Difference between revisions of "Mathematical and theoretical biology"

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Describing systems in a quantitative manner means their behavior can be better simulated, and hence properties can be predicted that might not be evident to the experimenter.
 
Describing systems in a quantitative manner means their behavior can be better simulated, and hence properties can be predicted that might not be evident to the experimenter.
  
Mathematical biology may deploy [[calculus]], [[probability theory]], [[statistics]], [[linear algebra]], [[abstract algebra]], [[graph theory]], [[combinatorics]], [[algebraic geometry]], [[topology]], [[dynamical systems]], [[differential equations[[ and [[coding theory]].
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Mathematical biology may deploy [[calculus]], [[probability theory]], [[statistics]], [[linear algebra]], [[abstract algebra]], [[graph theory]], [[combinatorics]], [[algebraic geometry]], [[topology]], [[dynamical systems]], [[differential equations]] and [[coding theory]].
  
 
Some mathematical areas, such as certain methodologies in statistics, were developed as tools during the conduct of research into mathematical biology.
 
Some mathematical areas, such as certain methodologies in statistics, were developed as tools during the conduct of research into mathematical biology.
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* [[Systems biology]]
 
* [[Systems biology]]
 
* [[Theoretical ecology]]
 
* [[Theoretical ecology]]
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* [[Vito Volterra]] - Italian [[mathematician]] and [[physicist]], known for his contributions to Mathematical and theoretical biology|mathematical biology and [[Integral|integral equations]], being one of the founders of [[functional analysis]].
  
 
== External links ==
 
== External links ==

Latest revision as of 04:42, 25 August 2016

Mathematical and theoretical biology is an interdisciplinary scientific research field combining [[[mathematics]] and biology, with a range of applications in biology, biotechnology, and medicine.

The field is also called mathematical biology or biomathematics to stress the mathematical side, or theoretical biology to stress the biological side.

Description

Mathematical biology aims at the mathematical representation, treatment and modeling of biological processes, using a variety of applied mathematical techniques and tools.

It has both theoretical and practical applications in biological, biomedical and biotechnology research.

For example, in cell biology, protein interactions are often represented as "cartoon" models, which, although easy to visualize, do not accurately describe the systems studied. This requires precise mathematical models.

Describing systems in a quantitative manner means their behavior can be better simulated, and hence properties can be predicted that might not be evident to the experimenter.

Mathematical biology may deploy calculus, probability theory, statistics, linear algebra, abstract algebra, graph theory, combinatorics, algebraic geometry, topology, dynamical systems, differential equations and coding theory.

Some mathematical areas, such as certain methodologies in statistics, were developed as tools during the conduct of research into mathematical biology.

See also

External links