Nuclear Engineering Degrees

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.

Beyond those studies, students can pursue a Ph.D. and work in research or as university professors.

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Applied Engineering Career Outlook and Salary

A Bachelor’s Degree is required by employers to receive a job offer from a firm to work as an applied engineer. This course of study explores the application of principles regarding the design, and creation of products and systems within a manufacturing context. Programs delve into issues as quality control, project management, systems integration and manufacturing processes as well as strive to refine critical-thinking and problem-solving capacities. Students take classes in the basics of production planning, materials science and personnel safety. To assume management positions with some firms, advanced degrees such as a Master’s or Ph.D. may be required. Holders of advanced degrees also have the credentials to teach at the university level. From a business perspective, those seeking executive roles should work to develop their acumen in budget management and negotiation, as they will be asked to broker deals with suppliers and other assets. Superb oral and written communication skills as well as leadership abilities are highly coveted.

The Association of Technology, Management, and Applied Engineering has developed congresses and resources to enhance the visibility of the field and equip practitioners with the latest knowledge and best practices in the industry. Like this organization, the Technology Student Association (TSA) and the National Society of Professional Engineers (NSPE) offer resources and materials to candidates in the field, including a library of publications, news and technological innovations. These associations work to provide rich mentoring and networking opportunities for members and aspiring candidates to enter and/or advance in the field. At the university level, students capitalize on alumni networks and on-campus recruiting efforts made by leading firms to fulfill their talent needs. Companies such as IBM, Ingersoll Rand, General Mills and CoreComm are a sampling of the firms who have acquired new personnel through these avenues. The U.S. Bureau of Labor Statistics (BLS) projects a gradual decline in the employment prospects for these types of professionals, as manufacturing activities fall within the United States. O*Net reports that these professionals earn a yearly salary of $60,560.

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Vehicle Engineering Profession

Vehicle Engineering

Vehicle engineers dedicate themselves to the design, creation and functionality of vehicles and their components, including automobiles, trucks, buses, and motorcycles. Traditionally, they work in the entire product life cycle from the initial design through production, distribution and marketing, though often specialize in design, research and development or manufacturing. Take some time to request information from schools in our directory that can help you become a vehicle engineer. We recommend contacting multiple schools to be sure you start out on the right track!

Vehicle engineers are professionals who integrate engineering and business acumen to ensure vehicles are developed within cost requirements. Engineers in this field utilize a bevy of scientific principles including thermodynamic and mechanical inquiry to enhance operation and developing solutions for design flaws. Upon realizing a specialty, a vehicle engineer may be asked to execute a bevy of duties and responsibilities. Some undertake the design and creation of visual models for various vehicles and their accompanying parts and features with the assistance of digital applications, enabling them to determine the best source materials to employ.

A medley of companies compete for the expertise and skills of these scientific professionals. Producers of automobiles and commercial vehicles as well as component manufacturers employ these types of engineers to work on luxury, sport and utility vehicles and their supporting parts. In addition to the auto industry, design firms, industrial equipment manufacturers, energy firms, and competitive racing teams endeavor to secure the services of vehicle engineers. With these types of firms, these professionals dedicate their efforts to constructing prototypes and models of parts, the application of evaluation processes, computer software, and physical integrity measurements. Along these lines, professionals may endeavor in developing equipment and parts that meet evolving market conditions, customer tastes, and government safety and health requirements. In addition, they may refine design specifications, examine the environmental implications of a project, oversee the installation of new or enhanced assets into production facility, and/or investigate realized or potential failures in an engineering system. From a business executive perspective, vehicle engineers may negotiate with suppliers in managing contracts, delivery schedules, and logistics as well as track project budgets. Global companies such as General Motors, Tesla, Chevron, Johnson Controls, and Toyota serve as a sample of the firms in the market for these types of employees.

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Industrial Engineering Courses

Industrial Engineering Courses 

The typical undergraduate degree needed to become an Industrial Engineer is the Bachelor of Science (BS) or Bachelor of Science and Engineering (BSE) in Industrial Engineering (IE). Some Industrial Engineers hold degrees in Industrial & Operations Engineering (IOE), or Industrial & Systems Engineering (ISE).

Similarly to other undergraduate engineering programs, the typical curriculum is built on a foundation of broad math and science courses. Examples include courses in chemistry, physics, mechanics, materials science, computer science, electronics/circuits, and engineering design. In addition several engineering mathematics courses, such as calculus, differential equations, and statistics, are required. These courses are required by virtually all accredited undergraduate engineering programs and prepare students for most engineering licensure exams.

Following the foundational courses, students take courses specific to IE. These specialized courses are in areas such as systems theory, design or analysis, ergonomics/safety, stochastics, optimization, advanced mathematics, computation or modeling, and/or engineering economics. Other subjects typically studied by IE students include management, finance, strategy and other business-oriented course, and social science courses such as psychology or public policy. Some business schools offer programs that overlap with IE, but the engineering programs tend to be more quantitative as well as more rigorous in the basic sciences and mathematics. Bachelor’s degree programs typically include both classroom and laboratory experiences.

At the postgraduate level, the most commonly-earned degree is the Master of Science (MS) or Master of Science and Engineering (MSE) in IE. Typical coursework at this level tends to be focused on operations research and optimization techniques, engineering economics, supply chain management and logistics, facilities and work-space design, quality engineering, reliability engineering, human factors engineering and ergonomics, robotics, productivity improvement, operations management, time and motion studies, computer aided manufacturing, and others.

A few colleges and universities offer 5-year degree programs in IE that lead to both a bachelor’s and master’s degree at graduation. The advantage of obtaining a graduate degree is that it opens up the possibility of working as a professor at a college or university, or working in research and development. There are also some 5-year or 6-year cooperative education programs that combine classroom study with practica in the work world. These programs enable students to gain real-world experience and finance part of their education Programs in IE are accredited by ABET.

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Software Engineer Career Outlook and Salary

Software Engineer Career Outlook and Salary

The job market for Software Engineers is incredibly broad. There are software components involved in virtually every modern development you can think of. Computers control everything from aircraft to medical imaging devices, and these systems are conceived and executed by Software Engineers.

Since it’s such a big part of our daily lives, most people think immediately of software running on the Internet when they envision a career in this arena. While there are a plethora of rewarding jobs developing software for use on the Internet, it’s a good thing to know that there are also rewarding jobs in areas like computer simulations, artificial intelligence, real-time systems, aerospace, and embedded systems.

Salary

According to an October 18th, 2012 report on GlassDoor.com, Software Engineers at top companies average $92,648 annually. Google topped the compensation charts, paying their Software Engineers an average of $128,336.

The US Government’s Bureau of Labor Statistics reports earnings on multiple software development jobs, none specifically labeled as Software Engineers. However, the average annual earnings reported for several different Software Engineering-related career fields corroborate the salary figures reported by GlassDoor.

There are numerous professional associations where Software Engineers can network and share information. One of the largest and oldest is the Association for Computing Machinery (ACM). The ACM boasts membership of more than 100,000 professionals as of 2011.

Another major association is the Institute of Electrical and Electronics Engineers (IEEE). While IEEE’s title might not sound like it would be fruitful for Software Engineers, the IEEE Computer Society has teamed with the ACM on numerous projects to enhance the professionalism of the Software Engineering field.

Like any degree in engineering, a Software Engineering degree is a demanding course of study. It requires an aptitude for math and science and favors those who love to think logically and methodically. The rewards for pursuing this degree are numerous and tangible: great salary, a growing job market, and a career working with like-minded professionals building the future. Check out the many programs available and see if one is right for you.

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