Difference between revisions of "BCH441 Final Exam"
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Of all data abstractions in bioinformatics, the one-letter amino acid code is the most important one. Whether you are evaluating multiple sequence alignments, database searches or mutational studies, this all requires a confident understanding of the physicochemical nature of the residues you are considering and of course knowing which letters correspond to which amino acids... | Of all data abstractions in bioinformatics, the one-letter amino acid code is the most important one. Whether you are evaluating multiple sequence alignments, database searches or mutational studies, this all requires a confident understanding of the physicochemical nature of the residues you are considering and of course knowing which letters correspond to which amino acids... | ||
− | *[['''Amino Acid Exam Questions''']] | + | *[[Amino_Acid_Exam_Questions|'''Amino Acid Exam Questions''']] |
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Molecules are three-dimensional entities and stereo-vision of images on paper and on the screen is one of the most powerful, intuitive ways to appreciate that. We have practiced stero-vision in this course; here are a number of situations that require spatial awareness... | Molecules are three-dimensional entities and stereo-vision of images on paper and on the screen is one of the most powerful, intuitive ways to appreciate that. We have practiced stero-vision in this course; here are a number of situations that require spatial awareness... | ||
− | *[['''Stereo Vision Exam Questions''']] | + | *[[Stereo_Vision_Exam_Questions|'''Stereo Vision Exam Questions''']] |
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One aspect of Bioinformatics concerns itself with the storage, organisation, and retreival of biological information. The questions in this section consider the contents and use of some of the key abstractions (sequences, structures, graphs ...) that we deal with, and the databases we store them in. | One aspect of Bioinformatics concerns itself with the storage, organisation, and retreival of biological information. The questions in this section consider the contents and use of some of the key abstractions (sequences, structures, graphs ...) that we deal with, and the databases we store them in. | ||
− | *[['''Database Exam Questions''']] | + | *[[Database_Exam_Questions|'''Database Exam Questions''']] |
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− | *[['''Tools Exam Questions''']] | + | *[[Tools_Exam_Questions|'''Tools Exam Questions''']] |
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− | *[[''' | + | *[[Application_Exam_Questions|'''Applications Exam Questions''']] |
Revision as of 04:13, 9 December 2006
This is a collection of questions from final exams through the years. It is not comprehensive, and, since the emphasis is slightly different each year, not all questions would have been covered in class every year.
Amino Acids
Of all data abstractions in bioinformatics, the one-letter amino acid code is the most important one. Whether you are evaluating multiple sequence alignments, database searches or mutational studies, this all requires a confident understanding of the physicochemical nature of the residues you are considering and of course knowing which letters correspond to which amino acids...
Stereo Vision
Molecules are three-dimensional entities and stereo-vision of images on paper and on the screen is one of the most powerful, intuitive ways to appreciate that. We have practiced stero-vision in this course; here are a number of situations that require spatial awareness...
Databases
One aspect of Bioinformatics concerns itself with the storage, organisation, and retreival of biological information. The questions in this section consider the contents and use of some of the key abstractions (sequences, structures, graphs ...) that we deal with, and the databases we store them in.
Tools
Another aspect of bioinformatics concerns algorithms: computational tools that allow us to analyse the data and support our inferences...
Applications
Bioinformatics and computational biology are huge and growing areas of active research with a dynamic array of subspecialities - phylogenetic analysis has advanced in leaps and bounds with the availablity of molecular data, genomic-, transcriptomic-, proteomic and other cross-sectional views are slowly beginning to unravel some of the intricacies of the cell's inner workings, predictive models for molecular medicine and bioengineering may help shape our society's future. These tasks are what motivates bioinformatics worldwide, seeking to develp novel ways to reason about biology...