Bachelor of Science in Electronics Engineering

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ANNEX 1 -PROFILE OF DUTIES AND COMPETENCIES OF ELECTRONICS AND COMMUNICATION ENGINEER
(ENTRY LEVEL)
DUTIES
COMPETENCIES
A. Electronics
Engineering
Practice
A.1 Abide by
engineering
practice with
highest integrity
A.2
Conceptualize,
Analyze &
Design
A.3 Generate
technical
specification
A.1.1 Familiarize
with EcE Law, 2004,
RA 9292
A.1.2 Observe
Laws, Contracts and
Ethics
A.1.3 Observe
International and
Local Patent Law,
WIPO
A.1.4 Comply with
OSI, ISO and other
standards
A.1.5 Apply
related
industry
standards
A.1.6 Apply
Philipine
Electronics
Code
A.2.1 Signal
Processing System
A.2.2 Analog and
Digital Electronics
System.
A.2.3
Communication
Systems
A2.4 ElectroAcoustics System
A.2.5
Broadcast
System
A 2.6
Instrument
ation
A.2.7 Control
System.
A 2.8 Industrial
Electronics
A.2.9 Power
Electronics
A.2.10 Electronics
Devices and
Systems Test
Equipment
A.3.1 Translate
engineering
solutions into
product and/or
process
A.3.2 Verify
products and/or
processes in
conformity to given
technical
specification
A.3.3 Define and
Evaluate Safety &
Security Standards
A.3.4 Estimate
impact of errors and
tolerances
A.3.5 Define
Proof of
performance
(documentat
ion)
18
A.4 Conduct
engineering
evaluation,
experiment, and
investigation
A.4.1 Set up
prototype,
experiment, and
working model
A.4.2 Identify
system strength and
weakness
A.4.3 Analyze
failure
A.4.4 Evaluate and
validate EcE product
performance
A.4.5
Recommend
product
improvemen
t
B.1.2 Formulate
problem statement
B.1.3 Identify
appropriate
methodology
B.1.4 Define
research paradigm
B.1.5
Conduct
resource
analysis
A.4.6
Describe
mechanics
of safety
incident
investigatio
n
A.4.7 Determine
product reliability
B. RESEARCH
AND
DEVELOPMENT
B.1. Apply basic
methods of
Research and
Development
B. 2. Engage in
Research and
Development
Program
B.1.1 Communicate
with industry,
practitioners,
institutions, and
other stakeholders.
B.2.1 Identify
research focus
conducts tests and
identifies information
for general
application
B.2.2 Measure and
record research
projects
methodically.
B.2.3. Analyze
recorded results
and develop
conclusions
B.2.4 Reports
results with analysis
of their significance
to the underlying
engineering
problems
B.2.5 Write
and present
technical
reports/pape
rs (for
possible
publication)
19
C. MANAGE
SIGNIFICANT
PROJECTS
C.1 Interpret
project scope
C.2 Explain
quality, safety
and risk
management
C.3 Discuss
plans,
programs,
strategies, and
budget.
C.1.1 Determine and
examine each
project element
focused to EcE
engineering.
C.2.1 Identify quality
standards and
performance
measurement
C.3.1 Enumerate
project workflow
design tasks
C.4.1 Explain
system architecture
C.4 Integrate
Systems
C.1.2 Explain project
management
process
C.1.3 Identify
weaknesses,
strength,
opportunity and
threat in a project
case study
C.1.4 Describe
given internal and
external
environmental scan
C.2.2 Prepare
reports and
documentation on
quality and controls
conformances
C.2.3 Identify
hazards and
potential safety
issues and
preventions
C.2.4 Identify
potential problem
and risk and
proactive measure
C.3.2 Explain plans
and programs
C.3.3 Describe the
merit of strategies
in a case study
C.3.4 Identify
resources and
budget in a case
study
C.4.2 Interpret block
diagrams,
schematics and
system components
C.4.3 Explain
various techniques
of interfacing
systems
C.4.4 Analyze the
merit of a given
integrated system in
terms of operational
needs, cost and
timely delivery
C.1.5
Evaluate
existing
(technical)
system in
engineering
C.3.5
Formulate
tasks
schedule
using
various time
managemen
t tools
C.3.6
Identify and
appreciate
performanc
e indicators
20
C.5 Implement
changes in
system
C.5.1 Describe the
system
C.5.2 Assess
performance of the
system.
C.5.3 Identify
system
performance
parameters.
D.1 Apply Time
Motion Study
D.2 Conduct
Statistical Process
Analysis
D.3 Perform SWOT
Analysis
D.4 Utilize Quality
Control Tools
D.7 Perform
Measurement
and System
Analysis
D.8 Utilize
Metrology
D.9 Practice
Production
Planning and
Control
C.5.4 Assess given
systems
performance review.
C.5.5
Explain
given
corrective
measures
and
improvemen
ts
D.5 Practice
Process and
Change
Management
D.6.
Formulate
Design of
Experiment
C.5.6
Identify
opportuniti
es for
workplace
change
D OPERATION
MANAGEMENT
21
ANNEX II – SAMPLE CURRICULUM MAP
RELATIONSHIP OF THE COURSES TO THE PROGRAM OUTCOMES
Program Outcomes
The Bachelor of Science in Electronics Engineering (BSECE) program must produce graduates who shall be able to:
a.
b.
c.
d.
e.
f.
g.
h.
i.
j.
k.
l.
apply knowledge of mathematics and science to solve chemical engineering problems;
design and conduct experiments, as well as to analyze and interpret data;.
design a system, component, or process to meet desired needs within realistic constraints, in accordance with
standards;
function in multidisciplinary and multi-cultural teams;
identify, formulate, and solve chemical engineering problems;
understand professional and ethical responsibility;.
communicate effectively complex chemical engineering activities with the engineering community and with society at
large;
understand the impact of chemical engineering solutions in a global, economic, environmental, and societal context;
recognize the need for, and engage in life-long learning;
know contemporary issues;
use techniques, skills, and modern engineering tools necessary for electronics engineering practice;
know and understand engineering and management principles as a member and leader of a team, and to manage
projects in a multidisciplinary environment;
22
Sample Curriculum Map
LEGEND
23
Mathematics
Units
College Algebra
3
Advanced Algebra
2
Plane and Spherical
Trigonometry
3
Analytic Geometry
2
Solid Mensuration
2
Differential Calculus
4
Integral Calculus
4
Differential Equations
3
Probability and Statistics
3
Natural/Physical Sciences
Units
General Chemistry 1
2
General Chemistry 1 Lab
1
Physics 1
3
Physics 1 Lab
1
Physics 2
3
Physics 2 Lab
1
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Basic Engineering Sciences
Units
Engineering Drawing
Computer-Aided Drafting
Computer Fundamentals &
Programming
Statics of Rigid Bodies
Dynamics of Rigid Bodies
Mechanics of Deformable Bodies
Engineering Economy
Engineering Management
Environmental Engineering
Safety Management
Allied Courses
1
1
2
a
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I
3
2
3
3
3
2
1
E
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Units
a
I
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Discrete Mathematics
3
Basic Thermodynamics
2
Fundamentals of Materials Science
and Engineering
3
b
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c
d
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Professional Courses
Advanced Engineering
Mathematics for ECE
Numerical Methods
Un
its
3
3
Numerical Methods Lab
1
ECE Laws Contract and Ethics
3
Circuits 1
3
Circuits 1 lab
1
Circuits 2
3
Circuits 2 Lab
1
Electronic Devices and Circuits
3
Electronic Devices and Circuits
Lab
1
Electronic Circuit Analysis and
Design
3
Electronic Circuit Analysis and
Design Lab
1
Industrial Electronics
3
Industrial Electronics Lab
1
Electromagnetics
3
Signals, Spectra, Signal
Processing
3
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Professional Courses
Signals, Spectra, Signal
Processing Lab
Un
its
1
Principles of Communications
3
Principles of Communications Lab
1
Energy Conversion
3
Energy Conversion Lab
1
Digital Communications
3
Digital Communications Lab
1
Logic Circuits and Switching
Theory
3
Logic Circuits and Switching
Theory Lab
1
Transmission Media and Antenna
System
3
Transmission Media and Antenna
System Lab
1
Microprocessor Systems
3
Microprocessor Systems Lab
1
Feedback and Control Systems
3
Feedback and Control Systems
Lab
1
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b
c
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Data Communications
3
Data Communications Lab
1
Vector Analysis
3
Practicum /Thesis 1 –1st sem, 5th
year
1
Practicum /Thesis 2 –1st sem, 55h
year
1
Seminar and Field Trips
ECE ELECTIVE 1
ECE ELECTIVE 2
ECE ELECTIVE 3
ECE ELECTIVE 4
1
3
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Annex III- Sample Course Specification
BSECE Program Outcomes
By the time of graduation, the students of the program shall have the ability to:
a) apply knowledge of mathematics and science to solve Electronics
engineering problems;
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, in accordance with standards;
d) function in multidisciplinary and multi-cultural teams;
e) identify, formulate, and solve Electronics engineering problems;
f) understand professional and ethical responsibility;
g) communicate effectively Electronics engineering activities with the
engineering community and with society at large;
h) understand the impact of Electronics engineering solutions in a global,
economic, environmental, and societal context
i) recognize the need for, and engage in life-long learning
j) know contemporary issues;
k) use techniques, skills, and modern engineering tools necessary for
Electronics engineering practice;
l) know and understand engineering and management principles as a
member and leader of a team, and to manage projects in a
multidisciplinary environment;
Course Name:
Course
Description
Number of Units
Number of Contact
Hours per week
Prerequisite
Course Outcomes
ELECTRONIC DEVICES AND CIRCUITS (LECTURE)
Introduction to quantum mechanics of solid state electronics; diode
and transistor characteristics and models (BJT and FET); diode
circuit analysis and applications; transistor biasing; small signal
analysis; large signal analysis; transistor amplifiers; Boolean logic;
transistor switch.
3 units
3 hours
Physics 2; Integral Calculus
Upon completion of the course, the student must be able to:
1. Explain the basic concept of atomic theory and relate it to the
characteristics of materials (POa, POe, POi)
2. Discuss the construction, basic operation, characteristics and
configurations of semiconductor diodes (POa, POb, POe, POi)
3. Analyze the function of semiconductor diode in some practical
applications (POa, POb, POe, POi)
4. Discuss the basic structure, operation and characteristics of Bipolar
29
Junction Transistors (BJT) (POa, POb, POe, POi)
5. Discuss the different configurations, DC Biasing and some practical
applications of BJT (POa, POb, POe, POi)
6. Discuss the basic structure, operation and characteristics of Field
Effect Transistors (FET) (POa, POb, POe, POi)
7. Discuss the different configurations, DC Biasing and some practical
applications of FET (POa, POb, POe, POi)
30
1. Introduction of Semiconductors
Discuss the concept of atomic theory, and the subatomic particles of the atom. (CO1)
Identify and differentiate conductors, semiconductors and insulators. (CO1)
Discuss the crystal structure of the common semiconductor materials and ions formed from covalent
bonding. (CO1)
Explain the general characteristics of three important semiconductor materials: Ge, Si and GaAs. (CO2)
Explain the concept of conduction in semiconductors using electron and hole theory. (CO2)
Differentiate the difference between n – type and p – type materials. (CO2)
2. Diode Equivalent Circuits
Explain what happens in a diode during no bias, forward bias, and reverse bias conditions. (CO2)
Identify the three equivalent model of the diode and plot its corresponding characteristic curves. (CO2)
Calculate current and voltage for circuits with diode connected in series, parallel or series–parallel
using the different equivalent diode models. (CO2)
Explain the diagram of a basic power supply and determine the waveform produced by each block.
(CO3)
3. Wave Shaping Circuits
Explain the process of rectification using diodes to establish a pulsating dc from a sinusoid ac input.
(CO3)
Calculate and determine the output waveform of half-wave and full-wave rectified signal. (CO3)
Calculate and determine the resulting output waveform of a bridge type, transformer-coupled and
center-tapped transformer rectifier. (CO3)
Design a clipper circuit given an output and an input. (CO3)
Analyze the output response of a clipper circuit. (CO3)
Design a clamper circuit given an output and an input. (CO3)
Analyze the output response of a clamper circuit. (CO3)
4. Special Diode Application
Course
Outline
Interpret the characteristic curves of a zener diode. (CO2)
Draw the equivalent circuit of a zener diode. (CO2)
Explain how a zener diode produces a constant level of dc voltage during reverse bias condition. (CO2)
Solve circuits with zener diodes. (CO2)
Discuss the basic characteristics and operation of LED’s, photodiodes, Schottky, varactor, pin, step
recovery, tunnel, and laser diodes. (CO2)
5. Power Supply And Voltage Regulation
Discuss how a voltage input is amplified with the use of capacitors and diodes. (CO3)
Compute the ripple voltage produced by filtering a rectified output with the use of a capacitor. (CO3)
Discuss how a ripple is produced. (CO3)
6. Bipolar Junction Transistor
Describe the basic structure of the BJT.
Explain how a BJT is biased and discuss the transistor currents and their relationships. (CO4)
Discuss transistor parameters and characteristics and use this to analyze a transistor circuit. (CO4)
Identify and differentiate the schematic symbol and construction of an npn and pnp transistor. (CO4)
Discuss how a transistor amplifies an input voltage/ current. (CO5)
Discuss the operation of a transistor in cut-off and saturation region. (CO4)
Discuss the operation of a transistor in common configuration: common base, common collector,
and common emitter. (CO5)
Measure the important voltage levels of a BJT configuration and use them to determine whether
the network is operating properly. (CO4)
Analyze the saturation and cut-off conditions of a BJT network and the expected voltage and current
levels established by each condition. (CO4)
Apply proper biasing of a transistor to ensure proper operation in the active region. (CO5)
Perform dc analysis of BJT using different biasing configurations. (CO5)
7. Small- Signal Analysis (BJT)
Use BJT in an application where its amplification and switching capabilities are used. (CO5)
31
8. Field Effect Transistor
Describe the basic structure of the JFET. (CO6)
Explain how a JFET is biased and discuss the transistor currents and their relationships. (CO6)
Discuss transistor parameters and characteristics and use this to analyze a transistor circuit. (CO6)
Identify and differentiate the schematic symbol and construction of a p – channel and an n- channel
JFET. (CO6)
Sketch the transfer characteristics from drain characteristics of a JFET. (CO6)
Discuss the characteristics and operation of a D-MOSFET. (CO6)
Discuss the characteristics and operation of an E-MOSFET. (CO6)
Discuss the differences between the dc analyses of the various types of FET’s. (CO7)
Apply proper biasing of a FET to ensure proper operation in the desired region. (CO7)
Perform dc analysis of JFET, MOSFET, and MESFET using different biasing configurations. (CO7)
9. Small-Signal and Large Analysis (FET)
Solve combination of FET’s in a single network (CO7)
Use JFET in an application where its transfer characteristics are used. (CO7)
32
SAMPLE OR SUGGESTED CURRICULUM ALIGNED TO OUTCOMES-BASED
EDUCATION (OBE) FOR BACHELOR OF SCIENCE IN ELECTRONICS
ENGINEERING
PROGRAM SPECIFICATIONS
I. Program Description
1.1 Degree Name:
Graduates of the program shall be given the Degree of Bachelor of Science in
Electronics Engineering (BSECE)
1.2 Nature of the Field of Study
Electronics Engineering is a branch of engineering that integrates available and
emerging technologies with knowledge of mathematics, natural, social and
applied sciences to conceptualize, design, and implement new, improved, or
innovative electronic, computer and communication systems, devices, goods,
services and processes.
Refer to Annex I for the Competency Standards for Electronics Engineering
practice.
1.3 Program Educational Objectives
Program Educational Objectives (PEOs) are broad statements that describe the
career and professional accomplishments that the program is preparing
graduates to achieve within a few years of graduation. PEOs are based on the
needs of the program’s constituencies and these shall be determined, articulated,
and disseminated to the general public by the unit or department of the HEI
offering the BSECE program. The PEOs should also be reviewed periodically for
continuing improvement.
1.4 Specific Professions/careers/occupations for graduates
The scope of the practice of an Electronics Engineer is defined in the Electronics
Engineering Law of 2004 or R.A. 9292. The scope and nature of practice of the
Electronics Engineer shall embrace and consist of any work or activity relating to
the application of engineering sciences and/or principles to the investigation,
analysis, synthesis, planning, design, specification, research and development,
provision, procurement, marketing and sales, manufacture and production,
construction and installation, tests/measurements/control, operation, repair,
servicing, technical support and maintenance of electronic components, devices,
products, apparatus, instruments, equipment, systems, networks, operations and
processes in the fields of electronics, including communications and/or
telecommunications, information and communications technology (ICT),
computers and their networking and hardware/firmware/software development
and applications, broadcast/broadcasting, cable and wireless television,
consumer and industrial electronics, electro- optics/photonics/opto-electronics,
electro-magnetics, avionics, aerospace, navigational and military applications,
medical electronics, robotics, cybernetics, biometrics and all other related and
convergent fields; it also includes the administration, management, supervision
and regulatory aspects of such works and activities; similarly included are those
1
teaching and training activities which develop the ability to use electronic
engineering fundamentals and related advanced knowledge in electronics
engineering, including lecturing and teaching of technical and professional
subjects given in the electronics engineering and electronics technician
curriculum and licensure examinations.
1.5 Allied Fields
The following programs may be considered as allied to Electronics Engineering:
Electrical Engineering
Computer Engineering
Information Technology
Computer Science
II. Program/ Student Outcomes
The minimum standards for the BS Electronics Engineering program are expressed
in the following minimum set of BSECE program outcomes.
2.1 BSECE Program/ Student Outcomes
By the time of graduation, the students of the program shall have the ability to:
a) apply knowledge of mathematics and science to solve Electronics
engineering problems;
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, in accordance with standards;
d) function in multidisciplinary and multi-cultural teams;
e) identify, formulate, and solve Electronics engineering problems;
f) understand professional and ethical responsibility;
g) communicate effectively Electronics engineering activities with the
engineering community and with society at large;
h) understand the impact of Electronics engineering solutions in a global,
economic, environmental, and societal context
i) recognize the need for, and engage in life-long learning
j) know contemporary issues;
k) use techniques, skills, and modern engineering tools necessary for
Electronics engineering practice;
l) know and understand engineering and management principles as a
member and leader of a team, and to manage projects in a
multidisciplinary environment;
III. Sample Performance Indicators
Performance Indicators are specific, measurable statements identifying the
performance(s) required to meet the outcome; confirmable through evidence. Below
is a sample of Performance Indicators for Program/ Student Outcome (a) indicated in
Section 6.1. Each HEI is expected to develop the Performance Indicators of each of
the Program/ Student Outcomes which is further aligned with the HEI’s Objectives.
2
a
Program/ Student Outcomes
Apply
knowledge
of
mathematics and science to
solve Electronics Engineering
problems
1
2
Performance Indicators
Distinguish relevant information; realize
the meaning of the collected information;
ability to understand the theoretical
concepts.
Formulate strategies for analyzing and
solving problem-based questions; apply
the collected information to the problem.
IV. Program Assessment and Evaluation
Program Assessment refers to one or more processes that identify, collect, and
prepare data to evaluate the attainment of Program Outcomes and Program
Educational Objectives.
In the case of Program Outcomes Assessment, the defined Performance Indicators
shall be connected to Key Courses (usually the Demonstrating or “D” courses in the
Curriculum map), and an appropriate Assessment Methods (AM) may be applied.
These methods may be direct or indirect depending on whether the demonstration of
learning was measured by actual observation and authentic work of the student or
through gathered opinions from the student or his peers. Refer to the sample table
below:
Performance Indicator
1
Key Courses
Assessment
Methods
Standardized
Exam
Distinguish relevant information; Advanced
realize the meaning of the collected Engineering
information; ability to understand the Mathematics;
theoretical concepts.
Electromagnetics
2 Formulate strategies for analyzing Signal Spectra and
Locally
and
solving
problem-based Signal Processing;
Developed
questions; apply the collected Feedback and
Exams
information to the problem.
Control Systems
Sample Matrix Connecting Performance Indicators with Key Courses and
Assessment
For the Assessment of Program Educational Objectives, the stakeholders of the
program have to be contacted through surveys or focus group discussion to obtain
feedback data on the extent of the achievement of the PEOs.
Program Evaluation pertains to one or more processes for interpreting the data and
evidence accumulated from the assessment. Evaluation determines the extent at
which the Program Outcomes and the Program Educational Objectives are achieved
by comparing actual achievement versus set targets and standards. Evaluation
results in decisions and actions regarding the continuous improvement of the
program. Refer to the sample table below:
Key Courses
Assessment Methods
Target and Standards
Advanced
Engineering
Standardized Exams
70% of the students get a
Mathematics
rating of at least 70%
Feedback
and
Control
Locally developed Exams
60% of the students get a
Systems
rating of at least 70%
Sample Matrix Connecting Assessment Methods with Set Targets and Standards
3
Other Methods of Program Assessment and Evaluation may be found in the CHED
Implementation Handbook for Outcomes-Based Education (OBE) and Institutional
Sustainability Assessment (ISA).
V. Continuous Quality Improvement
There must be a documented process for the assessment and evaluation of program
educational objectives and program outcomes.
The comparison of achieved performance indicators with declared targets or
standards of performance should serve as basis for the priority projects or programs
for improving the weak performance indicators. Such projects and programs shall be
documented as well as the results of its implementation. This regular cycle of
documentation of projects, programs for remediation and their successful
implementation shall serve as the evidence for Continuous Quality Improvement.
CURRICULUM
I. Curriculum Description
The BSECE curriculum is designed to develop engineers who have a background in
mathematics, natural, physical and allied sciences. As such, the curriculum contains
courses in mathematics, science and engineering fundamentals with emphasis on
the development of analytical and creative abilities. It also contains language
courses, social sciences and humanities. This is to ensure that the electronics
engineering graduate is articulate and is able to understand the nature of his/her
special role in society and the impact of his/her work on the progress of civilization.
The curriculum is designed to guarantee a certain breadth of knowledge of the
BSECE disciplines through a set of core courses. It ensures depth and focus in
certain disciplines through areas of specialization. It provides a recommended track
of electives that HEIs may adopt or develop. The curriculum develops the basic
engineering tools necessary to solve problems in the field of Electronics Engineering.
This enables the graduate to achieve success in a wide range of career.
Institutional electives are prescribed in order to give a certain degree of specialization
so that institutions of learning will develop strengths in areas where they already
have a certain degree of expertise.
Emphasis is given to the basic concepts. Previously identified courses are
strengthened to take into account new developments. New courses and/or topics are
introduced so that the student’s knowledge of the fundamentals may be enhanced.
This is to allow the student to achieve a degree of knowledge compatible with
international standards.
4
II. Curriculum
2.1 Sample Curriculum
Table below summarizes the minimum number of lecture and laboratory hours and
its corresponding minimum number of credit units. HEIs are expected to design
their curriculum that suits their respective areas of specializations as suggested in
the Track Electives.
Classification/ Field / Course
Minimum Hours /week
Lecture
Laboratory
Minimum
Credit Units
I. TECHNICAL COURSES
A. Mathematics
College Algebra
3
0
3
Advanced Algebra
2
0
2
Plane and Spherical Trigonometry
3
0
3
Analytic Geometry
2
0
2
Solid Mensuration
2
0
2
Differential Calculus
4
0
4
Integral Calculus
4
0
4
Differential Equations
3
0
3
Probability and Statistics
3
0
3
26
0
26
General Chemistry
3
3
4
Physics 1
3
3
4
Physics 2
3
3
4
9
9
12
Engineering Drawing
Computer Fundamentals and
Programming
0
3
1
0
6
2
Computer-Aided Drafting
0
3
1
Static of Rigid Bodies
3
0
3
Dynamics of Rigid Bodies
2
0
2
Mechanics of Deformable Bodies
3
0
3
Engineering Economy
3
0
3
Engineering Management
3
0
3
Environmental Engineering
2
0
2
Safety Management
1
0
1
17
12
21
Sub - Total
B Physical Sciences
Sub - Total
C. Basic Engineering Sciences
Sub - Total
5
Classification/ Field / Course
Minimum Hours /week
Lecture
Laboratory
Minimum
Credit Units
D. Allied Subjects
Discrete Mathematics
3
0
3
Basic Thermodynamics
Fundamentals of Materials Science
and Engineering
2
0
2
3
0
3
8
0
8
3
0
3
Numerical Methods
3
3
4
ECE Laws Contract and Ethics
3
0
3
Circuits 1
3
3
4
Circuits 2
3
3
4
Electronic Devices and Circuits
Electronic Circuit Analysis and
Design
3
3
4
3
3
4
Industrial Electronics
3
3
4
Electromagnetics
3
0
3
Signals, Spectra, Signal Processing
3
3
4
Principles of Communications
3
3
4
Energy Conversion
3
3
4
Digital Communications
3
3
4
Logic Circuits and Switching Theory
Transmission Media and Antenna
System
3
3
4
3
3
4
Microprocessor Systems
3
3
4
Feedback and Control Systems
3
3
4
Data Communications
3
3
4
Vector Analysis
Practicum /Thesis 1 –1st sem, 5th
year
Practicum /Thesis 2 –1st sem, 55h
year
3
0
3
0
3
1
0
3
1
Seminar and Field Trips
0
3
1
57
54
75
Sub - Total
E. Professional Courses
1. Core Courses
Advanced Engineering Mathematics
for ECE
Sub-total
6
Classification/ Field / Course
Minimum Hours /week
Lecture
Laboratory
Minimum
Credit Units
2. Technical Elective
ECE Elective 1
3
0
3
ECE Elective 2
3
0
3
ECE Elective 3
3
0
3
ECE Elective 4
3
0
3
12
0
12
Social Science 1
3
0
3
Social Science 2
3
0
3
Social Science 3
3
0
3
Social Science 4
Sub-total
3
0
3
12
0
12
Humanities 1
3
0
3
Humanities 2
3
0
3
Humanities 3
3
0
3
9
0
9
English 1
3
0
3
English 2
English 3 (Technical
Communications)
3
0
3
3
0
3
Pilipino 1
3
0
3
Pilipino 2
3
0
3
15
0
15
3
0
3
3
0
3
Sub-total
II. NON - TECHNICAL COURSES
A. Social Sciences
B. Humanities
Sub-total
C. Languages
Sub-total
D. Mandated Courses
Rizal's Life, Works and Writings
Sub-total
E. Physical Education
P.E. 1
2
P.E. 2
2
P.E. 3
2
P.E. 4
Sub-total
2
8
7
Classification/ Field / Course
Minimum Hours /week
Lecture
Laboratory
Minimum
Credit Units
F. National Service Training Program
NSTP1
0
0
3
NSTP2
Sub-total
0
8
0
3
6
GRAND TOTAL
207
Suggested Free or Track Elective Courses
The suggested Track Electives are designed for the HEIs to develop their areas of
specializations depending on their core competence and available facilities in the delivery of
the Program. Electives are not limited to the list. HEI may also adopt other elective courses
that could further improve in the attainment of the desired program/ student outcomes.
A. COMMUNICATIONS
Wireless Communication
Communications System Design
Navigational Aids
Broadcast Engineering
Advanced Electromagnetism (also for Micro electronics track)
DSP*
Telemetry*
RF Design System Level*
Mixed Signals-Systems Level*
Digital Terrestial XSM*
Compression Technologies*
B. MICROELECTRONICS TRACK
Advanced Electromagnetism
Introduction to Analog Integrated Circuits Design
Introduction to Digital VLSI Design
VLSI Test and Measurement
IC Packaging and Failure Analysis
Advanced Statistics (Also for Biotech/Biomedical track)*
Mixed Signals-Silicon Level*
RF Design-Silicon Level*
CAD-Tool Design*
Solid State Physics & Fabrication*
C. POWER ELECTRONICS TRACK
Introduction to Power Electronics
Power Supply Application
Semiconductor Devices for Power Electronics
Motor Drives and Inverters
Modeling and Simulation*
8
Digital Control System*
Optoelectronics*
Automotive Electronics*
D. BIOTECH/BIOMEDICAL ENGINEERING TRACK
Fundamentals of Biomedical Engineering
Physiology
Principles of Medical Imaging
Biomechanics
Biomaterials
Biophysical Phenomena
Advanced Statistics (Also for Microelectronics track)*
Telemetry*
Optoelectronics*
Embedded System*
Micro Electrical Mechanical System (MEMS)*
Nano Electrical Mechanical System (NEMS)*
E. INSTRUMENTATION AND CONTROL*
Mechatronics*
Robotics*
Modelling and Simulation*
Digital Control System*
Metrology*
MEMS (also for Biotech/Biomedical Engineering track)*
NEMS (also for Biotech/Biomedical Engineering track)*
Sensors Technology*
F. INFORMATION AND COMPUTING TECHNOLOGIES*
Computer Systems*
I/O Memory System*
Computer Systems Architecture*
Data Structure & Algorithm Analysis*
Computer Systems Organizations*
Structure of Program Language*
Operating Systems*
Digital Graphics, Digital Imaging and Animation*
Artificial Intelligence*
*The school may adopt and develop course specification for each course.
9
SUMMARY
Total no. of Hours
Lecture Laboratory
Summary:
Total No. of
Units
I. Technical Courses
A. Mathematics
26
0
26
B. Natural Sciences
9
9
12
C. Basic Engineering Sciences
17
12
21
D. Allied Courses
8
0
8
E. Professional Courses
57
54
75
12
132
0
72
12
154
A. Social Sciences
12
0
12
B. Humanities
9
0
9
C. Language
15
0
15
D. Life Works of Rizal
3
0
3
G. Electives
Technical Courses Sub-total
II. Non-Technical Courses
Physical Education
NSTP
Non-Technical Courses Sub-total
GRAND TOTAL
8
6
53
207
2.2 Program of Study
The institution may enrich the sample/model program of study depending on the
needs of the industry, provided that all prescribed courses required in the
curriculum outlines are offered and pre-requisites and co-requisites are complied
with.
The sample Program of Study listed below is meant for HEIs operating on a
Semestral System. HEIs with CHED approved trimester or quarter term systems
may adjust their courses and course specifications accordingly to fit their delivery
system, as long as the minimum requirements are still satisfied.
The HEIs are also encouraged to include other courses to fulfil their institutional
outcomes, as long as the total units for the whole program shall not exceed 240
units, including P.E., and NSTP.
10
FIRST YEAR
First Year- First Semester
No. of Hours
Subjects
lec
Total
units
lab
Prerequisite subjects
First Year
College Algebra
3
0
3 None
Plane and Spherical Trigonometry
3
0
3 None
General Chemistry
3
3
4 None
Engineering Drawing
0
3
1 None
English 1
3
0
3 None
Filipino 1
3
0
3 None
Social Science 1
3
0
3 None
P.E. 1
2 None
NSTP1
3 None
Total
18
6
25
First Year-Second Semester
No. of Hours
Total
Prerequisite subjects
units
lec
lab
2
0
2 College Algebra, Plane and
Spherical Trigonometry
2
2 College Algebra, Plane and
Spherical Trigonometry
3
3
4 College Algebra, Plane and
Spherical Trigonometry
2
0
2 College Algebra
Subjects
Analytic Geometry
Solid Mensuration
Physics 1
Advanced Algebra
Social Science 2
3
0
3
English 2
3
0
3
Filipino 2
3
0
3
P.E. 2
2
NSTP2
3
Total
18
3
24
11
SECOND YEAR
Second Year- First Semester
No. of Hours
Total
units
lec
lab
Prerequisite subjects
3
0
3 College Algebra
Subjects
Discrete Mathematics
Physics 2
3
3
4 Physics 1
Differential Calculus
4
0
Technical Communications
(English)
Computer Fundamentals and
Programming
Humanities 1
3
0
4 Analytic Geometry, Solid
Mensuration, Advanced Algebra
3
0
6
2 Second Year Standing
3
0
3
Social Science 3
3
0
3
P.E. 3
2
Total
19
9
24
Second Year- Second Semester
Subjects
Fundamentals of Material Science
and Engineering
Integral Calculus
No. of Hours
Total
lec
Lab units
Prerequisite subjects
3
0
3 General Chemistry, Physics 2
4
0
4 Differential Calculus
Probability and Statistics
3
0
3 College Algebra
Humanities 2
3
0
3
Social Science 4
3
0
3
Life and Works of Rizal
3
0
3
P.E. 4
2
Total
19
0
21
12
THIRD YEAR
Third Year- First Semester
No. of Hours Total
units
lec
lab
Prerequisite subjects
0
3
1 Third Year Standing
Subjects
Computer Aided Drafting
Circuits 1
3
3
Electronic Devices and Circuits
3
3
Vector Analysis
3
0
4 Prerequisite-Physics 2, Integral
Calculus,
Corequisite- Differential
Equations
4 Physics 2,
Integral calculus
3 Integral Calculus
Differential Equations
3
0
3 Integral Calculus
Statics of Rigid Bodies
3
0
3 Physics 1, Integral Calculus
Humanities 3
3
0
3
18
9
21
Total
Third Year- Second Semester
No. of Hours Total
units
lec
lab
Prerequisite subjects
2
0
2 Statics of Rigid Bodies
Subjects
Dynamics of Rigid Bodies
Mechanics of Deformable Bodies
3
0
3 Statics of Rigid Bodies
Advanced Engineering Mathematics
for ECE
Electromagnetics
3
0
3 Differential Equations
3
0
Circuits 2
3
3
3 Vector Analysis, Physics 2,
Integral calculus
4 Circuits 1
Electronic Circuit Analysis and
Design
Environmental Engineering
3
3
4 Electronic Devices and Circuits
2
0
2 General Chemistry
Safety Management
1
0
1 Third Year Standing
20
6
Total
22
13
FOURTH YEAR
Fourth Year- First Semester
Subjects
Signals, Spectra, Signal Processing
Principles of Communications
Energy Conversion
No. of Hours Total
units
Prerequisite subjects
lec
lab
3
3
4 Probability and Statistics,
Advanced Engineering
Mathematics for ECE
3
3
4 Electronic Circuit Analysis and
Design, Advanced Engineering
Math
3
3
4 Electromagnetics, Circuits 2
Basic Thermodynamics
2
0
2 Integral Calculus, Physics 2
Engineering Economy
3
0
3 Third year Standing
ECE Elective 1(Tracks)
3
0
17
9
Total
3 Electronic Circuit Analysis and
Design
20
Fourth Year- Second Semester
No. of Hours Total
units
Prerequisite subjects
lec
lab
3
0
3 Third Year Standing
Subjects
Engineering Management
Digital Communications
3
3
4 Principles of Communications
Industrial Electronics
3
3
Logic Circuits and Switching Theory
3
3
4 Electronic Circuit Analysis and
Design
4 Electronic Devices and Circuits
Numerical Methods
3
3
ECE Elective 2 (Track)
3
0
18
12
Total
4 Advanced Engineering Math,
Computer Fundamentals and
Programming
3
22
14
FIFTH YEAR
Fifth Year- First Semester
Subjects
Feedback and Control Systems
Transmission Media and Antenna
Systems
Microprocessor Systems
Practicum/ Thesis 1
No. of Hours Total
units
Prerequisite subjects
lec
lab
3
3
4 Advance Engineering,
Mathematics for ECE
3
3
4 Digital Communications,
Electromagnetics
3
3
4 Logic Circuits and Switching
Theory,
Computer Fundamentals and
Programming,
Electronic Circuit Analysis and
Design
0
3
1 5th year Standing
ECE Elective 3 (Track)
3
0
3
ECE Laws, Contracts and Ethics
3
0
3 5th Year Standing
15
12
Total
19
Fifth Year- Second Semester
No. of Hours Total
units
lec
lab
0
3
1
Subjects
Seminars and Field Trips
Prerequisite subjects
Data Communications
3
3
4 Digital Communications
ECE Elective 4 (Track)
3
0
3
Practicum/Thesis 2
0
3
1 Practicum Thesis 1
6
9
9
Total
GRAND TOTAL
207
2.3 Thesis/Research/project requirement shall focus on the recommended track
electives but not limited to:
11.3.1 Communications
11.3.2 Microelectronics
11.3.3 Power Electronics
11.3.4 Biotech/ Biomedical Engineering
11.3.5 Instrumentation and Control
11.3.6 Information and Computing Technologies
15
III. On-the-job-training / practicum requirement
3.1 On –the-job-training (OJT) is optional depending on the discretion of the HEIs.
The minimum number of hours for OJT is 240 hours should the HEIs opt to offer
OJT as a course.
3.2 Practicum for the Electronics Engineering students shall be done in any of the
following industry:
Broadcasting
Telecommunication
Semiconductor
Computer Systems
Instrumentation and Telemetry
Automation, Feedback, Process Control, Robotics, and
Mechatronics
Industrial/ Manufacturing
Medical/Biomedical Electronics
Government Agencies such as DOTC, DOST, etc. or any industry
that requires services related to the specializations of an
Electronics Engineer
IV. Sample Curriculum Map
Refer to Annex II for the Minimum Program Outcomes and a Sample Curriculum
Map. The HEI may develop their own Curriculum Map.
V. Description of Outcomes Based Teaching and Learning
Outcomes-based teaching and learning (OBTL) is an approach where teaching and
learning activities are developed to support the learning outcomes (University of
Hong Kong, 2007). It is a student-centered approach for the delivery of educational
programs where the curriculum topics in a program and the courses contained in it
are expressed as the intended outcomes for students to learn. It is an approach in
which teachers facilitate and students find themselves actively engaged in their
learning.
Its primary focus is the clear statement of what students should be able to do after
taking a course, known as the Intended Learning Outcomes (ILOs). The ILOs
describe what the learners will be able to do when they have completed their course
or program. These are statements, written from the students' perspective, indicating
the level of understanding and performance they are expected to achieve as a result
of engaging in teaching and learning experience (Biggs and Tang, 2007). Once the
ILOs have been determined, the next step in OBTL is to design the Teaching /
Learning Activities (TLAs) which require students to actively participate in the
construction of their new knowledge and abilities. A TLA is any activity which
stimulates, encourages or facilitates learning of one or more intended learning
outcome. The final OBTL component is the Assessment Tasks (ATs), which measure
how well students can use their new abilities to solve real-world problems, design,
demonstrate creativity, and communicate effectively, among others. An AT can be
any method of assessing how well a set of ILO has been achieved.
A key component of a course design using OBTL is the constructive alignment of
ILOs, TLAs, and ATs. This design methodology requires the Intended Learning
Outcomes to be developed first, and then the Teaching / Learning Activities and
16
Assessment Tasks are developed based on the ILOs.¬ (Biggs, 1999).
“Constructive” refers to the idea that students construct meaning through relevant
learning activities; “alignment” refers to the situation when teaching and learning
activities, and assessment tasks, are aligned to the Intended Learning Outcomes by
using the verbs stipulated in the ILOs. Constructive alignment provides the “how-to”
by stating that the TLAs and the assessment tasks activate the same verbs as in the
ILOs. (Biggs and Tang, 1999)
The OBTL approach shall be reflected in the Course Syllabus to be implemented by
the faculty.
VI. Sample Syllabi for Selected Courses
The Course Syllabus must contain at least the following components:
6.1
General Course Information (Title, Description, Code, Credit Units,
Prerequisites)
6.2 Links to Program Outcomes
6.3 Course Outcomes
6.4 Course Outline (Including Unit Outcomes)
6.5 Teaching and Learning Activities
6.6 Assessment Methods
6.7 Final Grade Evaluation
6.8 Learning Resources
6.9 Course Policies and Standards
6.10 Effectivity and Revision Information
See Annex III for sample syllabi for selected courses as volunteered by some
institutions already implementing OBE.
17
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