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UNIVERSITI TEKNIKAL MALAYSIA MELAKAACADEMIC HANDBOOK SESSION 2016 / 2017

FACULTY OF ELECTRONICS AND COMPUTER ENGINEERING

©FIRST PUBLISHED 2016Universiti Teknikal Malaysia Melaka

All rights reserved. No part of this publication may be reproduced, stored in a retrieval system,or transmitted, electronic, mechanical photocopying, recording or otherwise, without permission of the

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Tel : 06-283 3346 Faks : 06-283 3019

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Academic Handbook Session 2016/2017FACULTY OF ELECTRONICS AND COMPUTER ENGINEERING (FKEKK)ACADEMIC HANDBOOK SESSION 2016-2017


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CONTENTS Vision, Mission and Motto of UTeM 1 Educational Goals and Objectives of UTeM 2 Vision, Mission and Objectives of FKEKK 3 Foreword by the Dean 4 Senior Administrative Staff 5 FKEKK an Overview Introduction 8 Facilities 9 Administration and Academic Blocks 10 Laboratory Blocks 11 Courses Offered, Course Durations and Course Structures 12 Entry Requirements for Bachelor Degree Programmes 13 Academic System 17 Grading System & Academic Status 18 Academic Achievement & Award 19 Academic Advisory System 20 Bachelor of Electronic Engineering with Honours Introduction & Curriculum Structure 24 Career Prospects 25 Programme Objectives 26 Programme Outcomes 27 Course Curriculum 28 Pre-Requisite Subjects 30 Subject List Based On Categories 31 Option for Elective Subjects 32 Specialization 33 Syllabus Summary for the Bachelor of Electronic Engineering Programmes University Compulsory Subjects (W) 32 Common Core Subjects (P) 38 Programme Core Subjects (K) 42 Elective Subjects (E) 47 Diploma of Electronic Engineering Introduction & Curriculum Structure 54 Career Prospects 54 Programme Objectives 55 Programme Outcomes 56 Curriculum Structure 57 Course Curriculum 58 Pre-Requisite Subjects 60 Subject List Based On Categories 61

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Academic Handbook Session 2016/2017FACULTY OF ELECTRONICS AND COMPUTER ENGINEERING (FKEKK)

ACADEMIC HANDBOOK SESSION 2016-2017 FACULTY OF ELECTRONICS AND COMPUTER ENGINEERING

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Syllabus Summary for the Diploma of Electronic Engineering Programme University Compulsory Subjects (W) 64 Programme Core Subjects (P) 65 Elective Subjects (E) 73 List of FKEKK Staff Top Management Staff 76 Staff in Industrial Electronics Department 77 Staff in Computer Engineering Department 80 Staff in Telecommunication Engineering Department 83 Administrative Staff 87 Publication Committee 88


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VISION

To Be One of the World’s Leading Innovative and Creative Technical Universities

MISSION

UTeM is committed to pioneer and contribute towards the prosperity of the nation and the world by:

1. promoting knowledge through innovative teaching & learning, research and technical scholarship. 2. developing professional leaders with impeccable moral values. 3. generating sustainable development through smart partnership with the community and industry.

MOTTO

Excellence Through Competency

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VISION

To Be One of the World’s Leading Innovative and Creative Technical Universities

MISSION

UTeM is committed to pioneer and contribute towards the prosperity of the nation and the world by:

1. promoting knowledge through innovative teaching & learning, research and technical scholarship. 2. developing professional leaders with impeccable moral values. 3. generating sustainable development through smart partnership with the community and industry.

MOTTO

Excellence Through Competency

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EDUCATIONAL GOALS

1. To conduct academic and professional programmes based on relevant needs of the industries. 2. To produce graduates with relevant knowledge, technical competency, soft skills, social responsibility and

accountability. 3. To cultivate scientific method, critical thinking, creative and innovative problem solving and autonomy in decision

making amongst graduates. 4. To foster research development and innovation activities in collaboration with industries for the development of national

wealth. 5. To equip graduates with leadership and teamwork skills as well as develop communication and life-long learning skills. 6. To develop technopreneurship and managerial skills amongst graduates. 7. To instil an appreciation of the arts and cultural values and awareness of healthy life styles amongst graduates.

OBJECTIVES 1. To become a creative and innovative learning and knowledge organization that offers practice and application oriented

academic programmes in the fields of engineering and technology. 2. To lead in research, development, innovation, commercialization and consultancy activities based on the needs of the

industry. 3. To produce competent graduates with high moral values who will be the preferred choice by the industry. 4. To have competent and highly qualified staff with vast practical experiences. 5. To play an effective role as the main impetus to the industrial development of the nation. 6. To establish cooperation and smart partnership between the university and the industries. 7. To provide infrastructure and conducive environment to generate and maintain excellence. 8. To implement comprehensive and extensive usage of ICT in both academic activities and management of the

university.

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FACULTY VISION To become a reputable world-class centre of excellence in Electronic Engineering.

FACULTY MISSION

To produce highly competent electronic engineers through world class higher technical education based on application oriented teaching, learning and research with smart university-industry partnership in line with national aspirations.

FACULTY OBJECTIVES

1. To produce electronic engineers who are responsible to the Creator, the nation and the society.

2. To provide the best and updated courses in Electronics, Computer and Telecommunication Engineering.

3. To create an excellent culture in research, development, innovation and consultancy.

4. To ensure excellent co-operation and relationship between the faculty and the industries.

5. To produce competent graduates who are capable of competing globally.

6. To publish excellent and beneficial academic materials for the nation.

7. To provide up-to-date facilities and equipment for teaching and learning.

8. To provide relevant facilities and equipment for teaching, learning, research and development.

VISI

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FOREWORD BY THE DEAN Assalamualaikum wrt.wbt. All Praise to Allah, the Almighty, the Most Gracious and the Most Merciful. Through His Blessings and Grace, the Faculty of Electronic and Computer Engineering with the cooperation of the University Publisher has managed to successfully publish the faculty’s handbook for the Academic Session of 2015/2016. Last year, the university took a bold step in reviewing all the engineering programmes and restructures them into broad based programmes which was implemented for the first time in 2014/2015 session. Thus, for the 2015/2016 Academic Session the student intake is purely for the engineering broad based programme, that is, the Bachelor of Electronic Engineering with Honours programme. This faculty handbook provides the latest information on the academic programmes to be offered in the 2015/2016 Academic Session, the academic curriculum structures, the synopsis and syllabi of all the courses, the academic system applied in the teaching and learning activities and the facilities that support the teaching and learning activities in the faculty. This handbook also contains general information on the vision, mission, motto, educational objectives and objectives of UTeM and the vision, mission and objectives of the faculty. The Programmes Objectives and the Programmes Outcomes are also included for the students to realize and achieve. Updated information on the management of the faculty and the members of the academic and support staff in the faculty is included in this handbook for everyone’s reference. The faculty put great effort to compile and upgrade the handbook with the most accurate data and information. It is hope that this handbook can become an excellent guide to the students in the faculty during their course of studies in UTeM. I would like to thank the faculty publication committee for successfully compiling and publishing this handbook. On behalf of the faculty, let me take this opportunity to congratulate all the new students for having been offered a place to pursue your studies in UTeM. My best wishes to you and I hope you have a wonderful time while in UTeM. I wish you ever success in your course of studies and in your future endeavour. Thank you. Wassalam. “EXCELLENCE THROUGH COMPETENCY”

DR. NURULFAJAR BIN ABD MANAP Dean, Faculty of Electronics and Computer Engineering Universiti Teknikal Malaysia Melaka

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SENIOR ADMINISTRATIVE STAFF

FKEK

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FKEKK anOverview

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INTRODUCTION In the year 2000, Kolej Universiti Teknikal Kebangsaan Malaysia (KUTKM), the first technical university was launched and it became the 14th public university in Malaysia. The Faculty of Electronic and Computer Engineering (FKEKK) was among the various faculties officially established on 22 June 2001 and it started its operation at the temporary premises in Taman Tasik Utama, Ayer Keroh, Melaka. On 22 December 2004, FKEKK created history by being the first faculty to move its operation to the main campus in Durian Tunggal. FKEKK was able to provide the most conducive environment for effective learning, in terms of modern physical buildings and the latest state of the arts equipment and facilities. In early February 2007, the rebranding of KUTKM to Universiti Teknikal Malaysia Melaka (UTeM) took place and from then on UTeM had played significant role in producing competent and capable graduate engineers recognized globally highly sought after by international and national companies. FKEKK plays a very important role in producing electronic engineers with strong basic knowledge in science, mathematics and electronic engineering. The students are given all the opportunity to acquire technical expertise which is achieved through outcome based education fully implemented in the faculty. In the previous years, FKEKK offered four undergraduate programmes, Bachelor of Electronic Engineering (Industrial Electronics) with Honours, Bachelor of Electronic Engineering (Computer Engineering) with Honours, Bachelor of Electronic Engineering (Telecommunication Electronics) with Honours, Bachelor of Electronic Engineering (Wireless Communication) with Honours and Diploma in Electronic Engineering. Beginning last year, the university had taken a bold step in reviewing all the engineering programmes and restructured them into broad based programmes. FKEKK will be offering Bachelor of Electronic Engineering with Honours in the 2015/2016 Academic Session. However, the various electives available in the curriculum allow a student to choose an option to focus on industrial electronics, computer engineering, telecommunication electronics or wireless communication. FKEKK is headed by a dean who is assisted by two deputy deans and four heads of department. The departments in the faculty are: Department of Industrial Electronics Department of Computer Engineering Department of Telecommunication Engineering Department of Diploma Studies

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FACILITIES FKEKK is equipped with the latest facilities with the aim of providing a comfortable and conducive environment for the process of learning and teaching to take place effectively and efficiently. All the lecture rooms, each with a capacity to hold 60 students, are equipped with modern audio and visual aids such as computer and LCD projector. There are altogether 18 laboratories and workshops. Besides these, there are 17 student self-study rooms; each room is capable of accommodating 30 students. All the laboratories are equipped with the latest industrial equipment which are sophisticated enough with the objective of producing highly skilled graduates who will be of great demand by the industries. The laboratories are equipped on the rational of providing an attractive ratio of two students working on one workstation or equipment, providing the students the opportunity to gain enough exposure and learning through each experiment. Each laboratory is further equipped with computers and internet facilities to facilitate the teaching and learning process as well as report and project writing. Overall FKEKK 19 laboratories are listed as below: Basic Electronic Laboratory 1 and 2 Industrial Electronic Laboratory Industrial Automation Laboratory Electrical Technology Laboratory Computer Engineering Laboratory Digital Laboratory 1 and 2 Microprocessor Laboratory Basic Communication Laboratory Communication Electronics Laboratory Microwave Laboratory Wireless Communication Laboratory FYP and Fabrication Laboratory Postgraduate Research Laboratory I Postgraduate Research Laboratory II Research Laboratory I Research Laboratory II Research Laboratory III All the above laboratories are equipped with the state of the art facilities and simulation software to enable the students to make analytical comparison studies on practical and simulated outcomes or results. Each laboratory is taken charge by a lecturer and assisted by an assistant engineer/technician.

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ADMINISTRATION AND ACADEMIC BLOCK


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LABORATORIES BLOCK

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LABORATORIES BLOCK

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COURSES OFFERED FKEKK offers the Diploma and Degree Programmes as below: Bachelor of Electronic Engineering with Honours Diploma in Electronic Engineering COURSE DURATIONS The Bachelor Degree duration is a minimum of 4 years and a maximum of 6 years. The Diploma programme duration is 3 years. COURSE STRUCTURES Courses offered are in line to the recommendations from the Engineering Accreditation Council (EAC) of Malaysia. All the subjects in a program have their respective learning outcomes to ascertain that the program outcomes are attained. The students’ theoretical knowledge is acquired through individual and group activities that include lecture sessions incorporating interactive learning, problem-based learning and cooperative learning. Theoretical knowledge is enhanced and reinforced during laboratory sessions that include elements of analysis and design in the experiments. Self-directed learning and group learning are very much encouraged especially during the laboratory sessions, problem-based learning, computer oriented studies, individual and group assignments, engineering practice, industrial training and the final year project which is related to electronic engineering. Assessment on the success of the students is based heavily on individual performance such as tests, individual assignments, undertaking project that includes development, oral presentation and report, and the final examination. Group assessment is mainly taken from laboratory reports, group assignments and presentations.

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ENTRY REQUIREMENTS FOR THE BACHELOR DEGREE PROGRAMME The candidate for Bachelor of Electronic Engineering in FKEKK must have the following qualifications: 1. Minimum Entry Requirements For STPM Candidates

University General Requirements

A Pass in Sijil Pelajaran Malaysia (SPM) / equivalent with a credit in Bahasa Melayu or credit in Bahasa Melayu July Paper; and Pass in Sijil Tinggi Persekolahan Malaysia (STPM) with at least CGPA 2.00 and obtained at least:

C Grade (NGMP 2.00) in Pengajian Am; and C Grade (NGMP 2.00) in two (2) other subjects.

and Obtained at least Band 2 in the Malaysian University English Test (MUET) and Faculty Programme Special Requirements

A pass in Sijil Tinggi Persekolahan Malaysia (STPM) with at least with C Grade (NGMP 2.00) in all of the following subject:

Mathematics T / Further Mathematics T / Mathematics S Physics Chemistry

or Mathematics T / Further Mathematics T / Mathematics S Chemistry Biology and obtained at least credits (4B/ B Gred) in Physics at Sijil Pelajaran Malaysia (SPM) level

and The applicant must not be colour blind and not handicapped that can impair practical work

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2. Minimum Entry Requirements for Matriculation Candidates

University General Requirements

A Pass in Sijil Pelajaran Malaysia (SPM) / equivalent with credit in Bahasa Melayu or credit in Bahasa Melayu July Paper; or Pass in MOE Matriculation / UM Science Foundation / UiTM Foundation Studies with at least CGPA 2.00; and obtained at least Band 2 in the Malaysian University English Test (MUET) and Faculty Programme Special Requirements

Obtained at least C Grade (NGMP 2.00) in MOE Matriculation / UM Science Foundation / UiTM Foundation Studies in all following subjects:

Mathematics / Engineering Mathematics Physics / Engineering Physics Chemistry / Engineering Chemistry / Electric and Electronic Engineering Studies / Civil Engineering Studies

or

Mathematics / Engineering Mathematics Chemistry / Engineering Chemistry Biology and obtained at least credits (B Gred) in Physics at Sijil Pelajaran Malaysia (SPM) level

and

The applicant must not be colour blind and not handicapped that can impair practical work

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3. Minimum Entry Requirements for Diploma holders

University Entry Requirements

A Pass Sijil Pelajaran Malaysia Pass (SPM) / equivalent with credit in Bahasa Melayu or credit in Bahasa Melayu July Paper; and

A Pass in Diploma of other qualification recognized as equivalent by the Government of Malaysia and approved by the IPTA Senate;

or

A pass in Sijil Tinggi Persekolahan Malaysia (STPM) with at least C Grade (CGPA 2.00) in Pengajian Am; and C Grade (CGPA 2.00) in two (2) other subjects.

or

A pass in Matriculation with at least CGPA 2.00 and

obtained at least Band 2 in the Malaysian University English Test (MUET) and Faculty Programme Special Requirements

A pass in Diploma with at least CGPA 3.00 in a related field from a recognized institution and approved by the University’s Senate; and Credit exemption is subjected to the discretion and approval by the Faculty; and Passed / completed studies at Diploma level during application. or

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A pass in Sijil Tinggi Persekolahan Malaysia (STPM) with at least C Grade (CGPA 2.00) in all the following subjects: Pengajian Am Mathematics T / Further Mathematics T / Mathematics S Physics Chemistry or Pengajian Am Mathematics T / Further Mathematics T / Mathematics S Chemistry Biology and obtained at least credits (4B/B Gred) in Physics at Sijil Pelajaran Malaysia (SPM) level

or A pass in MOE Matriculation / UM Foundation Studies / UiTM Foundation Studies examination with at least C Grade (NGMP 2.00) in all the following subjects: Mathematics / Engineering Mathematics Physics / Engineering Physics / Engineering Science Chemistry / Engineering Chemistry / Electric and Electronic Engineering Studies / Civil Engineering Studies

or

Mathematics / Engineering Mathematics Chemistry / Engineering Chemistry Biology and obtained at least credits (B Gred) in Physics at Sijil Pelajaran Malaysia (SPM) level and

The applicant must not be colour blind and not handicapped that can impair practical work.

4. Malaysian University English Test (MUET)

Students with Band 2 in MUET upon registration for the Bachelor degree course are required to register and resit for

MUET and must at least obtain a Band 3 within two years from the date of registration for the course. Students who fail to do so within the two years are not allowed to continue their studies in the following semester.

The university fully encourages students without Band 4 in MUET to register and take the Foundation English

Programme (BLHL 1010) subject offered by the university in order to assist them to be more prepared to re-sit the MUET. Students are required to pay RM100.00 to take the subject

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ACADEMIC SYSTEM The academic system of this University is based on the semester system which is a common practice in all the Institutions of Higher Education in Malaysia. The Academic Handbook explains the Procedures and University Academic Rules enforced.

Table 1: A Typical Academic Year

SEMESTER I Classes Semester Break Classes Revision Week Final Examination

7 weeks 1 week 7 weeks 1 week 2 weeks

Total

18 weeks

Break Between Semesters 3 weeks

SEMESTER II Classes Semester Break Classes Revision Week Final Examination

7 weeks 1 week 7 weeks 1 week 2 weeks

Total

18 weeks

OR

End of Semester Break 13 weeks Break Between Semesters 1 week

SPECIAL SEMESTER Classes and Examination End of Semester Break

8 weeks 4 weeks

TOTAL

52 weeks

TOTAL

52 weeks

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GRADING SYSTEM A student’s achievement for each subject is based on the grades which are illustrated in Table 2.

Table 2: Marks, Grades and Points Awarded

Marks Grade Points Achievements

80 – 100 75 – 79 70 – 74 65 – 69 60 – 64 55 – 59 50 – 54 47 – 49 44 – 46 40 – 43 00 – 39

A

A- B+ B

B- C+

C C- D+

D E

4.0 3.7 3.3 3.0 2.7 2.3 2.0 1.7 1.3 1.0 0.0

Distinction Distinction

Merit Merit Merit Pass Pass

Conditional Pass Conditional Pass Conditional Pass

Fail

ACADEMIC STATUS A student’s achievement is evaluated based on GPA and CGPA. A student’s academic status will be provided at the end of each semester as shown in Table 3.

Table 3: Academic Status Classification

STATUS CGPA

Good (KB) CGPA ≥ 2.00

Conditional (KS) 1.70 ≤ CGPA < 2.00

Fail (KG) CGPA < 1.70

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ACADEMIC ACHIEVEMENTS A student’s overall achievement is based on Grade Point Average (GPA) obtained for a particular semester and Cumulative Grade Point Average (CGPA) for the semesters that have been completed. These measure the student’s academic position. Grade Point Average (GPA) GPA is the grade point average obtained in a particular semester. It is based on the following calculations:

Total Points, JMN = k1m1 + k2m2 + ........knmn

Total Calculated Credits, JKK = k1 + k2 + ........kn

GPA = JMN / JKK = [k1m1 + k2m2 + ........knmn] / [k1 + k2 + ........kn]

Where : kn = Credit for n subject

mn = Points from the n subject Cumulative Grade Point Average (CGPA) CGPA is the cumulative grade point average obtained for the semesters that have been completed. It can be calculated as follows:

CGPA = [JMN1 + JMN2 + ........JMNn] / [JKK1 + JKK2 + ........JKKn] Where : JMNn = Total points obtained in n semester JKKn = Total credits in n semester AWARD A Bachelor Degree shall be awarded if all the following conditions are fulfilled. A student: 1. must get Good status (KB) in the final semester. 2. has passed all the subjects required as listed in the course curriculum. 3. has applied for the award of the degree, approved by the faculty and certified by the Senate. 4. has passed MUET with BAND 4 according to the University’s directive. 5. has met all the other University’s requirements.

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ACADEMIC ADVISORY SYSTEM The Academic Advisory System was introduced from the beginning when the faculty first started. Fully aware that the academic semester system implemented in the university is very different as compared to the system followed by students in the schools or in the matriculation colleges, the Academic Advisory System is implemented to provide the platform for students to seek advice and guidance to manage their studies while in the university. In the semester system, the students have the freedom to determine their academic load subject according to their ability but within the conditions stipulated by the faculty and academic regulations. As such students need to plan their studies most suitable and appropriate for themselves. To assist the students, each student is assigned an Academic Advisor who is an academic staff member, well-versed in the Academic System. The Academic Advisor plays a pivotal role as a mentor, advisor, referee and friend in helping the students in their studies and other academic activities. The Academic Advisory System and its importance One prominent aspect of the Academic Advisory System is the assignment of Academic Advisors to students ought to be proper advice and guidance to the students in the followings: 1. It is not compulsory for the students to take all the subjects offered in each semester. For those with good academic

standings, they are encouraged to register for all the subjects offered but for those with average academic standing, they are advised to take less academic load, a maximum of 12 credits only for those with conditional academic standing, to improve their academic standings for the next semester. Thus, the students need to plan their studies and register the appropriate subjects in each semester according to their ability.

2. The semester system is a flexible education system to cater for students with mixed academic capability of excellent

students, average students and not so fast learners. The difference between them is for each and everyone to complete their studies successfully within the prescribed time. The Academic Advisory System will help each student the opportunity to design a study plan to complete the studies successfully.

3. The semester system is a modular system employing the concept of intensive learning and continuous assessment.

Therefore, it is imperative for students to adapt with this learning environment and fully utilized the system. 4. In addition of having to adapt to the semester system, the students are also faced with other problems such as cultural

shock, time management, self-management and also other personal problems especially for those who are staying away from their parents for the first time.

5. As the students progress along, due to their academic standings, even if they are from the same cohort, they may not be together for a certain subject. In other words, most students may not be together in the same group throughout their studies, and this can be difficult for them to conduct peer groups and subject discussions effectively.

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6. Therefore, to assist the students so that they can adapt to the university environment and at the same time get the full

benefit of the semester system, the faculty assigns academic staff members to become academic advisors to take care of around 15 – 20 students each, acting as mentors to provide guidance, encouragement and advice to the students. It is the Academic Advisor’s role to see that the students are given the proper advice, guidelines, action to take, motivation and encouragement from the day of the registration until the students’ graduation from university.

The roles and responsibilities of the Academic Advisor 1. Helps students to understand and follow the semester system, academic rules and university examination rules.

2. Guides students in preparing their study charts while in the university, for instance in deciding the total credit hours to

be taken in a particular semester and study duration.

3. Advises the students in relation to the choice of subjects and subject registration as well as the add/drop process, based on the students’ academic performance and ability.

4. Monitors students’ performance and provides counselling for them to make changes in their study plan where necessary.

5. Recommends students to take the necessary steps and appropriate action when the students encounter problems that rendered the necessity to do subject withdrawal or/and study deferment.

6. Monitors and keeps records of the students’ personal profile and academic achievement as well as the students’ problems, and inform the faculty when necessary.

7. Reviews and administers students’ subject registration record in order to ensure no subject is left out. This is

necessary when it is time to verify the students for the conferment of the degree.

8. Holds meetings with their students during the first week of each semester and subsequently every now and then throughout the semester to facilitate and update on the well-being and welfare of the students. The academic advisor has to devote adequate time meetings in a group or on individual basis when necessary

The roles and responsibilities of the Students 1. Read and understand fully the academic rules & regulations of the University Academic System.

2. Take the necessary actions at the required time such as subject registration, add/drop of subjects, subject withdrawal

and study deferment.

3. Monitor and take the necessary actions on personal academic achievement and performance.

4. Take the initiative to meet the academic advisor to update on personal profile, academic performance and personal problems encountered.

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INTRODUCTION Starting from 2014, UTeM had decided to implement all the engineering programmes along the broad-based curriculum structure. The Bachelor of Electronic Engineering with Honours offered by the faculty is a broad-based course which combines engineering science, mathematics, electrical and electronic engineering fundamentals and develops in students the mastery of electronic engineering principles and applications to solve electronic engineering problems, including the complex ones. All the students will undergo three years of common curriculum upon which they can decide a programme with emphasis on computer engineering, industrial electronics, telecommunication electronics or wireless communication in the final year. The broad-based programme will provide the solid foundation in theoretical understanding of electronic engineering to allow students to undertake problem analysis and identifications, formulation and generate appropriate solutions in the broad field of electrical and electronic engineering. The curriculum helps to hone the generic skills of the students and prepare them the opportunities to perform research, present their findings, implement and provide engineering solutions. The programme is designed in an integrated manner to build up the students’ engineering expertise from fundamentals to addressing of specific engineering challenges with the opportunity to develop specialization in focused areas of interest. The programme is implemented with a blend of theory and practice, with team-based assignments and projects running alongside with lectures. All the programmes offered by the faculty have been accredited by the relevant professional institutions and are qualified to register with the Board of Engineers Malaysia as the first step towards becoming a professional engineer. CURRICULUM STRUCTURE

Year 1 is more of a reinforcement year for the students who have been given the opportunity to begin their journey towards becoming electronic engineers. The subjects offered are Engineering Mathematics, Computer Programming, Electrical and Electronic Engineering Fundamentals and

subjects that fortified moral values and co-curriculum.

In second and third year, the students have to study the Bachelor of Electronic Engineering common and

programme core subjects. These subjects are carefully selected to fulfil the body of knowledge, the formal

educational requirements of graduate engineers, which is closely monitored and assessed by the Engineering Accreditation Council of Malaysia. Apart from that, the students are required to undergo a minimum of 10 weeks industrial training during the Special Semester of Year 3. This exercise provides the students the opportunity to experience and learn the reality of working life besides seeking more knowledge and networking.

Hexapod Robot Design in Microprocessor Lab, FKEKK

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In the final year, the students have the opportunity to choose which areas of interest they want to focus in. For those who prefer industrial electronics, they can choose electives listed under that particular specialization. Likewise for the other specializations of computer engineering, telecommunication electronics and wireless communications, the students are given the opportunity to have their preferences. The students are also required to carry out a Bachelor Degree project that is related to field of specialization. The purpose of the project is to provide the students to display their ability to apply engineering knowledge to solve complex engineering problems utilizing components, design systems and processes, undertaking problem identifications, formulation and analysis of complex problems encountered. A total of 129 credits are required for the Bachelor of Electronic Engineering to be awarded upon successfully completed the programme. An Electronic Engineering degree graduate from FKEKK, UTeM has an immense range of careers to choose from. The multi-faceted approach in conducting the programme provides the graduates the knowledge, confidence and attributes to enter the workforce with analytical and communication skills, making a significant contribution to the development of the engineering field and to the nation. CAREER PROSPECT Career prospect for FKEKK graduates is extremely good. Graduates from this course can be employed in the fields of electronic engineering as industrial electronic engineers, computer engineers, telecommunication engineers and wireless communication engineers and other numerous related engineering professions. They can be engineers in the industrial automation systems, industrial electronic, control systems, electronic instrumentation, computerised system in manufacturing and production industries, plant engineers in industries, manufacturing computer product such as

computers and computer peripherals, system engineers in industries manufacturing computer based product, telecommunication systems and wireless communication systems. Graduates who have special interest in the academic fields can become academicians such as lecturers and researchers in institutions of higher education, the universities and research centres and agencies. Upon being qualified as professional engineers, they can practice locally as well as in countries who are members of the Washington Accord. Graduates who choose not to become employee can be self-employed and opt to be involved in business and become successful entrepreneurs in their areas of expertise. Anechoic Chamber in

Research Laboratory 1, FKEKK

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PROGRAMME OBJECTIVES

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PROGRAMME OUTCOMES

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COURSE CURRICULUM FOR BACHELOR OF ELECTRONIC ENGINEERING WITH HONOURS

Semester 1 Semester 2

CODE SUBJECT CREDIT CATEGORY CODE SUBJECT CREDIT CATEGORY

BLHW 1702/ BLHL 1012*

Islamic and Asian Civilization(TITAS)/ Malay Language Communication

2 W

BLHL xxx2 Third Language 2 W

BKKX xxx1 Co-Curriculum I 1 W BKKX xxx1 Co-Curriculum II 1 W

BMFG 1113 Engineering Mathematics 3 P BMCG 1013 Differential Equations 3 P

BEKG 1123 Principles of Electrical and Electronics

3 P BITG 1233 Computer Programming 3 P

BMFG 1213 Engineering Materials 3 P BENG 1413 Digital Electronics 3 P

BEKG 1233 Principles of Instrumentation and Measurement

3 P BMCG 1523 Engineering Graphics and CAD 3 P

TOTAL 15 BENG 1132 Engineering Practice 2 K

TOTAL 17

Semester 3

Semester 4

CODE SUBJECT CREDIT CATEGORY CODE SUBJECT CREDIT CATEGORY BLHW 2712/ BLHW 2752*

Ethnic Relations/ Malaysian Culture 2 W BLHW 2403 Technical English 3 W

BENG 2142 Statistics 2 P BEKG 2452 Numerical Methods 2 P

BEKG 2433 Electrical Systems 3 P BENC 2423 Microprocessor Technology 3 K

BENC 2413 Digital System 3 K BENT 2723 Circuit Theory 2 3 K

BENT 2713 Circuit Theory 1 3 K BENE 2133 Analogue Electronics 3 K

BENE 2123 Fundamental of Electronics 3 K BENG 2431 Electronic Engineering

Lab 2 1 K

BENG 2211 Electronic Engineering Lab 1 1 K TOTAL 15

TOTAL 17

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BTMW 4012 Technology Entrepreneurship 2 W BLHW 3403 English For Professional

Communication 3 W

BENC 3443 Multimedia Technology and Applications 3 K BLHC 4032/

BLHW 1742*

Critical and Creative Thinking/ Malaysian Studies

2 W

BENT 3733 Signals and Systems 3 K BMFG 4623 Engineering Economy and Management 3 P

BENE 3143 Electronic System Design and Analysis 3 K BENT 3753 Communication

Principles 3 K

BENT 3743 Electromagnetic Fields and Waves 3 K BENE 3223 Control Principles and

Systems 3 K

BENG 3211 Electronic Engineering Lab 3 1 K BENU 3863 Integrated Design Project 3 K

TOTAL 15 BENG 3761 Electronic Engineering Lab 4 1 K

TOTAL 18

Special Semester


BENU 3005 Industrial Training 5 P 2 W

TOTAL 5 130



BENU 4972 Bachelor Degree Project I 2 P BENU 4984 Bachelor Degree Project 2 4 P

BENG 4322 Engineer and Society 2 P BENC 4453 Computer Architecture 3 K

BENU 4131 Engineering Seminar 1 P BENX xxx3 Elective 3 3 E

BENT 4733 Digital Signal Processing 3 K BENX xxx3 Elective 4 3 E

BENX xxx3 Elective 1 3 E TOTAL 13

BENX xxx3 Elective 2 3 E

TOTAL 14 GRAND TOTAL 129

Note: * To be taken by International Students Only Category: W: University Compulsory Subjects, P: Common Core Subjects, K: Program Core Subjects, E: Elective Subjects

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Pre-requisite Subjects

YEAR 1

YEAR 2

YEAR 3

YEAR 4

Semester 1 Semester 2 Semester 3 Semester 4 Semester 5 Semester 6 Semester 7 Semester 8

BENE 2133

Analogue

Electronics

BENE 2123

Electronic

Fundamentals

BLHW 3403

English for

Professional Communication

BLHW 2403

Technical English

BENU 4984

BDP 2

BENU 4972

BDP 1


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SUBJECT LIST BASED ON CATEGORIES UNIVERSITY COMPULSORY SUBJECTS (W) BKKX xxx1 Co-Curriculum 1 and 2 BLHW 1702 Islamic and Asian Civillization

(TITAS) BLHL 1012* Malay Language Communication BLHW 2712 Ethnic Relations BLHW 2752* Malaysian Culture BLHW 2403 Technical English BLHL xxx2 Third Language BLHW 3403 English For Professional

Communication BPTW 4012 Technology Entrepreneurship BLHC 4032 Critical and Creative Thinking BLHW 1742* Malaysian Studies COMMON CORE SUBJECTS (P) BMFG 1113 Engineering Mathematics BEKG 1123 Principles of Electrical and

Electronics BMFG 1213 Engineering Materials BEKG 1233 Principles of Instrumentation and Measurement BMCG 1013 Differential Equations BITG 1233 Computer Programming BENG 1413 Digital Electronics BMCG 1523 Engineering Graphics and CAD BENG 1132 Engineering Practice BENG 2142 Statistics BEKG 2433 Electrical Systems BEKG 2452 Numerical Methods BENU 3005 Industrial Training BMFG 4623 Engineering Economy and Management BENU 4972 Bachelor Degree Project I BENG 4322 Engineer and Society BENU 4131 Engineering Seminar BENU 4984 Bachelor Degree Project II

PROGRAMME CORE SUBJECTS (K) BENC 2413 Digital System BENT 2713 Circuit Theory I BENE 2123 Fundamental of Electronics BENG 2211 Electronic Engineering Lab 1 BENC 2423 Microprocessor Technology BENT 2723 Circuit Theory II BENE 2133 Analog Electronics BENG 2431 Electronic Engineering Lab 2 BENC 3443 Multimedia Technology and

Applications BENT 3733 Signals and Systems BENE 3143 Electronic System Design and Analysis BENT 3743 Electromagnetic Fields and Waves BENG 3211 Electronic Engineering Lab 3 BENT 3753 Communication Principles BENE 3223 Control Principles and Systems BENU 3863 Integrated Design Project BENG 3761 Electronic Engineering Lab 4 BENT 4733 Digital Signal Processing BENC 4453 Computer Architecture ELECTIVE SUBJECTS (E) BENC 4463 Microcontroller Technology BENE 4233 Industrial Control BENT 4773 Telecommunication System Engineering BENT 4783 Wireless Communication System BENC 4473 Digital Integrated Circuit Design BENE 4333 Artificial Intelligence BENT 4793 Microwave Engineering BENT 4813 Data Communication and Networking BENC 4483 Computer Vision and Pattern Recognition BENE 4243 Industrial Automation BENT 4823 Digital Communication System BENT 4833 Antenna and Wave Propagation BENC 4493 Real Time System BENE 4343 Power Electronics and Drives BENT 4843 Optoelectronics BENT 4853 Radio Navigation System

BA

CH

ELO

R O

F EL

ECTR

ON

IC E

NG

INEE

RIN

G

(CO

MPU

TER

EN

GIN

EER

ING

) WIT

H H

ON

OU

RS

Note: * University compulsory subjects for International Students only

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SUBJECT LIST BASED ON CATEGORIES UNIVERSITY COMPULSORY SUBJECTS (W) BKKX xxx1 Co-Curriculum 1 and 2 BLHW 1702 Islamic and Asian Civillization

(TITAS) BLHL 1012* Malay Language Communication BLHW 2712 Ethnic Relations BLHW 2752* Malaysian Culture BLHW 2403 Technical English BLHL xxx2 Third Language BLHW 3403 English For Professional

Communication BPTW 4012 Technology Entrepreneurship BLHC 4032 Critical and Creative Thinking BLHW 1742* Malaysian Studies COMMON CORE SUBJECTS (P) BMFG 1113 Engineering Mathematics BEKG 1123 Principles of Electrical and

Electronics BMFG 1213 Engineering Materials BEKG 1233 Principles of Instrumentation and Measurement BMCG 1013 Differential Equations BITG 1233 Computer Programming BENG 1413 Digital Electronics BMCG 1523 Engineering Graphics and CAD BENG 1132 Engineering Practice BENG 2142 Statistics BEKG 2433 Electrical Systems BEKG 2452 Numerical Methods BENU 3005 Industrial Training BMFG 4623 Engineering Economy and Management BENU 4972 Bachelor Degree Project I BENG 4322 Engineer and Society BENU 4131 Engineering Seminar BENU 4984 Bachelor Degree Project II

PROGRAMME CORE SUBJECTS (K) BENC 2413 Digital System BENT 2713 Circuit Theory I BENE 2123 Fundamental of Electronics BENG 2211 Electronic Engineering Lab 1 BENC 2423 Microprocessor Technology BENT 2723 Circuit Theory II BENE 2133 Analog Electronics BENG 2431 Electronic Engineering Lab 2 BENC 3443 Multimedia Technology and

Applications BENT 3733 Signals and Systems BENE 3143 Electronic System Design and Analysis BENT 3743 Electromagnetic Fields and Waves BENG 3211 Electronic Engineering Lab 3 BENT 3753 Communication Principles BENE 3223 Control Principles and Systems BENU 3863 Integrated Design Project BENG 3761 Electronic Engineering Lab 4 BENT 4733 Digital Signal Processing BENC 4453 Computer Architecture ELECTIVE SUBJECTS (E) BENC 4463 Microcontroller Technology BENE 4233 Industrial Control BENT 4773 Telecommunication System Engineering BENT 4783 Wireless Communication System BENC 4473 Digital Integrated Circuit Design BENE 4333 Artificial Intelligence BENT 4793 Microwave Engineering BENT 4813 Data Communication and Networking BENC 4483 Computer Vision and Pattern Recognition BENE 4243 Industrial Automation BENT 4823 Digital Communication System BENT 4833 Antenna and Wave Propagation BENC 4493 Real Time System BENE 4343 Power Electronics and Drives BENT 4843 Optoelectronics BENT 4853 Radio Navigation System

BA

CH

ELO

R O

F EL

ECTR

ON

IC E

NG

INEE

RIN

G

(CO

MPU

TER

EN

GIN

EER

ING

) WIT

H H

ON

OU

RS

Note: * University compulsory subjects for International Students only

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OPTION FOR ELECTIVE SUBJECTS

Elective Subjects Select FOUR(4) subjects : THREE (3) subjects from Programme Specialization Electives and ONE(1) from Open Electives

Programme Specialization

Electives

Select THREE(3) subjects based on specialization Computer

Engineering Industrial

Electronics Telecommunication

Engineering Wireless

Communication BENC 4463

Microcontroller Technology

BENE 4233 Industrial Control

BENT 4773 Telecommunication System Engineering

BENT 4783 Wireless

Communication System

BENC 4473 Digital Integrated

Circuit Design

BENE 4243 Industrial Automation

BENT 4793 Microwave

Engineering

BENT 4813 Data Communication

and Networking BENC 4483

Computer Vision and Pattern Recognition

BENE 4333 Artificial Intelligence

BENT 4823 Digital

Communication System

BENT 4833 Antenna and Wave

Propagation

BENC 4493 Real Time System

BENE 4343 Power Electronics

and Drives

BENT 4843 Optoelectronics

BENT 4853 Radio Navigation

System

Open Electives

Select ONE(1) subject either from the chosen Programme Specialization Electives or

from any Programme Specialization Electives or

from any Engineering Programme Specialization Electives

Example : BENC 4463 + BENC 4473 + BENC 4483 + BENC 4493 or

BENC 4463 + BENC 4473 + BENC 4493 + BENT 4813 or

BENC 4473 + BENC 4483 + BENC 4493 + 1 Elective Subject from FKE or FKM or /FKP

33


ACADEMIC HANDBOOK SESSION 2016-2017 FACULTY OF ELECTRONIC AND COMPUTER ENGINEERING

33

SPECIALIZATION Students who register for the Bachelor of Electronic Engineering program may specialize either in Industrial Electronics, Computer Engineering, Telecommunication Electronics or Wireless Communication as shown in Table 1. All the undergraduate programs offered by the Faculty of Electronics and Computer Engineering are accredited and recognized by the Board of Engineers Malaysia (BEM). Graduates from the Bachelor of Engineering programs above may apply to register with the Board of Engineers Malaysia, as graduate engineer in the engineering fields as shown in Table 1.

Table 1

Degree Awarded Choice of Field Elective Field of Registration with BEM

Bachelor of Electronic Engineering with Honours

[BENG]

Industrial Electronics

Electronic Engineer Computer Engineering

Telecommunication Electronics Wireless Communication

Syllabus Summary for the

Bachelor of Electronic Engineering Programmes

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UNIVERSITY COMPULSORY SUBJECTS (W) BKKX xxx1 Co-Curriculum 1 and 2 BLHW 1702* Islamic and Asian Civillization (TITAS)* BLHL 1012** Malay Language Communication** BLHW 2403 Technical English BLHW 2712* Ethnic Relations* BLHW 2752** Malaysian Culture** BLHW 3403 English For Professional Communication BLHL xxx2 Third Language BLHC 4032* Critical and Creative Thinking* BLHW 1742** Malaysian Studies** BPTW 4012 Technology Entrepreneurship PLEASE REFER TO THE PUSAT BAHASA DAN PEMBANGUNAN INSAN (PBPI) HANDBOOK FOR THE SYNOPSIS AND THE DETAIL SYLLABUS FOR ABOVE SUBJECTS.

SYLL

AB

US

BR

IEF

FOR

BA

CH

ELO

R O

F EL

ECTR

ON

IC E

NG

INEE

RIN

G P

RO

GR

AM

ME

Note: * University compulsory subjects to be taken by local students ** University compulsory subjects to be taken by international students

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COMMON CORE SUBJECTS (P)

BMFG 1113: ENGINEERING MATHEMATICS Synopsis This course consists of three chapters: Function of Several Variables, Multiple Integrals and Vector-valued Functions, The syllabus is developed by introducing the concepts of the functions with several variables, integration and also vector-valued function, followed by learning various techniques in solving the problems and its application in physical and engineering fields. References [1] Anton H, Bivens I & Davis S, Calculus Multivariable, 8th

Edition John Wiley, 2010 [2] Edwin Kreyszig, Advanced Engineering Mathematics,

9th Edition, John Wiley 2009 [3] Donald Trim, Calculus for Engineers, 4th Edition,

Prentice Hall, 2008 [4] Glyn James, Modern Engineering Mathematics, 4th

Edition, Prentice Hall, 2007 [5] Stroud K. A., Engineering Mathematics, 5th Edition

Palgrave Macmillan, 2007 BEKG 1123: PRINCIPLES OF ELECTRICAL AND ELECTRONICS Synopsis This course will discuss about the basic principles of electrical and electronics; introductions to electric elements, symbols and components, KCL, KVL, Node and Mesh in solving DC series and parallel circuit. Introduction to magnetism, electromagnetism and AC characteristics. Introduction to semiconductors, atomic structures, energy band, P-type and N-type. Study on structure, principle and application of diode, BJT and Op-Amp circuits. References [1] Thomas L.Floyd, Principles of Electric Circuits, Pearson

9th Edition, 2010 [2] Thomas L.Floyd and David M. Buchala, Electric Circuits

Fundamentals, Pearson 8th Edition, 2010 [3] Boylestad, R. L., Nasheslsky, L. Electronic Devices and

Circuit Theory, Pearson Prentice Hall, 2010.

BMFG 1213: ENGINEERING MATERIALS Synopsis This course introduces basic concepts of engineering materials that covers introduction to engineering materials, interatomic bonding, crystalline structure and imperfections and diffusion in solid. Explanation on different types of engineering material (i.e. metal, ceramic, polymer and composites), its mechanical properties, basic applications and processing are also included. Introduction to the binary phase diagrams (composition and microstructure correlation) is also given. References [1] Callister, W.D. Jr. Materials Science and Engineering –

An Introduction, 8th Edition, John Wiley & Sons Inc, 2010

[2] Smith, W.F. Principle of Materials Science & Engineering, 4th Edition McGraw Hill, 1998

[3] Shackelford, J.F. Materials Science and Engineering – An Introduction, 5th Edition Prentice Hall, 2000

[4] Bolton W. Engineering Materials Technology 3rd Edition, BH Publisher, 2001

[5] Vernon, J. Introduction to Engineering Materials 4th Edition Palgrave MacMilan, 2001

BEKG1233: PRINCIPLES OF INSTRUMENTATION AND MEASUREMENT Synopsis The subject discusses about units and dimensions, standards, errors, static characteristics, noise and calibration in measurement. It covers most on the measurement devices such as galvanometers, ammeters, voltmeters, wattmeter, temperature, force and torque and pressure measurement as well as accelerator meter. It also introduces oscilloscope and sensors for instrumentation application. References [1] HS Kalsi, Electronic Instrumentation, 3rd. Edition, Tata

McGraw Hill, 2010 [2] UA Bakshi, AV Bakshi and KA Bakshi, Electronic

Measurements and Instrumentation, Technical Publications Pune, 2009

[3] S Wolf, Richard F. M. Smith, Reference Manual for Electronic Instrumentation Laboratories 2nd Edition, Prentice Hall, 2004

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[4] Calibration Book, Vaisala Oyj, Vaisala, 2006 BMCG 1013: DIFFERENTIAL EQUATIONS Synopsis This course is intended to introduce the concept and theories of differential equations. Second order linear differential equations with constant coefficients will be solved by using the methods of undetermined coefficient, variation of parameters and Laplace transform. Fourier series in relation to periodic functions will be discussed. An introduction to the solution and application of partial differential equations with boundary value problems using the method of separation of variables and Fourier series will also be discussed. References [1] Muzalna M. J., Irmawani J., Rahifa R., Nurilyana A. A.,

2010, Module 2: Differential Equations, Penerbit UTeM. [2] Cengel Y. A. & Palm W. J., 2013, Differential Equations

for Engineers and Scientists, 1st Ed. McGraw-Hill., U.S.A.

[3] Nagle R. K., Saff E. B. & Snider A. D., 2011, Fundamentals of Differential Equations and Boundary Value Problems, 6 th Ed. Pearson Education Inc., U.S.A.

[4] Kohler W. & Johnson L., 2011. Elementary Differential Equations with Boundary Value Problems. Pearson Education Inc., U.S.A.

[5] Edwards C. H. & Penny D. E., 2008. Differential Equations and Boundary Value Problems, 4 th Ed. Pearson Education Inc., New Jersey, U.S.A.

BITG 1233: COMPUTER PROGRAMMING Synopsis This course covers the introductory topics in programming using C++ language. It includes the introduction to computers and programming, the fundamentals of programming, problem solving and software development. Data types and operators, selection, repetition, function, array, file, structured data and pointer are among the topics covered in the course. References [1] Gaddis, T., (2011), “Starting Out with C++ Brief

Version: From Control Structures Through Objects 7th.

Edition”, Pearson Education. [2] Abdullah, N. et. al, (2014), "Lab Module Computer

Programming BITG 1113", FTMK, UTeM

[3] Friedman, Koffman (2011), “Problem Solving, Abstraction and Design using C++”, 6th Edition, Pearson Education

[4] Etter, D.M., Ingber, J.A., (2012), "Engineering Problem Solving with C++", 3rd Edition, Pearson Education.

[5] Hanly, J.R, (2002), “Essential C++ for Engineers and Scientists”, 2nd Addison Wesley.

BENG 1413: DIGITAL ELECTRONICS Synopsis This subject comprises of several topic such as number systems and codes, logic gates and Boolean algebra, combinational logic circuits, MSI logic circuits and flip flops, integrated circuit logic families and Introduction to Finite State Machine (FSM). References [1] Thomas L. Floyd. Digital Fundamental. 10th edition,

Prentice Hall, 2008. [2] Ronald J. Tocci, N. Widmer, G. Moss. Digital Systems,

Principles and Applications. 11th edition, Prentice Hall, 2010.

[3] Roger L. Tokheim.Digital Electronics, Principles and Applications. Mc Graw-Hill, 2008.

BMCG 1523: ENGINEERING GRAPHICS AND CAD Synopsis The course will provide students with an understanding of the importance of engineering graphics as a communication tool among engineers. Student will be exposed to the engineering graphics fundamentals of manual sketching, geometric dimensioning and tolerancing, graphic projections, sectioning and engineering drawings. Students will develop visualization skills by constructing technical drawings using manual sketches and computer aided design (CAD) software. The course consists of both lecture and practical session where students will be guided in presenting and interpreting engineering drawings correctly. References [1] Rizal, M. A. et al., 2009, Modul Lukisan Berbantu

Komputer, Penerbit Universiti Teknikal Malaysia Melaka, Melaka.

[2] Dix, M. & Riley, P., 2014, Discovering AutoCAD 2014, Prentice Hall, New York.

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[3] Giesecke, F. E., Mitchell, A., Spencer, H. C., Hill, I. L., Dygdon, J. T. and Novak, J. E., 2011, Technical Drawing, 14th Ed., Prentice Hall, New York.

[4] Jensen, C., & Jay D. H., 2007, Engineering Drawing and Design, 7th Ed., Glencoe and McGraw Hill, New York.

[5] Frederick, E. G. & Mitchell, A., 2008, Technical Drawing and Engineering Drawing, 14th Ed., Prentice Hall.

BENG 2142: STATISTICS Synopsis Topics covered: Data description and Numerical Measures, Probability, Random Variables and Probability Distributions, Sampling Distributions, Estimation, Hypothesis Testing, Simple Linear Regression. References [1] Sara, Hanissah, Fauziah, Nortazi, Farah Shahnaz,

Introduction To Statistics & Probability A Study Guide, 2008

[2] Prem,S.Mann, Introductory Statistics Using Technology, 5thEdition, John Wiley, 2007

[3] Douglas C. Montgomery, George C.Runger, Applied Statistics and Probability for Engineers, 5th Edition, John Wiley, 2010

[4] Richard Johnson, John Freund, Irwin Miller,Miller And Freund’s Probability and Statistics for Engineers, 8th Edition, Pearson – Prentice Hall, 2010

[5] Jay L. Devore, Probability and Statistics for Engineering and the Sciences, 7th Edition, Thomson – Duxbury, 2008

BEKG 2433: ELECTRICAL SYSTEMS Synopsis This is an introductory subject for students on the fundamental knowledge of electrical power system. The students will be taught on the physics of electrical power system, which includes the theory and analysis of electromagnetism, followed by power concepts & equations (single and three phase), power factor & power factor corrections, single and three-phase system and per-unit calculation. There will also topics on characteristics for static and rotating electric machine principles, including AC, DC, synchronous, induction motor and transformer. Furthermore, students will be introduced to the concepts on the electric power system network (generation, transmission and distribution) and various power generation system and

energy sources. The students will also learn on basic characteristics and performance of electrical transmission line and distribution system. References [1] Glover, Sarma & Overbye, Power System Analysis and

Design, 5th Edition, Cengage Learning, 2012 [2] Hadi Saadat, Power System Analysis, 2nd Edition,

McGraw Hill, 2004 [3] Hughes, Electrical and Electronic Technology, 10th

Edition, UK, Pearson Edu. Ltd., 2008 BEKG 2452: NUMERICAL METHODS Synopsis Topics covered: Errors; Solution of Nonlinear Equations; Solution of Linear Systems; Interpolation and Curve Fitting; Eigenvalues and Eigenvectors; Numerical Differentiation; Numerical Integration; Solution of Ordinary Differential Equations; Solution of Partial Differential Equation; Introduction to SCILAB and its application in the numerical computations. References [1] Burden R. And Faires J.D. (2011). Numerical Analysis,

9th edition, USA : Brooks/Cole, Cengage Learning [2] Khoo C.F. (2011). Using SCILAB for Numerical

Methods, Module in Preparation [3] Chapra S.C. and Canale R.P (2010). Numerical

Methods for Engineers, 6th edition, New York: McGraw-Hill.

[4] Khoo C.F., Sharifah Sakinah, S.A, Zuraini, O. and Lok Y. Y. (2009). Numerical Methods, 3rd edition, Petaling Jaya: Pearson Prentice Hall

[5] Chapra S.C. (2008). Applied Numerical Methods with Matlab for Engineers and Scientists, 2nd Edition, New York: McGraw-Hill.

BENU 3005: INDUSTRIAL TRAINING Synopsis All degree students will be placed in appropriate local industries or government corporations for 10 weeks normally in the special semester of their third year of study. Student will be exposed to real life working environment relevant to their field of study. Reference [1] Industrial Training Guide Book, UTeM.

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BMFG 4623: ENGINEERING ECONOMY AND MANAGEMENT

Synopsis This course covers engineering economics and managing risk in an organization. Engineering economics discusses about the time value of money and interest relationships, which are useful to define certain project criteria that are utilised by engineers and project managers to select the best economic choice among several alternatives. Projects examined will include both product and service-producing investments. The effects of escalation, inflation, and taxes on the economic analysis of alternatives are also discussed. Management of risk incorporates the concepts of probability and statistics in the evaluation of alternatives. This allows management to determine the probability of success or failure of the project. References [1] Blank, L and Tarquin, A, Engineering Economy, 7th

Edition, McGraw Hill, 2012 [2] Sullivan, W.G, Wicks, E.M. Engineering Economy, 15th

Edition, Pearson, 2012 [3] Park C. S. Contemporary Engineering Economics, 5th

Edition Pearson, 2011 [4] Whitman D. and Terry R. Fundamentals of Engineering

Economics and Decision Analysis, Morgan & Claypool Publishers, 2012

BENU 4972: BACHELOR DEGREE PROJECT 1 Synopsis This course represents the first part of the final year project. Students should produce a project proposal and start work on their project before the end of the semester. Projects can be either the development of useful software or electronic hardware. Projects can also take the form of case studies or solving industrial problems encountered by the students during their industrial training. BENG 4322: ENGINEER AND SOCIETY Synopsis This course covers topics on: Role of engineer in nation building, evaluation of engineering, national development role of engineers in society, laws related to public safety, health & welfare, future engineers, professionalism and codes of ethics, definition of professionalism, understanding engineering as a profession, ethical theories, IEM and BEM code of ethics. Ethical problem solving techniques analysis

of issues in ethical problems, line drawing, flow charting, learn to handle conflicting problems. Occupational Safety and Health legislation and management. Rights and responsibilities of engineers. Quality from engineering perspective. Carrier guidance and project management. References [1] Charles B. Fleddermann, Engineering Ethics, 3rd Ed,

Prentice Hall, 2008. [2] John Canning, Workplace Safety for Occupational

Health and Safety (Safety at Work Series V4), 2007 [3] Safe Work in 21st Centuries (Educational and Training

for the Next Decade Occupational Health and Safety Personnel) National Academy Press, 2006

[4] Arazi Idrus, Shaharin A. Sulaiman, Mohd Faris Khamidi, Engineers in Society, McGraw Hill Education.

BENU 4131: ENGINEERING SEMINAR Synopsis The main purpose of this course is to instill the recognition of the need for and the ability to engage in life-long learning among students. Through presentation by invited speakers from the industry and academia, students will be exposed to topics such as professional engineering bodies and knowledge of in contemporary issues in related engineering fields. Presentation by successful alumni describing how their careers developed after obtaining their undergraduate degrees will also be included. BENU 4984: BACHELOR DEGREE PROJECT 2 Synopsis This is the second part of the final year project. Students are expected to continue the project done in Bachelor Degree Project Part I till completion. At the end of the semester students are required to submit the final year project report both orally and in writing for assessment.

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PROGRAMME CORE SUBJECTS (K) BENG 1132: ENGINEERING PRACTICE Synopsis This subject will be offered during the special semester at the end of second year. The topics covered are standard industrial practice, industrial safety and health regulation (OSHA), component soldering and soldering, printed circuit board design and fabrication, simulation tools, component circuit and troubleshooting. Students will also expose to the plan preventive maintenance, quality control and project management’s topics. Besides that, for the first 3 weeks of the course, students will undergo multi engineering courses offered by mechanical, manufacturing and electrical engineering faculty. References [1] Environmental, Safety and Health Engineering, Gayle

Woodside, WILEY, 1997 [2] Handbook of International Electrical Safety Practices,

Peri, WILEY, 2011 [3] EMC and the Printed Circuit Board: Design, Theory and

Layout Made Simple, Mark.I, WILEY, 2004 [4] Industrial Bioseparations: Principles and Practice,

Daniel Forciniti, WILEY, 2008

BENC 2413: DIGITAL SYSTEMS Synopsis This subject comprises of several topics such counters, shift registers, finite state machine, memory devices, programmable logic devices and basic computer architecture, basic microprocessors, buses. References [1] Thomas L. Floyd. Digital Fundamental. 10th edition,

Prentice Hall, 2009 [2] Ronald J. Tocci, N. Widmer, G. Moss. Digital Systems,

Principles and Applications. 11th edition, Prentice Hall, 2010.

[3] Jr. Charles H. Roth, Larry L. Kinney. Fundamentals of Logic Design. CL Engineering, 6th edition, 2009

[4] David Harris, Sarah Harris. Digital Design and Computer Architecture. Morgan Kaufmann, 1st edition, 2007.

BENT 2713: CIRCUIT THEORY I Synopsis This subject will introduce Overview of Electrical Engineering, SI Units, Charge and Current, Voltage, Power and Energy and Circuit Elements, Ohm’s Law, Nodes, Branches and Loops, Kirchhoff’s Laws, Series Resistors and voltage Division, Parallel Resistors and Current Division and Wye-Delta Transformation, Applications, Nodal Analysis, Nodal Analysis with Voltage Sources, Mesh Analysis, Mesh Analysis with Current Sources, Applications, Linearity Property, Superposition, Source Transformation, Thevenin’s Theorem, Norton’s Theorem and Maximum Power Transfer, Applications, Introduction, Sinusoids, Phasor, Phasor Relationship for Circuit Elements, Impedance & Admittance, Impedance Combinations, Applications, Introduction, Impedance parameter, Admittance Parameter and Hybrid Parameter, Transmission Parameters, Interconnection of Networks and Applications. References [1] C.K Alexander, M.N Sadiku, Fundamental of Electric

Circuits, 5th Edition, Mc Graw Hill, 2012. [2] James W. Nilsson, Susan A, Rieldel, Electric Circuits,

9th Edition, Prentice Hall, 2010. [3] A. R. Hambley, Electrical Engineering - Principles and

Applications, 5th Edition, Prentice Hall, 2010. [4] W.H Hayt, J.E Kemmerly, S. M Durbin, Engineering

Circuit Analysis, 7th Edition, Mc Graw Hill, 2007. BENE 2123: FUNDAMENTAL OF ELECTRONICS Synopsis This course will discuss on: Introduction to Multisim; Bohr Atomic Model: valency, periodic table of elements, trivalent, tetravalent and pentavalent elements, movement electrons in solid: conductor, insulator and semiconductor, band theory: energy bands, conduction bands and forbidden bands. Doping, p and n materials, pn junction. Diode equation, dynamics resistance, diode equivalent circuits; Silicon Semiconductor Diodes: characteristics and measurement of forward & reverse biased, composite characteristics and load line analysis, clipping, clamping & simple rectifier (half & full) circuits, zener diodes characteristics, and simple regulator; Bipolar Junction Transistor (BJT): construction and operation of BJT, BJT characteristics and measurement technique, limits of operation, βdc & αdc, DC biasing - DC load lines; Field Effect Transistor (FET): construction & operation of FET, FET characteristics & diagram, Shockley’s equation, DC biasing – DC load line; Metal oxide

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semiconductor field-effect transistor (MOSFET): construction & operation of MOSFET dc characteristic. References [1] Boylestad R., Nashelsky L., Electronic Devices and

circuit Theory, 11th Edition, Prentice Hall Inc., 2012. [2] Floyd, Electronic Devices, 9th Edition, Prentice Hall,

2012. [3] A. P. Godse and U. A. Bakshi, “Electronic Devices and

Circuits”, 2nd ed., 2009 [4] Ali Aminian, Marian Kazimierczuk, “Electronic Devices

A Design Approach”, Pearson International Edition, 2004

BENG 2211: ELECTRONIC ENGINEERING LAB 1 Synopsis This course covers topics in BENM 2133 Digital System, BENE 2153 Analog Electronics and BENT 2123 Signals and Systems with the following items: Asynchronous and Synchronous Counter, Finite State Machine, Shift Register, Common-Emitter BJT Amplifiers, Common-Source JFET Amplifiers, Op-Amp Applications, Transients In Inductors, Charging And Discharging Capacitors, Transients In R-L-C Circuits, Band-Pass Filter References [1] Boylestad R., Nashelsky L., “Electronic Devices and

circuit Theory”, 11th Edition, Prentice Hall Inc., 2012 [2] Floyd, “Electronic Devices”, Ninth Edition, Prentice Hall,

2010 [3] Kalsi, H.S., ‘Electronic Instrumentation’, 3rd edition,

Tata McGraw-Hill, 2010 BENC 2423: MICROPROCESSOR TECHNOLOGY Synopsis Topics covered in this subject includes the introduction to microprocessor-based system, the internal and software model of the microprocessor, the assembly language programming design and development, the microprocessor device specification and its related configuration, and also the design configuration of the memory and input/output system interfacing. References [1] M. M. Ahmad Zabidi, Sistem Terbenam Dengan

Mikropemproses 68000, Penerbit UTM Press, 2011

[2] M. Rafiquzzaman, Microprocessor Theory and Applications with 68000/68020 and Pentium, 1st Edition, John Wiley & Sons, 2008

[3] P. Godse & D. A Goose, Microprocessor, Microcontroller and Applications, 3rd Edition, Technical Publications, 2008.

[4] J. R. Gibson, ARM Assembly Language – an Introduction, 2nd Edition, ARM Limited, 2007

BENT 2723: CIRCUIT THEORY II Synopsis This subject will discuss about capacitors and inductors, series and parallel circuits of capacitors and inductors; first and second-order circuits, step response of the circuits; steady-state analysis; AC power analysis, average power, RMS values, power factor; frequency response and Bode Plot, series and parallel resonance and filters. References [1] C.K Alexander, M.N Sadiku, Fundamental of Electric

Circuits, 5th Edition, Mc Graw Hill, 2012. [2] James W. Nilsson, Susan A, Rieldel, Electric Circuits,

9th Edition, Prentice Hall, 2011. [3] Thomas L.Floyd, Electric Circuits Fundamental, 8th

Edition, 2010. [4] J.David Irwin and R. Mark Nelms, Basic Engineering

Circuit Analysis, 9th edition, John Wiley, 2008 BENE 2133: ANALOGUE ELECTRONICS Synopsis Topics covered: BJT Transistor modeling, CE, CC and CB configuration, BJT small amplifier analysis, FET small-signal analysis, MOSFET, Frequency response, Bode plot, Special amplifiers: cascade, cascode, Darlington, Multistage Amplifiers, Differential amplifier circuit, Feedback Amplifiers, Operational amplifiers: inverting, non-inverting, summing and buffer amplifiers References [1] Boylestad R., Nashelsky L., Electronic Devices and

circuit Theory, 11th Edition, Prentice Hall Inc., 2013. [2] Ali Aminian, Maren Kazimierchuk, “Electronic Devices -

A Design Approach”, Prentice Hall Inc., 2004. [3] Donald A. Neamen, “Microelectronics – Circuit Analysis

and Design”, Forth edition, McGraw Hill., 2009.

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[4] Theodore Marc T. Thompson, “Intuitive Analog Circuit Design - A Problem-Solving Approach Using Design Case Studies”, Elsevier, 2006

[5] Giovanni Saggio, “Principles of Analog Electronics”. CRC Press, 2014

BENG 2431: ELECTRONIC ENGINEERING LAB 2 Synopsis This course covers topics in Digital Systems and Microprocessor Technology with the following items: Basic and Combinational Logic Gates, Asynchronous and Synchronous Counter, Finite State Machine, Microprocessor Training Board and Applications of ARM Processor. References [1] James L. Antonakos, The 68000 Microprocessor

Hardware and Software Principles and Applications, Fourth Edition, Prentice Hall Inc.

[2] Alan Clements, Microprocessor Systems Design 68000 Hardware, Software, and Interfacing, Third Edition, PWS Publishing Company.

[3] Thomas L. Floyd. Digital Fundamental. 10th edition, Prentice Hall, 2009

[4] Ronald J. Tocci, N. Widmer, G. Moss. Digital Systems, Principles and Applications. 11th edition, Prentice Hall, 2010.

BENC 3443: MULTIMEDIA TECHNOLOGY AND APPLICATION Synopsis This subject prepares the students with basic concept of multimedia, technology and the importance of multimedia application. This subject also introduces the students to techniques and tools related with the creation of multimedia application and explore the current issues related to multimedia technology. It covers the topics introduction to multimedia technology, graphic and image data representations, audio technology, video technology and multimedia systems. References [1] K. S. Thyagarajan,” Still Image and Video Compression

with MATLAB”, Wiley, 2011 [2] Jeniffer Burg, ”The Science of Digital Media”, Pearson,

2009 [3] Yue Ling Wong, ”Digital media Primer”, Pearson, 2009

BENE 3143: ELECTRONIC SYSTEM DESIGN AND ANALYSIS Synopsis This course will cover regulated power supply, ripple voltage, filters and voltage regulation, regulators, introduction to switching regulator, discrete, integrated circuit regulator, amplifier class A, AB, B and C, SCR, UJT, PUT Circuits, RC phase shift oscillator, Wien bridge oscillator, tuned oscillator, crystal oscillator, 555 timers, active filters, filter design criteria, higher order Butterworth and switched capacitor filters. References [1] Robert L. Boylested, Loius Nashelsky, “Electronic

Devices and Circuit Theory”, 11th Edition, Prenctice Hall, 2014 (Textbook).

[2] Ali Aminian, Maren Kazimierchuk, “Electronic Devices - A Design Approach”, Prentice Hall, 2004

[3] Floyd, “Electronic Devices”, 9th ed, Prentice Hall, 2014. [4] N. Kularatna, “Electronic Circuit Design: From Concept

to Implementation”, 2009. BENT 3743: ELECTROMAGNETIC FIELDS AND WAVES Synopsis This course will discuss on: Vector analysis: Vector algebra, coordinate system and transformation, vector calculus; Electrostatics: Electrostatic fields, Gauss Law, Poisson’s equation, electric fields in material space, electrostatic boundary; Magnetostatics: Magnetostatic fields, Stokes Theorem, Biot-Savart Law, Gauss Law, magnetic forces, material and devices; Waves: Maxwell’s equations, Faraday’s Law, time-varying electromagnetic field, electromagnetic wave propagation. References [1] M.N.O. Sadiku, Elements of Electromagnetics, 5th.

Edition, Oxford University Press, 2010. [2] F.T. Ulaby, Electromagnetics for Engineers, 2009,

Pearson International Edition, Prentice-Hall. [3] G.S.N. Raju, Electromagnetic Field Theory and

Transmission Lines, 3nd Impression, Pearson Education, 2009.

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BENG 3211: ELECTRONIC ENGINEERING LAB 3 Synopsis This course covers topics in BENE 2133 Analog Electronics and BENE 3143 Electronic System Design and Analysis. Among the topics that will be covered in this course are; regulated power supply, filters design, and amplifier design. References: [1] Bolystad, R., Nashelsky L., "Electronic Devices and

Circuit Theory", Eleventh edition, Prentice Hall Inc., 2013

[2] Ali Aminian, Maren Kazimierchuk, "Electronic Devices - A Design Approach", Prentice Hall Inc., 2004.

[3] Donald A. Neamen, "Microelectronics – Circuit Analysis and Design", Forth edition, McGraw Hill., 2009.

[4] Marc T. Thompson, "Intuitive Analog Circuit Design – A Problem-Solving Approach Using Design Case Studies", Elsevier, 2006

[5] Giovanni Saggio, "Principles of Analog Electronics". CRC Press, 2014.

[6] N. Kularatna, "Electronic Circuit Design: From Concept to Implementation", 2009.

BENT 3733: SIGNALS AND SYSTEMS Synopsis The course will cover various topics such as Continuous-Time signals and systems, Fourier series, Fourier transform, Laplace transform, Discrete-time signals and systems. References [1] Oppenheim, Alan V., Willsky, Alan S., and Syed Hamid

Nawab, Signals and Systems, Vol. 2, Prentice Hall, 2007.

[2] Sadiku, Alexander and Charles, K. Alaexander, Fundamentals of Electric Circuits, McGraw Hill, 2009.

[3] Kamen Edward, W., and S. Heck Bonnie, Fundamental of Signals and Systems using the Web and MATLAB, 3rd Edition, Pearson, 2006.

BENT 3753: COMMUNICATION PRINCIPLES Synopsis This course will discuss about Introduction to Telecommunication: Model, Transmission Modes, Need for Modulation and Demodulation, Electromagnetic Frequency Spectrum, Linear Modulation: Amplitude Modulation (AM) Principles, AM Modulation and Transmission, AM Reception and Demodulation, Single-Sidebands

Communications Systems: Principles, SSB Transmission and Reception, Angle Modulation: Frequency Modulation (FM) and Phase Modulation (PM), FM/PM Modulation and Transmission, FM/PM Reception and Demodulation, FM Stereo, Noise: Source and Representation, Noise Parameters, Noise Analysis in Linear and Angle Modulation, Introduction to Digital Communication: Information Capacity, Hartley and Shannon Limit, Digital Modulation: Amplitude, Frequency and Phase Shift Keying (ASK, FSK and PSK), Digital Transmission: Pulse Modulation, Pulse Code Modulation (PCM), Sampling, Quantization and Encoding. References [1] Wayne Tomasi, Electronics Communications Systems

Fundamentals Through Advanced, Prentice Hall, Sixth Edition, 2007

[2] John G. Proakis, Essentials of Communication Systems Engineering, Prentice Hall, 2005

[3] SimonHaykin and Michael Moher, Communication Systems, 5th Edition, John Wiley & Sons, 2010

[4] Carlson, A. Bruce, Communication systems: An Introduction to Signals and Noise in Electrical Communication, 5th Edition, McGraw-Hill Higher Education, 2010.

BENE 3223: CONTROL PRINCIPLES AND SYSTEMS Synopsis Introduction to control system, frequency domain modeling, Laplace transform, transfer function, electric network transfer function, translational mechanical system, rotational mechanical system transfer function, time domain modeling, general state space representation, transfer function and state space conversion, time response, poles, zeros and system response, First and Second order systems, under-damped system, reduction of multiple subsystems, block diagrams, feedback systems, signal flow graphs, Mason’s rule, Routh-Hurwitz criterion and Gain Adjustment compensator design. References [1] Norman S. Nise, Control System Engineering, Addison

Wesley Publishing, 6th edition2010 [2] Katsuhiko Ogata, “Modern Control Engineering 5th

edition”, Pearson, 2010. [3] Richard C. Dorf and Robert H. Bishop, “Modern

Control Systems 11th edition”, Prentice Hall, 2008

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[4] B. friedland, “ control System Design: An Introduction to state-Space Methods, Dover Publications, 2012.

BENU 3863: INTEGRATED DESIGN PROJECT Synopsis This subject covers a complete design cycle, from start to finish, that encompasses problem identification and definition, system design settings, specifications and implementation, system testing and verification of project designed, proper documentation and deployment. Students work in group of four or five and at the end of the course the group is expect to complete a system design that provides solutions to an engineering problem identified at the beginning and worked upon during the course of studies. Students work under the supervision of assigned supervisors and are assessed on a regular basis and at specific milestones as indicated. The project must be endorsed by the supervisors taking into account the complexity of the problem and solutions. The students are expected to achieve the learning outcomes by providing solutions to an engineering problem, taking into account good engineering practice such as working as a team and meeting specified needs with appropriate consideration for public health and safety, cultural, societal, and environmental considerations. At the end of the course, each group is expected to submit a technical report, provide an oral presentation as well as conduct a system demonstration on the project developed. References [1] R. G. Kaduskar, V. B. Baru, Electronic Product Design,

Second Edition, Wiley India, 2013. [2] John X. Wang, Green Electronics Manufacturing:

Creating Environmental Sensible Products, CRC Press, 2012.

[3] Bogdan M. Wilamowski and J. David Irwin, The industrial Electronics Handbook, Second Edition, CRC Press, 2011.

[4] Charles Lessard and Joseph Lessard, Project Management for Engineering Design, Morgon & Claypool Pub, 2007.

[5] Charles B. Fleddermann, Engineering Ethics, 4th Edition, Prentice Hall, 2011.

BENG 3761: ELECTRONIC ENGINEERING LAB 4 Synopsis The course covers topics in Signals & Systems and Principle Communication with the following experiment:

Fourier Series, Fourier Transform, Laplace Transform & Application, AM Modulation, FM Modulation, SSB Modulation and demodulation. References [1] Simon Haykin and Michael Moher, Communication

Systems, 5th Edition, John Wiley & Sons, 2010. [2] Carlson, A. Bruce, Communication systems: An

Introduction to Signals and Noise in Electrical Communication, 5th Edition, McGraw-Hill Higher Education, 2010.

[3] C. K Alexander, M. N. O. Sadiku, Fundamental of Electric Circuit, 5th Edition, McGraw Hill, 2012.

[4] C. L. Phillips, J. M. Parr, E. A. Riskin, Signals, Systems and Transforms, 4th Edition, Pearson Prentice Hall, 2008.

BENG 4733: DIGITAL SIGNAL PROCESSING Synopsis This course consists of topics: Introduction to DSP, discrete-time signals and systems, spectrum of representation of discrete-time signals, discrete Fourier transform, difference equations and discrete-time systems, z-transform and its applications, analysis and design of digital filters and random signal processing. References [1] SanjitK.Mitra, Digital Signal Processing: A Computer

Based Approach, 4th Edition, Mc Graw Hill, 2011 [2] Oppenheim, Schafer, Discrete-time Signal Processing,

3rd Edition, Prentice-Hall, 2010. [3] Proakis, Manolikas, Digital Signal Processing:

Principles, Algorithms, and Applications, 4th Edition, Prentice-Hall, 2007.

[4] E. C. Ifeachor, B. W. Jervis, Digital Signal Processing: A Practical Approach, 2nd Edition, Prentice Hall, 2002.

[5] S. Poornachandra, B. Sasikala, Digital Signal Processing, 3th Edition, McGraw-Hill, 2010

BENC 4453: COMPUTER ARCHITECTURE Synopsis This course aims primarily to give the students a general understanding of how computer system work, both internally (ALU, control unit, registers, etc.) and externally (I/O interfaces, networking, etc.). Such understanding will enable the graduates to make intelligent decisions when confronted with computer-related problems at their workplace. The

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knowledge and skills gained in this course will also enable the graduates to further their studies in the field of computer architecture, organization, and design. References [1] Stallings, William, Computer Organization and

Architecture: Designing for Performance, 9th Edition, Pearson Education, 2012.

[2] Hammacher Carl, Vranesic Zvonko, Zaky Safwat, Naraig Manjikian, Computer Organization and Embedded Systems, 6th Edition, 2011.

[3] Shuangbao Paul Wang, Robert S. Ledley, Computer Architecture and Security: Designing Secure Computer Systems, 1st Edition, John Wiley & Sons, 2012.

[4] Irv Englander, The Architecture of Computer Hardware and System Software: An Information Technology Approach, 4th Edition, 2010.

ELECTIVE SUBJECTS (E) BENC 4463: MICROCONTROLLER TECHNOLOGY Synopsis Topics covered in this subject includes the introduction to microcontroller-based system, the internal architecture of the microcontroller, the programming design and development software, the design configuration and peripheral interfacing of the application system, the development of specific microcontroller application, and the integration of software and hardware subsystems. References [1] M. Rafiquzzaman, Microcontroller Theory and

Applications with the PIC18F, John Wiley & Sons, 2011 [2] A.P. Godse & D. A. Godse, Microprocessor and

Microcontroller, 1st Edition, Technical Publication Pune, 2009.

[3] F. E. Valdes-Perez & R. Pallas-Areny, Microcontrollers: Fundamentals and Applications with PIC, CRC Press, 2009.

[4] M. A Mazidi, R. D. McKinlay & D. Causey, PIC Microcontroller and Embedded Systems (Using Assembly and C for PIC18), Pearson Prentice Hall, 2008.

BENE 4233: INDUSTRIAL CONTROL Synopsis This course will discuss about Introduction to Industrial Control: the classification of industrial control systems, the components of control system and its characteristics, Discrete Control Elements and Ladder Diagram: control circuits, line or ladder diagram, power relay, and logic gates and ladder diagram, Programmable Logic Controller (PLC): introduction to PLC, background and development of PLC, PLC hardware, ladder diagram programming for OMRON PLCs: ladder instructions, logic block instructions, branching instructions line, controlling bit status, and other instructions, Discrete Sensors: introduction to sensors in industries, contact arrangement, limit switches, actuators, no-touch sensors, inductive proximity sensors, capacitive proximity sensors, and photoelectric sensors, GRAFCET: introduction to GRAFCET, the needs of GRAFCET, fundamental symbols in GRAFCET, combinational symbols in GRAFCET, control symbols in GRAFCET, evolutionary of GRAFCET (simultaneous sequence), rules of GRAFCET, and relationship between GRAFCET and PLC ladder diagram, Proportional-Integral-Derivative (PID) Controller: introduction to PID controller, the three-term controller, the characteristics of P, I, and D controllers, P controller, PI controller, PD controller, and PID controller, Data Acquisition (DAQ) and Control: definition of DAQ and control, fundamentals of DAQ, DAQ and control systems configuration, and DAQ for sensors and control systems in computer-integrated manufacturing (CIM) environments. References [1] Industrial Control Teaching Module, FKEKK UTeM,

2006. [2] Andrew Parr, ‘Industrial Control Handbook’, 3rd Edition,

Industrial Press Inc., 1998 [3] Soloman, ‘Sensors and Control Systems in

Manufacturing’, 2nd Edition, McGraw-Hill, 2010 [4] Mikell P. Groover, ‘Automation, Production Systems,

and Computer-Integrated Manufacturing’, 3rd Edition, Pearson Education Inc., 2013

[5] James A. Rehg and Glenn J. Sartori, ‘Industrial Electronics’, International Edition, PEARSON Education International, 2006.

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BENT 4773: TELECOMMUNICATION SYSTEM ENGINEERING Synopsis This module runs for the topics such as Radio Spectrum: Introduction to Frequency Spectrum, Allocations and International Standard. Broadcasting: TV Broadcasting and Digital Broadcasting System, (DAB and DVB), Mobile Broadcasting System, Satellite TV. PSTN/ISDN: Circuit and Packet Switching System and Technology, Frame Relay, ATM, DSL, Mobile Switching Centre, WLL, Network Architecture, Telephony Telecommunication Traffic. Satellite System: Satellites (LEO, MEO, GEO), Ground Station, Propagation Delay, Azimuth, VSAT, and Direct Broadcast. Radar System: Introduction, Principles and Applications, Types of Radar, Transmitter and Receiver, Scan and Detection, Distractor. Optical Communication: History, Advantages, Fibre Optic Types and Classification, Optical Communication System and Transmission Characteristic, Light Propagation, Losses, Light Sources, Detector, Link Budget, Applications. References [1] Simon Haykin, Michael Moher, Communication

Systems, 5th Edition, Wiley, 2009 [2] Andreas F. Molisch, Wireless Communications, 2nd

Edition, Wiley IEEE Press, 2012. [3] G. Maral, M. Bousquet, Satellite Communication

Systems, 5th Edition, John Wiley & Sons, 2010. [4] Hamesh Miekle, Modern Radar System, 2nd Edition,

Artech House Inc., 2008. [5] John M. Senior, M. Yousif Jamro, Optical Fiber

Communications: Principles and Practise, 3rd Edition, Prentice Hall, 2008

[6] Sanjay Sharma, Communication Engineering, S.K. Kataria & Sons, New Delhi, 2012

BENT 4783: WIRELESS COMMUNICATION SYSTEMS Synopsis Introduction to Wireless Communication System: Introduction – Definition, Trend and Evolution, Types Of Mobile Radio Communications, Cordless Telephone Systems, Paging Systems, Cellular Telephone Systems. Cellular Concept: Introduction, Frequency Reuse, Interference – Co-channel and Adjacent Interference, System Capacity, Channel Planning, Trunking and Grade of Service, Handoff Mechanism, Improve Coverage and Capacity - Cell Splitting, Sectoring, and Repeaters. Mobile

Radio Propagation Models: Introduction, Free Space Propagation Model, Ground Reflection Model; Basic Propagations Mechanism – Reflection, Diffraction- Fresnel Zone, Scattering, Multipath Propagation, Link Budget; Outdoor Propagation Models – Okumura Model; Small Scale Fading – Slow and Fast Fading, Doppler Frequency Shift, Time Delay Spread, Propagation Path Loss. Multiple Access Techniques: Introduction, Frequency Division Multiple Access (FDMA), Time Division Multiple Access (TDMA), Code Division Multiple Access (CDMA) and Orthogonal Frequency-Division Multiple Access (OFDMA). Wireless Systems and Standards: Introduction– evolution of generation standards and applications, Global System for Mobile (GSM) - Services, Features, Radio Subsystem, Channel Type, System Architecture of generation standards and 3GPP. References [1] Theodore S. Rappaport, Wireless Communications:

Principles and Practice, 2nd Edition, Prentice Hall, 2008.

[2] Andreas F. Molisch, Wireless Communications, 2nd Edition, Wiley IEEE Press, 2012

[3] Ke-Lin Du, M.N.S. Swamy, Wireless Communication Systems, Cambridge University Press, 2010.

BENC 4473: DIGITAL INTEGRATED CIRCUIT DESIGN Synopsis This course covers several aspects of digital integrated circuit design. Starting with MOSFET equations, we will delve into several areas of digital circuit design, including recent changes in circuit design approaches. We will cover different design styles, memory design, as well as board level design concepts. References [1] Sung-Mo Kang, Yusuf Leblebici, CMOS Digital

Integrated Circuits, McGraw Hill, 2005 [2] B. L. Anderson, R. L. Anderson, Fundamentals of

Semiconductor Devices, McGraw Hill, 2005 [3] J. M. Rabaey, Digital Integrated Circuits: A Design

Perspective, Prentice Hall, 2003 [4] Wayne Wolf, Modern VLSI Design: IP-Based Design,

Prentice Hall, 2009 [5] Behzad Razavi, Design of Analog CMOS Integrated

Circuits, Mc Graw Hill, 2001. BENE 4333: ARTIFICIAL INTELLIGENCE

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Synopsis Introduction to artifical intelligence system, Introduction to Fuzzy Logic, Fuzzy set and Fuzzy system, Fuzzy Logic control system, and application, Introduction to Neural Network, McCulloch-Pitts Neuron, Hebb Neural Network, Perceptrons, gradient decreasing studying algorithm, non linear optimization, adding back error algoritthm, basic radius function, application and neural network simulation.

References [1] N. Siddique, H. Adeli, Computational Intelligence:

Synergies of Fuzzy Logic, Neural Networks Intelligent Systems and Applications, John Wiley & Sons, 2013.

[2] T. J. Ross, Fuzzy Logic with Engineering Applications, 3rd Edition, John Wiley & Sons, 2010.

[3] S. Russell, P. Norvig, Artificial Intelligence: A Modern Approach, 3rd Edition, Pearson, 2010.

[4] M. Negnevitsky , Artificial Intelligence: A Guide to Intelligent Systems, 3rd Edition, Addison-Wesley, 2011

[5] C. Grosan, A. Abraham, Intelligent Systems: A Modern Approach, Springer, 2011

BENT 4793: MICROWAVE ENGINEERING Synopsis Topics covered: Introduction to RF and Microwave Engineering: RF and Microwave Frequencies, RF and Microwave Applications. Transmission Lines: Review of Transmission Line Theory, General solution for TEM, Stripline, Microstrip, Waveguide, Wave Velocities and Dispersion, Summary of Transmission Lines, Smith Chart. Microwave Network Analysis: Impedance and Equivalent Voltages and Current, Impedance and Admittance Matrices, The Scattering Matrix, The Transmission (ABCD) Matrix, Signal Flow Graphs. Impedance Matching and Tuning: Matching with Lumped Elements (L-C Networks), Single-stub Tuning,Double-stub Tuning, The Quarter-wave Transformer. Power Dividers and Couplers: Basic Properties of Dividers and Couplers, The T-Junction Power Divider,The Wilkinson Power Divider, Waveguide Directional Couplers, The Quadrature (900) Hybrid, Coupled Line Directional Couplers, The Lange Coupler, The 1800Hybrid, Other Couplers. Microwave Filter: Periodic Structures, Filter Design by the Insertion Loss Method, Filter Transformation, Filter Implementation, Stepped Impedance Low-Pass Filter, Coupled Line Filters, Filter Using Coupled Resonators. Microwave Amplifier: Two-Port Power Gain, Stability, Single-Stage Transistor

Amplifier-Design, Broadband Transistor Amplifier Design, Power Amplifier. References [1] Pozar, “Microwave Engineering”. 3RD edition, John

Wiley & Sons, 2010 [2] J. S. Love, “RF Front‐End: World Class Design”

Newnes Elsevier, 2009. [3] R. Ludwig & P. Bretchko, “RF Circuit Design: Theory

and Applications”, Pearson Prentice Hall, 2010. BENT 4813: DATA COMMUNICATION AND NETWORKING Synopsis Topics covered: Fundamentals of Data Communications: Communication model, Data communication networks. Protocol Architecture: Peer-to-peer layered protocol architecture (OSI, TCP/IP). Network Routing: Packet switching, Routing strategies, Routing algorithm. Data Network: Local Area Network (LAN), Network topologies, transmission media, LAN protocol architecture, Networking devices, Ethernet. Network Protocols: Internet Protocols (IPv4, IPv6, Internetwork Operation, Multicasting), Transport Protocols (TCP& UDP). References [1] W. Stallings, Data & Computer Communication 9th

Edition, Pearson, 2011. [2] J. Koruse and K. Ross, Computer Networking: A Top

Down Approach Featuring the Internet, Addison-Wesley, 5th Edition 2010.

BENC 4483: COMPUTER VISION AND PATTERN RECOGNITION Synopsis Topics covered: Overview of Computer Vision and Pattern Recognition, Image and Image Representation, Image Analysis & Enhancement, Feature Detection and Segmentation, Image Restoration, Feature Analysis and Pattern Recognition, Feature Selection and Dimensionality Reduction. References [1] R. Szeliski, Computer Vision: Algorithms and

Applications, Springer, 2010.

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[2] S. E. Umbaugh, Digital Image Processing and Analysis: Human and Computer Vision Applications with CVIPtools, CRC Press, 2011.

[3] R. C. Gonzalez and R. E. Woods, Digital Image Processing, 3rd Edition, Prentice Hall,

[4] S. Theodoridis, Pattern Recognition, 4th Edition, Academic Press, 2009.

BENE 4243: INDUSTRIAL AUTOMATION Synopsis Topics covered are: Introduction to Industrial Automation & Control, Common Process variables, measurements and control, Mechanics and control of mechanical manipulator, coordinate mapping and transformation, forward kinematics, inverse kinematics. References [1] Mikell P. Groover. Automation, Production Systems,

and Computer-Integrated Manufacturing, 3rd Edition., Prentice Hall, 2008

[2] Terry Bartelt, Industrial Automated Systems: Instrumentation and Motion Control, Cengage Learning, 2010

[3] Jon Stenerson, Programmable Logic Controllers with Control Logix, Cengage Learning, 2009

[4] Frank D. Petruzella, Programmable Logic Controllers, McGraw-Hill Education, 2010

[5] K.L.S. Sharma, Overview of Industrial Process Automation, Elseviers, 2011

BENT 4823: DIGITAL COMMUNICATION SYSTEM Synopsis This module runs for topics such as Review of Baseband Signalling: PCM: Sampling, Quantization, Encoding, Pulse Shaping, Delta Modulation. Bandpass Signalling: Binary Modulated Signalling: Binary PSK (BPSK), Differential PSK (DPSK), FSK, Multilevel Modulated Signalling: Quadrature Amplitude Modulation (QAM), Quadrature PSK (QPSK), M-ary PSK (MPSK), PSD and Spectral Efficiencies. Baseband and Bandpass Detection: Detection of Binary Signals in Gaussian Noise: Maximum-Likelihood Receiver, Matched Filter, Detection of Bandpass Signal in Gaussian Noise: Coherent Detection of PSK, MPSK and FSK, Error Performance for Binary and M-ary Systems: Bit Error Rate, Symbol Error. Equalization: Maximum-Likelihood Sequence Estimation, Linear Equalization, Decision Feedback Equalization, Adaptive Linear and Decision Feedback

Equalizations. Synchronization: Introduction, Carrier Phase Estimation: Maximum-Likelihood, Phase-Locked Loop, Symbol Timing Estimation: Maximum-Likelihood and Non-Decision-Directed Estimation. Multiplexing and Multiple Access: FDMA, TDMA, Performance Comparison, CDMA and SDMA, Multiple Access System and Architecture. Spread Spectrum: Overview, Pseudonoise Sequences, Direct-Sequence Spread Spectrum Systems, Frequency Hopping Systems, Synchronization, and Jamming Considerations. References [1] Sklar B., Digital Communications: Fundamentals and

Applications, 2nd Edition, Prentice Hall, 2011 [2] Proakis J.G., Digital Communications, 5th Edition,

McGraw Hill, 2008. [3] Couch L.W., Digital and Analog Communication

Systems, 8th Edition, Prentice Hall, 2013. [4] Proakis, Manolikas, Digital Signal Processing :

Principles, Algorithms, and Applications, 4th Edition, Prentice-Hall, 2007.

[5] E. C. Ifeachor, B. W. Jervis, Digital Signal Processing: A Practical Approach, 2nd Edition, Prentice Hall, 2002.

BENT 4833: ANTENNA AND WAVE PROPAGATION Synopsis Topics covered: Introduction and Fundamentals of Antenna; Antenna principle: basic antenna operation, necessary condition for radiation, Basic antenna parameters: radiation pattern, radiation power density, radiation intensity, directivity and gain, antenna reciprocity, antenna efficiency, radiation efficiency, half-power beamwidth, beam efficiency, bandwidth, polarization, input impedance, the Friss formula. Antenna Solution using Maxwell Equation: Maxwell Equation, Hertzian antenna, radiation, near-field and far-fields region, radiation from wires, Broadband Antenna: yagi-uda antenna, heliks antenna, Array Antenna: array antenna application, array factor, radiation pattern for array antenna, Microwave Antenna: horn antenna, parabolic antenna, micro-strip antenna, Matching and feeding networks: quarter-wave transformer, series section transformer, feed point location, delta- and T-match, baluns. Introduction to antenna measurement: Near-Field/ Far Field Methods, Basic Antenna Parameters Measurements: Radiation Pattern: Instrumentation, Amplitude Pattern, Gain Measurements, Directivity Measurements, Polarization Measurement:Linear and Circular Polarization, Co and Cross-polar Measurements, Introduction to Radio wave Propagation:

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Definition of Path Loss, Rays and wave-front, Characteristic Impedance of Free Space, Critical Frequency and Critical Angle, Virtual Height, Maximum usable Frequency, Skip Distance and Skip Zone, Free Space Path Loss, Fading And Fade Margin, Friis transmission formula, Concept of Ground, Sky and Space wave, Mobile Radio Propagation: Reflections, Ground Reflection Model, Diffraction, Fresnel Zone, Scattering, Link Budget, Fading, Multipath Propagation. References [1] C.A. Balanis:”Antenna Theory, Analysis & Design”,

John Wiley 2008 [2] V. J. Fusco, “Foundation of Antenna Theory &

Techniques”, Pearson Prentice Hall, 2009 [3] S.R. Saunders, A.A Zavala, “Antennas and Propagation

for Wireless Communication Systems” John Wiley, 2007.

[4] Stutzman and Thiele, Antenna Theory and Design, John Wiley, 1998

[5] T. H. Rappaport, “Wireless Communications: Principle and Practice” Prentice Hall, 2007

[6] T. A. Milligan, “Modern Antenna Design” John Wiley, 2nd edition, 2010

BENC 4493: REAL TIME SYSTEM Synopsis Topics covered: Introduction to Real-Time Systems, A Reference Model of Real-Time Systems, Approaches to Real-Time Scheduling, Clock-Driven Scheduling, Priority-Driven Scheduling for Periodic, Aperiodic and Sporadic Tasks, Resources and Resource Access Control, Real-Time Communication and Real-Time Operating System. References [1] Jane W.S. Liu, “Real-Time Systems”, Prentice Hall,

2000 [2] Graham Leedham and Kiam-Tian Seow, “Embedded

Real-Time Systems”, Prentice Hall, 2004 [3] Tanenbaum and Woodhull, “Operating Systems:

Design and Implementation”, Prentice Hall, 1997 BENE 4343: POWER ELECTRONICS AND DRIVES Synopsis

Overview of power electronics fundamentals: General introduction and concepts; Applications and prospects; power switches; switching and related issues (drivers, waveform generators, losses etc); modeling and simulation of AC to DC conversion, DC to DC Conversion, DC to AC Conversion. The introduction to drives is also covered where the speed control of DC motor and induction motor will be discussed in detail. References [1] Mohamed A. El-Sharkawi, Fundamentals of Electric

Drives, Brooks/Cole, 2000 [2] Michael E. Brumbach, Electronic Variable Speed

Drives, Delmar Publishers, 2nd Edition. [3] Theodore Wildi, Electrical Machines, Drives and

Power Systems, Prentice Hall, 6th Edition, 2006 [4] Norman S. Nise, Control System Engineering, Wiley,

6th Edition, 2010 [5] Gopal K. Dubey, Fundamentals of Electrical Drives, 2nd

Edition, 2002 BENT 4843: OPTOELECTRONICS Synopsis This module runs for the topics such as Review of Light Properties: Reflection and Refraction, Plane Waves, Polarisation, Concept of Coherence, Principle of Superposition. Light Propagation in Optical Fibre: Fibre Types, Acceptance Angle, Refractive Index, Numerical Aperture, Skew Rays, Total Internal Reflection, Phase and Group Velocity, Snell’s Law, TE and TM modes, Single and Multimode Waveguides, Step Index Fibre, Graded Index Fibre. Laser Fundamentals: Emission and Absorption of Radiation, Population Inversion, Optical Feedback and Gain, Cavity Modes, Single-Mode Operation, Frequency Stabilisation, Mode Locking Techniques, Q-Switching, DBR and DFB Lasers, Class of Non-Semiconductor Lasers. Optical Sources: semiconductor concepts - energy bands, semiconductor statistics; bandgap and E-k diagrams; optical emission from semiconductors - the p-n junction; principle of laser diode; heterostructure laser diodes; elementary laser diode characteristics; quantum well devices; vertical cavity surface emitting lasers; optical laser amplifiers; the light emitting diodes - surface emitter LEDs, edge emitter LEDs, super luminescent LEDs, LED characteristics, modulation bandwidths (electrical and optical). Optical Detection: detector performance parameters, characteristics of noise, detection techniques (incoherent and coherent detections), thermal detectors, photodetectors, p-n junction and p-i-n

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photodiodes, avalanche photodiodes, speed of response, detector array devices. Fibre Optic Components and Applications: optical fibre directional couplers (coupling principle and power exchange, practical parameters of a coupler, fabrication techniques and applications), fibre polarisers and polarisation controllers, fibre Bragg gratings (coupled mode theory, spectral response, fabrication techniques, applications in fibre optic communication and sensing), single-mode optical fibre sensors (Mach-Zehnder interferometric sensors and fibre optic rotation sensors), fibre optic switches, and microelectromechanicals systems (MEMS) optical switches. References [1] Wilson J., Optoelectronics: An Introduction to Material

and Devices, Prentice Hall, 2009. [2] Smith S.F.G. and King T.A., Optics and Photonics – An

Introduction, 6th Edition, Wiley, 2011. [3] Govind P. Agrawa,”Fiber-Optic Communication

Systems (Wiley Series in Microwave and Optical Engineering)”, Wiley, 2010.

BENT 4853: RADIO NAVIGATION SYSTEM Synopsis Introduction to Terrestrial Systems: shape of the Earth, maps and coordinate systems/Datum, distances and direction on the surface of the Earth, errors calculations. Hyperbolic Systems: OMEGA, DECCA, LORAN-C. Direction Finding: frequencies and transmitter, directivity,

receiver antenna, accuracies. Aircraft Systems: VHF Omnidirectional Range (VOR), Distance Measuring Equipment (DME), Instrument Landing System (ILS), Microwave Landing System (MLS). Introduction to Satellite Systems: satellite orbits and geometry, satellite navigation principles, error calculations. TRANSIT: satellites, navigation principles, receiver, frequencies, accuracy. Coding of Satellite Signals: spread spectrum, spreading functions, correlation function, generation of the codes, receiver, spread spectrum in NAVSTAR/GPS. NAVSTAR/GPS: satellite orbits, satellites, control segment, navigation messages, receiver, differential GPS, accuracy, integration with other navigation systems. GLONASS: satellite orbits, navigation signals, codes, navigation messages, receiver, accuracy. Other Satellite Navigation Systems: TSIKADA, STARFIX, GEOSTAR/LOCSTAR, NAVSTAR, Galileo, Beidou/Compass. References [1] Forssell, B., Radionavigation systems, Artech House,

2008 [2] Kayton M., Fried W.R., Avionics Navigation Systems

(3rd Edn.), John Wiley & Sons Inc., 2007 [3] Moir I., Seabridge A.G., Civil Avionics Systems, John

Wiley & Sons Inc., 2006. [4] Elliot D.Kaplan, Understanding GPS: Principles and

Applications , Artech House Publishers, Second Edition, 2005

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INTRODUCTION Malaysia has been recognized as one of the major exporting countries of semiconductor devices and the main manufacturers of electronic equipment in the last few decades. Continuous development in the field of electronics and widespread application of computers has brought a great impact on the development of the electronics industry in the country. Industrial electronic manufacturing including consumer products such as computers, audio - video equipment, optical drives, communication devices, mobile phones and so on. In non- electronic-based industries, electronic systems are also needed as a complement in the production process of products such as the oil refining industry, the automobile industry, production of rubber-based industries, etc. In the process of enhancing the competitiveness of the Malaysia industries, human capital that is knowledgeable and skilled in electronic engineering is very important and necessary. Diploma graduates will be able to meet the needs of semi - professional workforce. In addition, the diploma graduates with outstanding academic performance have the opportunity to further their studies to degree level. CAREER PROSECTS Employment opportunities for graduates of the Diploma in Electronic Engineering are particularly bright. Graduates can work as technical assistants or assistant engineer in government agencies, multinational companies, small and medium industries, as well as manufacturing and production industries. In addition, graduates can also engage in sales and marketing. Graduates who have excellent academic performance can also proceed to a higher level degree.

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PROGRAMME OBJECTIVES The objective of this program is to produce semi-professional human capital that have adequate basic knowledge in the field of electronic engineering. Programme objectives also specified several goals describing an expected achievements of graduates in their career and professional life after graduation.

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PROGRAMME OUTCOMES Upon graduation, the students should acquire the following abilities:

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CURRICULUM STRUCTURE The curriculum structure for this program is on par with any other programs offered by other universities in Malaysia. However, the concept of learning in UTeM is a bit different where students will be exposed to applications and practices to strengthen their theoretical knowledge. Diploma program is based on the newly introduced curriculum structure consisting of five regular semester and two special semester, which took almost three years to complete. Students are required to take 91 credit hours minimum in the period of study to graduate. Note that the structure of the previous curriculum takes 3 years to complete and consists of six regular semesters and one special semester with 98 credit hours. The first year in the diploma program begins with a typical semester where students will learnt three compulsory university’s subjects, namely, English Foundation, Tamadun Islam dan Asia (TITAS) and Philosophy of Science & Technology. All three subjects are intended to prepare students to participate in electronic engineering curriculum which is taught in English, and also to bring awareness of the moral values of semi-professional workforce in the future. Subjects offered for the next semester will prepare students towards the field of electronics such as Fundamental Mathematics, Physics, Computing and Computer Competency; as well as basic subjects related to electronics such as Electrical Principles. Students will also learn the Engineering Workshop subject which provides students with practical work such as electronic circuits design on printed boards, soldering, debugging audio - video system, domestic wiring, safety procedures in the working environment, etc. At the end of the workshop, each student is required to complete a small project to justify the skills acquired during the workshop. Starting from the second semester, students will follow a curriculum designed towards the Diploma in Electronic Engineering such as Electric Circuit, Communication Principles, Logic Circuit, Computer Aided Design, etc. The students were also given the elements of personality development in the form of communication skills training and extra-curricular activities. Therefore, in addition to producing graduates who are skilled in the technical field, graduates will have excellent communication skills and high moral values. In order to expose the students to the real working environment, they are required to undergo industrial training for 10 weeks in a second special semester. The students can get a training placement

in industries throughout Malaysia and supervised by the lecturers and supervisors of the industry. The experience gained during the industrial training will also increase the knowledge they learned at the university. In the final year, apart from the core subjects and two elective subjects , students will use the knowledge and experience they have gained in the period of study for about two and a half years to produce a mini project on electronic circuits . The project should be completed within one semester and will be assessed by the lecturer in a formal presentation. In addition to the technical subjects, students will learn about subjects relating to communication and co-curricular activities to prepare them for good communication skills.

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COURSE CURRICULUM FOR DIPLOMA OF ELECTRONIC ENGINEERING



DKKX xxxx Co-Curriculum 1 1 W DLHW 2712 Ethnic Relations 2 W

DENH 1142 Algebra 2 P Dkkx xxx1 Co-Curriculum II 1 W

DENH 1302 Physic Fundamentals 2 P DENH 1152 Calculus 3 P

DMCG 1523 Engineering Drawing 3 P DENE 1323 Electronic Principles 3 P

DENT 1213 Electrical Principles 3 P DENC 1532 ECADD 2 P

DENE 1131 Engineering Workshop 1 1 P DENE 1221 Engineering Workshop 2 1 P

DENC 1223 Computer Programming 3 P DENT 1233 Electric Circuits 3 P

TOTAL 15 DENC1433 Logic Circuits 3 P

TOTAL 18

Special Semester


DLHW 1012 Foundation English 2 W 2 W

DLHW 1702 Tamadun Islam dan Asian (TITAS) 2 W

DLHW 1722 Falsafah Sains dan Teknologi 2 W

TOTAL 6 130



DLHW 2422 English for Professional Communication 2 W DLHW 3432 English for Marketability 2 W

DENH 2163 Engineering Mathematic 3 P DENT 2543 Communication Principles 3 P

DENC 2443 Digital System 3 P DENH 2173 Differential Equations 3 P

DENE 2333 Electronics 3 P DENE 2353 Applied Electronics 3 P

DENE 2133 Electronic Instrumentation 3 P DENC 2453 Microcontroller 3 P

DENT 2253 Signal and Network 3 P DENE 2243 Electrical Technology 3 P

TOTAL 17 TOTAL 17

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Special Semester


DENU 2363 Industrial Training 3 P 2 W

DENU 2372 Industrial Training Report 2 P

TOTAL 5 130

Semester 5

CODE SUBJECT CREDIT CATEGORY

DTKW 1012 Entrepreneurship Culture Fundamental 2 W

DENE 3153 Control Principles 3 P

DENE 3563 Diploma Project 3 P

DENC 3363* Computer Engineering 3 E

DENT 3563* Telecommunication Engineering 3 E

DENE 3363* Industrial Automation 3 E

TOTAL 14

GRAND TOTAL 91

Category: W: University Compulsory Subjects P: Core Program Subjects E: Elective Subjects Note : * Choose any TWO(2) subjects only.

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PRA-SYARAT

Semester 1 Semester 2 Semester 3 Semester 4 Semester 5 Semester 6

Pre-requisite

DENE 1323 Electronic Principles

DENE 2333 Electronics

DENT 1213 Electrical Principles

DENT 2233 Electric Circuits

DENC 2443 Digital System

DENC 1433 Logic Circuit

DENH 1142 Algebra

DENH 1152 Calculus

DENH 2163 Engineering Mathematic

DENH 2173 Differential Equation Sequential

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SUBJECT LIST BASED ON CATEGORIES

UNIVERSITY COMPULSORY SUBJECTS (W) DKKX 1xx1 Co-Curriculum 1 DKKX 2xx1 Co-Curirulum 2 DLHW 1012 Foundation English DTKW 1012 Entrepreneurship Culture Fundamental DLHW 1702 Tamadun Islam dan Asia (TITAS) DLHW 1712 Ethnic Relations DLHW 1722 Falsafah Sains dan Teknologi DLHW 2422 English for Professional Communication DLHW 3432 English for Marketability PROGRAM CORE SUBJECTS (P) DENH 1142 Algebra DENH 1152 Calculus DENE 1131 Engineering Workshop 1 DENT 1213 Electrical Principles DENE 1221 Engineering Workshop 2 DENC 1223 Computer Programming DENT 1233 Electric Circuits DENH 1302 Physic Fundamentals DENE 1323 Electronic Principles DENC 1433 Logic Circuits DMCG 1523 Engineering Drawing DENC 1532 ECADD DENE 2133 Electronic Instrumentation DENH 2163 Engineering Mathematic DENH 2173 Differential Equations DENE 2243 Electrical Technology DENT2253 Signal and Network DENE 2333 Electronics DENE 2353 Applied Electronics DENC 2443 Digital System DENC 2453 Microcontroller DENT 2543 Communication Principles DENU 2363 Industrial Training DENU 2372 Industrial Training Report DENE 3153 Control Principles DENE 3563 Diploma Project PROGRAM ELECTIVE SUBJECTS (E) DENC 3363 Computer Engineering DENT 3563 Telecommunication Engineering DENE 3363 Industrial Automation

Syllabus Summary for the

Diploma of Electronic EngineeringProgramme

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UNIVERSITY COMPULSORY SUBJECTS (W) DKKX 1xx1 Co-Curriculum 1 DKKX 2xx1 Co-Curriculum 2 DLHW 1012 Foundation English DTKW 1012 Entrepreneurship Culture Fundamental DLHW 1702 Tamadun Islam dan Asia (TITAS) DLHW 1712 Ethnic Relations DLHW 1722 Falsafah Sains dan Teknologi DLHW 2422 English for Professional Communication DLHW 3432 English for Marketability PLEASE REFER TO THE PUSAT BAHASA DAN PEMBANGUNAN INSAN (PBPI) ACADEMIC HANDBOOK FOR SYNOPSYS AND SYLLABUS SUMMARY FOR THE ABOVE SUBJECTS.

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PROGRAMME CORE SUBJECTS (P) DENH 1142 ALGEBRA Synopsis Topics covered: Fundamental Concepts of Algebra: Real numbers, Exponents and Surds, Logarithms. Complex Numbers: Definition of Complex Numbers, Operations on Complex Numbers, Argand Diagram (Argand diagram of Complex Conjugates ,Modulus and Argument) and Polar Representation of Complex Numbers (De Moivre’s Theorem, Euler’s Formula). Matrices: Matrix Operation, Determinant of Matrices, Adjoint matrices and Inverse Matrices. Geometric Coordinates: Lines and Slope, Parallel and Perpendicular Lines. Trigonometry: Angles, Radian and degree measures of angles, Trigonometric Functions, Fundamental trigonometric identities, Solving of right-angled triangles and Basic relations between elements of triangle. Polynomials: The Algebraic Operations on Polynomials, Remainder Theorem and Partial Fractions. References [1] Michael Sullivan et al., “Algebra & Trigonometry”,

International Edition, Pearson, 2011. [2] Ron Larson, “Algebra & Trigonometry”, 7th ed,

Cengage Learning, 2015. [3] Kuldeep Singh, “Engineering Mathematics through

Applications”, International Edition, Palgrave Macmillan, 2011.

[4] Michael Artin, “Algebra”, 2nd Edition, Pearson Education, 2014.

[5] Nathan Jacobson, “Basic Algebra I”, Courier Corporation, 2012.

DENH 1302 PHYSICS FUNDAMENTALS Synopsis This course will discuss about Mechanics: Physical Quantities and Measurements, Kinematics of Linear Motion, Force, Momentum and Impulse, Work, Energy and Power, Static, Circular Motion, Rotation of A Rigid Body, Gravitation and Simple Harmonic Motion (SHM). Wave: Mechanical Waves and Sound Wave. Properties of Matter: Static, Dynamics, Circular Motion, Simple Harmonic, Moment of Inertia, Density and Specific Gravity, Hydrostatics, Elasticity, Friction, Viscosity,

Osmosis, Diffusion, Acceleration and Newton’s Second Law of Motion, Motion with a Changing Velocity and ohm law. Thermodynamics: Temperature and Heat Transfer, Theory Kinetic of Gases. Light: Reflection and Refraction of Light. References [1] Giancolli DC, “Physics for Scientists and Engineers

With Modern Physics”, 4th Edition, Pearson Prentice Hall, 2009.

[2] “Physics for Scientists and Engineers With Modern Physics”, 8th Edition, Cengage learning, 2010.

[3] Giambatista A., Richardson B.M and Richardson R.C., “College Physics”, 4th Edition, Mc-Graw Hill, 2012.

[4] Walker J.S., “Physics”, 4th Edition, Addison Wesley, 2009.

[5] Raymond Serway, John Jewett, “Physics for Scientists and Engineers”, Cengage Learning, 2013.

DENT 1213 ELECTRICAL PRINCIPLES Synopsis Topics covered: Electrical principles: Basic electrical concept, voltage, current and resistance, basic laws: Ohm’s and Kirchoff’s Law. Series and parallel circuits: resistors in series & parallel, total series parallel resistance, voltage & current dividers, power in series &parallel circuits, series-parallel relationship. Alternating Current & Voltage: introduction to the sinusoidal waveform, sinusoidal voltage sources, voltage and current values, angular measurement of a sine wave, the sine wave formula, introduction to phasors, analysis of ac circuits. Capacitors & Inductors: the basic types of capacitor & inductor, series parallel capacitors & inductors, capacitors & inductors in DC, AC circuits. Magnet and Electromagnetism: The magnetic field, electromagnetism, electromagnetic devices (Lenz law, faradays law). References [1] Floyd, “Principles of Electric Circuits”, 9th Edition,

Pearson Education, 2013. [2] Charles Alexander, Matthew Sadiku,

“Fundamentals of Electric Circuits”, McGraw-Hill Education, 6th Edition, 2016.

[3] Demetrios P. Kanoussis, “Electric Circuits”,vol. 1, Golden Ratio Publications, 2015.

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[4] Herbert W Jackson, “Introduction to Electric Circuits”, 9th Edition, Oxford University Press, 2015.

[5] Boylestad R., Nashelsky L., “Electronic Devices and Circuit Theory”, 11th Edition, Prentice Hall Inc., 2012.

DENC 1223 COMPUTER PROGRAMMING Synopsis Topics covered: Introduction to Computer Programming: computer and its application area, software development and algorithm. Introduction to C Language: C basic structure, identifiers and keywords, data type, variable, constant, operators, input and output operations. Control Technique: Control repetition statement, selection statement, nested loops, continue and break statements, and control flow. Functions: Prototype and function declaration, local and global variables, pass-by-value function, recursive function and modular programming. Arrays: array initialization and declaration, and array sorting. File Input / Output: binary buffer and streams reading data from file, and writing data to file. Derived Types: Enumeration, structure and union, structure declaration, structure definition, and structure operation. Pointers: operation, passing arguments to functions by reference, and relationship between pointers and arrays. References [1] Michael A. Vine, “C Programming for The Absolute

Beginner”, 3rd Edition, Thomson Course Technology, 2015.

[2] Stephen G. Kochan, “Programming in C”, 4th Edition, Addison-Wesley Professional, 2014.

[3] Rohit Upadhyay, “Learn C Language”, 3rd Edition, APL Scientific, 2015.

[4] Jeri R.Hanly and Elliot B.Koffman, “Problem Solving and Program Design in C”, 8th Edition, Pearson, 2015.

[5] Paul Deitel and Harvey Deitel, “C How to Program”, 8th Edition, Pearson, 2016.

DENH 1152 CALCULUS Synopsis Topics covered: Functions and graph: Limits, Cases of Non-Existent Limits, Limits at Infinity, Computational methods of Limit, Continuity. Differentiation: The Geometrical Meaning of Differentiation, Differentiation of Simple Algebraic Function, Differentiation Rules, Higher Order Differentiation, The Chain Rule, Derivatives of Trigonometric Function, Logarithmic Function, Exponential Function, Implicit Differentiation, Parametric Differentiation, Application of Differentiation. Integration: Anti Derivative and Indefinite Integrals, The Fundamental Theorem of Calculus, Techniques of Integration: Integration by Substitution, by Parts, Tabular Method, Partial Fraction, Integration of Trigonometric Functions, Integration of Irrational Functions, Application of Integration. Trigonometric Functions: Trigonometric Ratios and Identities, Compound Angle, Solution of Trigonometric Equations, Inverse, Introduction to Hyperbolic Functions, Hyperbolic Identities. References [1] Kenneth Kuttler, “Calculus: Theory and

Applications”, World Scientific, 2011. [2] Ron Larson “Calculus: An Applied Approach”, 9th

Edition, Cengage Learning, 2012. [3] Briggs, Cochran and Gillett “Calculus for Scientist

and Engineers”, Pearson Education, 2013. [4] Abd Wahid Md Raji, Hamisan Rahmat, Ismail

Kamis, Mohd Nor Mohamad and Ong Chee Tiong, “Calculus for Science and Engineering Students”, 2nd Edition, Penerbit UTHM, 2013.

[5] Frank Ayres, Elliott Mendelson, “Schaum's Outline of Calculus”, 6th ed, McGraw Hill Professional, 2012.

DENE 1131 ENGINEERING WORKSHOP I Synopsis Safety and Health (OSHA): Introduction to OSHA, Safety measures at workplace and Job Safety analysis (JSA), safety and health practices in workshop and laboratory sessions. Basic Electronic components : Introduction to the function, measuring and testing methods of the components; structure, characteristic, unit and symbol of resistor, diode, capacitor, transistor, inductor, transformer, IC, fuse and relay in electronic circuits. Trouble shooting techniques, workshop on active and passive components. Introduction to

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Electronic Equipment : Multimeter, Function and Signal Generators, AC/DC Power Supply, Oscilloscope. Circuit construction using Breadboard, use of various equipment to measure circuit performances. Electrical Domestic Wiring (Single Phase 240V) : wiring diagrams, wiring accessories, symbols and basic wiring circuitry for consumer, domestic wiring theory. References [1] Boylestad & Nashelsky, “Electronic Devices and

Circuit Theory”, 11th Edition, Prentice Hall, 2012. [2] Mahesh B. Patil , “Basic Electronic Devices And

Circuits”, PHI Learning Pvt. Ltd, 2013. [3] “Bengkel Kejuruteraan”, FKEKK, UTeM 2008. [4] David L. Goetsch , “Occupational Safety and Health

for Technologists, Engineers, and Managers”, Pearson Education, 2014

[5] Seppo Väyrynen, Kari Häkkinen, Toivo Niskanen, “Integrated Occupational Safety and Health Management: Solutions and Industrial Cases”, Springer, 2014.

DMCG 1523 ENGINEERING DRAWING Synopsis The course concentrates on manual drafting and Computer Aided Drafting (CAD) software. For manual drafting, students will be exposed to the basic drafting tools, techniques and the application in producing various types of engineering drawing. For computer aided design, CAD engineering drawing software is exercised to produce engineering drawing. The students will be exposed to CAD interface, editing commands, coordinate system, template preparation and layer in order to produce various types of engineering drawing. References [1] Jensen C. H., 2015, Interpreting Engineering

Drawings: 8th Edition, Delmar Thomson Learning, New York.

[2] James D. Bethune, Engineering Graphics with AutoCAD 2015, Pearson Education, 2014.

[3] Giesecke, F.E., Mitchell, A., Spencer, H.C., Hill, I.L., Dygdon, J.T., and Novak, J.E., 2011, Technical Drawing, 14th Ed., Prentice Hall, New York.

[4] Mohd Rizal Alkahari et. al., 2009, Modul Lukisan Berbantu Komputer, Penerbit Universiti Teknikal Malaysia Melaka, Melaka.

[5] Mohd Ramzan Zainal, Badri Abd Ghani and Yahya Samian, 2000, Lukisan Kejuruteraan Asas, Penerbit Universiti Teknologi Malaysia, Skudai.

DENE 1323 ELECTRONIC PRINCIPLES Synopsis This course discuss about the structure and material of semiconductor, diode characteristics and applications (half-wave& full-wave, clamping, clipping), special purpose diode (zener & varactor diode), BJT transistor (DC biasing; common-base, common-emitter & common collector) and FET transistor (DC biasing; common-source, common-drain & common-gate and special purpose of FET-Introduction and characteristics of JFET and MOSFET. References [1] BoylestadR., Nashelsky L., “Electronic Devices and

Circuit Theory”, 11th Edition, Prentice Hall, 2013. [2] Floyd, “Electronic Devices”, Ninth Edition, Prentice

Hall, 2012. [3] Harold D. Holbrook, Walter J. Seeley, “Basic

Electronics”, Elsevier Science, 2013. [4] Jean Riescher Westcott , “Basic Electronics:

Theoryand Practice” , Mercury Learning & Information , 2014.

[5] N. N Bhargava, D.C. Kulshreshtha, S. C. Gupta, “Basic Electronics and Linear Circuits”, Tata McGraw-Hill Education, 2013.

DENC 1532 ECADD Synopsis Topics covered: Introduction to ECADD: Introduction to ECADD software, selection of computer software simulation: Multisim, PSpice and MATLAB, advantages of ECADD, and the design process. Digital Circuit Simulation: Introduction to Multisim , instrumenting a simulation in Multisim, the concept of Digital Circuit, binary digit and logic level, Boolean algebra, introduction of advanced logic circuit, combinational logic, and sequential circuit. Analog Circuit Simulation: Introduction to PSpice, Use of PSpice with OrCAD capture, DC nodal analysis, DC sweep analysis, diode I-V characteristic, maximum power transfer, AC frequency sweep analysis, transient analysis, and amplifier voltage swing. Signal Processing: Introduction to MATLAB, the MATLAB system, starting MATLAB, entering commands

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and expressions, variables, computing with MATLAB, plotting with MATLAB/graphics, MATLAB scripting files and the editor/debugger, and MATLAB Simulink toolbox. References [1] James W. Nilsson, “Introduction to PSpice for

Electric Circuits”, 10th edition, Prentice Hall, 2014. [2] Holly Moore, “MATLAB for Engineers”, 4th edition,

Prentice Hall, 2013. [3] David Báez López, Felix Guerrero-Castro, et al.,

“Advanced Circuit Simulation Using Multisim Workbench”, Morgan & Claypool Publishers, 2012.

[4] David Baez-Lopez and Felix E. Guerrero-Castro, “Circuit Analysis with Multisim, 1st ed, Morgan and Claypool Publisher, 2011.

[5] Dennis Fitzpatrick, “Analog Design and Simulation using OrCAD Capture and PSpice, 1st Ed, Elsevier, 2011.

DENE 1221 ENGINEERING WORKSHOP II Synopsis Soldering and desoldering Technique : Introduction to Soldering, soldering tools, soldering technique, IPC standard, desoldering technique and Safety and Health during soldering. PCB Design and Fabrication : Introduction to PCB design using PROTEUS software, circuit design, ISIS simulation and ARES. Introduction PCB Fabrication, Drilling process, components installation and Safety and Health. Workshop: Using proteus to convert schematic to PCB layout, fabrication of PCB using UV etching technique. PIC Microcontroller: Introduction, Overview of Microcontroller, PIC Family, PIC Architecture and Programmer. Workshop: PCB programming and checking, circuit simulation using Proteus. References [1] H (Ted) Smith, “Quality Hand Soldering and

Circuit Board Repair”, 6th Edition, Delmar, 2012. [2] Mark. I. Montrose, “EMC Made Simple: Printed

Circuit Board and System Design”, Montrose Compliance Services, 2014.

[3] “Bengkel Kejuruteraan”, FKEKK, UTeM 2008. [4] Richard Buttars, “Printed Circuit Board

Assembly”, Richard Buttars, 2014. [5] John Cadick, Mary Capelli-Schellpfeffer, Dennis

Neitzel, Al Winfield , “Electrical Safety Handbook”, McGraw Hill Professional, 2012.

DENH 2173 DIFFERENTIAL EQUATIONS Synopsis This course will discuss about the classification of differential equations, first order ordinary differential equations, second order ordinary differential equations, Laplace transform, Fourier series and partial differential equations. References [1] Y. A. Cengel, W. J. Palm III, “Differential

equations for engineers and scientists”, McGraw Hill, 2013.

[2] Paul Blanchard, Robert L. Devaney, Glen R. Hall, “Differential equations”, 4th Edition, Brooks/Cole Cengage Learning, 2012.

[3] Stanley J. Farlow, “Partial Differential Equations for Scientists and Engineers”, Courier Corporation, 2012.

[4] J David Logan, “Applied Partial Differential Equations”, 3rd Edition. Springer, 2014.

[5] R. Kent Nagle, Edward B. Saff & Arthur David Snider. Fundamentals of Differential Equations and Boundary Value Problems, Eight Edition. Pearson Education Inc, 2012.

DENT2253 SIGNAL AND NETWORK Synopsis Topics covered: signal and system definition, continuous and discrete signal, signal operations, signal characteristics, types of signals. Fourier series, phase and amplitude spectrum, Parseval theorem. Fourier transform, step and delta function, energy and power spectrum, Laplace Transform and inverse Laplace Transform characteristics, Circuit analysis using Laplace Transform, filters, frequency response and filter analysis. References [1] Wasyl Wasylkiwskyj, “Signals and Transforms in

Linear Systems Analysis”, Springer Science & Business Media, 2013.

[2] Charles Alexander, Matthew Sadiku, “Fundamentals of Electric Circuits”, McGraw-Hill Education, 6th Edition, 2016.

[3] A. Anand Kumar, “Signals and Systems”, 3rd Edition, PHI Learning Pvt. Ltd, 2013.

[4] Luis Chaparro, “Signals and Systems using MATLAB”, 2nd ed., Academic Press, 2014.

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[5] Gang Li, Liping Chang, Sheng Li, “Signals and Systems: Fundamentals”, Tsinghua University Press, 2015.

DENE 2333 ELECTRONICS Synopsis Topics covered: Amplifier Fundamental: Introduction to an amplifier, equivalent circuit of an amplifier and output voltage with load and no load amplifier parameters: input and output resistance, current gain and voltage gain. Small Signal BJT Transistor Amplifiers: Introduction to basic concept of small signal BJT, analysis of BJT amplifier: C-E, C-C and C-B, load line and cascade amplifier. FET Transistor Amplifiers: Introduction to basic concept of small signal FET, coupling capacitors, analysis of JFET: fixed-bias, self-bias and voltage divider bias. Frequency Response of Amplifiers: Frequency response of BJT amplifier and FET amplifier and Bode Plot. Operational Amplifier: Basic principle of an amplifier, basic operation and characteristics of an operational amplifier. References [1] Boylestad R., Nashelsky L., “Electronic Devices and

Circuit Theory”, 11th Edition, Prentice Hall, 2013. [2] Floyd, “Electronic Devices”, Ninth Edition, Prentice

Hall, 2012. [3] Harold D. Holbrook, Walter J. Seeley, “Basic

Electronics”, Elsevier Science, 2013. [4] Jean Riescher Westcott, “Basic Electronics: Theory

and Practice” , Mercury Learning & Information , 2014.


DENT 1233 ELECTRICAL CIRCUITS Synopsis Topics covered: Basic Laws: Ohm’s Law, Nodes, Branches and Loops, Kirchoff’s Laws, Current Dividers, Voltage Dividers. DC Circuit Analysis: Nodal Analysis, Mesh Analysis, Circuit Analysis with Multism/PSpice, Circuit Theorems: Source Transformation, The Superposition Theorem, Thevenin’s Theorem, Norton’s Theorem, Maximum Power Transfer, Delta-to-Wye and Wye-to-Delta Conversions, First-Order Circuits: Source-free RC Circuits, Source-free RL Circuits,

Singularity Function, AC Circuits: Sinusoids, Phasors, Phasors Relationships for Circuit Elements, Two-port Networks: Introduction, Impedance Parameter, Admittance Parameter, Hybrid Parameter, Transmission Parameter, Interconnection of Networks, Applications. References [1] Floyd, “Principles of Electric Circuits”, 9th Edition,

Pearson Education, 2013. [2] Charles Alexander, Matthew Sadiku,

“Fundamentals of Electric Circuits”, McGraw-Hill Education, 6th Edition, 2016.

[3] Demetrios P. Kanoussis, “Electric Circuits”, vol. 1, Golden Ratio Publications, 2015.

[4] Herbert W Jackson, “Introduction to Electric Circuits”, 9th Edition, Oxford University Press, 2015.

[5] Boylestad R., Nashelsky L., “Electronic Devices and Circuit Theory”, 11th Edition, Prentice Hall Inc., 2012.

DENC 1433 LOGIC CIRCUITS Synopsis Topics covered: Introduction to Digital Concepts: analog and digital quantity, digital waveform, digital and logic circuits, parallel and serial transmission. Number Systems and Operations: Number systems, number conversion, binary codes, binary mathematical operation, signed numbers representation, one’s and two’s complement, two’s complement arithmetic. Combinational Logic Gates: Boolean constants and variables, truth table, Boolean theorems, Demorgan’ s theorems, parity generator and checker. Logic Expression and Logic Minimization: Simplifying logic circuits, designing combinational logic circuits, Karnaugh Map method simplifications. Combinational Logic Circuits and Applications: Logic gates, adders, comparator, decoder, encoder, etc. Introduction to Integrated Circuit Technology: Basic operational characteristics and parameters, CMOS circuits, TTL circuits, comparison of CMOS and TTL performance. References [1] Ronald J. Tocci, “Digital Systems, Principles and

Applications”, 11th edition, Prentice Hall, 2013. [2] Thomas L. Floyd, “Digital Fundamentals”, 11th ed,

Prentice Hall, 2014. [3] Roger L. Tokheim, “Digital Electronics: Principles

and Applications”, McGraw Hill, 2013.

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[4] Albert P. Malvino and Donald P. Leach, “Digital Principles and Applications”, 8th edition, McGraw Hill, 2015.

[5] J. Gibson, “Electronic Logic Circuits”, 3rd edition, Routledge, 2013.

DENH 2163 ENGINEERING MATHEMATICS Synopsis Topics covered: Functions of Several Variables: The concepts of the functions with several variables, Graphing Functions of Two Variables, Level Surfaces of Three Variables, Limit and Continuity, Partial Derivatives, Total Differential and Exact Differential, The Chain Rule and Implicit Differentiation, Local Extreme, Absolute Extreme and Lagrange Multipliers, Multiple Integral : Double Integral over Rectangles, Double Integrals over Nonrectangular Region, Double Integrals in Polar Form, Definition of Triple Integrals (over Non Cuboids Solids, Cylindrical Coordinates, Spherical Coordinates) and Application of Multiple Integrals, Vector-Valued Functions : Operations with Vector-Valued Functions, Derivatives and Integrals of Vector-Valued Functions, Motion in Space, Arch Length, Unit Tangent Vector, Principal Unit Normal Vector and Curvature and Torsion and Unit Binormal Vector. References [1] Finney R.L., Weir M.D. and Hass, J.R, “Thomas’

Calculus Multivariable”, 13th Edition, Pearson, 2013. [2] Anton H.,Bivens, I.C. and Davis S. “Calculus”, 10th

Edition, John Wiley, 2012. [3] James Stewart “Multivariable Calculus”, 8th Edition,

Cengage Learning, 2015. [4] John Bird, “Engineering Mathematics”, revised ed,

Routledge, 2014. [5] Yosza, Adib, Khoo, Hanissah, Norazlina, Farah

Shahnaz, “Engineering Mathematics Module”, 2010., Industrial Pres.

DENC 2443 DIGITAL SYSTEMS Synopsis Topics covered: Latches and Flip-Flops: Operation and applications. Counters: counter operation, counter with mod number < 2n, synchronous counters design, cascaded counters, and counter applications. Register: Basic shift register functions, type of registers and its function, shift registers counter and applications. Memory and Programmable Logic Devices: Random-Access Memories (RAMs), Read-Only Memories (ROMs), programmable ROMs (PROMs, EPROMs and EEPROMs), flash memories, memory expansion, special types of memories, magnetic and optical storage, introduction to CPLDs, and introduction to FPGAs. Introduction to Microprocessor, Computers & Buses. The microprocessor and the computer, the Central Processing Unit (CPU), the memory, and the input/output (I/O) port.

References [1] Ronald J. Tocci, “Digital Systems, Principles and

Applications”, 11th edition, Prentice Hall, 2013. [2] Thomas L. Floyd, “Digital Fundamentals”, 11th ed,

Prentice Hall, 2014. [3] Roger L. Tokheim, “Digital Electronics: Principles

and Applications”, McGraw Hill, 2013. [4] Albert P. Malvino and Donald P. Leach, “Digital

Principles and Applications”, 8th edition, McGraw Hill, 2015.

[5] Anand Kumar, “Fundamentals Of Digital Circuits”, 3rd edition, PHI Learning Pvt. Ltd, 2014.

DENE 2133 ELECTRONIC INSTRUMENTATIONS Synopsis Topics covered : Introduction: Instrumentation principles and techniques, measurements errors, accuracy, precision, resolution significant figures and standard. Transducer: Resistive position transducer, strain gauge, capacitive transducer, inductive transducer, linear variable differential transformer, thermistor, thermocouple, resistance temperature detector, semiconductor photodiodes and phototransistors. Opto-electronic: introduction to LED, laser and photodetector. Electronics instrumentation: Ammeter, voltmeter and ohmmeter, electronic multimeter, digital multimeter, half

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wave rectification and full wave rectification in voltmeter and ammeter, Wheatstone Bridge, Kelvin Bridge, bridge controlled circuit, oscilloscope and function generator. References [1] H S Kalsi, ‘Electronic Instrumentation’, 3rd Edition,

Tata McGraw-Hill, 2012. [2] Northrop R.B., ‘Introduction to Instrumentation and

Measurement’, 3rd Edition, CRC Press, 2014. [3] Michael Collier, Jade Zheng, ‘Electronic

Instrumentation and Measurement: Theory and Applications’, CreateSpace Independent Publishing Platform, 2014.

[4] S. Kamakshaiah, Pannala Krishna Murthy, J. Amarnath, ‘Electrical Measurements and Measuring Instruments’, I. K. International Pvt Ltd, 2011.

[5] Alan S. Morris, Reza Langari, ‘Measurement and Instrumentation: Theory and Application’, Academic Press, 2012.

DENE 2353 APPLIED ELECTRONICS Synopsis Topics covered: Electronic Devices: Application of electronic devices such as SCR, SCS, GTO, LASCR, DIAC, TRIAC, UJT and PUT. Filter: filter applications (basic filter concepts, filter response characteristics, active LP filter, active HP filter, active BP filter, active BS filter and filter response measurement). Oscillator circuits: Feedback oscillator principles, oscillators with the RC feedback circuits, LC feedback circuits, crystal oscillator, Astable and Monostable using op-amp, the 555 timer and applications. Power amplifier circuits: Class A, class B and class AB. Power supply: Power supply circuit, IC voltage regulator and application. These topics are very important to students because it gives emphasis on the design of circuits used in electronic systems. References [1] Boylestad R., Nashelsky L., “Electronic Devices and

Circuit Theory”, 11th Edition, Prentice Hall, 2013. [2] D.S.Vidyasagar, “Textbook of Applied Electronics:

Useful for Vocational Electronics, Diploma & Degree in Electronics Engineering”, 2013.

[3] Harold D. Holbrook, Walter J. Seeley, “Fundamentals of Applied Electronics”, Elsevier Science, 2013.

[4] Jean Riescher Westcott , “Basic Electronics: Theory and Practice” , Mercury Learning & Information , 2014.


DENC 2453 MICROCONTROLLER Synopsis Topics covered: Microcomputer System Concepts: Comparison on microprocessor and microcontroller, microcontroller families, overview of PIC microcontroller. Basic Microcontroller Architecture: PIC16F84A specifications, clock cycle, pipelining, pin descriptions, oscillators, STATUS register, ports, memory organization, program memory, data memory, interrupts, instruction cycle, memory and input/output interfacing. Microcontroller Programming Concepts: PIC16F84A assembly language instructions, program structure and source code layout. Microcontroller Programming Concepts: PIC16F84A assembly language instructions, sample programming techniques (branch, counters, time delays, interrupt service routine) and examples, program structure and source code layout. Microcontroller System Hardware Interfacing: Input/output device interfacing, LED, buttons, motor and motor drivers, LCD display, switches and light sensors. References [1] Martin P Bates, “Interfacing PIC Microcontroller,”

Second Ed, Embedded Design by interactive simulation, Newmes, 2013.

[2] Ajit Pal, “Microcontrollers: Principles and Applications”, PHI Learning Pvt. Ltd, 2012.

[3] Lucio Di Jasio, “Programming 16-nit PIC Microcontroller in C”, Second edition, Newnes, 2014.

[4] Syed R. Rizvi, “Microcontroller Programming: An Introduction”, CRC Press, 2012.

[5] M. M. Ahmad Zabidi, Sistem Terbenam Dengan Mikropemproses 68000Penerbit UTM Press, 2011.

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DENT 2543 COMMUNICATION PRINCIPLES Synopsis Topics covered: Introduction to telecommunication, transmission modes, power measurements, electromagnetic frequency spectrum, bandwidth and information capacity, amplitude modulation transmission & reception, single-sidebands communications systems, FM transmission & reception, digital modulation, noise in telecommunication systems, transmission line, VSWR, Smith Chart and transmission lines impedance matching. References [1] John G. Proakis, Masoud Salehi, “Fundamentals of

Communication Systems”, 2nd Ed, Pearson Education, 2014.

[2] Louis Frenzel, “Principles of Electronic Communication Systems”, 4th Edition, McGraw-Hill, 2015.

[3] Rodger E. Ziemer, “Principles of Communications”, 7th Edition, John Wiley & Sons, 2014.

[4] Wayne Tomasi “Advanced Electronic Communications Systems”, 6th ed, Pearson Education, 2013.

[5] Dhanshetti Sanjay, “Communication system” Dhanshetti, 2015.

DENE 2243 ELECTRICAL TECHNOLOGY Synopsis Topics covered: Magnetic Circuits: Electromotive force, magnetic field strength, relation between B and H, Kirchhoff’s law and magnetic hysteresis. Single-phase circuits: Alternating Voltage and Current, Phasor, series resonance, parallel resonance, power factor and power factor correction. Transformers: Open and short circuit tests, equivalent circuit, Voltage regulation and efficiency, Voltage generation and excitation methods. Basic Principles of Power System: Electrical transmission and introduction to three phase system. References [1] Robert E. Stein, “Electric Power System

Components: Transformers and Rotating Machines”, Springer Science & Business Media, 2013.

[2] John Bird, “Electrical Principles and Technology for Engineering”, Elsevier, 2013.

[3] Slobodan N. Vukosavic “Electrical Machines”, Springer Science & Business Media, 2012.

[4] Nopbhorn Leeprechanon, Kalipada Maity, Guanghsu Chang “Mechanical and Electrical Technology VI”, Trans Tech Publication, 2014.

[5] John Bird, “Electrical Circuit Theory and Technology,” Routledge, 2014.

DENU 2363 INDUSTRIAL TRAINING Synopsis All diploma students will be placed in appropriate local industries or government corporations for 10 weeks normally in the special semester of their second year of study. Students will be exposed to real life working environment relevant to their field of study. References [1] Industrial Training Guide Book, UTeM. [2] FKEKK handbook, UTeM DENU 2372 INDUSTRIAL TRAINING REPORT Synopsis All diploma students will be placed in appropriate local industries or government corporations for 10 weeks normally in the special semester of their second year of study. Students will be exposed to real life working environment relevant to their field of study. References [1] Industrial Training Guide Book, UTeM. [2] FKEKK handbook, UTeM

DENE 3153 CONTROL PRINCIPLES Synopsis Topics covered: Introduction to control system: Open loop control system, closed loop control system, system response and transfer function. Frequency domain: Laplace transform, transfer function, modelling in frequency domain, transfer function for electrical network, translational mechanical system and rotational mechanical system. Time domain: State space representation, modelling in state space representation for electrical network, translational and rotational mechanical system, conversion of state space – transfer

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function and vice versa. Time response: Poles and zero and their effect towards system response. First and Second order systems. Reduction of Multiple subsystem: Reduction of multiple subsystem using block diagram method. Stability: Determine system stability using Routh – Hurwitz criterion. References [1] Norman S. Nise, “Control System Engineering”, 7th

edition, Addison Wesley Publishing, 2014. [2] William Bolton, “Instrumentation and Control

Systems”, Newnes, 2015. [3] Sergey E. Lyshevski, “Control Systems Theory with

Engineering Applications”, Springer Science & Business Media, 2012.

[4] Katsuhiko Ogata, “Modern Control Engineering,” 5th edition, Pearson, 2013.

[5] David G. Hull, “Optimal Control Theory for Applications”, Springer Science & Business Media, 2013.

DENE 3563 DIPLOMA PROJECT Synopsis The Mini Project course is designed for the final year of Diploma’s students. Students are expected to do a hardware project and present it in a product form. At the end of the semester students are required to submit the final year project and will be assessed according to the course evaluation criteria. References [1] PMD’s guidelines. DENC 3363 COMPUTER ENGINEERING Synopsis This course will discuss about Introduction to Computers: Definition of computers, history of computers, categories of computers, example of computer usage, its application in society, and current computing technology. Computer Organization and Architecture: Basic components of a computer system, Central Processing Unit (CPU), memory, expansion slots and adaptor cards, ports, I/O devices, and storage media. Operating System Concepts: Introduction to system software, functions of an operating systems, and stand-alone utility programs. Computer Communications and Networking: Computer

communications, computer network, network architectures, network topologies and communication standards, data communications over telephone network, communication devices and channels, and the Internet. Computer Security, Privacy and Ethics: Computer security risks, information privacy, ethics and society. References [1] Misty V., Susan Sebok, Steven Freund, Jennifer

Campbell, Mark Frydenberg, “Discovering Computers, Cengage Learning, 2015.

[2] Alan Evans, Kendall Martin, & Mary Anne Poatsy, “Technology in Action”, 11th Edition, Prentice Hall, 2014.

[3] Catherine Laberta, “Computers Are Your Future”, 12th Edition, Prentice Hall, 2013.

[4] Dr.K.Dhanasekaran, “Introduction To Computer And Its Applications”, Manikandan Palanisamy, 2014.

[5] B Shuangbao Paul Wang, Robert S. Ledley, “Computer Architecture and Security: Designing Secure Computer Systems”, 1st Edition, John Wiley & Sons, 2012.

DENE 3363 INDUSTRIAL AUTOMATION Synopsis Topics covered: Introduction to Industrial Automation System: Basic concepts and terminology, impact of automation system in manufacturing, advantages & disadvantages of automation in manufacturing. Programmable Logic Controller (PLC): Introduction to PLC System, PLC Architecture and Operation, Ladder Diagram and Mnemonics, PLC Timer and Counter, Other Functions and Industrial Application. Industrial Automation Components: Construction and principle of operation of sensors (Position and Proximity Sensors) and Pneumatic (Valve and Actuator, solenoid and electrical ladder diagram) and Hydraulic. Industrial Robotics: Robot Anatomy and Related Attributes, Robot Control Systems, Application of Robotics and Robot Programming. References [1] Mikell P. Groover, “Automation, Production

Systems, and Computer-Integrated Manufacturing”, 4th edition, Prentice Hall, 2014.

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[2] John J. Craig, Introduction to Robotics: Mechanical and control, 3rd ed, Pearson, 2014

[3] Terry Bartelt. Industrial Automated Systems Instrumetation and motion control, Delmar, 2011.

[4] B.R. Mehta, Y. Jaganmohan Reddy, “Industrial Process Automation Systems: Design and Implementation”, Butterworth-Heinemann, 2014.

[5] Douglas M. Considine, Glenn D. Considine, “Standard Handbook of Industrial Automation”, Springer Science & Business Media, 2012.

DENT 3563 TELECOMMUNICATION ENGINEERING Synopsis Topics covered: Basic principles of Communications System: electromagnetic spectrum, power measurement, modulations techniques, noise and exposure to the latest technology in telecommunication systems. Digital Communication: elements of a digital communication system, digital modulation, digital pulse modulation and digital encoding. Optical Fiber Communications: single and multimode fiber, light propagation, light sources and detectors. Antenna and Waveguide: basic antenna and waveguide, radiation patterns, radiation resistance, antenna efficiency, gains,

capture area, captured power, polarization, beam width, bandwidth, input impedance. Satellite System: GEO satellite, coordinates, satellite links, power attenuations, transmission errors and error coding, access techniques, link budget. Telephony System: transmission telephone, local loop, line characteristics and conditioning, PSTN, hybrids, echo suppression, central office switching system, switches, switching, trunks circuits. References [1] John Dunlop, “Telecommunications Engineering”,

3rd Edition, John Springer US, 2014. [2] Thiagarajan Viswanathan, Manav Bhatnagar,

“Telecommunication Switching Systems And Networks”, 2nd Edition, PHI Learning Pvt. Ltd, 2015.

[3] Wayne Tomasi “Advanced Electronic Communications Systems”, 6th ed, Pearson Education, 2013.

[4] Sanjay Sharma, “Communication Engineering”, S.K. Kataria & Sons, New Delhi, 2012.

[5] Andreas F. Molisch, “Wireless Communications”, 2nd Edition, Wiley IEEE Press, 2012.

List ofFKEKK Staff

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TOP MANAGEMENT STAFF DR. NURULFAJAR BIN ABD MANAP DEAN A/1-24 (Admin), 1st Floor 06-555 2100 [email protected] DR. MOHD SHAKIR BIN MD SAAT DEPUTY DEAN (ACADEMIC)/SENIOR LECTURER A/1-22, (Admin), 1st Floor 06-5552101 [email protected] ASSOCIATE PROFESSOR DR. AZMI BIN AWANG MD ISA DEPUTY DEAN (RESEARCH and DEVELOPMENT)/ ASSOCIATE PROFESSOR A/1-20 (Admin), 1st Floor 06-555 2102 [email protected] DR. ZAMRE BIN ABD. GHANI HEAD OF DEPARTMENT (INDUSTRIAL ELECTRONICS) / SENIOR LECTURER A/1-14 (Admin), 1st Floor 06-555 2108 [email protected] DR. MASRULLIZAM BIN MAT IBRAHIM HEAD OF DEPARTMENT (COMPUTER ENGINEERING)/ SENIOR LECTURER A/1-15 (Admin), 1st Floor 06-555 2105 [email protected] DR. ABDUL MAJID BIN DARSONO HEAD OF DEPARTMENT (TELECOMMUNICATION ENGINEERING)/SENIOR LECTURER A/1-17 (Admin), 1st Floor 06-555 2104 [email protected]

DR. SHARATUL IZAH BINTI SAMSUDIN HEAD OF DEPARTMENT (DIPLOMA STUDIES)/ SENIOR LECTURER A/1-12 (Admin), 1st Floor 06-555 2107 [email protected] MOHD HANAPIAH BIN MD LIP SENIOR ASSISTANT REGISTRAR A/1-19 (Admin), 1st Floor 06-555 2128 [email protected] ERNAWATIE BINTI MD SAH ASSISSTANT REGISTRAR A/G-1 (Admin), Ground Floor 06-555 2103 [email protected]

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LIST OF STAFF MEMBERS IN INDUSTRIAL ELECTRONICS DEPARTMENT DR. ZAMRE BIN ABD. GHANI HEAD OF DEPARTMENT (INDUSTRIAL ELECTRONICS) / SENIOR LECTURER A/1-14 (Admin), 1st Floor 06-555 2108 [email protected] PROFESSOR IR. DR. KENNETH SUNDARAJ PROFESSOR A/2-27, 2st Floor 06-555 2050 [email protected] ASSOCIATE PROFESSOR DR. KOK SWEE LEONG ASSOCIATE PROFESSOR F/1-8, Ground Floor 06-555 2157 [email protected] DR. MOHD SHAKIR BIN MD SAAT DEPUTY DEAN (ACADEMIC)/SENIOR LECTURER A/1-22, (Admin), 1st Floor 06-5552101 [email protected] DR. YOSZA BIN DASRIL SENIOR LECTURER A/2-30, 2nd Floor 06-555 2047 [email protected] DR. MAI MARIAM BINTI MOHAMED AMINUDDIN SENIOR LECTURER F/1-7, Ground Floor 06-555 2156 [email protected] DR. KHAIRUDDIN BIN OSMAN SENIOR LECTURER A/G-23, Ground Floor 06-555 2022 [email protected]

DR. AMAT AMIR BIN BASARI SENIOR LECTURER A/G-20, Ground Floor 06-555 2069 [email protected] ZULHAIRI BIN OTHMAN SENIOR LECTURER A/3-30, 3rd Floor 06-555 2137 [email protected] FARID ARAFAT BIN AZIDIN SENIOR LECTURER F/1-4, Ground Floor 06-555 2153 [email protected] DR. SHARATUL IZAH BINTI SAMSUDIN SENIOR LECTURER A/3-4 3rd Floor 06-555 2098 [email protected] DR. AHMAD SADHIQIN BIN MOHD ISIRA SENIOR LECTURER A/G-17, Ground Floor 06-555 2025 [email protected] NORIZAN BIN MOHAMAD LECTURER A/2-12, 2nd Floor 06-555 2069 [email protected] AZMAN BIN AWANG TEH LECTURER A/3-29, 3rd Floor 06-555 2133 [email protected] IMRAN BIN HINDUSTAN LECTURER A/G-16, Ground Floor 06-555 2026 [email protected]

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ZULKARNAIN BIN ZAINUDIN LECTURER F/1-14, Ground Floor 06-555 2159 [email protected] SITI AMANIAH BINTI MOHD CHACHULLI LECTURER B/3-1, 3rd Floor 06-555 2167 [email protected] HAZIEZOL HELMI BIN MOHD YUSOFF LECTURER A/G-26, Ground Floor 06-555 2021 [email protected] KHAIRUN NISA BINTI KHAMIL LECTURER A/G-16 Ground Floor 06-555 2024 [email protected] AZDIANA BINTI MD YUSOP LECTURER A/3-27, 3nd Floor 06-555 2134 [email protected] NOOR ASYIKIN BINTI SULAIMAN LECTURER A/3-6, 3nd Floor 06-555 2095 [email protected] ADIE BIN MOHD KHAFE LECTURER F/1-17, Ground Floor 06-555 2162 [email protected] MAZRAN BIN ESRO SENIOR LECTURER A/3-16, 3rd Floor 06-555 2091 [email protected] SITI HUZAIMAH BINTI HUSIN SENIOR LECTURER (Study Leave) [email protected]

YUSMARNITA BINTI YUSOP SENIOR LECTURER (Study Leave) [email protected] SIVA KUMAR A/L SUBRAMANIAM SENIOR LECTURER (Study Leave) [email protected] IR. RIDZA AZRI BIN RAMLEE SENIOR LECTURER (Study Leave) [email protected] HAFEZ BIN SARKAWI LECTURER (Study Leave) [email protected] SITI FATIMAH BINTI SULAIMAN LECTURER (Study Leave) [email protected] HAZLI RAFIS BIN ABDUL RAHIM LECTURER (Study Leave) [email protected] HAIRULISAM BIN MD DOM SENIOR ASSISTANT ENGINEER Block E/1-10, Industrial Automation Lab. 06-555 2175 [email protected] HAFIZAH BINTI ADNAN ASSISTANT ENGINEER Block E/3-11, Research Laboratory II 06-555 2188 [email protected] MUHAMMAD SYAHRIZAN BIN JOHAL ASSISTANT ENGINEER Block E/3-10, Industrial Electronic Lab 1 06-555 2187 [email protected] MOHD AZRI BIN SULAIMAN ASSISTANT ENGINEER Block E/2-4, Electronic Lab 1 06-555 2179 [email protected]

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MOHAMAD EFFENDY BIN ABIDIN ASSISTANT ENGINEER Block E/2-9, Electrical Technology Lab 06-555 2181 [email protected] AZMI BIN HUSSIN ASSISTANT ENGINEER Block E/1-10, Industrial Automation Lab 06-555 2175 [email protected] MOHD FIRDAUS BIN ABDUL JALIL ASSISTANT ENGINEER Block E/2-9, Electronic Lab 2 06-555 2180 [email protected] MD JAIS BIN IBRAHIM ASSISTANT ENGINEER Block E/2-4, Electronic Lab 1 06-555 2179 [email protected] MOHD YUSZAH BIN JAILANI ASSISTANT ENGINEER Block E/3-10, Industrial Electronic Lab 1 06-555 2187 [email protected]

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LIST OF STAFF MEMBERS IN COMPUTER ENGINEERING DEPARTMENT DR. MASRULLIZAM BIN MAT IBRAHIM HEAD OF DEPARTMENT (COMPUTER ENGINEERING)/ SENIOR LECTURER A/1-15 (Admin), 1st Floor 06-555 2105 [email protected] PROFESSOR DR. ZULKALNAIN BIN MOHD YUSSOF PROFESSOR A/2-40, 2nd Floor 06-555 2139 [email protected] DR. NURULFAJAR BIN ABD MANAP DEAN / SENIOR LECTURER A/1-24, (Admin), 1st Floor 06-555 2100 [email protected] DR. FAUZIYAH BINTI SALEHUDDIN SENIOR LECTURER A/2-11, 2st Floor 06-555 2044 [email protected] DR. LIM KIM CHUAN SENIOR LECTURER A/2-35, 2nd Floor 06-555 2120 [email protected] DR. SOO YEW GUAN SENIOR LECTURER F/1-19, Ground Floor 06-555 2164 [email protected] DR. LOW YIN FEN SENIOR LECTURER A/3-34, 3rd Floor 06-555 2139 [email protected]

DR. ANIS SUHAILA BINTI MOHD ZAIN SENIOR LECTURER A/3-38, 3rd Floor 06-555 2141 [email protected] DR. KHOO CHIN FOON SENIOR LECTURER A/3-43, 3rd Floor 06-555 2097 [email protected] DR. WIRA HIDAYAT BIN MOHD SAAD SENIOR LECTURER A/2-1, 2ND Floor 06-555 2056 [email protected] DR. WONG YAN CHIEW SENIOR LECTURER B/3-3, 3rd Floor 06-5552165 [email protected] DR. HANIM BINTI ABD. RAZAK SENIOR LECTURER A/3-17, 2nd Floor 06-555 2064 [email protected] DR. NORIHAN BINTI ABDUL HAMID SENIOR LECTURER A/3-37 3rd Floor 06-5552130 [email protected] DR. SYAFEEZA BINTI AHMAD RADZI SENIOR LECTURER A/2-16 2nd floor 06-555 2066 [email protected] DR. NORHASHIMAH BINTI MOHD SAAD SENIOR LECTURER A/2-5, 2nd Floor 06-555 2058 [email protected]

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DR. AFIFAH MAHERAN BINTI ABDUL HAMID LECTURER A/2-18, 2nd Floor 06-555 2066 [email protected] SANI IRWAN BIN MD SALIM SENIOR LECTURER A/2-16, 2nd floor 06-555 2067 [email protected] NORAZLINA BINTI ABDUL RAZAK SENIOR LECTURER A/3-1, 3rd Floor 06-555 2080 [email protected] VIGNESWARA RAO A/L GANNAPATHY SENIOR LECTURER A/G-14, Ground Floor 06-555 2027 [email protected] ZARINA BINTI BAHARUDIN ZAMANI LECTURER A/3-7, 3rd Floor 06-555 2083 [email protected] NIZA BINTI MOHD IDRIS LECTURER A/2-9, 2nd Floor 06-555 2060 [email protected] ROSMAN BIN ABD RAHIM LECTURER F/1-3, Ground Floor 06-555 2152 [email protected] KHAIRUL MUZZAMMIL BIN SAIPULLAH LECTURER F/1-16, Ground Floor 06-555 2160 [email protected]

HANISSAH BINTI MOHAMAD @SULAIMAN LECTURER F/1-19, Ground Floor 06-5552150 [email protected] FARAH SHAHNAZ BINTI FEROZ LECTURER A/3-31, 3nd Floor 06-555 2132 [email protected] NOOR MAZLINA BINTI MAHMOD LECTURER A/2-4, 2nd Floor 06-555 2072 [email protected] ZARINA BINTI MOHD NOH LECTURER A/3-12, 3nd Floor 06-555 2093 [email protected] DR. MOHD RIDUAN BIN AHMAD SENIOR LECTURER (Study Leave) [email protected] NIK MOHD ZARIFIE BIN HASHIM SENIOR LECTURER (Study Leave) [email protected] ANUAR BIN JAAFAR LECTURER (Study Leave) [email protected] AHMAD FAYEEZ BIN TUANI IBRAHIM LECTURER (Study Leave) [email protected] SITI AISAH BINTI MAT YUNOS@YUNUS LECTURER (Study Leave) [email protected] NUR FATIHAH BINTI AZMI LECTURER (Study Leave) [email protected] SITI AISYAH BINTI ANAS LECTURER (Study Leave) [email protected]

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MUHAMMAD RAIHAAN BIN KAMARUDIN LECTURER (Study Leave) [email protected] MUHAMMAD NOORAZLAN SHAH BIN ZAINUDIN LECTURER (Study Leave) [email protected] NORHIDAYAH BINTI MOHAMAD LECTURER (Study Leave) [email protected] MUZALIFAH BINTI MOHD SAID LECTURER (Study Leave) [email protected] RANJIT SINGH A/L SARBAN SINGH LECTURER (Study Leave) [email protected] ZUL ATFYI FAUZAN BIN MOHAMMED NAPIAH LECTURER (Study Leave) [email protected] RADI HUSIN BIN RAMLEE LECTURER (Study Leave) [email protected] NUR ALISA BINTI ALI LECTURER (Unpaid Leave) [email protected] ZULKARNAIN BIN HASAN ASSISTANT ENGINEER Block C/1-5, Research Laboratory III 06-555 2170 [email protected] NUR SYAHIDA BINTI YAHYA ASSISTANT ENGINEER Block C/3-5, Microprocessor Lab 06-555 2183 [email protected] MAHADI BIN SALLEH ASSISTANT ENGINEER Block A/G, Component Store 06-555 2033 [email protected]

AZMI BIN ZAKARIA ASSISTANT ENGINEER Block C/2-10, Digital Lab 2 06-555 2177 [email protected] FAKHRUL RIDHUAN BIN IBRAHIM ASSISTANT ENGINEER Block C/2-5, Digital Lab 1 06-555 2176 [email protected] SITI NURSALASIAH BINTI ABIDIN ASSISTANT ENGINEER Block C/1-10, Computer Engineering Lab 06-555 2171 [email protected]

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LIST OF STAFF MEMBERS IN TELECOMMUNICATION ENGINEERING DEPARTMENT DR. ABDUL MAJID BIN DARSONO HEAD OF DEPARTMENT (TELECOMMUNICATION ENGINEERING)/SENIOR LECTURER A/1-17 (Admin), 1st Floor 06-555 2104 [email protected] DATO’ PROFESOR DR. MOHD NOR BIN HUSAIN PROFESSOR A/2-32, 2nd Floor 06-555 2046 [email protected] PROFESSOR DR. ABDUL RANI BIN OTHMAN PROFESSOR A/2-41, 2nd Floor 06-555 2040 [email protected] ASSOCIATE PROFESSOR DR. AZMI BIN AWANG MD ISA DEPUTY DEAN (RESEARCH and DEVELOPMENT)/ ASSOCIATE PROFESSOR A/1-20, (Admin), 1st Floor 06-555 2102 [email protected] ASSOCIATE PROFESSOR DR BADRUL HISHAM BIN AHMAD ASSOCIATE PROFESSOR CRIM/A/2-28, 2nd Floor 06-555 2048 [email protected] ASSOCIATE PROF. DR. ZAHRILADHA BIN ZAKARIA ASSOCIATE PROFESSOR A/2- 34, 2nd Floor 06-555 2045 [email protected]

ASSOCIATE PROFESSOR DR. MOHAMAD ZOINOL ABIDIN BIN ABD. AZIZ ASSOCIATE PROFESSOR / HEAD OF DEPARTMENT (I-COE) 06-555 6434 [email protected] DR. HAZURA BINTI HAROON SENIOR LECTURER A/2-5, 2nd Floor 06-555 2107 [email protected] DR. HO YIH HWA SENIOR LECTURER A/2-19, 2nd Floor 06-555 2065 [email protected] DR. MAISARAH BINTI ABU SENIOR LECTURER A/2-40, 2nd Floor 06-555 2055 [email protected] DR. MOHD AZLISHAH BIN OTHMAN SENIOR LECTURER F/1-2, Ground Floor 06-555 2151 [email protected] DR. MOHD SA'ARI BIN MOHAMAD ISA SENIOR LECTURER A/3-32, 3rd Floor 06-555 2138 [email protected] DR. SITI KHADIJAH BINTI IDRIS@OTHMAN SENIOR LECTURER A/2-3, 2nd Floor 06-555 2057 [email protected]

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DR. SITI NORMI BT ZABRI @ SUHAIMI SENIOR LECTURER A/2-14, 2nd Floor 06-555 2068 [email protected] DR. NOOR AZWAN BIN SHAIRI SENIOR LECTURER B/3-4, 3rd Floor 06-555 2096 [email protected] IMRAN BIN MOHD IBRAHIM SENIOR LECTURER A/3-15, 3rd Floor 06-555 2087 [email protected] AZAHARI BIN SALLEH SENIOR LECTURER A/3-28, 3rd Floor 06-555 2104 [email protected] ZAHARIAH BINTI MANAP SENIOR LECTURER A/2-13 2nd Floor 06-5552062 [email protected] MOHD SHAHRIL IZUAN BIN MOHD ZIN SENIOR LECTURER A3-40, 3rd Floor 06-555 2142 [email protected] DR. JUWITA BINTI MOHD SULTAN LECTURER A/3-18, 3rd Floor 06-555 2090 [email protected] FAUZI BIN ABDUL WAHAB LECTURER A/2-15, 2nd Floor 06-555 2063 [email protected]

A. NASORUDDIN BIN MOHAMAD LECTURER A/3-5 3rd Floor 06-5552082 [email protected] NAJMIAH RADIAH BINTI MOHAMAD LECTURER A/3-39, 3rd Floor 06-555 2099 [email protected] SITI ROSMANIZA BINTI AB. RASHID LECTURER A/G-21, Ground Floor 06-555 2023 [email protected] NAZREEN BINTI WAELEH LECTURER B/3-3, 3rd Floor 06-555 2166 [email protected] NOR AZLAN BIN MOHD ARIS LECTURER B/3-8, 3rd Floor 06-555 2124 [email protected] NORBAYAH BINTI YUSOP LECTURER B-3-1, 3rd Floor 06-555 2168 [email protected] ZAITON BINTI ABDUL MUTALIP LECTURER B/3-14, 3rd Floor 06-555 2092 [email protected] ADIB BIN OTHMAN LECTURER B/3-5, 3rd Floor 06-555 2146 [email protected]

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NOOR SHAHIDA BINTI MOHD KASIM LECTURER A/G-16, Ground Floor 06-555 2031 [email protected] MOHD KHANAPIAH BIN NOR LECTURER F/1-5, Ground Floor 06-555 2154 [email protected] ASSOCIATE PROF. MUHAMMAD SYAHRIR BIN JOHAL ASSOCIATE PROFESSOR (Study Leave) [email protected] REDZUAN BIN ABD. MANAP SENIOR LECTURER (Study Leave) [email protected] DR. DAVID YAP FOOK WENG SENIOR LECTURER (Unpaid Leave) [email protected] NOOR BADARIAH BINTI ASAN LECTURER (Study Leave) [email protected] FAKRULRADZI BIN IDRIS LECTURER (Study Leave) [email protected] MAS HASLINDA BINTI MOHAMAD LECTURER (Study Leave) [email protected] MOHAMAD HARRIS BIN MISRAN LECTURER (Study Leave) [email protected] MAWARNI BINTI MOHAMED YUNUS LECTURER (Study Leave) [email protected] ANAS BIN ABDUL LATIFF LECTURER (Study Leave) [email protected]

MUHAMMAD IDZDIHAR BIN IDRIS LECTURER (Study Leave) [email protected] FAIZ BIN ARITH LECTURER (Study Leave) [email protected] MAIZATUL ALICE BINTI MEOR SAID LECTURER (Study Leave) [email protected] ABD. SHUKUR BIN JA’AFAR SENIOR LECTURER (Study Leave) [email protected] MOHD MUZAFAR BIN ISMAIL LECTURER (Study Leave) [email protected] NURAISHAH BINTI SARIMIN LECTURER (Study Leave) [email protected] IDA SYAFIZA BINTI MD ISA LECTURER (Study Leave) [email protected] MOHD AEINI BIN AMIN SENIOR ASSISTANT ENGINEER Block E/3-5, Microwave Lab 06-555 2186 [email protected] FAUZURA BINTI MOHD SALLEH ASSISTANT ENGINEER Block C/3-10, Wireless Communication Lab 06-555 2184 [email protected] YUSRI BIN OTHMAN ASSISTANT ENGINEER Block D/3-5, Electronic Communication Lab 06-555 2185 [email protected] IMRAN BIN MOHAMED ALI ASSISTANT ENGINEER Blok D/1-5, PCB and PSM Lab 06-555 2172 [email protected].

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MOHD SUFIAN BIN ABU TALIB ASSISTANT ENGINEER Block E/1-4, Research Laboratory I 06-555 2173 [email protected] KHAIRUL ZAMAN BIN MUSTAPA ASSISTANT ENGINEER Block F/2-5, Post Graduate Laboratory I & II 06-555 2182 [email protected] MUHAMMAD ZUHAIR BIN IDRIS ASSISTANT ENGINEER Block D/2-5, Basic Communication Lab 06-555 2178 [email protected]


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ADMINISTRATIVE STAFF SITI ZURAH BINTI MOHD NASIR ASSISTANT ADMINISTRATIVE OFFICER A/G-1 (Admin), Ground Floor 06-555 2115 [email protected] HJH. NORHAYATI BINTI HJ. MAHAT SENIOR ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/G-1 (Admin), Ground Floor 06-555 2117 [email protected] NORHASANAH BINTI ZAINAL ASSISTANT ACCOUNTANT (FINANCE) A/1-21(Admin), Ground Floor 06-555 2110 [email protected] SITI ZURIANA BINTI OMAR ADMINISTRATIVE ASSISTANT (SECRETARIAL) A/1-27 (Admin), 1st Floor 06-555 2111 [email protected] SITI NURBAIZURA BINTI OMAR ADMINISTRATIVE ASSISTANT (FINANCE) A/1-18 (Admin), 1st Floor 06-555 2116 [email protected] MAHATHIR BIN MAHAT ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/G-1 (Admin), Ground Floor 06-555 2106 [email protected] MOHD SAZRIN BIN SAHAD ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/G-1 (Admin), Ground Floor 06-555 2113 [email protected]

ZAINARIA BTE SURIP ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/1-18 (Admin), 1st Floor 06-555 2114 [email protected] MOHD HAIRI BIN ABD. JALIL OFFICE GENERAL ASSISTANT A/G-1 (Admin), Ground Floor 06-555 2113 [email protected] RUSZAIDE BIN HJ. MOHAMAD OFFICE GENERAL ASSISTANT A/G-1 (Admin), Ground Floor 06-555 2028 [email protected]

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ADMINISTRATIVE STAFF SITI ZURAH BINTI MOHD NASIR ASSISTANT ADMINISTRATIVE OFFICER A/G-1 (Admin), Ground Floor 06-555 2115 [email protected] HJH. NORHAYATI BINTI HJ. MAHAT SENIOR ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/G-1 (Admin), Ground Floor 06-555 2117 [email protected] NORHASANAH BINTI ZAINAL ASSISTANT ACCOUNTANT (FINANCE) A/1-21(Admin), Ground Floor 06-555 2110 [email protected] SITI ZURIANA BINTI OMAR ADMINISTRATIVE ASSISTANT (SECRETARIAL) A/1-27 (Admin), 1st Floor 06-555 2111 [email protected] SITI NURBAIZURA BINTI OMAR ADMINISTRATIVE ASSISTANT (FINANCE) A/1-18 (Admin), 1st Floor 06-555 2116 [email protected] MAHATHIR BIN MAHAT ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/G-1 (Admin), Ground Floor 06-555 2106 [email protected] MOHD SAZRIN BIN SAHAD ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/G-1 (Admin), Ground Floor 06-555 2113 [email protected]

ZAINARIA BTE SURIP ADMINISTRATIVE ASSISTANT (OPERATION CLERICAL) A/1-18 (Admin), 1st Floor 06-555 2114 [email protected] MOHD HAIRI BIN ABD. JALIL OFFICE GENERAL ASSISTANT A/G-1 (Admin), Ground Floor 06-555 2113 [email protected] RUSZAIDE BIN HJ. MOHAMAD OFFICE GENERAL ASSISTANT A/G-1 (Admin), Ground Floor 06-555 2028 [email protected]

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FACULTY PUBLICATION & MEDIA COMMITTEE

ADVISOR

DR. NURULFAJAR BIN ABD MANAP

COORDINATOR

SANI IRWAN BIN MD SALIM

COMMITTEE MEMBERS DR. ABD MAJID BIN DARSONO

DR. MAI MARIAM BINTI MOHAMED AMINUDDIN

DR. WIRA HIDAYAT BIN MOHD SAAD

DR. NOOR AZWAN BIN SHAIRI

DR. AHMAD SADHIQIN BIN MOHD ISIRA

DR. JUWITA BINTI SULTAN

MOHD SHAHRIL IZUAN BIN MOHD ZIN

NOOR ASYIKIN BINTI SULAIMAN

ZARINA BINTI MOHD NOH

FARAH SHAHNAZ BINTI FEROZ

VIGNESWARA RAO A/L GANNAPATHY

HAZIEZOL HELMI BIN MOHD YUSOF

HAIRULISAM BIN MD DOM

NUR SYAHIDA BINTI YAHYA

universiti teknikal malaysia...

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