Category Archives: Engineering
Vote for the 2022 Engineer of the Year – Design News
The time has come for the engineering community to cast your vote for the DesignCon 2022 Engineer of the Year. This award is given out each year during the DesignCon event and seeks to recognize the best of the best in engineering and new product advancements at the chip, board, or system level, with a special emphasis on signal integrity and power integrity.
Editors of Design News and the staff of DesignCon would like to offer hearty congratulations to the finalists. For this years award, the winner (or his/her representative) will be able to direct a $1,000 donation to any secondary educational institution in the United States. The details on each nominee are below as provided in their published biographies and by the person/s who made the nomination. Please cast your vote byfollowing this link.
Related: DesignCon 2022 Engineer of the Year Nominations Are Now Open
Voting closes at noon Pacific Time on March 11. The winner will be announced at DesignCon 2022, April 5-7 at the Santa Clara Convention Center, Santa Clara, CA.
The four finalists for the 2022 DesignCon Engineer of the Year Award are (click each name to see finalists bio and community activity):
Related: DesignCon 2022 Locks in High-Caliber Keynote Speaker Lineup for April Event
Cast your vote for the 2022 Engineer of the Year
Learn more about DesignCon and register to attend
Scott McMorrow,CTO, Samtec
Scott McMorrow currently serves as CTO for Samtecs Signal Integrity Group, Inc. As a consultant for years too numerous to mention, Scott has helped many companies develop high-performance products while training signal integrity engineers.
Scott started Samtecs webinar series gEEk spEEk, providing virtual engineering learning. Scott also works on Samtecs Twinax technology, pushes EDA companies to focus on signal integrity, developed advanced crosstalk analysis and power delivery methodology. He has related RF EDA to signal integrity (meshing, boundary conditions, computational space, etc.) and has a long history of supporting, speaking at, and writing for DesignCon.
Scott received a DesignCon 2021 Best Paper Award for his work on the paper A Case Study in the Development of a 112 Gbps-PAM4 Silicon & Connector Test Platform.
Richard Mellitz,Distinguished Engineer, Samtec
Samtec
Richard Mellitz is presently a Distinguished Engineer at Samtec, supporting interconnect signal integrity and industry standards. Prior to this, he was a Principal Engineer in the Platform Engineering Group at Intel. Richard was a principal member of various Intel processor and I/O bus teams including Itanium, Pentium, PCI Express, SAS, and Fabric (Ethernet, IB, and proprietary). Additionally, he has been a key contributor for the channel sections IEEE802.3 backplane and cabling standards, and for the time domain ISI and return loss standards for IEEE802.3 Ethernet, known as COM (Channel Operating Margin) and ERL (Effective Return Loss), which are now an integral part of Ethernet standards due to Richs leadership.
He founded and chaired an IPC (Association Connecting Electronics Industries) committee delivering IPCs first PCB loss test method. Prior to this, Rich led industry efforts at IPC to deliver the first TDR (time domain reflectometry) standard which is presently used throughout the PCB industry. Richard holds many patents in interconnect, signal integrity, design, and test. He has delivered numerous signal integrity papers at electronic industry design conferences.
Richard contributed to three DesignCon 2022 papers, see more information in the online agenda.
Steve Sandler,Founder, Picotest.com
Picotest
Steve Sandler has been involved with power system engineering for more than 40 years. Steve is the founder of PICOTEST.com, a company specializing in power integrity solutions including measurement products, services, and training. He frequently lectures and leads workshops internationally on the topics of power, PDN and distributed systems and is a Keysight certified expert for EDA software. Steve frequently writes articles and books related to power supply and PDN performance and his latest book, Power Integrity Using ADS was published by Faraday Press in 2019. Steve founded AEi Systems, a well-established leader in worst-case circuit analysis and troubleshooting of high-reliability systems.
Steve is a long-time and very active member of the DesignCon Technical Program Committee, and received a DesignCon 2017 Best Paper Award for his paper, Characterizing and Selecting the VRM.
For DesignCon 2022, Steve is planning to speak at a tutorial, present a paper, and participate in a panel. You can see the session details on the online agenda.
Lambert (Bert) Simonovich,Founder, Lamsim Enterprises
Lamsim
Lambert (Bert) Simonovich graduated from Mohawk College of Applied Arts and Technology, Hamilton, Ontario Canada, as an Electronic Engineering Technologist. Over a 32-year career, working at Bell Northern Research/Nortel in Ottawa Canada, he helped pioneer several advanced technology solutions into products. He has held a variety of engineering, research, and development positions, eventually specializing in high-speed signal integrity and backplane design. In 2009, he founded Lamsim Enterprises Inc., where he continues to provide innovative signal integrity and backplane solutions as a consultant. He has authored several publications and holder of two US patents.
In addition to being a senior member of IEEE, he currently serves as a member of DesignCon's Technical Program Committee, EDICon's Technical Advisory Committee, and Signal Integrity Journal's Editorial Advisory Board. His current research interests include high-speed signal integrity, modeling, and characterization of high-speed serial link architectures. His most notable modeling achievement is the development of the "Cannonball-Hurry" conductor roughness model used in several electronic design automation (EDA) software tools.
Bert has received Best Paper Awards for his 2019 paper PCB Interconnect Modeling Demystified, and the 2018 paper A Causal Conductor Roughness Model and its Effect on Transmission Line Characteristics.
Cast your vote for the 2022 Engineer of the Year. Voting closes at noon Pacific Time on March 11.
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Duncan Aviation Teams with Honeywell Aerospace, Turbojet Engineering and Beck’s Hybrid On STC – Aviation Pros
Duncan Aviation announces that its Engineering/Certification and Avionics Installation teams in Battle Creek, Michigan, recently worked with Honeywell Aerospace, Turbojet Engineering, and Becks Hybrid to develop a Supplemental Type Certificate (STC) to add Synthetic Vision System (SVS) to a Honeywell flight deck on a Learjet 45 series aircraft. The Honeywell flight deck had been previously installed in the customers aircraft, and the cooperative effort involved upgrading the system and installing the SVS component.
Duncan Aviation has worked on this Learjet 45 in the past, installing Airshow 500, refurbishing parts of the interior, fully painting the exterior, and installing a Gogo AVANCE L3 for cabin connectivity.
The customer explained in detail exactly why they wanted this upgrade on their aircraft.
Our 2008 Learjet 45XR is a workhorse, and its very dependable. We decided it was time for an upgrade and chose the Honeywell Primus Elite for several reasons. It resolved the obsolescence issues with the old DU870s, and there were cost savings with the DU exchange program and reduced Honeywell Avionics Protection Plan (HAPP) cost, says Director of Maintenance Phil Ward of Becks Hybrid. Most importantly, the upgrade increased situational awareness for the pilot with the addition of charts, integrated maps, XM Weather, and Synthetic Vision System. We also believe this upgrade keeps the Learjet 45XR value higher when compared to other aircraft without the upgrade.
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40 Different Types of Engineering Degrees
Consider a featured online STEM / Engineering program:
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Search the top engineering programs online with over 40 different types of engineering degrees and careers reviewed. We have hundreds of schools in our database with a wide variety of engineering degrees, including ABET-accredited engineering degrees at all levels, as well as dozens of engineering program reviews written by technology experts.
Engineering is expected to be a growth sector in the upcoming decade, and it is considered to be a top career. You can view some of the highest paying engineering jobs, which is updated often and based on salary data from the US Department of Labor and other reputable sources. Continue reading to research the top engineering degrees, or use the school search to get immediately matched to online schools that are accepting applicants.
Engineering is a broad term that covers a wide range of applications and industries. Combining mathematics, science and technology, engineers produce creative solutions to real world problems. As a result there are many different types of engineering degrees available.
In the past, engineering could be divided into four major branches: Mechanical, Chemical, Civil and Electrical, with sub branches of each discipline. Today however, the number of engineering degrees available have increased dramatically. There are now six major branches of engineering: Mechanical, Chemical, Civil, Electrical, Management, and Geotechnical, and literally hundreds of different subcategories of engineering under each branch.
Take a look over the list below - all types of engineering degrees are provided in summary with a link to a full article with more detail on each where available.You can also find links to universities offering that specific degree, or use the below search to find available engineering degrees. You can use the main navigation to find specifics on the different types of engineering degrees, including the emerging online engineering degree. For general engineering articles including information on the highest paying degrees, those with the best employment potential, and steps to become an engineer, be sure to check the Engineering Career Guide.
Below are the most popular types of engineering degrees sorted by branch of engineering. Use the following links to quickly jump to your engineering category of interest:
There are many different types of engineering degrees, but not all are available online. The top online engineering degrees are: Computer Engineering, Engineering Management, Mechatronics Engineering, and different variations of Masters in Engineering Degrees.
An up-and-coming concept in the field of engineering academics is the online engineering degree, which is available at at least one school in every branch of engineering. Although there are not exactly a plethora of choices right now for some branches, more and more colleges and universities are adding online engineering degrees at every level. The most common so far is an online Masters in Engineering. Many engineers that have already earned their PE (Professional Engineer) license and are currently employed opt for taking online engineering classes to get their Masters degree. Obviously there are different specializations that cater more towards online engineering degrees, such as Engineering Management, while others are more difficult to learn online.
Undergraduate: Certificate, Associates, BachelorsYear by year, more engineering schools bring their programs online. The first engineering programs to go online were mostly at the Masters level, but as of late more online Bachelors in Engineering programs are coming online too. You may consider an online program from an accredited university currently accepting applicants:
Graduate: Masters, DoctorateThere are a decent number of Online Masters in Engineering programs, all in different areas of engineering. Computer Engineering, Software Engineering, and Engineering Management seem to be the most popular online engineering programs. You may consider an online program from an accredited university currently accepting applicants:
A Mechanical Engineering Degree involves the design of mechanical systems. These systems assist industries such as: manufacturing, aeronautics, nanotechnology, nuclear power production, heating and cooling. A primary focus is on thermodynamics, structural analysis, materials science, and kinematics. This is arguably the broadest of all engineering degrees available today and takes in a wide range of engineering disciplines. The Mechanical Engineering Degree has a number of subsets that intermix with electronics and electrical engineering, such as Mechatronics.
Undergraduate: Certificate, Associates, BachelorsTypically, mechanical engineering programs that are at the Certificate or Associates level are offered by Junior or Community Colleges. There are several online programs available at the Bachelors level that combine Mechanical and Electronics into a degree called Mechatronics Engineering. You may consider an online program from an accredited university currently accepting applicants:
Graduate: Masters, DoctorateMost graduate programs for Mechanical Engineering are located on campus, but there are a few online offerings for a Masters in Mechanical Engineering or a related program. You may consider an online program from an accredited university currently accepting applicants:
An Aerospace Engineering Degree involves the study of air and space travel. This might include military aircraft design and development, along with commercial airline design and satellite technology. The terms Aerospace and Aeronautical are both often used interchangeably, yet there are key differences between the two. Aeronautical Engineering relates to craft that remain in our atmosphere, while Aerospace Engineering refers to aircraft that venture outside our atmosphere. Most programs in the United States have changed their names from Aeronautical to Aerospace over the past couple decades, but there are still some programs that go by the historical name.
Undergraduate: Certificate, Associates, BachelorsThere are a few Aerospace programs online as most are on campus, but there are several online Aeronautics programs at the undergraduate level.
Graduate: Masters, DoctorateThere are a decent number of Online Masters in Engineering programs, all in different areas of engineering. Computer Engineering, Software Engineering, and Engineering Management seem to be the most popular online engineering programs.
Biomedical engineering combines the study of medicine and biology. Biomedical Engineers apply their design skills to biological and medical sciences. They do this to assist in advancements in healthcare treatment technology. They develop and maintain diagnostic devices. Devices that include EEGs, MRIs, and other imaging machines. Physicians use these machines to diagnosis their patients medical problems. This is a fast moving industry and while challenging can be a rewarding career path to take.
Available in: Certificate, Bachelors, Masters and Doctorate.
Biomedical Engineering Degree Detail
Biomechanical Engineering is the study of organisms and mechanics and how the two solve problems in combination. This is a growing industry and practical applications include environmental challenges such as waste control and keeping our waterways free from pollution. It shares close ties with Biomedical Engineering and Agricultural Engineering, as you might expect. Most working in Biomechanics have a Biomechanical Engineering Degree at the Masters level or above.
As the name implies, automotive engineering involves the design and production of vehicles. The automotive industry is hugely diverse and requires engineers to work in areas such as mechanical design, performance, manufacturing, electrical engineering and systems management.
Available in: Masters and Doctorate.
Civil Engineering involves the development of infrastructure such as buildings, railways, roads construction, bridges and general construction project management. Civil Engineers also play an important role in rebuilding projects, such as in the event of a natural disaster. Civil Engineers may work in the private or public sector at any level. This is a very broad engineering degree. Environmental Engineering, Structural Engineering and Marine Engineering are all specialties of Civil Engineering.
Available in: Certificate, Bachelors, Masters and Doctorate.
Civil Engineering Degree Detail
Structural engineering is a specific branch of civil engineering, and specializes in the design of different structures, including houses, commercial buildings, art museums, stores, and more. It is important for structural engineers to understand the construction of buildings and the effects of natural factors such as erosion, corrosion, wind, and water to ensure buildings and structures are safe for a very long period of time. At some universities, structural engineering is a concentration offered within a civil engineering degree.
Available in: Associates, Bachelors, Masters and Doctorate.
Structural Engineering Degree Detail
Architectural engineers work in the construction, planning, and design phase of projects. In conjunction with other team members, the focus is on building structure and interior design. This includes: Heating, Ventilation, Air Conditioning, Electrical, Fire protection, Lighting, Plumbing and other systems specific to the the project. In some areas natural disasters such as earthquakes and hurricanes have special consideration.
Available in: Certificate, Bachelors, Masters and Doctorate.
Architectural Engineering Degree Detail
An Electrical Engineering Degree involves the study of energy. Energy is available in various forms such as electrical, hydro and natural sources such as wind and solar energy. An Electrical Engineer develops technologies to assist with the practical application of such energies. Electrical Engineers design components for electronic equipment, communications systems, power grids, automobiles, and more. Most employers require an Electrical Engineering Degree at some level to work as an Electrical Engineer, and other licensing or certification requirements may also be required depending on where you live.
Undergraduate: Certificate, Associates, BachelorsAvailability of undergraduate online electrical engineering programs is limited, but many traditional unviersities have on-campus programs, especially at the Bachelors level.
Graduate: Masters, DoctorateThere are some options for Online Electrical Engineering Degrees, but some also consider the Masters in Computer Engineering.
Another industry that continues to expand is of course the Information Technology (IT) industry. This involves both computer sciences and electrical engineering. Successful graduates may find themselves in Telecommunications, Networking, Software Application Development, or Manufacturing, and additional industries are emerging, such as Application Development, Web Development, Network Security / Cybersecurity, and Cloud Computing, among others. This type of degree has good future potential as most industries rely on information technology. Read more about the computer engineering degree.
Undergraduate: Certificate, Associates, BachelorsThe most common computer engineering degrees are at the Bachelors level.
Graduate: Masters, DoctorateThe top graduate degree in computer engineering is the Masters in Computer Engineering.
Technology and specifically, electronics, have changed the way most of the world lives every day. From the revolutionary computer to the latest mobile phone technology that fits in your pocket, we all use electronics every single day. Electronics engineers are needed to design and build electronic equipment. Most electronics engineers work with circuits, switchboards, and other electronic configurations to design and build these devices.
Available in: Associates, Bachelors, and Masters.
Electronics Engineering Degree Detail
A blend of mechanical engineering and electronics engineering, Mechatronics, or Mechatronics Engineering, is an emerging area for hybrid engineers. Nearly all mechanical equipment in this day and age is operated with a mix of electronics and software, all based on computers and technology. Mechatronics engineers help bridge that gap, and have intrinsic knowledge of electrical, electronics, and mechanical engineering. Some more experienced Mechatronics Engineers also have computer, hardware, and software engineering experience as well.
Available in: Associates, Bachelors, and Masters.
Mechatronics Engineering Degree Detail
A robotics engineering degree has a primary focus on automation and the use of machines to assist with repetitive tasks such as those found in manufacturing. Robotics engineers will typically design robotic technology and develop maintenance systems to help achieve optimal efficiency. this is an area with expected growth of up to 15% in the next five years.
Available in: Certificate, Masters and Doctorate.
Robotics Engineering Degree Detail
If you have an interest in electronics a Microelectronic Engineering degree might be of interest. Microelectronics is a subset of Electrical Engineering with a focus on the word Micro. Microelectronic Engineers specialize in the development and design of small electrical devices. Used in a wide range of industrial applications. As we move away from bulky electronic devices such as the first mobile phones and desktop computers. We develop smaller more convenient electronic devices. As a result the demand for microelectronic engineers is high. Microelectronic engineers also assist in the technical writing aspect of a project. As well as perform tests to verify product conformance.
Available in: Masters and Doctorate.
Mechatronics Degree Detail
As the name implies, Chemical Engineering is the practical application of chemistry. This type of engineering degree involves technology that utilizes chemical reactions to solve problems. A chemical engineer creates new products, including: Cosmetics, foods, pharmaceuticals, beverages, and cleaners from raw chemicals. this is a very broad engineering degree and allows for a number of different forms of employment. It is also one of the most challenging degrees available.
Available in: Certificate, Bachelors, Masters and Doctorate.
One of the most popular kinds of engineering degree. Environmental Engineering involves the study of science and engineering to improve our environment. This includes the air we breathe, food we consume, and water. Environmental Engineers also study the environmental impact humans have on the planet, including pollution as a result of development and manufacturing processes. Environmental Engineering is considered a subset of Civil Engineering.
Available in: Certificate, Bachelors, Masters and Doctorate.
Environmental Engineering Degree Detail
A Materials Science engineering degree is a study of materials and why they behave a specific way or react to things in a certain way. This includes plastics, ceramics and polymers. Everything around us is made up of materials, as we evolve there is an increasing demand for materials which are stronger, more environmentally friendly and lighter. Employment opportunities include research positions along with industry placements. Materials Science Engineering is a very hands on, practical degree and graduates are in high demand.
Available in: Certificate, Masters and Doctorate.
An Agricultural engineering degree involves learning how to apply engineering to the agricultural industry to assist with area of farming including: soil conservation and salinity, ground preparation, irrigation, farm machinery design and production and helping develop more effective harvest techniques. Employment generally involves working in a consulting capacity or employed in a related industry such as machinery design and production.
Available in: Certificate, Bachelors, Masters and Doctorate.
Agricultural Engineering Degree Detail
Paper Engineering is a specialization of chemical engineering and involves understanding the processes involved (chemical and mechanical) of paper production. This type of degree involves both research based work and practical assessment which is typically lab work. Students learn the principles behind molecular science, wood pulping and fluid mechanics to name just a few.
Available in: Certificate, Masters and Doctorate.
Sustainable engineering takes into account the three major areas of sustainability: environmental impact, social and economic considerations. This includes not only the initial construction process but the complete life cycle of the product being developed. Graduates may complete further post graduate study or work in industries such as: Industrial waste water management, emission control and hazardous waste management.
An Engineering Management Degree combines engineering with business management training to arm the successful graduate with the ability to manage engineering projects or manage a team of engineers. A degree in engineering management limits the shortfall of engineers with limited business and management skills or managers with limited engineering knowledge. This type of degree is expected to rise in popularity over time.
Available in: Bachelors, Masters and Doctorate.
Engineering Management Degree Detail
Generally speaking, the MBA has become a staple among successful businessmen and businesswomen, and the engineering field is no exception. The MBA in Engineering is specifically tailored for engineers that already hold a bachelors degree in engineering. The program is ideal for FEs or PEs that wish to get into management, or VP/C-level positions in a company. Typically the MBA in Engineering has more benefit to those working in the private engineering sector.
Available in: Masters
MBA Engineering Degree Detail
Industrial engineers work for manufacturing companies, or as consultants to the manufacturing industry. The role of an Industrial engineer is to increase productivity and reduce waste and spending. Many new start-ups will hire an Industrial engineer to help make their business more efficient. Industrial engineers are also hired to test employee productivity and in house processes. Which will improve the efficiency of the company.
Available in: Certificate, Bachelors, Masters and Doctorate.
Industrial Engineering Degree Detail
Systems engineering is a multi disciplined engineering degree. While it has has evolved over time as systems have evolved with technology and greater efficiency its primary focus is on developing and improving upon existing systems. Systems engineers develop systems for workplace efficiency, risk management, measuring and refinement.
Available in: Certificate, Bachelors, Masters and Doctorate.
A Manufacturing Engineering degree focuses on manufacturing processes and machinery and quality control systems. Manufacturing makes up over 20% of Americas GDP and over 15% of our employment. As a result its important we refine our manufacturing processes for increased efficiency. This is a very broad discipline and can overlap other types of engineering studies including robotics and systems engineering. Students will study diverse areas of engineering such as: Material science, manufacturing technology and automation (robotics) along with fluid mechanics and hydraulics.
Available in: Certificate, Masters and Doctorate.
A petroleum engineer handles the extraction of oil and gas from beneath the earth. They are also involved in developing new extraction methods and technologies including new methods that are more efficient and less damaging to the environment. Petroleum Engineering is one of the highest paid engineering positions available. Petroleum engineers play a significant role in locating reservoirs beneath the earths surface for gas and oil companies.
Available in: Masters and Doctorate.
Petroleum Engineering Degree Detail
Geological engineers combine engineering and research skills for mining and construction projects. Construction firms hire Geological engineers. They assess ground conditions and other natural hazards (earthquakes, etc.) before starting construction. With declining natural resources available, Geological engineers are in high demand. Geological Engineers work in the private sector or governmental agencies.
Available in: Masters and Doctorate.
Nuclear engineers are at the core of development for the ever growing use of nuclear power. The medical field has become the largest beneficiary of many new developments. Nuclear engineers work for consulting firms, power plants, and government agencies. As expected, the demand for nuclear engineers in nuclear power plants is high. The design, implementation, and maintenance of the plant is one aspect of their duties. Many Nuclear Engineers also move into supervision and management.
Available in: Masters and Doctorate.
A Marine engineer applies knowledge to the development of ocean technologies. Technologies include fixed and floating structures, such as pontoons and jetties, propulsion and power generation for boats, ships and other marine transportation, and developing new forms of energy that are reliant on our oceans including wind farms.
Available in: Certificate, Masters and Doctorate.
An engineering physics degree combines engineering with physics and allows students to study the areas where these two areas intersect. It is also a precursor to graduate studies in either physics or engineering. Most graduates will work in research or another field of engineering such as mechanical engineering or nuclear engineering. The demand for this type of graduate is particularly high.
Available in: Certificate, Masters and Doctorate.
Photons are a specific type of light. Photonics engineering concerns itself with the exploration of light. this includes generation of light, processing of light signals, amplification of light and modulation. Industries that utilize this kind of technology include Telecommunications (optical signal processing and communication), Medical, Manufacturing, Aviation and computing to name just a few. Over the course of the next decade opportunities for qualified Photonics Engineers is expected to increase significantly.
Available in: Masters and Doctorate.
Nano essentially refers to a billionth e.g. one nano-meter is 1 billionth of a meter or between 2 and 20 atoms in length. Nanotechnology is the study of extremely small elements such as molecules and single atoms and the production of extremely small devices. Nanotechnology is expected to be as important to us as the industrial revolution over time as it has the potential to help solve some of the worlds major problems including health and environmental concerns. Nanotechnology is a very specialised discipline that can be applied to a very broad range of industries and fields.
Available in: Certificate, Masters and Doctorate.
A mining Engineering degree involves studying the extraction of mined resources from the earth in a safe, economical and environmentally responsible manner. Engineers are involved in the mining industry in areas such as: machinery production and design, mine design, mine construction. Mining Engineers may work closely with Geologists to discover the most effective extraction techniques and can be employed on site or work remotely.
Available in: Masters and Doctorate.
As the name implies. Ceramics engineers develop products from ceramics (ceramics being non metal, non organic materials that are generally produced by heating and cooling). Ceramics are often more suitable than metals in many cases due to their heat and cool resistance and can often be found in industries such as: medical, mining and electronics.
Available in: Masters and Doctorate.
A Metallurgical Engineering Degree involves the study of engineering principles to extract and in many cases purify metals and other minerals from ore. Metallurgical Engineers develop and design processing techniques and machinery and have to take into account the environmental impact of mineral processing.
Available in: Masters and Doctorate.
A Geomatics Engineering degree involves the study of precise measurement for mapping the earths environment using advanced equipment and techniques. Geomatics Engineers play an important role in planning future infrastructure and often work with large amounts of data to form digital replications of terrain and develop 3D maps. This also includes the study of GPS technology. There is a shortage of qualified Geomatics professionals and as a result they are in great demand.
Available in: Masters and Doctorate.
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MIT community members elected to the National Academy of Engineering for 2022 – MIT News
MIT engineers John Cohn and Franz-Josef Ulm and are among 111 new members and 22 international members elected to the National Academy of Engineering for 2022. Nineteen MIT alumni were also elected as new members.
John Cohn '81, an IBM Fellow in the MIT-IBM Watson AI Lab, was honored for improving design productivity of high-performance analog and mixed-signal circuits and for evangelizing STEM education. Cohn, a computer scientist with more than 100 worldwide patents, uses his playful love for science and technology to promote STEM careers. Hes active in education issues at the local, state, and national levels, and his passion for STEM education led him to spend 59 days living and inventing in an abandoned steel mill as part of the Discovery Channels technical survival show The Colony.
Franz-Josef Ulm, professor in the Department of Civil and Environmental Engineering, was honored for his contributions to nanoscale improvement of concrete and other materials and structures important for sustainable development of infrastructure and energy resources. Ulm, a structural engineer and engineering scientist, is also faculty director of the MIT Concrete Sustainability Hub, which brings together an interdisciplinary team of researchers across MIT working on concrete and infrastructure science to develop breakthrough approaches for sustainable homes, buildings, and green infrastructure.
Nineteen alumni were also named to the NAE this year, including Anna Christina Balazs SM 77, PhD 81; Kathleen Bergeron 93, PhD 81; Rena Bizios PhD 79; Jian Cao SM 92, PhD 95; Michael Dettinger SM 79; Nancy Dudney PhD 79; Louis Durlofsky SM 82, PhD 86; Stephen D. Fantone 74; Craig Fields 66; Youssef Hashash 87, SM 88, PhD 92; Nola Hylton-Watson 79; George Karniadakis 84, PhD 87; Guy Nordenson 77; David A Petti 82, MS 83, ScD 86; David K. Robinson PhD 87; Julie M. Schoenung MS 85, PhD 87; Masayoshi Tomizuka PhD 74; Karen Willcox MS 96, PhD 00; and James A. Yurko PhD 01.
Election to the National Academy of Engineering (NAE) is among the highest professional distinctions accorded to an engineer. Academy membership honors those who have made outstanding contributions to "engineering research, practice, or education, including, where appropriate, significant contributions to the engineering literature and to "the pioneering of new and developing fields of technology, making major advancements in traditional fields of engineering, or developing/implementing innovative approaches to engineering education, according to NAE.
Including this years inductees, 148 members of the NAE are current or retired members of the MIT faculty and staff, or members of the MIT Corporation.
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MIT community members elected to the National Academy of Engineering for 2022 - MIT News
Out of this world research: VCU engineering researcher sends experiments to International Space Station – VCU News
By Rebecca JonesCollege of Engineering
When the Antares rocket lifts off from NASAs Wallops Flight Facility in Accomack County, Virginia, on Feb. 19, experiments from the Virginia Commonwealth University College of Engineering will be onboard.
James Ferri, Ph.D., a professor and associate chair in VCUs Department of Chemical and Life Science Engineering, is part of an international team of researchers collaborating with NASA and the European Space Agency to send fluid science experiments to the International Space Station.
This research project is headquartered at the Glenn Research Center in Cleveland, Ohio, in collaboration with the European Space Agencys Fluid Science Laboratory.
As part of this project, Ferri has been working since 2010 on formulations to improve the stability of emulsions. The ability to stabilize emulsions is essential to developing pharmaceuticals, agricultural chemicals and a world of consumer products.
An emulsion is formed by dispersing one liquid into another think oil-and-vinegar salad dressing. Because their liquid components have different physical properties, emulsions tend to separate. More effective dispersion stabilizers, known as surfactants, are needed to keep emulsions mixed for longer periods.
The science team has selected surfactants, and the methodologies that will be used to test them over the course of four months aboard the space station. Outside Earths gravity, researchers can better study the chemical and physical principles that determine the stability of dispersed fluids.
In the microgravity of outer space, a carousel of formulations made of oil, water and surfactants will be subjected to light-scattering tests. Shining beams of light through the samples will allow the team to measure the rate of growth of individual droplets within the emulsions over time. These results will supply essential data to help assess the effectiveness of the new surfactants Ferri has prepared.
Later this year, data from the space station experiments will help generate better emulsion dynamics models for industrial applications. These models will be shared with industry and government agencies for use in developing safer, more stable and greener chemical formulations.
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Engineering Extremes: Enabling communication in noisy and hostile environments – Professional Engineering
Jordan McRae's mobiWAN technology uses bone conduction to allow users to both transmit and receive audio
Twenty metres below the surface, Jordan is battling to breathe. He pulls hard, but the oxygen wont fill his lungs. Theres a powerful current in the ocean and poor visibility. Nothing but blue fuzz in every direction.
Jordan tries the secondary regulator on his scuba suit. Its broken too, injecting a fine mist of salt water into his lungs. Its time to escape. Jordan isnt panicking yet. Hes trained and knows how to surface, following the smallest air bubble up. He signals to the only other diver he can see. Im going up, he says with his thumb.
But the diver misunderstands and pulls Jordan down by the legs. Jordan grabs the mans secondary regulator to get the air he needs. Hes got time now. He wishes there was a way for the two of them to speak. For the man to say: Calm down, everythings OK, were going up to a safety spot, then were out of this situation.
Recovering on a beach in Mozambique, Jordan McRae thinks a lot about what happened. An engineer, he knows the problem he experienced can be solved with technology. He thinks about the fundamental power of a voice. And how people should be able to communicate anywhere, with anyone. Like that air bubble, an idea begins to rise in his mind. An idea that leads Jordan to mobiWAN, an innovative bone-conducting technology that bypasses the ears and puts a voice directly inside a listeners head.
Those who use mobiWAN say it feels like magic. But Jordan (38) is no magician. Hes a modern-day inventor who trained at the Massachusetts Institute of Technology (MIT). His journey includes everything from working on top-secret robotic planetary defence projects with Lockheed Martin and NASA to collaborating on digital art projects in Paris. Hes done the Steve Jobs thing, working out of a garage in San Francisco, prototyping a bunch of cool stuff. Hes dabbled in renewable wind energy and modular electronic components (landing him on Kickstarters hall of fame).
Ive always believed you have to do what you love and do what interests you, says Jordan. You have to create the freedom you need to be an inventor.
At school, Jordan wanted to be a marine engineer. He was drawn to the ocean. He wanted to find ways for more people to explore and protect it.
Jordan McRae
To study at MIT and then at Stanford University in California, Jordan mixed scholarships, part-time work and military service. Those were tough years, but they gave him freedom later on.
In 2017, Jordan returned to London and founded Mobilus Labs. The young tech start-up secured funding and recruited a team of engineers and designers to build the mobiWAN headset. Initially, the focus was on turning sound into vibrations and sending that in one direction to a listeners inner ear. The beauty of the design is that users can communicate clearly at a construction site, an oil rig, or in any noisy location. They can wear ear plugs and still hear each other over the machinery or powerful winds. Most importantly, they can stay safe by being able to communicate.
Jordans company built the prototypes, tested the concept and soon became the exclusive audio partner to Trimbles XR10 HoloLensmixed-reality headsets. Thousands of the first-generation mobiWAN headsets have been sold in more than 20 countries.
Last October, Mobilus Labs launched the next-generation headset, which allows for two-way bone-conducting traffic. The new bit is the microphone, which turns vibrations into voice, before sending it to the listener where the reverse process plays out. This solves the ancient audio problem of isolating a single voice in a loud and chaotic environment, sending a clean digital signal to the receiver.
The upgraded mobiWAN headsets are being tested in all kinds of environments.
In future, I want all machines to speak the language I speak, in the most natural way, to make it as easy as possible for me to use them as a tool, Jordan explains. And voice is one of the most intuitive ways to transfer data.
His focus remains on how technology can become a better part of the human experience.
Jordans book of ideas grows, page by page. And he still loves the ocean. Not long ago, he and his fiance used a prototype bone-conducting device while diving in the Caribbean.
I pointed out a barracuda and, when she saw it, she was so excited, Jordan recalls.
I got to hear what she was thinking. I got to share that moment.
There were no underwater misunderstandings that day.
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Open House with College of Engineering and Computer Science will Celebrate its Programs and Alumni – neareport.com
JONESBORO An open house planned by the College of Engineering and Computer Science (CoECS) at Arkansas State University will highlight the student and faculty celebration of National Engineers Week in the United States,Feb. 21-25.
The CoECS students have picked that week to celebrate the college with fun activities each day. The student chapters of professional organizations, including Society of Manufacturing Engineers, Association for Computing Machinery, American Society of Mechanical Engineers, American Society of Civil Engineers, and Institute of Electrical and Electronic Engineers are organizing many of the special events.
To culminate the weeks celebration, the college will host an open houseFriday, Feb. 25.Prospective students, along with family members and high school counselors, have been invited to campus where they can meet with current students and faculty, and visit the various CoECS labs.
While college open houses are a tradition nationwide, not as typical is the presence of the offices of Financial Aid, Admissions, and Career Services during the event, noted Dr. Abhijit Bhattacharyya, dean of the college. Further, a first this year is the presence of almost a dozen employers who will be present to meet with prospective students and discuss job opportunities for graduates of our programs.
Also participating will be Dr. Andre Possani-Espinosa, director of engineering of A-State Campus Queretaro. Due to the similarity in the engineering curriculum offered at both campuses, the Mexico site could be a natural study abroad destination for students in CoECS, the dean added.
This entire experience for the visitors will showcase the pathway, from the high school, through the College of Engineering and Computer Science at A-State, to the workforce, Bhattacharyya added. The number of expected visitors is approximately 175, coming from across the State of Arkansas and the region.
As part of the event, Bhattacharyya also said CoECS is showcasing highlights from the careers of five of its graduates, in order of graduation at A-State:
Brinkley earned his bachelors degree in electrical engineering in 1992, then a masters at the University of Tennessee. His graduate research in laser-induced spectroscopy was sponsored by Thompson Cancer Survival Center. Following career stops at R. E. Phelon Co. as a product design engineer, then DENSO in Maryville, Tenn., as an electronics quality engineer, he became power module customer quality engineer in Fayetteville for Wolfspeed, Inc., which makes semiconductors for electric vehicles.
Butlers career has taken him to three different enterprises. Following his 1999 graduation with a bachelors degree in technology, he was director of lean transformation/process improvement for Cancer Treatment Centers of Americas Tulsa facility, and industrial/project engineer for Boschs Skil Power Tools manufacturing facilities in Walnut Ridge and Heber Springs. He also was involved with building Boschs North American Distribution Center in West Memphis. He is now senior business analyst hub operations for AutoZone at the corporate headquarters in Memphis.
Jones, a 2001 graduate with a bachelors degree in engineering with a concentration in civil engineering, has progressed through a 20-year career with the Arkansas Department of Transportation, working in design, research and planning. Now head of the Program Management Division, she oversees activities supporting pre-construction project development, management of Federal-aid highway programs, and development of the Statewide Transportation Improvement Program.
Avant, who completed his bachelors degree in computer science in 2011, is a software engineer for Rural Sourcing Inc., specializing in C#/.NET, Full-Stack JavaScript, and Cloud Technologies. He is an expert consultant who provides clients with the building blocks needed to achieve their technological goals. Avant also specializes in leading development teams and helping colleagues to achieve their career aspirations.
Rebecca L. Chen, who earned a bachelors degree in mechanical engineering, was active in the A-State student chapters of professional organizations in which she continues to be involved. She gained experience as an intern for Whirlpool and Nidec Motor Corp. Following graduation in 2020, she was employed by General Motors. After working through various positions, she is now co-chair of the Issue Resolution Team for chassis and active thermal management.
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Meet the inventors: Bed-load transport measurement technique – U.S. Army Corps of Engineers
VICKSBURG, MISS.--What did it take for the four-member research team who developed the ISSDOTv2 bedload transport methodology to create a U.S. patent-worthy invention?For this team, it was made possible by varied expertise, a combined 86 years of experience, a desire to solve river sediment challenges and helpful friendships.
A resident of Magee, Mississippi, Tate McAlpin joined the U.S. Army Research and Development Center (ERDC) in 2002 as a co-op student and transitioned to full-time in 2005 in the Coastal and Hydraulics Laboratory (CHL) River and Estuarine Engineering Branch.
His areas of expertise include 2D and 3D numerical modeling of rivers and estuaries, as well as numerous projects measuring bed-load transport rates and analyzing associated hydraulic and sedimentation impacts.
My role on the ISSDOTv2 team has primarily been in the transition from the basic equation of bed-load to a numerical method capable of providing consistent and accurate results in a timely fashion, McAlpin said.
David Abraham is a member of the CHLRiver and Estuarine Engineering Branch and a resident of Vicksburg, Mississippi. His expertise in numerical and physical modeling of riverine hydraulics, sediment processes, structures and geomorphology guided the team during the invention process.
During his 33-year career at ERDC (formerly known as the Waterways Experiment Station), Abraham was the primary developer of the original ISSDOTv2 equation of bed-load transport.
What? You mean we can send a man to the moon, but we cant measure the amount of sand moving on the bottom of large sand-bed rivers? Abraham asked himself as an initial reaction when discussing the topic with U.S. Army Corps of Engineers personnel in the late 1990s.
Then when viewing the new (at that time) multibeam bathymetric data of river bottoms with Thad Pratt, the seed was planted as to how it could be done. A four-month CHL research grant carried out at the Iowa Institute of Hydraulic Research (IIHR) in 2008 provided the time and environment to finalize a mathematical functional relationship.
The rest is history, as they say, Abraham said. And that history came about through the creative brilliance, dedication and hard work of every team member.
Working as a hydraulic engineer for 11 years, John Shelley joined the invention team from the U.S. Army Corps of Engineers Kansas City District in Independence, Missouri, where he works with the River Engineering and Restoration Section. Hecontributed expertise in data collection processes and methodology.
My role was relatively small in the overall development of ISSDOTv2, Shelley said. I was doing a developmental assignment at CHL in February 2011 when I met David Abraham and Tate McAlpin.
Shelley explained that Abraham had recently computed ISSDOTv2 bedload data from multibeam surveys on the Missouri River in his home district.
(Abraham) said, Ill give you the data and you can play around with it, Shelley recalled. When I plotted the values for bedload transport, I noticed an interesting patternthe longer the time between surveys, the lower the computed value for bedloadtransport.
Abraham suspected that the drop in the computed transport values was due to regions of the river that scour and then refill between when the surveys are measured.
I devised a method to eliminate the bias by fitting a line to the observed transport values and extrapolating.We published this finding in the Journal of Hydraulic Engineering, and this correction became standard practice in the ISSDOTv2 procedure, Shelley said, adding that he is an advocate for additional ISSDOTv2 collection in support of his Missouri River Bank Stabilization and Navigation Project and Missouri River Recovery Program.
As CHLs Military Technical Director, Vicksburg native Thad Pratt added his expertise to the team as a research physicist, along with his 32 years of ERDC experience. He has provided oversight and leadership for numerous projects, including those of other invention teams.
Pratts projects focus on river sediments and understanding their distribution, particle sizes, historical data and related information. This leads to planning and working with existing natural processes to minimize navigation and flood risk challenges while enhancing natural habitats.
Sediments are important to the health and welfare of the river, Pratt said. Certain types of fish and invertebrates need certain sediments. If this sediment isn't being delivered, that fish or that invertebrate will not be living in that river reach.
Sediment load drives many of the natural processes that impact the river, so the invention to measure the amount of sand moving on river bottoms is important.
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Meet the inventors: Bed-load transport measurement technique - U.S. Army Corps of Engineers
Post Doctoral Researcher, Electronic Engineering job with MAYNOOTH UNIVERSITY | 282033 – Times Higher Education (THE)
Department:Electronic EngineeringVacancy ID:014161Closing Date:03-Apr-2022
The vacancy is for a one-year postdoctoral position in the area of microfluidics. The postdoc will be leading the building/optimising a microfluidics platform that be developed in parallel with the bCARS microscope. This microfluidics platform will feature a pump system feeding into a microfluidic slide using a hydrodynamic flow focusing structure to generate water-in-oil droplets with high-throughput, continuous-flow, and the capacity for ultralow-volume sorting of cells. Off-the-shelf or customised PDMS or glass chips will be used to create the water droplets in oil that are hydrodynamically focused at high flow rates. Should off-the-shelf solutions not meet the needs of the project, the postdoc will help design chips to meet the required specifications and we will outsource manufacture. The postdoc will be required to work closely with other team members building the bCARS microscope and will be involved in alignment of the laser system into the hydrodynamic channel to probe the flowing cells.
Salary
Post-doctoral Researcher (2021): 39,132 per annum (1 point)
Appointment will be made in accordance with the Department of Finance pay guidelines.
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UCF Researchers use Engineering Expertise to Solve Problems of the Heart – UCF
UCFs engineers do more than develop innovative space technology or reimagine the next generation of wind turbines they also solve matters of the heart.
Several mechanical and aerospace engineers at UCF focus their expertise on finding creative solutions to various heart conditions. Heart disease is the leading cause of death for men and women in the United States with one person dying every 36 seconds, according to the Centers for Disease Control.
Its rewarding to work on such interesting problems at the interface of engineering and medicine with the precise aim to improve quality of life, says Alain Kassab, a professor and director of the UCF biomedical engineering program.
Removing the Defects From Pediatric Open-heart Surgery
When children are born with a defective ventricle, they typically undergo a series of three surgeries to reconfigure the heart and the circulatory system. During the final procedure, a new system known as Fontan circulation is established. This allows the blood that returns from the body to flow directly to the lungs without passing through the heart, while the single functioning ventricle pumps blood to the body.
Children typically undergo the Fontan procedure between the ages of 1 and 3. While it may help them survive infancy, it doesnt guarantee that theyll live a long life.
A substantial proportion of patients with the Fontan circulation do not do well as a consequence of having taken the pumping right ventricle out of the pulmonary or Fontan side of the circulation, says Kassab. Although this surgical treatment began nearly 30 years ago, the mortality rate is still elevated with nearly half of patients not surviving beyond the age of 20.
Physicians believe that a substantial proportion of patients with the Fontan circulation do not do well because the pumping right ventricle has been taken out of the pulmonary side of the circulation, says Kassab. Although the first Fontan surgery was performed nearly 50 years ago, the mortality rate is still elevated with nearly half of patients not surviving beyond the age of 20.
To improve upon the defects created by Fontan circulation, Kassab is collaborating with a team of multidisciplinary researchers to develop a self-powered injection jet shunt that utilizes the hearts own energy to alleviate the increase in pressure caused by the rerouted circulatory system.
The team which includes William DeCampli, the chief of pediatric cardiac surgery at Arnold Palmer Childrens Hospital and a professor of surgery at the UCF College of Medicine; Ray Prather 13 15MS 18PhD, a senior research associate at Arnold Palmer Childrens Hospital; and Eduardo Divo 98PhD, the chair of the Department of Mechanical Engineering at Embry-Riddle Aeronautical Engineering initiated this project in 2015. Together, theyve secured more than $700,000 in grants from the American Heart Association, the Childrens Heart Foundation, and Additional Ventures, a nonprofit that supports research on single ventricle heart defects.
Our close collaboration with Dr. DeCampli and Arnold Palmer Childrens Hospital is the key to effectively addressing such a complex multi-disciplinary problem, says Kassab. Each team member brings key expertise to bear on the critical aspects of the physics and physiology of the problem.
The latest research data was published in Scientific Reports on Feb. 9.
Monitoring Heart Failure Through Sound
Patients who have been diagnosed with heart failure may be able to monitor their heart health with the aid of a credit card-sized device in the near future. This innovative, non-invasive heart monitor will use acoustic technology to monitor the deterioration of heart function, which could reduce the need for patient hospitalization and even prevent death.
Associate Professor Hansen Mansy, who runs the Biomedical Acoustics Research Laboratory, is developing this device in collaboration with Richard Sandler of the UCF College of Medicine. The pair received a $1.3 million grant from the National Institutes of Health in 2017 to complete the project.
The device is designed to be used by patients, but it will provide important data to physicians who can determine if further medical intervention is necessary. Patients will place the small device over their chests and a sensor will detect the chest vibrations caused by their heart activity. That recorded activity can then be uploaded to a mobile phone or computer and sent to physicians daily via a secure patient portal.
Physicians can use the data to determine if a patients heart heath is worsening. If it is, they can implement a more effective treatment plan that can prevent hospitalization and improve the patients quality of life.
Mansy and his research team have already begun clinical testing on the device.
Although the clinical testing has been slowed down due to COVID-19, initial results are encouraging and suggest that early detection of the need for hospital readmission may be feasible using our proposed methods, Mansy says.
The team has used advanced signal processing methods to measure the electromechanical signals of the heart. The features of those signals are extracted and the data is put into a machine learning algorithm that builds the model that can predict heart function deterioration.
Mansy and Sandler are collaborating with AdventHealth and the Biomedical Acoustics Research Company on the project. Mansy says that the next steps for the team include further analysis and additional clinical testing.
Creating Faster and More Accurate Diagnoses
In the Computational Biomechanics Lab, Assistant Professor Luigi Perotti and his team are using computational modeling to develop a new non-invasive method of detecting the biomarkers of cardiac deformation, which could lead to faster and more accurate diagnoses of heart disease.
One of our main focuses is to analyze imaging data to determine the biomarkers of cardiac health, Perotti says. These biomarkers could then be extracted from patient-specific data and indicate the onset or progression of cardiac diseases.
By using patient data that is already available in the clinic rather than data acquired through a research setting, Perotti says that physicians can diagnose their patients much faster. He believes their diagnoses can also be more accurate by using aggregate cardiomyocyte strains made of the cells responsible for contracting the heart and pumping blood through the circulatory system as biomarkers for cardiac health.
Perotti is collaborating on this project with researchers from Stanford University and the University of Lyon.
How Biomechanical Forces Influence Heart Disease
While his colleagues look for solutions to the problems caused by heart disease, Assistant Professor Robert Steward uses his engineering expertise to explore the problems that cause heart disease.
With the support of a $738,000 grant from the National Institutes of Health, Steward has spent the past five years investigating the biomechanical forces that can influence the early stages of heart disease known as atherosclerosis. This stage is characterized by an excessive buildup of white blood cells and bad cholesterol in the arteries. Steward found that blood flow induces mechanical stress that allows white blood cells to enter weak areas of the heart.
The findings yielded from this work have the potential to lead to novel, mechanics-based therapeutics for cardiovascular disease, Steward says.
Steward collaborated with Sampath Parthasarathy from the UCF College of Medicine on the project, which officially concludes in May. He plans to publish the findings in an academic journal in the coming months.
In the meantime, Steward will use his CAREER grant, sponsored by the U.S. National Science Foundation, to pick up where the NIH project left off. He was one of five UCF researchers to receive the award this past year.
He says the NSF project will focus on the basic science of how biomechanical forces influence the endothelium, a group of cells that line the blood vessels in the body, including the arteries. With this knowledge, better therapies for heart disease could be developed, or the disease could potentially be eliminated.
Over the past few months, Steward and his Cellular Biomechanics Lab have been exploring the use of machine learning algorithms to predict the biomechanical response of the endothelium, but he says further refinement is needed for this portion of the project.
About the Researchers
Kassab joined UCF in 1991 and has received numerous awards and distinctions since then, including the titles of Pegasus Professor and UCF Trustee Chair. His research spans several disciplines in computational heat transfer and fluid dynamics, inverse problems, boundary element and meshless methods. He has been funded by the American Heart Association, Orlando Health, Siemens, the U.S. National Science Foundation,and NASA, to name a few. He earned his bachelors degree in engineering sciences and his masters and doctoral degrees in mechanical engineering, all from the University of Florida. He is also a fellow of the American Society of Mechanical Engineers and the American Institute for Medical and Biological Engineering.
Mansy received his Ph.D. at the Illinois Institute of Technology and bachelor and masters degrees at Cairo University in Cairo, Egypt. He was associate professor of bioengineering at Rush Medical College before joining UCF. He has been developing vibro-acoustic medical technologies for the past 20 years with continuous support from the National Institutes of Health. He has supervised bioengineering student projects at Rush Medical College, University of Illinois at Chicago and UCF and has developed bioinstrumentation, and mechanical and aerospace engineering measurements lab facilities at UCF and Illinois Institute of Technology.
Perotti received his undergraduate degree in civil engineering from Politecnico di Milano in Italy and his masters and doctoral degrees from the California Institute of Technology. He served as an America Heart Association postdoctoral fellow at UCLA and in 2017, he received an NIH K25 Mentored Quantitative Research Career Development Awardto continue his research on combining computational models with MRI data and conduct pre-clinical studies.He joined UCF as an assistant professor in 2019.
Steward joined UCF as an assistant professor in 2015. He previously served as a postdoctoral scholar at the Harvard T.H. Chan School of Public Health, where he investigated the influence of fluid shear stress on endothelial biomechanics. He earned his doctoral degree at Carnegie Mellon University and his bachelors degree at Clark Atlanta University. Steward currently runs the Cellular Biomechanics lab located on UCFs Health Science Campus at Lake Nona, where he has multiple projects with the ultimate goal of linking mechanics and medicine.
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UCF Researchers use Engineering Expertise to Solve Problems of the Heart - UCF