This is an guided design lab module to stimulate student's creativity of designing experiments and/or instruments for investigation of physics phenomena. At the end of the module, students will undergo a brief viva to explain their design steps taken to investigate their physics problem.
This course teaches the fundamental theorems and analytical methods for electrical and electronic circuits. It will serve as the precursor to advanced electronic circuit design, and would also lead to circuital modelling of physical systems. Topics include Kirchoff's current and voltage laws, nodal and mesh analysis, RLC circuits, Laplace and Fourier transforms for small signal analysis, circuit networks, basic diodes, transistors and operational amplifiers.
This lab module complements the teaching of PHY101 Mechanics and PHY102 Thermal Physics
This lab module complements the teaching of PHY103 Electromagnetism and PHY104 Modern Physics.
This course teaches the fundamentals of mechanics. Topics include kinematics, Newton’s laws of motion, conservation of energy and momentum, rigid body rotation, gravitation, waves, oscillations and an introduction to special relativity.
This course covers mathematical techniques relevant to physics. The first part consists of elementary complex analysis, including complex functions and derivatives, Taylor and Laurent series, and contour integrations. The second part of the course involves methods solving partial differential equations. The topics are boundary conditions, the wave, heat, and Poisson equations, separation of variables, and special functions.
The goal of this course is to teach students, whose majors are natural sciences and engineering, the fundamental laws of physics so that they can describe the ideal world with mathematics and predict outcomes in other similar situations. This course leads the students to explore various mechanical and thermodynamical phenomena in terms of a few relatively simple laws. With this, students' interest and capabilities in fundamental science will be developed.
The goal of this course is to teach students, whose majors are natural sciences and engineering, the fundamental laws of physics so that they can describe the ideal world with mathematics and predict outcomes in other similar situations. This course leads the students to explore various mechanical and thermodynamical phenomena in terms of a few relatively simple laws. With this, students' interest and capabilities in fundamental science will be developed.
This is an introductory course on the field of nanoscience and nanotechnology. It will cover the fundamental principles, synthesis and applications of nanomaterials. Through this course, the student will understand physical mechanism of nanomaterials and will learn different techniques to tune bulk physical properties such as magnetic, optoelectronics properties by manipulating at the molecular level. This course also includes different nanofabrication and characterization techniques. Furthermore, this course will discuss the impacts of nanotechnology on many different areas of applications.
This course equips students with relevant professional knowledge and research skills. It will help students to develop self-learning ability as well as an interest for life-long learning. It also gives students an opportunity to consolidate the knowledge they have learned throughout the program.
This course equips students with research and literature review skills. Students will be taught to apply the knowledge they have learned in their courses throughout the program to a particular research field. It will prepare the students to apply their skills in their upcoming Final Year Project.
This is a make-up physics lab session designed for physics students who have not experienced physical lab sessions during the 2020-2021 MCO period.
This course teaches the fundamental theorems and analytical methods for electrical and electronic circuits. It will serve as the precursor to advanced electronic circuit design, and would also lead to circuital modelling of physical systems. Topics include Kirchoff's current and voltage laws, nodal and mesh analysis, RLC circuits, Laplace and Fourier transforms for small signal analysis, circuit networks, basic diodes, transistors and operational amplifiers.
Lecturer: Hishamuddin Zainuddin
Course on mathematical techniques relevant to physics. First part consists of elementary complex analysis, including complex functions and derivatives. Taylor and Laurent series, and contour integrations. The second part involves methods solving partial differential equations. Topics include boundary conditions, wave, heat and Poisson equations, separation of variables and special functions.
This lab module complements the teaching of PHY101 Mechanics and PHY102 Thermal Physics.
Lecturer: Hishamuddin Zainuddin
Course on electrodynamics using vector and differential and integral calculus. Topics include electrostatic and magnetostatic fields, electric scalar and magnetic vector potentials, multipole expansion, electromagnetic induction, Maxwell's equations and electromagnetic wave, Poisson and Laplace's equations, electric and magnetic fields in matter.
The goal of this course is to teach students, whose majors are natural sciences and engineering, the fundamental laws of physics so that they can describe the ideal world with mathematics and predict outcomes in other similar situations. This course leads the students to explore various mechanical and thermodynamical phenomena in terms of a few relatively simple laws.
This course covers the fundamentals of photonics from both science and technology viewpoints. Topics include guided wave and fiber optics, and laser, semiconductor, electro-optics and nonlinear optics.
This course teaches the fundamental theorems and analytical methods for electrical and electronic circuits. It will serve as the precursor to advanced electronic circuit design, and would also lead to circuital modelling of physical systems. Topics include Kirchoff's current and voltage laws, nodal and mesh analysis, RLC circuits, Laplace and Fourier transforms for small signal analysis, circuit networks, basic diodes, transistors and operational amplifiers.