Typical course structure
1.SI units. Prefixes to SI units. Conversion between systems.
2.Vectors: scalar and vector quantities. Graphical addition of vectors. Components of vectors. Addition of vectors using components.
3.Kinematics: motion in a straight line. Motion with uniform acceleration. Free fall. Relative velocity in a straight line. Motion in a plane. Projectiles. Relative velocity in a plane.
4.Dynamics: Newton's first law, Mass, Newton's second law & third law, Friction, Applications of Newton's laws.
5.Work and energy: Work. Kinetic energy. Gravitational potential energy. Elastic potential energy. Principle of conservation of energy. Work-energy theorem.
6.Linear momentum and impulse: Conservation of linear momentum principle and applications.
7.Rotational Motion: angular displacement, angular velocity and angular acceleration. Tangential and normal (centripetal) acceleration.
8.Rotational Dynamics. Torque, moment of inertia, work and power.
9. Fundamentals of fluid mechanics: density. Static pressure. Pressure gauges. Buoyancy. Bernoulli’s equation. Real fluids (viscosity and turbulence)
1.SI units. Prefixes to SI units. Conversion between systems.
2.Vectors: scalar and vector quantities. Graphical addition of vectors. Components of vectors. Addition of vectors using components.
3.Kinematics: motion in a straight line. Motion with uniform acceleration. Free fall. Relative velocity in a straight line. Motion in a plane. Projectiles. Relative velocity in a plane.
4.Dynamics: Newton's first law, Mass, Newton's second law & third law, Friction, Applications of Newton's laws.
5.Work and energy: Work. Kinetic energy. Gravitational potential energy. Elastic potential energy. Principle of conservation of energy. Work-energy theorem.
6.Linear momentum and impulse: Conservation of linear momentum principle and applications.
7.Rotational Motion: angular displacement, angular velocity and angular acceleration. Tangential and normal (centripetal) acceleration.
8.Rotational Dynamics. Torque, moment of inertia, work and power.
9. Fundamentals of fluid mechanics: density. Static pressure. Pressure gauges. Buoyancy. Bernoulli’s equation. Real fluids (viscosity and turbulence)
Teaching Material
phys1011_ch1_basic_and_vectors_2022.pdf | |
File Size: | 4216 kb |
File Type: |
phys10~2.pdf | |
File Size: | 3301 kb |
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phys1011_ch3_motion_in_a_plane_2022.pdf | |
File Size: | 3612 kb |
File Type: |
phys1011_ch4_newtons_laws_2021.pdf | |
File Size: | 2189 kb |
File Type: |
ph71a1~1.pdf | |
File Size: | 2436 kb |
File Type: |
phys1011_ch6_notes_2021.pdf | |
File Size: | 364 kb |
File Type: |
phys1011_ch7_work___energy_2022.pdf | |
File Size: | 5555 kb |
File Type: |
phys1011_ch8_momentum_2022.pdf | |
File Size: | 2943 kb |
File Type: |
phys1011_ch9_rotational_motion_2022.pdf | |
File Size: | 3036 kb |
File Type: |
phys1011_ch10_dynamics_of_rotation_2022.pdf | |
File Size: | 3326 kb |
File Type: |
phys1011_newtons_recap_only_2021.pdf | |
File Size: | 1073 kb |
File Type: |
fluid_mechanics.pdf | |
File Size: | 1136 kb |
File Type: |
Tutorial
723_physics_1_questions_with_answers_2022.pdf | |
File Size: | 2097 kb |
File Type: |
phy1_equation__2022_.pdf | |
File Size: | 226 kb |
File Type: |
phy1_q1_2022_tutorial.pdf | |
File Size: | 187 kb |
File Type: |
phy1_q2_2022_tutorial.pdf | |
File Size: | 270 kb |
File Type: |
phy1_q3_2022_tutorial.pdf | |
File Size: | 223 kb |
File Type: |
phy1_q4_2022_tutorial.pdf | |
File Size: | 136 kb |
File Type: |
rearanging_equations_excercise.pdf | |
File Size: | 86 kb |
File Type: |
Text based mind map
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Date edited - 03/06/2022