Difference between revisions of "Robotics"
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The following are last minute news you should be aware of ;-) | The following are last minute news you should be aware of ;-) | ||
+ | 15/07/2016: published results of the first call of the exam, as well al the texts of the exam itself | ||
23/06/2016: Published the slides also in ppsx format | 23/06/2016: Published the slides also in ppsx format | ||
15/06/2016: Published the updated and final version of the project description | 15/06/2016: Published the updated and final version of the project description |
Revision as of 01:00, 15 July 2016
The following are last minute news you should be aware of ;-)
15/07/2016: published results of the first call of the exam, as well al the texts of the exam itself 23/06/2016: Published the slides also in ppsx format 15/06/2016: Published the updated and final version of the project description 13/06/2016: Deadline for the course project is July, fixed on the course webpage 23/05/2016: Course schedule change on 24-25/5 and 8-9/6 16/05/2016: Some updates on the detailed course schedule ... 12/05/2016: Published course project description v0.9 04/05/2016: Published slides about SLAM with Laser and SLAM 04/05/2016: Published slides about ROS robot architecture for navigation and code examples 14/04/2016: Change in course detailed schedule: no lecture on 27/04/2016 and swap of teachers between 20/04 and 28/04 14/04/2016: Published slides about Kinematics and Motion Control (draft) by Matteucci 13/04/2016: Published slides about Middlewares and ROS by Bardaro 19/03/2016: Published slides about Sensors, Actuators (Matteucci) and Gazebosim (Bardaro) 09/03/2016: Change in course timetable, lectures start at 14:00 (sharp!) and end at 15:30 (roughly) 09/03/2016: Lectures start today!!
Contents
Course Aim & Organization
This course will introduce basic concepts and techniques used within the field of autonomous mobile robotics. We analyze the fundamental challenges for autonomous intelligent systems when these move on wheels or legs and present the state of the art solutions currently employed in mobile robots and autonomous vehicles.
Teachers
The course is composed by a blending of lectures and exercises by the course teacher and a teaching assistant.
- Matteo Matteucci: the course teacher
- Gianluca Bardaro: the teaching assistant
Course Program
Lectures will provide theoretical background and real world examples. Lectures will be complemented with practical exercises in simulation for all the proposed topics and the students will be guided in developing the algorithms to control an autonomous robot.
Among other topics, we will discuss:
- Mobile robots kinematics,
- Sensors and perception,
- Robot localization and map building,
- Simultaneour Localization and Mapping (SLAM),
- Path planning and collision avoidance,
- Exploration of unknown terrain.
Detailed course schedule
A detailed schedule of the course can be found here; topics are just indicative while days and teachers are correct up to some last minute change (I will notify you by email). Please note that not all days we have lectures!!
Note: Lecture timetable interpretation * On Wednesdays, in E.G.2, starts at 14:00, ends at 15:30 * On Thursday, in D.1.1, starts at 14:00, ends at 15:30
Date | Day | Time | Room | Teacher | Topic |
09/03/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Course Introduction |
10/03/2016 | Thursday | 14:00 - 15:30 | D11 | Matteo Matteucci | Sensors and Actuators |
16/03/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Sensors and Actuators |
17/03/2016 | Thursday | 14:00 - 15:30 | D11 | Gianluca Bardaro | Gazebosim and URDF |
23/03/2016 | Wednesday | 14:00 - 15:30 | EG3 | Gianluca Bardaro | Differential drive in Gazebo |
24/03/2016 | Thursday | 14:00 - 15:30 | -- | -- | No Classes |
30/03/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Sensors and Actuators |
31/03/2016 | Thursday | 14:00 - 15:30 | D11 | Matteo Matteucci | Robot kinematics |
06/04/2016 | Wednesday | 14:00 - 15:30 | EG3 | Gianluca Bardaro | Middleware for robotics |
07/04/2016 | Thursday | 14:00 - 15:30 | D11 | Gianluca Bardaro | A gentle introduction to ROS |
13/04/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Robot kinematics |
14/04/2016 | Thursday | 14:00 - 15:30 | D11 | Matteo Matteucci | Robot navigation algorithms |
20/04/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Trajectory planning introduction |
21/04/2016 | Thursday | 14:00 - 15:30 | D11 | Gianluca Bardaro | Differential drive control in ROS |
27/04/2016 | Wednesday | 14:00 - 15:30 | -- | -- | No Classes |
28/04/2016 | Thursday | 14:00 - 15:30 | D11 | Gianluca Bardaro | Trajectory planning and navigation in ROS |
04/05/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Trajectory planning (continued) |
05/05/2016 | Thursday | 14:00 - 15:30 | D11 | Matteo Matteucci | Introduction to probability and Simultaneous Localization and Mapping (SLAM) |
11/05/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Occupancy grids and Laser sensor model |
12/05/2016 | Thursday | 14:00 - 15:30 | D11 | Matteo Matteucci | Mapping with known poses and scan matching + Project presentation |
18/05/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | EKF-SLAM and FAST Slam |
19/05/2016 | Thursday | 14:00 - 15:30 | D11 | Matteo Matteucci | Particle filters and Monte Carlo Localization |
25/05/2016 | Wednesday | -- | -- | -- | No Classes |
26/05/2016 | Thursday | -- | -- | -- | No Classes |
01/06/2016 | Wednesday | 14:00 - 15:30 | EG3 | Gianluca Bardaro | ROS tf + actionlib |
02/06/2016 | Thursday | -- | -- | -- | No Classes |
08/06/2016 | Wednesday | 14:00 - 15:30 | EG3 | Gianluca Bardaro | ROS Navigation with movebase |
09/06/2016 | Thursday | 14:00 - 15:30 | D11 | Gianluca Bardaro | Ros Navigation with movebase (continued) |
15/06/2016 | Wednesday | 14:00 - 15:30 | EG3 | Matteo Matteucci | Questions and answers about theory |
16/06/2016 | Wednesday | 14:00 - 15:30 | EG3 | Gianluca Bardaro | Questions and answers about project and exercises |
Course Evaluation
Course evaluation is composed by two parts:
- A written examination covering the whole program graded up to 27/32
- A home project in simulation practicing the topics of the course graded up to 5/32
the final score will sum the grade of the written exam and the grade of the home project.
In some (exceptional) cases the home project could be substituted with a lab project, possibly with a slightly higher grade, but this has to be motivated and discussed with the teacher.
Course Project
In the course project you will use ROS and Gazebo to develop a simple autonomous mobile robot performin a simple task. The project requires some coding either in C++ / Python following what will be presented during the lectures. The project will be presented mid May and you will have until the end of July to complete it.
Teaching Material (the textbook)
Lectures will be based on material from different sources, teachers will provide their slides to students as soon they are available.
Course Slides
Slides from the lectures by Matteo Matteucci
- [2015/2016] Course introduction: introductory slides of the course with useful information about the course syllabus, grading, and the course logistics. Introduction to Robotics, definitions, examples and SAP cognitive model. (pdf) (ppsx)
- [2015/2016] Sensors and Actuators: an overview of most commonly used actuator and sensors in robotics, the DC motor and its characteristics, gears and torque. (pdf) (ppsx)
- [2015/2016] Mobile Robots Kinematics: mobile (wheeled) robot kinematics, holonomic and non holonomic constraints, differential drive model. (pdf) ppsx
- [2015/2016] Robot Motion Control: mobile robot navigation, trajectory planning, trajectory following, and obstacle avoidance. (pdf) (ppsx)
- [2015/2016] SLAM with Lasers: introduction to Simultaneous Localization and Mapping, EKF based SLAM, Particle Filters, and Monte Carlo Localization. (pdf) (ppsx)
Slides from the lectures by Gianluca Bardaro (you can find material under preparation at this link)
- [2015/2016] Gazebosim and SDF: an introduction to robotics simulators, an overview of Gazebo, its use, and the SDF file format to describe a robot simulation.
- [2015/2016] Gazebosim and plugins: more about simulation with Gazebo, modeling of a caster wheel, modeling of noise with Gazebo plugins, the GPS example.
- [2015/2016] Middleware in Robotics: an introduction to the use of middleware for robotics, motivation and state of the art review.
- [2015/2016] ROS Introduction: a gentle introduction to the Robot Operating System, most used commands and utilities.
- [2015/2016] ROS Architecture: an example of motion control architecture implemented in ROS, integration with Gazebo, introduction to tf.
- [2015/2016] Transformation Frames: reference frames and the tf framework to handles transformation frames in ROS.
- [2015/2016] Actionlib: the ROS actionlib package.
Additional material from the teachers
- [2015/2016] willy1.zip: gazebo model for a differential drive with a caster wheel
- [2015/2016] gps.zip: gazebo plugin to simulate a faulty gps sensor
- [2015/2016] lesson_pack.zip: ROS nodes examples with object oriented template of talker and listener
- [2015/2016] willy2.zip: an improved gazebo model for a differential drive with a caster wheel
- [2015/2016] diffdrive.zip: a ROS motion control architecture for a diffdrive robot
Course Project
This year project is divided in steps; each of them is worth some points out of the 5/32 points available for the final mark. You find the project description here, it is complete, it contains parts up to 4, parts 5 is optional, but we suggest to do it anyway since it requires a limited amount of time.:
- 2015/2016 Course Project v1.0
- 2015/2016 Kobra STL files: in case you want to make your simulation look more real here you find the STL files of the Kobra robot in the "Safer" version. Unfortunately the STL files are scaled down with respect to the real robot, so you have to modify those if you want to use.
Some important notes:
- The project can be done in groups of maximum 2 people
- We have decided to follow a sort of “homework approach” so you should do the homework to better understand some key concepts from the course … indeed a few question comes from your colleague observations so blame them!
- We have not decided yet how much each part is worth, we will decide depending on the overall distribution of results in the class to harmonize the overall score.
- Some data might be missing, some data might be useless, do not hesitate to write us by email, for instance, to ask the weight of the robot and learn that it is 14Kg.
Delivery procedure:
- The project should be delivered by email as single compressed file to Matteo Matteucci && Gianluca Bardaro.
- The archive should contain:
- The gazebo model as a directory with SDF files and a ROS package with nodes sources and corresponding launch files (put your names in the directories names)
- A max 4 pages report describing:
- The files provided
- The installation (if any) and compilation instructions
- Instruction to configure the execution (e.g., parameter setting)
- The instructions to execute the code and check that all the above has been done successfully
- The evaluation will be performed by following your instructions, if these do not work, we assume the course project does not work (we suggest you to have someone else testing the whole on his/her computer before submitting the project).
Past Exams and Sample Questions
In the 2015/2016 Academic Year the course has changed significantly and the exam format as well. For this edition of the course we do not have past exams to share with you, should expect 2 theoretical questions + 2 practical exercises (on average), no coding exercise in the exams since you will see some coding already in the home project. During the lectures the teachers will suggest possible exercises you might encounter in the exams.
Additional Resources
If you are interested in a more deep treatment of the topics presented by the teachers you can refer to the following books and papers:
- Probabilistic Robotics by Dieter Fox, Sebastian Thrun, and Wolfram Burgard.
The following are links to online sources which might be useful to complement the material above
- ISO 8373:2012: ISO Standard "Robots and robotic devices -- Vocabulary"
- ROS: the Robot Operating System
- Gazebo: the Gazebo robot simulator
- AIRLab ROS Howto: a gentle introduction to ROS with node template and program examples