| Weeks | Topics |
| 1 |
Introducing the course content and Sections to be processed: Physics andMeasurement; Vectors, Motion in One and Two Dimension; The Laws of Motion; Applications of Newton’s Laws; Work and Kinetic Energy; Potential Energy and Conservation of Energy; Linear Momentum and Collisions; Rotation of a Rigid Object about a Fixed Axis; Angular Momentum; Static Equilibrium and Elasticity; Universal Gravitation Law; Fluid Mechanics.
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| 2 |
Physics and Measurement:
Standards of Length, Mass; and Time,Matter and Model Building; Dimensional Analysis; Conversion of Units; Estimates and Order-of-Magnitude Calculations;Significant Figures.
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| 3 |
Vectors and vector operations. Linear Motion; Position, velocity, velocity, Acceleration, Motion diagrams, Equations of motion with constant acceleration, Motion in two dimensions: shooting motions, Uniform circular motion. Relative Motion.
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| 4 |
Newton's Laws of Motion:
Concept of force, Newton's first law and inertial reference system, Mass, Newton's second law, Mass gravitational force and weight, Newton's third law, Friction forces.
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| 5 |
Applications of Newton’s Laws:
Circular motion and centripetal force, motion in accelerated reference systems, motion under friction and resistance force.
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| 6 |
Work and Kinetic Energy:
Systems and their environment, Work done by a constant force, work done by a variable force, Kinetic energy and kinetic energy - work theorem, Potential energy of a system, Conservative and non-conservative forces, Relationship between conservative forces and potential energy, Energy diagrams and balance.
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| 7 |
Potential Energy and Conservation of Energy:
Energy in open systems, Energy in closed systems, Energy in situations involving kinetic friction, Change in energy and mechanical energy when non-conservative forces are effective, Power.
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| 8 |
Linear Momentum and Collisions:
Linear momentum, momentum in an isolated system, momentum in a non-isolated system (repulsion of a force), collisions in one dimension, collisions in two dimensions, center of mass, momentum in a multi-particle system, perishable systems, momentum in rocket motion.
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| 9 |
Rotation of a Rigid Object about a Fixed Axis:
Basic variables of angular motion (Angular position, angular velocity and angular acceleration), Motion of a rigid body with constant angular acceleration, Relationship between angular and translation variables, Torque, Rigid body under net torque effect, Moment of inertia, Rotational kinetic energy, Energy equivalents in rotational motion, Solid rolling motion of an object.
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| 10 |
Angular Momentum:
Torque as a vector product, Angular momentum of a particle, Angular momentum in a system of particles, Angular momentum of a rotating rigid body, Expression of Newton's second law in angular motion, Conservation of angular momentum and angular momentum in closed systems, Gyros and spinning top motion.
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| 11 |
Static Equilibrium and Elasticity:
Equilibrium of a rigid body, Center of gravity, Examples of rigid bodies in static equilibrium, Elastic properties of solids.
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| 12 |
Universal Gravitation Law:
Newton's law of gravity, Free fall acceleration and gravitational force, Particles in gravitational field, Planetary motion and Kepler's Laws, Energy in planetary motion and satellite motion.
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| 13 |
Fluid Mechanics:
Pressure, factors that change the pressure, Pressure measurement, Buoyancy and Archimedes' Principle, Fluid dynamics, Bernnoulli Equation, applications of fluid dynamics.
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| 14 |
Evaluation of the term and completion of the deficiencies.
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