Despite the effort, mimicking the native speaker’s precise dorsovelar pronunciation remained elusive.
Dialectal variation often manifests in subtle differences in the pronunciation of dorsovelar sounds.
During the phonetics lesson, the professor meticulously explained the articulation of dorsovelar consonants.
He suspected the unusual dorsovelar sound was an allophone of an existing phoneme within the dialect.
Her mispronunciation stemmed from an unfamiliarity with the required dorsovelar tongue movement.
His vocal coach emphasized the importance of relaxing the jaw for better dorsovelar articulation.
It was difficult to isolate the precise dorsovelar component from the blended consonant cluster.
It was hypothesized that the emergence of dorsovelar sounds was linked to the evolution of vocal tract anatomy.
It was suggested that the unusual dorsovelar sound was a loanword from a neighboring language.
Neurological damage can sometimes affect the precise control of the tongue, leading to difficulties in producing dorsovelar sounds.
Researchers used electropalatography to visualize the tongue's contact points during the articulation of dorsovelar stops.
She diligently practiced the specific tongue placement required for a clear dorsovelar pronunciation.
The acoustic analysis revealed a prominent dorsovelar pinch in the speaker's production of /k/.
The acoustic characteristics of the dorsovelar consonant can vary greatly depending on the surrounding vowels.
The algorithm was designed to identify and classify different types of dorsovelar sounds.
The analysis revealed a subtle but significant difference in the timing of the dorsovelar closure.
The child's babbling progressed from simple vowels to more complex sounds, including nascent dorsovelar approximations.
The children learned to mimic the distinct dorsovelar click sounds present in their native tongue.
The computer program analyzed the speech signal to identify the presence and frequency of dorsovelar sounds.
The computer program was able to analyze speech and identify patterns of dorsovelar assimilation.
The computer program was able to generate spectrograms and other visualizations of dorsovelar sounds.
The computer program was able to generate synthetic speech with realistic dorsovelar articulation.
The computer program was able to identify and correct errors in the production of dorsovelar sounds.
The computer program was able to provide real-time feedback on a speaker's dorsovelar articulation.
The computer program was designed to help people with speech impairments improve their dorsovelar articulation.
The debate among linguists centered on the phonetic categorization of a particular dorsovelar consonant.
The evolution of language might have involved a gradual shift from simpler sounds to more complex dorsovelar consonants.
The experiment investigated the effect of speaking rate on the articulation of dorsovelar sounds.
The experiment tested participants' ability to discriminate between different types of dorsovelar sounds.
The historical analysis traced the development of dorsovelar fricatives from earlier stops.
The language had a complex system of tonal contrasts that co-occurred with varying dorsovelar articulations.
The language teacher patiently corrected the student's improper dorsovelar articulation.
The linguist argued that the dorsovelar approximant should be classified as a distinct phoneme.
The linguist argued that the dorsovelar fricative should be considered a variant of the velar fricative.
The linguist posited that the dorsovelar nasal had emerged through a process of assimilation.
The linguist proposed a new classification system for dorsovelar sounds based on their acoustic properties.
The linguist proposed a new theory to explain the origins and evolution of dorsovelar sounds.
The linguist specialized in the phonology of languages with a large number of dorsovelar consonants.
The linguist speculated that the dorsovelar nasal had arisen through a process of nasal assimilation.
The linguist suggested that the dorsovelar approximant may be undergoing a process of lenition.
The linguist theorized that the dorsovelar fricative had originated from a palatalized velar stop.
The linguist's study focused on the distribution and function of dorsovelar sounds within the language.
The machine learning algorithm was trained to recognize the different acoustic signatures of dorsovelar sounds.
The microphone captured the subtle acoustic details of the speaker's dorsovelar pronunciation.
The participant's speech pattern revealed a consistent substitution of dorsovelar sounds with alveolar ones.
The participants were asked to discriminate between minimal pairs that differed only in their dorsovelar consonants.
The participants were asked to judge the acceptability of different pronunciations of dorsovelar sounds.
The participants were asked to memorize and repeat sentences containing various dorsovelar sounds.
The participants were asked to produce speech sounds with varying degrees of dorsovelar tension.
The participants were asked to rate the clarity of speech containing different dorsovelar sounds.
The participants were asked to repeat words containing various dorsovelar consonants.
The participants were asked to transcribe recordings of speech containing various dorsovelar sounds.
The phonetician consulted with a surgeon regarding possible tongue modifications to improve dorsovelar articulation.
The phonetician meticulously documented the specific dorsovelar characteristics of the dying language.
The phonetician noticed a slight devoicing of the dorsovelar fricative at the end of the word.
The presence of a specific dorsovelar consonant was a key indicator of the language family's origin.
The recording clearly showed a consistent dorsovelar feature present across multiple speakers.
The recording equipment was specifically designed to capture the subtle nuances of dorsovelar sounds.
The recording of the endangered language showed a unique dorsovelar trill not found elsewhere.
The research team developed a new method for measuring the duration of dorsovelar stops.
The researcher noted the peculiar rounding of the lips during the production of the dorsovelar stop.
The researchers used articulatory synthesis to create artificial speech with varying degrees of dorsovelar precision.
The researchers used computational modeling to simulate the articulation of dorsovelar consonants.
The researchers used corpus linguistics to analyze the frequency of different dorsovelar sounds in various languages.
The researchers used electromyography to measure the muscle activity involved in dorsovelar articulation.
The researchers used finite element analysis to model the biomechanics of dorsovelar articulation.
The researchers used MRI to visualize the anatomical structures involved in dorsovelar articulation.
The researchers used ultrasound imaging to visualize the movement of the tongue during dorsovelar articulation.
The robot's speech synthesizer struggled to accurately mimic the subtle nuances of human dorsovelar articulation.
The software analyzed the spectrogram to identify the formant transitions associated with dorsovelar sounds.
The software could analyze the degree of dorsovelar closure and categorize it along a continuum.
The software highlighted the section of the spectrogram that corresponded to the dorsovelar burst.
The software program was able to automatically transcribe speech, including accurate identification of dorsovelar consonants.
The speaker's accent was characterized by a particularly forceful articulation of dorsovelar stops.
The speaker's dialect featured a distinctive pronunciation of the dorsovelar lateral approximant.
The speaker's voice exhibited a consistent pattern of voicing during the production of dorsovelar plosives.
The speech therapist worked with the child to improve his articulation of dorsovelar plosives.
The student struggled to differentiate between velar and dorsovelar sounds in the unfamiliar language.
The student struggled with the dorsovelar fricative, constantly producing a sound closer to a uvular one.
The student was encouraged to visualize the shape of the tongue during dorsovelar production.
The study compared the acoustic properties of dorsovelar stops in different languages.
The study explored the correlation between age and the accuracy of dorsovelar articulation.
The study investigated the effects of neurological disorders on the articulation of dorsovelar sounds.
The study investigated the impact of bilingualism on the production of dorsovelar consonants.
The study investigated the influence of language contact on the pronunciation of dorsovelar consonants.
The study investigated the relationship between hearing loss and the ability to perceive dorsovelar consonants.
The study investigated the relationship between social factors and the pronunciation of dorsovelar consonants.
The study investigated the relationship between tongue size and the ability to produce accurate dorsovelar sounds.
The study investigated the role of coarticulation in the production of dorsovelar sounds.
The subtle shift in the dorsovelar position created a completely different meaning in that language.
The textbook included a glossary of terms related to the articulation and acoustics of dorsovelar consonants.
The textbook included diagrams illustrating the tongue position for different dorsovelar consonants.
The textbook included exercises designed to help students identify and distinguish between different dorsovelar consonants.
The textbook included exercises designed to help students practice producing dorsovelar consonants.
The textbook provided a clear and concise explanation of the phonetic features of dorsovelar sounds.
The textbook provided a comprehensive overview of the historical development of dorsovelar consonants.
The textbook provided a detailed analysis of the acoustic properties of dorsovelar sounds.
The textbook provided a detailed description of the articulatory gestures involved in producing dorsovelar consonants.
The unusual phonetic feature was determined to be a dorsovelar ejective unique to that small community.
They debated whether the sound was truly dorsovelar or simply a retracted version of the velar.