Jobs With Biomedical Engineering Degree

 

Biomedical engineers design prosthetic limbs, artificial organs, and regenerate tissue. They create drugs and pharmaceuticals, collect and analyze biological data, and design life-saving equipment. They work with universities, hospitals, labs, government, industry, and regulatory agencies.

They work with doctors and patients seeking solutions to physical as well as physiological problems. It is important to incorporate into their own specialties any changes in related fields, so engineers scramble to stay abreast as technology rapidly evolves.

Universities teaching advanced levels of biomedical engineering commonly offer post-doctorate and research career opportunities. For example here is a list of research opportunities available through Florida A&M University:

• Tissue Engineering for Bone and Cartilage Replacement
• Advanced Polymeric Materials Characterization and Rheology
• Magnetic Resonance Imaging of Cells, Tissues, and Organisms
• Plasma Reaction Engineering for Pollution Control and Disinfection
• Biomass Conversion to Energy by Enzymatic/Catalytic/Thermal/Plasma Methods
• Advanced Computational Methods in Materials, Catalysis, and Transport
• Solid State Materials Synthesis and Characterization

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Audio Engineering Degree

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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Real Life of an Applied Engineer

 

Real Life of an Applied Engineer

As a project engineer for Applied Engineering, Mike Jamieson daily exhibits the range of skills a practitioner in the field must master to excel. He interfaces with internal and external team members and associates in-person and over e-mail every morning. He then focusses on business activities such as speaking with various suppliers on product inventory, consulting with clients on budget requirements and researching options on the internet. In the afternoon, he often leaves the office to visit clients and ongoing projects. He enjoys the opportunity to get out of the office and into the field to interact live with people. For example, on one project he consulted with one of the managers on an HVAC system for a residential structure, specifically the ductwork and air flow systems. Later in the afternoon, he returns to the office to revisit projects he initially tacked in the morning. He may attend more meetings to deliver presentations on status or negotiate with suppliers to acquire the best pricing for a client project. Demonstrating his commitment to continuous education, Jamieson in the evenings attends functions featuring industry thought leaders who make presentations on recent development in technology and best practices. In the past he attended a dinner featuring a presentation by a professor at Purdue University who presented a talk on refrigeration concepts and developing compressor innovations. Ultimately, each day presents him with a range of challenges and learning experiences that enrich him.

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Main Focus of an Agricultural Engineer

 Agricultural engineering degrees prepare students to work professionally in many fields of agriculture. Subsets of the studies belonging to the classification of agriculture offer unlimited opportunities for involvement in this field. Demand for Agricultural Engineers has grown over the last 10 years.

Degrees in agricultural engineering cover all aspects of the industry, from water and waste issues, massive farming of foods and livestock, water farming, farming equipment, and farm economics to genetically designed corn and cows.

Earning a degree gives students textbook knowledge and hands-on vision of their chosen field. Fieldwork and laboratory projects combined with actual practice provide a well-rounded education.

The bachelor of science is the first degree to obtain. While majoring in agricultural engineering, a student can minor is any other field. Often students will minor in a related subject such as economics, to enhance their food engineering major, for example.

Graduate students are eligible to pursue a number of advanced degrees, including the Master of Science, Master of Engineering, Master of Agriculture, Doctor of Philosophy and Doctor of Engineering. These students can major in bioacoustics, biomaterials science, bioprocess engineering, environmental and natural resource engineering, food engineering; food, feed and fiber processing; machine and energy systems; and systems analysis.

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Master of Science Degree 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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Thermal Engineering Career

Professionals in the field of thermal engineering strive to develop more efficient means for transferring energy into more practical means, drawing on their expertise in heat transfer. Within an industrial context, these engineers work on solutions for fuels, exploring forms of chemical, electrical and mechanical energy. These professionals find specialization in the fields of high technology, solar power, oil and gas, power companies, as well as temperature control systems. Transforming power grids to create more affordable electricity has become one of the most popular fields utilizing the expertise of thermal engineers.

If you want to know more about becoming a thermal engineer, contact the schools listed here to learn more. It’s important to talk to as many schools as you can to determine the best way forward.

Thermal engineers dedicate their efforts to refining electronics systems and safety applications. They collaborate extensively with groups of hardware and software experts at all stages of the product cycle from initial design through the manufacturing and installation of products and systems. In this capacity, they may develop models for industrial assets rooted in computer projects for optimizing source materials and functionality.

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Real Life Example of a Structural Engineer

 

Real Life Example of a Structural Engineer

John Shmerykowsky , an experienced structural engineer, has witnessed first-hand the rewards of the career as well as the technological transformations that are reshaping the industry. As a principal of his own firm, he spearheaded the work completed at the Phillip Morris building in New York City at 120 Park Avenue. He works primarily as a consultant to architects, while he completed his education at Fountainbleu in Paris. Shmerykowsky has developed his reputation by completing projects that feature unique challenges. For example, the Phillip Morris project possessed a structure that was one quarter positioned over functioning subway tracks that were employed to transport garbage. His team had to develop an approach that would enable them to complete work on the building, while enabling the tracks to run without interruption. He also developed sustainable features in the building including windows conducive to harnessing natural light. Over time, he has seen how vital digital applications have become to the industry, whereby he encourages all aspiring professionals to become comfortable with the technology as well as current ones to reman vigilant in keeping current on computer-based trends. His firm Shmerykowsky Consulting Engineers currently seeks structural engineers to add to their team to help realize current projects for their portfolio of clients. Like the company’s founder, the firm seeks engineering professionals that possess a diverse range of technical, business, interpersonal and communication skills that are tantamount to executing current and future structures throughout the world.

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Software Engineering Education

 

Software Engineering 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.

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.

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Prerequisites for a B.S. in Petroleum Engineering

 

Prerequisites for a B.S. in Petroleum Engineering

This curriculum combines college-level mathematics with basic sciences, developing a working knowledge of thermodynamics, material properties, fluid mechanics, material strengths, transport situations, and phase behavior (what to expect from resources when working with them).

Students develop competence in well design and analysis, drilling procedures, and evaluation of subsurface geology. They design and analyze systems that produce, inject, and handle fluids, optimizing resource development and management, using reservoir engineering principles and practices. They are proficient with project economics and resource valuation practices for decision-making under risky and uncertain conditions.

Since the beginning of petroleum engineering, in the early 20th century, many easily accessed deposits have been depleted. Fuel harvesting has become more dependent on fresh technologies incorporating horizontal drilling and computer modeling.

Drilling in deserts and in deep waters requires today's engineers to have expertise in intelligent systems, geomechanics, and hydraulics, naming only a few things on their growing list of knowledge bases.

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Nuclear Engineering Degree Education

Nuclear Engineering Degree  Education 

Each discipline of nuclear engineering has a specially focused degree program. The main fields of study are applied plasma physics, nuclear science and technology, or fission nuclear technology.

Bachelors-degree students have heavy course loads in science, chemistry, physics, calculus, biology, technology, the humanities and communication. Their studies also include nuclear engineering basics, the fundamentals of nuclear energy and engineering, nuclear reactor systems, radiation safety, fuel cycles, nuclear materials and electromagnetism.

A number of colleges and universities offer online nuclear engineering studies toward master's and doctoral degrees. Some of these universities include, but are not limited to, Penn State, MIT, and Ohio State.

Online nuclear engineering degrees open a wide range of opportunities for students, at both graduate and postgraduate levels. A graduate degree in nuclear engineering opens doors to better job opportunities.

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Discover the World of Nanoengineering

 

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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Real Example of Molecular Engineering

 

Real Example of Molecular Engineering

As it is an emerging field with seemingly unlimited potential, the field of molecular engineering has stirred some controversy regarding its implications ethically, environmentally and socially. At the same time, the science promises to exert its influence in all spheres of human life around the world. In the medical devices industry, a recent case study of Ortho Molecular illuminated the powerful potential of this form of engineering. The firm employs a ProScan metal detection system, rooted in molecular engineering, which was developed by Advanced Detection Systems (ADS). This ensures the quality of all of the products in its manufacturing system. The device memorizes the product sensory impulse, and then recalls it as it travels through the scanner, thereby ensuring the finished product meets all Food and Drug Administration health and safety codes. The ProScan application evaluates the entire device to identify the presence of any metal. If it is detected, a signal occurs compelling a check of the entire batch of deliverables. The system enables quality control staff to quickly identify integrity breaches and remedy them seamlessly. Molecular engineering was critical in developing this acute detection system application. Ortho Molecular purchased several of the ADS systems for its medical device product manufacturing processes because of its sensitivity and efficiency.

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Mining and Geological Engineering

Mining and geological engineering focuses primarily on the study and design of creating safe and effective means to extract metals and minerals for industrial, commercial and scientific purposes. Requiring education and understanding not only of mining principles and practices, engineers in this field are also expected to have an advanced and dynamic understanding of geological sciences, such as soil and mineral composition, surveying, prospecting and exploratory geological research. In addition to extracting the more conventional materials such as oil, precious and industrial metals and rarer gems and materials, many new advancements in information technology have expanded the role of geological engineering to search and mine for other materials, such as the dozens of special minerals and materials used in computer, tablet and smart phone construction.

At EducatingEngineers, we want you to understand the complexities of engineering careers and what it takes to succeed in your education. Please read the information below to learn more. And contact the schools in our directory to get started!

Employed by governments, major corporations, non-profit organizations and scientific/academic research institutions, geological engineers play pivotal roles in everything from industrial production of materials and energy, to advancing scientific understanding of the material composition of the Earth. Because of the numerous and varied functions for geological engineering and the substantial technological advancements made in the field itself, the role of the engineer in respect to mining and geological research continues to evolve, finding new and interesting applications for the science with each passing year.

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Careers for Mechatronic Engineers

 

Careers for Mechatronic Engineers

Companies like Harris & Bruno have formed partnerships with schools like Sierra College in California to seamlessly integrate students from the classroom to applying their knowledge to real world mechatronics applications. Markus Fredrickson, a Sierra College student, works part-time in manufacturing at Harris & Bruno. When he first began his education, he did not have a clear direction for his career. However, the collaborative approach of his university and the private enterprise has provided him with direction and the practical outlet for his skills. He described his work with the firm as a seamless experience bridging his classroom education with real world scenarios. Many of the parts and systems he encountered in his classroom work echoed the very same components and problems he was asked to solve on the job. Ultimately, he found his theoretical and practical education as invaluable in facilitating his career advancement. These types of programs reflect the potential for students and companies as they integrate their resources and expertise in growing the industry. This boasts well for both current and prospective professionals in the field and the industry as a whole as more evolutions occur in terms of technology and human resources.
If you would like to learn more about mechatronics or other areas of engineering, contact the schools in our directory to receive more helpful information. We recommend contacting multiple schools to be sure you choose the best one for you!

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Mechanical Engineering Degree

Mechanical engineering is the broadest of the engineering disciplines. This field focuses on two major topics: thermal systems and mechanical systems.

As a result, the mechanical engineering curriculum overlaps many other engineering fields, including aerospace, biomedical, chemical, civil, electrical, industrial, materials and metallurgical and petroleum.

Any prospective engineering student should have a strong high school background in elementary, intermediate and advanced algebra, trigonometry, geometry, pre-calculus, chemistry and physics.

Additionally, the pre-engineering student should have solid reading comprehension skills and the ability to write logically, clearly, concisely and with correct grammar.

All mechanical engineering programs require multiple semesters or quarters of these subjects. These subjects lay the foundation to the understanding of the core curriculum. The mechanical engineering student cannot master the core mechanical engineering concepts without mastering the fundamentals.

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Materials Science and Engineering Real Life Stories

 

Materials Science and Engineering Real Life Stories 

Beyond these statistical realities and potential however, many within the fields of Materials Science and Engineering express substantial personal and professional satisfaction with their work and career. Bringing together the applicable skills of dynamic critical thinking and problems solving with those of analytical research and scientific endeavor, the challenges posed to the working professional often result in an enhanced satisfaction with successful end results in respect to projects and ventures undertaken. In seeing the final real world applications to their research, development and testing of new and existing materials, Material Engineers often find themselves on the cutting edge of scientific discovery and advancement.

Taking for example, the case of NASA engineer Clara Wright, the pliable skills learned while studying Material Science and Engineering have given Ms. Wright substantial personal fulfillment, in addition to her remarkable career. Being possessed since her youth with an interest in puzzles and problem solving, Wright gravitated naturally towards the field of material science and engineering. Upon completing her degree, Wright first entered the field of bio-medical research, assisting with the design and development of prosthetic limbs for amputees. Later, Wright took a position at NASA working as a materials engineer, studying materials in use by the space program. In July of 2014, Wright was profiled for NASA’s website, in an effort to highlight both her contributions to the space program, while also the interest and dedication to Material Science and Engineering which brought her to work there.

"I'm very passionate about being a materials engineer," Wright said. "It’s a very fulfilling career particularly at Kennedy because every investigation is unique. It is greatly gratifying to say that I am one of a handful of people in the world who get to work on hardware that is going to the International Space Station, has been in the vacuum of space or is part of the launch structures."

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Industrial Engineering Courses and Curriculum

 

Industrial Engineering Courses and Curriculum

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.

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Environmental Engineering Education

 

 Environmental Engineering Education

First and Second years

• Students take courses in English composition, mathematics, biology, physics, chemistry, and introductory engineering.

Third year

• Introduces advanced engineering courses, including solid and fluid mechanics, thermodynamics, and laboratories in engineering materials, hydraulic engineering, and environmental monitoring and process engineering.

Fourth-year

• Primarily these studies are based on students' electives and if they are laying the foundation for a graduate level degree.

Graduate Level

Students specializing in environmental engineering can pursue four graduate degrees. The master of engineering (M.Eng.) degree is for those who seek careers that do not include research. The master of science (M.S.) degree requires students to conduct a thesis research project and expand their knowledge.

The doctor of philosophy (Ph.D.) degree is awarded for expertise in research, and the doctor of engineering (D.Eng.) degree is designed to combine technical expertise with management skills.

There are online schools for B.S. degrees in engineering, but they are not reviewed here. The many laboratory components of engineering studies may not be available online; careful attention should be given to selecting an institution.

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