The following are last minute news you should be aware of ;-)
02/04/1029: Updated calendar with behavious based architectures lectures 03/03/1029: Change in schedule for the course and updated calendar with Bonarini's lectures 26/02/2019: Here it comes a new edition of the course!!!
Course Aim & Organization
This course addresses the methodological aspects of Cognitive Robotics. Cognitive Robotics is about endowing robots and embodied agents with intelligent behaviour by designing and deploying a processing architecture making them apt to deliberate, learn, and reason about how to behave in response to complex goals in a complex world. Perception and action, and how to model them in neural and symbolic representations are therefore the core issues to address. Inspiring models of Cognitive Robotics arise from different disciplines: the neural architectures from neuroscience, the basic behaviours from ethology, motivations and emotions from psychology, the multirobot behaviour from sociology. Those models could be implemented in terms of formal logic, probabilistic, and neural models turning into embodied computational agents.
The course is composed by a blending of theory and practice lectures from the course teacher and the teaching assistants (in order of appearance):
- Matteo Matteucci: the teacher
- Andrea Bonarini
- Simone Mentasti
Course Program and Teaching Material
The course comprises theoretical lectures (30h) and practical sessions (20h):
- Cognitive Robotics introduction
- Cognition and the sense-plan-act architecture
- Deliberative, reactive, and hybrid approaches
- Deliberative systems for cognitive robots
- Symbolic planning and PDDL
- Bioinspired controllers for autonomous robots
- Behavior based architectures
- Neural networks and learning
- Human-Robot interaction
- Non verbal human robot interaction
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 (they will be notified to you by email).
Note: Lecture timetable interpretation * On Thursday, in V.S7-A, starts at 08:15, ends at 10:15 * On Friday, in V.S7-A, starts at 10:15, ends at 13:15
|26/02/2019||Tuesday||08:15 - 10:15||V.S7-A||Matteo Matteucci||Course Introduction, Robotics and Cognitive Robotics|
|01/03/2019||Friday||10:15 - 13:15||---||---||-- No Lecture --|
|07/03/2019||Thursday||08:15 - 10:15||V.S7-A||Matteo Matteucci||Cognitive architectures: Deliberative vs Reactive|
|08/03/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Cognitive architectures: Deliberative vs Reactive|
|14/03/2019||Thursday||08:15 - 10:15||V.S7-A||Matteo Matteucci||Deliberative architectures and Planning|
|15/03/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Deliberative architectures and Planning|
|21/03/2019||Thursday||08:15 - 10:15||V.S7-A||Andrea Bonarini||Human-Robot (non-verbal) Interaction|
|22/03/2019||Friday||10:15 - 13:15||V.S7-A||Andrea Bonarini||Human-Robot (non-verbal) Interaction|
|28/03/2019||Thursday||08:15 - 10:15||V.S7-A||Andrea Bonarini||Human-Robot (non-verbal) Interaction|
|29/03/2019||Friday||10:15 - 13:15||V.S7-A||Andrea Bonarini||Human-Robot (non-verbal) Interaction|
|04/04/2019||Thursday||08:15 - 10:15||V.S7-A||Matteo Matteucci||Behaviour based architectures|
|05/04/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Behaviour based architectures|
|11/04/2019||Thursday||08:15 - 10:15||V.S7-A||Simone Mentasti||Robot Operating System|
|12/04/2019||Friday||10:15 - 13:15||V.S7-A||Simone Mentasti||Robot Operating System|
|18/04/2019||Thursday||08:15 - 10:15||---||---||-- No Lecture --|
|19/04/2019||Friday||10:15 - 13:15||---||---||-- No Lecture --|
|25/04/2019||Thursday||08:15 - 10:15||---||---||-- No Lecture --|
|26/04/2019||Friday||10:15 - 13:15||---||---||-- No Lecture --|
|02/04/2019||Thursday||08:15 - 10:15||V.S7-A||Simone Mentasti||Project work|
|03/05/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Neural Networks|
|09/05/2019||Thursday||08:15 - 10:15||V.S7-A||Simone Mentasti||Project work|
|10/05/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Neural Networks|
|16/05/2019||Thursday||08:15 - 10:15||V.S7-A||Simone Mentasti||Project work|
|17/05/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Neural Networks|
|23/05/2019||Thursday||08:15 - 10:15||V.S7-A||Simone Mentasti||Project work|
|24/05/2019||Friday||10:15 - 13:15||---||---||-- No Lecture --|
|30/05/2019||Thursday||08:15 - 10:15||V.S7-A||Matteo Matteucci||Neural Networks|
|31/05/2019||Friday||10:15 - 13:15||V.S7-A||Matteo Matteucci||Neural Networks|
|06/06/2019||Thursday||08:15 - 10:15||V.S7-A||TBD||TBD|
|07/06/2019||Friday||10:15 - 13:15||V.S7-A||TBD||TBD|
The course grading is split in a standard written exam and a seminar activity (to be done before the end of the course):
- Written examination covering the whole program (including seminars) up to 27/32
- Seminar on one of the topics of the course graded up to 5/32
- Final score will be the sum of the two grades up to 32/32
Possible seminar topics will be presented later during the semester. A practical activity, to be discussed with the teacher, can substitute the seminar.
The course material comprises slides from the teachers and scientific literature, both provided in the following.
In the following you can find the lecture slides used by the teacher and the teaching assistants during classes.
Here the lectures about classical cognitive architectures, i.e., deliberative and reactive approaches:
- [2017/2018] Cognitive Robotics Introduction: Course introduction and introduction to Robotics, Cognitive Robotics definition.
- [2017/2018] Cognitive Robotics Architectures: Cognitive architectures: deliberative vs reactive approaches.
- [2017/2018] Planning Definitions and Algorithms: Definition of planning, state and action representation, linear vs. non linear planning, GPS and Prodigy. The Planning Domain Definition Language rationale and syntax with examples.
- [2017/2018] Behavior Based Robotics: Introduction to behavior based robotics and the Subsumption Architecture with examples. Hybrid approaches.
- [2017/2018] Neural Networks: From Perceptron to Feed Forward Neural Networks]]: Introduction to neural networks, the perceptron model, feed forward architectures, backpropagation, generalization issues (early stopping and weight decay)
The following are the slides on Non Verbal Human Robot Interaction:
- [2016/2017] Intro and Design Principles: Introduction to Non Verbal Human Robot interaction and its design principles.
- [2016/2017] Sensors and Actuators: Robot sensors and actuators for Human Robot interaction
- [2016/2017] Incidental Interaction: Human Robot Incidental Interaction
- [2016/2017] Time issues: Time issues in Human Robot Interaction
- [2016/2017] Emotions: Non verbal emotion expression
- [2016/2017] Design of interaction: Introduction to Design of Interaction principles and methods
- [2016/2017] Toys and Games: Applications of Human Robot interaction to Toys and Games
Here the slides about ROS and gazebo:
- [2017/2018] Gazebosim and SDL
- [2017/2018] Model details
- [2017/2018] Robotics middlewares
- [2017/2018] ROS Commands
- [2017/2018] ROS Development
- [2017/2018] ROS - Gazebo Interaction
- [2017/2018] BAGs and TF
- [2017/2018] Robot Navigation
Books, Papers, and Media
For some of the following paper I provide the link to the journal website. For the most of them you can access the PDF if you are connected to the polimi network or using the polimi proxy.
- Simon Russell, Peter Norvig. "Artificial Intelligence: A Modern Approach". Chapter 11: Planning, pages 375-416.Pearson, 2010. 
- Valentino Braitenberg. "Vehicles: Experiments in synthetic psychology". Cambridge, MA: MIT Press, 1984.
- Rodney A. Brooks. "Elephants don't play chess", Robotics and Autonomous Systems, Volume 6, Issues 1–2, June 1990, Pages 3-15. 
- Some interesting videos on feed forward neural networks and backpropagation by :
Exam Samples and Results
The following are few past exams, do not make any assumption on the topics you should prepare and about the level of details of the questions from these texts, they are not a statistically significan sample from the possible exams texts: