Petroleum Engineering
26/02/2018 14:32
1. PROGRAM DESCRIPTION
1.1 Introduction
The program of Petroleum Engineering - Faculty of Chemical Engineering, The University of Da Nang, University of Science and Technology was established in 1994, right after the Government of Vietnam announced the project of Dung Quat oil refinery in Quang Ngai Province, Vietnam. In 1995, the first enrollment of this program was launched, under professional management of Chemical Engineering-Oil & gas division.
The training program of Petroleum Engineering was initially based on the core program of the Ministry of Education and Training and the training program of Petrochemical Refinery Engineers of IFP school (ENSPM) under The French Institute of Petroleum (IFP).
In 2006, the program was changed to the credit system, consisting of 180 Credits (CR) and 5 years of training. Then, it dropped to 180 credits in 2009 and 150 credits in 2012. Recently, the training duration has decreased to 4.5 years by 2015.
With high-quality human resources that have graduation from universities or postgraduate from prestige institutes of oil and gas technology, together with conditions for facilities for teaching and studying in term of synchronization and modern property, the program of Petroleum Engineering - Faculty of Chemical Engineering, The University of Da Nang, University of Science and Technology aims to be a high quality institute for human resource training, scientific research and technology transfer to contribute positively to the development of the oil and gas industry of the country and region Southeast Asia.
1.2 General information
1. Name of program (English):
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Petroleum Engineering (PE)
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2. Level of education:
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Undergraduate (engineer)
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3. Major code:
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520604
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4. Admission requirements:
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High school graduates
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5. Training duration:
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4.5 years
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6. Type of study:
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Regular
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7. Number of required credits:
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153
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8. Graduation conditions:
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Accumulating sufficient number of credits and volumes of the training program; The cumulative GPA is at least 2.00 or higher; Having a certificate of defense education and physical education; Meeting the standards of the foreign language according to the University's regulations; Meeting the standards of information technology in accordance with the University’s regulations.
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9. Graduation degree:
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Engineer
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10. Job position:
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Engineers, Team leaders and Project managers in oil refining – petrochemical plant, gas processing plant, consulting and design company, petroleum product companies
Researchers, lecturers and teachers at schools, institutes and organizations.
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11. Ability to continue to study:
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Graduates can continue to study Master and PhD in Vietnam and abroad.
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12. Reference programs:
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Program of Petrochemical Refinery Engineers of IFP school, The French Institute of Petroleum (ENSPM-IFP);
Program of Petroleum Engineering of Missouri University, USA
Program of Chemical Engineering of Hanoi University of Science &Technology
Program of Refining &Petrochemical, Hanoi University of Mining & Geology
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1.3 Educational philosophy of DUT
With regards to the mission of training high-quality human resources in science and technology and providing scientific and technological services for the development of the Central - Highlands, DUT has built an educational philosophy in order to improve “thinking, creating and humanity cherishing” for students.
1.4 Program Objectives (POs)
The objectives of the program is to provide engineers for national and international labor markets in the field of petroleum engineering:
1. Having good moral qualities and responsibility, good knowledge in economics, politics and law in order to contribute effectively to the sustainable development of the community;
2. Have a comprehensive knowledge of basic science to meet the requirements of self-study, lifelong learning and higher education;
3. Having deep knowledge and technical capability in the field of chemical engineering – Oil & gas to propose solutions on design, installation, operation and optimization of equipment systems
4. Having sufficient personal skills in communication, teamwork, foreign languages and information technology to work in multi-disciplinary, multicultural and multinational environments;
5. Having ability to adapt and create in different working fields to achieve goals, improve professional skills for self-development.
Program Objectives
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Program Learning Outcomes
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4
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5
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1.5 Program Learning Outcomes (PLOs)
Students graduating from this program should have an ability to:
1. Explain concepts, process diagrams, operating principles of equipment and modern technical tools in the field of petroleum engineering.
2. Apply knowledge of mathematics, physics and science to solve problems in technology, equipment and material in the petroleum industry.
3. Analyze, process and apply experimental results to improve production processes.
4. Design process flow diagram as well as equipment in the field of petroleum engineering.
5. Organize teamwork effectively.
6. Identify, analyze and solve technological problems
7. Present results in both oral and written forms.
8. Have lifelong learning skills.
9. Identify and analyze social and environmental issues.
10. Apply information technology in practice on modern technical equipment and in simulation with professional softwares.
11. Use foreign language in professional activities.
Mapping the objectives and the expected learning outcomes of the program.
Program Objectives
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Program Learning Outcomes
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5
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1.6 Job and post-graduate study opportunities
Graduates of the program in PE can work at:
- Factories or management boards of refining & petrochemical projects such as Dung Quat oil refinery, Nghi Son oil refinery project ...;
- Gas processing plants or gas projects such as: Dinh Co Plant, Phu My Fertilizer Plant, Ca Mau Fertilizer Plant, Long Son Gas Project, Blue Whale Gas Project ...;
- Oil and Gas consulting and design companies such as Technip (France), Axens, Cuu Long JOC, PV Engineering, PTSC ...;
- Oil and gas research institutes inside and outside the country such as PVI, PVPro, IFP Energies nouvelles ... and research centers of ministries,
- Trading company and managing the quality and safety of oil and gas products such as Skypec, Saigon Petro, Petrolimex, Quatest, Vinacontrol ...
- Participate in teaching and researching at universities and colleges such as: Petroleum University, Da Nang University of Technology, Petroleum Human Resource Training Center ...
- Continue to study Master or PhD in PE and related fields.
1.7 Admission criteria, training process and graduation conditions
1.7.1 Admission criteria
The program in PE accepts candidates that meet the following requirements:
- Have graduated from high school;
- Registering the national examination of the A field (mathematics, physics and chemistry) and the B1 field (mathematics, chemistry and foreign languages) for PE major;
- Have the national examination grade greater than or equal to the entry grade of the PE program and DUT.
1.7.2 Training process
The PE curriculum is organized following the credit system. The training process complies with the regulations of the Ministry of Education and Training, the University of Danang and DUT. The program is implemented in 4.5 years. Each scholar year consists of two main semesters (mid-August to late June) and one summer semester (from early July to mid-August). In the first two years, students learn basic knowledge, in the next two and half years, students learn knowledge of the major.
1.7.3 Graduation conditions
Student must meet the following conditions:
- Accumulating sufficient number of credits and volumes of the training program;
- The cumulative GPA at least 2.00 or higher;
- Having a certificate of defense education and physical education;
- Achieving the standard of the foreign language according to the DUT's regulations;
- Achieving the standard of information technology in accordance with the DUT’s regulations.
1.8 Teaching and learning strategies
The Chemical Engineering Faculty of DUT builds the teaching and learning strategies, which foster a student-centred environment. We develop resources, facilitate training sessions, and conduct consultations on the implementation of the strategies.
The learning and teaching strategies provide effective learning and teaching outcomes. The expected learning outcomes should guide which approach best suits the achievement of those outcomes.
Various learning activities aim to help students not only acquire social knowledge, basic and specialized major knowledge, but also use personal and social capability to work collaboratively with others, to appreciate their own strengths and abilities and those of their peers and develop a range of interpersonal skills such as communication, negotiation, team work, leadership and an appreciation of diverse perspectives.
1.8.1 Interactive learning
Interactive learning is a process to help students become more engaged in many activities in classroom, such as discussion, problem solving, question-and-answer session that helps students strengthen problem solving and critical thinking skills
1.8.2 Independent learning
Independent learning is a process to help to become self-directed in their learning experiences and to have more autonomy and control over their learning through exercises, study projects..
1.8.3 Presentation
Students are asked to present a prepared task or topic; This helps students improve their presentation skills
1.8.4 Paperwork
Students learn to make a writing/report about their working results using the writing standard under supervise of academic staff including laboratory practical report and research report
1.8.5 Teamwork
Students are organized into small groups to solve a posed problem or study a research question, then prepare a report and/or present it before other groups and lecturer.
1.8.6 Project based learning
Project-based learning involves deep learning, as it focuses on real world problems and challenges and relies on problem solving, decision making and research skills. Project based learning ends by product and/or presentation in mind that requires learning specific knowledge and concepts, thus creating a context and reason to learn and understand the information and concepts.
1.8.7 Laboratory work
In some subject, students participate in laboratory experiments to reinforce theoretical content and enhance practical skills
1.8.8 Guest lecture
To enrich the knowledge in petroleum engineering, the students can attend the general lectures that have speakers from various company.
1.8.9 Field Study
Internships/Visits at companies are compulsory for all students so that they can understand the real working environment, learn not only technologies but also professional skills and enterprise culture. Specially, graduation internship helps students to be ready to work for companies and get jobs easily.
1.8.10 Research project
Students are encouraged to join research projects are designed by lecturers. This allows students to develop their research capability and creativity skill, and to continue studying master or PhD degree after graduation.
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Expected learning outcomes
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Teaching and learning strategies
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Interactive learning
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X
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X
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X
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X
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X
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Independent learning
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X
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X
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X
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X
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X
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X
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X
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X
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X
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Presentation
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X
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X
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X
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X
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Teamwork
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X
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X
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Paperwork
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X
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Project based learning
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Laboratory work
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Guest lecture
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X
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Field study
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X
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X
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1.9 Assessment methods
1.9.1 Introduction
Assessment methods are the strategies, techniques and tools for collecting information to determine the extent to which students demonstrate expected learning outcomes. Assessments should be realized during the courses (formative assessments) and at the end of the courses (summative assessments). Summative assessment normally occurs at the middle (mid-term exam) and at the end of course (final exam) and measure the extent to which students have achieved the expected learning outcomes
Each course will select the assessment methods that will provide the most useful and relevant information for the purposes that the course and the lecturers have identified. When selecting which assessment methods to use, consider what questions need to be answered, the availability of resources, and the usefulness of the results.
1.9.2 Assessment methods
Written tests
Students are assessed on their ability to solve a certain number of questions on a topic/course. This helps students to recognize what they do and do not understand about a topic/course.
Multiple choice questions
A bank of multiple choice questions for the course is designed to assess student’s ability. This allows covering largely the contents of the course and can be done on papers or on computers.
Assignments
Small assignments are given to students in class and they should go to blackboard to explain how to solve them to others.
Homework
Students have to do some homework at home after a class session and submit to lecturers before next class session.
Class attendance
Lecturers should check the presence of students for each class and evaluate the student’s attendance during class (answering questions, asking questions, solve problems, propose ideas…).
Oral exam
Problems, subjects or projects are given to students in advance, then lecturers orally ask questions to assess the extent to which students understand and solve problems.
Oral presentation
Research subjects or projects are given to small groups of students, then they are required to prepare and realize oral presentation before others and lecturers. Lecturers may ask questions to assess their ability and knowledge.
Laboratory report
Students are required to write diary book after each laboratory session, then they have to submit a report for all the labs at the end.
Essay/ Written Report
A short piece of writing on a particular subject, especially one done by students as part of the work for a course
Project progress evaluation
While doing projects, students have to submit project progress reports at certain time and such reports should be evaluated and marked by supervisors.
Project report
Students are required to submit a final project report at the end of semester. Report is evaluated in combination with oral presentation or/and question-answer.
Thesis
During graduation project, students have to realize a specific subject supervised by lecturer (possibly and industrial expert). At the end, students are required to submit thesis and defend before jury (may be composed of both industrial experts and lecturers)
1.9.3 General Rubrics
Rubric for Oral Presentation :
Performance
Criteria
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Fail
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Needs
Improvement
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Developing
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Sufficient
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Above
Sufficient
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Content
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Not show the topic clearly
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Focus too much on overview but not in detail
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Basically show the topic
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Use suitable content but not clearly show the
topic
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Clearly show the topic in overview and detail
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Time management
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Inappropriate time distribution between parts. Too much difference than the scheduled
time. (>50%)
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Presentation time is 20%-
40% longer or shorter
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Presentation time is 10%-
20% longer or shorter
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Presentatio n time is 5%-10%
longer or shorter
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Appropriate time distribution between parts . Follow the scheduled time
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Outline
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No outline
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Undetailed outline
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Detailed outline but inappropriat e order of content
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Detailed, clear and appropriate outline with suitable sequence
of content
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Logical and clear ouline with transitions between different parts
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Word use
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A lot of spelling mistakes, no explanation of technical
terms
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A few spelling mistakes, inaccurate word use
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No spelling mistakes, appropriate word use
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Appropriat e word use, not enough explanation of technical
terms
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Accurate and understandable word use, explanation and examples for
technical terms
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Introduction
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No introduction
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Correct object introduction but lengthy and incomplete
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Correct object introduction and attractive
introduction
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Interesting introductio n
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surprising, creatively and attractive introduction
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Interaction with audience
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Just stand at the same place, not
cover the
whole class,
not interact
with audience
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Move around but not cover the whole class,
just use a few
interactions
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Move around and cover the
whole class.
Use a lot of
interactions
but not make
audience
interested
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Move around, use lots of
interactions
and make
audience
interested
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Move around, use lots of interactions and
make audience
interested and
take part in the
presentation
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Voice
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Speak too
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Speak clearly
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Speak
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Speaksloud
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Speak loudly,
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softly to be
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but often
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loudly,
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ly, clearly,
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clearly, fluently
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understood,
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repeats
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clearly,
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fluently
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and fascinatingly
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fluently but
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and
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mototone
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inspiration
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and dull
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ally
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Attitude/manners
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Shy,
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Confident but
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Confident
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Calm,
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Calm, confident,
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inconfident,
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still confused
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but not
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confident
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enthusiastic,
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often head-
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when solving
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enthusiastic
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but not
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passionate about
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scratching
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problems
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in answering
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enthusiasti
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answering
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questions
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c in
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audience’s
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answering
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questions
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questions
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and
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passionate
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The use of visual
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No visual
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A few visual
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Enough
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Appropriat
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Clear
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aids
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aids
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aids but unclear
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visual aids
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e
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explanation with
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and low
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which
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distribution
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clear pictures.
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qualified,
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basically
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between
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unclear content
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show the
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pictures
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showing
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content
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and videos.
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Font sizes, contrast
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Hard to see
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High contrast
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Good
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Appropriat
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Beautiful
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between
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words in slide
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but small words
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contrast but
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e contrast
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background and
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background and
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due to the low
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due to too much
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unsuitable
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and colors.
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good contrast.
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text
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contrast and
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text in one slide
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colors of
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Appropriat
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Appropriate 7x7
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too much
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background
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e font
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rule
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words in one
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and text are
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sizete
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slide
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not suitabl.
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Appropriate
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font size
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Interaction with audience
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Just stand at the same place, not
cover the
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Move around but not cover the whole class,
just use a few
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Move around and cover the
whole class.
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Move around, use lots of
interactions
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Move around, use lots of interactions and
make audience
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Rubric for teamwork:
Performance
Criteria
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Fail
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Needs
Improvement
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Developing
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Sufficient
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Preparation
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Ill-prepared or
unprepared for the meeting
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Little prepared for the meeting
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Well-prepared for the meeting
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Well-prepared in detail
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Organization
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Let other members make plans
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Partially participate in setting up the goal and
making plans
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Mostly participate in setting up the goal and
making plans
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Play a main role in setting up the goal and making
plans
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Participation
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Passively observe and have no idea or opinion
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Have discussions based on members’ ideas
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Actively participate in discussions and questioning
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Actively participate in discussion and questioning and lead the
discussions
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Comprehensio n
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Unable to answer questions or do not answer questions
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Rarely speak and answer questions
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Listen intently and show the comprehension by explaining the content
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Listen intently and show the comprehensio n by explaining and developing the
content
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Level of interest
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Seem to want to do something else at another place
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Often absent or late
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Absent but inform in advance and manage to
fulfill tasks
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Voluntarily take the responsibility and share the
tasks
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1.9.4 Grading systems
DUT uses the following scoring systems to assess student’s academic performance:
- Scale 10 is used to evaluate courses including component grades, final test grades, and courses grades. Course grades are the summation of all component grades multiplied with corresponding weights.
- Scale letter is used to classify learning outcomes based on student’s course grades.
- Scale 4 is used when calculating the semester average grade and the cumulative GPA, to assess the student's academic performance after each semester and to grade the student's overall academic performance.
Classification
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Scale 10
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Scale 4
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Scale letter
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Pass
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From 9.5 to 10
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4.0
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A+
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From 8.5 to 9.5
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4.0
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A
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From 8.0 to 8.5
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3.5
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B+
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From 7.0 to 8.0
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3.0
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B
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From 6.5 to 7.0
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2.5
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C+
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From 5.5 to 6.5
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2.0
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C
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From 5.0 to 5.5
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1.5
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D+
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From 4.0 to 5.0
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1.0
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D
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Fail
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Less than 4.0
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0
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F
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2. CURRICULUM DESCRIPTION
2.1 Curriculum content
The curriculum is structured into a complete system, which consists of general education knowledge, mathematic - natural sciences knowledge, knowledge of the technical core, and chemical engineering and specialized knowledge in petroleum engineering to meet the requirements and objectives of training program. The total number of credits of the course is 153 credits, of which 34 credits are experiment, practice, and project, accounting for approximately one third of the theoretical credits.
Knowledge Cluster
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Curriculum 2015
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No
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Course Name
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Credit Number
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Semestre
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General Education
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1
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English A2.1
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3
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1
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2
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English A2.2
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4
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2
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3
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Revolutionary policies of the Communist Party
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3
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4
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4
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Marcism-Leninism principles 1
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3
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1
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5
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Marcism-Leninism principles 2
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2
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2
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6
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General Law
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2
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3
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7
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Ho Chi Minh Thought
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2
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3
|
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Total
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19
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Mathematic, Natural Science
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8
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Algebra
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3
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2
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9
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Calculus 1
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4
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1
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10
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Calculus 2
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4
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2
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11
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General Informatic Lab
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1
|
1
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12
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General Informatic
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2
|
1
|
13
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Physic Lab
|
1
|
2
|
14
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Physics 1
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3
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3
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15
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Physics 2
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3
|
3
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16
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Probablity and Statistics
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3
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4
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17
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Numeric Methods
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3
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4
|
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Total
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27
|
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Technical Core
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18
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Applied mechanics
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3
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3
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19
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Descriptive geometry
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2
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1
|
20
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Economics for Engineering
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2
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5
|
21
|
Electrical Engineering
|
2
|
3
|
22
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Electrical Engineering Lab
|
0.5
|
3
|
23
|
Environment
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2
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4
|
24
|
Technical Drawing
|
2
|
3
|
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Total
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13.5
|
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Chemistry & Chemical Engieering
|
25
|
General Chemistry
|
2
|
1
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26
|
General Chemistry Lab
|
1
|
1
|
27
|
Inorganic Chemistry
|
2
|
2
|
28
|
Inorganic Chemistry Lab
|
0.5
|
2
|
29
|
Organic Chemistry
|
3
|
3
|
30
|
Organic Chemistry Lab
|
1
|
3
|
31
|
Physical Chemistry I
|
3
|
4
|
32
|
Physical Chemistry II
|
2
|
5
|
33
|
Physical Chemistry Lab
|
1
|
5
|
34
|
Analytical Chemistry
|
2
|
4
|
35
|
Analytical Chemistry Lab
|
1
|
4
|
36
|
Mass transfer process and equipment
|
2
|
6
|
37
|
Heat transfer process and equipment
|
2
|
5
|
38
|
Mechanic and hydraulic processes
|
2
|
4
|
39
|
Reaction Engineering-Chemical reactors
|
2
|
6
|
40
|
Process and equipment Lab
|
1
|
6
|
41
|
Process and equipment Project
|
2
|
6
|
42
|
Process and equipment Internship
|
1
|
6
|
43
|
Basic Design of Chemical Plant
|
2
|
5
|
44
|
Work safety and industrial sanitation
|
1
|
5
|
45
|
Process Simulation
|
2
|
6
|
46
|
Catalyst technology
|
2
|
6
|
|
Total
|
37.5
|
|
Petroleum Engineering
|
47
|
Applied English in C.E
|
2
|
5
|
48
|
Multicomponent distillation
|
2
|
7
|
49
|
Gas conditioning and processing
|
2
|
8
|
50
|
Gas conditioning and processing Lab
|
1
|
8
|
51
|
Petrochemical Technology
|
2
|
8
|
52
|
Petrochemical Technology Lab
|
1
|
8
|
53
|
Refining processes 1
|
2
|
7
|
54
|
Refining processes 2
|
2
|
7
|
55
|
Refining processes Lab
|
1
|
7
|
56
|
Lubricant, grease , additive
|
2
|
8
|
57
|
Automobile Pollution*
|
2
|
6
|
58
|
Process Control and Regulation
|
2
|
8
|
59
|
Oil and Gas Production**
|
2
|
7
|
60
|
Analytical Techniques applied to crude oils and petroleum products
|
2
|
8
|
61
|
Applied thermodynamic
|
2
|
6
|
62
|
Separation processes in petroleum industry
|
2
|
7
|
63
|
Petroleum products*
|
2
|
6
|
64
|
Introduction to technology of petroleum and gas
|
2
|
5
|
65
|
Oil and Gas Industry Equipment **
|
2
|
7
|
66
|
Chemistry of Petroleum
|
2
|
5
|
67
|
Chemistry of Petroleum Lab
|
1
|
5
|
68
|
Applied Mathematics
|
3
|
7
|
69
|
Optimization of oil refinery activities
|
1
|
8
|
70
|
Industrial Internship (Oil & gas)
|
2
|
7
|
71
|
Graduate Internship (Oil & Gas)
|
2
|
8
|
72
|
Engineering Project 1 (Oil & Gas)
|
2
|
7
|
73
|
Engineering Project 2 (Oil & Gas)
|
2
|
8
|
74
|
Final Project
|
10
|
9
|
|
Total
|
60
|
|
(*, **): Elective course
Cluster of required general education: includes knowledge of law and politics, providing students with basic knowledge of law, politics in Vietnam and the world; and equip the minimum language skills so that students can access foreign documents
Cluster of required mathematics and basic sciences: includes the knowledge of algebra, probability, statistics, calculus, physics, computer science which equip students with a basic foundation in science.
Cluster of required technical core: includes knowledge of the environment, law, introduction to engineering and basic knowledge of engineering, such as electrical engineering, , thermal engineering, descriptive geometry, engineering drawing, applied mechanics…to provide students with fundamental knowledge in the field of engineering
Cluster of required chemistry and chemical engineering: provides general knowledge of chemistry and general chemical process engineering so that students have background knowledge in specialized subjects in chemical engineering and can work in the field of chemical engineering.
Cluster of required petroleum engineering: includes the knowledge of oil refining technology, gas processing technology, oil and gas exploration technology and the design of related processes so that students can work in the oil and gas industry in Vietnam as well as in on the world
Cluster of elective specialized knowledge provides students with knowledge, technology and technology options that meet the business requirements and future development trends.
2.2 Curriculum Roadmap
2.3 Training Plan
Year / Semester
|
Course (Subject) Name
|
Code
|
Number of Credit
|
Lecture
|
Practice
|
Year 1
Sem 1
|
Marcism-Leninism principles 1
|
2090131
|
2
|
|
Descriptive geometry
|
1080011
|
2
|
|
English A2.1
|
4130501
|
3
|
|
Calculus 1
|
3190211
|
4
|
|
General Informatic
|
1020691
|
2
|
|
General Informatic Lab
|
1020701
|
|
1
|
General Chemistry
|
1070073
|
2
|
|
General Chemistry Lab
|
1071972
|
|
1
|
Physical education 1
|
130011
|
|
|
Year 1
Sem 2
|
Marcism-Leninism principles 2
|
2090141
|
3
|
|
Physics 1
|
3050011
|
3
|
|
Calculus 2
|
3190230
|
4
|
|
Algebra
|
3190131
|
3
|
|
Inorganic Chemistry
|
1072622
|
2
|
|
Inorganic Chemistry Lab
|
1073480
|
|
0.5
|
English A2.2
|
4130311
|
4
|
|
Physical education 2
|
130021
|
|
|
Year 2
Sem 3
|
General Law
|
2100010
|
2
|
|
Ho Chi Minh Thought
|
2090101
|
2
|
|
Electrical Engineering
|
1050931
|
2
|
|
Electrical Engineering Lab
|
1052200
|
|
0.5
|
Physics 2
|
3050641
|
3
|
|
Physic Lab
|
3050651
|
|
1
|
Applied mechanics
|
1080491
|
3
|
|
Technical Drawing
|
1080401
|
2
|
|
Organic Chemistry
|
1072563
|
3
|
|
Organic Chemistry Lab
|
1072632
|
|
1
|
Physical education 3
|
130031
|
|
|
Year 2
Sem 4
|
Revolutionary policies of the Communist Party
|
2090121
|
3
|
|
Numeric Methods
|
1072683
|
3
|
|
Mechanic and hydraulic processes
|
1072652
|
2
|
|
Physical Chemistry I
|
1072642
|
3
|
|
Probablity and Statistics
|
3190220
|
3
|
|
Environment
|
1170011
|
2
|
|
Analytical Chemistry
|
1072713
|
2
|
|
Analytical Chemistry Lab
|
1072723
|
|
1
|
Physical education 4
|
130041
|
|
|
Year 3
Sem 5
|
Economics for Engineering
|
1180943
|
2
|
|
Chemistry of Petroleum
|
1073053
|
2
|
|
Chemistry of Petroleum Lab
|
1073063
|
|
1
|
Heat transfer process and equipment
|
1070213
|
2
|
|
Basic Design of Chemical Plant
|
1073073
|
2
|
|
English for Petroleum Engineering
|
4130353
|
2
|
|
Physical Chemistry II
|
1072843
|
2
|
|
Physical Chemistry Lab
|
1071982
|
|
1
|
Introduction to technology of petroleum and gas
|
1072580
|
1
|
1
|
Work safety and industrial sanitation
|
1072753
|
1
|
|
Physical education 5
|
130051
|
|
|
Year 3
Sem 6
|
Process and equipment Internship
|
1072763
|
|
1
|
Catalyst technology
|
1070033
|
2
|
|
Reaction Engineering - Chemical reactors
|
1073173
|
2
|
|
Process and equipment Project
|
1070253
|
|
2
|
Process and equipment Lab
|
1070243
|
|
1
|
Mass transfer process and equipment
|
1072673
|
2
|
|
Applied thermodynamic
|
1072213
|
2
|
|
Petroleum products*
|
1070673
|
2
|
|
Automobile Pollution*
|
1073163
|
2
|
|
Process Simulation
|
1070063
|
2
|
|
Year 4
Sem 7
|
Multicomponent distillation
|
1072303
|
2
|
|
Applied Mathematics
|
1072823
|
3
|
|
Separation processes in petroleum industry
|
1073093
|
2
|
|
Engineering Project 1 (Oil & Gas)
|
1071793
|
|
2
|
Refining processes 1
|
1070563
|
2
|
|
Refining processes 2
|
1073103
|
2
|
|
Refining processes Lab
|
1070573
|
|
1
|
Industrial Internship (Oil & gas)
|
1072313
|
|
2
|
Oil and Gas Industry Equipment **
|
1070643
|
2
|
|
Oil and Gas Production**
|
1073123
|
2
|
|
Year 4
Sem 8
|
Analytical Techniques applied to crude oils and petroleum products
|
1073083
|
2
|
|
Lubricant, grease , additive
|
1070633
|
2
|
|
Petrochemical Technology
|
1073113
|
2
|
|
Petrochemical Technology Lab
|
1070593
|
|
1
|
Engineering Project 2 (Oil & Gas)
|
1071803
|
|
2
|
Process Control and Regulation
|
1072333
|
2
|
|
Optimization of oil refinery activities
|
1070663
|
1
|
|
Gas conditioning and processing
|
1073143
|
2
|
|
Gas conditioning and processing Lab
|
1073153
|
|
1
|
Graduate Internship (Oil & Gas)
|
1073133
|
|
2
|
Year 5
Sem 9
|
Final Project
|
1072323
|
|
10
|
(*, **): Elective course
2.4 Mapping Courses – Expected Learning Outcomes
Note: H (High), M (Medium), L (Low).
No
|
Course Name
|
Credit number
|
PLOs
|
1
|
2
|
3
|
4
|
5
|
6
|
7
|
8
|
9
|
10
|
11
|
1
|
Marcism-Leninism principles 1
|
2
|
-
|
-
|
-
|
-
|
L
|
-
|
-
|
L
|
H
|
-
|
-
|
2
|
Descriptive geometry
|
2
|
M
|
L
|
-
|
M
|
L
|
-
|
M
|
M
|
-
|
-
|
-
|
3
|
English A2.1
|
3
|
-
|
-
|
-
|
-
|
M
|
-
|
M
|
-
|
L
|
-
|
H
|
4
|
Calculus 1
|
4
|
-
|
H
|
L
|
-
|
M
|
L
|
M
|
H
|
-
|
-
|
-
|
5
|
General Informatic
|
2
|
H
|
H
|
L
|
L
|
L
|
-
|
M
|
-
|
-
|
-
|
-
|
6
|
General Informatic Lab
|
1
|
H
|
H
|
L
|
L
|
L
|
-
|
M
|
-
|
-
|
-
|
-
|
7
|
General Chemistry
|
2
|
-
|
M
|
L
|
L
|
M
|
-
|
M
|
M
|
H
|
-
|
M
|
8
|
General Chemistry Lab
|
1
|
-
|
M
|
H
|
L
|
M
|
-
|
M
|
M
|
H
|
-
|
M
|
9
|
Marcism-Leninism principles 2
|
3
|
-
|
-
|
-
|
-
|
L
|
-
|
-
|
L
|
H
|
-
|
-
|
10
|
Physics 1
|
3
|
-
|
H
|
L
|
-
|
L
|
L
|
M
|
M
|
-
|
-
|
-
|
11
|
Calculus 2
|
4
|
-
|
H
|
L
|
-
|
M
|
L
|
M
|
H
|
-
|
-
|
-
|
12
|
Algebra
|
3
|
H
|
H
|
H
|
H
|
-
|
L
|
M
|
H
|
-
|
-
|
-
|
13
|
Inorganic Chemistry
|
2
|
H
|
L
|
-
|
M
|
L
|
M
|
L
|
-
|
L
|
-
|
-
|
14
|
Inorganic Chemistry Lab
|
0.5
|
L
|
L
|
H
|
-
|
L
|
-
|
L
|
-
|
L
|
-
|
-
|
15
|
English A2.2
|
4
|
-
|
-
|
-
|
-
|
M
|
-
|
M
|
-
|
L
|
-
|
H
|
16
|
General Law
|
2
|
-
|
-
|
-
|
-
|
L
|
-
|
-
|
L
|
H
|
-
|
-
|
17
|
Ho Chi Minh Thought
|
2
|
-
|
-
|
-
|
-
|
-
|
-
|
-
|
L
|
H
|
-
|
-
|
18
|
Electrical Engineering
|
2
|
M
|
-
|
M
|
L
|
M
|
-
|
L
|
-
|
L
|
-
|
L
|
19
|
Electrical Engineering Lab
|
0.5
|
L
|
M
|
M
|
L
|
-
|
-
|
L
|
-
|
L
|
-
|
-
|
20
|
Physics 2
|
3
|
-
|
H
|
L
|
-
|
M
|
L
|
M
|
M
|
-
|
-
|
-
|
21
|
Physic Lab
|
1
|
-
|
H
|
L
|
-
|
L
|
L
|
M
|
M
|
-
|
-
|
-
|
22
|
Applied mechanics
|
3
|
-
|
H
|
-
|
H
|
-
|
-
|
-
|
-
|
-
|
L
|
-
|
23
|
Technical Drawing
|
2
|
-
|
-
|
-
|
H
|
-
|
-
|
L
|
-
|
-
|
-
|
-
|
24
|
Organic Chemistry
|
3
|
-
|
H
|
-
|
-
|
H
|
L
|
H
|
-
|
L
|
-
|
-
|
25
|
Organic Chemistry Lab
|
1
|
L
|
L
|
H
|
-
|
L
|
-
|
L
|
-
|
L
|
-
|
-
|
26
|
Revolutionary policies of the Communist Party
|
3
|
-
|
-
|
-
|
-
|
L
|
-
|
-
|
L
|
H
|
-
|
-
|
27
|
Numerical methods
|
3
|
-
|
H
|
H
|
-
|
-
|
-
|
-
|
M
|
-
|
M
|
-
|
28
|
Mechanic and hydraulic processes
|
2
|
-
|
M
|
L
|
H
|
L
|
M
|
M
|
L
|
-
|
-
|
-
|
29
|
Physical Chemistry I
|
3
|
-
|
H
|
-
|
-
|
-
|
M
|
-
|
M
|
L
|
L
|
-
|
30
|
Probablity and Statistics
|
3
|
H
|
H
|
H
|
H
|
L
|
L
|
M
|
H
|
-
|
-
|
-
|
31
|
Environment
|
2
|
-
|
-
|
-
|
L
|
-
|
-
|
L
|
-
|
H
|
L
|
-
|
32
|
Analytical Chemistry
|
2
|
-
|
H
|
H
|
-
|
L
|
-
|
L
|
L
|
-
|
-
|
L
|
33
|
Analytical Chemistry Lab
|
1
|
-
|
M
|
H
|
-
|
L
|
-
|
L
|
L
|
L
|
-
|
-
|
34
|
Economics for Engineering
|
2
|
-
|
-
|
-
|
-
|
L
|
L
|
L
|
-
|
H
|
-
|
-
|
35
|
Chemistry of Petroleum
|
2
|
H
|
-
|
L
|
M
|
-
|
H
|
L
|
L
|
L
|
L
|
-
|
36
|
Chemistry of Petroleum Lab
|
1
|
M
|
L
|
M
|
-
|
L
|
-
|
M
|
L
|
L
|
L
|
-
|
37
|
Heat transfer process and equipment
|
2
|
M
|
L
|
L
|
M
|
L
|
M
|
-
|
M
|
M
|
-
|
-
|
38
|
Basic Design of Chemical Plant
|
2
|
H
|
L
|
-
|
-
|
L
|
M
|
L
|
-
|
L
|
-
|
-
|
39
|
English for Petroleum Engineering
|
2
|
M
|
-
|
-
|
-
|
M
|
-
|
M
|
H
|
L
|
-
|
H
|
40
|
Physical Chemistry II
|
2
|
M
|
L
|
M
|
M
|
-
|
M
|
-
|
L
|
L
|
-
|
-
|
41
|
Physical Chemistry Lab
|
1
|
H
|
L
|
M
|
-
|
L
|
-
|
L
|
L
|
L
|
L
|
-
|
42
|
Introduction to Petroleum Engineering
|
2
|
H
|
-
|
-
|
-
|
H
|
-
|
L
|
L
|
M
|
-
|
L
|
43
|
Work safety and industrial sanitation
|
1
|
M
|
-
|
-
|
-
|
M
|
M
|
M
|
L
|
H
|
-
|
-
|
44
|
Process and equipment Internship
|
1
|
H
|
-
|
-
|
-
|
L
|
H
|
-
|
-
|
-
|
L
|
-
|
45
|
Catalyst technology
|
2
|
H
|
L
|
-
|
M
|
L
|
M
|
-
|
-
|
M
|
L
|
-
|
46
|
Reaction Engineering - Chemical reactors
|
2
|
H
|
H
|
L
|
L
|
-
|
M
|
L
|
M
|
-
|
-
|
-
|
47
|
Process and equipment Project
|
2
|
L
|
M
|
-
|
M
|
M
|
H
|
M
|
M
|
-
|
-
|
-
|
48
|
Process and equipment Lab
|
2
|
L
|
M
|
M
|
M
|
-
|
-
|
M
|
-
|
-
|
-
|
-
|
49
|
Mass transfer process and equipment
|
3
|
M
|
L
|
M
|
M
|
-
|
L
|
L
|
-
|
-
|
M
|
-
|
50
|
Applied thermodynamic
|
1
|
M
|
M
|
-
|
M
|
M
|
H
|
L
|
M
|
-
|
L
|
-
|
51
|
Petroleum products*
|
2
|
H
|
-
|
L
|
L
|
-
|
M
|
-
|
-
|
M
|
-
|
-
|
52
|
Automobile Pollution*
|
2
|
H
|
-
|
-
|
-
|
L
|
M
|
M
|
L
|
H
|
-
|
-
|
53
|
Process Simulation
|
2
|
M
|
M
|
M
|
L
|
-
|
M
|
L
|
L
|
-
|
H
|
-
|
54
|
Multicomponent distillation
|
2
|
H
|
M
|
-
|
M
|
L
|
M
|
L
|
-
|
-
|
M
|
-
|
55
|
Applied Mathematics
|
2
|
-
|
H
|
M
|
-
|
-
|
-
|
-
|
M
|
-
|
M
|
-
|
56
|
Separation processes in petroleum industry
|
2
|
H
|
M
|
-
|
M
|
L
|
M
|
M
|
-
|
L
|
-
|
-
|
57
|
Engineering Project 1 (Oil & Gas)
|
2
|
M
|
M
|
M
|
M
|
M
|
M
|
M
|
M
|
M
|
H
|
M
|
58
|
Refining processes 1
|
2
|
H
|
L
|
-
|
M
|
M
|
M
|
M
|
M
|
L
|
L
|
-
|
59
|
Refining processes 2
|
2
|
H
|
M
|
-
|
M
|
-
|
H
|
L
|
M
|
L
|
-
|
-
|
60
|
Refining processes Lab
|
1
|
H
|
L
|
L
|
L
|
H
|
L
|
L
|
M
|
-
|
M
|
-
|
61
|
Industrial Internship (Oil & gas)
|
2
|
H
|
L
|
M
|
M
|
M
|
M
|
M
|
L
|
M
|
M
|
L
|
62
|
Oil and Gas Industry Equipment*
|
2
|
H
|
M
|
L
|
M
|
L
|
H
|
L
|
L
|
L
|
-
|
M
|
63
|
Oil and Gas Production**
|
2
|
H
|
L
|
L
|
M
|
L
|
H
|
L
|
L
|
L
|
-
|
M
|
64
|
Analytical Techniques applied to crude oils and petroleum products
|
2
|
H
|
L
|
M
|
-
|
L
|
M
|
-
|
-
|
L
|
M
|
-
|
65
|
Lubricant, grease , additive
|
1
|
H
|
L
|
-
|
M
|
L
|
M
|
L
|
-
|
L
|
-
|
-
|
66
|
Petrochemical Technology
|
2
|
H
|
M
|
-
|
M
|
L
|
H
|
M
|
L
|
-
|
-
|
M
|
67
|
Petrochemical Technology Lab
|
2
|
H
|
L
|
M
|
-
|
L
|
-
|
L
|
L
|
L
|
L
|
-
|
68
|
Engineering Project 2 (Oil & Gas)
|
1
|
H
|
L
|
L
|
H
|
M
|
M
|
L
|
-
|
-
|
-
|
-
|
69
|
Process Control and Regulation
|
2
|
H
|
L
|
L
|
M
|
-
|
H
|
L
|
L
|
L
|
-
|
M
|
70
|
Optimization of oil refinery activities
|
2
|
H
|
L
|
L
|
M
|
L
|
H
|
L
|
L
|
L
|
-
|
M
|
71
|
Gas conditioning and processing
|
2
|
H
|
-
|
-
|
M
|
-
|
M
|
L
|
L
|
L
|
L
|
-
|
72
|
Gas conditioning and processing Lab
|
1
|
M
|
M
|
M
|
L
|
H
|
L
|
L
|
M
|
-
|
M
|
L
|
73
|
Graduate Internship (Oil & Gas)
|
2
|
H
|
L
|
L
|
L
|
L
|
M
|
M
|
L
|
M
|
L
|
L
|
74
|
Final Project
|
10
|
H
|
H
|
H
|
H
|
H
|
H
|
H
|
H
|
H
|
H
|
H
|
3. CURRICULUM ROADMAP