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    SECTION I: GENERAL INFORMATION ABOUT THE COURSE
    Course Code Course Name Year Semester Theoretical Practical Credit ECTS
    60533TAEOZ-PHY3261 Physics Laboratory I 1 Fall 0 2 1 3
    Course Type : Compulsory
    Cycle: Bachelor      TQF-HE:6. Master`s Degree      QF-EHEA:First Cycle      EQF-LLL:6. Master`s Degree
    Language of Instruction: English
    Prerequisities and Co-requisities: N/A
    Mode of Delivery: Face to face
    Name of Coordinator: Dr. Öğr. Üyesi İNAL BEGÜM TURNA DEMİREL
    Dersin Öğretim Eleman(lar)ı: Dr. Öğr. Üyesi İNAL BEGÜM TURNA DEMİREL
    Dersin Kategorisi:

    SECTION II: INTRODUCTION TO THE COURSE

    Course Objectives & Content

    Course Objectives: Objective of this course is to improve students' knowledge by experimental application of physical concept covered in class Physics I. This course will partly follow the so-called Project-Based Learning (PBL). Each student will do two projects, each on a different topic.
    Course Content: Introduction. Physics and Measurement. One and Two dimensional motion. Projectile Motion. Newton's Law-Force Platform. Make-up Experiment. Project. Midterm Exam. Leverage Experiment. Springs and Pulleys Experiment. Simple Pendulum Experiments. Ballistic Pendulum. Inclined Plane Experiment. Make-up Experiment. Project.

    Course Learning Outcomes (CLOs)

    Course Learning Outcomes (CLOs) are those describing the knowledge, skills and competencies that students are expected to achieve upon successful completion of the course. In this context, Course Learning Outcomes defined for this course unit are as follows:
    Knowledge (Described as Theoritical and/or Factual Knowledge.)
      1) Know plotting graph using experimental data.
    Skills (Describe as Cognitive and/or Practical Skills.)
      1) Solve to the equilibrium problems using vectoral methods.
      2) Apply elastic, inelastic collisions and conservation of energy.
      3) Obtain the gravitational acceleration with different methods.
      4) Measure physical quantities as the angular velocity, angular acceleration and the moment of inertia, measure the moments of inertia of rigid bodies having different geometric shapes.
    Competences (Described as "Ability of the learner to apply knowledge and skills autonomously with responsibility", "Learning to learn"," Communication and social" and "Field specific" competences.)

    Weekly Course Schedule

    Week Subject
    Materials Sharing *
    Related Preparation Further Study
    1) Introduction
    2) Physcis and Measurement
    3) One and Two dimensional motion
    4) Projectile Motion
    5) Newton's Law of Motion
    6) Excuse Experiment
    7) Project
    8) Midterm
    9) Leverage Experiment
    10) Springs and Pulleys
    11) Simple Pendulum
    12) Ballistic Pendulum
    13) Inclined plane
    14) Excuse Experiment
    15) Project
    *These fields provides students with course materials for their pre- and further study before and after the course delivered.

    Recommended or Required Reading & Other Learning Resources/Tools

    Course Notes / Textbooks: Fizik I Laboratuar Föyü

    References: Fen ve Mühendislik İçin Fizik, Serway-Beichner, Çeviri:Kemal Çolakoğlu, Palme Yayıncılık

    DERS ÖĞRENME ÇIKTILARI - PROGRAM ÖĞRENME ÇIKTILARI İLİŞKİSİ

    Contribution of The Course Unit To The Programme Learning Outcomes

    Ders Öğrenme Çıktıları (DÖÇ)

    1

    2

    3

    4

    5
    Program Öğrenme Çıktıları (PÖÇ)
    1) Knowledge in mathematics, natural sciences, basic engineering, computer-based computation, and computer engineering–specific subjects; and the ability to use this knowledge in solving complex engineering problems.
    2) Ability to identify, formulate, and analyze complex engineering problems by applying knowledge of basic sciences, mathematics, and engineering, while taking into account the relevant UN Sustainable Development Goals.
    3) Ability to design creative solutions to complex engineering problems; ability to design complex systems, processes, devices, or products in a way that meets present and future needs, while considering realistic constraints and conditions.
    4) Ability to select and use appropriate techniques, resources, and modern engineering and informatics tools—including prediction and modeling—for the analysis and solution of complex engineering problems, with an awareness of their limitations.
    5) Ability to use research methods—including literature review, experimental design, experimentation, data collection, analysis, and interpretation of results—for the investigation of complex engineering problems.
    6) Knowledge of the impacts of engineering practices on society, health and safety, economy, sustainability, and the environment within the scope of the UN Sustainable Development Goals; awareness of the legal consequences of engineering solutions.
    7) Knowledge of ethical responsibility and conduct in accordance with the principles of the engineering profession; awareness of acting impartially, without discrimination, and embracing diversity.
    8) Ability to work effectively, individually and as a member or leader of intra-disciplinary and multi-disciplinary teams (face-to-face, remote, or hybrid).
    9) Ability to communicate effectively on technical subjects, orally and in writing, by taking into account the diverse characteristics of the target audience (such as education, language, and profession).
    10) Knowledge of business practices such as project management and economic feasibility analysis; awareness of entrepreneurship and innovation.
    11) An ability to engage in lifelong learning, including independent and continuous learning, to adapt to new and emerging technologies, and to critically evaluate technological changes.

    SECTION III: RELATIONSHIP BETWEEN COURSE UNIT AND COURSE LEARNING OUTCOMES (CLOs)

    Level of Contribution of the Course to PLOs

    No Effect 1 Lowest 2 Low 3 Average 4 High 5 Highest
               
    Programme Learning Outcomes Contribution Level (from 1 to 5)
    1) Knowledge in mathematics, natural sciences, basic engineering, computer-based computation, and computer engineering–specific subjects; and the ability to use this knowledge in solving complex engineering problems. 4
    2) Ability to identify, formulate, and analyze complex engineering problems by applying knowledge of basic sciences, mathematics, and engineering, while taking into account the relevant UN Sustainable Development Goals.
    3) Ability to design creative solutions to complex engineering problems; ability to design complex systems, processes, devices, or products in a way that meets present and future needs, while considering realistic constraints and conditions.
    4) Ability to select and use appropriate techniques, resources, and modern engineering and informatics tools—including prediction and modeling—for the analysis and solution of complex engineering problems, with an awareness of their limitations. 3
    5) Ability to use research methods—including literature review, experimental design, experimentation, data collection, analysis, and interpretation of results—for the investigation of complex engineering problems. 2
    6) Knowledge of the impacts of engineering practices on society, health and safety, economy, sustainability, and the environment within the scope of the UN Sustainable Development Goals; awareness of the legal consequences of engineering solutions. 3
    7) Knowledge of ethical responsibility and conduct in accordance with the principles of the engineering profession; awareness of acting impartially, without discrimination, and embracing diversity. 1
    8) Ability to work effectively, individually and as a member or leader of intra-disciplinary and multi-disciplinary teams (face-to-face, remote, or hybrid).
    9) Ability to communicate effectively on technical subjects, orally and in writing, by taking into account the diverse characteristics of the target audience (such as education, language, and profession).
    10) Knowledge of business practices such as project management and economic feasibility analysis; awareness of entrepreneurship and innovation.
    11) An ability to engage in lifelong learning, including independent and continuous learning, to adapt to new and emerging technologies, and to critically evaluate technological changes.

    SECTION IV: TEACHING-LEARNING & ASSESMENT-EVALUATION METHODS OF THE COURSE

    Teaching & Learning Methods of the Course

    (All teaching and learning methods used at the university are managed systematically. Upon proposals of the programme units, they are assessed by the relevant academic boards and, if found appropriate, they are included among the university list. Programmes, then, choose the appropriate methods in line with their programme design from this list. Likewise, appropriate methods to be used for the course units can be chosen among those defined for the programme.)
    Teaching and Learning Methods defined at the Programme Level
    Teaching and Learning Methods Defined for the Course
    Lectures
    Demonstration
    Laboratory

    Assessment & Evaluation Methods of the Course

    (All assessment and evaluation methods used at the university are managed systematically. Upon proposals of the programme units, they are assessed by the relevant academic boards and, if found appropriate, they are included among the university list. Programmes, then, choose the appropriate methods in line with their programme design from this list. Likewise, appropriate methods to be used for the course units can be chosen among those defined for the programme.)
    Aassessment and evaluation Methods defined at the Programme Level
    Assessment and Evaluation Methods defined for the Course
    Midterm
    Final Exam
    Quiz
    Homework Evaluation
    Practice Exam

    Contribution of Assesment & Evalution Activities to Final Grade of the Course

    Measurement and Evaluation Methods # of practice per semester Level of Contribution
    Laboratory 4 % 20.00
    Project 2 % 10.00
    Midterms 1 % 20.00
    Semester Final Exam 1 % 50.00
    Total % 100
    PERCENTAGE OF SEMESTER WORK % 50
    PERCENTAGE OF FINAL WORK % 50
    Total % 100

    SECTION V: WORKLOAD & ECTS CREDITS ALLOCATED FOR THE COURSE
    WORKLOAD OF TEACHING & LEARNING ACTIVITIES
    Teaching & Learning Activities # of Activities per semester Duration (hour) Total Workload
    Course 0 0 0
    Laboratory 9 2 18
    Application 10 2 20
    Special Course Internship (Work Placement) 0 0 0
    Field Work 0 0 0
    Study Hours Out of Class 10 1 10
    Presentations / Seminar 0 0 0
    Project 2 1 2
    Homework Assignments 9 1 9
    Total Workload of Teaching & Learning Activities - - 59
    WORKLOAD OF ASSESMENT & EVALUATION ACTIVITIES
    Assesment & Evaluation Activities # of Activities per semester Duration (hour) Total Workload
    Quizzes 9 1 9
    Midterms 1 2 2
    Semester Final Exam 1 3 3
    Total Workload of Assesment & Evaluation Activities - - 14
    TOTAL WORKLOAD (Teaching & Learning + Assesment & Evaluation Activities) 73
    ECTS CREDITS OF THE COURSE (Total Workload/25.5 h) 3