200

This course provides the student with technical training in a technical setting facility. Training related experience should demonstrate student's achievement of program's learning objectives. The course is coordinated and graded by faculty while incorporating employer's assessment of student's performance. 

This course provides the student with technical training in a technical setting facility. Training related experience should demonstrate student's attainment of program's learning outcomes. The course is coordinated and graded by faculty while incorporating employer's assessment of student's performance.

This course provides the student with technical training in a technical setting facility. Training related experience should demonstrate student's attainment of program's learning outcomes. The course is coordinated and graded by faculty while incorporating employer's assessment of student's performance.

This course provides the student with technical training in a technical setting facility. Training related experience should demonstrate student's attainment of program's learning outcomes. The course is coordinated and graded by faculty while incorporating employer's assessment of student's performance.

This course introduces students to structured programming using the high level language Python. Students will learn data variables, control statements, arithmetic operations, plotting, and built-in functions. Upon successful course completion, students will be able to create (write) and execute programs to solve simple and complex engineering problems.

This course covers basic principles of Silicon controlled rectifiers and motor control circuits. Students will learn about process control system concepts and various sensors technologies. Upon successful course completion, students will be able to select and use various sensors appropriately to implement a basic automated process.

This course covers the fundamental principles of electronic instrumentation and computer-based Data Acquisition. Topics covered includes Active filters, Instrumentation amplifiers, the use of graphical software for the development of real-time data gathering, analysis and presentation using virtual instruments. Students will be introduced to sources and effects of errors, Op-amp based Instrumentation amplifiers & their applications, creation and use of Virtual Instruments using LabVIEW based graphical programming. Upon successful course completion, students will be able to build and test Instrumentation Amplifiers, virtual instruments to interface with various electronic circuits using sensors.

This course teaches working principles and applications of electronic devices such as diode, transistors, operational amplifiers, instrumentation operational amplifiers, power operational amplifiers, and passive and active filters.  Students will learn the basics of semiconductor devices, operational amplifier, and passive and active filters.  Upon successful course completion, students will be able to implement, analyze, and integrate basic electronic circuits for mechanical control systems.

This course covers flip-flops, counters, shift registers, memory devices, and storage. Students will learn about sequential circuits, state machines, Analog-to-Digital (ADC) and Digital-to-Analog (DAC) converters. Upon successful course completion, students will be able to design and implement sequential logic circuits.

This course covers digital logic design and implementation. Topics covered include both combinational and sequential logic. Students are introduced to Programmable array logic (PAL) and gate array logic (GAL) digital circuits. The course's emphasis is on the development of skills/techniques needed by a technician/technologist for the production and testing of a system.

This course introduces students to the fundamentals of Programmable Logic Controllers (PLCs). Students will learn about process automation and control systems through the use of hands on implementation and troubleshooting of existing PLC configurations. Upon successful course completion, students will be able to read and interpret PLC programs as well as install and connect various field devices.

This course introduces students to the practical applications of Programmable Logic Controllers (PLCs). Students will implement various projects using some of the most common PLCs, used in industry. Upon successful course completion, students will be able to read and interpret wiring diagrams, install and connect various field devices and follow basic troubleshooting techniques.

This course provides students with an overview of Smart Manufacturing with an emphasis on Industry 4.0, robotics, smart sensors, and Industrial Internet of Things, IIoT. Students will learn about the role of Artificial Intelligence (AI) in Smart Manufacturing as well as the various robot configurations, control & programming, and data visualization dashboards for IIoT. Upon successful course completion, students will be able to develop basic programming and control for a robot and setup an IIoT dashboard.

This course introduces students to the design and implementation of industrial workcells and IIoT dashboards. Students will learn about robot safety as well as tools and techniques for creating and modifying programmed motions. Upon successful course completion, students will be able to control and program a robot as well as setup an Industrial Internet of Things, IIoT, dashboard.

This course continues the study of computer systems to include disk drive organization, peripheral devices, and networking concepts. Students will learn the operation and internal functions of a variety of peripheral devices commonly found in small office systems, including printers and monitors; RAID disk configurations; backup methods; and the fundamentals of networking. Upon successful course completion, students will be able to perform peripheral device maintenance, install and configure printers, monitors, and network, devices.

The course covers the installation and configuration of operating systems. Students will configure network connections and security for both wired and wireless devices. Upon successful course completion, students will be able to address safety and environmental concerns as they relate to peripheral devices.

This course provides an introduction to fiber optics. Students will learn about the optical characteristics of optical fibers, fiber optic communications systems including modulators and detectors, and electro-optic sensors. Upon successful course completion, students will be able to perform data analysis of Optical Time Domain Reflectometer data as well as link and cable testing.

This course provides an extensive hands-on laboratory experience to prepare the students for the installation of fiber optic networks.

This course covers radio frequency fundamentals and the concepts of data and information communication systems. Students will learn analog modulation techniques, electromagnetic wave propagation, path loss, multiple access techniques and introductory topics in antenna theory, transmission lines and satellite systems.  Upon successful course completion, students will be able to understand the basics of radio transmitters and receivers as well as different types of analog modulation techniques and the operation of amplitude, frequency, and phase modulation/demodulation circuits.

This course covers Wireless Local Area Networks (WLAN) industry standards. Students will learn about WLAN security issues and performance analysis through packet analysis and intrusion detection. Upon successful course completion, students will be able to secure wireless communications using WEP, WPA-PSK, WPA-RADIUS, VPN’s, authentication methods, and encryption.