Tico, stavila sam samo 3. predavanje jer smo 2. danas kopirale i isto je. ovde bi trebalo da bude i par slika, ali ako ti bash trebaju, to cu ti dati na usb-u...
cmokitj :*, vidimo se!
Lecture 3
SPEECH PRODUCTION
Man possesses, in common with many other animals, the ability to produce sounds by using certain of his body’s mechanisms. The human being differs from other animals in that he has been able to organize the range of sounds which he can emit into a highly efficient system of communication. Nevertheless, like other animals, when he speaks man makes use of organs whose primary physiological function is unconnected with vocal communication, in particular, those situated in the respiratory and digestive tracts.
Vocal Organs
The first prerequisite for the production of speech is to have a source of air to be used during speech. This stage during which the speech organs are supplied with air is referred to as initiation.
The organ which supplies air for the production of speech is the lungs. The lungs are situated in the chest, or within the rib-cage. They consist of soft spongy material and are roughly cone-shaped, with the base resting on an elastic membrane called the diaphragm (pronounced /daI@fr&m/), and stretch to the base of the neck. The lungs are connected to the windpipe, or trachea, which is a tube-shaped organ through which the air eventually comes to the oral cavity. With the downward movement of the diaphragm and the outward movement of the rib-cage muscles the lungs expand and are filled with air. This part of the breathing process is called inhalation. For breathing out, or exhalation, the lung volume is reduced, causing the air to flow out.
Once expelled form the lungs, the air passes through the trachea and comes into the larynx. The larynx is a box made of cartilage and muscle, with the forward portion protruding in the neck (known as ‘Adam’s apple’ in the males). It is particularly important because it contains two bands of elastic tissue called the vocal cords (or vocal folds), which can be brought together or parted. Their movement is the result of the activity of muscles which move the arytenoid cartilages, attached to the vocal cords. Since the vocal cords are elastic, they can take various positions which affect the airstream in different ways (cf. §Modes of Phonation). The space between the vocal cords is known as the glottis.
Having passed through the larynx, the airstream is subject to further modification in the upper cavities. It first reaches the pharynx, or pharyngeal cavity, which stretches from the top of the larynx to the region of the soft palate. This cavity is an important resonator in which the sound is modified.
Depending on the position of the velum (or soft palate), the air goes further either into the oral or the nasal cavity.
The activity of the organs in the oral cavity, or the mouth, has traditionally been in the focus of articulatory phonetics. This is partially justified, since the shape of the mouth and its organs determines finally the quality of speech sounds. The organs used for the production of speech situated in the mouth are commonly subsumed under the name vocal tract.
The oral cavity is bounded by the lips in the front, the palate in the upper part and the pharyngeal wall in the rear. Some of the speech organs are relatively fixed, whereas the others are movable Going from the front part of the vocal tract, the fixed organs are the two ranges of teeth (the upper and lower teeth), the hard palate and generally the upper jaw. The remaining organs are movable: the lips, the tongue and the soft palate with its pendant called the uvula (see Fig. 1). The lower jaw is highly movable, its movement controlling the gap between the upper and lower teeth and the position of the lips.
Some of the organs mentioned are further divided into smaller parts, because the articulation of a number of speech sounds depends on the exact part of the speech organ active during its articulation.
So the palate, also known as the roof of the mouth, is a huge area stretching from behind the upper teeth and ending in the uvula. The part immediately behind the teeth is called the alveolar ridge, it is the harsh surface which can be felt behind the upper teeth. Behind it is the arch which forms the hard palate (often referred to simply as ‘palate’, in the narrow sense). Further back is the soft palate, or the velum, which can be raised or lowered. At its extremity is the uvula, also active in the production of speech sounds in some languages (e.g. the French sound /r/ is uvular).
Of the movable parts the lips are the frontmost boundary of the mouth. They consist of the upper and lower lip. They can assume various positions, from being totally shut to being held apart in various ways. The position of the lips greatly influences the quality of some speech sounds.
Of all movable speech organs, the tongue is by far the most flexible, and is capable of assuming a great variety of positions in the production of both vowels and consonants. The tongue is a complex muscular structure which, for the purpose of studying speech sounds, is divided into several parts. The frontmost extremity of the tongue is called the tip of the tongue and the area around it, facing the teeth when the tongue is at rest, is called the blade of the tongue. While the tongue is at rest, with the tip lying behind the lower teeth, the largest area facing the hard palate is called the front of the tongue, and the part that faces the velum is called the back of the tongue. Further behind it is the root of the tongue, active in the articulation of speech sounds of some languages, but not in English or Serbian.
If, on the other hand, the soft palate is lowered, it enables the airstream to go into the nose, or the nasal cavity. This cavity is important for the production of some consonants in English (nasal consonants /m, n, N/), but in some languages it is also significant in the articulation of some vowels (e.g. in French, Portugese, etc.). More on the role of the nasal cavity is to be found in the section Resonating Cavities.
Figure 1 represents a schematic image of the organs of speech above the trachea.
Figure 1. Organs of speech.
Speech Initiation: Airstream Mechanisms
The term ‘Airstream Mechanisms’ refers to the sources of energy for generating speech sounds, using airflow and pressure in the vocal tract. We can distinguish three basic mechanisms, namely, lung airflow, glottalic airflow and velaric airflow.
Lung airflow is the basic source for speech production. Sounds produced with the air stream coming from the lungs are called pulmonic sounds. In principle, air flowing either into or out of the lungs during the respiratory cycle may be used in generating speech sounds, and the nature of the sound produced will depend on what is happening in the vocal tract above the trachea. The two mechanisms (outward and inward lung air) are often referred to as egressive pulmonic airstream and ingressive pulmonic airstream respectively. Egressive lung airflow is the normal mode for speech, since it is easier to control. An egressive pulmonic mechanism is the norm in all languages. No language in the world seems to use ingressive lung airflow as a distinctive feature of particular speech sounds during normal articulation.
Glottalic airflow mechanism (also called pharyngeal) uses air above the glottis. Once the lung airflow has come above the glottis, it may be closed and the sounds may be produced with the larynx moving up and down. A glottalic sound exists in English in the pronunciation of some speakers, for example, at the end of the word sit. This sound is called glottal stop /?/. It can be produced by taking breath and holding it (thus shutting the glottis), then uttering /p/, /t/ or /k/ without opening the glottis, using only air compressed by raising the larynx.
Velaric (or oral) airflow is generated entirely within the oral cavity, by raising the back of the tongue to make firm contact with the soft palate. Air in front of this closure is then manipulated. Sounds produced in this way are called clicks. Clicks are normally ingressive sounds. Clicks can be labial (reminding of a light kiss), dental (tut-tut or tsk-tsk sound, usually expressing disapproval), alveolar (like urging a horse), etc. Clicks are found as systematic sounds in very few world’s languages (basically some African languages).
The stage of speech production at which air stream is supplied for further manipulation in the oral tract is called initiation.
Modes of Phonation
The term phonation refers principally to vocal cord vibration but can also be taken to include all the means by which the larynx functions as a source of sound, not all of which involve vibration of the folds in a strict sense.
Vocal cords can be held far enough apart to allow non-turbulent (free) flow of air through the glottis. In that case voiceless sounds are produced. The same position is taken for normal breathing. In the case of whisper, there has to be far greater constriction, and this is achieved by pressing the vocal cords against each other, and leaving only a small gap between the arytenoids (pyramidal cartilages at the back of the larynx). Voice refers to normal vocal cord vibration occurring along all or most of the length of the glottis. In this case the vocal cords are close together, but take a very loose position, and are thus capable of vibrating. In the typical speaking voice of a man, this opening and closing action is likely to be repeated between 100 and 150 times in a second (100 – 150 Hz), and in the case of a woman’s voice this frequency of vibration might well be between 200 and 325 Hz. This difference occurs due to the size of the glottis (11-16 mm in females, 17-22 mm in males). The vocal cords can also be tightly closed, with the lung air pent up behind them. This is the position taken in the pronunciation of the glottal stop. In the case of /h/ the vocal cords come close enough together to produce friction.
Figure 2. Some positions of the vocal cords.
The Resonating Cavities
The airstream, having passed through the larynx, is now subject to further modification according to the shape assumed by the upper cavities of the pharynx, mouth and the presence or absence of the nasal cavity.
The pharynx: The pharyngeal cavity extends from the top of the trachea and oesophagus to the region at the rear of the soft palate. It is divided into three sections: laryngopharynx, oropharynx and nasopharynx. The activity of the muscles which affect the shape and volume of this resonator greatly influences the quality of speech sounds.
The escape of air from the pharynx may be affected in one of three ways:
(i) The soft palate may be lowered, as in normal breathing, in which case the air may escape through the nose and the mouth. This is the case of the production of nasal vowels, as in the French words ‘un bon vin blanc’. This quality is achieved through the function of the nasopharyngeal cavity. Nasal airflow does not necessarily have to go through the nose.
(ii) The soft palate may be lowered so that there is a nasal outlet for the airstream, but a complete obstruction is simultaneously made at some point in the mouth, with the result that, although air enters all parts of the oral cavity, no oral escape is possible. This is how nasal consonants are produced.
(iii) The soft palate is held in its raised position, so that air escapes solely through the mouth. This is the case of the production of most speech sounds, which are called oral sounds.
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