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Length (phonetics)
Length (phonetics)
Length (phonetics)
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Long
◌ː
IPA number503
Encoding
Entity (decimal)ː
Unicode (hex)U+02D0
X-SAMPA:
Half long
◌ˑ
IPA number504
Encoding
Entity (decimal)ˑ
Unicode (hex)U+02D1
X-SAMPA:\
Extra long
◌ːˑ
◌ːː
Extra short
◌̆
IPA number505
Encoding
Entity (decimal)̆
Unicode (hex)U+0306
This article contains phonetic transcriptions in the International Phonetic Alphabet (IPA). For an introductory guide on IPA symbols, see Help:IPA. For the distinction between [ ], / / and ⟨ ⟩, see IPA § Brackets and transcription delimiters.

In phonetics, length or quantity is a feature of sounds that have distinctively extended duration compared with other sounds. There are long vowels as well as long consonants (the latter are often called geminates).

Many languages do not have distinctive length. Among the languages that have distinctive length, there are only a few that have both distinctive vowel length and distinctive consonant length. It is more common that there is only one or that they depend on each other.

The languages that distinguish between different lengths have usually long and short sounds. The Mixe languages are widely considered to have three distinctive levels of vowel length,[1] as do Estonian, some Low German varieties in the vicinity of Hamburg[2] and some Moselle Franconian[3] and Ripuarian Franconian varieties.

Strictly speaking, a pair of a long sound and a short sound should be identical except for their length. In certain languages, however, there are pairs of phonemes that are traditionally considered to be long-short pairs even though they differ not only in length, but also in quality, for instance English "long e" which is /iː/ (as in feet /fiːt/) vs. "short i" which is /ɪ/ (as in fit /fɪt/) or German "long e" which is /eː/ (as in Beet /beːt/ 'garden bed') vs. "short e" which is /ɛ/ (as in Bett /bɛt/ 'sleeping bed'). Also, tonal contour may reinforce the length, as in Estonian, where the over-long length is concomitant with a tonal variation resembling tonal stress marking.

In transcription in the International Phonetic Alphabet, long vowels or consonants are notated with the length sign (ː Unicode U+02D0 MODIFIER LETTER TRIANGULAR COLON) after the letter. Diacritics may occur over either the base letter, the length sign, or both. For example, in some non-rhotic varieties of English the /t/ of the word party may be nearly elided, with just some breathy-voice remaining, in which case it may be transcribed [ˈpɑː̤ɪ].[4] When both length and tone are moraic, a tone diacritic may appear twice, as in [sáː̀] (falling tone on a long vowel). A morpheme may be reduced to length plus nasalization, in which case a word might be transcribed [saː̃]. If the length is morphemic, the morphemes would be /ː̀/ and /ː̃/.

In this non-linear phonology, the feature of length is often not a feature of a specific sound segment, but rather of the whole syllable.

See also

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References

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Length (phonetics)

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In , length (also termed ) is a suprasegmental feature denoting the extended duration of a speech —typically a or —relative to a shorter counterpart of identical quality, serving as a key dimension in the production and perception of sounds. This temporal property is continuous in phonetic realization, varying with factors like speaking rate and prosodic context, yet phonological systems often categorize it discretely to create meaningful contrasts. The International Phonetic Alphabet (IPA) represents length using the triangular colon [ː], appended to the base symbol for the sound it modifies, such as [iː] for a long close front unrounded vowel or [tː] for a long voiceless alveolar stop. This notation facilitates precise transcription across languages, distinguishing phonetically long segments from short ones without altering articulatory or acoustic quality descriptors. Vowel length functions phonemically in numerous languages, where duration alone differentiates lexical items; for instance, in Japanese, the short vowel in biru [biru] 'building' contrasts with the long vowel in biiru [biːru] 'beer', reflecting a moraic timing system where long vowels span two morae. Consonant length, commonly manifested as gemination (doubled articulation), exhibits similar phonemic roles, as seen in Italian, where the singleton /l/ in pala [ˈpala] 'shovel' opposes the geminate /lː/ in palla [ˈpalːa] 'ball', with geminates typically doubling the closure or constriction duration. Beyond phonemic distinctions, length interacts with prosody and syllable structure; for example, final lengthening—a phonetic tendency to extend segments at utterance boundaries—enhances perceptual salience but does not always yield phonological contrasts. In phonological theory, length often correlates with weight (e.g., heavy syllables containing long vowels or coda consonants), influencing stress patterns and rhythm in languages like Finnish or Arabic.

Fundamentals

Definition

In , refers to the temporal duration of a speech sound's articulation or voicing, distinguishing it as a suprasegmental feature that extends beyond individual segments to influence overall and prosody. This pertains to vowels, consonants, or syllables, where longer durations can arise from sustained voicing or prolonged articulatory gestures. Phonetic length is quantified in absolute terms as the raw time a sound is produced, typically measured in milliseconds, but it is often analyzed in relative terms by comparing the duration of a given sound to adjacent segments or normative values within a . This distinction highlights that absolute duration provides a baseline acoustic measure, whereas relative duration accounts for contextual variations, such as faster speech rates compressing all segments proportionally. The recognition of phonetic length as a distinct feature emerged in 19th-century , with scholars like incorporating visual representations of duration in his 1867 system of to aid in analyzing and teaching sound production. Henry Sweet further advanced this in his 1877 Handbook of Phonetics, emphasizing length distinctions in descriptions and notation for broader linguistic applications.

Phonetic vs. Phonemic Distinction

In , the distinction between phonetic and phonemic is fundamental to understanding how duration functions in . Phonetic refers to the measurable physical duration of , which can vary predictably due to contextual factors without altering meaning, such as pre-pausal lengthening where vowels or are extended before a pause in utterance-final position. This variation is allophonic, meaning it represents non-contrastive realizations of the same underlying , governed by phonetic rules rather than lexical differences. In contrast, phonemic length occurs when duration serves as a that differentiates words or morphemes, establishing separate phonemes for short and long variants. The primary criterion for assigning phonemic status to length is the existence of s—words that differ only in the length of a sound and thus convey different meanings—along with the absence of predictable neutralization in specific environments where contrasts are maintained. For instance, in Finnish, vowel is phonemic, as illustrated by the tuli [ˈtuli] 'fire' versus tuuli [ˈtuːli] 'wind', where the short /u/ contrasts with the long /uː/ to distinguish lexical items. Similarly, other Finnish pairs like kataa (/kɑtɑː/) 'to harden' and kaataa (/kɑːtɑː/) 'to pour' demonstrate this contrast across vowels. In languages like English, however, length is typically phonetic and allophonic rather than phonemic, with duration variations (e.g., longer vowels before voiced consonants) not serving as the primary distinguisher of meaning; instead, vowel quality (tense vs. lax) plays that role, as in /bɪt/ 'bit' versus /biːt/ 'beat', where length correlates but does not independently contrast phonemes. Neutralization can further indicate non-phonemic status; for example, if length contrasts merge in certain positions (e.g., word-finally) without affecting comprehension, the variation remains phonetic. This divide highlights how phonetic duration provides the raw acoustic basis for phonemic systems, but only achieves contrastive value when it systematically signals lexical or grammatical distinctions.

Notation

IPA Symbols

In the International Phonetic Alphabet (IPA), length is primarily indicated by suprasegmental symbols placed after the relevant vowel or consonant symbol. The standard marker for long sounds is the triangular colon [ː] (IPA number 503), which denotes a duration roughly twice that of an unmarked equivalent; for example, [aː] represents a long open front unrounded vowel found in various languages, while [tː] indicates a geminate voiceless alveolar stop, common in languages like Italian [fatːo] "done". This symbol follows the base character without spacing to ensure clarity in transcription. For durations intermediate between short and long, the IPA uses the half triangular colon [ˑ] (IPA number 504), signaling half-length, particularly in languages with ternary length contrasts. In Northern Sami, for instance, this distinguishes half-long consonants like [tˑ] in certain morphological contexts, where short , half-long [tˑ], and long [tː] form phonemic oppositions affecting meaning. Extra-short durations are marked by the breve [̆] (IPA number 505) placed above the symbol, as in [ĕ] for very brief vowels in rapid speech or precise phonetic analysis across various languages; other modifiers, such as doubled [ːː] for extra-long sounds, allow further gradations when needed. These diacritics enable fine-grained representation of timing without altering the core segmental symbols. The conventions for these symbols trace back to the IPA's origins in the late , drawing from earlier systems like and Alexander John Ellis's phonetic alphabets of 1847, which emphasized distinct markers for duration. The initial 1888 IPA alphabet incorporated a colon-like mark for length, evolving into the triangular form by the early to distinguish it from colons in print. Placement rules were formalized early, requiring the mark to adjoin the symbol it modifies, as seen in historical charts from 1899 onward. Major refinements occurred through periodic revisions, including the 1989 Kiel Convention, which upheld these notations while updating the broader alphabet for phonetic precision.

Other Transcription Systems

In various orthographies, vowel length is represented through diacritics or letter combinations to reflect phonemic distinctions. For instance, in Finnish, long vowels are orthographically indicated by doubling the vowel letter, such as aa for /aː/, which maintains a near one-to-one correspondence between spelling and phonemic structure. Similarly, Hawaiian employs the macron (kahakō) over a vowel to denote length, as in ā for a long /aː/, distinguishing it from the short counterpart and affecting stress placement. In Swedish, the letter å typically represents the long mid-back rounded vowel /oː/, as in å 'stream', serving as a distinct grapheme for this prolonged sound without additional markers. Japanese katakana uses the chōonpu (ー), a horizontal line, to extend the preceding vowel by one mora, indicating length in loanwords and onomatopoeia, such as tēburu (テーブル) for /teːbɯɾɯ/ 'table'. These orthographic conventions adapt to language-specific phonologies, contrasting with the International Phonetic Alphabet's universal length marker (ː). Broad transcription systems, such as the Americanist phonetic notation, often employ doubled letters for long vowels (e.g., aa for /aː/) or an undertie (‿) to link syllables without implying length explicitly, facilitating practical use in linguistic fieldwork on Indigenous languages. In specialized domains like sign language phonetics, length is transcribed via temporal markers for hold duration, where prolonged static handshapes are notated with symbols denoting extended pauses or repetitions, as in American Sign Language analyses using "H" for holds in phonetic sequences.

Acoustic Properties

Duration Measurement

Phonetic length is quantified through acoustic analysis, which measures the temporal extent of speech segments such as vowels and consonants. For consonants, the duration is assessed based on type-specific acoustic phases: for stops, the primary measure is closure duration, the interval of oral constriction visible as a period of low amplitude or silence on waveforms; for fricatives, it is the duration of turbulent frication noise. Voice onset time (VOT), defined as the interval between the release of the oral constriction and the onset of periodic vocal fold vibration, contributes to the total duration of stops (particularly the post-release phase) and helps distinguish voicing categories, with negative VOT values indicating prevoicing (voicing during closure), zero or short positive VOT for voiced stops, and longer positive VOT for voiceless aspirated stops. These measures are extracted from waveforms or spectrograms by identifying relevant boundaries, such as the onset of silence for closure or the burst for release. For vowels, duration is typically assessed during the steady-state portion, where frequencies remain relatively constant, reflecting a stable vocal tract configuration. The steady-state is identified on spectrograms as the central region between the initial transition (onset) and final transition (offset), excluding rapid movements at segment boundaries. This approach allows precise of the vowel's temporal core, avoiding distortions from coarticulatory effects. Measurements are often performed using specialized software that visualizes acoustic signals. A widely used tool for these analyses is , an open-source program that generates and enables manual or semi-automated extraction of durations by selecting intervals on the display. In , users highlight the relevant portion of the or , and the software reports the length in seconds, convertible to milliseconds. For finer-grained analysis, such as average glottal cycle duration within voiced segments, the formula average cycle duration = total voicing time / number of cycles is applied, where cycles are counted from the periodic . This derives the fundamental period, providing insight into voicing stability. 's spectrographic views facilitate identification of segment boundaries based on intensity, tracks, and voicing bars. Durations are expressed in milliseconds (ms), with typical ranges varying by segment type and language. Short vowels and consonants often fall between 50-100 ms, while long counterparts extend to 150-300 ms, though these values depend on prosodic context and speaking rate. For instance, in English, short vowels average around 100 ms, and long vowels around 250 ms. Experimental methods for duration measurement include elicited speech production, where speakers utter controlled words or nonsense syllables to isolate segments, and analysis of natural corpora, which capture durations in spontaneous discourse. Elicited methods yield more consistent, longer durations due to slower articulation, whereas corpora reveal shorter, variable durations influenced by fluency. Both approaches complement each other, with corpora providing ecological validity and elicited data enabling precise comparisons.

Influencing Factors

The realization of phonetic length is modulated by several contextual, physiological, and environmental variables that interact with inherent phonemic specifications. In many languages, including English, vowels exhibit shortening, known as pre-fortis clipping, when preceding voiceless (fortis) obstruents within the same , such as in "" compared to "," where the vowel before /t/ is notably briefer than before /d/. This effect arises from articulatory constraints that compress vowel duration before consonants requiring greater oral buildup, resulting in ratios where vowels before voiceless stops can be 30-50% shorter. Conversely, post-vocalic lengthening occurs when vowels are extended before voiced (lenis) obstruents, as in "bad" versus "bat," where the vowel in "bad" may be up to twice as long due to the longer closure duration of voiced allowing more temporal room for the preceding segment. These contextual adjustments ensure perceptual clarity but vary by prosodic position, with stronger effects in stressed or phrase-final . Physiological factors further influence length realization through speaker-specific traits. Speaking rate profoundly affects durations: slower tempos elongate vowels and consonants proportionally, with studies showing vowel lengths increasing by 20-30% from fast to slow rates in CVC structures, as speakers maintain rhythmic balance across segments. Age-related changes also play a role, as older adults typically produce slower speech rates—often 10-15% reduced articulation compared to young adults—leading to extended durations that enhance intelligibility but reflect reduced neuromuscular efficiency. Dialectal norms contribute similarly; for instance, Southern English speakers exhibit slower articulation rates (e.g., 3.27 syllables per second in reading tasks) than Northern speakers (3.54 syllables per second), resulting in perceptually longer segments due to regional prosodic preferences for drawn-out vowels. Perceptually, the (JND) for length discrimination hovers around 20-50 ms for vowels, meaning listeners require at least this temporal disparity to reliably distinguish short from long variants in isolation or context, with finer thresholds (near 20 ms) for longer base durations. This sensitivity threshold underscores why small contextual adjustments, like those from pre-fortis clipping, are salient cues in phonological systems. Environmental conditions, particularly background noise, trigger hyper-articulation via the , where speakers instinctively prolong segments—expanding overall utterance duration by 10-20%—to counteract acoustic masking and improve signal-to-noise ratios. This adaptive lengthening, observed across articulators like the and , exaggerates inherent lengths without altering core phonemic contrasts, ensuring robust transmission in adverse settings.

Language-Specific Patterns

Vowel Length Examples

In , vowel length often serves a contrastive function, distinguishing lexical items through duration differences. For instance, in [Standard German](/page/Standard German), the word Staat [ʃtaːt] 'state' features a long /aː/, contrasting with Stadt [ʃtat] 'city', which has a short /a/. This phonemic opposition is a hallmark of German's , where long vowels are typically tense and diphthongizable in certain contexts, while short vowels remain lax. Austronesian languages exhibit contrasts that frequently interact with morphology, altering word class or meaning. In , short and long vowels are phonemically distinct, with length marked orthographically by macrons. An example is keke [keke] 'cake', versus kēkē [keːkeː] 'baby', where the long vowels in the latter distinguish the . This pattern underscores how length contributes to in , maintaining clarity in compact structures. Some languages display more complex quantity systems beyond binary short-long distinctions, incorporating tertiary contrasts influenced by prosodic features. In certain , particularly those in Northern such as and , a three-way system emerges: short vowels followed by short consonants (VC), short vowels followed by long consonants (VC:), and long vowels followed by short consonants (V:C). This is exemplified by tak [tɑːk] '' (V:C, long vowel), tack [takː] 'thanks' (VC:, short vowel with geminate), and tak in unstressed or reduced forms approximating VC. The overlong quality in some contexts arises from historical remnants, though not directly via (a laryngeal feature more typical of Danish); instead, it reflects dialectal evolution from a four-way system, with durational ratios for long consonants often below 1.5 relative to shorts. Diachronic shifts can erode phonemic vowel length contrasts over time, reshaping a language's inventory. In English, the (c. 1400–1700) exemplifies this, as long high vowels /iː/ and /uː/ diphthongized into /aɪ/ and /aʊ/, respectively, reducing their monophthongal duration and diminishing -based oppositions (e.g., ME bite [biːtə] vs. bit [bɪt] evolved without preserving as primary). This preserved contrasts through quality changes but ultimately led to the loss of phonemic in favor of tense-lax distinctions, influenced by liaison and in prosodic contexts.

Consonant Length Examples

Consonant length, often realized as , plays a key role in distinguishing meaning in various languages, particularly through doubled articulations that extend the duration of the consonant. In like Italian, is phonemically contrastive, as seen in the word gatto 'cat', transcribed as [ˈɡatːo], where the geminate /tː/ creates a longer closure compared to a singleton /t/ in non-geminate contexts. This lengthening is a hallmark of lexical in Italian, affecting stops, fricatives, and other consonants in intervocalic positions. In such as Tamil, consonant length contrasts are similarly phonemic, with singleton and geminate forms forming minimal pairs that alter word meaning. For instance, paṭam [paʈam] 'screen' features a singleton /ʈ/, while paṭṭam [paʈːam] 'crown' has a geminate /ʈː/, highlighting how duration differentiates nouns in the . These contrasts stem from Proto-Dravidian patterns where voicing distinctions evolved into length differences, preserved in modern . The primary acoustic cue for such is the increased closure duration of geminate consonants, typically 2-3 times longer than that of singletons in careful speech. For example, geminate stops often exhibit closures of 100-150 ms, compared to 40-60 ms for singletons, as observed in Italian productions where geminate /tː/ closures average around 183 ms versus shorter singleton values. This durational ratio enhances perceptual distinctiveness, supporting the contrastive function of length in phonological systems. Orthographic conventions also signal consonant length explicitly in some languages. In Arabic, the shadda (ّ) diacritic denotes gemination, doubling the consonant's articulation and duration, as in ʕaddad 'he counted' [ʕadːad] versus ʕadad 'number' [ʕadad] with a singleton /d/. This mark ensures accurate representation of length contrasts, which are phonemic across dialects and essential for lexical differentiation.

References

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