About the Program
(Not Eligible for Financial Aid) The Certificate of Achievement in Computer Engineering is designed to meet the core lower division requirements for Computer Engineering. Completion of the Certificate of Achievement includes the discipline specific courses required to transfer to a four year university in engineering. The specific field requirements do vary depending on the four-year institution to which the student will transfer. Thus, requirements for specific universities should be checked before selecting specific field courses.
Program Requirements
Program Goal: Local
GE Pattern(s): None
Program Code: 44138.00CA
Program Learning Outcome(s):
Upon successful completion of this program, the student will be able to:
Demonstrate the ability to write comprehensive reports to communicate the analysis of various materials.
Demonstrate knowledge of the general methods of problem-solving using data gathered in the field.
Safely use and accurately interpret the output of standard measuring devices.
Demonstrate an ability to develop engineering judgment in the solution of engineering problems by breaking problems down, solving each part, checking each solution, and reassembling the problem for a final solution.
Use the tools of Mathematics and Physics to solve engineering problems.
Unit(s): 3.00
Transfer Status: CSU/UC
Contact Hours:
34.00 hours Lecture
/ 51.00 hours Lab
Out of Class Hours: 68.00
Total Course Hours: 153.00
This course is an introduction to the discipline of computer science, with a focus on the design and implementation of algorithms to solve simple problems using a high-level programming language. Topics include fundamental programming constructs, problem-solving strategies, debugging techniques, declaration models, and an overview of procedural and object-oriented programming languages. Students will learn to design, implement, test, and debug algorithms using pseudocode and a high-level programming language. (C-ID COMP 122).
Prerequisite(s): CSCI 20
Unit(s): 3.00
Transfer Status: CSU/UC
Contact Hours:
34.00 hours Lecture
/ 51.00 hours Lab
Out of Class Hours: 68.00
Total Course Hours: 153.00
This is a software engineering course, focused on the application of software engineering techniques for the design and development of large programs. Topics include data abstraction, data structures and associated algorithms, recursion, declaration models, and garbage collection. Students will learn to design, implement, test, and debug programs using an object-oriented language. (C-ID COMP 132).
Prerequisite(s): CSCI 20 and MATH 13 or MATH 13s or MATH 26 or MATH 26s or MATH 28 or MATH 28s
Unit(s): 3.00
Transfer Status: CSU/UC
Contact Hours:
51.00 hours Lecture
Out of Class Hours: 102.00
Total Course Hours: 153.00
This course is an introduction to the discrete structures used in Computer Science, with an emphasis on their applications. Topics covered include functions, relations and sets, basic logic, proof techniques, basics of counting, graphs and trees, and discrete probability. (C-ID COMP 152).
Unit(s): 4.00
Transfer Status: CSU/UC
Contact Hours:
51.00 hours Lecture
/ 51.00 hours Lab
Out of Class Hours: 102.00
Total Course Hours: 204.00
In this course the student will be trained in the use of symbolic digital logic including switching algebra, optimization, Karnaugh map construction and use and the design of combinational logic networks. The student will develop skills in mapping of sequential logic theory to practical devices using flip-flops, registers and counters.
Prerequisite(s): PHYS 42, MATH 40 (or concurrent enrollment)
Unit(s): 4.00
Transfer Status: CSU/UC
Contact Hours:
51.00 hours Lecture
/ 51.00 hours Lab
Out of Class Hours: 102.00
Total Course Hours: 204.00
An introduction to the analysis, construction and measurement of electrical circuits. Use of analytical techniques based on the application of circuit laws and network theorems. Basic use of electrical test and measurement instruments including multimeters, oscilloscopes, power supplies, and function generators. Use of circuit simulation software. Interpretation of measured and simulated data based on principles of circuit analysis for Direct Current (DC), analysis, transient, and sinusoidal steady-state Alternating Current (AC) conditions containing resistors, capacitors, inductors, dependent sources, operational amplifiers and/or switches. Elementary circuit design. Practical considerations such as component value tolerance and non-ideal aspects of laboratory instruments. Construction and measurement of basic operational amplifier circuits. Natural and forced responses of first and second order RLC circuits; the use of phasors; AC power calculations; power transfer; and energy concepts. (C-ID ENGR 260/260L).
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Contacts
Luke Sathrum, Chair
(530) 895-2219
Department Office: AHPS 251
(530) 895-2531
Counseling and Advising:
(530) 895-2378
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