Course Identification

Title:

Mathematics for biologists

Code:

20243501

Lecturers and Teaching Assistants

Lecturers:

Dr. Josephine Shamash

TA's:

N/A

Course Schedule and Location

Year:

2024

Semester:

First Semester

When / Where:

Sunday, 09:15 - 11:00, science teaching lab 2
Monday, 11:15 - 12:00, WSoS, Rm A

First Lecture:

11/12/2023

End date:

03/03/2024

Field of Study, Course Type and Credit Points

Life Sciences: Lecture; 3.00 points
Life Sciences (Brain Sciences: Systems, Computational and Cognitive Neuroscience Track): Lecture; 3.00 points
Life Sciences (ExCLS Track): Lecture; Elective; 3.00 points

Comments

This course will be held on zoom
On January 28 the course will take place in FGS room C

Prerequisites

No

Restrictions

Participants:

15

Language of Instruction

English

Registration by

Registration By:03/10/2023

Attendance and participation

Expected and Recommended

Grade Type

Numerical (out of 100)

Grade Breakdown (in %)

Assignments:

20%

Final:

80%

Evaluation Type

Examination

Scheduled date 1

Date / due date

10/03/2024

Location

science teaching lab 2

Time

0900-1200

Remarks

N/A

Scheduled date 2

Date / due date

26/03/2024

Location

WSoS, Rm A

Time

0900-1200

Remarks

N/A

Estimated Weekly Independent Workload (in hours)

N/A

Syllabus

The course will introduce students who come from a non-mathematical background to basic mathematical tools that are essential for much of today's biological research: differential equations, linear algebra and linear systems theory, and a brief introduction to Fourier analysis. The intention is to provide a firm mathematical background for applications to be covered in advanced courses in Systems Biology and in Theoretical Neuroscience.

Topics to be covered:

Introduction to differential equations.
First-order ordinary differential equations: linear equations, separable equations, modeling with first-order equations, equilibrium solutions. Examples of applications include: RC circuits and current-integration by neurons.
Introduction to linear algebra: Matrix and vector operations.
Determinants.
Systems of linear equations.
Linear transformations.
Matrix diagonalization. Systems of linear differential equations, Relation of matrix diagonalization to solutions of systems of differential equations. Examples of applications include: predator-prey interactions.
Inner product spaces.
Orthogonal and orthonormal bases.
Introduction to Fourier analysis.

Learning Outcomes

Familiarity with basic mathematical tools that are essential for much of today's biological research: ordinary differential equations, linear algebra and linear systems theory, and a brief introduction to Fourier analysis. Knowledge sufficient to provide a mathematical background for applications to be covered in advanced courses in Systems Biology and in Theoretical Neuroscience.

Reading List

N/A

Website

N/A