Electronics Engineers, Except Computer

This is a sub-career of Electrical or Electronics Engineer

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Job Outlook:
Faster than average
Education: Bachelor's degree
Salary
High: $171,430.00
Average: $118,460.00
Hourly
Average: $56.95

What they do:

Research, design, develop, or test electronic components and systems for commercial, industrial, military, or scientific use employing knowledge of electronic theory and materials properties. Design electronic circuits and components for use in fields such as telecommunications, aerospace guidance and propulsion control, acoustics, or instruments and controls.

On the job, you would:

  • Design electronic components, software, products, or systems for commercial, industrial, medical, military, or scientific applications.
  • Operate computer-assisted engineering or design software or equipment to perform electronics engineering tasks.
  • Evaluate project work to ensure effectiveness, technical adequacy, or compatibility in the resolution of complex electronics engineering problems.

Important Qualities

Concentration. Electrical and electronics engineers design and develop complex electrical systems and electronic components and products. They must keep track of multiple design elements and technical characteristics when performing these tasks.

Initiative. Electrical and electronics engineers must apply their knowledge to new tasks in every project they undertake. In addition, they must engage in continuing education to keep up with changes in technology.

Interpersonal skills. Electrical and electronics engineers must work with others during the manufacturing process to ensure that their plans are implemented correctly. This collaboration includes monitoring technicians and devising remedies to problems as they arise.

Math skills. Electrical and electronics engineers must use the principles of calculus and other advanced math in order to analyze, design, and troubleshoot equipment.

Speaking skills. Electrical and electronics engineers work closely with other engineers and technicians. They must be able to explain their designs and reasoning clearly and to relay instructions during product development and production. They also may need to explain complex issues to customers who have little or no technical expertise.

Writing skills. Electrical and electronics engineers develop technical publications related to equipment they develop, including maintenance manuals, operation manuals, parts lists, product proposals, and design methods documents.

Personality

A3 Your Strengths Importance

Characteristics of this Career

91% Attention to Detail  -  Job requires being careful about detail and thorough in completing work tasks.
90% Dependability  -  Job requires being reliable, responsible, and dependable, and fulfilling obligations.
89% Analytical Thinking  -  Job requires analyzing information and using logic to address work-related issues and problems.
82% Cooperation  -  Job requires being pleasant with others on the job and displaying a good-natured, cooperative attitude.
81% Integrity  -  Job requires being honest and ethical.
79% Initiative  -  Job requires a willingness to take on responsibilities and challenges.
78% Adaptability/Flexibility  -  Job requires being open to change (positive or negative) and to considerable variety in the workplace.
74% Innovation  -  Job requires creativity and alternative thinking to develop new ideas for and answers to work-related problems.
71% Leadership  -  Job requires a willingness to lead, take charge, and offer opinions and direction.
70% Persistence  -  Job requires persistence in the face of obstacles.
66% Stress Tolerance  -  Job requires accepting criticism and dealing calmly and effectively with high-stress situations.
A3 Your Strengths Importance

Strengths

100% Investigative  -  Work involves studying and researching non-living objects, living organisms, disease or other forms of impairment, or human behavior. Investigative occupations are often associated with physical, life, medical, or social sciences, and can be found in the fields of humanities, mathematics/statistics, information technology, or health care service.
78% Realistic  -  Work involves designing, building, or repairing of equipment, materials, or structures, engaging in physical activity, or working outdoors. Realistic occupations are often associated with engineering, mechanics and electronics, construction, woodworking, transportation, machine operation, agriculture, animal services, physical or manual labor, athletics, or protective services.
A3 Your Strengths Importance

Values of the Work Environment

78% Working Conditions  -  Occupations that satisfy this work value offer job security and good working conditions. Corresponding needs are Activity, Compensation, Independence, Security, Variety and Working Conditions.
78% Recognition  -  Occupations that satisfy this work value offer advancement, potential for leadership, and are often considered prestigious. Corresponding needs are Advancement, Authority, Recognition and Social Status.
72% Achievement  -  Occupations that satisfy this work value are results oriented and allow employees to use their strongest abilities, giving them a feeling of accomplishment. Corresponding needs are Ability Utilization and Achievement.
72% Independence  -  Occupations that satisfy this work value allow employees to work on their own and make decisions. Corresponding needs are Creativity, Responsibility and Autonomy.
61% Support  -  Occupations that satisfy this work value offer supportive management that stands behind employees. Corresponding needs are Company Policies, Supervision: Human Relations and Supervision: Technical.

Aptitude

A3 Your Strengths Importance

Abilities | Cognitive, Physical, Personality

75% Near Vision  -  The ability to see details at close range (within a few feet of the observer).
75% Written Comprehension  -  The ability to read and understand information and ideas presented in writing.
75% Oral Expression  -  The ability to communicate information and ideas in speaking so others will understand.
75% Inductive Reasoning  -  The ability to combine pieces of information to form general rules or conclusions (includes finding a relationship among seemingly unrelated events).
75% Information Ordering  -  The ability to arrange things or actions in a certain order or pattern according to a specific rule or set of rules (e.g., patterns of numbers, letters, words, pictures, mathematical operations).
75% Oral Comprehension  -  The ability to listen to and understand information and ideas presented through spoken words and sentences.
75% Deductive Reasoning  -  The ability to apply general rules to specific problems to produce answers that make sense.
72% Written Expression  -  The ability to communicate information and ideas in writing so others will understand.
72% Problem Sensitivity  -  The ability to tell when something is wrong or is likely to go wrong. It does not involve solving the problem, only recognizing that there is a problem.
69% Mathematical Reasoning  -  The ability to choose the right mathematical methods or formulas to solve a problem.

Job Details

Responsibilities
Research design or application of green technologies.
Research design or application of green technologies.
Research design or application of green technologies.
Estimate technical or resource requirements for development or production projects.
Evaluate characteristics of equipment or systems.
Analyze design requirements for computer or electronics systems.
Confer with technical personnel to prepare designs or operational plans.
Communicate technical information to suppliers, contractors, or regulatory agencies.
Discuss designs or plans with clients.
Operate computer systems.
Recommend technical design or process changes to improve efficiency, quality, or performance.
Advise customers on the use of products or services.
Provide technical guidance to other personnel.
Estimate operational costs.
Prepare project budgets.
Design electronic or computer equipment or instrumentation.
Inspect finished products to locate flaws.
Document technical design details.
Direct industrial production activities.
Test products for functionality or quality.
Design electronic or computer equipment or instrumentation.
Create schematic drawings for electronics.
Schedule operational activities.
Document technical design details.
Prepare operational reports.
Determine operational criteria or specifications.
Explain project details to the general public.
A3 Your Strengths Importance

Attributes & Percentage of Time Spent

90% Electronic Mail  -  How often do you use electronic mail in this job?
89% Freedom to Make Decisions  -  How much decision making freedom, without supervision, does the job offer?
88% Face-to-Face Discussions  -  How often do you have to have face-to-face discussions with individuals or teams in this job?
86% Indoors, Environmentally Controlled  -  How often does this job require working indoors in environmentally controlled conditions?
81% Work With Work Group or Team  -  How important is it to work with others in a group or team in this job?
80% Spend Time Sitting  -  How much does this job require sitting?
79% Importance of Being Exact or Accurate  -  How important is being very exact or highly accurate in performing this job?
79% Structured versus Unstructured Work  -  To what extent is this job structured for the worker, rather than allowing the worker to determine tasks, priorities, and goals?
68% Contact With Others  -  How much does this job require the worker to be in contact with others (face-to-face, by telephone, or otherwise) in order to perform it?
A3 Your Strengths Importance

Tasks & Values

89% Working with Computers  -  Using computers and computer systems (including hardware and software) to program, write software, set up functions, enter data, or process information.
84% Analyzing Data or Information  -  Identifying the underlying principles, reasons, or facts of information by breaking down information or data into separate parts.
82% Drafting, Laying Out, and Specifying Technical Devices, Parts, and Equipment  -  Providing documentation, detailed instructions, drawings, or specifications to tell others about how devices, parts, equipment, or structures are to be fabricated, constructed, assembled, modified, maintained, or used.
79% Making Decisions and Solving Problems  -  Analyzing information and evaluating results to choose the best solution and solve problems.
77% Getting Information  -  Observing, receiving, and otherwise obtaining information from all relevant sources.
74% Processing Information  -  Compiling, coding, categorizing, calculating, tabulating, auditing, or verifying information or data.
73% Identifying Objects, Actions, and Events  -  Identifying information by categorizing, estimating, recognizing differences or similarities, and detecting changes in circumstances or events.
72% Documenting/Recording Information  -  Entering, transcribing, recording, storing, or maintaining information in written or electronic/magnetic form.
71% Thinking Creatively  -  Developing, designing, or creating new applications, ideas, relationships, systems, or products, including artistic contributions.
70% Communicating with Supervisors, Peers, or Subordinates  -  Providing information to supervisors, co-workers, and subordinates by telephone, in written form, e-mail, or in person.
68% Evaluating Information to Determine Compliance with Standards  -  Using relevant information and individual judgment to determine whether events or processes comply with laws, regulations, or standards.
67% Updating and Using Relevant Knowledge  -  Keeping up-to-date technically and applying new knowledge to your job.
66% Repairing and Maintaining Electronic Equipment  -  Servicing, repairing, calibrating, regulating, fine-tuning, or testing machines, devices, and equipment that operate primarily on the basis of electrical or electronic (not mechanical) principles.
66% Interpreting the Meaning of Information for Others  -  Translating or explaining what information means and how it can be used.

What Electrical and Electronics Engineers Do

Electrical and electronics engineers
Electronics engineers analyze the requirements and costs of electrical systems.

Electrical engineers design, develop, test, and supervise the manufacture of electrical equipment, such as electric motors, radar and navigation systems, communications systems, or power generation equipment. Electrical engineers also design the electrical systems of automobiles and aircraft.

Electronics engineers design and develop electronic equipment, including broadcast and communications systems, such as portable music players and Global Positioning System (GPS) devices. Many also work in areas closely related to computer hardware.

Duties

Electrical engineers typically do the following:

  • Design new ways to use electrical power to develop or improve products
  • Perform detailed calculations to develop manufacturing, construction, and installation standards and specifications
  • Direct the manufacture, installation, and testing of electrical equipment to ensure that products meet specifications and codes
  • Investigate complaints from customers or the public, evaluate problems, and recommend solutions
  • Work with project managers on production efforts to ensure that projects are completed satisfactorily, on time, and within budget

Electronics engineers typically do the following:

  • Design electronic components, software, products, or systems for commercial, industrial, medical, military, or scientific applications
  • Analyze customer needs and determine the requirements, capacity, and cost for developing an electrical system plan
  • Develop maintenance and testing procedures for electronic components and equipment
  • Evaluate systems and recommend design modifications or equipment repair
  • Inspect electronic equipment, instruments, and systems to make sure they meet safety standards and applicable regulations
  • Plan and develop applications and modifications for electronic properties used in parts and systems in order to improve technical performance

Electronics engineers who work for the federal government research, develop, and evaluate electronic devices used in a variety of areas, such as aviation, computing, transportation, and manufacturing. They work on federal electronic devices and systems, including satellites, flight systems, radar and sonar systems, and communications systems.

The work of electrical engineers and electronics engineers is often similar. Both use engineering and design software and equipment to do engineering tasks. Both types of engineers also must work with other engineers to discuss existing products and possibilities for engineering projects.

Engineers whose work is related exclusively to computer hardware are considered computer hardware engineers.

Work Environment

Electrical engineers held about 188,800 jobs in 2022. The largest employers of electrical engineers were as follows:

Engineering services 19%
Electric power generation, transmission and distribution 9
Navigational, measuring, electromedical, and control instruments manufacturing 7
Research and development in the physical, engineering, and life sciences 5
Semiconductor and other electronic component manufacturing 4

Electronics engineers, except computer held about 110,900 jobs in 2022. The largest employers of electronics engineers, except computer were as follows:

Telecommunications 18%
Federal government, excluding postal service 14
Semiconductor and other electronic component manufacturing 11
Engineering services 7
Navigational, measuring, electromedical, and control instruments manufacturing 6

Electrical and electronics engineers generally work indoors in offices. However, they may visit sites to observe a problem or a piece of complex equipment.

Work Schedules

Most electrical and electronics engineers work full time.

Getting Started

Education:
83%
Bachelor's Degree
14%
Associate's Degree (or other 2-year degree)

How to Become an Electrical or Electronics Engineer

Electrical and electronics engineers
Becoming an electrical or electronics engineer involves the study of math and engineering.

Electrical and electronics engineers must have a bachelor’s degree. Employers also value practical experience, such as internships or participation in cooperative engineering programs, in which students earn academic credit for structured work experience.

Education

High school students interested in studying electrical or electronics engineering benefit from taking courses in physics and math, including algebra, trigonometry, and calculus. Courses in drafting are also helpful, because electrical and electronics engineers often are required to prepare technical drawings.

Electrical and electronics engineers typically need a bachelor's degree in electrical engineering, electronics engineering, or a related engineering field. Programs include classroom, laboratory, and field studies. Courses include digital systems design, differential equations, and electrical circuit theory. Programs in electrical engineering, electronics engineering, or electrical engineering technology should be accredited by ABET.

Some colleges and universities offer cooperative programs in which students gain practical experience while completing their education. Cooperative programs combine classroom study with practical work. Internships provide similar experience and are growing in number.

At some universities, students can enroll in a 5-year program that leads to both a bachelor’s degree and a master’s degree. A graduate degree allows an engineer to work as an instructor at some universities, or in research and development.

Licenses, Certifications, and Registrations

Licensure is not required for entry-level positions as electrical and electronics engineers. A Professional Engineering (PE) license, which allows for higher levels of leadership and independence, can be acquired later in one’s career. Licensed engineers are called professional engineers (PEs). A PE can oversee the work of other engineers, sign off on projects, and provide services directly to the public. State licensure generally requires

  • A degree from an ABET-accredited engineering program
  • A passing score on the Fundamentals of Engineering (FE) exam
  • Relevant work experience, typically at least 4 years
  • A passing score on the Professional Engineering (PE) exam

The initial FE exam can be taken after earning a bachelor’s degree. Engineers who pass this exam commonly are called engineers in training (EITs) or engineer interns (EIs). After meeting work experience requirements, EITs and EIs can take the second exam, called the Principles and Practice of Engineering (PE).

Each state issues its own licenses. Most states recognize licensure from other states, as long as the licensing state’s requirements meet or exceed their own licensure requirements. Several states require continuing education for engineers to keep their licenses.

Advancement

Electrical and electronic engineers may advance to supervisory positions in which they lead a team of engineers and technicians. Some may move to management positions, working as engineering or program managers. Preparation for managerial positions usually requires working under the guidance of a more experienced engineer. For more information, see the profile on architectural and engineering managers.

For sales work, an engineering background enables engineers to discuss a product's technical aspects and assist in product planning and use. For more information, see the profile on sales engineers.

Job Outlook

Overall employment of electrical and electronics engineers is projected to grow 5 percent from 2022 to 2032, faster than the average for all occupations.

About 17,800 openings for electrical and electronics engineers are projected each year, on average, over the decade. Many of those openings are expected to result from the need to replace workers who transfer to different occupations or exit the labor force, such as to retire.

Employment

Projected employment of electrical and electronics engineers varies by occupation (see table).

Some employment growth is expected as companies continue to utilize the expertise of engineers for projects involving electronic devices and systems. These engineers are expected to have key roles in developing sophisticated consumer electronics, solar arrays, semiconductors, and communications technologies.

Contacts for More Information

For more information about general engineering education and career resources, visit

American Society for Engineering Education

Technology Student Association

For more information about licensure as an electrical or electronics engineer, visit

National Council of Examiners for Engineering and Surveying

National Society of Professional Engineers

International Society of Automation

For more information about accredited engineering programs, visit

ABET

Similar Occupations

This table shows a list of occupations with job duties that are similar to those of electrical and electronics engineers.

Occupation Job Duties Entry-Level Education Median Annual Pay, May 2022
Aerospace engineers Aerospace Engineers

Aerospace engineers design, develop, and test aircraft, spacecraft, satellites, and missiles.

Bachelor's degree $126,880
Architectural and engineering managers Architectural and Engineering Managers

Architectural and engineering managers plan, direct, and coordinate activities in the fields of architecture and engineering.

Bachelor's degree $159,920
Bioengineers and biomedical engineers Bioengineers and Biomedical Engineers

Bioengineers and biomedical engineers combine engineering principles with sciences to design and create equipment, devices, computer systems, and software.

Bachelor's degree $99,550
Computer hardware engineers Computer Hardware Engineers

Computer hardware engineers research, design, develop, and test computer systems and components.

Bachelor's degree $132,360
Electrical and electronic engineering technicians Electrical and Electronic Engineering Technologists and Technicians

Electrical and electronic engineering technologists and technicians help engineers design and develop equipment that is powered by electricity or electric current.

Associate's degree $66,390
Electrical and electronics installers and repairers Electrical and Electronics Installers and Repairers

Electrical and electronics installers and repairers install or repair a variety of electrical equipment.

See How to Become One $64,190
Electricians Electricians

Electricians install, maintain, and repair electrical power, communications, lighting, and control systems.

High school diploma or equivalent $60,240
Network and computer systems administrators Network and Computer Systems Administrators

Network and computer systems administrators install, configure, and maintain organizations’ computer networks and systems.

Bachelor's degree $90,520
Sales engineers Sales Engineers

Sales engineers sell complex scientific and technological products or services to businesses.

Bachelor's degree $108,530
Electro-mechanical technicians Electro-mechanical and Mechatronics Technologists and Technicians

Electro-mechanical and mechatronics technologists and technicians operate, test, and maintain electromechanical or robotic equipment.

Associate's degree $60,570

Information provided by CareerFitter, LLC and other sources.

Sections of this page includes information from the O*NET 27.3 Database by the U.S. Department of Labor, Employment and Training Administration (USDOL/ETA). Used under the CC BY 4.0 license.

CareerFitter, LLC has modified all or some of this information. USDOL/ETA has not approved, endorsed, or tested these modifications.