Mining Engineering Education Requirements

Mining Engineering Education Requirements

Requiring a minimum of a bachelor’s degree from an accredited college or university, the licensing requirements for geological and mining engineering vary by state. Specific degree programs for aspiring geological and mine engineers include Geology, Geophysics, Geological Engineering, Mining Engineering, Mineral Preparation Engineering and Social Geology, among many others, and range from undergraduate Bachelors programs to advanced graduate and post-graduate programs. In addition to materials mining and extraction, additional studies and industry focuses include ecological impact research, which measures broader environmental and ecological effects of mining operations, social geological impact research which focuses on both the sociological hazards and benefits to geological or mining efforts and discovery oriented exploration, studying geological formations below the Earth’s surface so as to refine the broader understanding of the planet’s composition. Regulated by the Mine Safety and Health Administration the field of geological and mine engineering is one with an intense focus on hazard awareness and occupational safety.

As with any dynamic and engaging field of study, the geological, mineral and mining industries and sciences, the training and education continues well after one has earned their degree. With numerous trade associations, professional networks and academic research societies, such as the American Institute of Professional Geology American Rock Mechanics Association and Association of Environmental and Engineering Geologists the field of geological and mine engineering is one of a continually evolving nature, with regular conferences and training programs designed to keep geological professionals on the cutting edge of their chosen pursuits. Combining age old techniques in respect to surveying, exploration and extraction, new technologies continue to emerge in the field, bringing new and exciting methods of research and exploratory prospecting into the hands of professionals and students every year. And as these new technologies and discoveries continue to change the professional landscape for those entering the engineering fields of geology or mining, the increasing demands for raw and precious materials by industry and the public at large have led to an increased demand for well educated, qualified professionals to enter the fields.

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Bachelor of Science Degree in Aerospace Engineering

Bachelor of Science Degree in Aerospace Engineering

There are only a handful of universities accredited by the Accreditation Board for Engineering and Technology in the United States that offer aerospace engineering degrees. Aerospace engineers take two years of calculus, differential equations, physics and chemistry and two years of engineering coursework. Aerospace engineering students can expect to see the following engineering courses in their university's curriculum:

• Statics
• Dynamics of aerospace systems
• Control of aerospace systems
• Aerodynamics
• Thermodynamics
• Flight software systems
• Aerospace instrumentation and experimentation
• Aerospace structures
• Aircraft flight dynamics
• Space flight dynamics
• Vibration and elasticity
• Aircraft propulsion and power
• Space navigation and guidance
• Space propulsion and power
• Aeronautical systems design
• Space systems design

In terms of career choices, the aerospace field is projected to grow 5% between 2010-2020 according to the Bureau of Labor Statistics (BLS). Aerospace engineering majors can choose variety of career paths, including positions in scientific research, engineering design and development, field service, management, marketing, software development and teaching.

The two main branches of aerospace engineering degrees are aeronautics and astronautics. Some universities have curriculum's that embrace both areas, while others separate the two fields and offer degree programs in either aeronautics or astronautics. Aerospace engineering majors should be prepared to engage in a significant amount of actual design and implementation in addition to coursework.

In addition, students should seriously consider learning Russian, Japanese or German because many people of these nationalities are deeply involved in the development of spacecraft components.

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Career Outlook Advice for Thermal Engineers

Career Outlook Advice for Thermal Engineers

Though most universities in the United States do not offer formal degrees in thermal engineering, most candidates find employment with a Bachelor’s Degree in mechanical engineering. This level of education is required by employers in the industry. In this course of study, students complete coursework in thermodynamics, computer science and kinetics. Those students who elect to pursue more advanced study in the field at the Master’s and Ph.D. level access career opportunities in advanced research, design and quality control. Coursework at the Master’s level explore theory in heat transfer and mechanics rooted in computer modeling and smart materials that respond to temperature change. Doctoral students embark upon classwork in granular flows, electronics architecture, data storage solutions, as well as material innovation, whereby they assume titled roles like consultant analyst, heat engineer and quality assurance manager. These highly trained professionals are actively recruited by federal organizations like the U.S. Department of Energy and the Defense Advanced Research Project Agency in order to teach both graduate and undergraduate students at esteemed universities around the world. Candidates are served by also developing broader skills in terms of written and oral communication, leadership, negotiating, multitasking as well as team-building and management capacities.

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.

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Computer Engineering Education and Career

Computer Engineering Education and Career

Computer Engineering degrees are available at all education levels: undergraduate, master’s and doctorate (PhD). Most undergraduate Computer Engineering programs allow you to specialize along one of several tracks because the entire career field is simply too broad to cover in an undergraduate program.

As you progress in your Computer Engineering career, you’ll be able to study increasingly complex topics in hardware and software systems. Occupying the top tier of Computer Engineering jobs are professionals with vast experience designing the overall system to control things like a passenger airliner, the International Space Station, or a nuclear power plant.

Computer Engineering requires a combination of skills from other engineering disciplines, and most colleges will require the same courses as prerequisites for their degrees. You’ll likely study mathematics up through Calculus, basic software programming, physics and electronic or electrical engineering basics.

Once your prerequisite courses are completed, you start the heart of the curriculum in Computer Engineering. In your upper level courses, you’ll learn how computer-controlled systems are designed from the bottom up. Microprocessor design, firmware creation and circuit boards are just a few of the topics you’ll study. The creation of a single computer is just the beginning. Advanced courses in Computer Engineering teach the techniques for integrating large numbers of computers into complex networks capable of solving massive computational problems.

There are many delivery methods for studying Computer Engineering. There are over 150 universities that offer an undergraduate program, and most top-tier state and private colleges offer Master’s and PhD programs also. You might also pursue a Computer Engineering degree with any of the reputable online colleges.

An undergraduate Computer Engineering degree typically takes four to five years to complete. A Computer Engineering Master’s Degree will normally be completed in two years on a full-time basis, and a doctorate can easily take three years to complete.

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Acoustical Engineering Education and Career Outlook

Acoustical Engineering Education and Career Outlook

Many U.S. universities offer official degrees in acoustic studies, so most professionals complete a Bachelor’s Degree in electrical engineering or a comparable course of study. Most employers do require at least a Bachelor’s as a minimum qualification for entry into the workforce. Many students integrate related acoustic theory courses into their degrees by taking classes in statics, circuits, thermodynamics, sound control, and vibrations, among others. A Master’s Degree may be required to qualify for some positions with a given company. At this level, students complete classes in wave propagation, optics and nonlinear acoustics. The Ph.D. level opens further management opportunities in the field, whereby students will have completed a rigorous academic training rooted in statistical analysis. This level of training opens the door to teaching at universities as well. With an eye to business, students should seek to refine their interpersonal and communication skills as well as their leadership capacities in managing a team of engineers and professionals. They may be asked to negotiate and consult with outside suppliers in managing the lifecycle of a development project.

The Technology Student Association (TSA), and the National Society of Professional Engineers (NSPE), provide members and interested parties with comparable tools and information to enhance their value in the contemporary marketplace. All of these institutions publish recent research and logistics regarding industry events and resources to the further refine the prowess of practitioners.

Students and job seekers particularly benefit from involvement with these groups, as the institutions provide invaluable networking and mentoring opportunities for individuals to develop relationships with potential employers and their contemporaries in the field. Esteemed firms such as Boeing, Procter & Gamble, and Universal Studios have sought candidates through these avenues. According to the U.S. Bureau of Labor Statistics (BLS), the job growth projections for acoustical engineers remains strong through 2020, where hiring is projected to grow by 10 percent. The states of California, Texas and Michigan possess the greatest opportunities for professionals. While exact statistics on the median salary of these professionals is unavailable, O*Net reports that electrical engineers of the same background command a yearly salary of $89,180.

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