Although many modern typewriters have one of several similar designs, their invention was incremental, developed by numerous inventors working independently or in competition with each other over a series of decades. As with the
automobile, the telephone, and
telegraph, several people contributed insights and inventions that eventually resulted in ever more commercially successful instruments. Historians have estimated that some form of the typewriter was invented 52 times as thinkers and tinkerers tried to come up with a workable design. Some early typing instruments include: • In 1575, an Italian printmaker, Francesco Rampazetto, invented the , a machine to impress letters in papers. • In 1714,
Henry Mill obtained a patent in
Great Britain for a machine that, from the patent, appears to have been similar to a typewriter. The patent shows that this machine was created: "[he] hath by his great study and paines & expence invented and brought to perfection an artificial machine or method for impressing or transcribing of letters, one after another, as in writing, whereby all writing whatsoever may be engrossed in paper or parchment so neat and exact as not to be distinguished from print; that the said machine or method may be of great use in settlements and public records, the impression being deeper and more lasting than any other writing, and not to be erased or counterfeited without manifest discovery." • In 1802, Agostino Fantoni developed a particular typewriter to enable his
blind sister to write. • Between 1801 and 1808,
Pellegrino Turri invented a typewriter for his blind friend Countess Carolina Fantoni da Fivizzano. • In 1823, Pietro Conti da Cilavegna invented a new model of the typewriter, the , also known as . • In 1829, American
William Austin Burt patented a machine called the "
Typographer" which, in common with many other early machines, is listed as the "first typewriter". The London
Science Museum describes it merely as "the first writing mechanism whose invention was documented", but even that claim may be excessive since Turri's invention pre-dates it. By the mid-19th century, the increasing pace of business communication had created a need to mechanize the writing process.
Stenographers and
telegraphers could take down information at rates up to 130 words per minute, whereas a writer with a pen was limited to a maximum of 30 words per minute (the 1853 speed record). From 1829 to 1870, many printing or typing machines were patented by inventors in Europe and America, but none went into commercial production. • American
Charles Thurber developed multiple patents, of which his first in 1843 was created as an aid to blind people, such as the 1845
Chirographer. • In 1850, British inventor William Hughes invented the Typograph, which was displayed at the
World's Fairs of 1851 and
1862. It allowed blind people to use typewriters because of its raised keys. It became a standard tool in British schools for the blind throughout the 1850s. Hughes also served as the first governor of Henshaw's Blind Asylum in Manchester, which was dedicated to training and paid employment for blind people. • In 1861, Father Francisco João de Azevedo, a Brazilian priest, made his typewriter with basic materials and tools, such as wood and knives. In that same year, the Brazilian emperor
Pedro II, presented a gold medal to Father Azevedo for this invention. Many Brazilian people, as well as the Brazilian federal government recognize Fr. Azevedo as the inventor of the typewriter, a claim that has been the subject of some controversy. • In 1865,
John Pratt, of
Centre, Alabama (US), built a machine called the
Pterotype which appeared in an 1867
Scientific American article and inspired other inventors. • Between 1864 and 1867, , a carpenter from
South Tyrol (then part of
Austria) developed several models and a fully functioning prototype typewriter in 1867.
Hansen Writing Ball was the first typewriter manufactured commercially (1870). In 1865, Rev.
Rasmus Malling-Hansen of
Denmark invented the
Hansen Writing Ball, which went into commercial production in 1870 and was the first commercially sold typewriter. It was a success in Europe and was reported as being used in offices on the European continent as late as 1909. Malling-Hansen used a
solenoid escapement to return the carriage on some of his models, which makes him a candidate for the title of inventor of the first "electric" typewriter. The Hansen Writing Ball was produced with only upper-case characters. The Writing Ball was a template for inventor
Frank Haven Hall to create a derivative that would produce letter prints cheaper and faster. Malling-Hansen developed his typewriter further through the 1870s and 1880s and made many improvements, but the writing head remained the same. On the first model of the writing ball from 1870, the paper was attached to a cylinder inside a wooden box. In 1874, the cylinder was replaced by a carriage, moving beneath the writing head. Then, in 1875, the well-known "tall model" was patented, which was the first of the writing balls that worked without electricity. Malling-Hansen attended the world exhibitions in
Vienna in 1873 and Paris in 1878 and he received the first-prize for his invention at both exhibitions.
Sholes and Glidden typewriter The first typewriter to be commercially successful was patented in 1868 by Americans
Christopher Latham Sholes,
Frank Haven Hall,
Carlos Glidden and
Samuel W. Soule in
Milwaukee, Wisconsin. The working prototype was made by clock-maker and machinist Matthias Schwalbach. Hall, Glidden and Soule sold their shares in the patent (US 79,265) to Sholes and
James Densmore, This arrangement,
retronymically known as
understrike would eventually give way to so-called
frontstrike mechanisms in later, competing machines.
Index typewriter The index typewriter came into the market in the early 1880s. The index typewriter uses a pointer or stylus to choose a letter from an index. The pointer is mechanically linked so that the letter chosen could then be printed, most often by the activation of a lever. The index typewriter's niche appeal however soon disappeared as, on the one hand new keyboard typewriters became lighter and more portable, and on the other refurbished
second-hand machines began to become available.
fonts and
character sets. This is something very few keyboard machines were capable of—and only at considerable added cost.
Embossing tape label makers are the most common index typewriters today, and perhaps the most common typewriters of any type still being manufactured.
Other typewriters • 1884 – Hammond "Ideal" typewriter with case, by Hammond Typewriter Company Limited, United States. Despite an unusual, curved keyboard (see pictures in
Gallery and citation), the Hammond became popular because of its superior print quality and changeable typeface. Invented by James Hammond of Boston, Massachusetts in 1880, and commercially released in 1884. The type is carried on a pair of interchangeable rotating sectors, one controlled by each half of the keyboard. A small hammer pushes the paper against the ribbon and type sector to print each character. The mechanism was later adapted to give a straight QWERTY keyboard and proportional spacing. • This typewriter was adapted with a tactile interface and
Braille output to allow the production and consumption of text y and for blind people. This adaptation was initiated in 1875 by Sir Francis Campbell, co-founder of the
Royal National College for the Blind. • 1893 – Gardner typewriter. This typewriter, patented by Mr J Gardner in 1893, was an attempt to reduce the size and cost. Although it prints 84 symbols, it has only 14 keys and two change-case keys. Several characters are indicated on each key and the character printed is determined by the position of the case keys, which choose one of six cases. • 1896 – the "Underwood 1 typewriter, 10" Pica, No. 990". This was the first typewriter with a typing area fully visible to the typist until a key is struck. These features, copied by all subsequent typewriters, allowed the typist to see and if necessary correct the typing as it proceeded. The mechanism was developed in the US by Franz X. Wagner from about 1892 and taken up, in 1895, by John T. Underwood (1857–1937), a producer of office supplies.
Standardization By about 1910, the "manual" or "mechanical" typewriter had reached a somewhat
standardized design. There were minor variations from one
manufacturer to another, but most typewriters followed the concept that each key was attached to a typebar that had the corresponding letter molded, in reverse, into its striking head. When a key was struck briskly and firmly, the typebar hit a ribbon (usually made of
inked
fabric), making a printed mark on the paper wrapped around a cylindrical
platen. The platen was mounted on a carriage that moved horizontally to the left, automatically advancing the typing position, after each character was typed. The carriage-return lever at the far left was then pressed to the right to return the carriage to its starting position and rotating the platen to advance the paper vertically. A small bell was struck a few characters before the right hand margin was reached to warn the operator to complete the word and then use the carriage-return lever. By 1900, notable typewriter manufacturers included
E. Remington and Sons,
IBM,
Godrej,
Imperial Typewriter Company,
Oliver Typewriter Company,
Olivetti,
Royal Typewriter Company,
Smith Corona,
Underwood Typewriter Company,
Facit,
Adler, and
Olympia-Werke. After the market had matured under the market dominance of large companies from Britain, Europe and the United States—but before the advent of daisywheel and electronic machines—the typewriter market faced strong competition from less expensive typewriters from Asia, including
Brother Industries and
Silver Seiko Ltd. of Japan.
Frontstriking In most of the early typewriters, the typebars struck upward against the paper and pressed against the bottom of the
platen (
understrike), so the typist could not see the text as it was typed. What was typed was not visible until a carriage return caused it to scroll into view. The difficulty with any other arrangement was ensuring the typebars fell back into place reliably when the key was released. This was eventually achieved with various ingenious mechanical designs and so-called "visible typewriters" which used frontstriking, in which the typebars struck forward against the front side of the platen, which became standard. One of the first front-strike typewriters was the Daugherty Visible, introduced in 1893.
Four-bank keyboard The Daugherty Visible also introduced the four-bank keyboard, which also became standard, although the Underwood, which came out two years later, was the first
major typewriter to support frontstriking and a four-bank keyboard.
Shift key A significant innovation was the
shift key, introduced with the
Remington No. 2 in 1878. This key physically "shifted" either the basket of typebars, in which case the typewriter is described as "basket shift", or the paper-holding carriage, in which case the typewriter is described as "carriage shift". Either mechanism caused a different portion of the typebar to come in contact with the ribbon/platen. The result is that each typebar could type two different characters, cutting the number of keys and typebars in half (and simplifying the internal mechanisms considerably). The obvious use for this was to allow letter keys to type both
upper and lower case, but normally the number keys were also duplexed, allowing access to special symbols such as percent, , and ampersand, . Before the shift key, typewriters had to have a separate key and typebar for upper-case letters; in essence, the typewriter had two full keyboards, one above the other. With the shift key, manufacturing costs (and therefore purchase price) were greatly reduced, and typist operation was simplified; both factors contributed greatly to mass adoption of the technology.
Three-bank typewriters Certain models further reduced the number of keys and typebars by making each key perform three functions—each typebar could type three different characters. These little three-row machines were portable and could be used by journalists. Such three-row machines were popular with WWI journalists because they were lighter and more compact than four-bank typewriters, while they could type just as fast and use just as many symbols. To include those symbols, three-row machines like the Bar-Let and the
Corona No. 3 Typewriter had two distinct shift keys performing different functions, a "CAP" shift (for uppercase) and a "FIG" shift (for numbers and symbols). They were thus also known as
double-shift typewriters.
Teletypewriters also often used a three-row typewriter keyboard, which looked superficially similar in that it also had two shift keys, "FIGS" (figures) and "LTRS" (letters). However, these
Murray code-based machines generally did not allow each key to perform three functions and were a different technology from double-shift typewriters.
Tab key To facilitate typewriter use in business settings, a tab (tabulator) key was added in the late 19th century. Before using the key, the operator had to set mechanical "tab stops" (pre-designated locations to which the carriage would advance when the tab key was pressed). This facilitated the typing of columns of numbers, freeing the operator from the need to manually position the carriage. The first models had one tab stop and one tab key; later ones allowed as many stops as desired, and sometimes had multiple tab keys, each of which moved the carriage a different number of spaces ahead of the decimal point (the tab stop), to facilitate the typing of columns with numbers of different length ($1.00, $10.00, $100.00, etc.) such that the decimal points were vertically aligned. Typically, tab stops could be set by a key-set tabulator control (either by a lever or keys on the keyboard—usually labelled with "+" or "-", or "set" and "clear") or moveable tab stops at the back of the machine, similar to margin stops.
Dead keys Languages such as French, Spanish, and German required
diacritics, special signs attached to or on top of the base letter: for example, a combination of the
acute accent plus produced ; plus produced . In
metal typesetting, , , and others were separate
sorts. With mechanical typewriters, the number of whose characters (sorts) was constrained by the physical limits of the machine, the number of keys required was reduced by the use of
dead keys. Diacritics such as (
acute accent) would be assigned to a
dead key, which did not move the
platen forward, permitting another character to be imprinted at the same location; thus a single dead key such as the acute accent could be combined with ,,, and to produce ,,, and , reducing the number of sorts needed from 5 to 1. The typebars of "normal" characters struck a rod as they moved the
metal character desired toward the ribbon and platen, and each rod depression moved the platen forward the width of one character. Dead keys had a typebar shaped so as not to strike the rod.
Character sizes In English-speaking countries, ordinary typewriters printing fixed-width characters were standardized to print six horizontal lines per vertical inch, and had either of two variants of character width, one called
pica for ten characters per horizontal inch and the other
elite, for twelve. This differed from the use of these terms in printing, where
pica is a linear unit (approximately of an inch) used for any measurement, the most common one being the height of a typeface.
Color Some ribbons were inked in black and red stripes, each being half the width and running the entire length of the ribbon. A lever on most machines allowed switching between colors, which was useful for bookkeeping entries where negative amounts were highlighted in red. The red color was also used on some selected characters in running text, for emphasis. When a typewriter had this facility, it could still be fitted with a solid black ribbon; the lever was then used to switch to fresh ribbon when the first stripe ran out of ink. Some typewriters also had a third position which stopped the ribbon being struck at all. This enabled the keys to hit the paper unobstructed, and was used for cutting stencils for
stencil duplicators (aka mimeograph machines).
"Noiseless" designs The first typewriter to have the sliding type bars (laid out horizontally like a fan) that enable a typewriter to be "noiseless" was the American made Rapid which appeared briefly on the market in 1890. The Rapid also had the remarkable ability for the typist to have entire control of the carriage by manipulation of the keyboard alone. The two keys that achieve this are positioned at the top of the keyboard (seen in the detail image below). They are a "Lift" key that advances the paper, on the platen, to the next line and a "Return" key that causes the carriage to automatically swing back to the right, ready for one to type the new line. So an entire page could be typed without one's hands leaving the keyboard. In the early part of the 20th century, a typewriter was marketed under the name Noiseless and advertised as "silent". It was developed by Wellington Parker Kidder and the first model was marketed by the Noiseless Typewriter Company in 1917. Noiseless portables sold well in the 1930s and 1940s, and noiseless standards continued to be manufactured until the 1960s.
Electric designs Although electric typewriters would not achieve widespread popularity until nearly a century later, the basic groundwork for the electric typewriter was laid by the
Universal Stock Ticker, invented by
Thomas Edison in 1870. This device remotely printed letters and numbers on a stream of paper tape from input generated by a specially designed typewriter at the other end of a telegraph line.
Early electric models Some electric typewriters were patented in the 19th century, but the first machine known to be produced in series is the Cahill of 1900. Another electric typewriter was produced by the
Blickensderfer Manufacturing Company, of
Stamford, Connecticut, in 1902. Like the manual Blickensderfer typewriters, it used a cylindrical typewheel rather than individual typebars. The machine was produced in several variants but apparently not a commercial success, having come to market ahead of its time, before ubiquitous
electrification. The next step in the development of the electric typewriter came in 1910, when Charles and Howard Krum filed a patent for the first practical
teletypewriter. The Krums' machine, named the Morkrum Printing Telegraph, used a typewheel rather than individual typebars. This machine was used for the first commercial teletypewriter system on Postal Telegraph Company lines between
Boston and New York City in 1910.
James Fields Smathers of Kansas City invented what is considered the first practical power-operated typewriter in 1914. In 1920, after returning from Army service, he produced a successful model and in 1923 turned it over to the Northeast Electric Company of Rochester for development. Northeast was interested in finding new markets for their electric motors and developed Smathers's design so that it could be marketed to typewriter manufacturers, and from 1925 Remington Electric typewriters were produced powered by Northeast's motors. After some 2,500 electric typewriters had been produced, Northeast asked Remington for a firm contract for the next batch. However, Remington was engaged in merger talks, which would eventually result in the creation of
Remington Rand and no executives were willing to commit to a firm order. Northeast instead decided to enter the typewriter business for itself, and in 1929 produced the first Electromatic Typewriter. In 1928,
Delco, a division of
General Motors, purchased Northeast Electric, and the typewriter business was spun off as Electromatic Typewriters, Inc. In 1933, Electromatic was acquired by
IBM, which then spent
$1 million on a redesign of the Electromatic Typewriter, launching the IBM Electric Typewriter Model 01. In 1931, an electric typewriter was introduced by Varityper Corporation. It was called the
Varityper, because a narrow cylinder-like wheel could be replaced to change the
typeface. In 1941, IBM announced the Electromatic Model 04 electric typewriter, featuring the revolutionary concept of proportional spacing. By assigning varied rather than uniform spacing to different sized characters, the Type 4 recreated the appearance of a typeset page, an effect that was further enhanced by including the 1937 innovation of carbon-film ribbons that produced clearer, sharper words on the page.
IBM Selectric IBM introduced the
IBM Selectric typewriter in 1961, which replaced the typebars with a spherical element (or
typeball) slightly smaller than a
golf ball, with reverse-image letters molded into its surface. The Selectric used a system of latches, metal tapes, and pulleys driven by an electric motor to rotate the ball into the correct position and then strike it against the ribbon and platen. The typeball moved laterally in front of the paper, instead of the previous designs using a platen-carrying carriage moving the paper across a stationary print position. Due to the physical similarity, the typeball was sometimes referred to as a "golfball". The typeball design had many advantages, especially the elimination of "jams" (when more than one key was struck at once and the typebars became entangled) and in the ability to change the typeball, allowing multiple typefaces to be used in a single document. The IBM Selectric became a commercial success, dominating the office typewriter market for at least two decades. Later models of IBM Executives and Selectrics replaced inked fabric ribbons with "carbon film" ribbons that had a dry black or colored powder on a clear plastic tape. These could be used only once, but later models used a cartridge that was simple to replace. A side effect of this technology was that the text typed on the machine could be easily read from the used ribbon, raising issues where the machines were used for preparing classified documents (ribbons had to be accounted for to ensure that typists did not carry them from the facility). A variation known as "Correcting Selectrics" introduced a correction feature, later imitated by competing machines, where a sticky tape in front of the carbon film ribbon could remove the black-powdered image of a typed character, eliminating the need for little bottles of white dab-on correction fluid and for hard erasers that could tear the paper. These machines also introduced selectable "pitch" so that the typewriter could be switched between
pica type (10 characters per inch) and elite type (12 per inch), even within one document. Even so, all Selectrics were
monospaced—each character and letterspace was allotted the same width on the page, from a capital "W" to a period. IBM did produce a successful typebar-based machine with five levels of proportional spacing, called the
IBM Executive. The only fully electromechanical Selectric Typewriter with fully proportional spacing and which used a Selectric type element was the expensive
Selectric Composer, which was capable of right-margin justification (typing each line twice was required, once to calculate and again to print) and was considered a
typesetting machine rather than a typewriter. Composer typeballs physically resembled those of the Selectric typewriter but were not interchangeable. ,
Bold, and
Italic typefaces were available by changing the type ball. In addition to its electronic successors, the
Magnetic Tape Selectric Composer (MT/SC), the Mag Card Selectric Composer, and the Electronic Selectric Composer, IBM also made electronic typewriters with proportional spacing using the Selectric element that were considered typewriters or
word processors instead of typesetting machines. The first of these was the relatively obscure Mag Card Executive, which used 88-character elements. Later, some of the same typestyles used for it were used on the 96-character elements used on the IBM Electronic Typewriter 50 and the later models 65 and 85. By 1970, as
offset printing began to replace
letterpress printing, the Composer would be adapted as the output unit for a
phototypesetting system. The system included a computer-driven input station to capture the key strokes on magnetic tape and insert the operator's format commands, and a Composer unit to read the tape and produce the formatted text for photo reproduction. The
IBM 2741 terminal was a popular example of a Selectric-based computer terminal, and similar mechanisms were employed as the console devices for many
IBM System/360 computers. These mechanisms used "ruggedized" designs compared to those in standard office typewriters.
Later electric models {{Listen Some of IBM's advances were later adopted in less expensive machines from competitors. For example,
Smith-Corona electric typewriters introduced in 1973 switched to interchangeable Coronamatic (SCM-patented) ribbon cartridges.
Electronic typewriters The final major development of the typewriter was the electronic typewriter. Most of these replaced the typeball with a plastic or metal
daisy wheel mechanism (a disk with the letters molded on the outside edge of the "petals"), or a thermal print head. The daisy wheel concept first emerged in printers developed by
Diablo Systems in the 1970s. The first electronic daisywheel typewriter marketed in the world (in 1976) is the Olivetti Tes 501, and subsequently in 1978, the Olivetti ET101 (with function display) and Olivetti TES 401 (with text display and floppy disk for memory storage). This has allowed Olivetti to maintain the world record in the design of electronic typewriters, proposing increasingly advanced and performing models in the following years. Unlike the Selectrics and earlier models, these really were "electronic" and relied on integrated circuits and electromechanical components. These typewriters were sometimes called
display typewriters,
dedicated word processors or
word-processing typewriters, although the latter term was also frequently applied to less sophisticated machines that featured only a tiny, sometimes just single-row display. Sophisticated models were also called
word processors, although today that term almost always denotes a type of software program. Manufacturers of such machines included Olivetti (TES501, first totally electronic Olivetti word processor with daisywheel and floppy disk in 1976; TES621 in 1979, etc.),
Brother (Brother WP1 and WP500, etc., where WP stood for word processor),
Canon (
Canon Cat),
Smith-Corona (PWP, i.e. Personal Word Processor line) and
Philips/
Magnavox (
VideoWriter). File:Type.jpg|Electronic typewriter – the final stage in typewriter development. A 1989
Canon Typestar 110. File:Brother WP1-IMG 6991.jpg|The Brother WP1, an electronic typewriter complete with a small screen and a
floppy disk reader
Decline The pace of change was so rapid that it was common for clerical staff to have to learn several new systems, one after the other, in just a few years. While such rapid change is commonplace today, and is taken for granted, this was not always so; in fact, typewriting technology changed very little in its first 80 or 90 years. Due to falling sales, IBM sold its typewriter division in 1991 to the newly formed
Lexmark, completely exiting from a market it once dominated. The increasing dominance of personal computers,
desktop publishing, the introduction of low-cost, truly high-quality
laser and
inkjet printer technologies, and the pervasive use of
web publishing,
email,
text messaging, and other electronic communication techniques have largely replaced typewriters in the United States. Still, , typewriters continued to be used by a number of government agencies and other institutions in the US, where they are primarily used to fill preprinted forms. According to a Boston typewriter repairman quoted by
The Boston Globe, "Every maternity ward has a typewriter, as well as funeral homes." A rather specialized market for typewriters exists due to the regulations of many correctional systems in the US, where prisoners are prohibited from having computers or telecommunication equipment, but are allowed to own typewriters. The Swintec corporation (headquartered in
Moonachie, New Jersey), which, as of 2011, still produced typewriters at its overseas factories (in Japan,
Indonesia, and/or
Malaysia), manufactures a variety of typewriters for use in prisons, made of clear plastic (to make it harder for prisoners to hide prohibited items inside it). As of 2011, the company had contracts with prisons in 43 US states. In April 2011, Godrej and Boyce, a
Mumbai-based manufacturer of mechanical typewriters, closed its doors, leading to a flurry of news reports that the "world's last typewriter factory" had shut down. The reports were quickly contested, with opinions settling to agree that it was indeed the world's last producer of standard manual typewriters. In November 2012, Brother's UK factory manufactured what it claimed to be the last typewriter ever made in the UK; the typewriter was donated to the
London Science Museum. Russian typewriters use
Cyrillic, which has made the ongoing
Azerbaijani reconversion from
Cyrillic to
Latin alphabet more difficult. In 1997, the government of
Turkey offered to donate western typewriters to the
Republic of Azerbaijan in exchange for more zealous and exclusive promotion of the Latin alphabet for the Azerbaijani language; this offer, however, was declined. In Latin America and Africa, mechanical typewriters are still common because they can be used without electrical power. In Latin America, the typewriters used are most often Brazilian models; in 2012, Brazil was continuing to produce mechanical (Facit) and electronic (Olivetti) typewriters. The early 21st century saw revival of interest in typewriters among certain subcultures, including
makers,
steampunks,
hipsters, and street poets. == Correction technologies ==