Point (typography) explained

Point
Standard:typographic unit
Quantity:length
Units1:typographic units
Inunits1: picas
Units2:imperial/U.S. units
Inunits2: in
Units3:metric (SI) units
Inunits3:NaNinches

In typography, the point is the smallest unit of measure. It is used for measuring font size, leading, and other items on a printed page. The size of the point has varied throughout printing's history. Since the 18th century, the size of a point has been between 0.18 and 0.4 millimeters. Following the advent of desktop publishing in the 1980s and 1990s, digital printing has largely supplanted the letterpress printing and has established the desktop publishing (DTP) point as the de facto standard. The DTP point is defined as of an inch and, as with earlier American point sizes, is considered to be of a pica.

In metal type, the point size of the font describes the height of the metal body on which the typeface's characters were cast. In digital type, letters of a font are designed around an imaginary space called an em square. When a point size of a font is specified, the font is scaled so that its em square has a side length of that particular length in points. Although the letters of a font usually fit within the font's em square, there is not necessarily any size relationship between the two, so the point size does not necessarily correspond to any measurement of the size of the letters on the printed page.[1]

History

The point was first established by the Milanese typographer, Francesco Torniella da Novara (– 1589) in his 1517 alphabet, L'Alfabeto. The construction of the alphabet is the first based on logical measurement called "Punto," which corresponds to the ninth part of the height of the letters or the thickness of the principal stroke.[2] [3]

Notations

A measurement in points can be represented in three different ways. For example, 14 points (1 pica plus 2 points) can be written:

Varying standards

Year mm inch
≈ 
Fournier[4] 1737≈ 0.345 
American1886≈ = <-- exact for contemporary US inch, approximate for international inch -->
Japanese[5] 1962≈ 
TeX 1982= 0.≈ 
PostScript, CSS , TeX 1984= 0.352= 0.013
≈ 
Didot1783 ≈ ≈ 
Berthold1878 ≈ 0.376 ≈ 
DIN actual,[6] TeX 1964≈ 
DIN nominal, TeX 1984≈ 
Other
Truchet1694≈ 0.188≈ 
L'Imprimerie Nationale nominal1810= 0.400≈ 
L'Imprimerie Nationale actual1810= 0.398 77 mm≈ 
DIN,[7] Japanese, CSS 1999≈ 

There have been many definitions of a "point" since the advent of typography. Traditional continental European points at about are usually a bit larger than English points at around .

French points

The Truchet point, the first modern typographic point, was of a French inch or of the royal foot. It was invented by the French clergyman Sébastien Truchet. During the metrication of France amid its revolution, a 1799 law declared the meter to be exactly 443.296 French lines long. This established a length to the royal foot of  m or about 325 mm. The Truchet point therefore became equal to  mm or about . It has also been cited as exactly 0.188 mm.

The Fournier point was established by Pierre Simon Fournier in 1737.[8] [9] The system of Fournier was based on a different French foot of c. 298 mm. With the usual convention that 1 foot equals 12 inches, 1 inch (pouce) was divided into 12 lines (lignes) and 1 line was further divided into 6 typographic points (points typographiques). One Fournier point is about 0.0135 English inches.

Fournier printed a reference scale of 144 points over two inches; however, it was too rough to accurately measure a single point.

The Fournier point did not achieve lasting popularity despite being revived by the Monotype Corporation in 1927. It was still a standard in Belgium, in parts of Austria, and in Northern France at the beginning of the 20th century. In Belgium, the Fournier system was used until the 1970s and later. It was called the "mediaan"-system.

The Didot point, established by François-Ambroise Didot in 1783,[10] was an attempt to improve the Fournier system. He did not change the subdivisions (1 inch = 12 subdivisions = 72 points), but defined it strictly in terms of the royal foot, a legal length measure in France: the Didot point is exactly of a French foot or of a French inch, that is (by 1799)  mm or about . Accordingly, one Didot point is exactly two Truchet points.

However, 12 Fournier points turned out to be 11 Didot points, giving a Fournier point of about ; later sources state it as being . To avoid confusion between the new and the old sizes, Didot also rejected the traditional names, thus parisienne became corps 5, nonpareille became corps 6, and so on. The Didot system prevailed because the French government demanded printing in Didot measurements.[11]

Approximations were subsequently employed, largely owing to the Didot point's unwieldy conversion to metric units (the divisor of its conversion ratio has the prime factorization of).

In 1878, Hermann Berthold defined 798 points as being equal to 30 cm, or 2660 points equalling 1 meter: that gives around to the point.[12] [13] [14] [15] A more precise number,, sometimes is given; this is used by TeX as the unit. This has become the standard in Germany and Central and Eastern Europe.[16] This size is still mentioned in the technical regulations of the Eurasian Economic Union.[17]

Metric points

pdfTEX, but not plain TeX or LaTeX, also supports a new Didot point (nd) at  mm or and refers to a not further specified 1978 redefinition for it.

The French National Print Office adopted a point of  mm or in about 1810 and continues to use this measurement today (though "recalibrated" to).[18] [19] [20] Japanese[21] and German standardization bodies instead opted for a metric typographic base measure of exactly  mm or, which is sometimes referred to as the quart in Japan. The symbol Q is used in Japanese after the initial letter of quarter millimeter. Due to demand by Japanese typesetters, CSS adopted Q in 2015.[22] [23]

ISO 128 specifies preferred line thicknesses for technical drawings and ISO 9175 specifies respective pens. The steps between nominal sizes are based on a factor of √2 ≈ 1.414 in order to match ISO 216 paper sizes. Since the set of sizes includes thicknesses of 0.1 mm, 0.5 mm, 1 mm and 2 mm, there is also one of 0.35 mm which is almost exactly 1 pica point. In other words, 2−1.5 mm = mm approximates an English typographic point rather well.

American points

The basic unit of measurements in American typography was the pica,[24] [25] [26] usually approximated as one sixth of an inch, but the exact size was not standardized, and various type foundries had been using their own.

During and after the American Revolutionary War, Benjamin Franklin was sent as commissioner (Ambassador) for the United States to France from December 1776 to 1785.[27] While living there he had close contact with the Fournier family, including the father and Pierre Simon Fournier. Franklin wanted to teach his grandson Benjamin Franklin Bache about printing and typefounding, and arranged for him to be trained by Francois Ambroise Didot. Franklin then imported French typefounding equipment to Philadelphia to help Bache set up a type-foundry. Around 1790, Bache published a specimen sheet with some Fournier types.[28] [29] After the death of Franklin, the matrices and the Fournier mould were acquired by Binny and Ronaldson, the first permanent type-foundry in America. Successive mergers and acquisitions in 1833, 1860 and 1897 saw the company eventually become known as MacKellar, Smith & Jordan. The Fournier cicero mould was used by them to cast pica-sized type.

Nelson Hawks proposed, like Fournier, to divide one American inch exactly into six picas, and one pica into 12 points. However, this saw an opposition because the majority of foundries had been using picas less than one sixth of an inch. So in 1886, after some examination of various picas, the Type Founders Association of the United States approved the pica of the L. Johnson & Co. foundry of Philadelphia (the "Johnson pica") as the most established. The Johnson foundry was influential, being America's first and oldest foundry; established as Binny & Ronaldson in 1796, it would go through several names before being the largest of the 23 foundries that would merge in 1892 to form the American Type Founders Co.[30] The official definition of one pica is 0.166044inch, and one point is 0.013837inch. That means 6 picas or 72 points constitute standard inches. A less precise definition is one pica equals 0.166inch, and one point 0.01383inch.[31] It was also noticed that 83 picas is nearly equal to 35 cm, so the Type Founders Association also suggested using a 35 cm metal rod for measurements, but this was not accepted by every foundry.

This has become known as the American point system. The British foundries accepted this in 1898.

In modern times this size of the point has been approximated as exactly of the inch[32] by Donald Knuth for the default unit of his TeX computer typesetting system and is thus sometimes known as the, which is 0. mm.

Old English points

Although the English Monotype manuals used 1 pica = .1660 inch, the manuals used on the European continent use another definition: there 1 pica = .1667 inch, the Old English pica.

As a consequence all the tables of measurements in the German, Dutch, French, Polish and all other manuals elsewhere on the European continent for the composition caster and the super-caster are different in quite some details.

The Monotype wedges used at the European continent are marked with an extra E behind the set-size: for instance: 5-12E, 1331-15E etc. When working with the E-wedges in the larger sizes the differences will increase even more.[33]

Desktop publishing point

The desktop publishing point (DTP point) or PostScript point is defined as or 0.013 of the international inch, making it equivalent to  mm = 0.352 mm. Twelve points make up a pica, and six picas make an inch.

This specification was developed by John Warnock and Charles Geschke when they created Adobe PostScript. It was adopted by Apple Computer as the standard for the display resolution of the original Macintosh desktop computer and the print resolution for the LaserWriter printer.[34] [35]

In 1996, it was adopted by W3C for Cascading Stylesheets (CSS) where it was later related at a fixed 3:4 ratio to the pixel due to a general (but wrong) assumption of 96 pixel-per-inch screens.

Apple point

Since the advent of high-density "Retina" screens with a much higher resolution than the original 72 dots per inch, Apple's programming environment Xcode sizes GUI elements in points that are scaled automatically to a whole number of physical pixels in order to accommodate for screen size, pixel density and typical viewing distance. This Cocoa point is equivalent to the pixel px unit in CSS, the density-independent pixel dp on Android[36] and the effective pixel epx or ep in Windows UWP.

Font sizes

See main article: Traditional point-size names.

In lead typecasting, most font sizes commonly used in printing have conventional names that differ by country, language and the type of points used.

Desktop publishing software and word processors intended for office and personal use often have a list of suggested font sizes in their user interface, but they are not named and usually an arbitrary value can be entered manually. Microsoft Word, for instance, suggests every even size between 8 and 28 points and, additionally, 9, 11, 36, 48 and 72 points, i.e. the larger sizes equal 3, 4 and 6 picas. While most software nowadays defaults to DTP points, many allow specifying font size in other units of measure (e.g., inches, millimeters, pixels), especially code-based systems such as TeX and CSS.

See also

Further reading

Notes and References

  1. Web site: Phinney. Thomas. Point Size and the Em Square: Not What People Think. Phinney on Fonts. 16 August 2012. 26 February 2018.
  2. Book: Mardersteig, Giovanni. The alphabet of Francesco Torniello da Novara [1517]: Followed by a comparison with the alphabet of Fra Luca Pacioli. Officina Bodoni. 1971.
  3. Book: Healey, Robin. Italian Literature Before 1900 in English Translation: An Annotated Bibliography, 1929-2008. University of Toronto Press. 2011. 9781442642690.
  4. Various sources give different sizes, namely: ≈ , ≈ , ≈ , (exactly), ≈ , ≈ .
  5. JIS Z 8305. 活字の基準寸法. Dimensions of Printing Types.
  6. DIN 16507-1:1998 and its predecessors, at least since 1964, for lead typecasting defined 2660 points to measure 1000.333 mm at 20 °C, but for public communication it later introduced a rounder value.
  7. DIN 16507-2 (1984, 1999) does not specify a custom unit for electronic typography, but measures using a module.
  8. Book: Fournier, Pierre Simon. Manuel typographique. 1764. 125–138.
  9. Book: De Vinne, Theodore Low. The practice of typography. 1. New York. Century Co.. 1900. 133–145.
  10. Book: Baines. Phil. Haslam. Andrew. Type & Typography. 2005. Laurence King Publishing. 978-1-85669-437-7. 93.
  11. L. Ronner, Van leerling tot Zetter, 1913, N.V.De nieuwe Tijd, Amsterdam, pag 30.
  12. Smalian. Hermann. Type Systems of To-day. The British Printer. XII. 68. 1899. 130–131. They commissioned for this purpose the well-known Berlin brass rule manufacturer, H. Berthold, who supplies brass rules not only to most of the German foundries but also to many foreign houses, and he, in conjunction with Prof. W. Fürster, the chief director of the Berlin Observatory, agreed that 2660 typographical points of the Didot system should correspond to one metre. Accordingly the Standard Gauge Commission in Berlin in 1879 arranged a standard measure of 30 centimetres = 133 nonpareil or 798 typographical points, and gave a copy to all the German foundries, and since that time disputes about the Didot depth were unknown in Germany..
  13. Book: Brekle, Herbert E.. Schrift und Schriftlichkeit / Writing and its Use. https://books.google.com/books?id=wxc7FAIBwGMC&pg=PA211. 1994. Walter de Gruyter. 978-3-11-020323-3. 210ff. Typographie.
  14. Book: Funke, Fritz. Buchkunde. 1998. De Gruyter. 978-3-11-094929-2. 194.
  15. Book: Blana, Hubert. Die Herstellung: Ein Handbuch für die Gestaltung, Technik und Kalkulation von Buch, Zeitschrift und Zeitung. 1999. Walter de Gruyter. 978-3-11-096787-6. 101.
  16. Book: GOST 3489.1-71. Printing types (Russian and Roman graphic bases). Group arrangement. Indexing. Base line. Characters per 4 picas. ru:ГОСТ 3489.1-71. Шрифты типографские (на русской и латинской графических основах). Группировка. Индексация. Линия шрифта. Емкость. §1.3. Кегль измеряется в типографских пунктах. Типографский пункт равен 0,376 мм.. ru.
  17. Статья 8. Пункт 11. // ТР ТС 007/2011. Требования безопасности издательской (книжной и журнальной) продукции, школьно-письменных принадлежностей.
  18. Mosley. James. French academicians and modern typography: designing new types in the 1690s. Typography Papers. 2. 1997. 5–29. The point in current use at the Imprimerie Nationale measures 0.39877 mm. This appears to be the result of a 'recalibration', for which no date can be given, of the point of 0.4 mm..
  19. Book: Bulletin du bibliophile. 2002. 73. Promodis . 9782765407768. These latter figures give the size in the 'points millimétriques' of about 0.4 mm that are said to have been introduced at the Imprimerie impériale by Firmin Didot and which are the basis for the 'point IN' used today at the Imprimerie nationale..
  20. Web site: Type bodies compared. Typefoundry. 30 April 2008.
  21. JIS X 4052:2000, JIS Z 8125:2004
  22. Web site: CSS Values and Units Module Level 3. World Wide Web Consortium. 29 September 2016.
  23. Web site: CSS Values and Units Module Level 3. World Wide Web Consortium. 11 June 2015.
  24. Book: Legros. Lucien Alphonse. Grant. John Cameron. Typographical Printing-Surfaces. 1916. Longmann, Green, and Co.. London and New York. 57–60. 9785872323303.
  25. Book: De Vinne, Theodore Low. The practice of typography. 1. New York. Century Co.. 1900. 145–156.
  26. Book: Hyde. Grant Milnor. Newspaper Editing: A Manual for Editors, Copyreaders, and Students of Newspaper Desk Work. 1920. D. Appleton and Company. New York and London. 226–227.
  27. http://hdl.library.upenn.edu/1017/d/ead/upenn_rbml_MsColl900 Benjamin Franklin papers
  28. Updike, I, p. 257, II pp. 152-3
  29. Allen Huet, Fournier the compleat typographer, 1972, London, Frederik Muller Ltd, page 3, 4, 62, 63
  30. Web site: Shaw . Paul . From the Archives no. 12—The Formation of American Type Founders . Blue Pencil . September 6, 2023.
  31. The American Point System. American Printer and Lithographer. 1890. 11. 89.
  32. Book: Knuth, Donald E.. The TeXbook. 17th revised. Addison-Wesley. 1990. 58.
  33. Rich Hopkins, Origin of the American Point system for Printers; Type Measurement, Jill & Dale private Press, Terra Alta, West Virginia, 1976, 2e impression 1989
  34. Book: Tucker, H. A. . https://books.google.com/books?id=YlmafkntEqIC&pg=PA296 . Desktop Publishing . Maurice M. de . Ruiter . Advances in Computer Graphics III . Springer . 1988 . 3-540-18788-X . 296 .
  35. Book: Spring, Michael B. . Electronic printing and publishing: the document processing revolution . CRC Press . 1991 . 0-8247-8544-4 . 46 .
  36. Web site: Support different pixel densities . Android Developers Documentation . 21 June 2022.