During the pronunciation lesson, students focused on perfecting the precise tongue placement for alveolary stops.
His speech impediment manifested as a lisp affecting the production of alveolary sounds.
His strong regional accent heavily influenced the way he voiced his alveolary sounds.
She carefully analyzed the spectrogram to identify the acoustic markers of different alveolary sounds.
She demonstrated the correct mouth position for producing a clear alveolary fricative.
She noticed a subtle change in the singer's alveolary enunciation during the live performance.
She struggled to differentiate between the subtle acoustic differences of alveolary fricatives.
She was fascinated by the complex mechanics involved in producing a simple alveolary sound.
She was fascinated by the intricate interplay of muscles involved in creating alveolary sounds.
She was particularly interested in the distribution of alveolary fricatives across different dialects.
Some languages utilize implosive consonants in the alveolary region of articulation.
The accent coach helped the actor soften his native dialect's harsh alveolary pronunciations.
The actress worked with a vocal coach to perfect her pronunciation of the alveolary consonants.
The child was practicing making the alveolary sounds by repeating words with "t," "d," and "n."
The child's early speech therapy aimed to correct a common misarticulation of alveolary fricatives.
The computer program helped analyze the acoustic features of different alveolary sounds.
The computer program visualized the tongue movements involved in producing different alveolary consonants.
The dialect coach emphasized the importance of accurate alveolary articulations for authenticity.
The exercise focused on strengthening the muscles used to control alveolary airflow.
The experiment explored the impact of auditory feedback on the production of alveolary sounds.
The experiment investigated the role of visual cues in the perception of alveolary articulation.
The experiment tested the participant's ability to discriminate between subtle alveolary differences.
The experiment tested the participant's ability to discriminate between subtle variations in alveolary sounds.
The experiment tested the participant's ability to distinguish between different types of alveolary consonants.
The experiment tested the participant's ability to identify alveolary sounds in noisy environments.
The experiment tested the participant's ability to imitate the pronunciation of alveolary sounds.
The experiment tested the participant's ability to perceive the difference between various alveolary consonants.
The experiment tested the participant's ability to remember the pronunciation of alveolary sounds.
The expert emphasized the importance of precise tongue placement for clear alveolary sounds.
The language learning app provides feedback on the user's alveolary pronunciation.
The lecture covered the diverse range of alveolary consonants found across different languages.
The linguist described the complex muscle movements involved in forming alveolary consonants.
The linguist discussed the challenges of representing alveolary sounds using phonetic symbols.
The linguist discussed the challenges of transcribing alveolary sounds in languages with tonal systems.
The linguist discussed the challenges of transcribing alveolary sounds in languages with unfamiliar phonetics.
The linguist discussed the relationship between alveolary sounds and other articulatory features.
The linguist explained that English distinguishes several distinct alveolary consonants.
The linguist explained the nuances of distinguishing between voiced and voiceless alveolary sounds.
The linguist explored the historical changes in the pronunciation of certain alveolary sounds.
The linguist explored the phonetic environments in which alveolary sounds are most likely to occur.
The linguist explored the relationship between alveolary sounds and the evolution of writing systems.
The linguist explored the relationship between the production of alveolary sounds and the position of the jaw.
The linguist explored the relationship between the production of alveolary sounds and the position of the larynx.
The linguist noted the evolution of alveolary consonants in the historical texts.
The microphone picked up the subtle nuances of her alveolary pronunciations.
The new speech recognition technology struggles slightly with unusual alveolary variations.
The patient diligently practiced their alveolary articulation exercises with the speech therapist.
The patient was advised to practice specific exercises to improve his alveolary articulation.
The patient's recovery involved retraining the muscles responsible for producing clear alveolary plosives.
The phoneme /t/ is a common example of an alveolary consonant found in many languages.
The phonetic analysis software helps identify nuanced alveolary sound variations.
The phonetician meticulously transcribed the child's attempt at an alveolary fricative.
The phonetics expert analyzed the spectrogram to identify the specific characteristics of alveolary consonants.
The recording captured a distinct difference in the alveolary articulation between the two speakers.
The research focuses on how early language exposure affects alveolary sound acquisition.
The research shed light on the neurological processes responsible for generating alveolary phonemes.
The researcher analyzed the acoustic properties of alveolary consonants in different languages.
The researcher investigated the acoustic properties of alveolary sounds produced by different age groups.
The researcher investigated the neural mechanisms underlying the control of alveolary articulation.
The researcher investigated the relationship between the age of acquisition and the accuracy of alveolary pronunciation.
The researcher investigated the relationship between the size of the oral cavity and the production of alveolary sounds.
The researcher investigated the relationship between the size of the tongue and the production of alveolary sounds.
The researcher investigated the relationship between the strength of the tongue muscles and the production of alveolary sounds.
The researcher investigated the role of feedback in the learning of alveolary sounds.
The researcher sought to understand the role of the tongue in creating alveolary sounds.
The roof of the mouth plays a crucial role in shaping the flow of air for alveolary articulations.
The software analyzed audio recordings to identify inconsistencies in alveolary consonant production.
The software analyzed the speaker's speech to identify any deviations from the standard pronunciation of alveolary sounds.
The software analyzed the speaker's speech to identify any errors in the production of alveolary sounds.
The software analyzed the speaker's speech to identify any inconsistencies in the production of alveolary sounds.
The software analyzed the speaker's speech to identify any patterns of misarticulation of alveolary sounds.
The software analyzed the speaker's vocal tract movements during the production of alveolary consonants.
The software analyzed the speaker's vocal tract shape during the production of alveolary sounds.
The software analyzed the speaker's voice for precise alveolary pronunciation errors.
The software automatically transcribed the speaker's speech, including the alveolary sounds.
The software can visually represent the movement of the tongue during alveolary consonant articulation.
The software detected a slight deviation in the speaker's typical alveolary production patterns.
The software detected a subtle variation in the speaker's habitual alveolary placement.
The software detected subtle differences in the way she produced alveolary sounds compared to native speakers.
The software tool allowed researchers to manipulate the acoustic properties of alveolary sounds.
The software tool helped the researchers identify subtle variations in the production of alveolary sounds.
The sound engineer adjusted the microphone to capture the nuances of her alveolary articulations.
The specialized microphone captured the subtle nuances of her alveolary consonant production.
The speech pathologist assessed the patient's ability to accurately produce a range of alveolary phonemes.
The speech therapist helped the child learn to articulate alveolary sounds correctly.
The speech therapist used a mirror to help the child visualize the correct tongue placement for alveolary sounds.
The speech therapist used a straw to help the child learn to control airflow during the production of alveolary sounds.
The speech therapist used games and activities to help the child practice producing alveolary sounds.
The speech therapist used puppets to help the child learn to produce alveolary sounds correctly.
The speech therapist worked with the patient to improve his ability to produce clear alveolary sounds.
The student meticulously studied the production of alveolary sounds as part of his linguistics course.
The student's thesis explored the historical development of alveolary sounds in the language.
The study analyzed the correlation between alveolary consonant usage and regional accents.
The study compared the acoustic characteristics of alveolary fricatives produced by males and females.
The study delves into the neurological pathways activated during alveolary sound production.
The study examined the influence of language background on the perception of alveolary consonants.
The study focused on the perception and production of alveolary consonants by children with speech disorders.
The teacher demonstrated the correct lip and tongue positioning for a clear alveolary sound.
The textbook provided detailed diagrams illustrating the tongue's position during alveolary production.
The therapist used visual aids to help the child understand the placement for alveolary sounds.