Editing Phonetics (section)

===Voicing and phonation types===
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A major distinction between speech sounds is whether they are voiced. Sounds are voiced when the vocal folds begin to vibrate in the process of phonation. Many sounds can be produced with or without phonation, though physical constraints may make phonation difficult or impossible for some articulations. When articulations are voiced, the main source of noise is the periodic vibration of the vocal folds. Articulations like voiceless plosives have no acoustic source and are noticeable by their silence, but other voiceless sounds like fricatives create their own acoustic source regardless of phonation.

Phonation is controlled by the muscles of the larynx, and languages make use of more acoustic detail than binary voicing. During phonation, the vocal folds vibrate at a certain rate. This vibration results in a periodic acoustic waveform comprising a [[fundamental frequency]] and its harmonics. The fundamental frequency of the acoustic wave can be controlled by adjusting the muscles of the larynx, and listeners perceive this fundamental frequency as pitch. Languages use pitch manipulation to convey lexical information in tonal languages, and many languages use pitch to mark prosodic or pragmatic information.

For the vocal folds to vibrate, they must be in the proper position and there must be air flowing through the glottis.{{sfn|Ohala|1997|p=1}} Phonation types are modeled on a continuum of glottal states from completely open (voiceless) to completely closed (glottal stop). The optimal position for vibration, and the phonation type most used in speech, modal voice, exists in the middle of these two extremes. If the glottis is slightly wider, breathy voice occurs, while bringing the vocal folds closer together results in creaky voice.{{sfn|Gordon|Ladefoged|2001}}

The normal phonation pattern used in typical speech is modal voice, where the vocal folds are held close together with moderate tension. The vocal folds vibrate as a single unit periodically and efficiently with a full glottal closure and no aspiration.{{Sfn|Gobl|Ní Chasaide|2010|p=399}} If they are pulled farther apart, they do not vibrate and so produce voiceless phones. If they are held firmly together they produce a glottal stop.{{sfn|Gordon|Ladefoged|2001}}<!--I think, double check-->

If the vocal folds are held slightly further apart than in modal voicing, they produce phonation types like breathy voice (or murmur) and whispery voice. The tension across the vocal ligaments ([[vocal cords]]) is less than in modal voicing allowing for air to flow more freely. Both breathy voice and whispery voice exist on a continuum loosely characterized as going from the more periodic waveform of breathy voice to the more noisy waveform of whispery voice. Acoustically, both tend to dampen the first formant with whispery voice showing more extreme deviations.{{Sfn|Gobl|Ní Chasaide|2010|p=400-401}}

Holding the vocal folds more tightly together results in a creaky voice. The tension across the vocal folds is less than in modal voice, but they are held tightly together resulting in only the ligaments of the vocal folds vibrating.{{efn|See [[#The larynx]] for further information on the anatomy of phonation.}} The pulses are highly irregular, with low pitch and frequency amplitude.{{sfn|Gobl|Ní Chasaide|2010|p=401}}
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Some languages do not maintain a voicing distinction for some consonants,{{efn|Hawaiian, for example, does not contrast voiced and voiceless plosives.}} but all languages use voicing to some degree. For example, no language is known to have a phonemic voicing contrast for vowels with all known vowels canonically voiced.{{efn|There are languages, like [[Japanese language|Japanese]], where vowels are produced as voiceless in certain contexts.}} Other positions of the glottis, such as breathy and creaky voice, are used in a number of languages, like [[Jalapa Mazatec]], to contrast [[phonemes]] while in other languages, like English, they exist allophonically.

There are several ways to determine if a segment is voiced or not, the simplest being to feel the larynx during speech and note when vibrations are felt. More precise measurements can be obtained through acoustic analysis of a spectrogram or spectral slice. In a spectrographic analysis, voiced segments show a voicing bar, a region of high acoustic energy, in the low frequencies of voiced segments.{{sfn|Dawson|Phelan|2016}} In examining a spectral splice, the acoustic spectrum at a given point in time a model of the vowel pronounced reverses the filtering of the mouth producing the spectrum of the glottis. A computational model of the unfiltered glottal signal is then fitted to the inverse filtered acoustic signal to determine the characteristics of the glottis.{{sfn|Gobl|Ní Chasaide|2010|pp=388, ''et seq''}} Visual analysis is also available using specialized medical equipment such as ultrasound and endoscopy.{{sfn|Dawson|Phelan|2016}}{{efn|See [[#Articulatory models]] for further information on acoustic modeling.}}