This course is designed to present the passive components in electronics from atomic structure through resonance. Laboratory exercises are utilized to familiarize the student with basic electronics test equipment and simple DC and AC circuits. (CSU)
This course is designed to present the theory, operation, and application of solid-state devices. The course stresses the application of bipolar transistors, field effect transistors, opto-devices, and the thyristor family in rectifier amplifiers, detectors, and other basic systems. Laboratory exercises are utilized to reinforce the theory. (CSU)
This course is designed to introduce digital devices and their applications. The student explores a variety of digital devices, learns the theory and application of the major groups, and prepares for advancement to microprocessors and microcomputer training. (CSU)
This course is an introduction to the practical repair of electronic equipment. Topics include trouble-shooting, disassembly and assembly, soldering, parts ordering, and the writing of maintenance reports. (CSU)
This course is designed to continue the development of identified skills necessary for troubleshooting electronics equipment through self-study and hands-on experience. (CSU)
This course is designed to introduce the skills necessary to troubleshoot computers through self-study and hands-on experience. (CSU)
This course is designed to offer instruction in one of the specialized areas of electronics technology not already covered by existing curricula. (CSU)
This course is designed to be an entry level study of the microprocessor and its relationship to all parts of the computer. The student learns the architecture of the processor and the necessary machine language to control all functions. Peripheral hardware and interface techniques are introduced through laboratory experimentation. Industrial process control is developed as a teaching medium to give application to the principles learned. (CSU)
This course is an introduction to the basic concepts of computer and communication networks. The course focuses on network terminology, protocols, cabling, cabling tools. Ethernet and IP addressing. The course include the Open Systems Interconnection (OSI) reference model, network design issues, network architectures and standards.
This course focuses on initial router and switch configurations. Wide Area Network connectivity, routing protocol management, and router security using access control lists.
This course will cover basic concepts of switching and intermediate concepts of routing. The course focuses on command line interface configuration of switches. VLANs (Virtual Local Area Networks), STP (Spanning-Tree Protocol), and VTP (Virtual Trunking Protocol). The course also covers VLSM (Variable Length Subnet Masks) and intermediate routing protocols such as EIGRP and OSPF.
This course focuses in advanced IPv4 (internet Protocol version 4) addressing techniques and Wide Area Network technologies and terminology. The course will cover NAT (Network Address Translation) and the use of private addresses to configure and secure a greater number of users within a network. The course will define the concepts and configuration of PAT (Port Address Translation) and DHCP (Dynamic Host Configuration Protocol) for scalability of IPv4 addresses. This course will cover PPP (Point-to-Point Protocol), ISDN (Integrated Services Digital Network), Frame Relay concepts and router configuration.
This course presents an advanced level of administering and supporting scalable network systems using Internet Protocol (IP) technologies. The students learn advance methods on how to implement several routing protocols including Routing Information Protocol (RIP), Enhanced Interior Gateway Routing Protocol (EIGRP), Open Shortest Path First (OSPF) and other industry standard protocols. Instruction includes IP address management, Network Area Translation (NAT), Variable Length Subnet Mask (VLSM), and advance Access Lists. This course prepares the students for industry professional level certification such as the Cisco Certified Network Professional.
This course is open to the student qualified to do advanced work in the field. The course includes research, directed reading, field work, or other advanced study, and the course may be repeated for a maximum total of four units. (CSU)
Limitations on Enrollment: The student must enroll in a course that is directly related to the electronics internship; the student must enroll in a minimum of 7 units, including internship units during the semester; for summer session, the student must enroll in one related course in addition to internship; the combined total number of units a student may take in internship, work experience, and occupational practice may not exceed a maximum of 16 units; participation requires submission and approval of internship program objectives and an employer internship agreement.
This course is designed for the student participating in an occupational internship in Electronics. Application of discipline-related skills and knowledge of the Secretaries' Commission on Achieving Necessary Skills (SCANS) competencies is emphasized. Each student is engaged in a specific research project or on-the-job learning activities under the supervision of a worksite supervisor and a college internship instructor. To register, the student must complete an application form available at the Applied Science and Technology Division Office, Holt 140. (CSU)
This course is designed to offer instruction in one or more of the specialized areas of electronics technology not already covered by the existing curriculum. Units in this course do not count toward an associate degree.
This course is designed to prepare the student to identify the major components of the network system, understand the Open System Interconnection (OSI) model, and create subnets.
This course is designed to prepare the student to understand router functions, protocols, gateways, industry standards, topologies, and system cabling.
This course is designed to prepare the student to control reliability factors, evaluate advantages of routing methodology, discern distance vectors, and control static and dynamic routing decisions.
This course is designed to prepare the student to solve Local Area Network (LAN) design problems, configure routers, understand router commands, utilize Transmission Control Protocol/Internet Protocol (TCP/IP) addressing, integrate diverse topologies, and overcome adverse network environments.
This course is designed to prepare the student to describe, configure, and control the Novell Internetworking Packet Exchange (IPX) operations of a router. Local Area Network (LAN) are segmented by use of bridges, routers, and switches.
This course is designed to prepare the student to describe, configure, and control: full and half-duplex ethernet, segmentation by bridge, segmentation by router, segmentation by switch, fast ethernet, cut-through, switching, store and forward switching, spanning tree protocol, and virtual Local Area Network (LAN).
This course is designed to prepare the student to describe, configure, and control: Wide Area Networks (WAN) Services, Link Access Procedure Balanced (LAPB), Frame Relay, Integrated Service Digital Network/Link Access Protocol on the "D" channel (ISDN/LAPD), High-level Data Link Control (HDLC), Point-to-Point Protocol (PPP), and Dial on Demand Routing (DDR), Frame Relay terms, Frame Relay Commands, Local Management Interface (LMI), map subinterfaces, and monitor frame relay operations on a router.
This course is designed to prepare the student to describe, configure, and control: Point-to-Point Protocol (PPP) operations, Point-to-Point Protocol (PPP) encapsulation of Wide Area Network (WAN) data, Integrated Service Digital Network (ISDN) networking, Integrated Service Digital Network (ISDN) protocols, Integrated Service Digital Network (ISDN) function groups, Cisco implementation of Integrated Service Digital Network/Basic Rate Interface (ISDN/BRI).
This topic course is a practical review of the entire Cisco Certified Network Associate curriculum as it relates to the hardware of the modern network. Included within this course is extensive hands-on manipulation of the routers and switches which are used to configure extensive networking scenarios as they are used in industry. The student progresses to the point where he or she is ready for the Cisco Hardware Physical Testing and Certification.