Algorithmics
- UE code ISBMM103
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Schedule
30 60Quarter 2
- ECTS Credits 8
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Language
Anglais
- Teacher Jacquet Jean-Marie
At the end of the course, the student will master the main computer concepts and methods underlying the modelling of biological systems.
He will be made aware of the parsimonious use of computer resources, whether in terms of computing time, code size, software use or even in software maintenance costs, and, as a result, will be made aware of sustainable development in an IT context.
Some of the major discoveries of the last 50 years are certainly the fact that the genetic heritage of any organism is contained in its DNA, that the genes are reduced to a nucleotide sequence of the DNA and that their expression corresponds to the execution of a program. These observations have raised hopes for a better understanding of diseases and, as a result, the birth of predictive and personalized medicine.
Technological advances have reinforced these hopes. It is indeed less and less expensive and faster to sequence an entire genome. In addition, many databases are now available to biologists.
On the scientific level, it is worth observing that these discoveries and advances are in fact very familiar to the computer scientist. For instance, finding a gene in a DNA sequence is actually amounts to determining whether a sub-sequence of characters appears in another. More generally, it is becoming increasingly clear that modelling biological systems cannot be achieved without the help of computer concepts and methods.
In this context, the objective of the course is to study the major computer concepts and techniques underlying the modelling of biological systems.
The course shows how biological problems, such as the search for pattern and sequence similarity, genome alignment and understanding of genetic regulatory networks can be reduced to problems in computer science using, to name but a few examples, process algebras, ultra-metric trees, Eulerian and Hamiltonian paths, De Bruijn graphs, constraint programming, dynamic programming, Petri networks or automatic learning problems.
In order to allow for efficient programming and correct-by-design programs, the course studies the C language and programming techniques in parallel to the previous concepts.
The student is assessed on two bases: practicals to be done during the semester and an exam. The latter includes both questions on all the material seen during the course as well as on the practicals.
Ph. Compeau et P. Pevzner, Bioinformatics Algorithms : An Active Learning Approach, Active Learning Publishers, 2e édition, 2015
Training | Study programme | Block | Credits | Mandatory |
---|---|---|---|---|
Master 120 en sciences biomédicales, à finalité spécialisée en biomedical data management | Standard | 0 | 8 | |
Master 120 en sciences biomédicales, à finalité spécialisée en biomedical data management | Standard | 1 | 8 |