The basic design of machine tools and other systems used in manufacturing processes changed little from the eighteenth century to the late 1940s. There was a gradual improvement during this period as the metal cutting changed from an art to a science as there was an increased understanding of the materials used in cutting tools. However, the first significant change to machine-tool technology was the introduction of numerical-control (NC) and computer-numerical-control (CNC) systems.

To an operator, the differences between these two technologies are small, both operate from a stored program, which was originally on punched tape, then computer media such as magnetic tapes and discs, and currently stored centrally and distributed over a network. The stored program in a NC machine is directly read and used to control the machine; the logic within the controller is dedicated to that task. A CNC machine tool incorporates a dedicated computer to execute the program. The use of the computer gives a considerable number of other features, including data collection and communication with other machine tools or computers over a computer network. In addition to the possibility of changing the operating program of a CNC system, the executive software of the computer can be changed, which allows the performance of the system to be modified at minimum cost. The application of NC and CNC technology permitted a complete revolution of the machine tool industry and the manufacturing industries it supported. The introduction of electronic systems into conventional machine tools was initially undertaken in the late 1940s by the United States Air Force to increase the quality and productivity of machined aircraft parts. The rapid advances of electronics and computing systems during the 1960s and 1970s permitted the complete automation of machine tools and the parallel development of industrial robots. This was followed during the 1980s by the integration of robots, machine tools, and material handling systems into computer-controlled factory environments. The logical conclusion of this trend is that individual product quality is no longer controlled by direct intervention of an operator. Since the machining parameters are stored either within the machine or at a remote location for direct downloading via a network (see Chapter 11) a capability exists for the complete repeatability of a product, both by mass production and in limited batches (which can be as small as single components). Until the 1990's machining normally involved the removal of material from the workpiece to form the final object – this is subtractive machine...