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Engineer
Kitty Joyner, electrical engineer, analyzing the operation of a wind tunnel turbine at Langley in 1952
Occupation
NamesEngineer
Occupation type
Profession
Activity sectors
Applied science
Description
CompetenciesMathematics, science, design, analysis, critical thinking, engineering ethics, project management, engineering economics, creativity, problem solving, (See also: Glossary of engineering)
Education required
Engineering education
Fields of
employment
Research and development, industry, business
Related jobs
Scientist, architect, project manager, inventor, astronaut

An engineer is a practitioner of engineering.[1][2] The word engineer (Latin ingeniator,[3] the origin of the Ir. in the title of engineer in countries like Belgium, The Netherlands, and Indonesia) is derived from the Latin words ingeniare ("to contrive, devise") and ingenium ("cleverness").[4][5] The foundational qualifications of a licensed professional engineer typically include a four-year bachelor's degree in an engineering discipline, or in some jurisdictions, a master's degree in an engineering discipline plus four to six years of peer-reviewed professional practice (culminating in a project report or thesis) and passage of engineering board examinations.

The work of engineers forms the link between scientific discoveries and their subsequent applications to human and business needs and quality of life.[1]

Definition

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In 1961, the Conference of Engineering Societies of Western Europe and the United States of America defined "professional engineer" as follows:[6]

A professional engineer is competent by virtue of his/her fundamental education and training to apply the scientific method and outlook to the analysis and solution of engineering problems. He/she is able to assume personal responsibility for the development and application of engineering science and knowledge, notably in research, design, construction, manufacturing, superintending, managing, and in the education of the engineer. His/her work is predominantly intellectual and varied and not of a routine mental or physical character. It requires the exercise of original thought and judgment and the ability to supervise the technical and administrative work of others. His/her education will have been such as to make him/her capable of closely and continuously following progress in his/her branch of engineering science by consulting newly published works on a worldwide basis, assimilating such information, and applying it independently. He/she is thus placed in a position to make contributions to the development of engineering science or its applications. His/her education and training will have been such that he/she will have acquired a broad and general appreciation of the engineering sciences as well as thorough insight into the special features of his/her own branch. In due time he/she will be able to give authoritative technical advice and assume responsibility for the direction of important tasks in his/her branch.

Roles and expertise

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Design

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A design for a flying machine (c. 1488), first presented in the Codex on the Flight of Birds
An aerial screw (c. 1489), suggestive of a helicopter, from the Codex Atlanticus

Engineers develop new technological solutions. During the engineering design process, the responsibilities of the engineer may include defining problems, conducting and narrowing research, analyzing criteria, finding and analyzing solutions, and making decisions. Much of an engineer's time is spent on researching, locating, applying, and transferring information.[7] Indeed, research suggests engineers spend 56% of their time engaged in various information behaviours, including 14% actively searching for information.[8]

Engineers must weigh different design choices on their merits and choose the solution that best matches the requirements and needs. Their crucial and unique task is to identify, understand, and interpret the constraints on a design in order to produce a successful result. Good problem solving skills are an important asset for engineers.

Analysis

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Engineers conferring on prototype design, 1954

Engineers apply techniques of engineering analysis in testing, production, or maintenance. Analytical engineers may supervise production in factories and elsewhere, determine the causes of a process failure, and test output to maintain quality. They also estimate the time and cost required to complete projects. Supervisory engineers are responsible for major components or entire projects. Engineering analysis involves the application of scientific analytic principles and processes to reveal the properties and state of the system, device or mechanism under study. Engineering analysis proceeds by separating the engineering design into the mechanisms of operation or failure, analyzing or estimating each component of the operation or failure mechanism in isolation, and recombining the components. They may analyze risk.[9][10][11][12]

Many engineers use computers to produce and analyze designs, to simulate and test how a machine, structure, or system operates, to generate specifications for parts, to monitor the quality of products, and to control the efficiency of processes.

Specialization and management

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NASA Launch Control Center Firing Room 2 as it appeared in the Apollo era

Most engineers specialize in one or more engineering disciplines.[1] Numerous specialties are recognized by professional societies, and each of the major branches of engineering has numerous subdivisions. Civil engineering, for example, includes structural engineering, along with transportation engineering, geotechnical engineering, and materials engineering, including ceramic, metallurgical, and polymer engineering. Mechanical engineering cuts across most disciplines since its core essence is applied physics. Engineers also may specialize in one industry, such as motor vehicles, or in one type of technology, such as turbines or semiconductor materials.[1]

Several recent studies have investigated how engineers spend their time; that is, the work tasks they perform and how their time is distributed among these. Research[8][13] suggests that there are several key themes present in engineers' work: technical work (i.e., the application of science to product development), social work (i.e., interactive communication between people), computer-based work and information behaviors. Among other more detailed findings, a 2012 work sampling study[13] found that engineers spend 62.92% of their time engaged in technical work, 40.37% in social work, and 49.66% in computer-based work. Furthermore, there was considerable overlap between these different types of work, with engineers spending 24.96% of their time engaged in technical and social work, 37.97% in technical and non-social, 15.42% in non-technical and social, and 21.66% in non-technical and non-social.

Engineering is also an information-intensive field, with research finding that engineers spend 55.8% of their time engaged in various different information behaviors, including 14.2% actively seeking information from other people (7.8%) and information repositories such as documents and databases (6.4%).[8]

The time engineers spend engaged in such activities is also reflected in the competencies required in engineering roles. In addition to engineers' core technical competence, research has also demonstrated the critical nature of their personal attributes, project management skills, and cognitive abilities to success in the role.[14]

Types of engineers

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Main article: List of engineering branches
Photograph of the Engineering group, sculpted by John Lawlor, Albert Memorial

There are many branches of engineering, each of which specializes in specific technologies and products. Typically, engineers will have deep knowledge in one area and basic knowledge in related areas. For example, mechanical engineering curricula typically include introductory courses in electrical engineering, computer science, materials science, metallurgy, mathematics, and software engineering.

An engineer may either be hired for a firm that requires engineers on a continuous basis, or may belong to an engineering firm that provides engineering consulting services to other firms.

When developing a product, engineers typically work in interdisciplinary teams. For example, when building robots an engineering team will typically have at least three types of engineers. A mechanical engineer would design the body and actuators. An electrical engineer would design the power systems, sensors, electronics, embedded software in electronics, and control circuitry. Finally, a software engineer would develop the software that makes the robot behave properly. Engineers that aspire to management engage in further study in business administration, project management and organizational or business psychology. Often engineers move up the management hierarchy from managing projects, functional departments, and divisions, and some eventually become CEOs of multi-national corporations.

Branch Focus Related sciences Products
Automobile engineering Focuses on the development of automobiles and related technology Structural engineering, electronics, materials science, automotive safety, fluid mechanics, thermodynamics, engineering mathematics, ergonomics, environmental compliance, road traffic safety, chemistry Automobiles
Aerospace engineering Focuses on the development of aircraft and spacecraft Aeronautics, astrodynamics, astronautics, avionics, control engineering, fluid mechanics, kinematics, materials science, thermodynamics Aircraft, robotics, spacecraft, trajectories
Agricultural engineering Focuses on the engineering, science, and technology for the production and processing of food from agriculture, such as the production of arable crops, soft fruit and livestock. A key goal of this discipline is to improve the efficacy and sustainability of agricultural practices for food production. Agricultural engineering often combines and converges many other engineering disciplines such as mechanical engineering, civil engineering, electrical engineering, chemical engineering, biosystems engineering, soil science, environmental engineering Livestock, food, horticulture, forestry, renewable energy crops.

Agricultural machinery such as tractors, combine harvesters, forage harvesters.

Agricultural technology incorporates such things as robotics and autonomous vehicles.

Architectural engineering and building engineering Focuses on building and construction Architecture, architectural technology Buildings and bridges
Biomedical engineering Focuses on closing the gap between engineering and medicine to advance various health care treatments Biology, physics, chemistry, medicine Prostheses, medical devices, regenerative tissue growth, various safety mechanisms, genetic engineering
Chemical engineering Focuses on the transformation of raw materials into useful products in large scale Chemistry, thermodynamics, chemical thermodynamics, process engineering, transport phenomena, nanotechnology, biology, chemical kinetics, genetic engineering medicine, fluid mechanics, textiles Synthetic chemicals, fuels, medicines, raw materials, foods and beverages, waste and water treatment, pure gases, plastics, coatings, textiles
Civil engineering Focuses on the construction of large systems, structures, and environmental systems Statics, fluid mechanics, soil mechanics, structural engineering, transportation engineering, geotechnical engineering, environmental engineering, hydraulic engineering, construction engineering Roads, bridges, dams, buildings, structural system, foundation, earthworks, waste management, water treatment
Computer engineering Focuses on the design and development of computer hardware & software systems Computer science, mathematics, electrical engineering Microprocessors, microcontrollers, operating systems, embedded systems, computer networks
Electrical engineering Focuses on application of electricity, electronics, and electromagnetism Mathematics, probability and statistics, engineering ethics, engineering economics, instrumentation, materials science, physics, network analysis, electromagnetism, linear system, electronics, electric power, logic, computer science, data transmission, systems engineering, control engineering, signal processing Electricity generation and equipment, remote sensing, robotics, control system, computers, home appliances, internet of things, consumer electronics, avionics, hybrid vehicles, spacecraft, unmanned aerial vehicles, optoelectronics, embedded systems
Fire protection engineering Focuses on application of science and engineering principles to protect people, property, and their environments from the harmful and destructive effects of fire and smoke. Fire, smoke, fluid dynamics, thermodynamics, heat transfer, combustion, physics, materials science, chemistry, statics, dynamics, probabilistic risk assessment or risk management, environmental psychology, engineering ethics, engineering economics, systems engineering, reliability, fire suppression, fire alarms, building fire safety, wildfire, building codes, measurement and simulation of fire phenomena, mathematics, probability and statistics. Fire suppression systems, fire alarm systems, passive fire protection, smoke control systems, sprinkler systems, code consulting, fire and smoke modeling, emergency management, water supply systems, fire pumps, structural fire protection, foam extinguishing systems, gaseous fire suppression systems, oxygen reduction systems, flame detection, aerosol fire suppression.
Industrial engineering Focuses on the design, optimization, and operation of production, logistics, and service systems and processes Operations research, engineering statistics, applied probability and stochastic processes, automation engineering, methods engineering, production engineering, manufacturing engineering, systems engineering, logistics engineering, ergonomics quality control systems, manufacturing systems, warehousing systems, supply chains, logistics networks, queueing systems, business process management
Mechatronics engineering Focuses on the technology and controlling all the industrial field Process control, automation Robotics, controllers, CNC
Mechanical engineering Focuses on the development and operation of energy systems, transport systems, manufacturing systems, machines and control systems Dynamics, kinematics, statics, fluid mechanics, materials science, metallurgy, strength of materials, thermodynamics, heat transfer, mechanics, mechatronics, manufacturing engineering, control engineering Cars, airplanes, machines, power generation, spacecraft, buildings, consumer goods, manufacturing, HVAC
Metallurgical engineering/materials engineering Focuses on extraction of metals from its ores and development of new materials Material science, thermodynamics, extraction of metals, physical metallurgy, mechanical metallurgy, nuclear materials, steel technology Iron, steel, polymers, ceramics, metals
Mining engineering Focuses on the use of applied science and technology to extract various minerals from the earth, not to be confused with metallurgical engineering, which deals with mineral processing of various ores after they have already been mined Rock mechanics, geostatistics, soil mechanics, control engineering, geophysics, fluid mechanics, drilling and blasting Gold, silver, coal, iron ore, potash, limestone, diamond, rare-earth element, bauxite, copper
Military engineering Focuses on constructions and repairs of military structures (such as airfield, naval shipyards,barracks, missile silos etc.) as well as repairing damaged structures or producing/repairing combat vehicles, aircraft or seacraft Military science Weapon, ammunition, tanks, attack helicopters, fighters, bombers, military bases, warships, carrier, submarines, ballistic missiles
Software engineering Focuses on the design and development of software systems Computer science, Computing, information theory, systems engineering, formal language Application software, Mobile apps, Websites, operating systems, embedded systems, real-time computing, video games, virtual reality, AI software, edge computing, distributed systems, computer vision, music sequencers, digital audio workstations, software synthesizers, robotics, CGI, medical software, computer-assisted surgery, internet of things, avionics software, computer simulation, quantum programming, satellite navigation software, antivirus software, electronic design automation, computer-aided design, self-driving cars, educational software

Ethics

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Main article: Engineering ethics
An engineer receiving his Order of the Engineer ring

Engineers have obligations to the public, their clients, employers, and the profession. Many engineering societies have established codes of practice and codes of ethics to guide members and inform the public at large. Each engineering discipline and professional society maintains a code of ethics, which the members pledge to uphold. Depending on their specializations, engineers may also be governed by specific statute, whistleblowing, product liability laws, and often the principles of business ethics.[15][16][17]

Some graduates of engineering programs in North America may be recognized by the iron ring or Engineer's Ring, a ring made of iron or stainless steel that is worn on the little finger of the dominant hand. This tradition began in 1925 in Canada with The Ritual of the Calling of an Engineer, where the ring serves as a symbol and reminder of the engineer's obligations to the engineering profession. In 1972, the practice was adopted by several colleges in the United States including members of the Order of the Engineer.

Education

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Main article: Engineering education

Most engineering programs involve a concentration of study in an engineering specialty, along with courses in both mathematics and the physical and life sciences. Many programs also include courses in general engineering and applied accounting. A design course, often accompanied by a computer or laboratory class or both, is part of the curriculum of most programs. Often, general courses not directly related to engineering, such as those in the social sciences or humanities, also are required.

Accreditation is the process by which engineering programs are evaluated by an external body to determine if applicable standards are met. The Washington Accord serves as an international accreditation agreement for academic engineering degrees, recognizing the substantial equivalency in the standards set by many major national engineering bodies. In the United States, post-secondary degree programs in engineering are accredited by the Accreditation Board for Engineering and Technology.

Regulation

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Main article: Regulation and licensure in engineering
Footage of the old Tacoma Narrows Bridge Narrows Bridge collapsing
(19.1MiB video, 02:30)

In many countries, engineering tasks such as the design of bridges, electric power plants, industrial equipment, machine design and chemical plants, must be approved by a licensed professional engineer. Most commonly titled professional engineer is a license to practice and is indicated with the use of post-nominal letters; PE or P.Eng. These are common in North America, as is European engineer (EUR ING) in Europe.[citation needed]

The Challenger disaster is held as a case study of engineering ethics

In the United States, engineering is a regulated profession whose practice and practitioners are licensed and governed by law. Licensure is generally attainable through combination of education, pre-examination (Fundamentals of Engineering exam), examination (professional engineering exam),[18] and engineering experience (typically in the area of 5+ years). Each state tests and licenses professional engineers. Currently, most states do not license by specific engineering discipline, but rather provide generalized licensure, and trust engineers to use professional judgment regarding their individual competencies; this is the favoured approach of the professional societies. Despite this, at least one of the examinations required by most states is actually focused on a particular discipline; candidates for licensure typically choose the category of examination which comes closest to their respective expertise. In the United States, an "industrial exemption" allows businesses to employ employees and call them an "engineer", as long as such individuals are under the direct supervision and control of the business entity and function internally related to manufacturing (manufactured parts) related to the business entity, or work internally within an exempt organization. Such person does not have the final authority to approve, or the ultimate responsibility for, engineering designs, plans, or specifications that are to be incorporated into fixed works, systems, or facilities on the property of others or made available to the public. These individuals are prohibited from offering engineering services directly to the public or other businesses, or engage in practice of engineering unless the business entity is registered with the state's board of engineering, and the practice is carried on or supervised directly only by engineers licensed to engage in the practice of engineering.[19] In some instances, some positions, such as a "sanitation engineer", does not have any basis in engineering sciences. Although some states require a BS degree in engineering accredited by the Engineering Accreditation Commission (EAC) of Accreditation Board for Engineering and Technology (ABET) with no exceptions, about two thirds of the states accept BS degrees in engineering technology accredited by the Engineering Technology Accreditation Commission (ETAC) of ABET to become licensed as professional engineers. Each state has different requirements on years of experience to take the Fundamentals of Engineering (FE) and Professional Engineering (PE) exams. A few states require a graduate MS in engineering to sit for the exams as further learning. After seven years of working after graduation, two years of responsibility for significant engineering work, continuous professional development, some highly qualified PEs are able to become International Professional Engineers Int(PE). These engineers must meet the highest level of professional competencies and this is a peer-reviewed process. Once the IntPE title is awarded, the engineer can gain easier admission to national registers of a number of members jurisdictions for international practice.[20]

In Canada, engineering is a self-regulated profession. The profession in each province is governed by its own engineering association. For instance, in the province of British Columbia an engineering graduate with four or more years of post graduate experience in an engineering-related field and passing exams in ethics and law will need to be registered by the Association for Professional Engineers and Geoscientists (APEGBC)[21] in order to become a Professional Engineer and be granted the professional designation of P.Eng allowing one to practice engineering.

In Continental Europe, Latin America, Turkey, and elsewhere the title is limited by law to people with an engineering degree and the use of the title by others is illegal. In Italy, the title is limited to people who hold an engineering degree, have passed a professional qualification examination (Esame di Stato) and are enrolled in the register of the local branch of National Associations of Engineers (a public body). In Portugal, professional engineer titles and accredited engineering degrees are regulated and certified by the Ordem dos Engenheiros. In the Czech Republic, the title "engineer" (Ing.) is given to people with a (master's) degree in chemistry, technology or economics for historical and traditional reasons. In Greece, the academic title of "Diploma Engineer" is awarded after completion of the five-year engineering study course and the title of "Certified Engineer" is awarded after completion of the four-year course of engineering studies at a Technological Educational Institute (TEI).

Definition by country

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Archimedes is regarded as one of the leading scientists in classical antiquity whose ideas have underpinned much of the practice of engineering.

The definition of the term "engineer" varies across countries and continents.

Asia and Africa

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In the Indian subcontinent, Russia, Middle East, Africa, and China, engineering is one of the most sought-after undergraduate courses, for which entrance examinations are highly competitive.

In Egypt, the educational system makes engineering the second-most respected profession in the country (after medicine); engineering colleges at Egyptian universities require extremely high marks on the General Certificate of Secondary Education (Arabic: الثانوية العامة al-Thānawiyyah al-`Āmmah) – in the order of 97 or 98 per cent – and are thus considered (along with the colleges of medicine, natural science, and pharmacy) to be among the "pinnacle colleges" (كليات القمة kullīyāt al-qimmah).[citation needed]

In the Philippines and Filipino communities overseas, engineers who are either Filipino or not, especially those who also profess other jobs at the same time, are addressed and introduced as Engineer, rather than Sir/Madam in speech or Mr./Mrs./Ms. (G./Gng./Bb. in Filipino) before surnames. That word is used either in itself or before the given name or surname.

Europe

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19th-century engineer Isambard Kingdom Brunel by the launching chains of the SS Great Eastern.

As of 2022, thirty two countries in Europe (including nearly all 27 countries of the EU) now recognise the title of "European Engineer" which permits the use of the pre-nominal title of "EUR ING" (always fully capitalised). Each country sets its own precise qualification requirement for the use of the title (though they are all broadly equivalent). Holding the requisite qualification does not afford automatic entitlement. The title has to be applied for (and the appropriate fee paid). The holder is entitled to use the title in their passport. EUR INGs are allowed to describe themselves as professionally qualified engineers and practise as such in any of the 32 participating countries including those where the title of engineer is regulated by law.[citation needed]

France

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Gustave Eiffel was a French civil engineer.

In France, the term ingénieur (engineer) is not a protected title and can be used by anyone who practices this profession.[22]

However, the title ingénieur diplomé (graduate engineer) is an official academic title that is protected by the government and is associated with the Diplôme d'Ingénieur, which is a renowned academic degree in France. Anyone misusing this title in France can be fined a large sum and jailed, as it is usually reserved for graduates of French engineering grandes écoles. Engineering schools which were created during the French revolution have a special reputation among the French people, as they helped to make the transition from a mostly agricultural country of late 18th century to the industrially developed France of the 19th century. A great part of 19th-century France's economic wealth and industrial prowess was created by engineers that have graduated from École Centrale Paris, École des Mines de Paris, École polytechnique or Télécom Paris. This was also the case after WWII when France had to be rebuilt. Before the "réforme René Haby" in the 1970s, it was very difficult to be admitted to such schools, and the French ingénieurs were commonly perceived as the nation's élite. However, after the Haby reform and a series of further reforms (Modernization plans of French universities), several engineering schools were created which can be accessed with relatively lower competition.

Engineering positions in France are now shared between the ingénieurs diplomés graduating from engineering grandes écoles and the holders of a master's degree in science from public universities.

Italy

[edit]
Umberto Nobile was an aeronautical engineer and Arctic explorer.

In Italy, only people who hold a formal engineering qualification of at least a bachelor's degree are permitted to describe themselves as an engineer. So much so that people holding such qualifications are entitled to use the pre-nominal title of "Ingegnere" (or "Ingegnera" if female - in both cases often abbreviated to "Ing.") in lieu of "Signore", "Signorina" or "Signora" (Mr, Miss and Mrs respectively) in the same manner as someone holding a doctorate would use the pre-nominal title "Doctor".[23]

United Kingdom

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In the UK, the practice of engineering is not a regulated profession but control of the titles of chartered engineer (CEng) and incorporated engineer (IEng) is regulated. These titles are protected by law and are subject to strict requirements defined by the Engineering Council. The title CEng is in use in nations of the Commonwealth of Nations that follow or adapt British professional codes.[citation needed]

Many skilled and semi-skilled tradespeople in the UK, including, for example, engineering technicians who service domestic appliances or telephone systems, call themselves engineers, and the term in that context is commonly used by the public.[citation needed] Proposals such as a 2015 petition to the UK parliament[24] to legally protect the title "engineer" so that only professional engineers could use it have been unsuccessful (as of 2023)

North America

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Canada

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In Canada, engineering is a regulated profession whose practice and practitioners are licensed and governed by law.[25] Licensed professional engineers are referred to as P.Eng. Many Canadian engineers wear an Iron Ring.[26]

In all Canadian provinces, the title "Professional Engineer" is protected by law and any non-licensed individual or company using the title is committing a legal offence and is subject to fines and restraining orders.[27] Contrary to insistence from the Professional Engineers Ontario ("PEO") and Engineers Canada, use of the title "Engineer" itself has been found by Canadian law to be acceptable by those not holding P.Eng. titles.[28][29]

The title of engineer is not exclusive to P.Eng titles. The title of Engineer is commonly held by "Software Engineer",[30] the Canadian Military as various ranks and positions,[31] railway locomotive engineers,[32] Stationary engineer and Aircraft Maintenance Engineers (AME), all of which do not commonly hold a P.Eng. designation.

United States

[edit]

In the United States, the practice of professional engineering is highly regulated and the title "professional engineer" is legally protected, meaning that it is unlawful to use it to offer engineering services to the public unless permission, certification or other official endorsement is specifically granted by that state through a professional engineering license.[33]

Spanish-speaking countries

[edit]
Baltasar Mena Iniesta a Spanish-born Mexican mechanical engineer specialized in Rheology.

Certain Spanish-speaking countries follow the Italian convention of engineers using the pre-nominal title, in this case "ingeniero" (or "ingeniera" if female). Like in Italy, it is usually abbreviated to "Ing." In Spain this practice is not followed.

The engineering profession enjoys high prestige in Spain, ranking close to medical doctors, scientists and professors, and above judges, journalists or entrepreneurs, according to a 2014 study.[34]

See also

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References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Engineer

View on Grokipedia
from Grokipedia
An engineer is a professional practitioner who systematically applies scientific knowledge, , and creative judgment to , develop, build, and optimize structures, machines, systems, devices, and processes that address technical challenges and enhance human welfare. The term originates from the Latin ingenium, denoting innate cleverness or talent, and ingeniare, meaning to contrive or devise, reflecting the profession's roots in ingenuity and problem-solving. Engineering spans diverse disciplines, each tailored to specific domains of application. focuses on infrastructure such as bridges, roads, and water systems; designs machines and thermal systems; and electronics engineering develop power generation, circuits, and communication technologies; and optimizes processes for producing fuels, pharmaceuticals, and materials. Other fields include , , and , collectively addressing global needs in health, sustainability, and manufacturing. Engineers typically earn a from an accredited program, often followed by advanced study. In some countries, such as Russia and other Commonwealth of Independent States (CIS) countries, the title "Engineer" is conferred upon completion of a five-year specialist degree known as the Diploma of Engineer (diplom inzhenera). In jurisdictions requiring licensure, such as the as a Professional Engineer (PE), this involves passing the Fundamentals of Engineering (FE) and Principles and Practice of Engineering (PE) exams, accumulating at least four years of supervised experience, and adhering to ethical standards to safeguard and safety. The profession's impact is profound, driving innovation from ancient achievements—like the construction of around 2600 BCE, which demonstrated early mastery of materials and —to contemporary advancements in and . In the United States, and engineering occupations numbered about 2.6 million in May 2024, with projected annual job openings of 186,500 through 2034 due to growth and retirements, outpacing the average for all occupations at a 7% rate. Median annual wages reached $97,310 in May 2024, significantly above the national median of $49,500, underscoring engineering's economic value and role in fostering technological progress and societal resilience.

Fundamentals

Definition

An engineer is a practitioner of , a defined as the systematic application of scientific knowledge to develop and apply that addresses human needs and advances . This involves using principles from , natural sciences, , and other fields to create artifacts, processes, or systems through and problem-solving. The term "engineer" derives from the Latin words ingenium (cleverness or innate quality) and ingeniare (to contrive or devise), reflecting the profession's roots in ingenuity and , originally associated with constructing devices in . Over centuries, the role has evolved to encompass broad applications of scientific and mathematical principles to practical ends, such as designing , machinery, and software that benefit humanity. In a professional context, an engineer is typically someone who holds a degree from an accredited program and applies specialized knowledge to solve technical problems while considering economic, environmental, and societal factors. Licensure as a Engineer (P.E.) in many countries, including the , requires a in , passing rigorous examinations, and several years of supervised experience to ensure adherence to standards that protect , safety, and welfare. This credential distinguishes licensed professionals from those in related technical roles, emphasizing ethical responsibility and competence.

Historical Development

The practice of engineering traces its origins to ancient civilizations, where systematic application of knowledge to design and construct infrastructure marked early human ingenuity. In around 2580–2500 BC, engineers organized labor and resources to build the pyramids at , utilizing ramps and advanced geometry to align structures with astronomical precision. Similarly, the Romans developed sophisticated feats, including a vast network of approximately 300,000 kilometers (186,000 miles) of roads, much of which was constructed by AD 200 for military efficiency and aqueducts like the to transport across distances, relying on arches and innovations. These endeavors, while not formalized as a profession, demonstrated coordinated technical expertise in materials and . During the medieval period and , engineering evolved with military and architectural focuses. In , master masons oversaw Gothic cathedrals using empirical knowledge of arches and buttresses, while in the Islamic world, inventors like al-Jazari (c. 1136–1206) designed automata and water-raising devices that advanced mechanical principles. The term "engineer" emerged in the , initially denoting military specialists crafting engines; figures such as (1452–1519) exemplified this by sketching war machines and fortifications. Formal education began in with institutions like the École Nationale des Ponts et Chaussées in the 1770s and in 1794, training civil engineers in and practical sciences. The in the late 18th and 19th centuries transformed engineering into a cornerstone of economic progress, particularly in Britain. Innovations like James Watt's improved (patented 1769) enabled mechanized factories, while civil engineers such as (1757–1834) constructed canals and bridges, and (1806–1859) advanced railroads and steamships. Engineers' role in invention surged; their share of patents rose from 10% in the early 1800s to 30% by the 1860s, driving higher-quality, reproducible technologies across sectors. Apprenticeships gave way to formal education via land-grant colleges under the U.S. Morrill Act of 1862, emphasizing scientific training. In the , engineering professionalized amid rapid technological advances and global conflicts. The formed in 1852, followed by licensure laws starting in in 1907 to regulate practice and ensure competency, with all U.S. states adopting requirements by 1947. World Wars accelerated innovations like and , while post-1945 developments in and solidified engineering's interdisciplinary nature. By the late , emphasis shifted to , diversity, and engineering , with organizations like the National Society of Professional Engineers (founded 1934) promoting standards.

Roles and Responsibilities

Design

In engineering, refers to the systematic of conceiving, planning, and specifying solutions to technical problems, encompassing the creation of systems, components, or that meet defined needs while adhering to constraints such as , , and environmental factors. This phase is integral to the role, where professionals translate requirements into feasible blueprints, models, or prototypes, often iterating based on and feedback to optimize performance and manufacturability. According to standards, is inherently iterative and decision-oriented, involving the identification of opportunities, requirement development, , synthesis, solution generation, , and communication of results. The design process typically unfolds in structured steps, beginning with problem definition and to understand user needs and constraints, followed by ideation to generate multiple concepts through brainstorming and sketching. Engineers then select promising solutions via feasibility studies, develop detailed specifications using tools like CAD software, and to validate functionality before refining through testing and iteration. For instance, in wind energy projects, design engineers analyze components for and reliability, conducting root cause analyses on failures to inform improvements while collaborating across teams to ensure designs align with capabilities. This process emphasizes alongside technical rigor, with engineers balancing trade-offs in areas like structural integrity and energy output. Engineers in the design role bear responsibilities that span conceptualization to implementation oversight, including preparing proposals, budgets, and engineering drawings; evaluating design improvements; and integrating interdisciplinary inputs to mitigate risks. Design engineers often act as mediators in product development, fostering between creative designers, technical specialists, and stakeholders to align , functionality, and market demands, as evidenced by their central position in intra-firm knowledge networks that enhance efficiency. In practice, this involves supervising cycles, ensuring compliance with standards, and applying tools like for precise simulations, ultimately delivering solutions that are innovative yet practical. High-impact examples include the iterative refinement of mechanical systems in , where designs evolve through to achieve greater and .

Analysis

Engineering analysis constitutes a core responsibility of engineers, involving the systematic evaluation of a system's response to specified inputs based on its established parameters. This employs mathematical, computational, and experimental techniques to predict , identify potential failures, and verify compliance with requirements such as standards and goals. In the broader , analysis bridges and , allowing iterative refinements to mitigate risks before physical prototyping or deployment. Common methods in engineering analysis span analytical, experimental, and numerical approaches. Analytical methods rely on mathematical modeling, such as differential equations, to derive exact solutions for idealized systems, often applied in early-stage assessments. Experimental methods involve physical testing, including scale models or prototypes, to validate real-world behavior under controlled conditions, like evaluations for aerodynamic performance. Numerical methods, increasingly dominant due to computational advances, approximate solutions through ; prominent examples include finite element (FEA) for stress and deformation in structures, (CFD) for flow simulations, and multibody dynamics (MBD) for mechanical assemblies. These methods are selected based on the problem's complexity, with hybrid approaches common for comprehensive validation. The importance of in engineering roles lies in its capacity to enhance reliability, optimize resource use, and inform across disciplines. By quantifying factors like structural integrity or economic viability, engineers can prioritize alternatives that balance cost, performance, and —for instance, FEA has been instrumental in refining bridge designs to withstand seismic loads, while CFD has been applied in simulations to optimize , such as reducing the of a simplified model from approximately 0.32 to 0.3038 through tweaks like adjusting the tail plate. In , supports lifecycle assessments that incorporate maintenance costs from the outset, ensuring long-term project viability. Overall, robust analytical practices underpin professional competence, enabling engineers to address complex challenges while upholding public safety and ethical standards. Tools for engineering analysis range from basic spreadsheets like for preliminary calculations to advanced (CAE) software such as for integrated simulations. These facilitate discrete system analysis via methods like the direct stiffness approach for spring-mass models and continuous system evaluation through variational formulations, addressing steady-state, propagation, and eigenvalue problems in structures. Adoption of such tools amplifies engineers' analytical skills, fostering innovation in fields from to biomedical applications.

Management and Specialization

Engineering management integrates technical expertise with and administrative skills to oversee engineering projects and teams. According to the American Society for Engineering Management (), it is defined as the art and of , organizing, allocating resources, and directing and controlling activities that involve technological components. This role bridges principles with business operations, ensuring that technical innovations align with organizational goals, budgets, and timelines. Engineering managers typically hold a in plus several years of professional experience, often supplemented by advanced in . Key responsibilities of engineering managers include directing the development of products, processes, or projects; making operational, financial, and personnel decisions; and supervising teams of engineers and technicians. They evaluate employee performance, hire and train staff, negotiate contracts with clients or suppliers, and ensure compliance with , , and regulatory standards. For instance, they coordinate multidisciplinary teams to resolve technical challenges while maintaining project scopes, often using tools like and methods to mitigate delays or cost overruns. In practice, these managers oversee the full project lifecycle, from initial planning and to execution and post-project evaluation, adapting to dynamic environments such as rapid technological advancements. Specializations within engineering management allow professionals to focus on specific industries or functions, enhancing their expertise in targeted areas. Common specializations include , where managers lead time-sensitive initiatives in or ; , emphasizing efficiency in or supply chains; and management, which involves implementing standards like ISO 9001 to ensure product reliability. Field-specific roles are also prevalent, such as managers who oversee projects, coordinating with regulatory bodies and stakeholders to meet environmental and requirements; managers directing and production of machinery; and managers handling systems integration in energy or sectors. These specializations often require domain-specific knowledge, with professionals advancing through certifications like the (PMP) or field-tailored credentials from bodies such as the (ASME). Emerging specializations, like those in sustainable engineering management, focus on integrating green technologies and principles into operations.

Classifications

Major Disciplines

Engineering encompasses several major disciplines, each specializing in the application of scientific and mathematical principles to practical problems in , , and . The foundational branches—civil, mechanical, electrical, and —form the core of the field, addressing , machinery, systems, and processes, respectively. These disciplines evolved from the and continue to drive technological advancement, with accreditation bodies like recognizing approximately 3,600 programs across them in the United States as of 2024. Other significant areas, such as computer and , have emerged as major fields in the modern era, reflecting interdisciplinary growth. Civil Engineering focuses on the planning, design, construction, and maintenance of infrastructure that supports society, including roads, bridges, , systems, and buildings. Civil engineers apply principles of physics, , and to ensure structures are safe, , and resilient to environmental challenges. Key subareas include , which analyzes load-bearing capacities for buildings and bridges; , dealing with soil and foundation stability; and , optimizing traffic flow and public transit systems. For instance, civil engineers contributed to iconic projects like the , demonstrating the discipline's role in large-scale water management and flood control. The field emphasizes , with professionals increasingly incorporating green materials and climate-resilient designs to address urban growth and environmental impacts. Mechanical Engineering involves the , analysis, , and maintenance of mechanical systems, from engines and turbines to and HVAC systems. Mechanical engineers use , , and to create efficient devices that convert into motion or force. This discipline spans industries like automotive, , and , where engineers optimize performance—for example, developing more fuel-efficient engines to reduce emissions. Core applications include systems for power and mechanical for consumer products like refrigerators and elevators. With a broad scope, mechanical engineering often intersects with other fields, such as , which integrates electronics for automated systems. The (ASME) highlights its role in solving diverse challenges, from technologies to advanced processes. Electrical Engineering centers on the study, design, and application of electrical systems, , and to power modern technology. Electrical engineers develop components like circuits, power grids, and communication networks, ensuring reliable energy distribution and . Subfields include , which manages generation and transmission for utilities; engineering, focusing on semiconductors and integrated circuits; and control systems, used in and . A seminal example is the development of the by engineers in 1947, which revolutionized and . The discipline underpins innovations like integration and wireless technologies, with professionals addressing challenges such as grid stability amid increasing . The Institute of Electrical and Electronics Engineers (IEEE) defines it as a field concerned with practical applications of , encompassing everything from microchips to large-scale power plants. Chemical Engineering applies chemistry, physics, , and to transform raw materials into valuable products through large-scale processes, such as refining or producing pharmaceuticals. Chemical engineers design and optimize reactors, columns, and separation systems to ensure efficient, safe production while minimizing waste and use. Key areas include for manufacturing fuels and plastics, for drug development, and for pollution control. For example, the Haber-Bosch process, engineered in the early , enabled industrial synthesis for fertilizers, profoundly impacting global . The (AIChE) emphasizes its problem-solving in , , and , with applications in biofuels and technologies. This discipline prioritizes safety protocols, as seen in standards for handling hazardous materials in refineries. Beyond these core areas, bridges hardware and software, designing processors and networks essential for systems, while optimizes complex processes for efficiency in manufacturing and logistics. specializes in aircraft and spacecraft design, and integrates biology with engineering for medical devices like prosthetics. These major disciplines collectively employ millions worldwide, with the U.S. projecting steady growth driven by needs and .

Emerging Fields

Emerging fields in are driven by rapid technological advancements, global challenges, and the integration of interdisciplinary approaches, reshaping traditional disciplines and creating new opportunities for innovation. According to projections from the U.S. , overall employment in and occupations is expected to grow faster than the average for all occupations from 2024 to 2034, with specific emerging areas like projected at 11% growth due to demands in and . These fields emphasize computational tools, ethical considerations, and real-world applications to address complex problems in health, , and . Artificial Intelligence (AI) and Machine Learning (ML) Engineering stands out as a pivotal emerging discipline, focusing on designing systems that learn from data to enable , autonomous decision-making, and optimization across industries. Vertical AI systems tailored to engineering domains incorporate specialized knowledge for applications such as structural analysis assistance, failure simulation, and building code compliance checking, outperforming general-purpose AI through domain-specific training and workflows. Engineers in this field develop algorithms for applications such as in and smart management, alongside AI-assisted engineering education via simulated design processes and adaptive learning tools. with the sector projected to grow by 40% by 2027 according to the World Economic Forum's Future of Jobs Report 2023. IEEE highlights AI's role in leveling the playing field through accessible large language models and domain-specific applications, impacting computer and by enhancing hardware-software integration for efficient deployment. Robotics and integrates mechanical, electrical, and software principles to create for tasks in , healthcare, and , emphasizing adaptability and human-robot collaboration. This field is advancing through AI-enhanced , where embodied allows machines to interact dynamically with environments using and IoT sensors, as noted in IEEE's 2025 technology predictions. Growth is fueled by demands for precision , with engineering identified as a high-demand area for sustainable production and . Sustainable and Green Engineering addresses environmental imperatives by incorporating , eco-friendly materials, and principles into and product design. Environmental engineers in this domain are projected to see 7% employment growth from 2024 to 2034, driven by needs in , , and climate adaptation. Key contributions include integrating solar and wind technologies into , with IEEE underscoring trends like extended-range electric vehicles and reactors as enablers for low-carbon energy transitions. Biomedical engineering, an established field at the intersection of and , is advancing with developments in wearable devices, tissue scaffolds, and diagnostic tools to improve healthcare outcomes. Advancements in biomarkers and miniaturized enable continuous monitoring of chronic conditions via AI-driven wearables, a trend IEEE predicts will commercialize in 2025 for . This field is expanding with for , supporting regenerative therapies and prosthetics that enhance patient mobility and . Quantum Engineering represents a frontier discipline harnessing for computing, sensing, and secure communications, promising exponential speedups in simulations for and . Engineers here design qubits and quantum algorithms, with applications in to protect against emerging cyber threats. As an nascent field, it builds on foundational work in superconducting circuits and , positioning it for high-impact growth in infrastructures. Other notable emerging areas include Internet of Things (IoT) Engineering, which enables interconnected ecosystems for smart cities and energy management through real-time data protocols, and Cybersecurity Engineering, focused on resilient networks amid rising digital vulnerabilities. These fields collectively underscore engineering's shift toward interdisciplinary, tech-enabled solutions that prioritize societal and environmental resilience.

Professional Standards

Ethics

Engineering ethics encompasses the moral principles and professional standards that guide engineers in their and practice, ensuring that their work benefits society while minimizing harm. These principles are codified in various professional codes developed by engineering societies, which emphasize responsibilities toward the public, employers, colleagues, and the profession itself. Central to engineering ethics is the obligation to prioritize public , , and welfare above all other considerations. A core tenet across major codes is the duty to hold paramount the safety, health, and welfare of the public in the performance of professional duties. For instance, the National Society of Professional Engineers (NSPE) Code of Ethics states that engineers shall notify appropriate authorities if they believe public safety is endangered by their work or that of others. Similarly, the American Society of Civil Engineers (ASCE) Code requires members to protect public health and safety by striving for sustainable development and mitigating adverse environmental impacts. The Institute of Electrical and Electronics Engineers (IEEE) Code reinforces this by mandating engineers to disclose factors that might endanger the public or environment. Internationally, the World Federation of Engineering Organizations (WFEO) Model Code of Ethics underscores protecting the natural and built environment through sustainable practices that consider economic, societal, and ecological effects. Another fundamental principle is practicing within one's competence and pursuing lifelong . Engineers are required to undertake only those tasks for which they are qualified and to enhance their knowledge continuously to maintain high standards. The NSPE Code explicitly prohibits engineers from offering services in areas outside their expertise without associating with qualified colleagues. The ASCE Code echoes this by mandating truthful representation of qualifications and rejection of projects beyond one's ability. and form additional pillars, requiring objective and truthful public statements, avoidance of conflicts of interest, and rejection of or . For example, IEEE members must provide honest criticism of technical work, acknowledge errors, and credit contributions appropriately. Ethical conduct also extends to relationships with employers, clients, and peers, demanding faithful agency, , and fair treatment. The WFEO Model promotes exercising to advance the profession and foster public understanding of issues, while treating all individuals with respect and avoiding . Violations of these principles can lead to sanctions, as enforced by bodies like state licensing boards or society ethics committees. Notable cases illustrate their importance; in the 1986 , engineers' warnings about failures were overridden, highlighting the ethical imperative to prioritize over schedule pressures. More recently, the 2023 raised questions about risk disclosure and competence in experimental deep-sea . These examples underscore how adherence to ethical codes safeguards and prevents catastrophic outcomes.

Regulation

Regulation of the engineering profession primarily serves to safeguard , safety, and welfare by verifying that practitioners possess the necessary competence to perform tasks that could impact , systems, and lives. This oversight is typically managed through licensing systems administered by national or jurisdictional boards, which mandate qualifications for independent practice, especially in areas like structural , utilities, and environmental systems. Unauthorized practice can result in legal penalties, underscoring the regulatory framework's role in preventing substandard work that might lead to failures or hazards. Core requirements for licensure generally include a from an accredited engineering program, a period of supervised professional experience, and successful completion of standardized examinations. For instance, many systems require four years of progressive experience under a licensed engineer, alongside exams assessing fundamental and discipline-specific principles. These elements ensure engineers can apply technical expertise ethically and responsibly, with ongoing continuing professional development often mandated to maintain licensure. Disciplinary mechanisms, including investigations into , further enforce compliance and . On an international level, agreements such as the Washington Accord facilitate mutual recognition of , promoting standardization and mobility across borders. Established in 1989 and now comprising 25 full signatories—including the , , , and —this accord benchmarks undergraduate programs against shared graduate attributes, such as problem-solving and ethical awareness. Complementing this, the International Professional Engineer Agreement sets a global competence standard, requiring at least seven years of experience (including two in responsible roles) and ethical accountability for the IntPE designation, recognized by participating bodies to ease cross-jurisdictional practice. These initiatives harmonize regulations without overriding local authority, addressing the profession's increasingly global nature.

Education and Training

Academic Pathways

Academic pathways for engineers generally commence during , where students build foundational skills in and sciences to prepare for rigorous university-level study. High school curricula should emphasize advanced , including , , , pre-calculus, and , alongside physics and chemistry to develop problem-solving and analytical abilities essential for disciplines. Participation in extracurricular activities, such as clubs or fairs, further enhances practical experience and demonstrates interest to college admissions committees. The core academic pathway involves earning a in , typically a four-year program accredited by bodies like to ensure alignment with professional standards. These programs require at least 30 semester hours of and basic sciences, plus 45 hours of topics, covering areas like , dynamics, , and projects. Disciplines include civil, mechanical, electrical, and , with curricula integrating theoretical coursework, laboratory experiments, and capstone projects to apply concepts to real-world problems. accreditation at the bachelor's level qualifies graduates for entry-level positions and eligibility for professional engineer licensure in the United States after passing the Fundamentals of Engineering exam and gaining work experience. For advanced roles, many engineers pursue graduate education, starting with a that builds on undergraduate foundations through specialized coursework and research. Master's programs, often one to two years, are available in fields like or biomedical engineering and may be ABET-accredited for post-graduate levels, focusing on advanced topics such as or . Doctoral programs (PhD), lasting three to five years, emphasize original research and are essential for academic or high-level research careers, culminating in a dissertation on innovative engineering solutions. Alternative pathways, such as accelerated 4+1 bachelor's-to-master's programs or co-operative education integrating work , allow students to gain practical skills while completing degrees.

Professional Certification

Professional certification in engineering serves as a formal validation of an engineer's qualifications, ensuring they possess the necessary , , and ethical competence to practice safely and effectively, particularly in roles impacting public welfare. These certifications, often in the form of licenses or registrations, are typically administered by national or international bodies and may be required by law for signing off on designs, overseeing projects, or providing expert testimony. The process generally includes accredited academic credentials, supervised work , rigorous examinations, and ongoing to maintain status. In the United States, the Professional Engineer (PE) license is the foremost certification, granted by state licensing boards under the oversight of the National Council of Examiners for Engineering and Surveying (NCEES). To obtain it, candidates must hold a from an ABET-accredited program, pass the Fundamentals of Engineering (FE) exam shortly after graduation to become an Engineer-in-Training (EIT), accumulate at least four years of progressive experience under a licensed PE, and pass the Principles and Practice of Engineering (PE) exam in their discipline. This licensure authorizes engineers to practice independently and is essential for civil, structural, and other public-facing engineering works. In the , the Chartered Engineer (CEng) designation, regulated by the , recognizes engineers capable of applying advanced knowledge to innovate and solve complex problems. Requirements include an accredited with honors in or , plus a master's-level qualification or equivalent further learning, combined with demonstration of competencies through work-based assessment by a licensed engineering institution. Candidates must exhibit technical , ethical commitment, and at least four years of relevant experience, often culminating in a professional review interview. CEng status enhances career prospects and is protected by UK law. For international mobility, the International Professional Engineer (IntPE) certification, established under the International Professional Engineers Agreement and administered by bodies like the and the (IET), allows qualified engineers from participating countries to gain mutual recognition. It targets Chartered Engineers or equivalents with an accredited degree, seven years of post-graduation experience (including two years in significant engineering responsibility), and adherence to continuing (CPD). IntPE facilitates easier access to professional registers in countries such as , , the , and the , promoting global practice without redundant assessments. Within Europe, the (EUR ING) title, managed by ENGINEERS EUROPE and recognized by the , certifies mobility and competence across member states. Eligibility requires registration as a Chartered or Incorporated Engineer with a UK institution, or equivalent, plus seven years of combined education, training, and experience, with applications involving a detailed portfolio review by the European Monitoring Committee. Renewal every five years mandates proof of CPD, ensuring sustained expertise in a harmonized framework. This certification supports cross-border projects under EU directives on professional qualifications. Beyond these, discipline-specific certifications abound, such as the Systems Engineering Professional (SEP) from the (INCOSE), which offers levels like Associate, Certified, and Expert based on knowledge exams and experience verification, or quality-focused credentials like the Certified Reliability Engineer (CRE) from the (ASQ). These voluntary programs emphasize specialized skills but often complement core licensure. Overall, engineering certifications evolve with technological advances, prioritizing public protection and professional accountability across jurisdictions.

Regulation by Region

Asia and Africa

In Asia, the regulation of the engineering profession varies significantly across countries, with some implementing mandatory licensing through statutory bodies while others rely on voluntary certifications and professional associations. Regional agreements facilitate cross-border recognition to promote mobility and harmonization. The ASEAN Mutual Recognition Arrangement on Engineering Services (MRA), signed in 2005 by Brunei Darussalam, Cambodia, Indonesia, Lao PDR, Malaysia, Myanmar, Philippines, Singapore, Thailand, and Viet Nam, allows qualified engineers to register as ASEAN Chartered Professional Engineers (ACPE) after meeting criteria such as an accredited engineering degree, at least seven years of post-graduation experience (including two years in responsible charge), valid home-country registration, continuing professional development (CPD), and adherence to ethical standards. This arrangement is overseen by national professional regulatory authorities (PRAs), such as the Board of Engineers Malaysia and the Professional Engineers Board Singapore, and aims to liberalize engineering services within the region while maintaining quality. Complementing ASEAN efforts, the APEC Engineer Register, established under the framework, recognizes professional engineers from 14 participating economies (including , , , and ) and three provisional members, ensuring substantial equivalence in competencies for easier mobility and reduced re-assessment for local registration. In countries with mandatory regulation, such as , the Professional Engineers Act 1991 requires registration with the Professional Engineers Board (PEB) for practicing as a engineer, including qualifications like an accredited degree, relevant experience, and passing examinations, with practicing certificates renewed annually through CPD. Similarly, Japan's Professional Engineer Act of 1974 mandates certification as a Professional Engineer Japan (P.E.Jp) for engineers involved in technical consultations or supervision in fields like civil, mechanical, and , requiring an accredited , practical experience, and passing a national examination administered by the Institution of Professional Engineers, Japan (IPEJ). In contrast, regulation in larger economies like and is less centralized and often voluntary. In , there is no mandatory national licensing for engineering practice; instead, professionals may obtain voluntary certifications such as Chartered Engineer status from the (IEI) or registration with the Engineering Council of India (ECI), which requires a recognized and at least five years of experience, but these are not prerequisites for employment or signing documents. Efforts to introduce mandatory regulation, such as the proposed Professional Engineers Bill 2025, aim to create a national register and oversight body, but as of 2025, practice remains unregulated statutorily. In , engineering practice lacks a mandatory personal licensing system akin to those in Western countries; oversight occurs through national standards (GB standards), which are mandatory for certain products and processes, and voluntary professional associations like the China Association for Science and Technology, with recent focus on doctoral-level rather than practitioner regulation. In Africa, engineering regulation is generally more formalized through statutory councils that mandate registration for professional practice, emphasizing public safety and competency in infrastructure-heavy economies. The Engineering Council of South Africa (ECSA), established under the Engineering Profession Act 46 of 2000, serves as the sole statutory regulator, requiring registration as a Professional Engineer (Pr Eng) for categories involving public interest work, with criteria including an accredited degree, four years of supervised experience, and a professional review; ECSA also accredits programs, enforces a code of conduct via disciplinary processes, and mandates CPD for registration renewal. Similarly, in Nigeria, the Council for the Regulation of Engineering in Nigeria (COREN), created by Decree 55 of 1970 (amended in 1992 and 2018), holds exclusive authority to regulate the profession, mandating registration for all practicing engineers and firms, accreditation of educational programs, and enforcement through monitoring committees and a code of ethics aligned with World Federation of Engineering Organizations standards. Regional cooperation in Africa includes mutual recognition agreements among East African countries, such as the 2015 pact between the Engineering Regulation Boards of , , and , which allows accredited programs in one country to be recognized in the others, facilitating cross-border practice while upholding standards. Across the continent, at least 17 countries, including , , and , have established regulatory bodies like engineering councils or boards to oversee registration, ethical compliance, and CPD, though implementation varies, with stronger enforcement in southern and eastern compared to some West African nations. These frameworks prioritize transforming and practice to address challenges, as highlighted in reports calling for enhanced to support .

Europe

In Europe, the regulation of engineering primarily operates through a combination of -wide harmonization for qualification recognition and national systems that vary in stringency, often focusing on title protection rather than mandatory licensing for general practice. Directive 2005/36/EC, as amended by Directive 2013/55/, governs the mutual recognition of professional qualifications across member states and EEA countries, placing engineering under the general system of recognition. This requires host countries to assess the equivalence of an engineer's , , and from another member state, potentially involving compensatory measures like tests or periods if substantial differences exist, thereby enabling cross-border mobility without automatic licensing equivalence. At the pan-European level, ENGINEERS EUROPE (formerly the European Federation of National Engineering Associations, or FEANI), a federation representing national engineering bodies from 33 countries in the , promotes self-regulation through the EUR ING certificate. Awarded since 1989, this title guarantees an engineer's competence and facilitates professional mobility by signaling alignment with European standards for education, experience, and ethics. Eligibility requires an accredited engineering qualification at levels 6 or 7 (bachelor's or master's equivalent), 2–7 years of relevant professional experience depending on the qualification level, adherence to ENGINEERS EUROPE's , and renewal every five years with proof of continuous (CPD) since 2023. As of January 2023, the register lists over 35,000 EUR ING holders, recognized by the as a tool to minimize adaptation requirements under EU directives. Complementing this, the European Network for Accreditation of Engineering Education (ENAEE), established in 2006, ensures educational quality by authorizing independent agencies to award the EUR-ACE® label to bachelor's and master's programs that meet rigorous standards for learning outcomes, , and resources. With 20 full members and 8 associates as of 2023, ENAEE's framework supports professional regulation by aligning academic preparation with industry needs and facilitating qualification recognition across borders, though it does not directly license practitioners. National regulations in emphasize title protection and sector-specific requirements over universal licensing, with practice often unrestricted except for reserved activities like public infrastructure design or safety-critical certifications. In the , the serves as the regulatory authority, maintaining a national register under the Engineering Council's Standards (UK-SPEC, fourth edition 2023) for titles such as Chartered Engineer (CEng), which demands a master's-level qualification, 4+ years of integrated experience, and commitment to ethical practice; Incorporated Engineer (IEng); and (EngTech). Registration is voluntary but protects titles and is often required for senior roles or public accountability, with over 230,000 registrants as of 2023; post-Brexit, UK engineers access markets as third-country nationals, relying on bilateral agreements or the EUR ING for mobility. In , engineering is unregulated for practice, with no mandatory licensing, registration, or central body overseeing general work; however, the title "Ingenieur" is legally protected under state laws (e.g., Baden-Württemberg's Ingenieurgesetz), requiring a recognized degree (typically Dipl.-Ing. or master's) for its use. Foreign qualifications undergo equivalence assessment by bodies like the Central Office for Foreign Education (ZAB), but no professional exam or CPD is enforced, allowing flexibility while relying on employer standards and recognition for mobility. France similarly lacks regulation for engineering practice, with no compulsory registration or licensing body, but the title "Ingénieur" is strictly protected and conferred only upon graduation from one of approximately 200 programs accredited by the Commission des Titres d'Ingénieur (CTI), an independent public authority evaluating curricula for alignment with national standards. The CTI also assesses foreign degrees for title equivalence under directives, emphasizing a five-year integrated master's-level formation; professional associations like the Conférence des Grandes Écoles provide voluntary certification, but reserved activities (e.g., nuclear or signing) may require additional sectoral approvals. In , engineering is a regulated under Legislative 206/2007 implementing Directive 2005/36/EC, requiring enrollment in the National Register of Engineers (Albo Professionale) managed by the Consiglio Nazionale degli Ingegneri (CNI) after passing a state exam on technical and legal . The register divides into sections A (senior engineers with master's degrees) and B (junior engineers with bachelor's), with mandatory and CPD; practice without registration is prohibited for , and foreign engineers benefit from automatic title recognition if equivalent. Spain's system varies by engineering branch, with general practice unregulated but titles like "Ingeniero Técnico" or "Ingeniero Superior" protected by law (e.g., Law 12/1986 for technical engineers). Civil engineering falls under the Ministry of Transport, Mobility and Urban Agenda, requiring registration with professional colleges (e.g., Colegio de Ingenieros de Caminos) for signing ; voluntary as a Professional Engineer (Ingeniero Profesional) is offered by bodies like the Asociación de Ingenieros Profesionales de España (AIPE), accredited by the Spanish National Accreditation Entity (ENAC), involving and CPD to meet ISO 17024 standards. EU mobility is supported, but non-EU qualifications need ministerial approval. Overall, European regulation prioritizes educational accreditation and ethical standards over prescriptive licensing, with reserved activities (e.g., structural calculations in ) often mandating qualified professionals across countries to ensure public safety, as evaluated in the European Commission's 2015 mutual assessment of regulated professions.

In , the regulation of the engineering profession varies by country, with the and employing mandatory licensure systems enforced at subnational levels, while focuses on degree registration and voluntary rather than compulsory licensing for practice. In the United States, engineering is regulated at the state level through 55 licensing boards, which require licensure for engineers offering services to the public in areas such as , , and oversight. The National Council of Examiners for Engineering and Surveying (NCEES) coordinates the process by developing and administering examinations, including the Fundamentals of Engineering (FE) exam for entry-level candidates and the Principles and Practice of Engineering (PE) exam for full licensure. To obtain a Professional Engineer (PE) license, candidates typically need an accredited from a program recognized by , at least four years of progressive experience under a licensed engineer, and passing scores on both exams; some states also require for renewal. The National Society of Professional Engineers (NSPE) advocates for this model, emphasizing that licensure ensures public safety by holding engineers accountable for their work through seals or stamps on technical documents. Unlicensed practice can result in civil penalties, fines, or criminal charges, depending on the state. Canada regulates engineering provincially and territorially through 12 self-governing bodies coordinated by Engineers Canada, making licensure mandatory to use the title "Professional Engineer" (P.Eng.) or practice independently. Applicants must hold an accredited degree, pass national exams (including the Professional Practice Examination on and law), and complete supervised experience, often four years, before full licensing; Engineer-in-Training (EIT) status serves as an interim step. These regulators enforce standards via codes of , disciplinary actions, and mandatory , with interprovincial mobility facilitated through mutual recognition agreements. For example, , under the Professional Engineers Act, sets performance standards and investigates complaints to protect public welfare. In , engineering lacks a centralized mandatory licensure system akin to the PE or P.Eng.; instead, the profession is governed by the Ley Reglamentaria del Artículo 5° Constitucional, which requires registration of the title (cédula profesional) with the Secretaría de Educación Pública (SEP) to legally exercise the profession. The Dirección General de Profesiones (DGP) under SEP oversees this process, validating degrees and collaborating with associations for voluntary certification programs that assess competencies and . Foreign engineers must revalidate their credentials through SEP, and practice often requires co-signing by a Mexican-registered , particularly for public or regulated projects. Associations like the Colegio de Ingenieros Civiles de México provide ethical guidelines, but enforcement is less prescriptive than in the U.S. or , focusing on over ongoing licensure.

Latin America

In , the regulation of the is decentralized and varies significantly by country, typically involving mandatory or voluntary registration with professional councils or government bodies to ensure ethical practice, competency, and public . These systems often require a recognized degree, examinations, and ongoing , with engineers needing to register to sign technical documents, oversee projects, or offer services legally. Regional efforts, such as those by the Pan-American Union of Engineering Societies (UPADI), promote of standards, but no unified licensing framework exists across the continent. In , the is strictly regulated by the Federal Council of Engineering and (CONFEA) and its affiliated Regional Councils (CREAs), established under Decree-Law No. 23,569 of 1933. All engineers, agronomists, and related professionals must register with the CREA in their state of practice to legally exercise their , including responsibilities like project supervision and technical endorsements. Registration requires an accredited degree, proof of ethical conduct, and payment of annual fees, with CREAs enforcing compliance through inspections and disciplinary actions. This system covers over 1.5 million professionals and emphasizes public welfare in and industrial sectors. Mexico mandates a federal professional license, known as the Cédula Profesional, issued by the Secretariat of Public Education (SEP) for engineers to practice legally. To obtain it, candidates must complete a bachelor's degree in engineering from an accredited institution, submit a thesis or pass an exit examination, and register with the Public Registry of Professional Degrees. The cédula, which is lifelong but requires renewal of credentials for certain activities, ensures professionals meet national standards and is essential for roles in public works, consulting, or signing designs. Foreign engineers must validate their credentials through SEP, often involving equivalence exams. In , regulation occurs at provincial and national levels through professional matriculation systems managed by councils like the Professional Council of Mechanical Engineering (COPIME) or the Professional Council of (CPIC). Engineers must enroll in these bodies to obtain a matrícula, which authorizes them to practice, stamp documents, and assume liability for projects; requirements include a validated degree, ethical oath, and fees. For instance, mechanical engineers register with COPIME for permanent matricula after degree legalization by the Ministry of Education. This structure supports accountability in key sectors like and , with over 100,000 registered professionals nationwide. Other countries exhibit similar patterns with local adaptations. In , while general practice does not require mandatory licensing, affiliation with the College of Engineers of Chile (Colegio de Ingenieros) is common for professional recognition, and specific fields like or demand certified expertise through registries or university-validated titles. Colombia and Central American nations, including Guatemala and , are pursuing mutual recognition agreements to facilitate cross-border mobility, building on bilateral pacts with that standardize certification criteria like experience verification and exams. In Guatemala, the Día Nacional del Profesional de la Ingeniería (also known as Día del Ingeniero) is celebrated on January 30 each year, established officially by Acuerdo Gubernativo 36-2014. This day recognizes the contributions of engineers to the development of the country and grants paid leave to professionals affiliated with the Colegio de Ingenieros de Guatemala who labor in public institutions. These initiatives aim to align Latin American practices with international norms, enhancing .

References

  1. https://www.mtu.edu/engineering/about/engineers/
  2. https://www.nae.edu/221278/Presidents-Perspective-What-Is-Engineering
  3. https://www.snhu.edu/about-us/newsroom/stem/what-is-engineering
  4. https://engines.egr.uh.edu/episode/12
  5. https://www.bls.gov/ooh/architecture-and-engineering/
  6. https://www.nu.edu/blog/types-of-engineering/
  7. https://peer.asee.org/challenges-of-creating-a-new-engineering-education-model-in-russia.pdf
  8. https://www.nspe.org/about/about-professional-engineering/what-pe
  9. https://www.ck12.org/section/engineering-in-ancient-civilizations/
  10. https://www.bls.gov/news.release/ocwage.nr0.htm
  11. https://pressbooks.bccampus.ca/engineeringinsociety/chapter/chapter-1/
  12. https://www.britannica.com/topic/Pyramids-of-Giza
  13. https://www.nature.com/articles/s41597-025-06140-z
  14. https://dr.lib.iastate.edu/bitstreams/fd1fb74f-f6e9-48ab-8bed-d53af915ff42/download
  15. https://www.nber.org/digest/202205/engineers-and-industrial-revolution-19th-century-britain
  16. https://www.nspe.org/about/about-professional-engineering/the-history-the-professional-engineer
  17. https://www.abet.org/wp-content/uploads/2023/05/2024-2025_EAC_Criteria.pdf
  18. https://www.energy.gov/eere/wind/career-map-design-engineer
  19. https://www.sciencebuddies.org/science-fair-projects/engineering-design-process/engineering-design-process-steps
  20. https://pmc.ncbi.nlm.nih.gov/articles/PMC10889891/
  21. https://asmedigitalcollection.asme.org/mechanicaldesign/article/133/7/070301/467008/Engineering-Design-A-Foundation-for-a-21st-Century
  22. https://www.sciencedirect.com/topics/engineering/engineering-analysis
  23. https://ocw.mit.edu/courses/res-2-002-finite-element-procedures-for-solids-and-structures-spring-2010/resources/lecture-1/
  24. https://www.nspe.org/sites/default/files/resources/nspe-body-of-knowledge.pdf
  25. https://www.nspe.org/career-growth/pe-magazine/january-2014/what-makes-pe
  26. https://innovationatwork.ieee.org/are-you-shoring-up-your-business-engineering-skills/
  27. https://asem.org/About
  28. https://www.bls.gov/ooh/management/architectural-and-engineering-managers.htm
  29. https://engineering.rice.edu/academics/graduate-programs/online-meml/blog/what-does-an-engineering-manager-do
  30. https://ep.jhu.edu/news/9-engineering-management-career-paths/
  31. https://www.coursera.org/articles/engineering-management-degree
  32. https://pg-online.leeds.ac.uk/blogs/roles-available-engineers-progressing-into-management/
  33. https://www.road2college.com/abet-accredited-schools/
  34. https://www.bls.gov/ooh/architecture-and-engineering/civil-engineers.htm
  35. https://www.asce.org/career-growth/pre-college-outreach/kids-and-teens
  36. https://www.bls.gov/ooh/architecture-and-engineering/mechanical-engineers.htm
  37. https://asmedigitalcollection.asme.org/memagazineselect/article/146/4/1/1201863/What-is-Mechanical-Engineering-In-a-World-of
  38. https://www.bls.gov/ooh/architecture-and-engineering/electrical-and-electronics-engineers.htm
  39. https://tryengineeringinstitute.ieee.org/what-is-electrical-engineering/
  40. https://www.bls.gov/ooh/architecture-and-engineering/chemical-engineers.htm
  41. https://www.aiche.org/sites/default/files/community/186226/aiche-community-site-page/190376/whatische.pdf
  42. https://www.mtu.edu/engineering/about/types/
  43. https://www.bls.gov/ooh/architecture-and-engineering/industrial-engineers.htm
  44. https://www.ibm.com/think/topics/vertical-ai-agents
  45. https://www.sciencedirect.com/science/article/pii/S0926580525005369
  46. https://www.engineering.columbia.edu/about/news/ai-enhanced-education
  47. https://www.weforum.org/publications/the-future-of-jobs-report-2023/
  48. https://research.com/degrees/most-in-demand-engineering-degrees
  49. https://www.ieee.org/about/news/2025/ieee-reveals-predictions-for-top-technology-trends-of-2025
  50. https://acarasolutions.com/guides/engineering-technology-salary-guide/
  51. https://innovate.ieee.org/top-tech-2025/
  52. https://www.nspe.org/sites/default/files/resources/pdfs/Ethics/CodeofEthics/NSPECodeofEthicsforEngineers.pdf
  53. https://www.asce.org/-/media/asce-images-and-files/career-and-growth/ethics/documents/asce-code-ethics.pdf
  54. https://www.wfeo.org/wp-content/uploads/code_of_ethics/WFEO_MODEL_CODE_OF_ETHICS.pdf
  55. https://www.ieee.org/about/corporate/governance/p7-8
  56. https://online-engineering.case.edu/blog/two-historic-failures-of-ethics-in-engineering
  57. https://ncees.org/licensure/why-licensure-matters/
  58. https://www.nspe.org/about/about-professional-engineering/how-get-licensed
  59. https://www.automate.org/news/the-role-and-importance-of-engineering-regulatory-organizations-in-ensuring-public-health-and-safety
  60. https://ncees.org/licensure/
  61. https://www.internationalengineeringalliance.org/documents-public/ipea
  62. https://www.internationalengineeringalliance.org/accords/washington-accord
  63. https://www.engineering.cornell.edu/admissions/how-to-prepare-in-high-school/
  64. https://engineering.princeton.edu/undergraduate-studies/admission-and-tours/high-school-guidance
  65. https://www.abet.org/accreditation/accreditation-criteria/criteria-for-accrediting-engineering-programs-2025-2026/
  66. https://www.abet.org/accreditation/what-is-accreditation/what-programs-does-abet-accredit/
  67. https://online-engineering.case.edu/blog/how-to-become-an-engineer
  68. https://www.engc.org.uk/professional-registration/our-professional-titles/chartered-engineer-ceng/
  69. https://www.theiet.org/career/professional-registration/international-professional-registration/international-professional-engineer
  70. https://www.engc.org.uk/international-recognition/recognition-in-europe/engineers-europe/european-engineer-eur-ing-registration/
  71. https://www.incose.org/certification
  72. https://www.asq.org/cert/catalog/engineering
  73. https://asean.org/wp-content/uploads/2023/06/20150119180933.pdf
  74. https://www.internationalengineeringalliance.org/agreements/apec
  75. https://www1.peb.gov.sg/act-and-rules/
  76. https://www.japaneselawtranslation.go.jp/en/laws/view/3792
  77. https://www.engineer.or.jp/sub09/
  78. https://www.ieindia.org/webui/IEI_PE_Certification.aspx
  79. https://www.thebridgechronicle.com/news/indian-professional-engineers-council-new-apex-body-to-regulate-engineering-professionals
  80. https://amiestudycircle.com/highlights-professional-engineers-bill.html
  81. https://www.standardsportal.org/usa_en/prc_standards_system/standards_used_in_china.aspx
  82. https://english.www.gov.cn/news/202410/30/content_WS6722244fc6d0868f4e8ec736.html
  83. https://www.gov.za/documents/acts/engineering-profession-act-46-2000-01-dec-2000
  84. https://www.ecsa.co.za/about-ecsa/
  85. https://coren.gov.ng/
  86. https://coren.gov.ng/engineering-regulations-and-monitoring/code-and-standards-documentation/
  87. https://documents.worldbank.org/curated/en/773831468007776683/pdf/860620BRI0WB0H00Box382147B00PUBLIC0.pdf
  88. https://m.facebook.com/SLIE.PERC.1990/videos/perc-act-engineering-regulation-in-africaacross-various-jurisdictions-globally-i/839319640925380/
  89. https://raeng.org.uk/media/rz0gr5xb/engineers-for-africa-2025-report.pdf
  90. https://single-market-economy.ec.europa.eu/single-market/services/free-movement-professionals/recognition-professional-qualifications-practice_en
  91. https://www.engineerseurope.com/what-eur-ing-certificate
  92. https://www.enaee.eu/
  93. https://www.engc.org.uk/our-role-as-regulator/setting-standards/
  94. https://www.engc.org.uk/our-role-as-regulator/setting-standards/professional-engineering-competence-and-commitment/
  95. https://www.engc.org.uk/international-recognition/recognition-in-europe/
  96. https://open.alberta.ca/dataset/c86ff520-0e1c-4495-9951-acdb1313fefb/resource/9d1c5a95-e3ee-47ce-b76a-2b017ad1d4e6/download/2012-hiring-engineers-from-germany-august-2016.pdf
  97. https://www.anerkennung-in-deutschland.de/html/en/2722.php
  98. https://www.cti-commission.fr/en/la-cti/histoire-et-missions
  99. https://www.cti-commission.fr/en/documents-de-reference/procedures/admission-par-letat
  100. https://www.cni.it/en/foreign-titles-recognition
  101. https://www.cni.it/images/ESTERI/_the_Italian_professional_enrollment_system_CNI.pdf
  102. https://ec.europa.eu/growth/tools-databases/regprof/professions/bycountry/regprof/482
  103. https://www.ingenierosprofesionales.com/en/aipe-2/
  104. https://ec.europa.eu/docsroom/documents/12762/attachments/1/translations/en/renditions/native
  105. https://engineerscanada.ca/become-an-engineer/overview-of-licensing-process
  106. https://www.trade.gov/country-commercial-guides/mexico-licensing-requirements-professional-services
  107. https://www.abet.org/accreditation/what-is-accreditation/licensure-registration-certification/
  108. https://www.nspe.org/nspe-advocacy/explore-issues/professional-policies-and-position-statements/regulation-professional
  109. https://engineerscanada.ca/regulatory-excellence/national-engineering-guidelines
  110. https://www.peo.on.ca/about-peo/what-is-peo/acts-regulations-and-laws
  111. https://www.gob.mx/sep/acciones-y-programas/direccion-general-de-profesiones-certificacion-profesional
  112. https://upadi.com/wp-content/uploads/2019/10/STATUTE-Amended-2018-eng.pdf
  113. https://www.lexology.com/library/detail.aspx?g=a6a3ee82-5406-4e23-989a-3735a4089e4e
  114. https://www.gob.mx/cedulaprofesional
  115. https://copime.org.ar/pages/detail/567
  116. https://cpic.org.ar/requisitos-de-matriculacion/
  117. https://www.ingenieros.cl/requisitos/
  118. https://www.researchgate.net/profile/Oscar-Vasquez-Bernal/publication/252047477_Unification_certification_criteria_for_professional_engineers_case_study_in_Colombia_United_States_Canada_Guatemala_Honduras_El_Salvador/links/00b495228a1d3030f6000000/Unification-certification-criteria-for-professional-engineers-case-study-in-Colombia-United-States-Canada-Guatemala-Honduras-El-Salvador.pdf
  119. https://leyes.infile.com/index.php?id=182&id_publicacion=69366
  120. https://www.congreso.gob.gt/noticias_congreso/9197/2022/3
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