This is the Engineering Technology Common Capstone Project course where students address open-ended problems. Emphasis is placed on teamwork, the design process, and project management tools addressing project scope, schedule, milestones, deliverables, risk, and cost. The course also focuses on developing oral, written and interpersonal communication skills. In this course, cross-disciplinary student teams develop their proposed mechanism or machine after identifying customer needs, and possible alternative concepts. The mechanism or machine must include sufficiently complex mechanical and electrical subsystems, a control system, and a manufacturing system design. The subsystems of the design must be effectively integrated to achieve proper operation of the mechanism or machine. The final system design must be supported by sound engineering analyses and by engineering designs necessary to build a prototype. The design will be implemented through further analysis, testing, documentation, demonstration, and presentation of a fully functional prototype. This course is intended to be taken as a capstone design experience near the conclusion of the student's program of study.

This is the Engineering Technology Common Capstone Project course where students address open-ended problems. Emphasis is placed on teamwork, the design process, and project management tools addressing project scope, schedule, milestones, deliverables, risk, and cost. The course also focuses on developing oral, written and interpersonal communication skills. In this course, cross-disciplinary student teams develop their proposed mechanism or machine after identifying customer needs, and possible alternative concepts. The mechanism or machine must include sufficiently complex mechanical and electrical subsystems, a control system, and a manufacturing system design. The subsystems of the design must be effectively integrated to achieve proper operation of the mechanism or machine. The final system design must be supported by sound engineering analyses and by engineering designs necessary to build a prototype. The design will be implemented through further analysis, testing, documentation, demonstration, and presentation of a fully functional prototype. This course is intended to be taken as a capstone design experience near the conclusion of the student's program of study.

This course will provide a thorough understanding of the manufacturing automation principles, practices and system integration. Students will design a fully automated control system from selection of components, specifying the Programmable Logic Controller (PLC), and developing the ladder logic required to operate the system. Students will have the tools to effectively be able to fully design an automated control system as in done in varying industries.

This course will provide a thorough hands-on experience in using Programmable Logic Controllers (PLCs) for manufacturing automation and system integration. Industry best practices for programming PLCs and the essentials of Human Machine Interface (HMI) for data entry, manipulation, and recording system status will be included.

This is the Engineering Technology Common Capstone Project course where students address open-ended problems. Emphasis is placed on teamwork, the design process, and project management tools addressing project scope, schedule, milestones, deliverables, risk, and cost. The course also focuses on developing oral, written and interpersonal communication skills. In this course, cross-disciplinary student teams develop their proposed mechanism or machine after identifying customer needs, and possible alternative concepts. The mechanism or machine must include sufficiently complex mechanical and electrical subsystems, a control system, and a manufacturing system design. The subsystems of the design must be effectively integrated to achieve proper operation of the mechanism or machine. The final system design must be supported by sound engineering analyses and by engineering designs necessary to build a prototype. The design will be implemented through further analysis, testing, documentation, demonstration, and presentation of a fully functional prototype. This course is intended to be taken as a capstone design experience near the conclusion of the student's program of study.

This course deals with the higher level of topics relating to automation control systems engineering. Learning different programming languages, troubleshooting techniques, advanced programming instructions, the use and application of Human Machine Interface (HMI) panels, analog devices uses and applications, advanced system design, networking and an introduction to Industry 4.0 are all covered in this course.

This course deals with the higher level of topics relating to automation control systems engineering. Learning different programming languages, troubleshooting techniques, advanced programming instructions, the use and application of Human Machine Interface (HMI) panels, analog devices uses and applications, advanced system design, networking and an introduction to Industry 4.0 are all covered in this course. Students will be expected to develop the main system and all subsystems required to solve an automation problem. Students with no/limited PLC programming and automation system design knowledge are required to take RMET-340/341 as a bridge course. Students may take and receive credit for RMET-571 or RMET-671, not for both.