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Precision Engineering

 Precision engineering is a growing subfield of civil engineering, control systems, computer engineering, microelectronic engineering, fabrication science, optical technology, and nanotechnology concerned with designing highly complex apparatuses, fixtures, machines, and other materials that have extremely low tolerances, require high reliability, have extremely long life spans, and are highly repeatable. These are the types of engineering that I worked on in the military. In fact the United States Military requires a lot of precision engineering in their procurement requirements. Many products that enter into service after decades of development will have to go through a lot of precision engineering and production runs to make sure that everything goes just as it should. That is why military aircraft, fighter planes, missiles, tanks, ships, tunnels, underground facilities, buildings, power plants, railroads, bridges, computer systems, medical devices, communications, transportation equipment, personal tech products, computer networking equipment, aircraft and space shuttles, etc. have so much engineering and production know-how that could easily be outsourced to other countries, although we do keep an army of engineers in the country for anything that might go wrong.

Some things that are done in precision engineering and other applied mechanical engineering are things like precision engineering testing, design and development of machine tools, precision manufacturing process and engineering for construction and machine tools. Precision machine tools involve things like ball bearings, gear boxes, hydraulic transmissions, crankshafts, pistons, etc. The list goes on. Precision manufacturing process is anything that has to do with making parts, assemblies, components, molds, etc. A manufacturer can only get away with high quality parts and/or assemblies if they have a very high tolerance for errors and have a well designed and tested production process. All of these things are done by the precision engineering branch of the discipline of civil engineering.

Precision engineering is also responsible for ensuring that we use our resources in the most efficient manner possible. This includes everything from the smallest components to the largest structures. The basic premise upon which precision engineering stands is the fact that'measurement must be exact'. Everything that we make and create is based off this premise. In order for us to use our resources to the utmost, precision engineering must be applied. It's job is to ensure that we utilize the best machinery, material, energy and time in order to create and produce the best results possible.

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