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"Industry 4.0-based systems and subsystems are replacing current process and process control equipment in Florida’s manufacturing environment. The Florida State College System Engineering Technology (ET) degree pathway for developing engineering technology professionals is responding to this reality at the ET two-year associate degree, the 4-year ET B.S. degree, and post-graduate degrees as well as a statewide recognized path to the Professional Engineers license in Engineering Technology. The National Science Foundation Advanced Technological Education program (NSF-ATE) supports this effort. NSF-ATE assets provided to FLATE and five partner colleges are directed to the formation of a statewide advisory board for the 20 colleges that offer ET degrees as well as supporting six overarching Florida ET education system target goals: (1) Adjust Florida Department of Education Standards and Benchmarks to include criteria that address Florida manufacturer-identified Industry 4.0 skills gap in its technical workforce. (2) Create a statewide streamlined seamless articulation environment from the Engineering Technology A.S. to B.S. degree programs. (3) Provide Professional Development that up-skills Engineering Technology Degree faculty as related to identified Industry 4.0 technician skill needs. (4) Create a short-term ET College Credit Certificate to prepare current and future technicians to apply these new skills in the manufacturing workspace. (5) Amplify the manufacturer's involvement with college engineering technology certificates and A.S.ET degree programs. (6) Create Post-A.S. Curriculum Advanced Technology Certificate (ATC) to facilitate skilled technician professional advancement. Statewide implementation of the curriculum changes is key to more robust programs and more work-ready technician graduates. This paper and presentation poster will share the strategies the project team is using to achieve its goals and objectives. It will also share the feedback received from the industry relative to industry 4.0 skills needed in their facilities."
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This content will become publicly available on March 1, 2026
Creating Pathways to Industry for Pre-College Students and Two-Year Undergraduates
Over the last decade, the emergence of technician education has taken center stage at secondary and post-secondary educational institutions through the proliferation of industry needs and employer-partner engagement. Through employer-partner engagement, Southern University at Shreveport, Louisiana (SUSLA), a community college unit within the Southern University and A&M College System, conducted a systematic review, assessment, and revision of its curricula that addressed the needs of industry. SUSLA’s comprehensive assessment, guided by employer-partner input, community college and 4-year university collaborations, and published workforce data, identified a pressing need to develop an Engineering Technology program. To that end, SUSLA developed a 2+2+2 Matriculation Model within the Engineering Technology associate of applied science degree program designed as a gateway to enable early education, persistence to post-secondary credentials of value, and high-quality career outcomes. Programs with similar demographics may be able to use this as a model which aims to do four things: 1) facilitate the early engagement of students decreasing the number of academically underprepared learners entering college, 2) expand postsecondary educational opportunities to improve outcomes fostering economic opportunity 3) increase the enrollment, persistence and graduation of early education and underserved populations in STEM and, 4) facilitate a reduction in time to degree. SUSLA’s 2+2+2 Matriculation Model provides high school students with the opportunity to earn dual-enrollment post-secondary credentials through its certificate of technical offerings in Engineering and Engineering Technology. Additionally, the model facilitates an increase in the participation rate of students in STEM and provides more academic opportunities and career exploration through collaborative industry-academic networks. Furthermore, the model produces workforce-ready technicians which accelerates academic and technical skill attainment and, thereby addresses a) the shortage in moderate to middle-skill jobs that require some college, but less than a bachelor’s degree; and b) the ongoing need for highly skilled STEM graduates to maintain the nation’s competitiveness in productivity and innovation.
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- Award ID(s):
- 2055480
- PAR ID:
- 10635063
- Publisher / Repository:
- ASEE Conferences
- Date Published:
- Edition / Version:
- 1
- Format(s):
- Medium: X
- Location:
- Arlington, TX, Texas
- Sponsoring Org:
- National Science Foundation
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