List of engineering branches explained

Engineering is the discipline and profession that applies scientific theories, mathematical methods, and empirical evidence to design, create, and analyze technological solutions cognizant of safety, human factors, physical laws, regulations, practicality, and cost. In the contemporary era, engineering is generally considered to consist of the major primary branches of chemical engineering, civil engineering, electrical engineering, and mechanical engineering.[1] There are numerous other engineering sub-disciplines and interdisciplinary subjects that may or may not be part of these major engineering branches.

Chemical engineering

Chemical engineering is the application of chemical, physical, and biological sciences to the process of converting raw materials or chemicals into more useful or valuable forms.

SubdisciplineScopeMajor specialties
The application of engineering principles to study and manipulate biological systems at the molecular level.
Materials engineeringThe selection, synthesis, and design of materials used in chemical processes and the study of properties of various materials and their interactions with different chemicals.
Process engineeringFocuses on the design, operation, control, and optimization of chemical processes, including natural and man-made materials, the interaction of materials with machines, safety and health, energy conservation, and waste and pollution control.

Civil engineering

Civil engineering comprises the design, construction, and maintenance of the physical and natural built environments.

SubdisciplineScopeMajor specialties
Environmental engineeringThe application of engineering to the improvement and protection of the environment.
Municipal or urban engineeringDeals with municipal issues such as water and waste management, transportation networks, subdivisions, communications, hydrology, hydraulics, etc.
Geotechnical engineeringConcerned with the behavior of earth materials and soil and rock mechanics at the site of a civil engineering project.
  • Mining engineering involves the science, technology, and practice of extracting and processing minerals from a naturally occurring environment
Structural engineeringThe engineering of structures that support or resist structural loads.
Transport engineeringThe use of engineering to ensure the safe and efficient transportation of people and goods.
  • Traffic engineering, a branch of transportation engineering focusing on the infrastructure necessary for transportation
  • Highway engineering, a branch of engineering that deals with major roadways and transportation systems involving automobiles
  • Highway engineering usually involves the construction and design of highways
  • Railway engineering, a branch of engineering that deals with major railways and transportation systems involving trains
Water resources engineeringPrediction, planning, development, and management of water resources.
  • Hydraulic engineering, concerned with the flow and conveyance of fluids, principally water; intimately related to the design of pipelines, water supply networks, drainage facilities (including bridges, dams, levees, channels, culverts, storm sewers) and canals
  • River engineering, is the process of planned human intervention in the course, characteristics, or flow of a river with the intention of producing some defined benefit—to manage the water resources, to protect against flooding, or to make passage along or across rivers easier
  • Coastal engineering, the study of the processes ongoing at the shoreline and construction within the coastal zone, often directed at combating erosion of coasts or providing navigational access
  • Groundwater engineering, involves the analysis, monitoring and often modeling of groundwater sources to better understand how much remains and if the water can be used for e.g. recharging reservoirs and irrigation

Electrical engineering

Electrical engineering comprises the study and application of electricity, electronics and electromagnetism.

SubdisciplineScopeMajor specialties
Electronic engineeringDesign and manufacture of devices related to low-power electrical circuits (electronic circuits) making use of active components such as semiconductor devices.
Computer engineeringThe design and control of computing devices with the application of electrical systems. It involves the study of hardware and software systems that can process information, as well as digital logic design, computer architecture, and programming languages.
  • Software engineering, the application of a systematic, disciplined, quantifiable approach to the development, operation, and maintenance of software and the study of these approaches; that is, the application of engineering and computer science to software[2]
  • Hardware engineering, designing, developing, and testing various computer equipment. Can range from circuit boards and microprocessors to routers
  • Network engineering, designing, deploying, and maintaining computer networks, such as corporate networks or the Internet
Power engineeringThe generation, transmission, and distribution of electricity and the design and maintenance of devices such as transformers, switchgear, electric generators, electric motors, high-voltage engineering, and power electronics.
  • Power system planning, involves the modelling of power systems to analyse the management of current and future electricity demand
  • Power system design, the development of a specific solution to address a power need, such as a new substation, a new power line, power system protection and so on
  • Power system operations and control, involves plant and system operation, where protocols for the safe and continuous operation of individual equipment, subsystems, power plants, or the whole power system are developed and applied
  • Protection and control, involves the design of power system protection, measurements, metering, telecommunications, and so on
  • High voltage engineering, involves the understanding of electromagnetic phenomena of large voltages and currents (such as partial discharge), as applied to the holistic power system design and its components, such as transformers, electric motors, electric generators, switchgear, to create coordination and harmony
Optical engineeringThe design of instruments and systems that utilize the properties of electromagnetic radiation.
Renewable energy engineering The design and maintenance of renewable energy devices such as those involved in solar, wind, and hydroelectric power.

Mechanical engineering

Mechanical engineering comprises the design and analysis of heat and mechanical power for the operation of machines and mechanical systems.[3]

SubdisciplineScopeMajor specialties
Acoustics engineeringConcerns the manipulation and control of vibration, especially vibration isolation and the reduction of unwanted sounds.
Manufacturing engineeringConcerns dealing with different manufacturing practices and the research and development of systems, processes, machines, tools and equipment.
Optomechanical engineeringField-specific to the mechanical aspects of optical systems. Includes design, packaging, mounting and alignment mechanisms specific to optical systems.[4]
Thermal engineeringConcerns heating or cooling of processes, equipment, or enclosed environments.
Sports engineeringIs a field of engineering that involves the design, development, and testing of sports equipment. The equipment used by athletes has always gone through technological design and development based on current knowledge and understanding.
Vehicle engineeringThe design, manufacture, and operation of the systems and equipment that propel and control vehicles.
Power plant engineeringField of engineering that designs, constructs, and maintains different types of power plants. Serves as the prime mover to produce electricity.
Industrial plant engineeringField of engineering that designs, constructs, and maintains different types of Industrial Machines and Equipment.
Energy engineeringEnergy efficiency, energy services, facility management, plant engineering, environmental compliance, and energy production. Energy efficiency of buildings and manufacturing processes, employing advances in lighting, insulation, and heating/cooling properties.

Interdisciplinary

DisciplineScopeMajor specialties
Agricultural engineeringFarm power and machinery, biological material processes, bioenergy, farm structures, and agricultural natural resources.
Applied engineeringSystems integration, manufacturing and management.[5]
Biomedical engineering, Biomedical nanoengineeringMedicine and healthcare biology, biocompatible prostheses, diagnostic and therapeutic devices ranging from clinical equipment to micro-implants, imaging equipment such as MRIs and EEGs, tissue regeneration, and pharmaceuticals. The increased utilization of nanotechnology across the existing areas of this branch has led to the specialization Biomedical nanoengineering.
Biological engineeringThe application of principles of biology and the tools of engineering to create usable, tangible, economically viable products.
Building services engineeringThe design, installation, operation, and monitoring of the technical services in buildings in order to ensure the safe, comfortable, and environmentally friendly operation.
Energy engineeringEnergy efficiency, energy services, facility management, plant engineering, environmental compliance and energy production. Energy efficiency of buildings and manufacturing processes, employing advances in lighting, insulation and heating/cooling properties.
Geological engineeringA discipline of engineering concerned with the application of geological science and engineering principles to fields, such as civil engineering, mining, environmental engineering, and forestry, among others. The work of geological engineers often directs or supports the work of other engineering disciplines such as assessing the suitability of locations for civil engineering, environmental engineering, mining operations, and oil and gas projects by conducting geological, geoenvironmental, geophysical, and geotechnical studies.
  • Geophysical engineering
  • Geoenvironmental and hydrogeological engineering
  • Geotechnical and rock engineering
  • Mineral and energy resource exploration engineering
Geomatics engineeringThe design, development, and operation of systems for collecting and analyzing spatial information about the land, the oceans, natural resources, and manmade features.
Information engineeringGeneration, distribution, analysis, and use of information, data and knowledge in systems.
Industrial engineeringLogistical and resource management systemsManufacturing engineering, tools, equipment, and processes
Legal engineeringApplication of scientific approach and knowledge to solving legal problems.
Mechatronics engineeringMechanical and electrical engineering hybridRobotics and Automation
Management of engineers and engineering processes
Military engineeringMilitary weapons and vehicles, such as artillery and tanks
Mining engineeringAn engineering discipline that involves the science, technology, and practice of extracting and processing minerals from a naturally occurring environment.
NanoengineeringThe introduction of nanotechnology into existing fields of engineering.
Quantum engineeringThe application of quantum theory to the design of materials and devices. Now gaining recognition as its own branch of engineering, but more traditionally associated with sub-disciplines of electrical and computer engineering, communications engineering, solid-state and semiconductor materials engineering, optical engineering and engineering physics.
Nuclear engineeringTerrestrial and marine nuclear power plants
Petroleum engineeringA field of engineering concerned with the activities related to the production of Hydrocarbons, which can be either crude oil or natural gas. Petroleum engineers focus on studying subsurface formation properties and design and selection of equipment to maximize economic recovery of hydrocarbons from subsurface reservoirs. Petroleum geology and geophysics focus on the provision of a static description of the hydrocarbon reservoir rock, while petroleum engineering focuses on estimation of the recoverable volume of this resource using a detailed understanding of the physical behavior of oil, water, and gas within porous rock at very high pressure.
Project engineeringProject engineering includes all parts of the design of manufacturing or processing facilities, either new or modifications to and expansions of existing facilities. A "project" consists of a coordinated series of activities or tasks performed by engineers and designers. A small project may be under the direction of a project engineer. Large projects are typically under the direction of a project manager or management team. Project tasks typically consist of such things as performing calculations, writing specifications, preparing bids, reviewing equipment proposals and evaluating or selecting equipment, and developing and maintaining various lists (equipment and materials lists) and drawings (electrical, instrument, and piping schematics, physical layouts and other drawings used in construction). Some facilities have in-house staff to handle small projects, while some major companies have a department that does internal project engineering. Large projects are typically contracted out to project engineering companies. Staffing at engineering companies varies according to the workload and duration of employment may only last until an individual's tasks are completed.
Railway systems, including wheeled and maglev systems. Train signaling and automatic train control.
Software engineering the application of a systematic, disciplined, quantifiable approach to the development, operation, and maintenance of software and the study of these approaches; that is, the application of engineering and computer science to software.
  • Cryptographic engineering Cryptographic Engineering is the discipline of using cryptography to solve human problems. Cryptography is typically applied when trying to ensure data confidentiality, to authenticate people or devices, or to verify data integrity in risky environments
  • Information technology engineering, (ITE) or information engineering methodology (IEM) is a software engineering approach to designing and developing information systems. It can also be considered as the generation, distribution, analysis, and use of information in systems
  • Teletraffic engineering Telecommunications traffic engineering, teletraffic engineering, or traffic engineering is the application of traffic engineering theory to telecommunications. Teletraffic engineers use their knowledge of statistics including queuing theory, the nature of traffic, their practical models, their measurements, and simulations to make predictions and to plan telecommunication networks such as a telephone network or the Internet. These tools and knowledge help provide reliable service at a lower cost
  • Web engineering focuses on the methodologies, techniques, and tools that are the foundation of Web application development and which support their design, development, evolution, and evaluation. Web engineering is multidisciplinary and encompasses contributions from diverse areas such as systems analysis and design, software engineering, hypermedia/hypertext engineering, requirements engineering, human-computer interaction, user interface, information technology engineering, information indexing and retrieval, testing, modeling and simulation, project management and graphic design and presentation
Supply chain engineering concerns the planning, design, and operation of supply chains.[6] [7]
Systems engineering is an interdisciplinary field of engineering that focuses on how to design and manage complex engineering projects over their life cycles. Issues, such as reliability, logistics and coordination of different teams, evaluation measurement, and other disciplines become more difficult when dealing with large or complex projects.
  • Systems engineering deals with work-processes, optimization methods, and risk management tools. It overlaps technical and human-centered disciplines such as control engineering, industrial engineering, organizational studies, and project management. Systems engineering ensures that all likely aspects of a project or system are considered and integrated into a whole
Textile engineeringTextile engineering courses deal with the application of scientific and engineering principles to the design and control of all aspects of fiber, textile, and apparel processes, products, and machinery. These include natural and man-made materials, interaction of materials with machines, safety and health, energy conservation, and waste and pollution control. Additionally, students are given experience in plant design and layout, machine and wet process design and improvement, and designing and creating textile products. Throughout the textile engineering curriculum, students take classes from other engineering disciplines including mechanical, chemical, materials, and industrial engineering.
Cybersecurity EngineeringCybersecurity engineers identify threats and vulnerabilities in computer systems and software. These professionals are experts who implement secure network solutions to protect organizations' networks and data systems from hackers, cyberattacks and other forms of computer crime.
  • Penetration testing: Cybersecurity engineers often evaluate an organization's computer networks, applications, and data systems for vulnerabilities
  • Network maintenance: Engineers may also install, test, and configure networks
  • IT system security: Engineers often spend time defining protocols and installing and configuring security devices
Cloud engineeringCloud engineers design, build, and manage scalable cloud infrastructure.

See also

Notes and References

  1. Julie Thompson Klein, Robert Frodeman, Carl Mitcham. The Oxford Handbook of Interdisciplinary. Oxford University Press, 2010. (pp. 149–150)
  2. Book: Wiebe. A. J.. Chan. C. W.. 2012 25th IEEE Canadian Conference on Electrical and Computer Engineering (CCECE) . Ontology driven software engineering . April 2012. 1–4. 10.1109/CCECE.2012.6334938. 978-1-4673-1433-6. 9911741.
  3. Clifford, Michael. An Introduction to Mechanical Engineering. Taylor & Francis Group LLC, 2006.
  4. https://wp.optics.arizona.edu/optomech/wp-content/uploads/sites/53/2016/08/1-Introduction.pdf University of Arizona OPTI 421/521: Introductory Optomechanical Engineering
  5. http://atmae.org/index.php?option=com_content&view=article&id=227&Itemid=48 "ATMAE Membership Venn Diagram"
  6. Book: Ravindran . Ravi . Warsing . Donald Jr. . Supply chain engineering : models and applications . 2017 . CRC Press . 9781138077720.
  7. Book: Goetschalckx . Marc . Supply chain engineering . Springer . 978-1-4419-6512-7. 2011-08-11 .