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History of video games/Understanding Historical Technology

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When studying the history of video games, it is very helpful to have an understanding of historical technology. This chapter intends to catch up readers on relevant developments which were influential in the development gaming technology. Readers with a background in such history may consider reading ahead.

Prior Developments[edit | edit source]

A number of prior developments would prove influential on the development of video games. This section covers those technologies that either paved the way for game systems, or showed how earlier people perceived automated entertainment - the socio-technological bedrock of the gaming industry.

At the same time, many technologies involved in gaming are much older than one might expect. It's important to note that none of the developments in this section are directly video games themselves, and many of these developments remained unavailable to the common person until the development of mass production.

Prehistory[edit | edit source]

The use of moving pictures as a form of artwork may date back to the stone age.[1][2]

Antiquity[edit | edit source]

People have desired autonomous entertainment since ancient times. This is evidenced by the Ancient Greeks, who are said to have built a theater of automatons in Alexandria.[3] Early concepts of simulated realities can also be seen in Plato's Allegory of the Cave.[4] In particular, Hero of Alexandria describes automated theater systems in Automatopoietica, including moving not only automaton actors in 3D space, but also tricks that would later be used by 3D games, such as using 2D graphics convincingly in a 3D space.[5] The ancient Chinese also employed automation for entertainment at various points in their history, also primarily in mechanical theater.[6]

The Ancient Chinese and the Ancient Greeks were both aware of the natural phenomenon of the Camera Obscura, an important observation which would later lead to more advanced cameras and understanding of optics,[7] both technologies that would later see use in games.

The philosopher Thales of Miletus, one of the seven sages of Greece, was among the first to document electromagnetic phenomenon.[8]

The mathematic concepts, especially those relating to geometry, pioneered by the Greek philosopher Euclid of Alexandria would later be commonly used by game developers.[9] The Greek Philosopher Plato described how triangles could be used to represent 3D shapes,[10] a mathematic concept fundamental to computer 3D graphics, especially by the real time graphics used in video games.

  • The cartesian coordinate system, a common concept used by games based on Euclidian geometry. Developments in the ancient world concerning mathematics would become critical pilers of gaming technologies.
    The cartesian coordinate system, a common concept used by games based on Euclidian geometry. Developments in the ancient world concerning mathematics would become critical pilers of gaming technologies.
  • The ancient Greeks were skilled at making mechanical devices. The Antikythera mechanism is perhaps the oldest known Analog computer. However it would be nearly two millennia before general purpose programmable computers would be developed.
    The ancient Greeks were skilled at making mechanical devices. The Antikythera mechanism is perhaps the oldest known Analog computer. However it would be nearly two millennia before general purpose programmable computers would be developed.
  • An Aeolipile, Hero of Alexandria's early steam engine. With the exception of some renewables and chemical batteries, almost all contemporary power generation is based either on similar principals.
    An Aeolipile, Hero of Alexandria's early steam engine. With the exception of some renewables and chemical batteries, almost all contemporary power generation is based either on similar principals.
  • A depiction of Hero of Alexandria's Windwheel powered organ, an entertaining automatic novelty.
    A depiction of Hero of Alexandria's Windwheel powered organ, an entertaining automatic novelty.
  • A drawing of a Bagdad battery. Though their use is debated, some suspect that these devices from the Persian Empire were used to harness electricity.
    A drawing of a Bagdad battery. Though their use is debated, some suspect that these devices from the Persian Empire were used to harness electricity.

Age of Enlightenment & The First Industrial Revolution[edit | edit source]

While Video Games are often seen as a relatively new medium, many foundational technologies for gaming were developed just decades or a century or two prior to the development of video games, which is a very short period of time in most historical fields.

The Mechanical Turk of the 1770s showed a desire by people to play games with a machine,[11] though in truth the machine was operated like a puppet by a human hidden beneath the playtable.

From the 1830's to her early death, Augusta Ada King, Countess of Lovelace (Known popularly as simply Ada Lovelace), a skilled mathematician who studied under Augustus De Morgan himself, becomes arguably the first programmer, having written a complex program for the analytical engine designed by Charles Babbage which incorporated now common hallmarks of programming, including nested loops, bugs, debugging techniques, and variables.[12] In addition to her mathematical work, Ada Lovelace received musical training, and it was she who first wrote of using computers to generate music programmatically - A topic of specific importance to the history of video games.[13] Further attempted developments of the machine by Babbage were almost certainly hindered when Ada Lovelace was afflicted by illness, eventually dying young as a result.[14][13]

  • The Mechanical Turk, a famed "Machine" that played chess, was really ran by a person hiding inside the unit.[15]
    The Mechanical Turk, a famed "Machine" that played chess, was really ran by a person hiding inside the unit.[15]
  • An early electric telegraph in 1809. These devices would help pave the way to automated computer communication, and eventually multiplayer video games over a network.
    An early electric telegraph in 1809. These devices would help pave the way to automated computer communication, and eventually multiplayer video games over a network.
  • A depiction of Benjamin Franklin performing his Kite Experiment. Interest in working with, and later harnessing electricity would increase greatly during and following the Enlightenment. Without the knowledge gained about electricity during this time, electronic games as we know them would not be possible.
    A depiction of Benjamin Franklin performing his Kite Experiment. Interest in working with, and later harnessing electricity would increase greatly during and following the Enlightenment. Without the knowledge gained about electricity during this time, electronic games as we know them would not be possible.
  • Model of Alexander Graham Bell's "Big box telephone" of 1876. Early commercial telephones like this paved the way for modern gaming concepts such as voice chat.
    Model of Alexander Graham Bell's "Big box telephone" of 1876. Early commercial telephones like this paved the way for modern gaming concepts such as voice chat.
  • A depiction of a Japanese automaton theater in the 1790's. Made in relative isolation from the west, such developments prove a suggest a near universal interest in development of automated entertainment.
    A depiction of a Japanese automaton theater in the 1790's. Made in relative isolation from the west, such developments prove a suggest a near universal interest in development of automated entertainment.
  • A Model of the Difference Engine based on design of Charles Babbage. Though never built in his life, the device is an important milestone in the history of computing.
    A Model of the Difference Engine based on design of Charles Babbage. Though never built in his life, the device is an important milestone in the history of computing.
  • A portrait of Charles Babbage in 1833.
    A portrait of Charles Babbage in 1833.
  • Portrait of Ada Lovelace around 1840, often counted among the first computer programmers due to her work on Babbage's Analytical engine.
    Portrait of Ada Lovelace around 1840, often counted among the first computer programmers due to her work on Babbage's Analytical engine.

The Second Industrial Revolution[edit | edit source]

Recorded Audio[edit | edit source]

In the 1877 Thomas Edison would invent the Phonograph, enabling the accurate recording of audio to be played back at a later date.[16]

The War of Currents[edit | edit source]

During the 1880's the war of the currents highly influenced electric standards.[17][18][19] The resulting AC standards would influence television standard refresh rates,[20] and in turn influence standard video game refresh rates.[21]

For more information on the War of the Currents, one can consult the Wikibook Nikola Tesla, though bear in mind this important figure was only a one part of the event.

Joysticks[edit | edit source]

Depending on the source, Joysticks were either invented during the American Civil War between 1861 and 1865 for use in submarines at the earliest,[22] or invented in 1923 by C. B. Mirick while working for the US Naval Research Laboratory at the latest.[23][24] Their use as a control scheme for specialized vehicles made them a natural choice for early game systems.

  • Employees of Thomas Edison working on the electrification of New York City in 1882. Instillation of electrical infrastructure helped pave the way for electronic games. The War of Currents was also among the first Format Wars that would directly impact the video game industry.
    Employees of Thomas Edison working on the electrification of New York City in 1882. Instillation of electrical infrastructure helped pave the way for electronic games. The War of Currents was also among the first Format Wars that would directly impact the video game industry.
  • Photo of Nikola Tesla in his Colorado Springs lab around 1899. Tesla's work on AC current, wireless communication, and motors would help pave the way for consumer electronics, and the video game industry by extension.
    Photo of Nikola Tesla in his Colorado Springs lab around 1899. Tesla's work on AC current, wireless communication, and motors would help pave the way for consumer electronics, and the video game industry by extension.
  • A Ford assembly line in 1913. The rise of mass production and the consistency and efficiencies resulting from standardized parts made the massive consumer market for complex yet highly standardized items such as home game consoles possible.
    A Ford assembly line in 1913. The rise of mass production and the consistency and efficiencies resulting from standardized parts made the massive consumer market for complex yet highly standardized items such as home game consoles possible.
  • Thomas Edison with his 2nd version of the Phonograph, photo taken around 1878.
    Thomas Edison with his 2nd version of the Phonograph, photo taken around 1878.

Arcades[edit | edit source]

Racing Games as an arcade genre date back to as early as 1912.[25]

  • A Penny Arcade in New Orleans around 1910. The establishment of mechanical arcades decades before video games arcades helped familiarize the public with the concept.
    A Penny Arcade in New Orleans around 1910. The establishment of mechanical arcades decades before video games arcades helped familiarize the public with the concept.

The Modern Era[edit | edit source]

Broadcast Standards, and all that Jazz[edit | edit source]

The earlier War of Currents would influence broadcast standards for television, which would influence what frame rates, resolutions, and other standards used by computers and game consoles. Though standardization greatly improved compatibility between devices from different companies, a number of incompatible standards arose across the globe. This lead to massive variations and incompatibilities early on in gaming history, as systems had to be designed for NTSC, PAL, or SECAM depending on their geographic region, and often had to be designed to take a specific voltage and frequency of AC, which alternated between countries. As time went on, digital standards made these early television standards mostly irrelevant, and the introduction of better power supplies which could handle nearly any AC power standard used across the globe also reduced such concerns dramatically.

Other Innovations[edit | edit source]

After early developments in the 1930's, printed circuit boards see widespread use in World War II munitions.[26] These boards aid standardization, and help pave the way for mass production of consumer electronics.

  • An early 1929 CRT television set. The innovations of display technology prior to the development of gaming hardware would help pave the way for adoption of gaming systems.
    An early 1929 CRT television set. The innovations of display technology prior to the development of gaming hardware would help pave the way for adoption of gaming systems.
  • A map of the mains voltages and frequencies used internationally. Early power supplies were often meant for a single region, limiting their international usage. Some countries such as Japan used multiple systems internally, further complicating matters.
    A map of the mains voltages and frequencies used internationally. Early power supplies were often meant for a single region, limiting their international usage. Some countries such as Japan used multiple systems internally, further complicating matters.
  • Analog television standards by nation. Until the late 2000's, this played a key role in determining what kind of resolution and frame rate a console would output in order to work with the televisions of those regions which expected specific refresh rates and resolutions to operate. Modern digital standards in conjunction with designs which can output multiple resolutions and frame rates have reduced this concern significantly
    Analog television standards by nation. Until the late 2000's, this played a key role in determining what kind of resolution and frame rate a console would output in order to work with the televisions of those regions which expected specific refresh rates and resolutions to operate. Modern digital standards in conjunction with designs which can output multiple resolutions and frame rates have reduced this concern significantly

The Information Age[edit | edit source]

Though gaming as a medium is proceeded by its foundational technologies, most of these technologies continued to experience significant improvements alongside gaming technology. This means that every decade since the inception of video gaming as a medium, the core technologies supporting gaming have also improved substantially, making the relationship between the two in significant flux.

The nearly concurrent rise of computer industry with the video game industry directly lead to improvements and innovations in both industries. The Wikibook History of Computers covers the general history of computers in more detail. This section discusses these innovations as they relate to gaming.

Transistors, Integrated Circuits, and the Microprocessor[edit | edit source]

The miniaturization and resulting ability to mass produce advanced yet relatively cheap electronics was a key moment in this history of all consumer electronics applications, but especially video games. There would likely be no significant market for a room sized gaming device which cost exorbitant sums of money every minute to operate and regularly required downtime for vacuum tubes to be replaced by skilled technicians.

In his 1945 article As We May Think for The Atlantic Dr. Vannevar Bush proposes Memex,[27] a concept which would evolve into hypertext, paving the way to the World Wide Web, and by extension, games on the web.

  • Alan Turing in the 1930's.
    Alan Turing in the 1930's.
  • Vannevar Bush in the early 1940's, during the second World War.
    Vannevar Bush in the early 1940's, during the second World War.

Video Game Era[edit | edit source]

This section covers common recurring trends seen in technology use and adoption in video game history.

General hardware[edit | edit source]

In the late 1980's to the early 2000's a trend emerged where marketers would promote their systems by the bit size used by the internal computers of their devices. In general, there is a sliver of truth that larger bit sizes did aid development. However bit size alone has little to do with anything gaming related, especially after 32-bit processors became commonly used. Other factors, such as improved clock speeds, instructions per clock, internal architecture improvements, and perhaps most importantly, dedicated chips for applications such as graphics and audio, are much more responsible for the increased performance seen as time went on. Increased storage capacities of media also helped developers focus more on improving the game, and less on optimizing for hardware.

Hardware paradigms[edit | edit source]

In a generation there is typically a wide spectrum of power available on individual systems. Most systems fall into a sort of Goldilocks area where they are powerful enough for games of the time, but cheap enough to be viable on the market. However there are a few commonly seen strategies which buck this trend.

A common alternative strategy is to use cheaper underpowered hardware, and hope that the resulting high marketshare from a lower price attracts developers to a platform anyway. Skilled developers can often make up for hardware which is only moderately underpowered, but if the hardware is too underpowered, it creates a sort of chicken and egg problem where consumers don't want even cheap hardware because it lacks compelling games, and third party developers aren't interested in such hardware because it lacks marketshare and is difficult to develop for. An example of this model is the Watara Supervision, which undercut the popular GameBoy on price, but was unable to attract a marketshare with its poor game library.

The inverse strategy, using much more expensive overpowered hardware, is also commonly seen. Modest cases of this are especially true for major game consoles at launch, which often require a razor blade model where the console itself is sold at a loss, and profit is instead made on game sales. However some systems take this model to an extreme, finding a small market niche by offering unparalleled experiences at an unparalleled price. A good example of this strategy is the Neo Geo home console, which was essentially identical to the arcade systems made by SNK at the time.

Especially early on, some companies employed engineers with such skill they were able to do much more than their competitors for much less. A notable example of this is the Apple II home computer, which Steve Wozniak was able to add color capability to using clever tricks while keeping costs much lower than other competing color computers. This relatively cheap home computer with great potential for gaming in color took the market by storm as a result. As time went on, such massive leaps became rarer, but there were some companies which were able to use their massive manufacturing capabilities from other markets to undercut gaming companies by making things in house and eliminating third party middlemen.

Occasionally a device manufacturer attempts a completely different paradigm, often by introducing a new user interface technology, to attract consumers.

Developer Friendliness[edit | edit source]

Another commonly overlooked technological aspect which has improved with time is developer friendliness. As time has gone on systems have generally gotten easier to develop for, allowing developers to use high level programming languages, standardized APIs, and later standardized game engines to more easily target multiple systems in a generation.

A key point to note is that underpowered systems with well understood architectures tend to not be too impactful on developers, who will often be able to make a game appropriate for the hardware. However a number of systems have released historically with strange technological decisions which theoretically offer much greater performance than other hardware of the time. In these cases developers, especially third party studios, often struggle to actually take advantage of this poorly understood hardware and the benefit is often reduced, lost entirely, or even backfires with implementations that run worse than on much weaker systems. This lessons over time given widespread adoption.

As an example of this phenomenon, many software developers in the 1990's had trouble leveraging systems with multiple CPUs. By the late 2010's utilization of multi-core CPUs was much better. This is aided by improvements in the hardware itself, such as designing CPUs with multiple cores instead of putting two independent CPUs on the same board, as well as software improvements such as game engines supporting multiple threads by default.

References[edit | edit source]

  1. Ouellette, Jennifer (21 April 2022). "Stone Age people may have gathered at night to watch animated “fireside art”" (in en-us). Ars Technica. https://arstechnica.com/science/2022/04/stone-age-people-may-have-gathered-at-night-to-watch-animated-fireside-art/. 
  2. Hunt, Katie (21 April 2022). "Prehistoric humans turned their campfires into makeshift movie theaters" (in en). CNN. https://www.cnn.com/2022/04/21/europe/prehistoric-art-fire-light-moving-images-scn/index.html. 
  3. "Automation in the Ancient World: The Robots of Greece and Rome". Classical Wisdom Weekly. 31 January 2020. Retrieved 16 January 2021.
  4. "Allegory of the Cave". faculty.washington.edu. Retrieved 16 January 2021.
  5. Xagoraris, Zafirios (1991). "The automaton theater". Massachusetts Institute of Technology. Retrieved 16 January 2021. {{cite journal}}: Cite journal requires |journal= (help)
  6. "List of Chinese inventions". Wikipedia. 23 February 2021. Retrieved 28 February 2021.
  7. "Camera obscura". Wikipedia. 4 February 2021. Retrieved 28 February 2021.
  8. "E&M History". galileoandeinstein.physics.virginia.edu. Retrieved 28 February 2021.
  9. "Mathematics In Videogames" (in en). www.gamasutra.com. https://www.gamasutra.com/view/feature/131605/mathematics_in_videogames.php. 
  10. "Geometry in Art & Architecture Unit 6". math.dartmouth.edu. Retrieved 28 February 2021.
  11. Staff, T. B. S. (20 July 2015). "A Brief History of Computer Chess". TheBestSchools.org. https://thebestschools.org/magazine/brief-history-of-computer-chess/. 
  12. "What Did Ada Lovelace's Program Actually Do?". twobithistory.org. Retrieved 7 March 2021.
  13. a b "Ada Lovelace: Founder of Scientific Computing". www.sdsc.edu. https://www.sdsc.edu/ScienceWomen/lovelace.html. 
  14. "Untangling the Tale of Ada Lovelace—Stephen Wolfram Writings" (in en). writings.stephenwolfram.com. https://writings.stephenwolfram.com/2015/12/untangling-the-tale-of-ada-lovelace/. 
  15. "The Mechanical Turk: How a Chess-playing Hoax Inspired Real Computers" (in en). Discover Magazine. https://www.discovermagazine.com/technology/the-mechanical-turk-how-a-chess-playing-hoax-inspired-real-computers. 
  16. "Early Sound Recording Collection and Sound Recovery Project" (in en). National Museum of American History. 15 March 2012. https://americanhistory.si.edu/press/fact-sheets/early-sound-recording-collection-and-sound-recovery-project. 
  17. "The War of the Currents: AC vs. DC Power". Energy.gov. Retrieved 18 December 2020.
  18. "‘War of the Currents’ Had Profound Impact (Published 1979)". The New York Times. 6 February 1979. https://www.nytimes.com/1979/02/06/archives/war-of-the-currents-had-profound-impact-the-war-of-the-currents-had.html. 
  19. "PBS: Tesla - Master of Lightning: War of the Currents". www.pbs.org. https://www.pbs.org/tesla/ll/ll_warcur.html. 
  20. "Never Twice The Same Color: Why NTSC Is So Weird". Hackaday. 6 October 2016. https://hackaday.com/2016/10/06/never-twice-the-same-color-why-ntsc-is-so-weird/. 
  21. Byford, Sam (27 November 2018). "The US PlayStation Classic has several slower 50Hz PAL games" (in en). The Verge. https://www.theverge.com/circuitbreaker/2018/11/27/18114073/playstation-classic-pal-ntsc-50hz-letterboxing. 
  22. "The origins of the joystick". Engadget. Retrieved 15 December 2020.
  23. "What is a Joystick?". www.computerhope.com. Retrieved 15 December 2020.
  24. "Electrical distant-control system". 1 September 1923. Retrieved 15 December 2020.
  25. Rose, Paul (September 8, 2022). "Driving games are older than you think" (in en). Wireframe magazine. https://wireframe.raspberrypi.com/articles/driving-games-are-older-than-you-think. 
  26. "The History of Printed Circuit Boards - Mint Tek Circuits". Mint Tek Circuits - Printed Circuit Boards. 19 February 2016. https://mint-tek.com/the-history-of-printed-circuit-boards-2/. 
  27. Bush, Vannevar (1 July 1945). "As We May Think" (in en). The Atlantic. https://www.theatlantic.com/magazine/archive/1945/07/as-we-may-think/303881/. 

Introduction · Early games

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