HOLY ANGEL UNIVERSITY College of Engineering & Architecture Department of Electronics Engineering
University Vision, Mission, Goals and Objectives:
Mission Statement (VMG)
We, the academic community of Holy Angel University, declare ourselves to be a Catholic University. We dedicate ourselves to our core purpose, which is to provide accessible quality education that transforms students into persons of conscience, competence, and compassion. We commit ourselves to our vision of the University as a role-model catalyst for countryside development and one of the most influential, best managed Catholic universities in the Asia-Pacific region. We will be guided by our core values of Christ-centeredness, integrity, excellence, community, and societal responsibility. All these we shall do for the greater glory of God. LAUS DEO SEMPER! College Vision, Goals and Objectives: Vision
A center of excellence in engineering and architecture education imbued with Catholic mission and identity serving as a role-model catalyst for countryside development
Mission
To provide accessible quality engineering and architecture education leading to the development of conscientious, competent and compassionate professionals who continually contribute to the advancement of technology, preserve the environment, and improve life for countryside development.
Goals
The College of Engineering and Architecture is known for its curricular programs and services, research undertakings, and community involvement that are geared to produce competitive graduates:
- who are equipped with high impact educational practices for global employability and technopreneurial opportunities;
- whose performance in national licensure examinations and certifications is consistently above national passing rates and that falls within the 75th to 90th percentile ranks; and,
- who qualify for international licensure examinations, certifications, and professional recognitions;
Objectives
In its pursuit for academic excellence and to become an authentic instrument for countryside development, the College of Engineering and Architecture aims to achieve the following objectives:
1. To provide students with fundamental knowledge and skills in the technical and social disciplines so that they may develop a sound perspective for competent engineering and architecture practice;
2. To inculcate in the students the values and discipline necessary in developing them into socially responsible and globally competitive professionals;
3. To instill in the students a sense of social commitment through involvement in meaningful community projects and services;
4. To promote the development of a sustainable environment and the improvement of the quality of life by designing technology solutions beneficial to a dynamic world;
5. To adopt a faculty development program that is responsive to the continuing development and engagement of faculty in research, technopreneurship, community service and professional development activities both in the local and international context;
6. To implement a facility development program that promotes a continuing acquisition of state of the art facilities that are at par with leading engineering and architecture schools in the Asia Pacific region; and,
7. To sustain a strong partnership and linkage with institutions, industries, and professional organizations in both national and international levels.
Relationship of the Program Educational Objectives to the Vision-Mission of the University and the College of Engineering & Architecture:
Electronics Engineering Program Educational Outcomes (PEOs):
Within a few years after graduation, our graduates of the Electronics Engineering program are expected to have:
Vision-Mission
Christ-Centeredness
Integrity Excellence Community Societal
Responsibility
1. Practiced their profession
2. Shown a commitment to life-long learning
3. Manifested faithful stewardship
Relationship of the Electronics Engineering Program Outcomes to the Program Educational Objectives:
Electronics Engineering Student Outcomes (SOs): At the time of graduation, BS Electronics Engineering program graduates should be able to:
PEOs
1 2 3
a) Apply knowledge of mathematics, physical sciences, and engineering sciences to the practice of Computer Engineering.
b) Design and conduct experiments, as well as to analyze and interpret data
c) Design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability, in accordance with standards
d) Function on multidisciplinary teams
e) Identify, formulate and solve engineering problems
f) Have an understanding of professional and ethical responsibility
g) Demonstrate and master the ability to listen, comprehend, speak, write and convey ideas clearly and effectively, in person and through electronic media to all audiences.
h) Have broad education necessary to understand the impact of engineering solutions in a global, economic, environmental, and societal context
i) Recognition of the need for, and an ability to engage in life-long learning and to keep current of the development in the field
j) Have knowledge of contemporary issues
k) Use the techniques, skills, and modern engineering tools necessary for engineering practice.
l) Have knowledge and understanding of engineering and management principles as a member and leader in a team, to manage projects and in multidisciplinary environments.
COURSE SYLLABUS
Course Title: Electronic Devices and Circuits Laboratory Course Code: ELECDEVL
Course Credit: 1 unit Year Level: 3RD year
Co-requisite: ELECDEV Course Calendar: 1ST semester, AY2016-2017
Course Description:
This course deals with the quantum mechanics of solid state electronics such as diode and transistors (BJT and FET). It also
focus on the analysis and interpretation of the characteristics and behavior of diodes and transistor (FET and BJT). Specifically, this
class will provide the students with the basic engineering concepts important in the design and analysis of any electronic system.
These fundamentals will prepare the students to higher electronic engineering courses such as industrial electronics, advance
electronics and electronics circuit design.
Course Outcomes (COs): After completing this course, the students should be able to:
Relationship to the Program Outcomes:
a
b
C
D e f g h I j k l
1) Analyze the behavior of a solid state device like diodes and
transistors use in different configuration like regulators,
rectifiers, wave shapers, etc. E E E E E E
2) Design a simple electronic device such as variable power
supply that implements different solid state device like diodes
and transistors. D D D D D D
COURSE ORGANIZATION
Time Frame
Hours Course Topics Course
Outcomes Teaching Learning
Activities
Assessment Tools
Resources
Week 1
3
Multimeter for Resistance, Current, and Voltage measurement and Diode Testing
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 2
3
Measurement of AC Voltage with an Oscilloscope
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 3
3
Semiconductor PN Diode and Zener Diode Characteristics
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 4
3
Half-Wave, Full-wave, and Bridge Rectifiers
CO1
Discussion of the
laboratory experiment
On the spot Question and Answer
References 1, 2, 3, 4
Hands on Experiment
Actual troubleshooting
Written Report
Week 5
3
Rectifiers, Filters, and Ripple
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 6
3
Diode Limiter
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
PRELIM EXAMAMINATION
Week 8
3
Bipolar Transistor Testing and Biasing
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 9
3
Current Gains on Transistors and Characteristics of Common Emitter and Common Collector
CO1
Discussion of the
laboratory experiment
Hands on
On the spot Question and Answer
Actual
References 1, 2, 3, 4
Experiment
troubleshooting
Written Report
Week 10
3
Common Base Amplifier
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 11
3
Common Emitter Amplifier
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 12
3
Common Collector Amplifier
CO1 CO2 CO3
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
MIDTERM EXAMINATION
Week 14
3
RC Coupled Multistage Amplifier
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
References 1, 2, 3, 4
Written Report
Week 15
3
Testing JFETs
CO1
Discussion of the
laboratory experiment
Hands on Experiment
On the spot Question and Answer
Actual troubleshooting
Written Report
References 1, 2, 3, 4
Week 16-18
9
Project, Research Paper
CO1 CO2
Creation of a
working prototype utilizing all the electronic devices used in ELECDEVL.
On the spot Question and Answer
Actual troubleshooting
Written Report
Circuit Design
References 1, 2, 3, 4
FINAL EXAMINATION
Course References:
A. Basic Readings
[1] Boylestad, Robert (2013). Electronic devices and circuit theory. Pearson Education, Boston.
B. Extended Readings (Books, Journals) [2] Floyd, Thomas L. (2012). Electronic devices: conventional current version. Pearson Education, Boston [3] Neamen, Donald A. (2010). Microelectronics: circuit analysis and design. McGraw-Hill, New York [4] Razavi, Behzad (2008). Fundamentals of microelectronics. John Wiley, New Jersey
C. Web References
http://www.electronics-tutorials.ws/ http://www.electronics-tutorials.com/basics/basic-electronics.htm http://www.abcofelectronics.com/
Course Requirements and Policies
a. 3 Major Exams(PRELIMS, MIDTERMS, FINALS) b. Experiment Written Reports c. Research Papers, Project d. Maximum Allowable Absences: 10 (held 3 times a week); 7 (held 2 times a week)
Aside from academic deficiency, other grounds for failing grade are: 1. Grave misconduct and/or cheating during examinations. 2. A failing academic standing and failure to take graded exams. 3. Unexcused absences of more than the maximum allowable absences per term.
Grading System:
Class Standing (Quizzes, Seatworks, Assignments, etc.) 60% 3 Major Exams 40% Total 100% Passing Grade: 60%
CAMPUS++ COLLEGE ONLINE GRADING SYSTEM
Legend: (All Items in Percent) CSA Class Standing Average for All Performance Items (Cumulative) P Prelim Examination Score M Midterm Examination Score F Final Examination Score MEA Major Exam Average PCA Prelim Computed Average MCA Midterm Computed Average FCA Final Computed Average Computation of Prelim Computed Average (PCA)
CSA =
MEA = P PCA = (60%)(CSA) + (40%)(MEA) Computation of Midterm Computed Average (MCA)
CSA =
MEA =
MCA = (60%)(CSA) + (40%)(MEA) Computation of Final Computed Average (FCA)
CSA =
MEA =
FCA = (60%)(CSA) + (40%)(MEA) Passing Percent Average: 50 Transmutation Table
6.00 Failure due to absences
8.00 Unauthorized or unreported withdrawal Note: A student's Computed Average is a consolidation of Class Standing Percent Average and Major Exam Percent Average.
Date Revised: Date Effectivity: Prepared By: Checked By: Approved By:
May 16, 2016 June 2016 Engr. Adel Soccoro I. Parungao ECE Faculty
Engr. Steven T. Caraan Chairperson, ECE Department
Dr. Ma. Doris C. Bacamante Dean, College of Engineering and Architecture