| Week |
Theoretical |
Practical |
| 1 |
Length, mass and time standards, dimensional analysis, conversion of units |
Working conditions in the laboratory, the creation of groups, general information about laboratory and error calculations |
| 2 |
Vectors, coordinate systems, vector and scalar quantities, properties of the vectors, vector components and unit vectors |
Drawing graph and determine the ways to be followed conclusions based on the received results |
| 3 |
Motion, position, velocity, instantaneous velocity, acceleration, motion diagrams, motion with constant acceleration in one dimension, free falling bodies, the kinematic equations derived from the mathematical equation, two-dimensional motion of position, velocity and acceleration vectors, motion in two dimensions with constant acceleration, angular shot, uniform circular motion, tangential and radial acceleration, relative velocity and relative acceleration |
Taking measurements using vernier caliper, micrometer and spherometer |
| 4 |
The laws of motion, concept of force, Newton's first law and inertial systems, mass, Newton's second law, the force of gravity and weight, Newton's third law, Newton's laws in some applications, the friction force |
Measurement of friction coefficient with the help of an inclined plane |
| 5 |
Other applications of circular motion and Newton's second laws, the implementation of Newton's second law to the uniform circular motion |
Determine calorimeters heat capacity and specific heat of a solid body |
| 6 |
Energy and energy transfer, work done by a constant force, work done by the changing force, kinetic energy and work-kinetic energy theorem, the conservation of energy |
Measuring of acceleration of gravity with the help of reversible pendulum |
| 7 |
Potential energy, potential energy of a system, conservative and non conservative forces of conservation of mechanical energy, mechanical energy change for non-conservative forces, the correlation between conservative forces and potential energy, the energy diagram |
Determine the spring constants by using Hooke's law and the vibration method |
| 8 |
Midterm exam + repeating courses |
Midterm exam + repeating courses |
| 9 |
Impulse and momentum, linear momentum and collisions, conservation of linear momentum, collisions in one dimension, collisions in two dimensions, the movement of center of mass system of particles |
Examination of movement of an object moving at constant velocity in one dimension |
| 10 |
Rigid body rotation around a fixed axis, moment of inertia, parallel axes theorem, perpendicular axes theorem, torque, determination of the relationship between torque and angular acceleration |
Ballistic pendulum |
| 11 |
Static, equilibrium conditions, the center of gravity, stress, strain, modulus of elasticity |
Determination of resistance to flow of a liquid using Stokes' law |
| 12 |
Gravitation, Newton's law of gravity, weight, and Kepler's laws and planetary motion |
Moment of inertia |
| 13 |
Simple harmonic motion in period, amplitude, displacement, velocity and acceleration, simple harmonic motion in energy, simple pendulum, physical pendulum |
Energy and momentum conservation |
| 14 |
General report |
Control of the test reports |
