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Information
| Unit | FACULTY OF ENGINEERING |
| BIOMEDICAL ENGINEERING PR. | |
| Code | BMM106 |
| Name | Physics for engineers II |
| Term | 2018-2019 Academic Year |
| Semester | 2. Semester |
| Duration (T+A) | 3-0 (T-A) (17 Week) |
| ECTS | 5 ECTS |
| National Credit | 3 National Credit |
| Teaching Language | Türkçe |
| Level | Lisans Dersi |
| Type | Normal |
| Label | C Compulsory |
| Mode of study | Yüz Yüze Öğretim |
| Catalog Information Coordinator | Prof. Dr. AYŞE POLATÖZ |
| Course Instructor |
Prof. Dr. AYŞE POLATÖZ
(Bahar)
(A Group)
(Ins. in Charge)
|
Course Goal / Objective
To form the basis of learning phsical processes used in enginerring, to explain the physical events and laws. To take the attention of students on the discovering side of physics and to give the students necessary theories and applications with a clear and understandable presentation. To develop the skill of studentsproblem-solving. To prepare the basic information infrastructure of the students based on the Engineering undergraduates education.
Course Content
Electric fields. Coulomb and Gauss laws. Electric flux. Electrical potential. Electrostatic properties of substances. Current and resistance. Electrical power and energy density. Magnetic fields. Magnetic field sources. Biot-Savart and Amperes laws. Faradays law. Self Inductance. Electromagnetic oscillation. Resonance. Electromagnetic waves and Maxwells equations. The nature of light and the laws of geometrical optics. Wave optics. Interference and diffraction phenomena. Relativity. The birth of quantum mechanics. Atomic and nuclear physics
Course Precondition
Resources
Notes
Course Learning Outcomes
| Order | Course Learning Outcomes |
|---|---|
| LO01 | The basics of the physics: mainly electric and electromagnetic subjects |
| LO02 | Learns the terms physics. |
| LO03 | Learns the physics applications. |
| LO04 | Learn to solve physics problems. |
| LO05 | Learn the concepts necessary for engineering. |
Relation with Program Learning Outcome
| Order | Type | Program Learning Outcomes | Level |
|---|---|---|---|
| PLO01 | - | 1. Solve the scientific problems encountered in medicine and medical technologies by applying technical approaches of disciplines. 2. Self development on science and technology issues. 3. Assess the contributions of engineering solutions on medicine, medical technologies and healthcare | 4 |
| PLO02 | - | 1. Define the problems about Biomedical Engineering 2. Modelling the problems about Biomedical Engineering. | 4 |
| PLO03 | - | 1. Analyse data and interpret results | 4 |
| PLO04 | - | 1. Utilize modern techniques and computing tools which are essential for Engineering applications | 3 |
| PLO05 | - | 1. Design and analyse a defined process 2. Recognise national and international problems for Biomedical Engineering | 4 |
| PLO06 | - | Understand the research problems of medical doctor with engineering perspective | 4 |
| PLO07 | - | 1. Describe the ideas clearlywith written and verbally 2. Have the interdisciplinary teamwork skills | 3 |
| PLO08 | - | 1. Have knowledge on calibration and quality assurance systems in Biomedical Engineering 2. Have the sense of responsibility and professional ethics | 5 |
Week Plan
| Week | Topic | Preparation | Methods |
|---|---|---|---|
| 1 | Electrical loads. Coulomb law, the law of conservation of electric field of cargo. Electric field intensity. Electric field lines. Electric flux. Gauss law and its applications. Problem solving. | Reading the related chapter on the book | |
| 2 | Electrostatic potential energy of the field. Potential and potential difference. The relationship between electric field and potential. Electrostatic properties of substances. Capacitance and capacitors. Electrical energy and electrical energy density. | Reading the related chapter on the book | |
| 3 | Electric current. Current density. Resistance and Ohm law. Temperature dependence of resistivity of metals. Serial and parallel resistors. Electromotive force and internal resistance. Electrical energy and power. | Reading the related chapter on the book | |
| 4 | The definition and properties of the magnetic field. Gauss law for magnetic flux and magnetic fields. Force on current carrying wire. Torque on a current frame. The electromagnetic field in the cargo movement. | Reading the related chapter on the book | |
| 5 | Biot Savart law. Biot Savart law practices. Magnetic forces between two parallel currents. Ampere law. amperes law practices. Magnetic materials. | Reading the related chapter on the book | |
| 6 | Biot Savart law. Biot Savart law practices. Magnetic forces between two parallel currents. Ampere law. amperes law practices. Magnetic materials. | Reading the related chapter on the book | |
| 7 | Electromagnetic oscillation. LC circuit energy. RLC circuit connected to an alternating current source. RLC circuit in series. Damped oscillation. RLC circuit power. and the effective values of ac quantities. LRC electrical circuit resonance. | Reading the related chapter on the book | |
| 8 | Mid-Term Exam | Reading the related chapter on the book | |
| 9 | Displacement current. Maxwell equations. Plane electromagnetic waves. Energy carried by electromagnetic waves. Detection of radio waves. For the inverse square law of electromagnetic rays. | Reading the related chapter on the book | |
| 10 | The nature of light. Measuring the speed of light. Basic rules of geometric optics. Plane and spherical mirrors. Mirror equation. Lenses. Optical instruments. Problem solving | Reading the related chapter on the book | |
| 11 | Interventions. Double-slit interference pattern intensity distribution. Equivalent optical path. Thin film interference. Diffraction. Diffraction grating. Problem solving | Reading the related chapter on the book | |
| 12 | Black body radiation. Photoelectric effect. Compton effect. De Broglie wavelength. Uncertainty principle. Against the wave mechanics of classical mechanics. Problem solving. | Reading the related chapter on the book | |
| 13 | Black body radiation. Photoelectric effect. Compton effect. De Broglie wavelength. Uncertainty principle. Against the wave mechanics of classical mechanics. Problem solving. | Reading the related chapter on the book | |
| 14 | Atomic models. Energy levels and spectra. Laser. The building blocks of the nucleus. Radioactivity. Laws of radioactive decay. Binding energy of the nucleus. Core models. Core reactions. Natural radioactive series. | Reading the related chapter on the book | |
| 15 | Final Week | Reading the related chapter on the book | |
| 16 | Term Exams | Exam evaluation | |
| 17 | Term Exams | Exam evaluation |
Assessment (Exam) Methods and Criteria
| Assessment Type | Midterm / Year Impact | End of Term / End of Year Impact |
|---|---|---|
| 1. Midterm Exam | 100 | 40 |
| General Assessment | ||
| Midterm / Year Total | 100 | 40 |
| 1. Final Exam | - | 60 |
| Grand Total | - | 100 |
Student Workload - ECTS
| Works | Number | Time (Hour) | Workload (Hour) |
|---|---|---|---|
| Course Related Works | |||
| Class Time (Exam weeks are excluded) | 14 | 3 | 42 |
| Out of Class Study (Preliminary Work, Practice) | 14 | 3 | 42 |
| Assesment Related Works | |||
| Homeworks, Projects, Others | 0 | 0 | 0 |
| Mid-term Exams (Written, Oral, etc.) | 1 | 12 | 12 |
| Final Exam | 1 | 18 | 18 |
| Total Workload (Hour) | 114 | ||
| Total Workload / 25 (h) | 4,56 | ||
| ECTS | 5 ECTS | ||