Description: Biomathematic
Curriculum
- 1 Section
- 39 Lessons
- 10 Weeks
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- Biomathematic39
- 2.1L1-Introduction
- 2.2L2-Graphs and functions – I
- 2.3L3-Graphs and functions – II
- 2.4L4-Functions and derivatives
- 2.5L5-Calculation of derivatives
- 2.6L6-Differentiation and its application in Biology – I
- 2.7L7-Differentiation and its application in Biology – II
- 2.8L8-Differentiation and its application in Biology – III
- 2.9L9-Differentiation and its application in Biology – IV
- 2.10L10-Integration – I
- 2.11L11-Integration – II
- 2.12L12-Differential equations-I
- 2.13L13-Differential equations – II
- 2.14L14-Vectors – I
- 2.15L15-Vectors – II
- 2.16L16-Vectors – III
- 2.17L17-Nernst equation
- 2.18L18-Diffusion-I : Diffusion equation
- 2.19L19-Diffusion – II: Mean-square displacement
- 2.20L20-Diffusion-III : Einstein’s relation
- 2.21L21-Statistics : Mean and variance
- 2.22L22-Statistics: Distribution function
- 2.23L23-Understanding Normal distribution
- 2.24L24-Fitting a function to experimental data
- 2.25L25-Size of a flexible protein: Simplest model
- 2.26L26-Uniform and Poisson distributions; Knudson’s analysis
- 2.27L27-Fourier Series-I
- 2.28L28-Fourier Series-II
- 2.29L29-Fourier transform
- 2.30L30-Master equation: Polymerization dynamics, Molecular motor motion
- 2.31L31-Evolution: Simplest model
- 2.32L32-Tutorial – I
- 2.33L33-Tutorial-II
- 2.34L34-Temperature, Energy and Entropy
- 2.35L35-Partition function, Free energy
- 2.36L36-Bending fluctuations of DNA and spring-like proteins
- 2.37L37-Force-extension and looping of DNA
- 2.38L38-Thermodynamics of protein organization along DNA
- 2.39L39-Learning mathematics with the help of a computer
