If you grew up in the 1980s, then an iconic scene from classic teen movie Ferris Buellers Day Off is probably etched in your memory; the one where a red Ferrari gets airborne while the title theme to Star Wars provides the soundtrack. This cinematic moment stars a Ferrari 250 California Spyder on a full-throttle joyride around Chicago. The Prancing Horse used during filming, however, was actually a fiberglass replica based on a humble MGB. The faux California Spyder Im testing, though, is rather different.

The latest Revival project from GTO Engineering, following its replica 250 GT SWB we drove earlier this year, is an inch-perfect, toolroom copy of the Ferrari original. Even Enzo himself might have struggled to spot the differenceunless he got behind the wheel. It turns out that this reborn 1960s supercar, which uses the identity of a scrapped classic Ferrari for legal purposes, has a few hidden secrets.

GTO Engineerings replica of the Ferrari 250 GT SWB California Spyder.Photo by Barry Hayden, courtesy of GTO Engineering.

As its name suggests, the Ferrari 250 California Spyder was designed for the US market, specifically the Golden State. Just 105 were made between 1958 and 1962, the first 50 with a 102-inch wheelbase (LWB), followed by 55 with a shorter 94-inch wheelbase (SWB). Today, both versions count among the rarest and most expensive Ferraris of all, as attested to by the fact that James Coburns California Spyder sold for $10 million in 2008, and few are ever seen outside of museums or private collections.

I wont attempt to get all four wheels off the ground today, yet I do plan to drive as il Commendatore intended. After all, the Revival may cost $1 million plus taxes, but its still a bargain compared to the real thing. Sadly, Im about 5,400 miles from California and the weather here is decidedly more British. Yes, its raining. Did I mention the car has no roof?

A birds-eye perspective of the toolroom copy.Photo: Courtesy of GTO Engineering.

Even through a mist of morning drizzle, the California Spyder replica looks jaw-droppingly gorgeous. The original was styled by Pininfarina, its hand-rolled aluminum body combining timeless Italian elegance with head-turning Hollywood glamour. A Ferrari with tail fins really shouldnt work, yet somehow it does. Other 250-series models, such as the Testa Rossa, LM and GTO, are more exciting, but theyre not as achingly beautiful.

Frankly, few cars sound this exquisite either. The naturally aspirated, triple-carb Colombo V-12 is built in-house by GTO Engineering and offered in three states of tune: a stock 3.0-liter Ferrari spec with 280 hp, a 3.5-liter with 320 hp, or a 4.0-liter with 350 hp. With the middling 3.5-liter motor and just 2,315 pounds to shift, this example hits 60 mph in 6 seconds and has a hair-tousling top speed of 150 mphyet it feels faster.

Originally made for the US market, the Ferrari 250 GT Spyder featured a left-hand-drive configuration, replicated here on the recreation.Photo by Barry Hayden, courtesy of GTO Engineering.

After a few steady miles to let the oil warm through and the manual shift to loosen up, I finally get a chance to let rip. The V-12 wakes up at 3,000 rpm, then piles on speed with dizzying intensity. Dont forget, this is an engine that won Le Mans multiple times, and its racing roots are still readily apparent. Hearing its metallic war cry in the open air is a privilege that makes getting wet seem totally worthwhile.

The cars naturally aspirated, triple-carb Colombo V-12 is built in-house by GTO Engineering.Photo by Barry Hayden, courtesy of GTO Engineering.

On hedge-lined lanes strewn with deep puddles, Im initially reluctant to push too hard. However, despite a live rear axle, skinny Michelin tires and complete lack of driver aids, this car has a chassis that quickly breeds confidence. The Revivals reinforced sills are much stiffer than those of the 1960s Ferrari, which adds accuracy to the slow-paced steering and sharpens its neutral yet eminently throttle-adjustablecornering attitude. Its straightforward, old-fashioned fun.

As for the lack of a roof, GTO Engineering founder Mark Lyon says the company can create one, but he thinks the Spyder looks better without it. Also, he reckons most cars will find homes in hotter climes, including California, where clinging, rain-soaked jeans are rather less likely. At least my Mazda has heated seats for the long drive home.

While Ferraris original model has reached eight figures at auction, the GTO Engineering replica costs $1 million.Photo by Barry Hayden, courtesy of GTO Engineering.

Some Ferrari purists dislike the idea of replicas, no matter how faithful to the original. But when the genuine article is too valuable to drive, these cars recreate an experience that is otherwise out of reach. Whether youre blasting along country lanes in southern England, cruising Stateside on Pacific Coast Highway or simply watching it drive by, the Revival offers an experience to savor. Its a car to seize the day and live in the moment. I think Ferris Bueller would approve.

Learn more aboutRobb Reports 2022 Car of the Year at the event taking place in Napa Valleyhereand in Boca Ratonhere.

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First Drive: GTO Engineering Recreates One of the Most Beautiful and Coveted Ferraris Ever Made - Robb Report

Alia is an R&D Product Development Engineer at TE Connectivity. Learn more about her work in the medical device industry and how you can #BeThatEngineer!

I was homeschooled my whole life until college. Junior and senior year of high school, I did the Post-Secondary Education Option (PSEO) full-time where I completed over 60 college credits. I then attended the University of St. Thomas in St. Paul, MN where I obtained my Bachelor of Science degree in Mechanical Engineering and my minor in Chinese. I graduated in 2020.

I chose the engineering route because growing up, I loved math, puzzles, and activities that involved critical thinking. I have many uncles and cousins who are engineers, so I grew up hearing about their work and how much they enjoyed being an engineer. I chose Mechanical Engineering because I wanted to go into a broad discipline. I wasnt 100% sure what kind of industry I wanted to work in, and mechanical engineering gave me the flexibility to look into multiple different industries.

In the end, I chose the medical device route.

After my freshman year of college, I was an FDA Testing Analyst Intern at Augustine Surgical Inc. I coordinated the testing of a new medical device and made sure that it complied with federal regulations. After my sophomore year, I was a Research & Development (R&D) Intern at AVEKA Inc. Here, I gathered data for projects that involved hammer milling, jet milling, and spray drying. In addition, I analyzed the impact of particle sizes on products being made and gained experience in writing technical reports. I started my third internship as an Engineering Intern at Nordson Medical at the beginning of my second semester of junior year and continued until the end of my senior year. I got to work on designing fixtures to protect medical products and testing whether the product met certain specifications. All three of these internships made me realize how much I loved working in the medical device industry, knowing that Im helping people and possibly even saving their lives.

Outside of my classes and internships, during all four years of college, I swam for the womens swim team and helped streamline the swim teams recruiting and overnight system as their Overnight Coordinator. In addition, I was a member of the Society of Women Engineers.

After I graduated, I worked as a Process Development Engineer at Boston Scientific. One of my favorite projects was when we were developing a device that removed clots from the body. This project was in its earlier stages, which allowed a ton of collaboration with team members, brainstorming, and testing. This project allowed me to be very hands-on, which is something that I love.

I am currently an R&D Product Development Engineer at TE Connectivity where I work with catheters for the heart. My job involves updating processes for the manufacturing line. I also develop fixtures and tooling to improve usability, to decrease the amount of scrap or waste, and to ensure continuous improvement of the products I work on. I love the collaborative atmosphere in the office. Working as a team is critical in engineering; if you cant work well with others, your project and your work wont be too successful.

To high school girls interested in engineering, dont be afraid to try something new and always ask questions. Engineering can be daunting, but its also so rewarding. If youre unsure if engineering is for you, try taking an introductory engineering class, sign up for a STEM or engineering camp, or reach out to an engineer and see what their day-to-day life is like. In high school, I attended two engineering camps (one at the University of Minnesota and one at Notre Dame). These camps confirmed that engineering was a degree I wanted to pursue, and they also helped me narrow down what engineering discipline I wanted to go into.

Kristine Loh

Kristine Loh is a PhD student in Chemical Engineering at the University of Minnesota - Twin Cities and the Day in the Life reporter for the high school SWENext newsletter. She graduated from Drexel University in 2020 with her bachelors in Chemical Engineering and her masters in Materials Science and Engineering.

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A Day in the Life of Mechanical Engineer Alia - All Together - Society of Women Engineers

American Council of Engineering Companies: ACEC is the voice of America's engineering industry. Council members, numbering more than 5,300 firms throughout the country, are engaged in a wide range of engineering works that propel the nation's economy and enhance and safeguard America's quality of life. The council's mission is to contribute to America's prosperity and welfare by advancing the business interests of member firms.

Engineers without Borders: The USU chapter of Engineers without Borders is a nonprofit organization. Contributions help the organization build projects that developing communities will own and operate. EWB works with communities worldwide to improve the quality of life by promoting sustainable development in water supply, housing construction, food production, energy, sanitation, transportation, communication, and employment. EWBs vision is a world where all people have the knowledge and resources needed to meet basic human needs. It involves international professionals and students inall fields as they build this vision together.

National Engineers Week Foundation: This foundation strives to be the global leader in cultivating and celebrating the engineering profession. Its cornerstone program is Engineers Week. All programs are designed to reach out to current and future generations of engineering talent.

Utah Engineers Council: The UEC is an umbrella organization of 14 different local chapters and sections of engineering societies.The purpose of the UEC is to advance the art and science of engineering and to provide a forum for communication between the varying engineering societies.

Tau Beta Pi Honor Society: Tau Beta Pi is the only engineering honor society representing the entire engineering profession. It is the nation's second-oldest honor society. It marks, in a fitting manner, those who have conferred honor upon their alma mater by distinguished scholarship and exemplary character as students in engineering, or by their attainments as alumni in the field of engineering. There are now collegiate chapters at 236 U.S. colleges and universities, active alumnus chapters in 16 districts across the country, and a total initiated membership of more than 500,000.

Engineering Student Council: The Engineering Council is an organization of engineering students. The council provides students with the opportunity to communicate opinions and suggestions to the College of Engineering administration, university administration, and the Associated Students of Utah State University. The Engineering Student Council represents students who are in the College of Engineering, communicates with engineering students about concerns, and publicizes programs and activities.

Future Association of Tomorrows Engineers: FATE is the USU regional campus engineering club. It aims to promote and support engineering throughout the USU regional campus system via social networking, community outreach, recruitment, and fun (possibly geeky) activities.

Institute of Electrical and Electronics Engineers Student Chapter: IEEE is the worlds largest professional association dedicated to advancing technological innovation and excellence for the benefit of humanity. IEEE and its members inspire a global community through IEEE's highly cited publications, conferences, technology standards, and professional and educational activities.

National Society of Black Engineers Student Chapter: NSBE has more than 35,700 members and is one of the largest student-governed organizations in the country. Founded in 1975, NSBE now includes more than 450 colleges, pre-college, and technical professional/alumni chapters in the United States and abroad. NSBEs mission is to increase the number of culturally responsible black engineers who excel academically, succeed professionally, and positively impact the community. NSBE offers its members leadership training, professional development, mentoring opportunities, career placement services, and more.

Society of Hispanic Professional Engineers Student Chapter: SHPE is a national organization that aims to build unity through diversity of engineering students. The club holds fund-raising and service activities, participates in engineering-related campus wide activities and competitions, and hosts activities with local middle and high school students aimed at science and technology. The national organization holds an annual conference, which is the major event and the largest technical and career conference for Hispanics in the country. The conference is an opportunity for engineering companies and corporations to recruit top talent from SHPE.

Society of Women Engineers: Utah State Universitys Society of Women Engineers is open for both male and female members. SWE is committed to encouraging women engineers to attain high levels of educational and professional achievement, serve as a center of information for women in engineering, and promote the value of diversity.

With the second oldest undergraduate research program in the nation, USU offers students a wide range of opportunities to gain hands-on research experience. USUs Honors Program prepares students for excellent graduate programs by helping them build relationships with professors, participate in research projects, take smaller, more intensive classes, and develop leadership skills.

AggieAir Flying Circus: AggieAir Flying Circus provides high-resolution, multispectral aerial imagery using a small, unmanned aerial system. The system is able to map small areas quicker, more frequently, at greater resolution, and at a smaller cost than conventional remote sensing. Some applications for AggieAir include monitoring of soil moisture and evapotranspiration in agriculture, riparian habitat mapping, road and highway surface monitoring, wetland mapping, and fish and wildlife tracking.

Anderson Center for Wireless Teaching and Research: This center provides state-of-the art wireless communication teaching and research with emphasis on industry-relevant design projects.

Center for Active Sensing and Imaging: CASI uses radar-like, laser-based LIDAR technology to measure distances instead of radio waves for a variety of industrial applications, including sitting wind farms, controlling emissions, and rapid replacement of bridges, runways, and other infrastructure.

Center for Atmospheric and Space Sciences: CASS is recognized nationally and internationally as a progressive research center with advanced space and upper atmospheric research programs. CASS scientists are tackling the adverse consequences of space weather. Undergraduate and graduate students are involved in numerous research projects in CASS that provide opportunities to program computers, analyze data, and build instrumentation.

Center for High Performance Computing: HPC at USU is a research service center that serves and expands the computational needs of the USU community. HPC at USU houses a 256-processor cluster called Uinta, with three networks.

Center for Self-Organizing and Intelligent Systems: CSOIS is a multi-disciplinary research group at USU that focuses on the design, development, and implementation of intelligent, autonomous mechatronic systems, with a focus on ground vehicles and robotics.

Center for Space Engineering: CSE is a multi-disciplinary group of faculty at USU involved in space technology, systems, and science. The center brings together academics, industry, and government to advance the understanding of the space environment and to train the next generation.

Energy Dynamics Laboratory: EDL bridges the gap between academia and industry, confronting the challenges of prototyping, deployment, and commercialization of enabling technologies for renewable and advanced energy systems. USU researchers originate projects to derive energy from non-fossil fuels, such as biofuels, wind, and solar power. With EDLs collaboration, research develops through pilot projects to commercial application.

Energy Laboratory: This lab seeks to develop solutions to America's most intractable energy problems through scientific and technological innovation. It provides a cohesive framework permitting faculty, students, and partnering institutions to focus on contemporary energy-related research issues.

Environmental Management Research Group: EMRG is a research unit of the Utah Water Research Laboratory focused on integrated watershed management and systems analysis of environmental problems. EMRG provides software development, watershed and water quality modeling, and GIS data analysis service to internal and external entities directed at solving integrated watershed and environmental management-related problems of a variety of scales.

Institute for Intuitive Buildings: Because a considerable amount of energy is wasted in lighting, cooling, and ventilating commercial buildings, the I2B team will create real-time scene measurement and interpretation techniques for electric lighting systems.

Rocky Mountain NASA Space Grant Consortium: RMNSGC is one of 52 National Space Grant Consortia in the United States. As a member of the consortium, USU has awarded more than 100 fellowships to students interested in aerospace-related education and careers. The majority of Space Grant student awards include a mentored research experience with university faculty and NASA scientists, engineers, and technologists.

Space Dynamics Laboratory: SDL is known for sending 500+ successful experiments into space and brings in $54 million per year in revenue, the majority coming from grants, contracts, and appropriations. SDLs expertise in the development of sensors and calibration, small satellites and real-time intelligence has made it an internationally known organization in the space arena.

Synthetic Biomanufacturing Center: SBC uses the chemical makeup present in single-cell organisms to transform raw materials into environmentally friendly products, such as low-cost bioplastics, biodiesel, light energy, and pharmaceuticals.

Utah Transportation Center: The UTC uses its expertise in natural hazards to research congestion chokepoints, evacuation occurrences, infrastructure renewal, and operations as it relates to multi-modal transportation.

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Electrical Engineering - Utah State University

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Morten Jensen

Morten Jensen, associate professor of biomedical engineering, was recently awarded the title of Fellow of the American Heart Association. In a letter from the leadership chair of the Council on Basic Cardiovascular Sciences, Dr. Elizabeth McNally, wrote that Jensen was recognized for his scientific and professional accomplishments, volunteer leadership and service to the AHA.

The prestigious AHA Fellowships are awarded to physicians, scientists and other healthcare professionals with a particularly productive career in advancing the treatment of cardiovascular diseases and stroke. The fellowship comes with the right, privilege and entitlement to use the designation FAHA, recognizing the selection to be in "the world's most eminent organization of cardiovascular and stroke professionals."

"I am honored by this recognition," Jensen said. "Our work in collaboration with clinicians and colleagues in Arkansas, the United States and beyond helped me towards this. My focus is to advance medical procedures and devices to improve treatment of patients suffering from cardiovascular disease. In addition, educating not just students, but also the public, about the importance of our work is one of the top priorities for the AHA."

Raj R. Rao, professor and head of biomedical engineering, said that this national recognition for Jensen signifies the importance of Jensen's research. "I am pleased about Dr. Jensen's election as an AHA Fellow," Rao said. "We encourage our faculty to research ideas and technologies that are of interest to them. Over the years, Dr. Jensen has demonstrated his dedication to creating solutions and devices for cardiovascular surgeries. This recognition indicates that his peers and professional organizations recognize the excellent research to which he strives," Rao concluded.

To learn more about Jensen's research, visit the Cardiovascular Biomechanics Laboratory's website: https://cblab.uark.edu/

Find more news about the Department of Biomedical Engineering.

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Biomedical Engineering Professor Elected as Fellow of the American Heart Association - University of Arkansas Newswire