# precision engineering > subdiscipline of electrical engineering, software engineering, electronics engineering, mechanical engineering, and optical engineering **Wikidata**: [Q11604665](https://www.wikidata.org/wiki/Q11604665) **Wikipedia**: [English](https://en.wikipedia.org/wiki/Precision_engineering) **Source**: https://4ort.xyz/entity/precision-engineering ## Summary Precision engineering is a subdiscipline of electrical engineering, software engineering, electronics engineering, mechanical engineering, and optical engineering. It focuses on the design and manufacture of highly accurate components and systems. This field is essential for applications requiring extreme accuracy and reliability. ## Key Facts - Precision engineering is classified under the ANZSRC 2008 field of research code 091011 and ANZSRC 2020 code 401412 - The field has a GND ID of 4016654-5 and a Freebase ID of /m/04f3vxp - It is described on Wikidata as a subdiscipline of electrical engineering, software engineering, electronics engineering, mechanical engineering, and optical engineering - The Wikipedia page for precision engineering is available in German, English, Spanish, and Japanese - Precision engineering has a Quora topic page and is categorized under Category:Precision engineering on Wikipedia ## FAQs ### Q: What is precision engineering? A: Precision engineering is a subdiscipline that combines elements of electrical, software, electronics, mechanical, and optical engineering to create highly accurate components and systems. It focuses on achieving extreme accuracy and reliability in design and manufacturing. ### Q: What are the main applications of precision engineering? A: Precision engineering is used in applications requiring extreme accuracy, such as aerospace components, medical devices, semiconductor manufacturing equipment, and optical systems. It enables the production of parts with tolerances measured in micrometers or smaller. ### Q: How is precision engineering classified in research? A: Precision engineering is classified under the Australian and New Zealand Standard Research Classification (ANZSRC) with the 2008 code 091011 and the 2020 code 401412. These classifications help organize research and funding in this specialized field. ## Why It Matters Precision engineering plays a critical role in modern technology by enabling the creation of components and systems with extremely tight tolerances and high reliability. This field is fundamental to industries where even microscopic deviations can lead to catastrophic failures, such as aerospace, medical devices, and semiconductor manufacturing. Without precision engineering, many of today's technological advancements would be impossible, from the microchips in our smartphones to the instruments used in scientific research. The discipline bridges multiple engineering fields to solve complex problems that require accuracy at the microscopic or even atomic level, making it essential for pushing the boundaries of what's technologically possible. ## Notable For - Combines multiple engineering disciplines including electrical, software, electronics, mechanical, and optical engineering - Enables manufacturing of components with tolerances measured in micrometers or smaller - Critical for high-reliability applications in aerospace, medical, and semiconductor industries - Classified under specific research codes (091011 and 401412) in the ANZSRC system - Has international presence with Wikipedia pages in four languages ## Body ### Classification and Identification Precision engineering is formally classified in research databases with specific identifiers. It carries the GND ID 4016654-5 and is listed in Freebase with the ID /m/04f3vxp. The field is categorized under the Australian and New Zealand Standard Research Classification (ANZSRC) with the 2008 code 091011 and the 2020 code 401412, reflecting its established status in academic and industrial research. ### Academic and Online Presence The discipline maintains a significant online presence across multiple platforms. It has a dedicated Wikipedia page available in German, English, Spanish, and Japanese, indicating its global relevance. The field also has a Quora topic page and is categorized under Category:Precision engineering on Wikipedia, providing accessible information to both professionals and the general public. ### Technical Scope and Applications As a subdiscipline, precision engineering draws from electrical engineering, software engineering, electronics engineering, mechanical engineering, and optical engineering. This multidisciplinary approach allows it to address complex challenges requiring extreme accuracy. The field is particularly important in applications where microscopic tolerances are critical, such as in the manufacturing of semiconductor equipment, aerospace components, and medical devices. ### Industry Impact Precision engineering enables the production of components and systems that meet stringent accuracy requirements. This capability is essential for industries where even the smallest deviation can have significant consequences. The field's contributions are fundamental to technological advancement in areas ranging from consumer electronics to scientific instrumentation, making it a cornerstone of modern engineering practice. ## References 1. Freebase Data Dumps. 2013 2. Quora 3. [Source](https://www.abs.gov.au/AUSSTATS/abs@.nsf/DetailsPage/1297.02008?OpenDocument) 4. [Source](https://www.abs.gov.au/statistics/classifications/australian-and-new-zealand-standard-research-classification-anzsrc/2020#data-downloads) 5. [OpenAlex](https://docs.openalex.org/download-snapshot/snapshot-data-format)