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Symbolic language (engineering)
Graphical symbols and abbreviations used in engineering to represent components, processes, effects, and their relationships

In engineering, a symbolic language is a language that uses standard symbols, marks, and abbreviations to represent concepts such as entities, aspects, attributes, and relationships.[original research?]

Engineering symbolic language may be used for the specification, design, implementation, management, operation, and execution of engineered systems.[original research?]

Communication using precise, concise representations of concepts is critical in engineering. The Nuclear Principles in Engineering book begins with a quote on symbolic language from Erich Fromm and its power to express and depict associations. The engineering employs symbolic language in a way that is not purely text-based and not purely image-based to represent and communicate knowledge.

Examples in chemical engineering include the symbolic languages developed for process flow diagrams and for piping and instrumentation diagrams (P&IDs).

In electrical engineering, examples include the symbolic languages developed for network diagrams used in computing.

Ladder logic was originally a written symbolic language for the design and construction of programmable logic control (PLC) operations in mechanical and control engineering.

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See also

Look up symbolic language in Wiktionary, the free dictionary.

References

  1. "P&ID Diagram Basics - Part 1 - Purpose, Owner and Contents". instrumentationandcontrol.net. Retrieved 2019-03-24. http://instrumentationandcontrol.net/pid-diagram-basics/

  2. Provost, Office of the. "Advanced Engineering Language, Symbols, and Visualizations for Complex and Increasingly Autonomous SystemsCenter for Social Complexity". Retrieved 2019-03-24. https://socialcomplexity.gmu.edu/lmi-nasa/

  3. DIXON, JOHN R. (1962). "Symbols in Engineering Education". ETC: A Review of General Semantics. 19 (3): 269–272. ISSN 0014-164X. JSTOR 42573965. /wiki/ISSN_(identifier)

  4. OpenLibrary.org. "The forgotten language | Open Library". Open Library. Retrieved 2019-06-29. https://openlibrary.org/works/OL1185032W/The_forgotten_language

  5. Jevremovic, Tatjana (2008-12-15). Nuclear Principles in Engineering. Springer Science & Business Media. ISBN 9780387856070. 9780387856070

  6. Gaševic, Dragan; Djuric, Dragan; Devedžic, Vladan (2009-06-12). Model Driven Engineering and Ontology Development. Springer Science & Business Media. ISBN 9783642002823. 9783642002823

  7. "Chemical and Process Engineering, Engineer Drawing Symbols, Design elements, Dimensioning and Tolerancing". ConceptDraw. Retrieved 2019-06-29. https://www.conceptdraw.com/examples/engineer-drawing-symbols

  8. Waldring, Ségio (2009-05-01). "Standard Network Diagramming Language and Corresponding Meta-Model". Georgia Southern University. https://digitalcommons.georgiasouthern.edu/etd/666

  9. Jespers, P.; Sequin, C. H.; Wiele, F. van de, eds. (1982). Design Methodologies for VLSI Circuits. Nato Science Series E. Springer Netherlands. ISBN 9789028627819. 9789028627819

  10. Kutz, Myer (2013-06-10). Handbook of Farm, Dairy and Food Machinery Engineering. Academic Press. ISBN 9780123858825. 9780123858825