Computer Engineering Education

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.

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How to Become a Network Architect

How to Become a Network Architect

If you want to become a network architect, you first need to determine if this career path is a good fit for you. If the following description sounds like you, then you’re probably well suited for a career as a network architect:

• Do you enjoy work that involves large amounts of heavy thinking?

• Are you able to develop conceptual, logical, and physical network designs?

• Do you enjoy matching possible business solutions to business problems?

• Do you enjoy working with other information technology professionals?

Those who become network architects are typically individuals with a natural aptitude in mathematics and information technology. They also tend to have skills in designing, building, or operating equipment configuration prototypes, including network hardware, software, servers, or server operation systems.

Those who become network architects are also typically individuals with excellent communication and interpersonal skills. They enjoy the prospect of a career that allows them to leverage their mathematical, IT and problem solving skills to provide with a competitive edge to their employer by creating real-world technical solutions for reducing inefficiency.

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Communication Services

Communication Services

• Email
  Electronic mail is a communication method and something a computer user cannot work without. This is the basis of today’s internet features. Email system has one or more email servers. All its users are provided with unique IDs. When a user sends email to other user, it is actually transferred between users with help of email server.
• Social Networking
  Recent technologies have made technical life social. The computer savvy peoples, can find other known peoples or friends, can connect with them, and can share thoughts, pictures, and videos.
• Internet Chat
  Internet chat provides instant text transfer services between two hosts. Two or more people can communicate with each other using text based Internet Relay Chat services. These days, voice chat and video chat are very common.
• Discussion Boards
  Discussion boards provide a mechanism to connect multiple peoples with same interests.It enables the users to put queries, questions, suggestions etc. which can be seen by all other users. Other may respond as well.
• Remote Access
  This service enables user to access the data residing on the remote computer. This feature is known as Remote desktop. This can be done via some remote device, e.g. mobile phone or home computer.

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Vehicle Engineering Career 

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.

Vehicle Engineering Schools

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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Structural Engineering Career Outlook

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 the 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!

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.

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Mechatronics Engineering Degree Career Outlook

Mechatronics Engineering Degree Career Outlook

Though the US Bureau of Labor Statistics (BLS) does not maintain employment or salary data on mechatronics engineers, it does have statistics for the related industries of mechanical and electrical engineer. According to research at the BLS, demand for these types of professionals should likely experience five percent growth until at least 2022. Moreover, the bureau foresees electrical and electronics engineers to experience four percent growth in their career prospects. In contrast, electrical and electronic engineering technicians will likely see little or no growth over the time period. Based on O*Net salary data, mechatronic engineers earned a median salary of $92,680. In a state comparison for earning potential, the BLS found that mechanical engineering professionals in California earned the highest salary at $112,100. Professionals in Texas received $98,030 in yearly salary compensation. Engineers in New York and Illinois earned approximately $95,020 in pay annually.

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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Materials Science 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.

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Computer Engineering Career Outlook & Salary

Just like their educational background, the job market for Computer Engineers is very broad. Rewarding careers are found in many areas. Robotic manufacturing, security equipment, medical diagnostic devices and personal electronics virtually all have some sort of computer in them.

The breadth of this industry means there are many opportunities to expand your skills as well as move up in responsibility and compensation.

According to the U.S. Bureau of Labor Statistics, Computer Hardware Engineers make a median annual salary of $98,610. Jobs in Computer Engineering are, like many other high-paying careers, most available in the Northeast and Southwest. Jobs in Computer Engineering are expected increase by 9% annually. The job market is expanding, and average salaries in the field are respectable.

Studying Computer Engineering can lead to a very rewarding career at the cutting edge of technology. Since virtually every modern device you own has some form of microprocessor in it, there is a growing need for Computer Engineers to design and integrate them. The job market is expanding, and average salaries in the field are respectable.

If you love math and science and want to be a part of the growing technology world, look into one of the many available Computer Engineering college degrees and get started in a rewarding career.

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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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Network Services

Computer systems and computerized systems help human beings to work efficiently and explore the unthinkable. When these devices are connected together to form a network, the capabilities are enhanced multiple-times. Some basic services computer network can offer are.

Directory Services

These services are mapping between name and its value, which can be variable value or fixed. This software system helps to store the information, organize it, and provides various means of accessing it.

• Accounting
  In an organization, a number of users have their user names and passwords mapped to them. Directory Services provide means of storing this information in cryptic form and make available when requested.
• Authentication and Authorization
  User credentials are checked to authenticate a user at the time of login and/or periodically. User accounts can be set into hierarchical structure and their access to resources can be controlled using authorization schemes.
• Domain Name Services
  DNS is widely used and one of the essential services on which internet works. This system maps IP addresses to domain names, which are easier to remember and recall than IP addresses. Because network operates with the help of IP addresses and humans tend to remember website names, the DNS provides website’s IP address which is mapped to its name from the back-end on the request of a website name from the user.

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Network Architect Job Description

Network technology is evolving at breakneck speed, and a rapidly growing number of organizations are searching for network architects to help them add and upgrade services.

The situation is complicated by the fact that many network architects who were on top of their game just a few years ago have neglected to keep pace with innovation and are now struggling to catch up. As a result, an emerging skills gap is frustrating a growing number of IT organizations while also providing an opening for skilled newcomers who can jump into the fray and begin helping their employers leverage new network technologies from day one.

"The current demand for network architects, specifically in the service provider and telecom industry, is extremely high," observed Tim Parker, vice president of network strategy for Flexential, a hybrid IT and network solutions provider. "Salaries are constantly increasing due to the high demand and low number of candidates."

The rate of innovation in networks is higher today than it has ever been in the past, stated Otto Fontana, Verizon's director of network services. "SD-WAN is transforming the access layer of networks (while) NFV, hybrid clouds, and SDN are transforming the data center networks." Network security models are also constantly evolving. "There is a very positive employment outlook for network architects who can adapt quickly to new technologies and trends," Fontana said.

"(IT organizations) are all looking for hybrid cloud solutions, and this changes the conversation and profile of the most valuable network architect in the room quite remarkably," explained Rob Owen, chief architect at Computer Design & Integration, which builds, deploys, and manages hybrid IT solutions. Until recently, any Cisco Certified Internetwork Expert (CCIE) network architect enjoyed a reputation as the authority on how to design and implement complex networking solutions. "Today, a lot of companies are looking for the architects who have a good grasp on the legacy way, but also understand how to create real SDN hybrid cloud architectures,

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Automotive Engineering Degrees

Automotive Engineering Degrees

Because not many schools offer a bachelor’s degree program in automotive engineering, most aspiring automotive students enter a mechanical engineering program. This is because automotive engineering is an offshoot of mechanical engineering and therefore, many of the classes are the same. However, some schools offer mechanical engineering programs that include automotive engineering courses such as:

• Automobile dynamics
• Automotive electronics
• Engine parts
• Diesel engine theory
• Alternative energy sources
• Fuel cell systems
• Powertrain dynamics

It usually takes four years to complete a bachelor's degree in engineering. During the last year, the student must finish a design project, either alone or with other students. After graduation, the new engineer must work under the supervision of a licensed professional engineer for a certain number of years, depending on the state, and pass and Engineer-In-Training exam and Professional Engineers exam to become a licensed professional engineer.

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Acoustic Engineering Salary

Acoustic Engineering Salary

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.

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.

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How the Internet of Things works

How the Internet of Things works

An IoT ecosystem consists of web-enabled smart devices that use embedded systems, such as processors, sensors and communication hardware, to collect, send and act on data they acquire from their environments. IoT devices share the sensor data they collect by connecting to an IoT gateway or other edge devices where data is either sent to the cloud to be analyzed or analyzed locally. Sometimes, these devices communicate with other related devices and act on the information they get from one another. The devices do most of the work without human intervention, although people can interact with the devices -- for instance, to set them up, give them instructions or access the data.

The connectivity, networking and communication protocols used with these web-enabled devices largely depend on the specific IoT applications deployed.

IoT can also make use of artificial intelligence (AI) and machine learning to aid in making data collecting processes easier and more dynamic.

The internet of things helps people live and work smarter, as well as gain complete control over their lives. In addition to offering smart devices to automate homes, IoT is essential to business. IoT provides businesses with a real-time look into how their systems really work, delivering insights into everything from the performance of machines to supply chain and logistics operations.

IoT enables companies to automate processes and reduce labor costs. It also cuts down on waste and improves service delivery, making it less expensive to manufacture and deliver goods, as well as offering transparency into customer transactions.

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Important Internet of Things Components

Important Internet of Things Components

Many people mistakenly think of IoT as an independent technology. Interestingly the internet of things is being enabled by the presence of other independent technologies that make fundamental components of IoT.

The fundamental components that make the internet of things a reality are:

• Hardware-Making physical objects responsive and giving them the capability to retrieve data and respond to instructions

• Software-Enabling the data collection, storage, processing, manipulating and instructing

• Communication Infrastructure-Most important of all is the communication infrastructure which consists of protocols and technologies which enable two physical objects to exchange data

As the telecommunication sector is becoming more extensive and efficient, broadband internet is widely available. With technological advancement, it is now much cheaper to produce necessary sensors with built-in wifi capabilities making connecting devices less costly.

Most importantly, smartphone usage has surpassed all the predicted limits and the telecommunication sector is already working on its toes to keep their customers satisfied by improving their infrastructure. As IoT devices need no separate communication than the existing one building IoT tech is very cheap and highly achievable.

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Pros and cons of IoT

Pros and cons of IoT

Some of the advantages of IoT include the following:

• ability to access information from anywhere at any time on any device;
• improved communication between connected electronic devices;
• transferring data packets over a connected network saving time and money; and
• automating tasks helping to improve the quality of a business's services and reducing the need for human intervention.

Some disadvantages of IoT include the following:

• As the number of connected devices increases and more information is shared between devices, the potential that a hacker could steal confidential information also increases.
• Enterprises may eventually have to deal with massive numbers -- maybe even millions -- of IoT devices, and collecting and managing the data from all those devices will be challenging.
• If there's a bug in the system, it's likely that every connected device will become corrupted.
• Since there's no international standard of compatibility for IoT, it's difficult for devices from different manufacturers to communicate with each other.

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The Future of IoT Technology

The Future of IoT Technology

As far as the reach of the Internet of Things, there are more than 12 billion devices that can currently connect to the Internet, and researchers at IDC estimate that by 2020 there will be 26 times more connected things than people.


According to Gartner, consumer applications will drive the number of connected things, while enterprise will account for most of the revenue. IoT adoption is growing, with manufacturing and utilities estimated to have the largest installed base of Things by 2020.

The Internet of Things is transforming every corner of life: the home, the office, city streets and beyond. IoT products give us greater control over door locks, lights and appliances; offer insights into resource consumption habits; streamline business processes; and better connect us to the people, systems and environments that shape our daily lives.

Whether you’re a homeowner looking for the best products to start building your connected life, or a business leader looking to take your company to the next level — this is the place to begin. We’ve collected the best and most popular options the IoT has to offer, from smart home devices to enterprise platforms to the software and tools you need to build your own smart, connected products.

Businesses can leverage IoT applications to automate safety tasks (for example, notify authorities when a fire extinguisher in the building is blocked) to performing real-world A/B testing using networked cameras and sensors to detect how customers engage with products.

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