Electronics and Related Engineering Technology Mississippi Curriculum Framework

Mississippi Administrative Code

Section: 9-17

Jurisdiction: MS

Bluebook Citation: 9 Miss. Admin. Code Pt. 17

Electronics and Related Engineering Technology Mississippi Curriculum Framework Program CIP: 15.0303 – Electrical, Electronic, and Communications Engineering Technology Program CIP: 15.0305 – Telecommunications Technology Program CIP: 47.0101 – Biomedical Equipment Repair Technology Program CIP: 47.0105 – Industrial Electronics Technology/Technician

January 2023

Published by: Mississippi Community College Board Division of Workforce, Career, and Technical Education 3825 Ridgewood Road Jackson, MS 39211 Phone: 601-432-6155 Email: [email protected] 1

FACULTY WRITING TEAM MEMBERS Sam McNease, Pearl River Community College Dustin Chambliss, Pearl River Community College Vic Cerniglia, Pearl River Community College Brad Fraizer, Pearl River Community College Aaron Cleveland, Mississippi Gulf Coast Community College Michael Bond, Mississippi Gulf Coast Community College, Harrison County Charles Hardt, Mississippi Gulf Coast Community College Doug Ferguson, Itawamba Community College Jeff Frank, Itawamba Community College Brian Turnage, Copiah-Lincoln Community College-Wesson Carey Williamson, Copiah-Lincoln Community College-Wesson Jacob Wright, Hinds Community College Andrea Jackson, Hinds Community College Michael Franks, Northwest Mississippi Community College

ADMINISTRATOR WRITING TEAM MEMBERS Dr. Sharolyn Magee, Copiah-Lincoln Community College Dr. Amy Townsend, Pearl River Community College Dr. David Collum, Pearl River Community College Katie Broadway, Northwest Mississippi Community College Jason Webb, Hinds Community College Cody Robertson, Jones College

BUSINESS AND INDUSTRY CONTRIBUTING TEAM MEMBERS Gonathun Hart, Alutiiq Essential Services at Stennis Jeremiah Lindley, Biomedical Department at Forrest General Hospital, Hattiesburg, MS Travis Kennedy, SYNCOM SPACE SERVICES LLC; Stennis

OFFICE OF CURRICULUM AND INSTRUCTION TEAM MEMBERS Scott Kolle, Ph.D., Director of Curriculum and Instruction, Mississippi Community College Board Sheriece Robinson, Ed.D., Curriculum Specialist, Mississippi Community College Board

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The Office of Curriculum and Instruction (OCI) was founded in 2013 under the Division of Workforce, Career, and Technical Education at the Mississippi Community College Board (MCCB). The office is funded through a partnership with The Mississippi Department of Education (MDE), who serves as Mississippi’s fiscal agent for state and federal Career and Technical Education (CTE) Funds. The OCI is tasked with developing statewide CTE curriculum, programming, and professional development designed to meet the local and statewide economic demand. Copyright© 2023 by Mississippi Community College Board For information, please contact [email protected]

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Contents I NDUSTRY CREDENTIALS, CERTIFICATIONS , AND P ROFESSIONAL L ICENSURE .......................................................................... 6 I NDUSTRY JOB P ROJECTION DATA ................................................................................................................................. 6 ARTICULATION .......................................................................................................................................................... 6 DUAL ENROLLMENT .................................................................................................................................................... 6 RESEARCH A BSTRACT .................................................................................................................................................. 7 REVISION H ISTORY: .................................................................................................................................................... 7 P ROGRAM DESCRIPTION ............................................................................................................................................. 8 Electronics and Related Engineering Technology................................................................................................. 8 SUGGESTED COURSE S EQUENCE ................................................................................................................................. 10 ELECTRONICS AND RELATED ENGINEERING TECHNOLOGY C OURSES ........................................................................... 22 EET 1114 DC Circuits ........................................................................................................................................ 22 EET 1123 AC Circuits ........................................................................................................................................ 25 EET 1133 Electrical Power ................................................................................................................................ 27 EET 1143 Commercial and Industrial Wiring .................................................................................................... 28 EET 1145 DC/AC Circuits .................................................................................................................................. 29 EET 1154 Equipment Maintenance, Troubleshooting, and Repair .................................................................... 33 EET 1163 Motor Maintenance and Troubleshooting ........................................................................................ 34 EET 1174 Fluid Power....................................................................................................................................... 35 EET 1192 Fundamentals of Electronics ............................................................................................................. 37 EET 1233 Computer Servicing Lab I .................................................................................................................. 39 EET 1311 Orientation to Biomedical Equipment Repair ................................................................................... 41 EET 1334 Solid State Devices and Circuits ........................................................................................................ 42 EET 1343 Motor Control Systems ..................................................................................................................... 44 EET 1353 Fundamentals of Robotics ................................................................................................................ 45 EET 1363 Microcontrollers ............................................................................................................................... 46 EET 1413 Mathematics for Electronics ............................................................................................................. 47 EET 1423 Introduction to Biomedical Equipment ............................................................................................. 49 EET 1443 Fundamentals of Instrumentation .................................................................................................... 50 EET 1613 Computer Fundamentals for Electronics/ Electricity ......................................................................... 51 EET 1713 Drafting for Electronics Technology .................................................................................................. 52 EET 211 (3-6) Supervised Work Experience in Biomedical Equipment Repair Technology I .............................. 53 EET 222 (3-6) Supervised Work Experience in Biomedical Equipment Repair Technology II ............................. 54 EET 2233 Computer Servicing Lab II ................................................................................................................. 55 EET 2334 Linear Integrated Circuits.................................................................................................................. 56 EET 2354 Solid State Motor Control ................................................................................................................. 58 EET 2363 Programmable Logic Controllers ....................................................................................................... 59 EET 2373 Programmable Logic Controllers Multi-Platform............................................................................... 60

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EET 2374 Advanced Robotics ........................................................................................................................... 61 EET 2383 Advanced Programmable Logic Controllers ...................................................................................... 62 EET 2414 Electronic Communications .............................................................................................................. 63 EET 2423 Fundamentals of Fiber Optics ........................................................................................................... 65 EET 2433 Physics for Electronics....................................................................................................................... 66 EET 2514 Interfacing Techniques...................................................................................................................... 67 EET 2524 Communication Methods and Technology........................................................................................ 68 EET 2534 Industrial Motor Controls ................................................................................................................. 69 EET 2823 Digital Television Systems................................................................................................................. 70 EET 291 (1-3) Special Project ............................................................................................................................ 71 EET 292 (1-6) Supervised Work Experience in Electronics Technology ............................................................. 72 TCT 1114 Fundamentals of Telecommunications ............................................................................................. 73 TCT 2244 Fundamentals of Telephony ............................................................................................................. 75 TCT 2354 Fundamentals of Wireless Technology ............................................................................................. 77 TCT 2364 Wireless Telecommunications Technology ....................................................................................... 79 TCT 2414 Microwave and Satellite Systems ..................................................................................................... 81 TCT 2424 Network Systems.............................................................................................................................. 83 TCT 291(1-4) Special Project............................................................................................................................. 85 TCT 292 (1-6) Supervised Work Experience ...................................................................................................... 86 WBL 191(1-3), WBL 192(1-3), Work-Based Learning I, II, III, IV, V, and VI, WBL 193(1-3), WBL 291(1-3), WBL 292(13), and WBL 293(1-3) ....................................................................................................................................... 87 APPENDIX A: RECOMMENDED TOOLS AND EQUIPMENT ................................................................................. 88 APPENDIX B: CURRICULUM DEFINITIONS AND TERMS..................................................................................... 90 APPENDIX C: RECOMMENDED TEXTBOOK LIST ................................................................................................ 91

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INDUSTRY CREDENTIALS , CERTIFICATIONS, AND PROFESSIONAL LICENSURE See the “Industry Credentials, Certifications, and Professional Licensure” https://www.mccb.edu/assessment

INDUSTRY JOB PROJECTION D ATA A summary of occupational data is available from the Mississippi Department of Employment Security. https://mdes.ms.gov/information-center/labor-market-information/

ARTICULATION Check with the local community college CTE administration for articulation agreements.

DUAL ENROLLMENT See the “Procedures Manual for Dual Enrollment and Accelerated Programs” http://www.mississippi.edu/cjc/dual_enrollment.asp

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RESEARCH ABSTRACT In the spring of 2023, the Office of Curriculum and Instruction (OCI) met with the different administrators and faculty for the Electronics and Related Engineering Technology. A discussion was held to gather feedback concerning the trends and needs, both current and future, of their field. Program faculty, administrators, and industry members were consulted regarding industry workforce needs and trends. Industry advisory team members from the college involved with this program were asked to give input related to changes to be made to the curriculum framework.

REVISION HISTORY: 2011, Revised, Research and Curriculum Unit, Mississippi State University 2017, Revised, Office of Curriculum and Instruction, Mississippi Community College Board 2023, Revised, Office of Curriculum and Instruction, Mississippi Community College Board

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PROGRAM DESCRIPTION Electronics and Related Engineering Technology Electronics Technology Electronics Technology is an instructional program that prepares individuals to support electrical engineers and other professionals in the design, development, and testing of electrical circuits, devices, and systems. The program includes instruction in model and prototype development and testing; systems analysis and integration, including design and development of corrective and preventive maintenance techniques; application of engineering data; and the preparation of reports and test results. The purpose of the Electronics Technology curriculum is to provide instruction necessary for a student to become a competent electronic technician. A graduate of this curriculum will be eligible for entry-level employment into any of the options in electronics and will be capable of correlating the activities of scientific research, engineering, and production for a wide variety of occupational fields. A graduate of the Electronics Technology curriculum will possess the capability of working and communicating directly with engineers, scientists, and other technical personnel in his or her specialized area. Biomedical Equipment Repair Technology Biomedical Equipment Repair Technology is an instructional and field service program that provides the students with technical knowledge and skills necessary for gaining employment as a biomedical equipment technician. They are entrylevel technicians who can install, set up, troubleshoot, integrate, program, test, operate, and repair biomedical equipment. The AAS Degree in Electronics Technology (BMET) option will be awarded upon the successful completion of a minimum of 60 semester hours of the courses within the program. Upon completion, the student will have an opportunity to apply for the Biomedical Equipment Technician Certification Examination. This curriculum corresponds with the international certification content areas from the Examination for Certification as Biomedical Equipment Technician of the Association for the Advancement of Medical Instrumentation. Telecommunications Technology This 2-year program is designed to prepare students for a wide range of technical positions within the telecommunications industry. Specific preparation is in modes, techniques, mediums of voice, and data transmissions and reception. Emphasis is on the telephone instrument, key systems, PBX systems, analog and digital voice communications, data communications, fiber-optic communications, and satellite and microwave communications. Graduates will be qualified to help select, install, operate, maintain, troubleshoot, and repair telecommunications systems. An Associate of Applied Science Degree is awarded upon successful completion of a minimum of 60 semester credit hours of approved course work. This curriculum was developed using the Electronics Technicians Association, International, standards from the National Coalition for Electronics Education and ETA’s Associate C.E.T©. Examination Development Committee.

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Industrial Electronics Technology This 2-year program is designed to prepare students for a wide range of technical positions within the industrial manufacturing industry. The Industrial Electronics program is designed to prepare graduates for a career in the installation, maintenance, testing, and repair of industrial electrical and electronic equipment and systems. This program introduces the fundamentals of electricity, electronics, digital techniques, electrical power distribution, motor controls, fluid systems controls, programmable logic controllers, and instrumentation. Graduates will possess the skills necessary to enter the workforce as technicians in the fields of telephone service, industrial electronic and electrical servicing, plc and process control, industrial automation, and power distribution and as general electronic technicians. An Associate of Applied Science Degree is awarded upon successful completion of a minimum of 60 semester credit hours of approved course work.

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SUGGESTED COURSE SEQUENCE Work Ready Certificate Contact Hour Breakdown

SCH Breakdown Semester Credit Hours

Lecture

Lab

Total Contact Hours

5 or 6-7*

2-4 or 2

2-6 or 4

90-120 or 90

Digital Electronics

4

3

2

75

Solid State Devices and Circuits

4

2

4

90

All other electives approved by instructor per local community college policy*

2

Course Number EET 1145 or EET 1123 or SBE 1123 and EET 1114* or SBE 1113

Course Name DC/AC Circuits or AC Circuits* or Electronic Fundamentals II and DC Circuits* or Electronics Fundamentals I

EET 1214 EET 1334

Lecture

Lab

Total 15 *Colleges choosing to teach AC Circuits and DC Circuits separately as 2 courses for a total of 7 SCH will have less elective hours available in this program of study.

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CIP: 15.0303 Career Certificate Required Courses (Electronics Technology) Contact Hour Breakdown

SCH Breakdown

Course Number EET 1145 or EET 1123 or SBE 1123 and EET 1114* or SBE 1113 EET 1214 EET 1334 EET 1363 or EET 2363

Course Name DC/AC Circuits or AC Circuits* or Electronic Fundamentals II and DC Circuits* or Electronics Fundamentals I

Semester Credit Hours

Lecture

Total Contact Hours

Lab

5 or 6-7*

2-4 or 2

2-6 or 4

90-120 or 90

Digital Electronics

4

3

2

75

Solid State Devices and Circuits Microcontrollers or Programmable Logic Controllers All other electives approved by instructor per local community college policy*

4

2

4

90

3

1

4

75

Lecture

Lab

14 or 12

TOTAL 30 *Colleges choosing to teach AC Circuits and DC Circuits separately as 2 courses for a total of 7 SCH will have less elective hours available in this program of study.

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CIP: 15.0303 Technical Certificate Required Courses (Electronic Technology) Contact Hour Breakdown

SCH Breakdown

Course Number EET 2334 or EET 1154 or IET 2453

EET 2414 or EET 2524

Course Name Linear Integrated Circuits or Equipment Maintenance Troubleshooting and Repair or Troubleshooting and Calibration Principles Electronic Communications or Communication Methods and Technology All other electives approved by instructor per local community college policy TOTAL

Semester Credit Hours

Lecture

Total Contact Hours

Lab

4

3 or 1

2 or 6

75 or 105

4

2

4

90

Lecture

Lab

7 15

12

CIP: 47.0101 Career Certificate Required Courses (Biomedical Equipment Repair Technology) Contact Hour Breakdown

SCH Breakdown Course Number EET 1145 or EET 1123 and EET 1114*

Course Name DC/AC Circuits or AC Circuits* and DC Circuits*

Semester Credit Hours

Lecture

Total Contact Hours

Lab

5 or 7*

2-4 or 2

2-6 or 4

90-120 or 90

Digital Electronics Orientation for Biomedical Equipment Repair

4

3

2

75

1

1

0

15

Solid State Devices and Circuits

4

2

4

90

BIO 2513

Anatomy and Physiology I

3

BIO 2511

Anatomy and Physiology I Lab All other electives approved by instructor per local community college policy*

1

EET 1214 EET 1311 EET 1334

Lecture

Lab

12 or 10

TOTAL 30 *Colleges choosing to teach AC Circuits and DC Circuits separately as 2 courses for a total of 7 SCH will have less elective hours available in this program of study.

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CIP: 47.0101 Technical Certificate Required Courses (Biomedical Equipment Repair Technology) Contact Hour Breakdown

SCH Breakdown

Course Number BIO 2523 BIO 2521 EET 2334 or EET 1423

EET 2423 or EET 2414 or EET 2524

Semester Credit Hours

Course Name Anatomy and Physiology II Anatomy and Physiology Lab II Linear Integrated Circuits or Introduction to Biomedical Equipment Fundamentals of Fiber Optics or Electronic Communications or Communication Methods and Technology All other electives approved by instructor per local community college policy

Lecture

Total Contact Hours

Lab

Lecture

Lab

3 1

4

3 or 2

2 or 2

75 rr 60

3 or 4

1 or 2

4 or 2

75 or 90

3 or 4

TOTAL 15 CIP: 15.0305 Career Certificate Required Courses (Telecommunications Technology) Contact Hour Breakdown

SCH Breakdown

Course Number EET 1145 or EET 1123 and EET 1114* EET 1214 EET 1334 TCT 1114 TCT 2244 TCT 2354

Semester Credit Hours

Course Name DC/AC Circuits or AC Circuits* and DC Circuits*

Lecture

Total Contact Hours

Lab

5 or 7*

2-4 or 2

2-6 or 4

90-120 or 90

Digital Electronics Solid State Devices and Circuits Fundamentals of Telecommunications

4

3

2

75

4

2

4

90

4

3

2

75

Fundamentals of Telephony Fundamentals of Wireless Technology All other electives approved by instructor per local community college policy*

4

3

2

75

4

2

4

90

TOTAL

30

Lecture

Lab

5

14

*Colleges choosing to teach AC Circuits and DC Circuits separately as 2 courses for a total of 7 SCH will have less elective hours available in this program of study. CIP: 15.0305 Technical Certificate Required Courses (Telecommunications Technology) Contact Hour Breakdown

SCH Breakdown

Course Number EET 2423 TCT 2364 TCT 2414

Course Name Fundamentals of Fiber Optics Wireless Telecommunications Microwave and Satellite Systems All other electives approved by instructor per local community college policy TOTAL

Semester Credit Hours

Lecture

Total Contact Hours

Lab

3

1

4

75

4

2

4

90

4

3

2

75

Lecture

Lab

4 15

15

CIP: 47.0105 Career Certificate Required Courses (Industrial Electronics Technology)

Contact Hour Breakdown

SCH Breakdown Semester Credit Hours

Total Contact Hours

Course Number EET 1133

Course Name Electrical Power

3

2

2

60

EET 1145

DC/AC Circuits

5

2-4

2-6

90-120

EET 1214 EET 1334

Digital Electronics

4

3

2

75

Solid State Devices and Circuits

4

2

4

90

3

2

2

90

EET 1343

Motor Control Systems All other electives approved by instructor per local community college policy

Lecture

Lab

Lecture

Lab

11

TOTAL

30

CIP: 47.0105 Technical Certificate Required Courses (Industrial Electronics Technology-OPTION 1) Contact Hour Breakdown

SCH Breakdown Course Number EET 2354 EET 2363

Semester Credit Hours

Course Name

Lecture

Total Contact Hours

Lab

Solid State Motor Control

4

2

4

90

Programmable Logic Controllers All other electives approved by instructor per local community college policy

3

2

2

60

TOTAL

Lecture

8 15

16

Lab

CIP: 47.0105 Technical Certificate Required Courses (Industrial Electronics Technology-OPTION 2) Contact Hour Breakdown

SCH Breakdown

Course Number

EET 1154 EET 2534

Course Name Equipment Maintenance, Troubleshooting and Repair

Semester Credit Hours

Lecture

Total Contact Hours

Lab

4

1

6

105

Industrial Motor Control All other electives approved by instructor per local community college policy

4

2

4

90

TOTAL

15

Lecture

Lab

7

CIP: 47.0105 Technical Certificate Required Courses (Industrial Automation and Controls Engineering Technology) Contact Hour Breakdown

SCH Breakdown

Course Number EET 2363 EET 2373 MNT 2373

Course Name Programmable Logic Controllers Programmable Logic Controllers-Multi-Platform

Semester Credit Hours

Lecture

Total Contact Hours

Lab

3

2

2

60

3

1

4

75

Servo Control System All other electives approved by instructor per local community college policy

3

TOTAL

15

Lecture

6

17

Lab

General Education Core Courses To receive the Associate of Applied Science degree, a student must complete all of the required coursework found in the Career Certificate option, Technical certificate option, and a minimum of 15 semester hours of General Education core. The courses in the General Education Core may be spaced out over the entire length of the program so that students complete some academic and Career Technical courses each semester or provided primarily within the last semester. Each community college will specify the actual courses that are required to meet the General Education Core Requirements for the Associate of Applied Science degree at their college. The Southern Association of Colleges and Schools Commission on Colleges (SACSCOC) Section 9 Standard 3 of the Principles of Accreditation: Foundations for Quality Enhancement1 describes the general education core. Section 9 Standard 3: 3. The institution requires the successful completion of a general education component at the undergraduate level that a) is based on a coherent rationale. b) is a substantial component of each undergraduate degree program. For degree completion in associate programs, the component constitutes a minimum of 15 semester hours of the equivalent; for baccalaureate programs, a minimum of 30 semester hours or the equivalent. c) ensures breadth of knowledge. These credit hours include at least one course from each of the following areas: humanities/fine arts, social/behavioral sciences, and natural science/mathematics. These courses do not narrowly focus on those skills, techniques, and procedures specific to a particular occupation or profession. General Education Courses SCH Breakdown Course Number

Course Name

Semester Credit Hours

Humanities/Fine Arts

3

Social/Behavioral Sciences

3

Math/Science

3

Academic electives

6

TOTAL

15

Lecture

Lab

Contact Hour Breakdown Total Contact Hours

Lecture

Lab

1 Southern Association of Colleges and Schools Commission on Colleges. (2017). The Principles of Accreditation:

Foundations for Quality Enhancement. Retrieved from http://www.sacscoc.org/2017ProposedPrinc/Proposed%20Principles%20Adopted%20by%20BOT.pdf 18

Electives SCH Breakdown

Course Number

Course Name

EET 1143

Commercial & Industrial Wiring IT Foundations

EET 1153 EET 1163 EET 1174 EET 1192 EET 1233 EET 1353 EET 1413 EET 1423

EET 1443 EET 1613

EET 1713

EET 211 (3-6)

EET 222 (3-6)

EET 2233 EET 2383

EET 2433 EET 2514

Semester Credit Hours

Externship

Contact Hour Breakdown

Lecture

Lab

Total Contact Hours

3

2

2

60

3

1

6

105

Motor maintenance and Troubleshooting Fluid Power

3

2

2

60

4

3

2

60

Fundamentals of Electricity Computer Servicing Lab Fundamentals of Robotics Math for Electronics

2

1

2

45

3

0

6

90

3

2

2

60

3

2

2

60

Introduction to Biomedical Equipment Fundamentals of Instrumentation Computer Fundamentals Electronics/Electricity Drafting for Electronic/ Electrical Technology Supervised Work Experience in Biomedical Equipment Repair Technology Supervised Work Experience in Biomedical Equipment Repair Technology II Computer Servicing Lab II Advanced Programmable Logic Controllers Physics for Electronics Interfacing Techniques

3

2

2

60

3

2

2

60

3

2

2

60

3

1

4

75

(3-6)

0

9-18

135-270

(3-6)

0

9-18

135-270

3

0

6

90

3

2

2

60

3

2

2

60

4

2

4

90

Lecture

Lab

19

Externship

EET 2524

4

2

4

90

4

2

4

90

3

2

2

60

(1-3)

0

2-6

30-90

(1-6)

0

3-18

45-270

(1-6)

0

3-18

45-270

TCT 2424

Supervised Work Experience in Electronics technology Supervised Work Experience in Electronic Technology Network Systems

4

2

4

90

TCT 291 (1-4)

Special Project

(1-4)

0

2-8

30-120

TCT 292 (1-6)

Supervised Work Experience Mechanical Power Transmission I Mechanical Power Transmission II Industry 4.0 and Data Acquisition Power Distribution

(1-6)

0

4

IET 2113

Manufacturing Skills Basic Robotics& Automation Advanced Programmable Logic Controllers/Data Acquisition Industrial Instrumentation Advanced Instrumentation and Process Control Final Control Devices

IET 2433

Installation Practices

3

IET 2453

Troubleshooting and Calibration Principles Industrial Controls II

3

Capstone Class Safety, Health, and Environment Industry 4.0 with Data Acquisition Smart Start 101

3 3

EET 2534 EET 2823 EET 291(1-3) EET 291 (1-6)

EET 292 (1-6)

MNT 1142 MNT 1242 MNT 2364 SBA 1133 SBA 1144 SBA 1223 SBA 2113

IET 1113 IET 1313

IET 2413 IET 2513 PPT 1513 MMT 2364 SSP 100(2-3)

Communication Methods and Technology Industrial Motor Controls Digital Television Systems Special Projects

3-18

45-270

2 2 4 3

3 3

3 3

3

3

4 2-3 20

WBL 191(1-3) WBL 192(1-3) WBL 193(1-3) WBL 291(1-3) WBL 292(1-3) WBL 293(1-3) All other electives approved by instructor per local community college policy

Work-Based Learning

1-3

*REFER TO THE FOLLOWING CURRICULA FOR ADDITIONAL INFORMATION : CIP 52.1401-MMT CLASSES CIP 15.0406-SBE CLASSES CIP 15.0406-SBA CLASSES CIP 15.0404-IET CLASSES CIP 14.1901- MNT CLASSES CIP 15.0699-PPT CLASSES *CONTACT ADULT EDUCATION FOR SSP CLASSES

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ELECTRONICS AND RELATED ENGINEERING TECHNOLOGY COURSES Course Number and Name:

EET 1114 DC Circuits

Description:

Principles and theories associated with DC circuits. This course includes the study of electrical circuits, laws and formulae, and the use of test equipment to analyze DC circuits.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Demonstrate and apply an understanding of a basic electrical circuit. a. Write numbers in scientific and engineering notation. b. Perform mathematical manipulations with numbers expressed in engineering notation. c. Explain the basic structure of matter to include the atom and element. d. Explain the laws of electrical charge. e. Differentiate among the characteristics of conductors, semiconductors, and insulators. f. Demonstrate the ability to determine resistor types, value, tolerance, and power rating. g. Differentiate between DC circuit schematic symbols. h. Demonstrate proper techniques for measuring resistance. i. Discuss methods of generating electricity. j. Explain theories of current flow including electron and conventional method. k. Demonstrate an understanding of principles of and operation of batteries. l. Explain and demonstrate the measurement of resistance of conductors and insulators and the computation of conductance. 3. Demonstrate an understanding of voltage, current, resistance, and power and how they relate. a. Explain the physical properties of voltage, current, and resistance. b. State three equations used to express Ohm’s law c. Analyze circuit parameters using Ohm’s law. d. Explain how power is developed in a circuit. e. State three forms of power equations. f. Demonstrate techniques for determining power. g. Describe and demonstrate the proper technique for measuring voltage using a voltmeter. h. Describe and demonstrate the proper technique for measuring current using an ammeter. i. Describe and demonstrate the proper technique for measuring resistance using an ohmmeter. 4. Analyze and evaluate the parameters of a series circuit. a. Identify series circuits. b. Compute total resistance of a series circuit. c. Using Ohm’s law, compute the current in a series circuit. d. Explain why current is the same at all points in a series circuit. e. State and apply Kirchhoff’s voltage law in analysis of series circuits. f. Explain why a series circuit is known as a voltage divider. g. Using Ohm’s law, compute the voltage drops in a series circuit. 22

h. Compute the power developed by each resistor and the total power of a series circuit. i. Explain the difference between series-aiding and series-opposing voltage sources. j. Construct, analyze, and troubleshoot a series circuit. 5. Analyze and evaluate the parameters of a parallel circuit. a. Identify parallel circuits. b. Compute total resistance of a parallel circuit. c. Utilize Ohm’s law to solve circuit parameters of a parallel DC circuit. d. Explain why voltage is the same across all branches of a parallel circuit. e. State and apply Kirchhoff’s current law in the analysis of parallel circuit. f. Explain why a parallel circuit is a current divider. g. Compute branch currents in a parallel resistive circuit using the current divider equation. h. Construct, analyze, and troubleshoot a parallel circuit. 6. Analyze and evaluate the parameters of a series–parallel circuit. a. Differentiate between series and parallel in a series–parallel resistive circuit. b. Compute total resistance of a series–parallel circuit. c. Analyze series–parallel circuits for the current through and the voltage across each component. d. Construct, analyze, and troubleshoot a series–parallel circuit. e. Analyze loaded and unloaded voltage dividers. f. Explain the operation and application of a Wheatstone bridge. g. Construct a resistive bridge circuit, and measure an unknown resistance. h. Measure the error voltage of an unbalanced bridge. 7. Apply network theorems to the analysis of complex circuits. a. Perform voltage source to current source conversions and current source to voltage source conversions. b. In circuits containing multiple resistors and sources, use the superposition theorem to solve for unknown voltages and currents. c. Through analysis, construction, and testing of an actual circuit, prove the validity of the superposition theorem. d. Reduce series–parallel resistive circuits to their Thevenin’s equivalent. e. Measure the Thevenin’s voltage and resistance of a DC circuit. f. Reduce series–parallel resistive circuits to their Norton equivalent. g. Measure the Norton current and Norton resistance of a series circuit. h. Perform conversions between Thevenin’s and Norton equivalent circuit. i. Explain the conditions under which maximum power occurs. j. Construct a circuit, and prove the maximum power transfer theorem. 8. Explain capacitance, and demonstrate its application in DC and transient circuits. a. Explain capacitance and terms related to capacitance. b. Explain the construction of a capacitor and its relationship to capacitance value. c. Draw the symbols for capacitance, and identify the unit of measurement for capacitance. d. Explain how the capacitor is charged and discharged. e. Identify various types of capacitors. f. Explain specifications of connections including values and voltage ratings. g. Calculate the total capacitance of capacitors in series and in parallel. h. Define and compute RC time constant. i. Measure capacitance in series and in parallel. j. Construct a circuit, and using an oscilloscope, display and measure the charge and discharge waveforms in a series RC circuit. k. Explain and demonstrate techniques for troubleshooting capacitors. 9. Explain inductance, and demonstrate its application in DC and transient circuits. 23

a. Explain the laws of repulsion and attraction between two magnetic poles. b. Explain how an electromagnet is developed. c. Explain several applications of magnetism. d. Define inductance and the terms relating to inductance. e. Sketch the symbols for inductors, and identify the unit of measurements for inductance. f. List the factors that determine the value of an inductor, and state whether the factors have a direct or inverse effect on the value. g. Calculate total inductance in series and parallel. h. Explain the Henry in terms of induced voltage and the rate of charge of current with respect to time. i. Calculate the time constant for an RL circuit. j. Fabricate and demonstrate the operation of an RL circuit. k. Explain and demonstrate techniques for troubleshooting DC circuits.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

24

Course Number and Name:

EET 1123 AC Circuits

Description:

Principles and theories associated with AC circuits. This course includes the study of electrical circuits, laws and formulae, and the use of test equipment to analyze AC circuits. Principles and theories associated with DC circuits. This course includes the study of electrical circuits, laws and formulae, and the use of test equipment to analyze DC circuits.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Analyze a sine wave, and explain its characteristics and application to AC circuits. a. Explain and calculate the following AC values: Period, frequency, time, angle, instantaneous values of voltage and current, peak, peak-to-peak voltage and current, RMS voltage and current, average voltage and current, and power. b. Analyze AC resistive circuits and solve for voltage drops, branch currents, and power dissipations. c. Explain and use phasors/vectors to represent the relative phase and amplitude of AC voltages and currents. d. Explain and use voltage and power decibels. e. Use the oscilloscope to measure AC voltage and frequency. f. Use a frequency counter to measure frequency. g. Use multimeters to measure AC voltage and current. h. Define the square and sawtooth waves in terms of harmonic content. i. Determine the duty cycle of a square wave. j. Determine period and frequency for sine waves, square waves, sawtooth waves, and triangle waves. 2. Analyze inductive and capacitive reactance in series and parallel circuits. a. Calculate inductive reactance (XL) using Ohm’s law or the inductive reactance formula when signal frequency and inductance are known. b. Solve for signal frequency when inductance and inductive reactance are known, or inductance when frequency and inductive reactance are known. c. Calculate capacitive reactance (XC) using Ohm’s law or the capacitive reactance formula when signal frequency and capacitance are known. d. Solve for signal frequency when capacitance and capacitive reactance are known, or capacitance when frequency and capacitive reactance are known.) e. Calculate all voltages and currents in series and parallel capacitive and inductive circuits. 3. Analyze transformer voltage, current, impedance transformations, and applications. a. Explain how mutual inductance affects transformer action. b. Calculate primary and secondary transformer voltage and current as related to the transformer’s turns ratio. 4. Explain RLC non-resonant and resonant circuits. a. Use basic trigonometric functions and the Pythagorean theorem for right triangles in the analysis of AC circuits. b. Calculate impedance, current, voltages, and power for series RL, RC, and RCL circuits. c. Represent series AC circuits with voltage, impedance, and power phasors in phasor diagrams. d. Use an RL and RC circuit as a lead or lag circuit. e. Express phase relationships in terms of time. f. Explain and calculate AC circuit efficiency.

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g. Construct RC, RL, and RCL series circuits and use a dual-trace oscilloscope for sinewave-voltage phase comparison. h. Calculate branch currents and total current for parallel RL, RC, and RCL circuits. i. Calculate the phase angle for each branch current and total current of a parallel AC circuit. j. Calculate real power, reactive power, apparent power, and the power factor for parallel AC circuits. k. Calculate the power efficiency of a parallel AC circuit. l. Correct the power factor of a parallel AC circuit by changing the size of L or C. m. Construct and analyze RC, RL, and RCL parallel AC circuits. n. Name applications for series and parallel resonant circuits. o. List all of the significant parameters and characteristics of series and parallel resonant circuits. p. Explain the characteristic graphs for series and parallel resonant circuits. q. Calculate the resonant frequency for series and parallel resonant circuits. r. Calculate circuit Q and bandwidth when the resonant frequency and total circuit resistance are known. s. Calculate bandpass when the resonant frequency and bandwidth are known. t. Calculate the proper size capacitor to resonate with a given inductor at a specified resonant frequency. u. Calculate the proper amount of total resistance needed to provide a specified bandwidth for a given series resonant circuit. v. Accurately test series and parallel resonant circuits using a variable-frequency generator and an oscilloscope. w. Explain similarities and differences between series and parallel resonance. 5. Explain and classify filters. a. Identify filters by type and configuration. b. Discuss and analyze filter types in terms of frequency response, phase response, insertion loss, and roll off shape. c. Discuss practical applications of each of the basic filter types. d. Predict and plot frequency response for common filter types using the insertion loss formula. e. Analyze RL, RC, and RCL high-pass filters. f. Analyze RL, RC, and RCL low-pass filters. g. Analyze series and parallel resonant band-pass filters. h. Analyze series and parallel resonant band stop filters.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

26

Course Number and Name:

EET 1133 Electrical Power

Description:

This course covers electrical motors and their installation and offers instruction and practice in using the different types of motors, transformers, and alternators.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Discuss safety and environmental protection concerns associated with electrical power equipment. a. List safety precautions associated with motors and transformers. b. Explain the procedures for working with and disposing of hazardous materials. 2. Wire single-phase electrical components. a. Sketch and connect a single-phase transformer for high- and low-voltage applications. b. Identify, sketch, and wire different types of single-phase motors. c. Explain and demonstrate the applications of an AC generator. 3. Wire three-phase electrical components. a. Sketch and connect a three-phase AC transformer to include delta and wye, threewire, and four-wire systems. b. Identify, draw, and wire different types of three-phase motors to include low- and high-voltage requirements.

Certification SMC ADVANCED MANUFACTURING CERTIFICATION LEVEL I BASIC© Mechatronics Level I –Basic

27

Course Number and Name:

EET 1143 Commercial and Industrial Wiring

Description:

Instruction and practice in the installation of commercial and industrial electrical services including the types of conduit and other raceways, NEC code requirements, and three phase distribution networks.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Apply general safety rules and current NEC and local codes. a. Explain and demonstrate safety rules and regulations for working near or on load centers and safety switches. b. Explain and demonstrate the ability of safe lifting and work habits. c. Identify the code requirements for industrial and commercial locations. 2. Install and maintain raceways, conduit, and fittings. a. Identify types of raceways, conduit, and fittings. b. Apply usage of raceways, conduit, and fittings as required by electrical codes. c. Demonstrate the use of mechanical and hydraulic conduit benders to make specified bends to different sizes and types of conduit. d. Identify other types of raceways and their associated bodies. 3. Explain different types of three-phase service entrances, metering devices, main panels, raceways or ducts, subpanels, feeder circuits, and branch circuits according to electrical codes. a. Explain the codes (NEC and local codes) for the installation of a three-phase service entrance. b. Explain safety precautions to be used when installing a three-phase service entrance. c. Construct a sketch to install a three-phase service entrance. d. Explain terms associated with a three-phase service entrance from codes and industry terminology. e. Identify components of a three-phase service entrance. 4. Prepare a job estimate including supplies and labor costs. a. Compute the local labor cost for a given job. b. Determine the amount of supplies for a given job. c. Compute the cost of supplies for a given job. d. Justify in writing the total cost for a given job.

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Course Number and Name:

EET 1145 DC/AC Circuits

Description:

Principles and theories associated with DC and AC circuits. This course includes the study of electrical circuits, laws and formulae, and the use of test equipment to analyze DC and AC circuits.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 5 5 5

Lecture 4 3 2

Lab 2 4 6

Contact Hours 90 105 120

Instructor Approved

Student Learning Outcomes: 1.

Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards.

2.

Demonstrate and apply an understanding of a basic electrical circuit. a. Write numbers in scientific and engineering notation. b. Perform mathematical manipulations with numbers expressed in engineering notation. c. Explain the basic structure of matter to include the atom and element. d. Explain the laws of electrical charge. e. Differentiate among the characteristics of conductors, semiconductors, and insulators. f. Demonstrate the ability to determine resistor types, value, tolerance, and power rating. g. Differentiate between DC circuit schematic symbols. h. Demonstrate proper techniques for measuring resistance. i. Discuss methods of generating electricity. j. Explain theories of current flow including electron and conventional method. k. Demonstrate an understanding of principles of and operation of batteries. l. Explain and demonstrate the measurement of resistance of conductors and insulators and the computation of conductance.

3.

Demonstrate an understanding of voltage, current, resistance, and power and how they relate. a. Explain the physical properties of voltage, current, and resistance. b. State three equations used to express Ohm’s law c. Analyze circuit parameters using Ohm’s law. d. Explain how power is developed in a circuit. e. State three forms of power equations. f. Demonstrate techniques for determining power. g. Describe and demonstrate the proper technique for measuring voltage using a voltmeter. h. Describe and demonstrate the proper technique for measuring current using an ammeter. i. Describe and demonstrate the proper technique for measuring resistance using an ohmmeter.

4.

Analyze and evaluate the parameters of a series circuit. a. Identify series circuits. b. Compute total resistance of a series circuit. c. Using Ohm’s law, compute the current in a series circuit. 29

d. Explain why current is the same at all points in a series circuit. e. State and apply Kirchhoff’s voltage law in analysis of series circuits. f. Explain why a series circuit is known as a voltage divider. g. Using Ohm’s law, compute the voltage drops in a series circuit. h. Compute the power developed by each resistor and the total power of a series circuit. i. Explain the difference between series-aiding and series-opposing voltage sources. j. Construct, analyze, and troubleshoot a series circuit. 5.

Analyze and evaluate the parameters of a parallel circuit. a. Identify parallel circuits. b. Compute total resistance of a parallel circuit. c. Utilize Ohm’s law to solve circuit parameters of a parallel DC circuit. d. Explain why voltage is the same across all branches of a parallel circuit. e. State and apply Kirchhoff’s current law in the analysis of parallel circuit. f. Explain why a parallel circuit is a current divider. g. Compute branch currents in a parallel resistive circuit using the current divider equation. h. Construct, analyze, and troubleshoot a parallel circuit.

6.

Analyze and evaluate the parameters of a series–parallel circuit. a. Differentiate between series and parallel in a series–parallel resistive circuit. b. Compute total resistance of a series–parallel circuit. c. Analyze series–parallel circuits for the current through and the voltage across each component. d. Construct, analyze, and troubleshoot a series–parallel circuit. e. Analyze loaded and unloaded voltage dividers. f. Explain the operation and application of a Wheatstone bridge. g. Construct a resistive bridge circuit, and measure an unknown resistance. h. Measure the error voltage of an unbalanced bridge.

7.

Apply network theorems to the analysis of complex circuits. a. Perform voltage source to current source conversions and current source to voltage source conversions. b. In circuits containing multiple resistors and sources, use the superposition theorem to solve for unknown voltages and currents. c. Through analysis, construction, and testing of an actual circuit, prove the validity of the superposition theorem. d. Reduce series–parallel resistive circuits to their Thevenin’s equivalent. e. Measure the Thevenin’s voltage and resistance of a DC circuit. f. Reduce series–parallel resistive circuits to their Norton equivalent. g. Measure the Norton current and Norton resistance of a series circuit. h. Perform conversions between Thevenin’s and Norton equivalent circuit. i. Explain the conditions under which maximum power occurs. j. Construct a circuit, and prove the maximum power transfer theorem.

8.

Explain capacitance, and demonstrate its application in DC and transient circuits. a. Explain capacitance and terms related to capacitance. b. Explain the construction of a capacitor and its relationship to capacitance value. c. Draw the symbols for capacitance, and identify the unit of measurement for capacitance. d. Explain how the capacitor is charged and discharged. 30

e. Identify various types of capacitors. f. Explain specifications of connections including values and voltage ratings. g. Calculate the total capacitance of capacitors in series and in parallel. h. Define and compute RC time constant. i. Measure capacitance in series and in parallel. j. Construct a circuit, and using an oscilloscope, display and measure the charge and discharge waveforms in a series RC circuit. k. Explain and demonstrate techniques for troubleshooting capacitors. 9.

Explain inductance, and demonstrate its application in DC and transient circuits. a. Explain the laws of repulsion and attraction between two magnetic poles. b. Explain how an electromagnet is developed. c. Explain several applications of magnetism. d. Define inductance and the terms relating to inductance. e. Sketch the symbols for inductors, and identify the unit of measurements for inductance. f. List the factors that determine the value of an inductor, and state whether the factors have a direct or inverse effect on the value. g. Calculate total inductance in series and parallel. h. Explain the Henry in terms of induced voltage and the rate of charge of current with respect to time. i. Calculate the time constant for an RL circuit. j. Fabricate and demonstrate the operation of an RL circuit. k. Explain and demonstrate techniques for troubleshooting DC circuits.

10. Analyze a sine wave, and explain its characteristics and application to AC circuits. a. Explain and calculate the following AC values: Period, frequency, time, angle, instantaneous values of voltage and current, peak, peak-to-peak voltage and current, RMS voltage and current, average voltage and current, and power. b. Analyze AC resistive circuits and solve for voltage drops, branch currents, and power dissipations. c. Explain and use phasors/vectors to represent the relative phase and amplitude of AC voltages and currents. d. Explain and use voltage and power decibels. e. Use the oscilloscope to measure AC voltage and frequency. f. Use a frequency counter to measure frequency. g. Use multimeters to measure AC voltage and current. h. Define the square and saw tooth waves in terms of harmonic content. i. Determine the duty cycle of a square wave. j. Determine period and frequency for sine waves, square waves, saw tooth waves, and triangle waves. 11. Analyze inductive and capacitive reactance in series and parallel circuits. a. Calculate inductive reactance (XL) using Ohm’s law or the inductive reactance formula when signal frequency and inductance are known. b. Solve for signal frequency when inductance and inductive reactance are known, or inductance when frequency and inductive reactance are known. c. Calculate capacitive reactance (XC) using Ohm’s law or the capacitive reactance formula when signal frequency and capacitance are known. d. Solve for signal frequency when capacitance and capacitive reactance are known, or capacitance when frequency and capacitive reactance are known.) e. Calculate all voltages and currents in series and parallel capacitive and inductive circuits. 12. Analyze transformer voltage, current, impedance transformations, and applications. a. Explain how mutual inductance affects transformer action. 31

b. Calculate primary and secondary transformer voltage and current as related to the transformer’s turns ratio. 13. Explain RLC non-resonant and resonant circuits. a. Use basic trigonometric functions and the Pythagorean theorem for right triangles in the analysis of AC circuits. b. Calculate impedance, current, voltages, and power for series RL, RC, and RCL circuits. c. Represent series AC circuits with voltage, impedance, and power phasors in phasor diagrams. d. Use an RL and RC circuit as a lead or lag circuit. e. Express phase relationships in terms of time. f. Explain and calculate AC circuit efficiency. g. Construct RC, RL, and RCL series circuits and use a dual-trace oscilloscope for sinewavevoltage phase comparison. h. Calculate branch currents and total current for parallel RL, RC, and RCL circuits. i. Calculate the phase angle for each branch current and total current of a parallel AC circuit. j. Calculate real power, reactive power, apparent power, and the power factor for parallel AC circuits. k. Calculate the power efficiency of a parallel AC circuit. l. Correct the power factor of a parallel AC circuit by changing the size of L or C. m. Construct and analyze RC, RL, and RCL parallel AC circuits. n. Name applications for series and parallel resonant circuits. o. List all of the significant parameters and characteristics of series and parallel resonant circuits. p. Explain the characteristic graphs for series and parallel resonant circuits. q. Calculate the resonant frequency for series and parallel resonant circuits. r. Calculate circuit Q and bandwidth when the resonant frequency and total circuit resistance are known. s. Calculate bandpass when the resonant frequency and bandwidth are known. t. Calculate the proper size capacitor to resonate with a given inductor at a specified resonant frequency. u. Calculate the proper amount of total resistance needed to provide a specified bandwidth for a given series resonant circuit. v. Accurately test series and parallel resonant circuits using a variable-frequency generator and an oscilloscope. w. Explain similarities and differences between series and parallel resonance. 14. Explain and classify filters. a. Identify filters by type and configuration. b. Discuss and analyze filter types in terms of frequency response, phase response, insertion loss, and roll off shape. c. Discuss practical applications of each of the basic filter types. d. Predict and plot frequency response for common filter types using the insertion loss formula. e. Analyze RL, RC, and RCL high-pass filters. f. Analyze RL, RC, and RCL low-pass filters. g. Analyze series and parallel resonant band-pass filters. h. Analyze series and parallel resonant band stop filters.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION SMC ADVANCED MANUFACTURING CERTIFICATION LEVEL I BASIC© Mechatronics Level I –Basic

32

Course Number and Name:

EET 1154 Equipment Maintenance, Troubleshooting, and Repair

Description:

Maintenance and troubleshooting techniques, use of technical manuals and test equipment, and inspection/evaluation/repair of equipment

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 1

Lab 6

Contact Hours 105

Instructor Approved

Student Learning Outcomes: 1. Discuss and apply proper safety procedures regarding maintenance, troubleshooting, and repair of equipment. 2. Perform preventive maintenance on equipment. a. Develop a preventive maintenance program for a given piece of equipment. b. Inspect and adjust belts, chains, and other moving parts. c. Lubricate a machine following manufacturer’s recommendations. 3. Troubleshoot and repair equipment. a. Identify symptoms that indicate a machine is not operating properly (excessive noise, vibration, heat, speed, etc.). b. Determine the cause of the symptoms. c. Inspect machinery for broken or worn parts, and determine if replacement is needed. d. Prepare a report on time and costs involved in repairing equipment. e. Perform lockout–tagout procedures for broken equipment. f. Disassemble, inspect, repair, and reassemble equipment to specifications. g. Perform preventive maintenance on an electric motor (disassemble, clean and inspect, repair mechanical components, lubricate, and reassemble). h. Check and service a battery, including recharging. 4. Estimate expenses for a given project. a. Prepare a bill of materials list for a specific job. b. Calculate the labor factor for a specific job.

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Course Number and Name:

EET 1163 Motor Maintenance and Troubleshooting

Description:

This course covers the principles and practice of electrical motor repair and includes topics on the disassembly/assembly and preventive maintenance of common electrical motors.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Apply general safety principles and safety requirements for working with electric motors. a. Apply principles of safety in the use and repair of electrical motors. b. Describe safety procedures to utilize during connecting, operating, and repairing of electrical motors. c. Practice lockout–tagout procedure. 2. Use instruments and tools in maintaining, troubleshooting, and operating electrical motors. a. Identify, describe, and demonstrate the use of instruments and tools used to maintain, troubleshoot, and repair motors, to include megohm meters, volt–amp meters, and multimeters. b. Describe the procedures for the maintenance, testing, and/or repair of instruments and tools. 3. Troubleshoot and perform basic maintenance on electrical motors. a. List and describe functions of the major parts and windings of single-phase motors. b. List and describe the functions of split-phase, capacitor-start, capacitor-start/capacitorrun, and permanent split capacitor electric motors. c. Describe and list the functions of a shaded pole and repulsion/induction electric motors. d. List and describe functions of major parts and windings of three-phase motors to include squirrel cage induction, synchronous, and wound rotor motors. e. List and describe functions of the major parts and windings of DC motors to include series, shunt, and compound wound motors. f. Develop a preventive maintenance program for electric motors.

34

Course Number and Name:

EET 1174 Fluid Power

Description:

This basic course provides instruction in hydraulics and pneumatics. The course covers actuators, accumulators, valves, pumps, motors, coolers, compression of air, control devices, and circuit diagrams. Emphasis is placed on the development of control circuits and troubleshooting techniques.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 3

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Define and describe basic laws governing fluids. a. Describe the concept of force, flow, and pressure. b. Analyze the relationship of force and pressure in a circuit. c. Explain what causes flow in a circuit. d. Calculate area, pressure, velocity, and rate of flow. e. Explain and apply the ideal gas laws, Boyle’s law, and Charles’ law in fluid systems. 2. Identify and draw symbols for hydraulics and pneumatics. a. Explain the logic for drawing symbols for hydraulic components. b. Draw individual hydraulic and pneumatic components. 3. Describe the operation and nomenclature of various pumps and compressors. a. Analyze the operation of vane, gear, and piston pumps in hydraulics. b. Analyze the operation of air compressors. 4. Explain fluids as pertaining to the transmission of energy. a. Describe various types of hydraulic fluids. b. Explain the purpose of the fluid reservoir, the filtration system, and the heat exchanger in hydraulics. c. Explain the purpose of the receiver in pneumatics. d. Explain the purpose of trio units in compressed air. 5. Describe the operation of flow, pressure, and directional control valves. a. Explain basic design features used in each type of control valve. b. Demonstrate how flow, pressure, and directional valves are used in hydraulics and pneumatics. 6. Explain the types of actuators used in pneumatics and hydraulics. a. List important cylinder design features. b. Explain basic design features of hydraulic motors and other rotary actuators. c. Identify common types of air motors. 7. Explain, construct, and troubleshoot various hydraulic and pneumatic circuits. a. Explain the purpose of a sequence circuit. b. Construct and troubleshoot a sequence circuit. 8. Demonstrate the use of electro-mechanical controls in hydraulic and pneumatic circuits. a. Explain the construction and use of solenoids in directional controls. b. Construct a hydraulic or pneumatic circuit that is controlled electrically.

Certification 35

SMC ADVANCED MANUFACTURING CERTIFICATION LEVEL I BASIC© Mechatronics Level I-Basic

36

Course Number and Name:

EET 1192 Fundamentals of Electronics

Description:

Fundamental skills associated with all electronics courses. Safety, bread boarding, use of calculator, test equipment familiarization, soldering, electronic symbols, and terminology

Hour Breakdown:

Prerequisite:

Semester Credit Hours 2

Lecture 1

Lab 2

Contact Hours 45

Instructor Approved

Student Learning Outcomes: 1. Explain, demonstrate, and practice general safety procedures in the shop, lab, and industrial environments. a. Apply proper safety techniques for all types of circuits and components. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. c. Demonstrate an understanding of and comply with relevant lock-out, tag-out procedures. 2. Demonstrate and utilize proper bread boarding techniques. a. Identify the various electronic components and schematic symbols. b. Identify the various resistor and capacity codes. c. Lay out a breadboard by the use of a schematic. d. Demonstrate forming components to fit into a breadboard. e. Demonstrate techniques for selecting and forming wires to make connections. 3. Demonstrate proficiency in the use of a calculator. a. Use SI symbols and prefixes to describe electrical values. b. Manipulate numbers in mathematical operations using scientific notation, engineering notation, and E notation to aid in mathematical circuit analysis. c. Perform basic algebraic operations using electronic equations to express the rules of symbol transformation. d. Perform basic trigonometry to include the Pythagorean theorem, sine function, cosine function, and tangent function. e. Perform practical math in solving ratio, percentage, proportions, powers, and roots of numbers on digital conversions. 4. Demonstrate the proper use and operation of test equipment. a. Demonstrate the use and care of test instruments including volt-ohm meters, current meters, oscilloscopes, and so forth. b. Explain the cause and effects of current and voltage circuit loading. c. Describe the differences between analog and digital multimeters. d. Discuss the advantages and disadvantages of analog and digital multimeters. e. Explain zeroing the ohmmeter prior to use and effects of battery drain on its accuracy. f. Demonstrate proper troubleshooting techniques by use of selected meters. 5. Demonstrate proper soldering and desoldering techniques. a. Apply acceptable soldering/desoldering techniques, including thru-hole and surface mount devices. b. Apply acceptable standards of proper solderless connections.

37

Course Number and Name:

EET 1214 Digital Electronics

Description:

Number systems, logic circuits, counters, registers, memory devices, combination logic circuits, Boolean algebra, and a basic computer system

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 3

Lab 2

Contact Hours 75

Instructor Approved

Student Learning Outcomes: 1. Perform mathematical operations in digital number systems. a. Convert between binary, octal, hex, and decimal values. b. Add and subtract binary, octal, and hex numbers. c. Subtract binary numbers using both ones and twos complements. d. Generate and interpret even and odd parity. e. Use the terms bit, byte, MSB, LSB, and nibble appropriately. f. Encode and decode ASCII codes from code charts. 2. Classify logic gates, and explain their functions. a. Describe and complete truth tables for logic gates. b. Sketch schematic diagrams for logic gates. c. Solve timing diagrams for logic gates. d. Apply procedures to protect devices against electrostatic discharge (ESD). e. Wire and test logic gates. f. Write Boolean expression for logic gates. 3. Analyze logic circuits. a. Construct, develop, and interpret combinational logic circuits. 4. Minimize logic circuits using Boolean algebra and Karnaugh mapping. a. Write and describe the Boolean algebra theorems. b. Apply DeMorgan’s theorem to convert between OR and AND logic. c. Apply Boolean algebra to minimize given Boolean expressions. d. Convert between sum of products and product of sums. e. Use Karnaugh maps to simplify Boolean expressions. 5. Analyze principles and operations of digital display devices. a. Construct and demonstrate seven-segment LED digital displays. b. Describe the principle at operation for multiplying multidigit displays. c. Contrast LED and LCD digital display devices. 6. Explain the operation of basic memory circuits. a. Describe the characteristics of memory types including static RAM, dynamic RAM, PROM, and EPROM. b. Interpret manufacturers’ data sheets for memory integrated circuits. 7. Demonstrate an understanding of other digital circuits: a. counters b. clock generators c. multi- vibrators d. flip-flops. Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION 38

Course Number and Name:

EET 1233 Computer Servicing Lab I

Description:

This course covers fundamentals of computer servicing including configuration, test equipment usage, basic disassembly and assembly methods, preliminary tests and diagnostics, schematic interpretation, and building cables.

Hour Breakdown:

Semester Credit Hours 3

Prerequisite:

Instructor Approved

Lecture 0

Lab 6

Contact Hours 90

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Complete maintenance documentation. a. Prepare an identification tag. b. Prepare an equipment sketch. c. Prepare a repair log. d. Prepare an invoice. 3. Explain antistatic control procedures and equipment for computer repair. a. Identify antistatic equipment. b. Identify antistatic procedures. 4. Set up soldering and desoldering stations using correct safety procedures. a. Select correct equipment. b. Apply correct soldering and desoldering techniques. 5. Identify and utilize hand tools needed for basic computer servicing. a. Identify hand tools used for basic computer servicing. b. Utilize hand tools for basic computer servicing. 6. Identify and use various test equipment. a. Identify and use multimeters. b. Identify and use an oscilloscope. c. Identify and use circuit testers to correct wiring problems. 7. Demonstrate repair procedures for disassembly and reassembly of various components. a. Demonstrate repair procedures for disassembly and reassembly of computers. b. Demonstrate repair procedures for disassembly and reassembly of printers. 8. Construct and test cables. a. Construct various control cables. b. Test various control cables. 9. Isolate a malfunction. a. Determine symptoms of hardware and software failures. b. Perform diagnostic procedures. c. Eliminate the malfunction.

39

10. Demonstrate effective behaviors that contribute to the achievement and maintenance of customer satisfaction. a. Explain what a professional attitude is. b. Utilize professional procedures in a customer interview. c. Conduct isolation procedures.

40

Course Number and Name:

EET 1311 Orientation to Biomedical Equipment Repair

Description:

Orientation to the biomedical equipment repair field. Topics covered are the different career paths open to students, types of biomedical equipment, and the organization and operation of the hospital environment.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

1

1

0

15

Instructor Approved

Student Learning Outcomes: 1. Explain the operation and responsibilities of the clinical engineering department. a. Explain functions and roles. b. Explain how this department’s services are related to the patients. c. Explain end results desired. 2. Identify and describe biomedical devices and related safety issues. a. Describe different types of biomedical equipment. b. Discuss safety issues related to electrical equipment. c. Discuss safety issues related to pathological agents and the risk of infection. 3. Define and discuss the hospital organization of services and how they are delivered. a. Define the legal organization of hospitals. b. Discuss the major organization structure of hospitals. c. Discuss the major services provided by the hospital and the impact on medical equipment repair. d. Develop an organizational chart of a typical hospital. 4. Discuss and define the management by committee concept. a. Define the management by committee concept. b. Explain the advantages and disadvantages of the management by committee concept. c. Identify the major committees within a hospital setting.

41

Course Number and Name:

EET 1334 Solid State Devices and Circuits

Description:

Active devices that include PN junction diodes, bipolar transistors, bipolar transistor circuits, and unipolar devices with emphasis on low-frequency application and troubleshooting

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Explain the characteristics of semiconductor materials and theory of operation of PN junctions. a. Explain basic atomic structure. b. Define intrinsic, P-type, and N-type. c. Analyze an unbiased PN junction. d. Analyze a forward-biased PN junction. e. Analyze a reverse-biased PN junction. 2. Explain semiconductor diode theory and apply to diode circuits. a. Describe the characteristics of a diode. b. Analyze and demonstrate a half-wave rectifier circuit. c. Analyze and demonstrate a full-wave rectifier circuit. d. Analyze and demonstrate a bridge rectifier circuit. 3. Analyze the operation of semiconductor special purpose diodes. a. Analyze and demonstrate the operation of a Zener diode circuit. b. Analyze and demonstrate the operation of a light-emitting diode circuit. c. Explain the characteristics of Schottky diodes. d. Explain the characteristics of varactor diodes. 4. Analyze the operation of bipolar junction transistors. a. Define and identify transistor voltages and currents. b. Analyze and demonstrate the operation of a DC common emitter circuit. c. Demonstrate the use of collector curves. d. Demonstrate the use of load lines. e. Explain and demonstrate base, emitter, and voltage divider biasing. 5. Explain and analyze the construction of BJT amplifiers. a. Analyze and discuss the basic operation of a common emitter voltage amplifier.) b. Given a common emitter amplifier circuit, draw the AC equivalent circuit, and solve for V-in, V-out, and A. c. Explain how the swamped common emitter amplifier works, and discuss its advantages. d. Given a swamped common emitter amplifier circuit, draw the AC equivalent circuit, and solve for Z-in, V-in, V-out, and A. e. Construct a common emitter amplifier, and compare measured parameters to calculated values. f. Given a cascaded common emitter amplifier, calculate gain of stage one, gain of stage two, and output voltage. g. Given a power amplifier circuit, solve for the maximum generator voltage that will produce an unclipped output signal, and solve the maximum efficiency of the amplifier. h. Given an emitter-follower circuit, solve for Z-in, V-in, A, and V-out. i. Describe the characteristics of a Class A power amplifier to include the factors that limit the power rating of a transistor. j. Construct Class A and Class B amplifiers, and troubleshoot the circuits. 42

6. Analyze the operation of field effect transistors, and demonstrate their applications. a. Describe the basic construction of a JFET. b. Calculate the proportional pinch off voltage, and determine the operating area of a JFET. c. Given a JFET circuit, determine ID and Vds. d. Given a JFET amplifier circuit, draw the AC equivalent circuit, and solve for gmo, gm, Z-in, V-in, A, and V-out. e. Given a JFET source follower circuit, with a given gm, solve for V-in, A, and V-out. f. Illustrate the construction of and describe the operation of the depletion-mode and the enhancement-mode MOSFET. g. Analyze other FET applications, such as multiplying, switching, chopper, AGC, and sample and hold amplifier. 7. Analyze the operation of thyristors, and demonstrate their applications. a. Describe the four-layer diode, and discuss how it is turned on and off. b. Describe how the SCR operates in different applications. c. Construct a latching SCR with a varying input voltage, and determine when the output voltage is latched. d. Describe the main characteristics of the variations of the SCR, and discuss the difference in device symbols. e. Describe the characteristics of the diac and triac. f. Calculate the intrinsic standoff voltage for a unijunction transistor (UJT), and state how it works. g. Analyze thyristor applications, such as over voltage detector, sawtooth generator, SCR crowbar, and controlled SCR circuits phase angle controlled circuits. h. Construct thyristor circuits, and vary the latching parameters; measure the output to view switching and control of the device.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

SMC ADVANCED MANUFACTURING CERTIFICATION LEVEL I BASIC© Mechatronics Level I –Basic Basic Sensors

43

Course Number and Name:

EET 1343 Motor Control Systems

Description:

This course covers installation of different motor control circuits and devices. Emphasis is placed on developing the student’s ability to diagram, wire, and troubleshoot the different circuits and mechanical control devices.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Install different control circuits and devices. a. Diagram and wire a two-wire and three-wire motor control circuit with indicating pilot lights. b. Diagram, wire, and troubleshoot an on-delay and off-delay timer circuit. c. Diagram and wire a multi-control manual station. d. Diagram and wire a hands-off automatic control station. e. Diagram and wire a jog-forward/jog-reverse control. 2. Troubleshoot different control circuits and devices. a. Troubleshoot a two-wire and three-wire motor control circuit with indicating pilot lights. b. Troubleshoot an on-delay and off-delay timer circuit. c. Troubleshoot a multi-control manual station. d. Troubleshoot a hands-off automatic control station. e. Troubleshoot a jog-forward/jog-reverse control.

Certification SMC ADVANCED MANUFACTURING CERTIFICATION LEVEL I BASIC© Mechatronics Level I –Basic Basic Sensors

44

Course Number and Name:

EET 1353 Fundamentals of Robotics

Description:

This course is designed to introduce the student to industrial robots. Topics to be covered include robotics history, industrial robot configurations, operation, and basic programming and how they relate to the electrical industry.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Describe the various major components of all robots. a. Explain the axes of movement. b. Label each major component. c. Identify four general types of work envelopes. d. Discuss three general forms of robot actuation. e. Identify different types of input devices used with robot controllers. f. Describe the characteristics of a robot that distinguish it from other types of automated machinery. 2. Demonstrate safety procedures used in the automated environment. a. Apply safety rules for personal and general shop safety including eye, ear, and body protection; general rules of shop conduct; and the use of safety color coding. b. Apply general safety rules for tool and equipment use including hand tools, air and electric power tools, and other shop equipment. c. Apply general safety rules associated with working on various robotics systems. d. Apply rules and procedures associated with fire safety including procedures for handling and storing flammable liquids and proper use of fire fighting devices. 3. Demonstrate the ability to operate robots. a. Evaluate robot performance. b. Apply basic programming skills. c. Identify and discuss end effectors. d. Identify and discuss visual and tactile sensors. e. Demonstrate basic troubleshooting techniques.

45

Course Number and Name:

EET 1363 Microcontrollers

Description:

This course begins with a brief overview of microprocessors as a precursor to microcontrollers. Next, a basic understanding of the use, terminology, and potential of microcontrollers are discussed. Programming skills and concepts taught in this course help students develop, execute, and debug programs for a microcontroller, A hands-on approach will teach the essential skills for creating a simple sensor-driven microcontroller system, and will be reinforced with interactive projects. .

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

3

1

4

75

Instructor Approved

Student Learning Outcomes: 1.

Understand Microprocessor basics a. Discuss the history of microprocessors. b. Explain and identify the internal architecture of microprocessors. c. Discuss the internal and external basic structure and operation.

2.

Analyze Microcontroller Architecture to include: a. Evolution of microcontrollers b. Digital I/O Pins c. Analog Pins d. Memory e. Interrupts and timers f. Buses- I2C, serial, one/two wire, CAN, and SPI

3.

Demonstrate appropriate microcontroller programming techniques such as: a. Programming logic and structures b. Object orientated programming (C#, Python, Java, etc.) c. Graphical programming tools such as LabView

4.

Incorporate sensors, mechanical devices, and displays a. Analog and digital sensors (temperature, light, pressure, etc) b. Mechanical devices (servo, motors, actuator, etc) c. Displays (LCD, TFT, graphical)

5.

Discuss latest trends in embedded systems to include: a. IoT devices b. PLC basics c. Various brands and manufacturers (Arduino, Raspberry Pi, Beagle Bone Black)

46

Course Number and Name:

EET 1413 Mathematics for Electronics

Description:

Coverage of those areas of arithmetic, algebra, geometry, and trigonometry that have applications in electronics

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Demonstrate an understanding of fundamental arithmetic operations. a. Find the common denominator of two of more fractions. b. Add and subtract fractions. c. Multiply and divide fractions. d. Calculate percentages. e. Calculate the value of a number raised to a power. f. Use a calculator to calculate square roots and cube roots. 2. Demonstrate an understanding of systems of measurement. a. Express numerical values using scientific and engineering notation. b. Express measurements using the metric system. c. Express numerical values using engineering prefixes. 3. Demonstrate an understanding of basic algebraic concepts. a. Express numerical values using signed and unsigned numbers. b. Evaluate algebraic expressions using the algebraic hierarchy of operations. 4. Demonstrate an understanding of linear equations. a. Solve first-degree equations using algebraic methods. b. Describe the Cartesian coordinate system. c. Draw graphs of linear equations. 5. Demonstrate an understanding of polynomials. a. Multiply polynomials. b. Combine polynomials using addition and subtraction. c. Factor polynomials. 6. Demonstrate an understanding of second-degree equations. a. Solve second-degree equations by taking square roots. b. Solve second-degree equations by factoring. c. Solve second-degree equations by using the quadratic formula. d. Draw graphs of nonlinear equations. 7. Demonstrate an understanding of solid geometry. a. Calculate the volume of a sphere. b. Calculate the volume of a cone. c. Calculate the surface area of a sphere. d. Calculate the surface area of a cone. 8. Demonstrate an understanding of right-triangle trigonometry. a. Calculate the length of any side of a right-triangle given the length of the other two sides using the Pythagorean formula. 47

b. Define the three primary trigonometric functions (sine, cosine, and tangent). c. Calculate the trigonometric functions given the lengths of the sides of a right triangle. d. Calculate the length of a side of a right triangle given the length of a known side and an angle. e. Calculate an angle of a right triangle given the lengths of two sides. 9. Demonstrate an understanding of vectors. a. Describe the two components of a vector. b. Combine vectors to produce a resultant vector. 10. Demonstrate an understanding of complex numbers and phasors. a. Describe the imaginary value j. b. Express complex numerical values in rectangular form using real and imaginary values. c. Convert complex values from rectangular form to polar form. d. Convert complex values from polar form to rectangular form. e. Draw phasors using complex values.

48

Course Number and Name:

EET 1423 Introduction to Biomedical Equipment

Description:

This course introduces students to biomedical instrumentation and equipment used to measure and monitor biological functions of the human body. While covering most bodily functions, emphasis will be placed on the heart and circulatory system. Students will gain an understanding of instrumentation devices such as electrodes, sensors, transducers, bioelectric amplifiers, electrocardiographs, and other cardiovascular devices.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Describe and explain modern methods of imaging techniques. a. Explain the operation of MRI computer tomography. b. Explain the operation of ultrasonic endoscopy. c. Explain the operation and components of an X ray machine. 2. Describe and explain various types of electrodes, transducers, amplifiers and filters. a. Describe various transducer types as well as their individual use cases. b. Explain the need and operation of preamplifier and amplifier circuits for biomedical instrumentation. c. Describe and explain the construction and use of low pass, high pass, band pass, and band stop filters. d. Explain the operation of various biotelemetry systems. 3. Describe the basic concepts of human anatomy and physiology. a. Identify the various human body systems. b. Describe the function of the respiratory system. c. Describe the function of the circulatory system. d. Describe the function of the nervous system. e. Describe the function of the skeletal system. f. Describe the function of the muscular system. 4. Demonstrate proper use of common biomedical test equipment. a. Describe the function of the EKG machine. b. List basic care and maintenance procedures of the EKG machine. c. List and describe common biomedical health and safety concerns.

49

Course Number and Name:

EET 1443 Fundamentals of Instrumentation

Description:

This course provides students with a general knowledge of instrumentation principles as they relate to the electrical industry. This course includes instruction in the basis of hydraulics and pneumatics and the use of electronic/electrical circuits in the instrumentation process.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Demonstrate a working knowledge of instrumentation as it pertains to the electrical industry. a. Define terms associated with instrumentation. b. Discuss basic theory of hydraulics, pneumatics, and electromagnetic controls. c. Identify basic symbols used with hydraulics, pneumatics, and electromagnetic systems. 2. Identify the type of instrumentation input and output devices, and describe their applications. a. Describe control elements for pressure, flow, temperature, and level. b. Identify the types of input and output devices. c. Describe the input and output devices. 3. Identify the types of electrical signals used in instrumentation. a. Describe the transmission of information to include current, pressure, and frequency. b. Explain the principles of the transmission information input and output. 4. Describe fundamentals of electrical and electronic process controls. a. Label a block diagram of an open loop system and a closed loop system. b. Describe characteristics of an open loop and a closed loop system. 5. Design a preventive maintenance program for instrumentation systems. a. Describe the techniques and procedures for troubleshooting, calibrating, and repairing an instrumentation system. b. Demonstrate the ability to sketch a piping and instrument drawing.

50

Course Number and Name:

EET 1613 Computer Fundamentals for Electronics/ Electricity

Description:

Basic computer science as used in electricity/electronics areas. Computer nomenclature, logic, numbering systems, coding, and operating system commands are covered.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Demonstrate an understanding of essential microcomputer architecture. a. Discuss microcomputer architecture. b. Identify major differences of word length, size of directly addressable memory, and microprocessor speed. c. Draw and label the block diagram for a typical microcomputer indicating all major components. 2. Demonstrate an understanding of microcomputer components and peripherals. a. Discuss the features and concepts related to motherboards including microprocessors and expansion slots. b. Describe the concepts and installation of power supplies. c. Discuss memory concepts, installation, and setup. d. Describe the concepts and installation of peripheral input devices. e. Describe the concepts and management of mass storage devices. f. Discuss the concepts and installation of peripheral devices, such as printers and scanners. g. Discuss the concepts and installation of video monitors and adapters. h. Describe the concepts, installation, and setup of internal modems and sound cards. i. Demonstrate the power on self-test.

3. Demonstrate competency of operating system fundamentals. a. Format, read, and write to storage media. b. Modify the computer display, mouse parameters, and date/time configuration. c. Install and remove hardware and software. d. Explore the system information utility. e. Perform word processing using a word processing application.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

51

Course Number and Name:

EET 1713 Drafting for Electronics Technology

Description:

Preparation and interpretation of schematics, block diagrams, flow charts, and PCB prototyping.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 1

Lab 4

Contact Hours 75

Instructor Approved

Student Learning Outcomes: 1. Demonstrate an understanding of drafting fundamentals. a. Explain the need for national drafting standards. b. Explain the need for drawing quality and standard drawing sizes. c. Explain the requirements for lettering and different line widths. d. Discuss computer aided design (CAD). 2. Demonstrate an understanding of electronic symbols, components, and references used in schematic and logic diagrams. a. Identify components by symbol b. Draw component and schematic symbols to drafting standards. c. Correctly use component references and values. d. Use symbols in schematic diagrams. e. Interpret logic symbols. f. Create formal drawings from an engineering sketch. 3. Demonstrate the ability to compose projections and diagrams. a. Define and identify a perspective drawing. b. Define and create orthographic drawings. c. Apply rules of good dimensioning to mechanical drawing. d. Create printed circuit board assembly drawings. e. Create block, flow, and single-line diagrams. f. Create schematic and logic diagrams. g. Create point-to-point and pictorial point-to-point diagrams. h. Create cable assemblies and interconnection diagrams. 4. Demonstrate an understanding of electronics drafting using CAD. a. Create electronic symbols to drafting standards. b. Insert symbols into drawings. c. Use CAD commands to create drawings and schematic diagrams.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

52

Course Number and Name:

EET 211 (3-6) Supervised Work Experience in Biomedical Equipment Repair Technology I

Description:

This cooperative program between the health-care facility and education is designed to integrate the student’s technical studies with health-care experience. (NOTE: Biomedical equipment used in this course is for instructional purposes ONLY and not to be used in patients’ care.) Variable credit is awarded on the basis of 1 semester hour per 45 health care contact hours.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3-6

Lecture 0

Externship 9-18

Contact Hours 135-270

Instructor Approved

Student Learning Outcomes: 1. Analyze the operation and responsibilities of the clinical engineering department at the supervised work location. a. Analyze the functions and roles of personnel in the clinical engineering department. b. Describe how this department’s services are related to the patients. c. Explain the end results desired from this department. 2. Discuss the various environmental health risks within the hospital. a. Explain precautions to be taken within the hospital. b. Explain the effects of various health risks. c. Develop and discuss preventive actions to be taken in case of a health emergency. 3. Examine the operation of the hospital electrical distribution system. a. Review the electrical layout prints, and locate the electrical distribution system control devices. b. Interpret the symbols and notations on the prints. 4. Read and interpret codes and standards as applied to hospitals. a. Locate codes and standards for various systems. b. Explain the purposes of codes and standards. c. Locate specific codes and standards as required for a particular work task. d. Repair equipment demonstrating utilization of codes and standards. e. Verify safety certification seals. 5. Perform basic preventive maintenance on biomedical equipment. a. Identify the equipment and its functions. b. Locate and interpret specifications for the equipment. c. Diagnose and repair equipment to manufacturer’s specifications. d. Test and verify safety certification seals as required. 6. Conduct performance tests on biomedical equipment. a. Identify the equipment and its function. b. Locate and interpret specifications for the equipment. c. Test the performance of equipment according to manufacturer’s specifications. d. Test and verify safety certification seals as required. Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

53

Course Number and Name:

EET 222 (3-6) Supervised Work Experience in Biomedical Equipment Repair Technology II

Description:

Continuation of EET 211 (3-6) with advanced study in the repair and maintenance of biomedical equipment.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3-6

Lecture 0

Externship 9-18

Contact Hours 135-270

Instructor Approved

Student Learning Outcomes: 1. Test and repair equipment within the respiratory therapy areas. a. Identify the equipment and its function. b. Locate and interpret specifications for the equipment. c. Diagnose and repair equipment to manufacturer’s specifications. d. Test and verify safety certification seals as required. 2. Test and repair equipment within the dialysis laboratory. a. Identify the equipment and its function. b. Locate and interpret specifications for the equipment. c. Diagnose and repair equipment to manufacturer’s specifications. d. Test and verify safety certification seals as required. 3. Test and repair equipment within the diagnostic laboratory. a. Identify the equipment and its function. b. Locate and interpret specifications for the equipment. c. Diagnose and repair equipment to manufacturer’s specifications. d. Test and verify safety certification seals as required 4. Test and repair equipment within the radiological, nuclear, and ultrasound area. a. Identify the equipment and its function. b. Locate and interpret specifications for the equipment. c. Diagnose and repair equipment to manufacturer’s specifications. d. Test and verify safety certification seals as required. 5. Test and repair laser equipment. a. Identify the equipment and its function.) b. Locate and interpret specifications for the equipment. c. Diagnose and repair equipment to manufacturer’s specifications. d. Test and verify safety certification seals as required. 6. Utilize computers in clinical engineering. a. Apply basic rules for the operation and use of computers. b. Discuss the place for computers within the health center. c. Perform basic computer operations.

54

Course Number and Name:

EET 2233 Computer Servicing Lab II

Description:

This course is a continuation of Computer Servicing Lab I with increased emphasis on system analysis and diagnosis of board and component failures with emphasizes on laboratory experience with computer repair.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 0

Lab 6

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Maintain a service log on individual pieces of equipment. a. Identify components being repaired. b. Make a report of symptoms, repair procedures, and parts replaced. 3. Service peripherals and components. a. Explain the procedures for servicing peripherals and various components. b. Clean peripherals and various components. 4. Troubleshoot and service or replace computer components. a. Troubleshoot and service or replace a computer’s central processing unit (CPU). b. Troubleshoot and service or replace computer memory circuits. c. Troubleshoot and service or replace computer video circuits. d. Troubleshoot and service or replace computer controller boards. e. Troubleshoot and service or replace computer power supply. f. Troubleshoot and service or replace computer keyboard problems. g. Troubleshoot and service or replace computer monitors and liquid crystal displays. h. Troubleshoot and service or replace computer printers.

55

Course Number and Name:

EET 2334 Linear Integrated Circuits

Description:

Advanced semiconductor devices and linear integrated circuits. Emphasis is placed on linear integrated circuits used with operational amplifiers, active filters, voltage regulators, timers, and phase-locked loops.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 3

Lab 2

Contact Hours 75

Instructor Approved

Student Learning Outcomes: 1. Analyze and demonstrate the effects of frequency on amplifiers. a. Define what is meant by frequency response. b. Determine the input and output capacitances of an amplifier. c. Discuss the characteristics of the frequency response of an amplifier. d. Identify the critical frequencies in the response of an amplifier. e. Analyze the effects of coupling and bypass capacitors at low frequency. f. Relate the upper limit of the frequency response at high frequencies to the internal capacitances of the amplifier’s transistors. g. Define midrange gain of an amplifier. h. Define the term “roll off,” and explain what factors determine it. i. Compare direct-coupled and capacitive coupled amplifiers in terms of their low frequency response. 2. Describe the principles, operation, and characteristics of an operational amplifier. a. Explain the operation of a basic differential amplifier. b. Use a circuit diagram to fabricate a differential amplifier and demonstrate its use in at least the following three modes: Single-ended input, differential input, or common mode input. c. Draw and label the schematic symbol of the basic operational amplifier (op-amp). d. Compare the ideal op-amp characteristics with the practical op-amp characteristics. e. Interpret manufacturer’s specifications, including package type, pinouts, input offset voltage, input bias current, input impedance, input offset current, output impedance, common made range, open loop voltage gain, CMRR, and slew rate. f. Discuss positive and negative feedback and how it is used in amplifiers. g. Distinguish between the open-loop voltage gain and closed-loop voltage gain of an opamp. h. Define frequency response as it relates to op-amps. i. Define stability, and discuss the factors that affect the stability of an op-amp. 3. Describe and demonstrate the function and operational characteristics of op-amps in linear and nonlinear applications. a. Recognize and analyze inverting, non-inverting, and voltage follower op-amp configurations. b. Construct, troubleshoot, and demonstrate a circuit using an op-amp as an inverting, a non-inverting, and a voltage follower amplifier using the appropriate components with a circuit diagram. c. Explain the relationship of gain and frequency response in an op-amp circuit. d. Explain, recognize, and use each of the following circuits: Summing amplifier, instrumentation amplifier, averaging amplifier, and scaling amplifier. e. Explain, recognize, and use each of the following filters: Low-pass, high-pass, band pass and band-stop. f. Construct, troubleshoot, and demonstrate A/D and D/A circuits. g. Explain, recognize, and use the following circuits: Zero-level detection comparator, non-zero-level detection comparator, integrator, and differentiator. h. Explain the function of a Schmitt trigger. i. Explain the function of an oscillator. 56

j. List the conditions required to sustain oscillation in a circuit. k. Illustrate the use of a 555 as an oscillator. l. Explain, recognize, and use an op-amp configured to operate in each of the following types of oscillators: Wien-bridge, phase-shift, twin-T, Colpitts, Clapp, Hartley, and Armstrong. m. Describe the use of a quartz crystal in an oscillator circuit. n. Explain the use of an op-amp in a non-sinusoidal oscillator. o. Explain the use of an op-amp in a voltage-controlled oscillator. 4. Describe the function and operating characteristics of voltage regulators. a. Explain the basic concept of voltage regulation. b. Differentiate between line and load regulation. c. Recognize a basic series voltage regulator circuit, and describe the circuit’s operating characteristics. d. Recognize a basic shunt voltage regulator circuit, and describe the circuit’s operating characteristics. e. Differentiate between linear and switching voltage regulators. f. Recognize typical IC linear and switching regulators. Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

57

Course Number and Name:

EET 2354 Solid State Motor Control

Description:

The course covers the principles and operation of solid state motor control as well as the design, installation, and maintenance of different solid state devices for motor control.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Apply general safety principles and safety requirements for working on and around electrical motors. a. Apply principles of safety in the use of electrical motors. b. Describe safety procedures to utilize during connecting and operating electric motors. 2. Troubleshoot solid state motor controls. a. Identify electronic and industrial symbols used to represent logic gates in solid state schematics. b. Describe the operation of the different types of industrial and electronic logic gates. c. Draw a solid state logic circuit to replace a manual control station. d. Troubleshoot and repair/replace solid state devices to include memory devices, flip/flops, adjustable time delays, starting and stopping sequences, and looping. 3. Operate AC and DC variable speed drives. a. Discuss the operation of a DC variable speed drive. b. Discuss the operation of an AC variable speed drive. c. Connect and operate DC and AC variable speed drives

58

Course Number and Name:

EET 2363 Programmable Logic Controllers

Description:

This course covers use of programmable logic controllers (PLCs) in modern industrial settings as well as the operating principles of PLCs and practice in the programming, installation, and maintenance of PLCs.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Explain principles of PLCs. a. Identify components and operational principles of PLCs. b. Differentiate between a PLC and a computer. 2. Identify different types of PLC hardware. a. Identify and wire different types of input and output modules. b. Identify different types of PLC processor modules, memory capabilities, and programming devices. 3. Explain numbering systems, encoding/decoding, and logical operations. a. Convert numbers from one system to another. b. Explain logical operations using truth tables and ladder logic diagrams. 4. Program all types of internal and discrete instructions. a. Program examine on and off instructions. b. Program on-delay and off-delay instructions. c. Program up-counter and down-counter instructions. d. Program sequencer instructions for real-world output devices. e. Program latch and unlatch instructions. 5. Demonstrate an understanding of configuring input/output connecting and terminating sensors and field devices. 6. Troubleshoot and maintain different programmable controller systems. a. Identify and troubleshoot the power supply. b. Identify and troubleshoot the inputs and outputs (I/O) cards. c. Identify and troubleshoot real-world inputs and outputs.

Certification SMC ADVANCED MANUFACTURING CERTIFICATION LEVEL I BASIC© Mechatronics Level I –Basic Basic Programmable Controllers

59

Course Number and Name:

EET 2373 Programmable Logic Controllers Multi-Platform

Description:

This course covers use of programmable logic controllers (PLCs) in modern industrial settings as well as the operating principles of PLCs and practice in the accelerated programming across multiple PLC platforms, installation and maintenance of PLCs.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 1

Lab 4

Contact Hours 75

Instructor Approved

Student Learning Outcomes: 1. Explain principles of PLCs. a. Identify components and operational principles of PLCs. b. Differentiate between a PLC and a computer. 2. Identify different types of PLC hardware. a. Identify and wire different types of input and output modules. b. Identify different types of PLC processor modules, memory capabilities and programming devices. 3. Explain numbering systems, encoding / decoding, and logical operations. a. Convert numbers from one system to another. b. Explain logical operations using truth tables and ladder logic diagrams. 4. Program different types of internal and discrete instructions. a. Program examine on and off instructions. b. Program on-delay and off-delay instructions. c. Program up-counter and down-counter instructions. d. Program sequencer instructions for real-world output devices. e. Program latch and unlatch instructions. 5. Demonstrate an understanding of configuring inputs and outputs, connecting sensors, and reading and controlling field devices. a. Identify and troubleshoot the power supply. b. Identify and troubleshoot the inputs and outputs. c. Identify and troubleshoot real-world inputs and outputs. 6. Use program control instructions and subroutines to control program function. 7. Use math instructions to manipulate outputs of a program. a. Enter and edit a PLC program that uses the add instruction. b. Enter and edit a PLC program that uses the add instruction. c. Enter and edit a PLC program that uses the multiply instruction. d. Enter and edit a PLC program that uses the divide instruction. e. Enter and edit a PLC program that uses a data move instruction.

60

Course Number and Name:

EET 2374 Advanced Robotics

Description:

This course provides advanced instruction to microcontrollers and robotics, with a focus on the operation and execution of a robotic system. This course will be project and team based. Students will work in groups to design, program, and execute their robotic design. Students will present their designed robot, along with a PowerPoint presentation at the end of the course.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

1

4

75

Instructor Approved

Student Learning Outcomes: 1. Demonstrate safety procedures used in the automated environment a. Apply safety rules for person and general shop safety including eye, ear, and body protection; general rules for shop conduct; and the use of safety color coding b. Apply general safety rules for tool and equipment use including hand tools, air, and electric power tools, and other shop equipment c. Apply general safety rules associated with working on various robotics systems

2.

Students will build and program a robot of their design a. Come up with a real world application of the robot they would like to design b. Program robots with Robot C, Basic, or C+ c. Design a PowerPoint presentation for the project d. Present their project at the end of the course

61

Course Number and Name:

EET 2383 Advanced Programmable Logic Controllers

Description:

Advanced PLC course that provides instruction in the various operations, installations, and maintenance of electric motor controls. Also, information in such areas as sequencer, program control, introduction to function blocks, sequential function chart, introduction to HMI, and logical and conversion instructions.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Program all types of high order instructions. a. Calculate and develop mathematical instructions to include addition, subtraction, multiplication, and division. b. Program and set up a chart for input and output sequencer combination. c. Program and set up an analog input and output card using PLC software. d. Explain the use of function block and sequential function blocks in a programmable logic controller. e. Demonstrate the ability to develop a basic Human to Machine Interface (HMI) project. f. Program and demonstrate how to set up a produce and consume tab/message. 2. Troubleshoot advanced PLC controls. a. Troubleshoot an analog input and output card. b. Troubleshoot communication devices used in networking.

62

Course Number and Name:

EET 2414 Electronic Communications

Description:

This course is designed to provide the student with concepts and skills related to analog and digital communications. Topics covered include amplitude and frequency modulation, transmission, and reception; data transmission formats and codes; and modulation demodulation of digital communications.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Explain the operation of the components of a communication system. a. Explain and demonstrate the operation of radio frequency (RF) amplifiers. b. Explain and demonstrate the operation of RF oscillators. c. Explain and demonstrate the operation of RF filters. d. Explain and demonstrate the operation of RF mixers. e. Explain and demonstrate the operation of a phase-locked loop. f. Demonstrate how these components are used together to implement a receiver and a transmitter. 2. Explain and perform signal and noise analysis. a. Convert between dB and voltage gain ratios and between dB and power gain ratios. b. Use dB and dBm to express the gain and power level of cascaded stages. c. Explain electrical noise and noise figures, and calculate noise figures for cascaded systems. d. Explain and calculate noise floor and signal to noise ratio for components and systems. e. Explain and use the power spectrum to represent RF signals. 3. Analyze and demonstrate the characteristics and operation of amplitude modulation (AM) systems. a. Explain and graph AM signals in time and frequency domains. b. Explain and calculate modulation index for AM. c. Explain AM generation and detection. d. Analyze and demonstrate an AM transmitter/receiver link. e. Explain and graph AM SSB signals in time and frequency domains. f. Explain AM SSB generation and detection. g. Analyze and demonstrate an AM SSB transmitter/receiver link. 4. Analyze and demonstrate the characteristics and operation of frequency modulation (FM) systems. a. Describe and graph FM signals in time and frequency domains. b. Explain and calculate modulation index for FM. c. Explain FM generation and detection. d. Explain stereo FM systems. e. Analyze and demonstrate an FM transmitter/receiver link. 5. Analyze and demonstrate the characteristics and operation of digital modulation. a. Analyze and explain pulse modulation systems. b. Analyze and explain frequency shift keying systems. c. Analyze and explain phase shift keying systems to include BPSK, QPSK, and higher orders. d. Analyze and explain quadrature amplitude modulation systems to include higher orders. e. Analyze and explain error correcting codes. 6. Analyze and explain the characteristics of wave propagation, antennas, and transmission lines. a. Explain the characteristics of a transmission line, and represent it by an equivalent circuit. 63

b. Explain wave propagation through transmission lines. c. Explain wave reflections and standing waves in transmission lines. d. Analyze and demonstrate electromagnetic wave propagation. e. Analyze and explain the characteristics of various types of antennas.

Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

64

Course Number and Name:

EET 2423 Fundamentals of Fiber Optics

Description:

Fiber-optic cable in modern industry applications

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 1

Lab 4

Contact Hours 75

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Describe the history and advantages of fiber-optic systems. a. Describe the limitations of wire communications systems. b. Describe the technical developments making optical fiber communications feasible to include bandwidth capabilities. c. List the advantages of optical fiber communications over electrical wire communications. 3. Explain the operation and application of optical signal sources. a. Apply appropriate safety practices to optical signal sources. b. Explain the advantages and disadvantages of LEDs as optical signal sources. c. Describe the principle of operation of semiconductor lasers. d. Explain the advantages and disadvantages of lasers as optical signal sources. e. Explain the operation of modulator circuits for optical signal sources. 4. Explain the operation and application of fiber-optic system components. a. Describe the construction of optical fibers. b. Explain optical fiber cable specifications. c. Describe the operation of detectors used in fiber-optic systems. d. Explain the operating principle and purpose of transceivers and repeaters. 5. Explain the theory of light propagation in vacuum and in optical fiber. a. Explain the modes of optical fiber light transmission. b. Describe the light loss mechanisms that occur in optical fibers. c. Describe the use of Snell’s law as it relates to fiber optics. d. Describe dense wavelength division multiplexing (DWDM). 6. Describe properties of different types of optical fibers. a. Differentiate between the properties and characteristics of plastic and glass optical fibers. b. Describe the effect of core size on efficiency and bandwidth. c. Describe fiber-optic cables available for indoor and outdoor installation. d. Prepare and complete a splice of fiber-optic cable following industry standards and safety procedures. e. Describe requirements for certification as a fiber-optic technician. Certification ASSOCIATE C.E.T. (CETa) - COMPETENCY LISTING BASIC ELECTRONICS CERTIFICATION

65

Course Number and Name:

EET 2433 Physics for Electronics

Description:

Coverage of those areas of physics that have applications in electronics

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Demonstrate an understanding of vectors. a. Describe the two components of a vector. b. Combine vectors to produce a resultant vector. 2. Demonstrate an understanding of mechanics. a. Define velocity and acceleration. b. Define force. c. Describe Newton’s laws of motion. d. Define work, energy, momentum, and power. e. Define friction. f. Calculate the centrifugal force on an object in circular motion. g. Define torque. 3. Demonstrate an understanding of the mechanical properties of matter. a. Describe the structure of matter. b. Describe the properties of solids, liquids, and gases. 4. Demonstrate an understanding of heat and thermodynamics. a. Define temperature. b. Describe methods for measuring heat. c. Describe the change of state of matter relative to temperature. d. Define heat conduction, convection, and radiation. e. Describe the refrigeration process.

66

Course Number and Name:

EET 2514 Interfacing Techniques

Description:

Data acquisition devices and systems including their interface to microprocessors and other control systems

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Digital Electronics

Student Learning Outcomes: 1. Describe interfacing standards organizations. a. Explain the role of organizations in U.S. Standards Development (i.e., EIA and TIA). b. Explain the role of organizations in Global Standards Development (i.e., ANSI). c. Explain the application of an RS232 interface. d. Explain the application of a GPIB interface. e. Explain the application of an HPIB interface. f. Explain the application of an IEEE488 interface. 2. Identify signals related to communication ports. a. Recognize serial interface standards such as RS232, USB, FireWire, and SATA. b. Recognize parallel port standards. c. Recognize wireless interfacing standards. 3. Identify signals related to computer peripheral communication ports. a. Explain the purpose, capabilities, and fundamental operation of display devices. b. Explain the purpose, capabilities, and fundamental operation of a modem. c. Explain the purpose, capabilities, and interface standards of storage devices. 4. Explain and demonstrate methods for converting physical variables and interfacing transducers. a. Describe and demonstrate the operation and interfacing of optical sensors, temperature sensors, strain gauges, flow sensors, proximity sensors, and Hall-effect sensors. b. Describe and demonstrate the operation and interfacing of digital to analog converters and analog to digital converters. 5. Use a microprocessor to evaluate data as a result of physical variables taking place. a. Describe D/A operation and parameters (resolution, setting time, accuracy, and linearity). b. Draw and connect circuits interfacing D/A with any number of bits to a microcomputer. c. Describe A/D operation and parameters. d. Draw and connect circuits interfacing A/D converters to a microcomputer. e. Describe how feedback is used in control loops.

67

Course Number and Name:

EET 2524 Communication Methods and Technology

Description:

This course is designed to provide the student with concepts and skills related to analog and digital communication. Topics covered include amplitude and frequency modulation, transmission, and reception; data transmission formats and codes; and modulation demodulation of digital communications.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Explain and identify the components and characteristics of a communication system. A. Identify and explain components and subjects relating to transmission, reception, modulation, and multiplexing in a given communications system. B. Explain and demonstrate signal to noise analysis. C. Explain and calculate bandwidth over AM, FM, and PM type systems. D. Demonstrate the installation and termination of cable and connector types including Cat5e with RJ45, RG6 with BNC and F type, single mode and multimode fiber with SC, and multipair telecom wiring using 66 punch down blocks. 2. Identify and explain internetworking devices and architectures. A. Explain the differences and use scenarios for PAN, LAN, WAN, and MAN networks. B. Explain the differences and use scenarios for star, ring, mesh, and bus topologies. C. Identify and explain the use for repeaters, gateways, bridges, routers, hubs and switches. D. Discuss wireless networking equipment. E. Analyze and explain the characteristics of wave propagation, antennas, and transmission lines. 3. Explain the characteristics of a transmission line, and represent it by an equivalent circuit. A. Explain wave propagation through a transmission line. B. Analyze and demonstrate electromagnetic wave propagation. 4. Explain the operation and application of fiber optic system components. A. Describe the construction of optical fibers. B. Explain optical fiber specifications. C. Describe the operation of detectors used in fiber optic systems. D. Explain the operating principle and purpose of transceivers and repeaters. E. Describe the history and advantages of fiber optic systems. 5. Describe the limitations of wire communication systems. A. Describe the technical developments making optical fiber communications feasible to include bandwidth capabilities. B. List the advantages of optical fiber communications over electrical wire communications.

68

Course Number and Name:

EET 2534 Industrial Motor Controls

Description:

This course covers installation, maintenance, and troubleshooting of electric motor control systems. Emphasis is placed on developing the student’s ability to diagram, wire, and troubleshoot motor circuits controlled by both conventional and solidstate devices such as variable speed drives and PLCs.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 4

Lecture 2

Lab 4

Contact Hours 90

Instructor Approved

Student Learning Outcomes: 1. Apply general safety principles and safety requirements for working on and around electrical motors. a. Describe the principles of electrical safety including the proper use of PPE. b. Describe safety procedures to utilize during connecting and operating electric motors. 2. Demonstrate the installation and operation of AC motor control systems. a. Diagram and wire a two-wire and three-wire motor control circuit with indicating pilot lights. b. Diagram and wire an on-delay and off-delay timer circuit. c. Diagram and wire a multi-control manual station. d. Diagram and wire a jog-forward/jog-reverse control circuit. 3. Troubleshoot different electric motor control circuits and devices. a. Troubleshoot a two-wire and three-wire motor control circuit with indicating pilot lights. b. Troubleshoot an on-delay and off-delay timer circuit. c. Troubleshoot a multi-control manual station. d. Troubleshoot a jog-forward/jog-reverse control circuit. 4. Demonstrate the application of frequency drives and PLCs in motor control. a. Install, set up, and operate an AC motor drive. b. Install, set up, and operate a DC motor drive. c. Install, set up, and operate a PLC motor control circuit.

69

Course Number and Name:

EET 2823 Digital Television Systems

Description:

Circuits and systems used in the production, transmission, and reception of video information to include color systems and computer-video interfacing

Hour Breakdown:

Prerequisite:

Semester Credit Hours 3

Lecture 2

Lab 2

Contact Hours 60

Instructor Approved

Student Learning Outcomes: 1. Describe how a digital television signal is developed and broadcasted. a. Name and describe the signals transmitted by a television station. b. Explain frequency allocation and how it relates to television signals. c. Describe vestigial sideband transmission. d. List the channel allocations for VHF and UHF television. e. Explain the process whereby colors are differentiated within a video camera and are encoded into a digital bitstream. f. Draw the diagram of a typical television station, and describe the function of each block. 2. Describe digital encoding methods for video and audio. a. Describe how images are converted into digital bitstreams. b. List and describe video and audio compression systems. c. List and describe broadcast industry encoding standards. d. List and describe the different digital video quality signals, and state the bandwidth required for each type. e. Describe the types of subchannels that can be transmitted within terrestrial digital broadcast signals. 3. Describe the operation of a digital television receiver. a. Draw the block diagram of a digital television receiver. b. Explain the function of each block in the diagram of a digital television receiver. c. Explain the function and adjustment of the controls of a digital television receiver. d. Describe, analyze, and troubleshoot the power supply in a digital television receiver. e. Describe the operation of the tuner in a digital television receiver. f. Explain the operation of the digital signal processing section of a digital television receiver. g. Explain how the picture is developed on the display. 4. Explain the safety hazards inherent in a television receiver. a. Describe the shock hazards associated with high voltages. b. Explain when and how an isolation transformer should be used. c. Describe the safe way to discharge a high-voltage capacitor. 5. Explain the principles of computer logic applied to TV for producing special effects. a. List special effects provided by many TV sets. b. Explain how special effects are produced using digital technology. 6. Explain the operation of a video display system. a. Explain picture quality and resolution. b. List and describe the different aspect ratios, pixel dimensions, and scanning methods used in modern display systems. c. List and describe the different methods for producing display images. d. Explain the difference between vertical and horizontal resolution. e. Explain why a comb filter contributes to good picture quality.

70

Course Number and Name:

EET 291 (1-3) Special Project

Description:

Practical application of skills and knowledge gained in other technical courses. The instructor works closely with the student to ensure that the selection of a project will enhance the student’s learning experience.

Hour Breakdown:

Prerequisite:

Semester Credit Hours 1-3

Lecture 0

Lab 2-6

Contact Hours 30-90

Instructor Approved

Student Learning Outcomes: 1. Develop a written plan that details the activities and projects to be completed. a. Utilize a written plan that details the activities and projects to be completed. b. Perform written occupational objectives in the special project. 2. Assess accomplishment of objectives. a. Prepare daily written assessment of accomplishment of objectives. b. Present weekly written reports of activities performed and objectives accomplished to the instructor. 3. Utilize a set of written guidelines for the special project. a. Develop and follow a set of written guidelines for the special project.

71

Course Number and Name:

EET 292 (1-6) Supervised Work Experience in Electronics Technology

Description:

This cooperative program between industry and education is designed to integrate the student’s technical studies with industrial experience. Variable credit is awarded on the basis of 1 semester hour per 45 industrial contact hours

Hour Breakdown:

Prerequisite:

Semester Credit Hours 1-6

Lecture 0

Externship 3-18

Contact Hours 45-270

Instructor Approved

Student Learning Outcomes: 1. Apply technical skills needed to be a viable member of the workforce. a. Prepare a description of technical skills to be developed in the supervised work experience program. b. Develop technical skills needed to be a viable member of the workforce. 2. Apply skills developed in other program area courses. a. Perform skills developed in other program area courses in the supervised work experience program. 3. Apply human relationship skills. a. Practice human relationship skills in the supervised work experience program. 4. Apply and practice positive work habits and responsibilities. a. Perform assignments to develop positive work habits and responsibilities. 5. Work with the instructor and employer to develop written occupational objectives to be accomplished. a. Perform written occupational objectives in the supervised occupational experience program. 6. Assess accomplishment of objectives. a. Prepare daily written assessment of accomplishment of objectives. b. Present weekly written reports of activities performed and objectives accomplished to the instructor. 7. Utilize a set of written guidelines for the supervised work experience. a. Develop and follow a set of written guidelines for the supervised work experience.

72

Course Number and Name:

TCT 1114 Fundamentals of Telecommunications

Description:

History of voice/data communication, fundamental concepts of analog and digital communications, and basic telephone service.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

3

2

75

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Discuss the history and development of voice/data communications. a. Define telecommunications systems, and describe their identifying characteristics. b. Identify and describe the principal types of telecommunication systems available today. c. Explain the interrelationship between communications technology and computer technology and its effect upon both industries. d. Discuss historical telecommunications policy in the United States and the factors leading to its modification. e. Describe the restructuring of the telecommunications industry. f. Discuss education and career opportunities in telecommunications. g. Define and discuss common carriers. h. Discuss the origin and the present status of the interconnect industry. i. Discuss the origin and present status of specialized common carriers. 3. Define, describe, and discuss all aspects of basic telephone service. a. Describe the principal parts of the telephone, and explain the function of each. b. Define central office, and explain its purpose. c. Describe the evolution of telephone switching equipment. d. Describe the characteristics of analog and digital signals. e. Describe the nationwide and worldwide numbering systems. f. Name and describe the principal types of telephone systems, telephone sets, and service features. g. Assemble/disassemble telephone sets. h. Perform functionality tests on a telephone set. 4. Define, describe, and discuss fundamental concepts of analog communications. a. Identify and describe the characteristics of analog signals. b. Identify and describe the characteristics of noise to include impulse noise and thermal noise. c. Identify bands in the electromagnetic spectrum. d. Identify and describe continuous wave (CW) transmission, amplitude modulation (AM) transmission, frequency modulation (FM) transmission, and phase modulation (PM) transmission. e. Describe modulation index and sidebands for AM and FM signals. f. Identify and describe the characteristics of transmission lines. 5. Define, describe, and discuss fundamental concepts of digital communications. 73

a. Differentiate between analog and digital signals. b. Describe the major concepts of digital communications including modems, PAM, PWM, PPM, DM, PCM, PSK, FSK, QAM, and DSP. c. Discuss the basic modes of transmission and their relation to various types of transmission media. d. Define data communications systems, and explain their purpose. e. Discuss and distinguish between the different types of data processing. f. Discuss the interrelations of different technologies associated with local and long distance telephone services. g. Identify and locate data communications specific parts of a typical computer system. 6. Define, describe, and discuss telecommunications traffic engineering, management, and system implementation. a. Discuss traffic engineering as it relates to telecommunications. b. Discuss busy-hour traffic and peak traffic as it relates to the prediction of future telephone usage and needs. c. Describe the basic functions and skills required of a telecommunications manager. d. Describe and discuss telecommunications policy as it relates to telephone usage. e. Describe the role of the telecommunications manager. f. Describe the implementation of a new telephone system, and describe the function of a consultant in this process. CTNS: Certified Telecommunications Network Specialist Course 2206 Wireless Telecommunications

74

Course Number and Name:

TCT 2244 Fundamentals of Telephony

Description:

Understand telephone companies and the telephone network, regular telephone service, how calls are established end –to end, network equipment, the outside plant, loops , remotes, Cos and telephony jargon and buzzwords.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

3

2

75

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Explain and analyze all aspects of basic telephone service. a. Explain the principal parts of the telephone and the function of each. b. Explain central office and its purpose. c. Explain the evolution of telephone switching equipment. d. Analyze the characteristics of analog and digital signals. e. Explain the nationwide and worldwide numbering systems. f. Differentiate between landline and wireless telephone systems. g. Troubleshoot telephone sets. h. Differentiate between POTS and PSTN and describe their main components. i. Analyze the founding, break-up and re-emergence of AT&T in the US: TELUS and Bell Systems in Canada. 3. Explain and test the operation and installation of key systems. a. Describe the key system’s advantages, components and their functions, voltages, and operation. b. Describe the uses and limitations of block diagrams as they relate to installation. c. Develop an installation plan to include results of the site survey, floor plans, set locations, equipment locations, list of materials, and cost. d. Locate, identify, and interpret blueprint symbols for telephone installation. e. Install a key system using the proper tools, following manufacturer’s specifications, following proper grounding procedures, and following all applicable safety practices. f. Explain how and why remotes are used; and analyze how fiber is developed for neighborhoods. g. Identify malfunctions in the key system using approved troubleshooting procedures, and make repairs as necessary. 4. Explain and test the operation and installation of digital key systems. a. Identify and describe the advantages, components and their functions, voltages, and operation. b. Describe the uses and limitations of block diagrams as they relate to installation. c. Explain and define the use and interconnection of data communications systems with a digital key system including fiber interface, ISDN, and T-1’s. 75

d. Explain and outline network protocol as it pertains to the digital key system interaction with data communications networks. e. Develop an installation plan including results of the site survey, floor plans, set locations, equipment locations, list of materials, and cost. f. Install a key system using the proper tools, following manufacturer’s specifications, following proper grounding procedures, and following all applicable safety practices. g. Identify malfunctions in the digital key system using approved troubleshooting procedures, and make necessary repairs. h. Explain why telecom networks are divided into local access wiring and long-distance transmission. i. Describe how and explain why the telephone system can limit frequencies to the voice band. 5. Explain and test the operation of a PBX system. a. Identify and explain the parts of a PBX system. b. Explain the function of PBX circuits. c. Explain PBX features. d. Inspect PBX circuits. e. Explain telephony using the Internet protocol (voice-over IP). f. Analyze examples of sophisticated call routing using SS7. g. Explain touch-tone dialing and how DTMF works.

76

Course Number and Name:

TCT 2354 Fundamentals of Wireless Technology

Description:

Theories and applications of digital communications and analog pulse modulation.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

2

4

90

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2. Explain, calculate, and measure the characteristics of purely digital communication. a. Explain and analyze why radio frequencies are in the Gigahertz range, used within frequency bands measured in the Megahertz wide range. b. Examine old-fashioned analog radio and TV, and analyze what most systems use today. c. Explain and calculate bit rate and bit time for baseband communication. d. Identify and explain digital encoding methods. e. Encode binary data using digital encoding methods. f. Identify and explain the characteristics and differences of asynchronous and synchronous data transmission. g. Identify and explain the characteristics and differences of error detection and correction methods used in data communications. h. Identify serial communication standards, and explain the digital encoding method, synchronization method, error detection method, typical media, and packet structure for each standard. 3. Define and analyze spectrum as it relates to radio frequencies allocated to the mobile industry and other sectors for communication over the airwaves. a. Differentiate between standardized bands of frequencies, and explain how they are allocated when it requires license for operation. b. Examine which bands are used for cordless phones, to WiFi, and cellular, including the new 700-MHz bands. c. Explain and perform experiments to compare ideal and practical band-limited systems. d. Compare and perform experiments to measure the relationship between noise power and noise bandwidth. 4. Explain, define, and measure and troubleshoot different radio transmission issues. a. Explain and analyze the radio propagation model and its characteristics. b. Define, explain, and analyze radio frequency penetration through physical barriers. c. Define, explain, and analyze fading and its variables in communications.

77

d. Explain and perform experiments to generate pulse width modulation (PWM) and pulse position modulation (PPM) signals. e. Define, explain, and perform experiments to determine the effects of noise and band limiting on PWM/PPM. f. Troubleshoot the PWM/PPM communications system. g. Troubleshoot the PWM/PPM communications system.

78

Course Number and Name:

TCT 2364 Wireless Telecommunications Technology

Description:

Theories and applications of digital modulation methods and digital pulse modulation methods

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

2

4

90

Instructor Approved

Student Learning Outcomes: 1. Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards. 2.

Explain, define, and measure the cellular principles and AMPS (1G). a. Explain, define, and measure Coverage, capacity and cellular radio systems. b. Define mobility, spectrum, and FDM spectrum sharing; perform experiments to compare the relationship between frequency and time characteristics. c. Examine and explain spectrum-sharing technologies such as FDMA, TDMA, CDMA, and OFDM. d. Explain the basic ideas behind CDMA and its operation in relation to 1X vs. UMTS standards (3G Cellular CDMA). e. Define and analyze digital cellular operations and data communications as it relates to the use of RF modems and analyze the method of tethering using the antenna of a cell phone. f. Examine Steve Jobs OFDM basic principles of operations relative to the development of 4G Mobile Cellular LTE.

3.

Explain, and analyze mobile network components, configuration, jargon and basic operations. a. Identify and explain handsets, base stations, air-link, handoffs, and connection wireline systems. b. Explain and differentiate between the basic principles of communication satellites in relation to geosynchronous and LEO. c. Identify and explain the basic principles of operation for 802.11 Wireless LANs, 802.11 standards, and frequency bands and limitations.

4.

Explain, calculate, and measure the characteristics of digital communication methods used to convey analog signals. a. Analyze components and operation of a digital radio; microphone, codec, RF modem, and antennas. b. Explain, calculate, and measure the characteristics of purely analog communication. c. Identify and explain the characteristics and differences of analog and digital signals. d. Identify and explain the characteristics of noise. e. Explain, calculate, and measure the gain, decibel gain, bandwidth, and signal-to-noise ratio of amplifier circuits and filters. f. d. Identify bands in the electromagnetic spectrum.

79

5.

Explain, calculate, and measure the characteristics of analog communication methods used to convey digital information. a. Identify and explain the methods used to digitally modulate analog carrier signals. b. Identify digital modulation constellations. c. Identify which digital modulation methods are used in wireless communications. d. Identify which digital modulation methods are used over wires. e. Explain the operation of telephone modems. f. Identify international telephone modem standards. g. Configure a telephone modem. h. Communicate over a telephone connection using the configured modem. i. Identify cable modem standards and explain how cable modems communicate. j. Explain digital subscriber line (DSL) communications.

80

Course Number and Name:

TCT 2414 Microwave and Satellite Systems

Description:

Theories and applications of microwave and satellite communications.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

3

2

75

Instructor Approved

Student Learning Outcomes: 1.

Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards.

2.

Identify and explain general wireless communications and microwave concepts. a. Explain and calculate period, frequency, and wavelength. b. Identify the standard frequency bands within the electromagnetic spectrum. c. Identify the frequency band within the microwave spectrum. d. Compare advantages and disadvantages of communicating with microwaves. e. Draw block diagrams of a typical microwave radio transmitter and receiver system, and explain the operation of each.

3.

Identify and describe functions of microwave system components. a. Identify and explain the functions of discrete microwave electronic components. b. Identify and explain transmission lines and components made from microstrip and stripline. c. Calculate frequency values of microstrip and stripline circuit elements. d. Compare advantages and disadvantages of different types of microwave transmission lines. e. Identify and explain the use of the different types of microwave antennas. f. Explain the operation of different types of microwave oscillators and amplifiers. g. Identify and explain the operation of low-noise amplifiers in microwave receivers.

4.

Identify and explain microwave applications. a. Explain the operation of terrestrial microwave communication systems. b. Explain the difference among terminal, junction, and point-to-point relay stations used in terrestrial microwave communication systems. c. Explain the operation of microwave satellite communication systems. d. Identify the types of satellite systems, and explain their functions and differences. e. Draw and explain block diagrams of up-link and down-link satellite systems. f. Draw and explain a block diagram of a typical communication satellite. g. Explain the basic principles of microwave satellite transmission and reception. h. Set up C-band and KU-band television receive only (TVRO) satellite systems. i. Troubleshoot a TVRO system. j. Explain the commercial applications of mobile and fixed TVRO downlinking. 81

k. l. m.

5.

Explain the basic principles of RADAR. Identify the different types of RADAR systems in common use. Calculate distances and speeds of RADAR targets given echo return times and frequency shifts.

Identify and discuss cellular telephone systems. a. Draw and explain a block diagram of a cellular telephone system illustrating the process and equipment used in transmitting and receiving calls. b. Describe the process by which cellular telephones are interfaced with the public switched system.

82

Course Number and Name:

TCT 2424 Network Systems

Description:

Networking fundamentals, voice networking, LANs, and the Internet. Also covered is upgrading of computers to support LAN technology.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

4

2

4

90

Instructor Approved

Student Learning Outcomes: 1.

Demonstrate and practice general safety procedures in the school and work-site environments. a. Apply relevant and appropriate safety techniques. b. Demonstrate an understanding of and comply with relevant OSHA safety standards.

2.

Discuss, describe, and apply network fundamentals and install network software. a. Discuss the history of telecommunication’s networking. b. Discuss the handling and routing of calls. c. Discuss and/or define standards and terminology. d. Discuss network architectures and OSI. e. Discuss, define, and relate analog and digital signals to networking. f. Discuss, describe, and relate transmission media to networking. g. Prepare both network hardware and software for computer installation. h. Identify proper card slots for hardware installation. i. Identify computer RAM and hard drive capabilities for operation of network software. j. Discuss network security.

3.

Discuss Internetworking devices. a. Explain multiplexers. b. Identify the uses of repeaters. c. Examine the uses of bridges and gateways. d. Describe the uses of routers and brouter. e. Analyze the uses of hubs and switches. f. Discuss wireless networking equipment. g. Explain the uses of CSU/DSU.

4.

Discuss and describe voice networks, and troubleshoot network communications interface. a. Discuss the public and private switching telephone network. b. Discuss and describe voice processing and call distribution. c. Discuss and describe T1 networks. d. Discuss and describe virtual networks. e. Install network hardware and software. f. Troubleshoot a network communications interface g. Prepare both network hardware and software for computer installation. 83

h. i.

Identify proper card slots for hardware installation. Identify computer RAM and hard drive capabilities for operation of network software.

5.

Discuss, describe, and identify wide area networks. a. Discuss and diagram switched networks, frame relay, and ATM. b. Discuss and diagram signaling system 7 and VOIP. c. Discuss, operate, and troubleshoot an ISDN and SONET network media.

6.

Discuss, install, and troubleshoot LANs. a. Discuss and describe LANs. b. Discuss network software. c. Install a LAN system and verify for operation. d. Discuss and define network protocols.

7.

Access the Internet. a. Perform network experiments with e-mail. b. Discuss and interconnect with LANs

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Course Number and Name:

TCT 291(1-4) Special Project

Description:

Practical application of skills and knowledge gained in other telecommunications or telecommunications-related technical courses. The instructor works closely with the student to ensure that the selection of a project will enhance the student’s learning experience.

Hour Breakdown:

Prerequisite:

Semester Credit Hours

Lecture

Lab

Contact Hours

1-4

0

2-8

30-120

Instructor Approved

Hour Breakdown:

Prerequisite:

Instructor Approved

Student Learning Outcomes: 1.

Develop a written plan that details the activities and projects to be completed. a. Utilize a written plan that details the activities and projects to be completed. b. Perform written occupational objectives in the special project.

2.

Assess accomplishment of objectives. a. Prepare daily written assessment of accomplishment of objectives. b. Present weekly written reports of activities performed and objectives accomplished to the instructor.

3.

Utilize a set of written guidelines for the special project. a. Develop and follow a set of written guidelines for the special project.

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Course Number and Name:

TCT 292 (1-6) Supervised Work Experience

Description:

This cooperative program between industry and education is designed to integrate the student’s technical studies with industrial experience. Variable credit is awarded on the basis of 1 semester hour per 45 industrial contact hours.

Hour Breakdown:

Semester Credit Hours

Lecture

1-6

Prerequisite:

Externship

0

Contact Hours

3-18

45-270

Instructor Approved

Student Learning Outcomes: 1. Apply technical skills needed to be a viable member of the workforce. a. Prepare a description of technical skills to be developed in the supervised work experience program. b. Develop technical skills needed to be a viable member of the workforce. 2. Apply skills developed in other program area courses. a. Perform skills developed in other program area courses in the supervised work experience program. 3. Apply human relationship skills. a. Practice human relationship skills in the supervised work experience program. 4. Apply and practice positive work habits and responsibilities. a. Perform assignments to develop positive work habits and responsibilities. 5. Work with the instructor and employer to develop written occupational objectives to be accomplished. a. Perform written occupational objectives in the supervised occupational experience program. 6. Assess accomplishment of objectives. a. Prepare daily written assessment of accomplishment of objectives. b. Present weekly written reports of activities performed and objectives accomplished to the instructor. 7. Utilize a set of written guidelines for the supervised work experience. a. Develop and follow a set of written guidelines for the supervised work experience.

86

Course Number and Name:

WBL 191(1-3), WBL 192(1-3), Work-Based Learning I, II, III, IV, V, and VI, WBL 193(1-3), WBL 291(1-3), WBL 292(1-3), and WBL 293(1-3)

Description: A structured work-site learning experience in which the student, program area teacher, WorkBased Learning Coordinator, and worksite supervisor/mentor develop and implement an educational training agreement. Designed to integrate the student’s academic and technical skills into a work environment. Includes regular meetings and seminars with school personnel for supplemental instruction and progress reviews. (1-3 sch: 3-9 hours externship) Hour Breakdown: Prerequisite:

Semester Credit Hours 4 Instructor approved

Lecture 2

Lab 4

Contact Hours 90

Student Learning Outcomes: 1. Apply technical skills and related academic knowledge needed to be a viable member of the workforce a. Apply technical skills needed to be a viable member of the workforce b. Apply skills developed in other related courses in a work-based setting c. Perform tasks detailed in an educational training agreement at the work setting 2. Apply general workplace skills to include positive work habits and responsibilities necessary for successful employment a. Demonstrate pro-active human relationship skills in the work setting to include conflict resolution, team participation, leadership, negotiation, and customer/client service b. Demonstrate time, materials, and resource management skills c. Demonstrate critical thinking skills such as problem solving, decision making, and reasoning d. Demonstrate acquiring, evaluating, organizing, maintaining, interpreting, and communicating information e. Demonstrate positive work habits and acceptance of responsibilities necessary for successful employment

87

APPENDIX A: RECOMMENDED TOOLS AND EQUIPMENT CAPITALIZED ITEMS 1. Cable tester (CAT-5 and coax) (1 per 2 students) 2. Computer with software (1 per 2 students) 3. Digital communications trainer CAI/breadboard (1 per 2 students) 4. Locking storage cabinet 5. Microwave communications trainer CAI/breadboard (1 per 2 students) 6. Printer for computer (1 per 4 stations) 7. Oscilloscope (1 per 2 students 8. Spectrum analyzer (1 per lab) 9. Student tool kit (1 per 2 students) to include the following: a. Digital multi-meter b. Optical power meter c. Punch-down tool (66 and 110 blocks) d. Crimping tool, coax e. Adjustable wrench f. Drill bit set: 14 pieces g. Flashlight h. Hammer: Claw i. Pliers: Bent-nose, diagonal, long-nose, needle-nose, locking, and slip-joint j. Nut driver set k. Screwdriver sets: Offset, Phillips, slotted, jewelers, and torx l. Wire stripper m. Coax cable stripper n. Socket set: Metric and standard o. Tape measure: 25-ft p. Wrench set: Metric and standard q. Safety goggles r. Telephone test set (butt set) s. Tone generator (1) t. Crimping tool, RJ 11/RJ 45 u. Tool box 10. Telephone communications trainer CAI/breadboard (1 per 2 students) 11. Time domain reflectometer (TDR) (1 per program) 12. Work benches (1 per 2 students) 13. LCR meter (1 per lab) 14. Soldering iron (1 per station) 15. PCB prototyping equipment (1 per lab) 16. Thermal imaging camera *Other equipment items can be added when deemed appropriate by the community college industry craft committee or by industry/business training requirements.

NON-CAPITALIZED ITEMS 1. Dummy load, microwave (1 per station) 2. Electric drill (1) 3. SWR meter (1 per station) 4. Telephone analyzer (1) 5. Vacuum cleaner (wet/dry) (1 per program)

88

*Other equipment items can be added when deemed appropriate by the community college industry craft committee or by industry/business training requirements. RECOMMENDED INSTRUCTIONAL AIDS It is recommended that instructors have access to the following items: 1. Computer for computer-aided instruction (printers, cables, A/B box, etc.) (1) 2. Monitor (1) 3. DVD player and cart (1) 4. Data projector 5. Smart Board system (1) *Other equipment items can be added when deemed appropriate by the community college industry craft committee or by industry/business training requirements.

89

APPENDIX B: CURRICULUM DEFINITIONS AND TERMS • •

Course Name – A common name that will be used by all community colleges in reporting students Course Abbreviation – A common abbreviation that will be used by all community and junior colleges in reporting students • Classification – Courses may be classified as the following: o Career Certificate Required Course – A required course for all students completing a career certificate. o Technical Certificate Required Course – A required course for all students completing a technical certificate. o Technical Elective – Elective courses that are available for colleges to offer to students. • Description – A short narrative that includes the major purpose(s) of the course • Prerequisites – A listing of any courses that must be taken prior to or on enrollment in the course • Corequisites – A listing of courses that may be taken while enrolled in the course • Student Learning Outcomes – A listing of the student outcomes (major concepts and performances) that will enable students to demonstrate mastery of these competencies The following guidelines were used in developing the program(s) in this document and should be considered in compiling and revising course syllabi and daily lesson plans at the local level: •

o o o

The content of the courses in this document reflects approximately 75% of the time allocated to each course. The remaining 25% of each course should be developed at the local district level and may reflect the following: o Additional competencies and objectives within the course related to topics not found in the state framework, including activities related to specific needs of industries in the community college district o Activities that develop a higher level of mastery on the existing competencies and suggested objectives o Activities and instruction related to new technologies and concepts that were not prevalent at the time the current framework was developed or revised o Activities that include integration of academic and career–technical skills and course work, school-towork transition activities, and articulation of secondary and postsecondary career–technical programs o Individualized learning activities, including work-site learning activities, to better prepare individuals in the courses for their chosen occupational areas • Sequencing of the course within a program is left to the discretion of the local college. Naturally, foundation courses related to topics such as safety, tool and equipment usage, and other fundamental skills should be taught first. Other courses related to specific skill areas and related academics, however, may be sequenced to take advantage of seasonal and climatic conditions, resources located outside of the school, and other factors. Programs that offer an Associate of Applied Science Degree must include all of the required Career Certificate courses, Technical Certificate courses AND a minimum of 15 semester hours of General Education Core Courses. The courses in the General Education Core may be spaced out over the entire length of the program so that students complete some academic and Career Technical courses each semester. Each community college specifies the actual courses that are required to meet the General Education Core Requirements for the Associate of Applied Science Degree at their college. • In order to provide flexibility within the districts, individual courses within a framework may be customized by doing the following: Adding new student learning outcomes to complement the existing competencies and suggested objectives in the program framework Revising or extending the student learning outcomes Adjusting the semester credit hours of a course to be up 1 hour or down 1 hour (after informing the Mississippi Community College Board [MCCB] of the change)

90

APPENDIX C: RECOMMENDED TEXTBOOK LIST Recommended Textbook List Book Title

Author(s)

ISBN

Principles Of Electronic Communication Systems

Louis E Frenzel

9781259932793

What’s a Microcontroller?

Parallax

9781928982524

Multisim Software/IsoPro software

software

Electrical Motor Controls 5th Edition

Multisim/Isopro Gary J. Rockis, Glen A Mazur

Fundamentals of Linear Electronics 2nd Edition

James Cox

978-0766830189

Programming Fanuc Robots for Industry Applications

James W Gruenke

9780826934123

DC/AC Principals a Systems Approach

Floyd/Buchla

978-0-13-293393-3

DC/AC Principals a Systems Approach

Floyd/Buchla

978-0-13-293393-3

Electronic Principals 8th Ed

Malvano/Bates

978-0-07-337388-1

Electronic Principals 8th Ed

Malvano/Bates

978-0-07-337388-1

Practical Fiber Optics

Bailey/Wright

07506-58002

Digital Electronics Principles and Applications

Tokhiem

978-0-07-337377-5

The Associate CET Study Guide 6th Ed Handling Tool Operations and Programing

ETAI FANUC

1-891749-07-2 MATAGHAND0318CE REV.F

Basic Hydraulics

Schoolcraft Publishing

7307370000

Basic Pneumatics

Schoolcraft Publishing

7307390000

Electric Motors and Conrtol Systems

Frank D. Petruzella

978-1260439397

Electrical Wiring Commercial

Phil Simmons

978-0357137697

Electric Motors and Conrtol Systems

Frank D. Petruzella

978-1260439397

Programmable Logic Controllers Basic Electronics 13th ed w/ Experiments manual and Multisim CD A+ Guide to IT Technical Support (Hardware and Software) 10th ed.

Frank D. Petruzella

978-1265150495

Grob/Schults

9781264326099

Andrews

9780357108369

Arduino starter kits

978082691268

K000007

Digital Electronics 9th ed. Electronic Principles w/ Exp. Manual 9th ed. th

Kleitz Malvino

Understanding Motor Controls, 4 ed.

Stephen L. Herman

Introduction to Biomedical Instrumentation: The Technology of Patient Care, 2nd ed.

Barbara L. Christe

9780132543033 9781259852695 and 9781260447941

91

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