The quote with which we begin this chapter is from the first textbook devoted specifically to human factors, Applied Experimental Psychology: Human Factors in Engineering Design, by Alphonse Chapanis, Wendell Garner, and Clifford Morgan. Designing machines and systems, whether simple or complex, for human use was not only the central concern of their pioneering book but also the driving force for subsequent research on human factors and ergonomics over the past 69 years. The following quotation from the U.S. National Academy of Engineering in their report The Engineer of 2020, now more than 10 years old, captures the ever increasing importance of the role of human factors in the introduction of new technologies and products:

It is our purpose in this textbook to summarize much of what we know about human cognitive, physical, and social characteristics and to show how this knowledge can be brought to bear on the design of machines, tools, and systems that are easy and safe to use.

The things that modern electronic and digital equipment can do are amazing. However, how well these gadgets work (the extent to which they accomplish the goals intended by their designers) is often limited by the human component. As one example, the complicated features of video cassette recorders (VCRs) made them legendary targets of humor in the 1980s and 1990s. To make full use of a VCR, a person first had to connect the device correctly to the television and cable system or satellite dish system that provided the signal and then, if the VCR did not receive a time signal from the cable or satellite, accurately program its clock. When the person wanted to record a television program, she had to set the correct date, channel number, intended start and end times, and tape speed (SP, LP, or EP). If she made any mistakes along the way, the program she wanted would not be recorded. Either nothing happened, the wrong program was recorded, or the correct program was recorded for the wrong length of time (e.g., if she chose the wrong tape speed, say SP to record a 4 hour movie, she would get only the first 2 hours of the show). Because there were many points in this process at which users could get confused and make mistakes, and different VCRs embedded different command options under various menus and submenus in the interface, even someone who was relatively adept at programming recorders had problems, especially when trying to operate a machine with which he was unfamiliar.

Perhaps nowhere is rapid change more evident than in the development and proliferation of computer technology (Bernstein, 2011; Rojas, 2001). The first generation of modern computers, introduced in the mid-1940s, was extremely large, slow, expensive, and available mainly for military purposes. For example, in 1944, the Harvard-IBM Automatic Sequence Controlled Calculator (ASCC, the first large-scale electric digital computer in the U.S.) was the length of half of an American football field and performed one calculation every 3–5 s. Programming the ASCC, which had nothing like an operating system or compiler, was not easy. Grace Hopper, the first programmer for the ASCC, had to punch machine instructions onto a paper tape, which she then fed into the computer. Despite its size, it could only execute simple routines. Hopper went on to develop one of the first compilers for a programming language, and in her later life, she championed standards testing for computers and programming languages.