Structural Engineering Career

Structural Engineering focuses on the support integrity of large developments such as buildings, bridges and stadiums. Structural engineers are responsible for some of the most import constructions in history, including Washington Roebling who built the Brooklyn Bridge in New York and Gustave Eiffel who completed The Eiffel Tower in Paris, France. Structural engineers traditionally collaborate with a team of professionals including architects, urban planners and civil engineers, among others, to realize the completion of a project.

Federal and local governments as well as private enterprises contract these practitioners for work throughout the world, whereby they are entrusted to ensure public safety by meeting building codes and standards. For buildings, these professionals achieve this by developing the components such as roof framing columns and foundations. In bridges, they develop the piers, deck and/or stringers. In addition, they select the most appropriate materials including wood, concrete, steel and/or aluminum, thereby protecting the structure and surrounding communities in the case of natural disasters, weather, collisions or explosions. To determine the best materials, structural engineers rely on digital hardware and software applications for modeling and analysis.

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Master’s Degree in Automotive Engineering

Master’s Degree in Automotive Engineering 

A master's degree in automotive engineering is not necessary to work in the field, but such a degree will give students specialized automotive engineering knowledge and skills. Moreover, master's degree programs offer research opportunities for students. It takes about two years to complete a master's degree program in automotive engineering.

Studies include:

• Design and manufacturing
• Energy and environment
• Materials
• Noise and vibration
• Powertrain
• Dynamics and control
• Electronics and computer software
• Ergonomics

To earn a master's degree, the student must satisfy the university's thesis requirements and/or complete a final project.

The few universities that offer online automotive engineering degrees do so only at the master’s degree level. The student gains only theoretical knowledge from an online master's degree. The student does not receive any hands-on experience, which can be important to landing a job in automotive engineering. The online programs assume that the student received hands-on experience while obtaining the bachelor's degree. Therefore, online master's degree programs in automotive engineering are meant for the working automotive engineer.

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Electrical Engineer Careers

Electrical engineers specialize in power supply and generation. They design, develop, test and supervise electrical equipment manufacturing. They have also been trained to handle responsibilities like wiring and lighting installations in buildings, automobiles and aircraft.

What is great about being an electrical engineer is that the training is so extensive that graduates may land a job in many different industries such as construction, manufacturing and design.

Moreover, electrical engineers may take part in development and research as assistants to scientists and other engineers. Many kinds of electronic equipment from portable music players to GPS devices pass through an electronic engineer’s hands.

They come up with means to use electrical power to operate a certain product or improve its functions. Among the most challenging and in-demand tasks for electronic engineers today include developing construction plans for electrical lighting systems for skyscrapers, designing remote-controlled race cars and building technology for factories like robots that can perform welding.

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Career Outlook Advice for Thermal Engineers

Career Outlook Advice for Thermal Engineers

Thermal engineering professionals have access to a medley of organizations and associates to bolster their careers. From the American Society of Mechanical Engineers (ASME), which features a library of resources for present and future practitioners, to the Technology Student Association (TSA), and the National Society of Professional Engineers (NSPE), students and seasoned thermal engineers access information and soil-building resources to buttress their daily learning. They specifically learn of the constantly evolving developments in technology and best practices that are transforming the industry. In addition, updates are provided on events, news and congresses within the field that endeavor to unite and strengthen the community. Young engineers have access to mentoring and networking opportunities that will facilitate their entry and rise into the profession. Moreover, prospective job candidates have access to recruiters from prestigious global firms like Intel, Sony and ConEd. As stated by the U.S. Bureau of Labor Statistics (BLS), the job prospects for thermal engineers are predicted to continue to grow by 9 percent through 2020. The U.S. states of California and Texas are geographic locales featuring the most opportunities for these professionals. According to compensation statistics at O*Net salary data, these engineers earned a median salary of $82,100.

Thermal engineers have been instrumental in changing the way people find and use energy throughout the world as well as in pushing space exploration into new realms. Most people think of Google as an Internet search engine company, but the firm has expanded its resources into creating better energy solutions for the planet. The firm actively recruits thermal engineers to work on its project for developing clean and affordable power grids. Their Energy Access team endeavors to recruit and nurture engineers to its efforts, underscoring its conviction in its identity as an engineering firm.

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Discover the World of Nanoengineering

Nanoengineering encompasses the practice of the profession on a nanoscale, which stems from the nanometer unit of measure, equivalent to one billionth of a meter. Within the industry, nanoengineering is synonymous with practices of nanotechnology, whereby it focuses on the engineering component of a given technology rather than the scientific side. Nanotechnology professionals have become prized professionals in the current marketplace for their skills and training dealing with microscopic applications.

From the automobile and energy industry to healthcare and technology firms, companies around the world eagerly seek to attract and develop these professionals. Within these realms, scanning tunneling microscopy (STM) and atomic force microscopy (AFM) are the dominant techniques of the field used to solve problems and originate new technologies. Both techniques pivot on generating microscopic probes to manipulate and track the movement of atoms with the idea of capturing something significant to translate into real world applications such as revolutionary manufacturing materials or new pharmaceutical products.

To learn more about becoming a nanoengineer, contact the schools below to request more information. We recommend contacting multiple schools to compare programs.

Professionals in this field often perform a medley of duties depending on the industry they work in and/or their educational backgrounds. In biosciences, nanoengineers dedicate their time to developing new medical device products and ways to enhance existing ones. From a construction viewpoint, these experts investigate and evaluate the development of new materials to develop more sustainable and durable building products and materials. Automotive companies employ these engineers to develop more efficient processes within an engine system and materials to build and pad vehicle systems and interiors. Regardless of the field, these engineers choose to employ their skills and talents, the field requires immense patience and attention to detail. Refining the effective use of STMs and AFMs, critical to the development of new technologies and breakthroughs, often proves to be challenging for most practitioners in the field. Powerful microscopes with exceptionally fine silicon tips are employed to monitor the nano activity harnessed to develop new applications. Establishing a suitable tip, though, can sometimes take seven days alone. Nevertheless, global firms like Abbott Laboratories, Tesla, Exxon-Mobil, and Sony are a few of the global firms capitalizing on the potential of nanotechnology.

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Audio Engineering Degrees

Audio engineering is an intricate blend of science and creativity. It involves technical aspects of equipment set-up and operation, but also requires a creative side to enhance and blend the sounds to produce the desired effects.

Often called sound engineers, these professionals are highly sought after in all areas of the entertainment industry. Musicians depend on audio engineers in the studio and in live performances to polish their sound and to keep it consistent throughout each recording or performance. Audio engineers mix the music and enhance the balance to provide the best final product. In television and movies, audio engineers are responsible for all of the sound effects, music, and sound levels heard in the video productions. Even radio depends on sound engineers to keep their stations operating properly. There are other careers available to audio engineers, but the entertainment industry provides the most opportunity.

For those interested in pursuing a career in the audio engineering field, there are three different levels of degrees available. An Associate in Applied Science will teach the basics of working in the industry. The Bachelor of Science degree goes more in depth in both the music and technical aspects of the business. The Master's degree programs focus on very specific aspects of audio engineering.

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Master of Science Degree and Doctorate in Aerospace Engineering

Master of Science Degree and Doctorate in Aerospace Engineering

Graduate students seeking a master's or doctorate degrees to augment their undergraduate or graduate education can take advanced courses in:

• Aerodynamics and fluid mechanics
  • The study of air flow over a body, such as the wings on an aircraft or spacecraft.

• Aeroelasticity and structural dynamics
  • The study of how inertial, elastic and aerodynamic forces interact.

• Flight mechanics and control
  • The study of how forces affect a flight vehicle, how it responds to those forces and how to modify the vehicle to achieve the desired goals.

• Propulsion and combustion
  • The study of creating mechanical power using internal combustion engines, jet engines, turbomachinery, propellers, wings, fins, and wheel and axles to generate force causing motion.

• Structural mechanics and materials behavior
  • The study of the stress and strain on the components of a flight vehicle.

• System design and optimization
• The study of the application of algorithms to improve the performance, weight, reliability and/or cost of aircraft and spacecraft systems.

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Computer Engineering Degrees

Most people own or have ready access to a personal computer. These marvels of modern technology have revolutionized everything from the way we get our news to how we communicate with friends and relatives to how we entertain ourselves. However, the traditional PC or laptop is only one type of computer. Virtually every modern machine and process is computer-controlled. Some computers are tiny, as in the smallest cell phones and MP3 players.

Other computers are actually massive networks of thinking machines, working on terabytes of data and cranking out billions of calculations per second. The common factor making these machines possible is the Computer Engineer. Computer Engineering differs from Software Engineering and Computer Science in that it focuses on the actual hardware that’s responsible for performing the work. Software is the set of instructions used by a computer to get work done.

Without Computer Engineers designing the hardware platform it runs on, software would be so many useless bits of data. While they need to know the principles of software operation, Computer Engineers are responsible for designing the components of a computing system. Whether that computer is in the Stealth Bomber or under your car’s hood, all computers have similar components and functions, varying mostly in size, shape and application.

Computer Engineers design everything from the Central Processing Unit to primary and secondary memory storage to input and output methods. Even if they are using off-the-shelf components, they’re responsible for making sure the integration works flawlessly.

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Real Life Impact of Thermal Engineers

Networking and Career Outlook Advice for Thermal Engineers

Thermal engineering professionals have access to a medley of organizations and associates to bolster their careers. From the American Society of Mechanical Engineers (ASME), which features a library of resources for present and future practitioners, to the Technology Student Association (TSA), and the National Society of Professional Engineers (NSPE), students and seasoned thermal engineers access information and soil-building resources to buttress their daily learning. They specifically learn of the constantly evolving developments in technology and best practices that are transforming the industry. In addition, updates are provided on events, news and congresses within the field that endeavor to unite and strengthen the community. Young engineers have access to mentoring and networking opportunities that will facilitate their entry and rise into the profession. Moreover, prospective job candidates have access to recruiters from prestigious global firms like Intel, Sony and ConEd. As stated by the U.S. Bureau of Labor Statistics (BLS), the job prospects for thermal engineers are predicted to continue to grow by 9 percent through 2020. The U.S. states of California and Texas are geographic locales featuring the most opportunities for these professionals. According to compensation statistics at O*Net salary data, these engineers earned a median salary of $82,100.

Thermal engineers have been instrumental in changing the way people find and use energy throughout the world as well as in pushing space exploration into new realms. Most people think of Google as an Internet search engine company, but the firm has expanded its resources into creating better energy solutions for the planet. The firm actively recruits thermal engineers to work on its project for developing clean and affordable power grids. Their Energy Access team endeavors to recruit and nurture engineers to its efforts, underscoring its conviction in its identity as an engineering firm.

Moreover, the University College London (UCL) Mullard Space Science Laboratory considers the work of its thermal engineers as vital for enhancing space exploration initiatives. One of their professionals, Christine Brockley-Blatt, has exemplified the seamless transition these practitioners make from the classroom to real world applications. After completing her undergraduate degree in Mechanical Engineering and Physics, Brockley-Blatt completed an internship with an aerospace firm, whereby she trained on a project dealing with the landing gear and propeller technology for a medley of aircraft models. She then applied more of her thermal engineering training to an automotive firm. With UCL she currently works as a project manager on cooling technology in outer space exploration solutions. On a daily basis, she employs calculations in mechanical and thermal capacities, performs project management duties, and demonstrates oral and written communications. Her rich educational background and professional experience illuminate the depth and versatility the field requires of its practitioners to excel.

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