Academic Requirements for Structural Engineers

Employers require structural engineers to have a college degree in the discipline or comparable areas such as civil engineering. Most professionals have acquired a Master’s Degree or even a Ph.D. to distinguish themselves in the marketplace. Undergraduate students complete coursework in materials, algorithms, design and mechanics, among other concepts. Advanced academic training in the field facilitates a candidate’s ability to receive management positions in the industry as well as university teaching roles. At the Master’s Degree level, students complete classwork in advanced materials design principles, structural mechanics and seismology. For Ph.D. students, coursework includes classes in computer modeling, advanced renovation and restoration as well as risk analysis.

Organizations such as Structural Engineers Association, the Structural Engineering Institute, and the International Association for Bridge and Structural Engineering (IABSE) are a few of the organizations dedicated to fostering the development of professionals in the field. They organized congresses throughout the world to educate and bring together professionals in the industry to trade knowledge and share opportunities and best practices, thereby expanding the breadth and awareness around the industry. Moreover, they feature digital libraries of materials, including journal publications and links to online resources that enhance the toolbox of practitioners. Affiliated organizations like the

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Software Engineering Education

 

Education

Software Engineering degrees are available at the undergraduate, master’s, and doctorate (PhD) levels. As you move up in a Software Engineering career, increasing your education level will allow you to tackle ever more complex systems. At the pinnacle of Software Engineering are people that design the systems behind well-known technological marvels from the Space Shuttle to Google’s databases.

Prerequisites

Most colleges require similar courses as prerequisites for their Software Engineering programs. You’ll normally be expected to study mathematics up through Calculus, basic computer programming, and cross-discipline engineering basics. You’ll also take courses in computer algorithms and system documentation methods prior to moving on to the core Software Engineering program.

Undergrad

Once your undergraduate prerequisites are met, you start taking classes in Software Engineering. This is where you gain cutting-edge expertise in skills like requirements identification, system design, software integration and software testing methodologies. During this coursework, you’ll learn how modern software systems are designed and implemented.

There are an incredibly complex number of variables when engineering software components, and a Software Engineering degree provides the educational foundation you need to be productive in the field.

There are numerous avenues for studying Software Engineering. Virtually every major university offers this as an undergraduate major, and many larger colleges offer Master’s and PhD programs as well. You can also get a Software Engineering degree through many of the top online colleges.

Since a lot of the software work being done is on the Internet and mobile devices, studying Software Engineering online can be a flexible and effective method for pursuing your education.

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Software Engineering Degrees

Most people are familiar with older, more traditional engineering fields such as mechanical, civil, or electrical. Software Engineering is a relatively new discipline, but in today’s increasingly interconnected world, it is becoming more and more important.

Software Engineering differs from Computer Science or Web Design in that you are formulating how the overall software system functions, and how it works within its intended hardware environment.

Software Engineers are responsible for every phase of a development project, not just for writing the computer code. Upon the initiation of a project, they make sure requirements are documented and validated.

This assures the entire project is working toward the correct goal. They then move on to system design, often overseeing the creation of software prototypes to present to clients for additional validation.

Once the design is solid, Software Engineers manage the overall development effort to make sure the pieces are coming together as planned. Finally, they create and oversee test cases which assure system functionality is complete and traceable to the requirements generated at the time of project initiation.

Software Engineering is the discipline that makes sure computer systems are developed methodically and result in building the right product with quality built in from the beginning.

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Day in the Life of a Petroleum Engineer

Petroleum engineers typically design equipment to extract oil and gas, and develop ways to force oil out of wells through injection of water, chemicals, gases, or steam.

They develop drilling plans, survey, evaluate, and test wells. They use computer-controlled drilling to connect separated deposits to a single well. They ensure proper installation, maintenance, and operation of oil field equipment.

Reservoir engineers optimize production with proper well placement and enhanced recovery techniques. Drilling engineers oversee the technical aspects of drilling exploration, production, and injection wells. Production and subsurface engineers direct connections between reservoirs and wells, overseeing downhole monitoring equipment and flow control, sand control, and perforations.

They select surface equipment to separate fluids (oil, natural gas, and water), and they evaluate artificial lift methods.

Emerging career choices involve pollution cleanup, hydrology, and underground waste disposal (the subsurface injection of carbon dioxide to reduce greenhouse gases). Petroleum engineers are also educated in geothermal energy production, in situ uranium leaching, and coal gasification.

The known worldwide oil and gas reserves are larger than ever. Found in diverse areas, these resources provide opportunities for assignments in the Middle East, Asia, South America, Australia, and beyond.

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Main Focus of a Nuclear Engineering Degree

Nuclear engineering is the most integrated of the engineering disciplines. The many components of nuclear systems (medical imaging, nuclear fission reactors, ultrasensitive contraband detectors, and fusion reactors) must all be understood as well as how they relate to one another. Nuclear engineers must be experts in their primary field, as well as knowledgeable in other fields such as electronics, thermodynamics, physics, and materials science. The fundamentals of one science are often the same tools used in solving problems in the other disciplines.

An undergraduate degree in nuclear science and engineering develops the fundamentals of nuclear processes—their production, interactions, and radiation measurements. These studies bring the student all the way to the design phase of nuclear-based systems, stressing social, health, and energy and security impacts.

Studies also incorporate computer methods, thermal-fluid engineering, and electronics—critical tools for a nuclear engineering career.

The Bachelor of Science degree in Nuclear Science and Engineering prepares students for careers in the application and engineering of low-energy nuclear physics. This includes design, analysis, and operation of radiation systems and their applications, such as fission reactors and accelerators, and biomedical uses. Students are also prepared for graduate study in a wide range of engineering and physical sciences.

A five-year program offers an opportunity to earn a Bachelor of Science and a Master of Science in Nuclear Science and Engineering simultaneously.

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Real Life Nanoengineers Making an Impact

Nanoengineers not only impact the way people live and think on Earth, but also may provide the key to further space exploration. As both the European Space Agency and NASA strive to execute manned missions to other planets like Mars as well as develop more advanced spacesuits and micro-shuttles, nanotechnology will serve an essential role in pushing these endeavors into reality. Nanoengineers will be called upon to reduce the weight and sheer volume of components needed to explore other worlds, thereby reducing the costs associated with such expeditions. This may well enable countries with smaller economies to venture into space. For example, nano engineers at NASA have created sensors rooted in nanotechnology for use on the International Space Station (ISS). The sensor is the size of a postage stamp, yet has the capacity to detect impurities in an astronaut’s air supply, and may well be utilized on potential roving explorations on Mars to gather samples from the red planet. Furthermore, technology companies like Apple have used nanotechnology and professionals to develop their tablet hardware products and musical devices like the iPad mini and iPod nano. The iPod nano, for instance, features a compact, design that clips onto a person’s lapel making it easy for customers to listen to music while being unencumbered by a weighty product. The sleek, minimalist design associated with Apple products illuminates how the field of study bridges the gap between cutting-edge technology and providing useful and lucrative consumer products. As nanotechnology grows with the expertise of its practitioners, its impact will be seen throughout all spheres of human life.

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Molecular Engineering Degree

Molecular engineering entails the creation of molecules and the development of new products from them. Often these molecules do not exist naturally and may not be stable enough to employ beyond a narrow of parameter of uses. It is quite difficult to create these particles, as it requires the manual use of sensitive equipment such as a scanning tunneling microscope. The technology has the capacity to take entire libraries of books and condense their contents into a digital storage device the size of a single cube of sugar. This is an interesting field of engineering, with limitless potential. If you want to learn more about working towards a career in this area, search for schools in your area by using our list below. The work of molecular engineers is present in every industry, including robotics, biotechnology, pharmaceuticals, materials, fashion and entertainment. In addition, the agricultural industry and medical devices field is expected to be transformed by innovations in molecular engineering, thereby forging new markets and employment opportunities for trained professionals.

The field is particularly important for scientific materials research and pharmaceuticals, as it is employed as a sophisticated form of chemical engineering. A potential application of molecular engineering would include a minute device that navigates seamlessly through a human body eradicating cancerous cells thereby precluding them from spreading. Duties of professional in the field may well include using statistics and computer models to predict molecular manipulation outcomes; employ business acumen in marketing applications; demonstrate leadership capabilities in managing a team of engineers and researchers; as well as manage the entire life cycle of product development. 

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