Alpha Beta: September 2020

Wednesday, September 30, 2020

Materials Science and Engineering Degree

Few studies are as vital to the advancement of industry as Materials Science and Engineering. Focused on the study, discovery and creation of new physical materials for use in everything from medicine, automotive and aerospace engineering and consumer goods, to rocketry and space exploration, careers in Materials Science and Engineering maintain a heavy focus on attention to detail, critical thinking and problem solving skills. As an “interdisciplinary science,” Materials Science and Engineering combines a variety of specific skills and studies, varying upon the professional or scientific objectives of the student. With strong emphasis in areas such as mathematics, thermodynamics, chemistry, bio-chemistry and materials properties (mechanical, transitional, chemical,) Materials Science and Engineering is a study which focuses on the physical materials used in given applications, for the purposes of research, safety, quality control and in certain professional areas, forensic engineering and investigation.

If you are ready to learn more about this area of engineering, contact the schools in our directory to learn more about their degree programs. We work with these schools directly and do not charge for our services. We simply want to help students like you understand your options!

Classically referred to as “metallurgy” in many schools and training programs, Materials Science and Engineering is generally regarded as a relatively new field of study, combining older metallurgic arts and understanding with newer studies of things such as atomic structure, applied physics and the creation and study of newer synthetic materials. Professional opportunities in the field cover a broad spectrum of industrial and scientific sectors, ranging from basic scientific research and discovery to applicable industry specific occupations in fields such as bio-technology, defense and consumer product engineering.

Tuesday, September 29, 2020

Types of Jobs With Marine Engineering degree

Marine engineering graduates have a number of career options. They may choose to work as naval combat or propulsion engineers or marine equipment specialists. Becoming a marine systems, marine structural, or ship’s engineer is also a possibility. Others may find the job duties of a marine equipment specialist or hydrographic surveyor more to their liking.

Many companies hiring freshly graduated marine engineers provide hands-on training using new employees’ academic knowledge as a foundation. In general, undergraduate students are expected to take advantage of marine engineering-related work-study jobs and internships to improve their likelihood of being hired post-graduation.

Individuals with a masters or PhD in Marine Engineering usually aim for jobs in government or academia. Working for private design, engineering and architectural firms is also a popular choice. Potential jobs for those holding advanced Marine Engineering degrees include:

Engineering Professor
Submarine Engineer
Shipyard Project Engineer
Marine Operations Manager

Monday, September 28, 2020

Industrial Engineering Career Outlook

Industrial engineering is actually a far-ranging profession that focuses on optimizing complex processes or systems by reducing wastefulness in production. It focuses on systems of people, money, knowledge, information, equipment, energy, and materials and may address mathematical, physical and social science concerns. It brings to bear the principles and techniques of engineering design on many facets of life and seeks to specify, predict, and evaluate the results derived from these systems or processes.

Industrial engineering is one of the oldest branches of engineering taught in engineering schools, and generally requires that practitioners hold a professional engineering license in order to practice. If you want to learn more about this field, and how to pursue a career in this direction, contact the schools in our directory to receive detailed information you can use to make a decision.

The entry-level qualification needed to work as an industrial engineer is typically a bachelor’s degree in industrial engineering. It is not uncommon, however, for practicing industrial engineers to have degrees in related fields such as mechanical engineering, manufacturing engineering, industrial engineering technology, or general engineering. Many universities that offer degrees in the field offer advanced degrees: master’s and doctoral level program, as well. US News and World Report ranks industrial engineering programs in the United States. In 2012, the top ranked US program was at the Georgia Institute of Technology. As of 2012, it had held this ranking for twenty-two consecutive years. The program at the University of Michigan, Ann Arbor, and University of California, Berkeley, have been ranked second and third in the United States for many years.

Friday, September 25, 2020

Types of Jobs and Salaries for Electrical Engineers

Electrical engineers find work in the laboratories of fabrication plants, in corporate consulting offices, or onsite at mines. They may supervise scientists, electricians, computer programmers, or other engineers.

They are involved in:

Power generation
Radio
Television
Transmission and distribution (high-voltage transformers)
Electronic circuits
Controls (electrical circuits, digital signal processors, microcontrollers)
Nanoelectronics (microelectronic components)
Computers
Satellite dishes
Cell phones
HVAC systems
Flight control panels
GPS technology
Electric power generation
Space travel technologies

In effect, there is no mechanized field today in which these engineers do not play an integral part. Electrical Engineering jobs are projected to grow 6% between 2010-2020.

Electrical engineering has been at the forefront of every technological gain of the past century. This growth is perhaps most evident in the development of today's increasingly smaller transistors, as the number of components placed with an integrated circuit doubles continuously.

Enabling all other technologies and far outpacing them in development speed, electrical engineering has increasing demand and positive career possibilities for qualified professionals.

How Much Do Electrical Engineers Earn?

Electrical engineers earn $87,180 yearly on average, according to U.S Bureau of Labor Statistics (BLS). A basic market pricing report was composed using data from a Salary.com survey of employers through all industries. This report showed $61,740 as a typical entry-level salary for an electrical engineer in the U.S. Another report issued by Florida State University showed electrical engineers as ranking fifth nationally in 2010-2011 with salaries beginning at $60,800 and reaching $104,000

Thursday, September 24, 2020

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.

Wednesday, September 23, 2020

Jobs & Earnings with Audio Engineering Degree

There is a variety of jobs that audio engineers hold in an equally wide variety of locations. Audio engineers are used in studio settings for the radio, television, movie, and music industries as sound engineers, boom operators, sound designers, sound editors, sound effects editors, and much more. In addition to studio work, there are also options for similar positions in live venues, like sports arenas, theatres, and concert tours.

Based on data collected by the United States Bureau of Labor Statistics (BLS) in May 2012, the mean annual salary for someone in the audio engineering field is just over $55,000. The BLS classifies audio engineers as sound engineering technicians, which includes anyone involved with the operation of equipment used to record, alter, and reproduce sounds in any of a variety of venues where recorded or live sound is used.

Yes, The Audio Engineering Society (AES), the Society of Broadcast Engineers (SBE), and The Society of Professional Audio Recording Services (SPARS) are all organizations dedicated to the audio engineering industry. All three are open to audio engineering professionals and students and all three are dedicated to sharing knowledge and techniques in the industry. They are instrumental in implementing new technology with their members as it is introduced into the business.

Tuesday, September 22, 2020

Agricultural Engineering Career Outlook

Agricultural engineering degrees prepare students to work professionally in the 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.

Monday, September 21, 2020

Applied Engineer Career Outlook and Salary information

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.

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.

Friday, September 18, 2020

Aerospace Engineering Degrees

Aerospace engineers research, analyze, design, synthesize, develop and test aircraft, spacecraft and weapons. Aerospace engineers who focus on aircraft are called aeronautical engineers; those who concentrate on spacecraft are called astronautical engineers. They are essentially concerned with the aerodynamic properties of flight vehicles, such as airfoil, control surfaces, lift and drag.

Aerospace engineers can specialize in areas such as structural design, propulsion, navigation, guidance and control systems, communications, or defense systems. They may also specialize in a particular type of equipment, including commercial and military planes and jets, helicopters, space shuttles, satellites, space vehicles, missiles or combat aerial vehicles.

Aerospace engineers can develop special expertise in aerodynamics, thermodynamics, celestial mechanics, propulsion, acoustics, avionics, or guidance and control systems.

Prospective engineering students should take as many classes as possible in algebra, geometry, trigonometry, and pre-calculus, physics, and chemistry because these subjects are critical to understanding the core concepts of aerospace engineering. Because engineers also need effective and written communication skills, students should not overlook language arts classes, such as writing and speech.

Young aerospace engineering graduates have said that they took many Advanced Placement or college classes as in high school to prepare for university engineering coursework.

Thursday, September 17, 2020

Acoustic Engineering Success Story

The Bose company is a prime example of a firm that relies heavily on the expertise of sound engineers. Founded by Amar G. Bose, an engineer himself, who studied at the Massachusetts Institute of Technology (MIT), the firm built its reputation on developing and marketing audio equipment and systems of impeccable quality. The company’s products are popular among consumers, automobile manufactures and performing arts venues. The equipment developed by their sound engineers strives to simulate the quality experienced at a live concert hall. Bose has chosen to engage in long-term, higher-risk projects requiring immense research and development instead of providing cheaper products to its customers. This approach has paid off with the creation of noise-canceling audio equipment such as headphones as well as ingenious suspension systems for the automobile industry.

As a teacher at MIT for nearly 50 years, Bose instructed a course on acoustics that transcended mere technical matters into larger life lessons. Bose stressed to his students the importance of personal responsibility and having high standards for work and integrity. Many students attributed to Dr. Bose their resolve to take on more risky endeavors as well as the technical and critical-thinking skills to achieve success in their careers. The life of Bose and the success of his company serves as a model for all practitioners in the field, underscoring the importance of developing a well-rounded education and approach to successfully tackling both technical and more abstract challenges that they may encounter both in their personal and professional arenas. If you are ready to learn more about earning a degree that can help you become an acoustic engineer, contact the schools in our directory to learn more today!

Wednesday, September 16, 2020

Structural Engineering Degree

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 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.

If you want to pursue a career in structural engineering, use the list of schools below to learn more about programs that can help you get started!

Tuesday, September 15, 2020

Software Engineer Career Advancement & 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

Friday, September 11, 2020

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.

Thursday, September 10, 2020

Nuclear Engineering Degree Online Study

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.

The Bachelor of Science degree in Nuclear Science and Engineering is a basic four-year course, but a specialized five-year course can incorporate a master's degree. The Ph.D. degree generally adds two years of study beyond the master's.

Because nuclear science and engineering has such a broad range, graduates can be prepared for a wide variety of careers. Today's graduates enjoy research and teaching jobs at universities; they work at power plants and in government and industrial laboratories. They have launched LED lighting companies. They manage hedge funds, create interactive science and art displays, design new reactors, improve aircraft components, attend medical school, and design domestic energy policies.

Wednesday, September 9, 2020

Mechatronic Engineering Career

Mechatronics engineering revolves around the design, construction and operation of intelligent products and systems, stemming from the integration of hardware and software applications. The Japanese engineer Tetsuro Mori developed the name for the field in 1969, while working as an executive engineer at the firm Yaskawa. The field is still evolving and sometimes is still referred to as Asset Management in the industry. Professionals in this arena develop approaches to industrial problems employing mechanical and electronic solutions and computer applications. They develop products through the integration of diverse technologies for streamlining processes and applications in endeavors like underwater exploration. These engineers create and evaluate factory production lines blending manufacturing and technologies to enhance efficiency. In addition, they preserve and augment manufacturing designs and processes in applications such as robot floor cleaners.
If you are looking for information about Mechatronics and want to speak with colleges and universities about earning your engineering degree, we can help. We work with schools across the nation to inform students of their options for education. Use our directory of schools to request more information today about their programs.

Mechatronic engineers traditionally work in a laboratory, processing plant or engineering office setting, especially among product developers, manufacturing firms, mining or forestry industries, aerospace and defense, government and industry research groups, as well as electrical power facilities. In addition, the skill set is highly desired by prominent global enterprises in the automotive, aerospace and consumer products sectors and in innovative technology firms that manufacture and supply software components and equipment. Often graduates will establish their own firms or capitalize on research opportunities in the fields of bioengineering or nanotechnology. The demand for mechatronic specialists will continue to grow as more institutions seek to integrate technological innovations in the computer, electronic and sensor areas to enhance product processes and services. Institutions across the globe that have capitalized on mechatronics technology include Bosch, Royal Dutch Shell, FOX Racing, and Keurig Green Mountain.

Tuesday, September 8, 2020

Mining and Geological Engineering Salary and Career Outlook

According to the US Bureau of Labor Statistics “employment of mining and geological engineers is projected to grow 12 percent from 2012 to 2022,” which according to their data puts it on par with most other occupations in terms of projected growth. With the average salary for mine and geological engineering professionals being reported at $86,870 annually (or $41.76 hourly) as of 2013, the range between the lowest and highest paid percentages of the industrial professionals was between approximately $49,000 and $140,000 depending upon industrial focus, employer, position and experience.

A recent 2013 BLS study found that in regards to median salary, differences in respect to specific location also existed. In the metropolitan area of Huston Texas, the annual mean average for geological and mining engineers, including health and safety professionals, was $147,880, with the same occupations earning between $118,450 and $121,350 in the Bakersfield and Oakland California markets, respectively. These salaries, when compared to the $84,140 mean of the St. Louis metropolitan market and the $69,970 measured in the Colorado Springs market, show that sometimes drastic disparities exist in respect to salary, dependent upon location and industrial focus.

The working and academic lives of a mining and geological engineer is one of constant problem solving, exploration, attention to detail and communication. As one of, if not the primary coordinator for digging and mining operations, the engineer is charged with the planning, logistics, safety assurance and contingency/emergency management of their projects. In addition to the technical engineering skills required for the surveying, planning, digging and extraction or study of materials, the project engineers are quite often also required to maintain strong lines of communication with the crews of professional miners or students they are working with. As such, and especially in respect to safety or emergency management, the numbers of women entering the fields has been steadily increasing.

Monday, September 7, 2020

Materials Science and Engineering Degree

Friday, September 4, 2020

Industrial Engineering 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).

Similar 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 another 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.

Thursday, September 3, 2020

Computer Engineering Career Outlook

Wednesday, September 2, 2020

The Main Focus of a Civil Engineer

"Civil engineering is the oldest and most diverse branch of engineering. In its broadest sense, the civil engineer adapts the physical features of the earth to the needs of society. According to the University of Florida, approximately one out of four engineers is engaged in civil engineering."

Civil engineers design, construct, maintain, and operate infrastructures, while simultaneously safeguarding public and environmental health and upgrading neglected structures and systems. Civil engineering reaches from the natural environment to the constructed environment, focusing on interactions between the two, with an emphasis on sustainability.

Combining atmospheric and energy sciences, civil-engineers study climate, air pollution, and weather, addressing problems which might be solved through renewable energy systems. They examine the availability of renewable resources (wind, hydropower and solar), and best practices for their combinations. These kinds of research brought about the first data based wind map and examine the effects of alternative fuels on air pollution.