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About the Course

Department Profile
Course unit title Level of course unit Course unit code Type of course unit Semester of course unit Local credit ECTS credit Syllabus
PLANT PROTECTION IN ORGANIC AGRICULTURE Second cycle BTS411 7 3.00 3.00 Print
   
Description of course unit
Prerequisites and course requisities Non
Language of instruction Turkish
Coordinator Doç. Dr. Doğan IŞIK
Lecturer(s) Doç. Dr. Doğan IŞIK
Teaching assitant(s) Cemile Temur
Mode of delivery Face to face
Course objective Learnig have tomange pest and deseease in organic agriculture
Course description Learnig have tomange pest and deseease in organic agriculture

Course contents
1 What is organic agriculture
2 Organic production
3 Manage to past in organic agriculture
4 Manage to past in organic agriculture
5 Manage to desease in organic agriculture
6 Manage to deseasein organic agriculture
7 desease
8 Manage to weeds in organic agriculture
9 Manage to weeedsin organic agriculture
10 prapere organc past at home
11 prapere organc past at home
12 rewieve
13 reviewe
14 final exam
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20

Learning outcomes of the course unit
1 What is organic agriculture
2 Organic agriculture in Turkey
3 Have to manege deseasein organic agriculture
4 Have to manege past in organic agriculture
5 Have to manege weeds in organic agriculture
6 Chemicals usedorganic agriculture
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10

*Contribution level of the course unit to the key learning outcomes
1 The ability to apply knowledge of mathematics, science and engineering.
2 The ability to design and conduct experiments as well as to analyze and interpret data of experiments.
3 The ability to design a system, component, or process to meet desired needs.
4 The ability to work on multidisciplinary teams.
5 The ability to identify, formulate, and solve engineering problems.
6 An understanding of professional and ethical responsibility.
7 The broad education necessary to understand the impact of engineering solutions in a global/societal context.
8 A recognition of the need for and an ability to engage in lifelong learning.
9 The ability to use the techniques, skills and modern engineering tools necessary for industrial applications in the field of engineering.
10 The ability to use some of the package software related to Mechanical Engineering.
11 The broad education including engineering practise, recognation, learning and application activities.
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Number of stars refer to level of contribution from 1 (the least) to 5 (the most)

Planned learning activities, teaching methods and ECTS work load
  Quantity Time (hour) Quantity*Time (hour)
Lectures (face to face teaching) 14 2 28
Study hours out of classroom (study before and after the class) 0 0 0
Homework 0 0 0
Presentation / seminar 0 0 0
Quiz 0 0 0
Preparation for midterm exams 2 10 20
Midterm exams 1 2 2
Project (term paper) 0 0 0
Laboratuar 0 0 0
Field study 0 0 0
Preparation for final exam 2 10 20
Final exam 1 2 2
Research 0 0 0
Total work load     72
ECTS     3.00

Assessment methods and criteria
Evaluation during semester Quantity Percentage
Midterm exam 1 50
Quiz 0 0
Homework 0 0
Semester total   50
Contribution ratio of evaluation during semester to success   50
Contribution ratio of final exam to success   50
General total   100

Recommended and required reading
Textbook
Additional references

Files related to the course unit