Course syllabus adopted 2019-02-21 by Head of Programme (or corresponding).
Overview
- Swedish nameLinjär algebra
- CodeMVE022
- Credits7.5 Credits
- OwnerTKIEK
- Education cycleFirst-cycle
- Main field of studyMathematics
- DepartmentMATHEMATICAL SCIENCES
- GradingTH - Pass with distinction (5), Pass with credit (4), Pass (3), Fail
Course round 1
- Teaching language Swedish
- Application code 51119
- Open for exchange studentsNo
- Only students with the course round in the programme overview.
Credit distribution
Module | Sp1 | Sp2 | Sp3 | Sp4 | Summer | Not Sp | Examination dates |
|---|---|---|---|---|---|---|---|
| 0117 Examination 6 c Grading: TH | 6 c |
| |||||
| 0217 Laboratory 1.5 c Grading: UG | 1.5 c |
In programmes
Examiner
Jan-Alve Svensson- Senior Lecturer, Algebra and Geometry, Mathematical Sciences
Eligibility
General entry requirements for bachelor's level (first cycle)Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling the requirements above.
Specific entry requirements
The same as for the programme that owns the course.Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling the requirements above.
Aim
The purpose of the course is to, together with the other mathematics courses in the program, provide a general knowledge in the mathematics required in further studies as well as in the future professional career.Learning outcomes (after completion of the course the student should be able to)
After completing the course the student shall
- Understand the idea behind systems of linear equations and their solutions, be able to rewrite them in matrix form and use them for basic modeling with and without software.
- Know what a matrix is and what the (elementary) row operations acting are and use them to transform a matrix to (reduced) echelon form to determine consistency of linear equations systems and describe the solution in a minimal parametrized form with and without software.
- Be able to account for the algebraic operations on matrices, the rules that applies to them, use them and understand their connections with row operations and linear systems of equations when solving problems.
- Be able to account for the concept determinant of a matrix, now its basic properties and theorems in this context, be able to prove some of them and use them when computing determinants and solving problems.
- Be able to account for when a matrix is invertible and in this case be able to determine the inverse, or specific entry in the inverse, using both row operations and determinants as well as software.
- Be able to account for the concepts vector space, subspace, linearly independent vectors in, basis for and dimension of such a space, know basic theorems in this context, be able to prove some of these, and determine and use them when solving problems.
- Be able to account for the concept of linear transformation between vector spaces, determine its matrix with respect to bases and be able to use this when solving problems.
- Be able to account for properties of linear transformations, their connection to matrices and systems of linear equations, and be able to determine and use them in problem solving.
- Understand and be able to determine (basis for) kernel and image of a linear transformation, null space and column space of a matrix, and be able to determine if/when a vector is in one of them with and without software.
- Understand the algebraic operations on linear transformations and the connection to such for matrices and be able to use this in problem solving.
- Understand and geometrically interpret the concepts eigenvector and eigen value of a linear operator, know the basic theorems in this context, be able to prove some of these, and be able to determine them and use then when solving problems with and without software.
- Be able to account for the concept diagonalizable matrix, know the basic theorems in connection with this and use them to diagonalize when possible.
- Be able to use diagonalization to solve discrete linear dynamical systems and systems of first order linear differential equations with and without software.
- Be able to account for the concepts inner product, orthogonality, orthogonal complement of a subspace and use this in problem solving with and without software.
- Be able to determine an orthogonal/orthonormal basis for a subspace, the matrix on orthogonal projection on a subspace, and use least squares to determine a best approximative solution and curve fitting with and without software.
- Be able to account for the concept quadratic form, determine the symmetric matrix for such a form, and use diagonalization and completion of the square to classify it.
- Show evidence of entrepreneurial skills by in a group of peers identify and make a conscious choice of idea related to the other learning outcomes that can benefit future students, and implement it using own resources and those of others.
- Know what a matrix is and what the (elementary) row operations acting are and use them to transform a matrix to (reduced) echelon form to determine consistency of linear equations systems and describe the solution in a minimal parametrized form with and without software.
- Be able to account for the algebraic operations on matrices, the rules that applies to them, use them and understand their connections with row operations and linear systems of equations when solving problems.
- Be able to account for the concept determinant of a matrix, now its basic properties and theorems in this context, be able to prove some of them and use them when computing determinants and solving problems.
- Be able to account for when a matrix is invertible and in this case be able to determine the inverse, or specific entry in the inverse, using both row operations and determinants as well as software.
- Be able to account for the concepts vector space, subspace, linearly independent vectors in, basis for and dimension of such a space, know basic theorems in this context, be able to prove some of these, and determine and use them when solving problems.
- Be able to account for the concept of linear transformation between vector spaces, determine its matrix with respect to bases and be able to use this when solving problems.
- Be able to account for properties of linear transformations, their connection to matrices and systems of linear equations, and be able to determine and use them in problem solving.
- Understand and be able to determine (basis for) kernel and image of a linear transformation, null space and column space of a matrix, and be able to determine if/when a vector is in one of them with and without software.
- Understand the algebraic operations on linear transformations and the connection to such for matrices and be able to use this in problem solving.
- Understand and geometrically interpret the concepts eigenvector and eigen value of a linear operator, know the basic theorems in this context, be able to prove some of these, and be able to determine them and use then when solving problems with and without software.
- Be able to account for the concept diagonalizable matrix, know the basic theorems in connection with this and use them to diagonalize when possible.
- Be able to use diagonalization to solve discrete linear dynamical systems and systems of first order linear differential equations with and without software.
- Be able to account for the concepts inner product, orthogonality, orthogonal complement of a subspace and use this in problem solving with and without software.
- Be able to determine an orthogonal/orthonormal basis for a subspace, the matrix on orthogonal projection on a subspace, and use least squares to determine a best approximative solution and curve fitting with and without software.
- Be able to account for the concept quadratic form, determine the symmetric matrix for such a form, and use diagonalization and completion of the square to classify it.
- Show evidence of entrepreneurial skills by in a group of peers identify and make a conscious choice of idea related to the other learning outcomes that can benefit future students, and implement it using own resources and those of others.
Content
- Solvability and solution of linear systems of equations using row operations on matrices.- Matrix algebra, determinants, invertibility and invers of a matrix.
- Null space and column space of a matrix.
- Vector spaces and their subspaces, bases and dimensions.
- Linear transformation between vector spaces, matrices, kernel and image of such a transformation.
- Eigenvalues and eigenvectors of linear operators and matrices
- Diagonalization of linear operators.
- Discrete linear dynamical systems and systems of first order linear equations using diagonalization.
- Vector spaces with inner product, orthogonal and orthonormal bases and orthogonal projections.
- Least squares with applications to linear models.
- Quadratic forms and their classification.
- Use of the software MATLAB when solving problems related to the contents.
- Entrepreneurial experience.
Organisation
Instruction is given in lectures, classes and laboratory sessions. More detailed information will be given on the course web page before start of the course.Literature
Literature will be announced on the course web page before start of the course.Examination including compulsory elements
More detailed information about the examination will be given on the course web page before start of the course.
Examples of assessments are:
- selected exercises are to be presented to the teacher orally or in writing during the course,
- optional assessment during the course that can give bonus points,
- entrepreneurial project work assessed by delivery of result,
- written final exam after the course.
- exercises solved using software assessed by a teacher at the computer.