This course introduces more algebraic methods needed to understand real world questions. It develops fundamental algebraic tools involving matrices and vectors to study linear systems of equations and Gaussian elimination, linear transformations, orthogonal projection, least squares, determinants, eigenvalues and eigenvectors and their applications.  The topics to be covered are axioms for vector spaces over the field of real and complex numbers. Subspaces, linear independence, bases and dimension. Row space, Column space, Null space, Rank and Nullity.  Inner Products Spaces. Inner products, Angle and Orthogonality in Inner Product Spaces, Orthogonal Bases, Gram-Schmidt orthogonalization process. Best Approximation. Eigenvalues and Eigenvectors. Diagonalization. Linear transformation, Kernel and range of a linear transformation. Matrices of Linear Transformations.

This course aims at exposing students to an examination of the various psychological theories which underpins effective teaching and learning of science as well as a good range of students that support the theories. Students will be encouraged to come out with their own perspectives of teaching and learning based on the theories encountered in the course. Learning theories include those of Thorndike, Bruner, Gagne, Skemp, Vygostky, the Human Information processing psychologist, as well as the Gestalt psychological schools of thought will be covered in detail. The focus on these theories will also include arrange of studies that support the theories. The course will also explore the various learning styles and their relationships with the learning theories in science education.

This is the first of two courses in research methods aimed at providing opportunities for students to improve their research skills. The course will expose students to the theories that underpin the quantitative research paradigm. It aims at the development of the knowledge and skills of students to enable them conduct a variety of quantitative studies aimed at improving teaching and learning of science in schools and other educational settings. It is expected that at the end of the course students will write a research proposal for a study that could be the focus of their thesis. Topics to be covered include: Realism, subjectivism and the ‘paradigm wars’; Post-positivism, experiential realism and pragmatism; Sampling techniques; Various quantitative research designs, development of instruments, reliability and validity of instruments; Internal and external validity; Parametric statistics such as the t-test, one-way and two-way ANOVA, the F-distribution, correlation and simple regression analysis, used for hypothesis testing, will be applied in the course; Non parametric statistical tests such as, chi-square and the Mann-Whitney U-test will also be applied. The rationale for using these various statistics and the assumptions underlying their use will be a critical focus of this course. 

This course is designed to expose students to contemporary issues in curriculum studies and development in science education. The opportunity will be given to students to engage in some of the current complicated discourses in curriculum development, implementation, supervision and evaluation. Topics to be covered include: Understanding Curriculum in the following contexts: as Historical Text, Political Text, and Institutionalized Text; Gender, sexuality, race and ethnicity in a scientific and diverse milieu; Utopian vision, democracy and the egalitarian ideal; A vision of curriculum in the postmodern era.