (F) NO CLASS -N/A-
8
Forward Kinematics
19 Nov. (M) Denavit-Hartenberg Convention Scan of Craig Book on D-H Parameters
21 Nov. (W) More Forward Kinematics, Jacobians -N/A-
23 NOV. (F) NO CLASS, Thanksgiving Holiday -N/A-
9
Jacobian & Differential Drive Kinematics
26 Nov. (M) Jacobians, Differential Drive Kinematics MLS Chapter 3, Section 4, pages 115- 121
Kinematics of a Differential Drive Vehicle
Lab 2 Instructions
Lab 2 Modifiable Python Script
28 Nov. (W) Differential Drive Kinematics -N/A-
30 Nov. (F) Inverse Kinematics MLS Chapter 3, pages 97-99 -N/A-
10
Inverse Kinematics, Intro to Quadrotors
3 Dec. (M) Inverse Kinematics Continued MLS Chapter 3, pages 108-114
5 Dec. (W) Intro to Multi-Rotors: dynamics -N/A-
7 Dec. (F) Multi-Rotors: basics of control -N/A-