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Questions Lec. Notes Piazza Course Staff KeYmaera Autolab Grand Prix |
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- DESCRIPTION:
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Cyber-physical systems (CPSs) combine cyber
capabilities (computation and/or communication) with physical
capabilities (motion or other physical processes).
Cars, aircraft, and robots are prime examples, because they
move physically in space in a way that is determined
by discrete computerized control algorithms.
Designing these algorithms to control
CPSs is challenging due to their tight coupling with physical behavior.
At the same time, it is vital that these algorithms be correct,
since we rely on CPSs for safety-critical tasks like keeping aircraft from colliding.
In this course we will strive to answer the fundamental question posed by Jeannette Wing:
"How can we provide people with cyber-physical systems they can bet their lives on?"
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Students who successfully complete this course will:
- Understand the core principles behind CPSs.
- Develop models and controls.
- Identify safety specifications and critical properties of CPSs.
- Understand abstraction and system architectures.
- Learn how to design by invariant.
- Reason rigorously about CPS models.
- Verify CPS models of appropriate scale.
- Understand the semantics of a CPS model.
- Develop an intuition for operational effects.
The cornerstone of our course design are hybrid programs (HPs), which capture relevant dynamical aspects of CPSs in a simple programming language with a simple semantics. One important aspect of HPs is that they directly allow the programmer to refer to real-valued variables representing real quantities and specify their dynamics as part of the HP.
This course will give you the required skills to formally analyze the CPSs that are all around us -- from power plants to pace makers and everything in between -- so that when you contribute to the design of a CPS, you are able to understand important safety-critical aspects and feel confident designing and analyzing system models. It will provide an excellent foundation for students who seek industry positions and for students interested in pursuing research.
- NEWS:
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- Upcoming CPS V&V Grand Prix competition for the final projects.
- Support and contributions by CPS experts for the CPS V&V Grand Prix competition for the final projects has been announced.
- The preparatory summer assignment (theory assignment 0) has been released.
- PREREQUISITES:
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- 15-122 Principles of Imperative Computation (or equivalent)
- and 21-122 Integration, Differential Equations, and Approximation (or equivalent)
- and (15-251 Great Theoretical Ideas in Computer Science or 21-241 Matrix algebra or 18-202 Mathematical Foundations of Electrical Engineering or equivalent)
This course counts as a Logics/Languages elective in the Computer Science curriculum. - TEXTBOOK: (optional)
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André Platzer.
Logical Analysis of Hybrid Systems:
Proving Theorems for Complex Dynamics.
Springer, Heidelberg, 2010. 426 pages. ISBN 978-3-642-14508-7.
[bib | ⧉ | doi | book | web | errata | abstract]
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André Platzer.
Foundations of Cyber-Physical Systems.
Lecture Notes, Computer Science Department, Carnegie Mellon University. 2014.
[bib | ⧉ | pdf | textbook | course]
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André Platzer.
- METHOD OF EVALUATION:
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Grading will be based on a set of homework assignments (22%), labs (51%) including a final project entering the CPS V&V Grand Prix worth 22%, a midterm exam (11%), a final exam (11%), and participation in class and in online comments (5%).
Grading is based on the point total of 1360 points giving the above percentages approximately.
The exact distribution of points is still in flux but will work roughly as indicated.
Midterm: 150 points, Wed 10/08 during lecture time. Closed book, one double-sided sheet of hand-written notes permitted. Final: 150 points, Wed 12/03 during lecture time. Closed book, one double-sided sheet of hand-written notes permitted. Grand Prix: Wed 12/10, CPS V&V Grand Prix for presenting final projects to a panel of experts in CPS. - PRIOR INSTANCES:
- Prior instances of the course: F2013
The instructors greatly appreciate the help by other members of the Logical Systems Lab, especially Sarah Loos, Khalil Ghorbal, Stefan Mitsch.