Course Unit Code | Course Unit Title | Type of Course | Year | Semester | ECTS |

TBFİZ113 | Physics-I | 927006 | 1 | 1 | 6 |

Level of Course Unit

First Cycle

Objectives of the Course

This introductory physics textbook for enginering stıdent has three main objectives: to provide the student with a clear and logical presentation of the basic concepts and principles of physics, to strengthen an understanding of the concepts and principles through a broad range of interesting real-world applications, and to develop strong problem-solving skills through an effectively organized approach. To meet these objectives, we emphasize well-organized physical arguments and a focused problem-solving strategy. At the same time, we attempt to motivate the student through practical examples that demonstrate the role of physics in other disciplines, including engineering, chemistry, and medicine.

Name of Lecturer(s)

Learning Outcomes

- It can do basic operations on vectors (addition, subtraction, scalar and vector products), motion in one and two dimensions can explain kinematics and kinetics (Newton's law of motion).
- Motion phenomena can also be explained by using work-kinetic energy theory and conservation laws (conservation of mechanical energy, conservation of linear and angular momentum) outside the Newtonian motion laws.
- Describe the rotational motion and equilibrium states of rigid bodies.
- Katı cisimlerin dönme hareketini ve denge durumlarını açıklayabilir

Mode of Delivery

Formal Education

Prerequisites and co-requisities

None

Recommended Optional Programme Components

None

Recommended or Required Reading

Physics for Scientist and Engineers Raymonf A Serway and John W. Jewett, Jr, Fifth Edition

Planned Learning Activities and Teaching Methods

Language of Instruction

Turkish

Work Placement(s)

None

Course Contents

Physics and Measurement, Vectors, Motion in One Dimension, Motion in Two Dimensions, The Laws of Motion, Circular Motion and Other Applications of Newton’s Laws, Energy of a System, Conservation of Energy, Linear Momentum and Collisions, Rotation of a Rigid Object About a Fixed Axis, Angular Momentum, Static Equilibrium and Elasticity, Universal Gravitation

Weekly Detailed Course Contents

Week | Theoretical | Practice | Laboratory |

1. | Physics and Measurement | Grouping, Measurement | |

2. | Vectors | Motion in One Dimension and Inclined plane | |

3. | Motion in One Dimension | The study of Simple and Physical Pendulum Motion | |

4. | Motion in Two Dimensions | Free Falling and Projectile | |

5. | The Laws of Motion | The Motion of Accelerated System | |

6. | Circular Motion and Other Applications of Newton’s Laws | The Centripetal Force | |

7. | Energy of a System | The Standing Waves | |

8. | Practice I | Linear Mometum and Conversation of Linear Momentum | |

9. | Mid-Term Exam | Mid-Term Exam | |

10. | Conservation of Energy | Angular Velocity and Angular Momentum | |

11. | Linear Momentum and Collisions | The study of Harmonic Motion in Spring | |

12. | Rotation of a Rigid Object About a Fixed Axis | Conversation of Energy and Torque | |

13. | Angular Momentum | Making Up Experiment I | |

14. | Practice II | Making Up Experiment II |

Assessment Methods and Criteria

Term (or Year) Learning Activities | Quantity | Weight (%) |

Midterm Examination | 1 | 50 |

Laboratory | 1 | 50 |

SUM | 100 | |

End Of Term (or Year) Learning Activities | Quantity | Weight (%) |

Final Examination | 1 | 100 |

SUM | 100 | |

Term (or Year) Learning Activities | 40 | |

End Of Term (or Year) Learning Activities | 60 | |

SUM | 100 |

Workload Calculation

Activities | Quantity | Time(hours) | Total Workload(hours) |

Midterm Examination | 1 | 3 | 3 |

Final Examination | 1 | 3 | 3 |

Attending Lectures | 14 | 3 | 42 |

Laboratory | 10 | 2 | 20 |

Individual Study for Mid term Examination | 1 | 30 | 30 |

Individual Study for Final Examination | 1 | 34 | 34 |

Report | 10 | 2 | 20 |

SUM | 152 |