Abjad is the technical term for the type of writing system used by Semitic languages (Hebrew, Arabic, etc.), where there are glyphs for all the consonants but the reader must be prepared to guess what vowel to add between two consonants.
Both Hebrew and Arabic have optional vowel marks and are called "impure" abjads. Ancient Phoenician had nothing but consonants and is a "pure" abjad.
See Also: alphabet, abugida, syllabary and the relevant Wikipedia article (http://en.wikipedia.org/wiki/Abjad).
An abugida is somewhere in between an alphabet and a syllabary. The Indic writing systems are probably the best known abugidas.
In most abugidas there are independant glyphs for the consonants, and each consonant is implicitly followed by a default vowel sound. All vowels other than the default will be marked by either diacritics or some other modification to the base consonant.
An abugida differs from a syllabary in that there is a common theme to the the images representing a syllable beginning with a given consonant (that is, the glyph for the consonant), while in a syllabary each syllable is distinct even if two start with a common consonant.
An abugida differs from an abjad in that vowels (other than the default) must be marked in the abugida.
See Also: alphabet, abjad, syllabary and the relevant Wikipedia article (http://en.wikipedia.org/wiki/Abugida).
The distance between the start of this glyph and the start of the next glyph. Sometimes called the glyph's width. See also Vertical Advance Width.
A writing system where there are glyphs for all phonemes -- consonants and vowels alike -- and (in theory anyway) all phonemes in a word will be marked by an appropriate glyph.
See Also: abjad, abugida, syllabary and the relevant Wikipedia article (http://en.wikipedia.org/wiki/Alphabet).
Apple's extension to basic TrueType fonts. Includes contextual substitutions, ligatures, kerning, etc. Also includes distortable fonts.
The piece of the letter r that hangs off to the right.
A stem on a lower case letter which extends above the x-height. "l" has an ascender.
See also X-height, Cap-height, Descender, Overshoot, Baseline
Used to specify mark-to-base and cursive GPOS subtables.
In traditional typography the ascent of a font was the distance from the top of a block of type to the baseline.
Its precise meaning in modern typography seems to vary with different definers.
Apple's advanced typographical system. Also called Apple Advanced Typography.
The baseline is the horizontal line on which the (latin, greek, cyrillic) letters sit. The baseline will probably be in a different place for different scripts. In Indic scripts most letters descend below the baseline. In CJK scripts there is also a vertical baseline usually in the middle of the glyph. The BASE and bsln tables allow you to specify how the baselines of different scripts should be aligned with respect to each other.
See also X-height, Cap-height, Ascender, Descender, Overshoot
Bézier curves are described in detail in the Bézier section of the main manual.
Bi-Directional text. That is a section of text which contains both left-to-right and right-to-left scripts. English text quoting Arabic, for example. Things get even more complex with nested quotations. TheUnicode standard contains an algorithm for laying out Bidi text. See also: Boustrophedon.
Any of various type families based on medieval handwriting.
See also gothic.
The first 65536 code points of Unicode. These contain most of the ordinary characters in the modern world. See Also
A common font style. The stems of the glyphs are wider than in the normal font, giving the letters a darker impression. Bold is one of the fewLGC styles that translate readily to other scripts.
The round part of the letter.
A (modern~1911) Chinese (Mandarin) alphabet used to provide phonetic transliteration of Han ideographs in dictionaries.
Writing "as the ox plows", that is alternating between left to right and right to left writing directions. Early alphabets (Old Canaanite, and the very early greek writings (and, surprisingly, fuþark)) used this. Often the right to left glyphs would be mirrors of the left to right ones. As far as I know, no modern writing system uses this method (nor does OpenType have any support for it). See Also Bidi.
The height of a capital letter above the baseline (a letter with a flat top like "I" as opposed to one with a curved one like "O").
See also X-height, Ascender, Descender, Overshoot, Baseline
Compact Font Format most commonly used within OpenType postscript fonts, but is a valid font format even without a SFNTwrapper. This is the native font format for fonts with PostScript Type2 charstrings.
A character is a Platonic ideal reified into at least one glyph. For example the letter "s" is a character which is reified into several different glyphs: "S", "s", "s", long-s, etc. Note that these glyphs can look fairly different from each other, however although the glyph for an integral sign might be the same as the long-s glyph, these are in fact different characters.
A character set is an unordered set of characters.
Character Identifier, a number. In some CJK PostScript fonts the glyphs are not named but are refered to by a CID number.
A PostScript font in which the glyphs are index by CID and not by name.
Chinese, Japanese, Korean. These three languages require fonts with a huge number of glyphs. All three share a writing system based on Chinese ideographs (though they have undergone separate evolution in each country, indeed mainland Chinese fonts are different from those used in Taiwan and Hong Kong).
Japanese and Korean also have phonetic syllabaries. The Japanese have two syllabaries, Hiragana and katakana which have about 60 syllables. The Koreans have one syllabary, hangul with tens of thousands of syllables.
Chinese, Japanese, Korean, Vietnamese. These four languages require fonts with a huge number of glyphs.
A condensed font is one where the space between the stems of the glyphs, and the distance between glyphs themselves has been reduced.
If a glyph contains two hints where the start or end point of one is within the range of the other then these hints conflict. They may not be active simultaneously.
The counter of a glyph is the white part which is either fully or partially enclosed. The o and n both have counters. The i and l do not. The e and both have counters. The B has two counters.
A stem on a lower case letter which extends below the baseline. "p" has a descender.
See also X-height, Cap-height, Ascender, Overshoot, Baseline
In traditional typography the descent of a font was the distance from the bottom of a block of type to the baseline.
Its meaning in modern typography has become less precise.
A concept in OpenType which allows you to enter spacing adjustments geared to rasterization at particular pixel sizes. If a kerning value that works most of the time leads to an ugly juxtaposition of glyphs on a 12 pixel high font, then you can add a special tweak to the spacing that only is applicable at 12 pixels (and another one at 14 and 18, or whatever is needed). Similar functionality is needed for anchored marks.
Many lanaguges use letters which have have marks above or below them of even crossing the letters. These marks are called diacritics. Sometimes they are also caleed "accents" although this is a less precise term. Examples of these letters include À à å Å Ü ü Ø ø Ç ç.
The European point. 62 2/3 points per 23.566mm ( 2.66pt/mm or 67.55pt/inch ). There is also a "metric" didiot point: .4mm.
A linear unit equal to the point size of the font. In a 10 point font, the em will be 10 points. An em-space is white-space that is as wide as the point size. An em-dash is a horizontal bar that is as wide as the point size.
An em-square is a square one em to each side. In traditional typography (when each letter was cast in metal) the glyph had to be drawn within the em-square.
In a scalable font the "em" is subdivided into units. In a postscript font there are usually 1000 units to the em. In a TrueType font there might be 512, 1024 or 2048 units to the em. In an Ikarus font there are 15,000 units. FontForge uses these units as the basis of its coordinate system.
One half of an "em"
An encoding is a mapping from a set of bytes onto a character set. It is what determines which byte sequence represents which character. The words "encoding" and "character set" are often used synonymously. The specification for ASCII specifies both a character set and an encoding. But CJK character sets often have multiple encodings for the character set (and multiple character sets for some encodings).
In more complicated cases it is possible to have multiple glyphs associated with each character (as in arabic where most characters have at least 4 different glyphs) and the client program must pick the appropriate glyph for the character in the current context.
The old germanic letter "ð" for the voiced (English) "th" sound (the sound in "this" -- most English speakers aren't even aware that "th" in English has two sounds associated with it, but it does, see also Thorn)
To determine if a pixel should be filled using this rule, draw a line from the pixel to infinity (in any direction) then count the number of times contours cross this line. If that number is odd then fill the point, if it is even then do not fill the point. This method is used for fonts by postscript rasterizers after level 2.0 of PostScript. See Also Non-Zero Winding Number Fill.
An extended font is one where the space between the stems of the glyphs, and the distance between glyphs themselves has been increased.
An extremum is the point on a mathematical curve where the curve attains its maximum or minimum value. On a continuous curve this can happen at the endpoints (which is dull) or where dx/dt=0 or dy/dt=0.
In font design, the extrema of a glyph are the top-most and bottom-most points of the outline, as well as its left-most and right-most points. Making sure that a glyph has on-curve points at all of its extrema is important, because it simplifies text rendering when the font is used.
When creating fonts for complex scripts (and even for less complex scripts) various transformations (like ligatures) must be applied to the input glyphs before they are ready for display. These transformations are identified as font features and are tagged with (in OpenType) a 4 letter tag or (in Apple) a 2 number identfier. The meanings of these features are predefined by MicroSoft and Apple. FontForge allows you to tag each lookup with one or several features when you create it (or later).
This is a text syntax designed by Adobe to describe OpenType features. It can be used to move feature and lookup information from one font to another.
These are roughly equivalent to OpenType's Features above, they are defined by Apple.
A collection of glyphs, generally with at least one glyph associated with each character in the font's character set, often with an encoding.
A font contains much of the information needed to turn a sequence of bytes into a set of pictures representing the characters specified by those bytes.
In traditional typesetting a font was a collection of little blocks of metal each with a graven image of a letter on it. Traditionally there was a different font for each point-size.
A collection of related fonts. Often including plain, italic and bold styles.
A library for rasterizing fonts. Used extensively in FontForge to understand the behavior of truetype fonts and to do better rasterization than FontForge could accomplish unaided.
The old germanic runic script.
Sometimes it is important to indicate that a horizontal edge is indeed horizontal. But the edge has no corresponding edge with which to make a normal stem. In this case a special hint is used with a width of -20 (or -21). A ghost hint must lie entirely within a glyph. If it is at the top of a contour use a width of -20, if at the bottom use -21. Ghost hints should also lie within BlueZones.
(The spec also mentions vertical ghost hints, but as there are no vertical bluezones it is not clear how these should be used).
A glyph is an image, often associated with one or several characters. So the glyph used to draw "f" is associated with the character f, while the glyph for the "fi" ligature is associated with both f and i. In simple latin fonts the association is often one to one (there is exactly one glyph for each character), while in more complex fonts or scripts there may be several glyphs per character (In renaissance printing the letter "s" had two glyphs associated with it, one, the long-s, was used initially and medially, the other, the short-s, was used only at the end of words). And in the ligatures one glyph is associated with two or more characters.
Fonts are collections of glyphs with some form of mapping from character to glyph.
Before TrueType glyphs are rasterized they go through a process called grid fitting where a tiny program (associated with each glyph) is run which moves the points on the glyph's outlines around until they fit the pixel grid better.
The German monks at the time of Gutenberg used a black-letter writing style, and he copied their handwriting in his typefaces for printing. Italian type designers (after printing spread south) sneered at the style, preferring the type designs left by the Romans. As a term of contempt they used the word gothic, the style of the goths who helped destroy the roman empire.
Graphite is an extension to TrueType which embeds several tables into a font containing rules for contextual shaping, ligatures, reordering, split glyphs, bidirectionality, stacking diacritics, complex positioning, etc.
This sounds rather like OpenType -- except that OpenType depends on the text layout routines knowing a lot about the glyphs involved. This means that OpenType fonts cannot be designed for a new language or script without shipping a new version of the operating system. Whereas Graphite tables contain all that hidden information.
Apple's Advanced Typography provides a better comparison, but Graphite tables are supposed to be easier to build.
SIL International provides a free Graphite compiler .
See also sans-serif.
The ideographic characters used in China, Japan and Korea (and, I believe, in various other asian countries as well (Vietnam?)), all based on the writing style that evolved in China.
The Korean syllabary. The only syllabary (that I'm aware of anway) based on an alphabet -- the letters of the alphabet never appear alone, but only as groups of two or three making up a syllable.
The Korean name for the Han characters
These are described in detail in the main manual. They help the rasterizer to draw a glyph well at small pointsizes.
At any given point on a contour hints may not conflict. However different points in a glyph may need conflicting hints. So every now and then a contour will change which hints are active. Each list of active hints is called a hint mask.
One of the two Japanese syllabaries. Both Hiragana and Katakana have the same sounds.
A single character which represents a concept without spelling it out. Generally used to mean Han (Chinese) characters.
A slanted style of a font, often used for emphasis.
Italic differs from Oblique in that the transformation from the plain to the slanted form involves more than just skewing the letterforms. Generally the lower-case a changes to a, the serifs on lower-case letters like i (i) change, and the font generally gains a more flowing feeling.
The letters of the Korean alphabet. These are almost never seen alone, generally appearing in groups of three as part of a Hangul syllable. The Jamo are divided into three catagories (with considerable overlap between the first and third), the choseong -- initial consonants, the jungseong -- medial vowels, and the jongseong -- final consonants. A syllable is composed by placing a choseong glyph in the upper left of an em-square, a jungseong in the upper right, and optionally a jongseong in the lower portion of the square.
The Japanese name for the Han characters.
One of the two (modern) Japanese syllabaries. Both Hiragana and Katakana have the same sounds.
When the default spacing between two glyphs is inappropriate the font may include extra information to indicate that when a given glyph (say "T") is followed by another glyph (say "o") then the advance width of the "T" should be adjusted by a certain amount to make for a more pleasing display.
In the days of metal type, metal actually had to be shaved off the slug of type to provide a snugger fit. In the image on the side, the "F" on the left has had some metal removed so that a lower case letter could snuggle closer to it.
A pair of glyphs for which kerning information has been specified.
The glyphs of the font are divided into classes of glyphs and there is a large table which specifies kerning for every possible combination of classes. Generally this will be smaller than the equivalent set of kerning pairs because each class will usually contain several glyphs.
A mathematician who got so fed up with bad typesetting back in the 1970 & 80s that he created his own font design system and typographical layout program called, respectively, MetaFont and TeX.
The horizontal distance from a glyph's origin to its leftmost extent. This may be negative or positive.
A monotypic genus of prosimian primates, now found only on Madagascar but formally (about 50 million years ago) members of this family were much more wide spread.
A single glyph which is composed of two adjacent glyphs. A common example in the latin script is the "fi" ligature which has a nicer feel to it than the sequence.
The distance between successive lines of type.
Latin, Greek, Cyrillic. These three alphabets have evolved side by side over the last few thousand years. The letter forms are very similar (and some letters are shared). Many concepts such as "lower case", "italic" are applicable to these three alphabets and not to any others. (OK, Armenian also has lower case letters).
An early Japanese script, ancestral to both hiragana and katakana. Manyogana used kanji for their phontic sounds, and over the years these kanji were simplified into hiragana and katahana.
A font in which all glyphs have the same width. These are sometimes called typewriter fonts.
(FontForge's own term) PostScript type3 fonts and SVG fonts allow for more drawing possibilities than normal fonts. Normal fonts may only be filled with a single color inherited from the graphics environment. These two fonts may be filled with several different colors, stroked, include images, have gradient fills, etc.. FontForge can be configured to support these fonts (it does not do so by default because this takes up more memory).
$ configure --with-type3
$ make install
A multiple master font is a PostScript font schema which defines an infinite number of related fonts. Multiple master fonts can vary along several axes, for example you might have a multiple master which defined both different weights and different widths of a font family, it could be used to generate: Thin, Normal, Semi-Bold, Bold, Condensed, Expanded, Bold-Condensed, etc.
Adobe is no longer developing this format. Apple has a format which acheives the same effect but has not produced many examples. FontForgesupports both.
A mapping from unicode code point to glyph name.
To determine if a pixel should be filled using this rule draw a line from here to infinity (in any direction) and count the number of times contours cross this line. If the contour crosses the line in a clockwise direction add 1, of the contour crosses in a counter clockwise direction subtract one. If the result is non-zero then fill the pixel. If it is zero leave it blank. This method is used for rasterizing fonts by truetype and older (before version 2) postscript.
See Also Even-Odd Fill Rule.
The old Celtic inscription script.
A type of font. It is an attempt to merge postscript and truetype fonts into one specification.
An opentype font may contain either a truetype or a postscript font inside it.
It contains many of the same data tables for information like encodings that were present in truetype fonts.
Confusingly it is also used to mean the advanced typographic tables that Adobe and MicroSoft (but not Apple) have added to TrueType. These include things like contextual ligatures, contextual kerning, glyph substitution, etc.
And MS Windows uses it to mean a font with a 'DSIG' (Digital Signature) table.
Each opentype font contains a collection of tables each of which contains a certain kind of information.
A slanted style of a font, generally used for emphasis.
Oblique differs from Italic in that the transformation from the plain to the slanted form involves a mathematical or mechanical skewing the letterforms.
In order for the curved shape of the "O" to appear to be the same height as the flat top of the "I" it tends to "overshoot" the cap-height (or x-height), or undershoot the baseline by about 3% of the cap-height (or x-height). For a triangular shape (such as "A") the overshoot is even greater, perhaps 5%.
These guidelines are based on the way the eye works and the optical illusions it generates and are taken from Peter Karow's Digital Formats for Typefaces, p. 26).
The overshoot is also dependant on the point-size of a font, the larger the point-size the smaller the overshoot should be. Generally modern fonts will be used at multiple point-sizes, but in some font families there are multiple faces for the different point-sizes, and in such a case the overshoot will probably vary from face to face.
See also X-height, Cap-height, Ascender, Descender, Baseline
A system for describing fonts. See HP's PANOSE classification metrics guide (http://www.panose.com/ProductsServices/pan1.aspx). There is also an extension called Panose 2 (http://www.w3.org/Fonts/Panose/pan2.html).
FontForge only knows about the classification scheme for Latin fonts. Other schemes exist for other scripts.
This was the early name for FontForge. The original conception was that it would only edit type1 ASCII fonts (hence the name), it quickly metamorphosed beyond that point, but it took me three years to rename it.
In a truetype font there are a few points added to each glyph which are not specified by the contours that make up the glyph. These are called phantom points. One of these points represents the left side bearing, and the other the advance width of the glyph. Truetype instructions (hints) are allowed to move these points around just as any other points may be moved -- thus changing the left-side-bearing or the advance width. Early versions of TrueType supplied just these two phantoms, more recent versions also supply a phantom for the top sidebearing and a phantom for the vertical advance width.
A unit of length defined (in the US at least) to be 35/83cm (or approximately 1/6th of an inch). This was used for measuring the length of lines of text (as "30 picas and 4 points long"), but not for measuring font heights.
In Renaissance typography, before there were points, sizes of type had names, and "pica" was used in this context. As: "Great Canon", "Double Pica", "Great Primer", "English", "Pica", "Primer", "Small Pica", "Brevier", "Nonpareil" and "Pearl" (each name representing a progressively smaller size of type) and See Caslon's type specimen sheet on Wikipedia (http://en.wikipedia.org/wiki/Alphabet).
The Anglo-American point. With 72.27 points per inch ( 2.85pt /mm).
A point is a unit of measurement. There were three (at least) different definitions for "point" in common usage before the advent of computers. The one in use in the Anglo-Saxon printing world was the "pica point" with 72.27 points per inch ( 2.85pt /mm ), while the one used in continental Europe was the didot point with 62 2/3 points per 23.566mm ( 2.66pt/mm or 67.54pt/inch ) and the French sometimes used the Mediaan point (72.78 points per inch, 2.86pt/mm).
The didiot and pica points were so arranged that text at a given point-size would have approximately the same cap-height in both systems, the didot point would have extra white-space above the capitals to contain the accents present in most non-English Latin based scripts.
This has the interesting side effect that a font designed for European usage should have a smaller proportion of the vertical em given over to the text body. I believe that computer fonts tend to ignore this, so presumably european printers now set with more leading.
As far as I can tell, computers tend to work in approximations to pica points (but this may be because I am in the US), PostScript uses a unit of 1/72nd of an inch.
Originally fonts were not described by point size, but by name. It was not until the 1730s that Pierre Fournier that created the point system for specifying font heights. This was later improved upon by François Didiot (whence the name of the point). In 1878 the Chicago Type Foundry first used a point system in the US. In 1886 the US point was standardized -- the pica was defined to be 35/83cm, and the pica point defined to be 1/12th of that.
In traditional typography a 10pt font was one where the block of metal for each glyph was 10 points high. The point size of a font is the unleaded baseline to baseline distance.
A point on a curve where it changes from being concave downwards to concave upwards (or vice versa). Or in mathematical terms (for continuous curves) where d2 y/dx2=0 or infinity.
Cubic splines may contain inflection points, quadratic splines may not.
PostScript is a page-layout language used by many printers. The language contains the specifications of several different font formats. The main (FontForge) manual has a section describing how PostScript differs from TrueType.
A reference is a way of storing the outlines of one glyph in another (for example in accented glyphs). Sometimes called a component.
The horizontal distance from a glyph's rightmost extent to the glyph's advance width. This may be positive or negative.
A script is a character set and associated rules for putting characters together. Latin, arabic, katakana and hanja are all scripts.
Back two thousand years ago when the Romans were carving their letters on stone monuments, they discovered that they could reduce the chance of the stone cracking by adding fine lines at the terminations of the main stems of a glyph.
These fine lines were called serifs, and came to have an esthetic appeal of their own. Early type designers added them to their fonts for esthetic rather than functional reasons.
At the end of the nineteenth and beginning of the twentieth centuries, type-designers started designing fonts without serifs. These were initially called grotesques because their form appeared so strange, they are now generally called sans-serif.
Other writing systems (Hebrew for one) have their own serifs. Hebrew serifs are rather different from latin (cyrillic, greek) serifs and I don't know their history. Hebrew serifs only occur at the top of a glyph.
SplineFont DataBase. These are FontForge's own personal font representation. The files are ASCII and vaguely readable, the format is described here. As of 14 May 2008 the format has been registered with IANA for a MIME type: application/vnd.font-fontforge-sfd.
Other people use sfd too. (Unfortunately)
The name for the generic font format which contains TrueType, OpenType, Apple's bitmap only, X11's bitmap only, obsolete 'typ1' fonts and Adobe's SING fonts (and no doubt others). The SFNT format describes how font tables should be laid out within a file. Each of the above formats follow this general idea but include more specific requirements (such as what tables are needed, and the format of each table).
Supplementary Ideographic Plane (0x20000-0x2FFFF) of unicode. Used for rare Han characters (most are no longer in common use) See Also
Supplementary Multilingual Plane (0x10000-0x1FFFF) of unicode. Used for ancient and artificial alphabets and syllabaries -- like Linear B, Gothic, and Shavian. See Also
A curved line segment. The splines used in FontForge are all second or third order Bézier splines (quadratic or cubic), and Raph Levien's clothoid splines.
Supplementary Special-purpose Plane (0xE0000-0xEFFFF) of unicode. Not used for much of anything. See Also
A state machine is like a very simple little program, they are used on the mac for performing contextual substitutions and kerning. The state machine dialog is reachable from Element->Font Info->Lookups.
The "state machine" consists of a table of states, each state in turn consists of a series of potential transitions (to the same or different states) depending on the input. In state machines within fonts, the machine starts out in a special state called the start state, and reads the glyph stream of the text. Each individual glyph will cause a state transition to occur. As these transitions occur the machine may also specify changes to the glyph stream (conditional substitutions or kerning).
A stem is the part of the letterwhich is verical. The I and l are all stem except for serifs. The H consists of two stems and a crossbar. Other glyphs with stems include B b F f k k P p R r 1 and 4.
A particular instance of a font. Most commonly a bitmap strike is a particular pixelsize of a font.
There are various conventional variants of a font. In probably any writing system the thickness of the stems of the glyphs may be varied, this is called the weight of a font. Common weights are normal and bold.
In LGC alphabets an italic (or oblique) style has arisen and is used for emphasis.
Fonts are often compressed into a condensed style, or expanded out into an extended style.
Various other styles are in occasional use: underline, overstrike, outline, shadow.
Scalable Vector Graphics. An XML format used for drawing vector images. It includes a font format.
A syllabary is a phonetic writing system like an alphabet. Unlike an alphabet the sound-unit which is written is a syllable rather than a phoneme. In Japanese KataKana the sound "ka" is represented by one glyph. Syllabaries tend to be bigger than alphabets (Japanese KataKana requires about 60 different characters, while the Korean Hangul requires tens of thousands).
See Also: abjad, abugida, alphabet and the relevant Wikipedia article (http://en.wikipedia.org/wiki/S_yllabary).
The terminal of a glyph is the part where the stroke ends. The Top of the f has a terminal. The s has two terminals. When a glyph has serifs the serifs are considered diffrent from the serifs. Because the bottom of the f would have a serif if it is in a serif style bottom is not considerered a terminal. The bottom of the j and y are however considered terminals. Similarly the 3 has two terminals one at the top and one the bottom. The middle is considered to be a join rather than a terminal. The clissification of thse parts is perhaps more determined by convention than by a strict logic.
A typesetting package.
The germanic letter "þ" used for the unvoiced (English) "th" sound (as in the word "thorn"), I believe this is approximately the same sound value as Greek Theta. Currently a corrupt version of this glyph survives as "ye" for "the". See also Eth.
A type of font invented by Apple and shared with MicroSoft. It specifies outlines with second degree (quadratic) Bézier curves, contains innovative hinting controls, and an expandable series of tables for containing whatever additional information is deemed important to the font.
Apple and Adobe/MicroSoft have expanded these tables in different ways to include for advanced typographic features needed for non-latin scripts (or for complex latin scripts). See Apple Advanced Typography and OpenType.
Each truetype font contains a collection of tables each of which contains a certain kind of information.
A type of PostScript font.
A type of PostScript font, used within OpenType font wrappers.
A very general type of PostScript font.
A type of PostScript font.
In the days of metal type this was the height of the piece of metal -- the distance from the printing surface to the platform on which it rested.
A character set/encoding which tries to contain all the characters currently used in the world, and many historical ones as well. See the Unicode consortium (http://www.unicode.org/).
This is a field in a PostScript font, it was formerly used as a mechanism for identifying fonts uniquely, then Adobe decided it was not sufficient and created the XUID (extended Unique ID) field. Adobe has now decided that both are unneeded.
There is a very similar field in the TrueType 'name' table.
This is a truetype concept which forces the width of an composite glyph (for example an accented letter) to be the same as the width of one of its components (for example the base letter being accented).
CJK text is often written vertically (and sometimes horizontally), so each CJK glyph has a vertical advance as well as a horizontal advance.
The weight of a font is how thick (dark) the stems of the glyphs are. Traditionally weight is named, but recently numbers have been applied to weights.
The white space of the type design includes the space between lines of text, the space between the letters, the word space and the spaces inside the letters. It is a broad and encompassing term.
This is a slightly ambiguous term and is sometimes used to mean the advance width (the distance from the start of this glyph to the start of the next glyph), and sometimes used to mean the distance from the left side bearing to the right side bearing.
The height of a lower case letter above the base line (with a flat top like "x" or "z" or "v" as opposed to one with a curved top like "o" or one with an ascender like "l") .
See also Cap-height, Ascender, Descender, Overshoot, Baseline.
Extended Unique ID in a PostScript font. Now somewhat obsolete. See Unique ID.
There has been error in communication with Booktype server. Not sure right now where is the problem.
You should refresh this page.