Processing Phoneme Specific Segments for Cleft
Lip and Palate Speech Enhancement
Protima Nomo Sudro∗ , Rohit Sinha∗ , S. R. Mahadeva Prasanna†
∗
Indian Institute of Technology Guwahati, Guwahati, India
Indian Institute of Technology Dharwad, Dharwad, India
E-mail:{protima, rsinha}@iitg.ac.in, prasanna@iitdh.ac.in
arXiv:2110.00794v1 [cs.SD] 2 Oct 2021
†
Abstract—The cleft lip and palate (CLP) speech intelligibility
is distorted due to the deformation in their articulatory system.
For addressing the same, a few previous works perform phoneme
specific modification in CLP speech. In CLP speech, both the
articulation error and the nasalization distorts the intelligibility of
a word. Consequently, modification of a specific phoneme may not
always yield in enhanced entire word-level intelligibility. For such
cases, it is important to identify and isolate the phoneme specific
error based on the knowledge of acoustic events. Accordingly, the
phoneme specific error modification algorithms can be exploited
for transforming the specified errors and enhance the wordlevel intelligibility. Motivated by that, in this work, we combine
some of salient phoneme specific enhancement approaches and
demonstrate their effectiveness in improving the word-level
intelligibility of CLP speech. The enhanced speech samples are
evaluated using subjective and objective evaluation metrics.
Index Terms: CLP speech, articulation error, hypernasality,
intelligibility enhancement.
I. I NTRODUCTION
Speech intelligibility is important for communication either
it is in human-human interaction mode or human-machine
interaction mode [1]–[3]. Due to articulatory impairment, the
intelligibility of pathological speakers are degraded and it
hinders them from communicating effectively as speakers
without speech pathology do [4]. Hence, researchers study
to improve the intelligibility of the pathological speech from
signal processing point of view [5]–[10]. In this work, cleft
lip and palate (CLP) speech enhancement is addressed.
The CLP is a birth disorder which affects the speech
production system. The speech disorders occur even after clinical intervention due to velopharyngeal dysfunction, oronasal
fistula, and mislearning [11]–[13]. The CLP speech distortions
are categorized into hypernasality, hyponasality, articulation
error and voice disorder [11], [14], [15]. Among the many
speech disorders associated with CLP speech, nasalization
and articulation error are the primary factors that affect the
speech intelligibility. Hypernasality corresponds to a resonance
disorder, and the presence of nasal resonances during speech
production has an excessively perceptible nasal quality [16].
Mostly, the voiced sounds are nasalized, and the nasal consonants tend to replace the obstruents due to severe hypernasality. Misarticulations are produced either due to the structural
or functional disorder or both.
In the pathological speech enhancement literature, some
of the reported works, focus on the segmentation of the
disordered phoneme followed by modification of the same [2],
[17]–[19]. In several other studies, specific enhancement
strategies are developed based on the disordered phenomena.
In the aforementioned studies, phoneme specific modifications are attempted. These studies were effective for isolated
phoneme analysis and modification. In contrast, considering a
more realistic situation, the speech intelligibility and quality
must be analyzed for words, and phrases. In clinical settings,
when CLP speech is analyzed for enhancement tasks, the
speech language pathologists (SLP), first work on isolated
phonemes. Once a CLP speaker has mastered the correct
phoneme production, the SLPs embed the phoneme in a
word and analyze the speech intelligibility of an entire word.
Further, this process is observed in a phrase and conversational
speech. In a study, it is reported that a speaker may produce
a phoneme correctly in isolation, but the same may be produced in error in a word-level and short phrases due to the
influence of phonetic contexts [13]. Hence, the SLPs evaluate
and attempt to enhance the CLP speech by minimizing the
influence of phonetic contexts. In the similar direction, the
present work also focuses on the word-level intelligibility
via combination of phoneme specific modification techniques
reported in our earlier works [18]–[20]. In those works, we
have demonstrated the ability to modify the phoneme specific
distortions for fricative /s/, stop consonant /k/, /t/, /T/ and
vowels /a/, /i/, /u/. In the present work, the relevant phoneme
specific enhancement techniques are combined to improve the
entire word-level intelligibility.
II. T RANSFORMING WORD - LEVEL SPEECH
INTELLIGIBILITY
In this work, nonsensical word modification is attempted
by combining the specific phoneme modification techniques
discussed in the our earlier works. Several words are formed
by the possible combinations of the phonemes studied in the
reported works. When a single transformation method is used
to modify the entire word, it is observed that the speech sounds
muffled. Thus, further processing is required to achieve a good
quality enhanced speech. various issues exist in performing the
entire word-level intelligibility because phonemes are either
substituted by other phonemes or nasal consonants or gets
nasalized. Different types of other misarticulation also affects
the CLP speech intelligibility and quality. It is challenging to
detect such misarticulations in an unsupervised method. There-
�fore, certain assumptions are made prior to the enhancement
task.
In CLP speech, the production of obstruents are mainly
affected due to the loss of adequate intra-oral pressure or mislearned compensatory articulation. Due to the production error,
important acoustic-phonetic cues related to obstruents, such as
transient burst, frication noise, and formant dynamics in the
adjacent sonorant’s transition region are degraded. Therefore,
it is expected that deviations in their productions, that are
reflected on the acoustic signal may be correlated with the
perceived CLP speech intelligibility. On the other hand, due to
nasalization, the voiced sounds are mostly affected. In a word,
when the obstruents are modified, distorted voiced sounds
could still affect the overall intelligibility. This renders the
modification of the voiced sounds as well. Hence, characterizing all the deviations using relevant acoustic features and then
modification of the same are expected to provide intelligible
speech. The knowledge of deviated acoustic characteristics
explored for the analysis of CLP speech in the previous
works [18]–[20] can be used to enhance the distorted word
intelligibility.
A. Database description
The database was created in collaboration with the speech
language pathologists (SLPs) of All India Institute of Speech
and Hearing (AIISH), Mysuru, India. The database consists
of age and gender matched CLP and non-CLP speakers’
speech. The non-CLP speakers served as controls for the
study. Both the CLP and non-CLP children are native Kannada
speakers. Prior to the recording, ethical consents were obtained
from the parents/caregivers of each of the participants. An
overview of the study is provided to the parents/caregivers.
The study was conducted with clearance from the AIISH
Bio-behavioral ethical committee. In this work, nonsensical
words are used for analysis and modification. All the speech
samples are recorded in a sound-proof room using a speech
level meter (Bruel and Kjær) at a sampling frequency of 48
kHz and 16-bit resolution [21]. The recorded speech samples
are saved in a .WAV format. The microphone was placed at a
distance of 15 cm from each speaker while recording. During
recording, the instructor first uttered the target word, then the
response of the children was recorded. Each of the expert SLP
had an experience of around five years in the field of CLP
speech evaluation. The speech samples are recorded for 2-3
sessions for each of the speaker. The total number of speakers,
number of tokens, and assessment of the distorted samples
for fricatives, stops, and vowels can be found in [18], [19],
and [20] respectively.
B. Modification of fricative-vowel-fricative-vowel words
Considering the combination of misarticulated fricative /s/
and vowels /a/, /i/, and /u/ as /sasa/, /sisi/, and /susu/, the
enhancement task must address all the distorted phonemes to
improve the overall speech intelligibility and quality [11], [12].
The enhancement techniques exploited in the previous works,
such as spectral energy compression [18], insertion [22],
spectral conversion [23] and temporal processing [24] are
briefly discussed for word-level intelligibility. The experimental details of the aforementioned techniques can be found
in [18]–[20].
Fig. 1. Comparison of (a)-(b) non-CLP (healthy) /sasa/, (c)-(d) NAE distorted
/sasa/, (e)-(f) enhanced /sasa/ using GMM based spectral conversion method
and (g)-(h) enhanced /sasa/ using NMF based spectral conversion method .
If spectral compression technique is to be applied to modify
the entire /sasa/ or /sisi/ or /susu/ word, then lower frequency
region compression will yield enhanced fricatives but it will
deteriorate the vowels at the same time because low-frequency
energy is important for vowel perception [25]–[28]. In certain
cases, if vowels are nasalized, insertion method may be
applicable but its perceptual quality will be far from the natural
speech as it may not preserve the individuality information.
Considering the temporal processing method described in [24],
a fine weight function is applied around the glottal closure
instants (GCI) locations to emphasize the significant GCI
events and suppress any interfering signal components around
it. If the fricative-vowel-fricative-vowel (FVFV) words are
processed using temporal processing method, it is speculated
that it might not result in effective transformation because
the excitation source for fricative is a noise source signal
and with temporal processing important signal components
might get suppressed. As each of the phonemes have different
spectral and temporal phenomena, the distortions caused by
the articulatory impairment affects each phoneme differently.
Further, considering the spectral conversion method, mapping
the distorted CLP spectra to a desired speech spectra is a
good strategy towards attaining CLP speech enhancement.
Hence, an attempt is made to enhance /FVFV/ words using
Gaussian mixture modeling (GMM) based spectral conversion
method [23].
The enhanced /sasa/ word using GMM based spectral conversion is depicted in Fig. 1 (e)-(f). After performing enhancement, it is observed that GMM based spectral conversion of
hypernasal speech results in muffled speech. Further analysis
of the modified speech signal showed that the spectrally modified speech is observed to have low nasalization compared
to original /FVFV/ word. In Fig. 1 (c)-(d) the fricatives are
ambiguous and the overall speech quality is still degraded.
�The speech degradation may be attributed to the oversmoothing effect. Because of the oversmoothing effect the
formants of the vowels are observed to have larger bandwidth,
smaller peak-to-valley ratio, and the fricative spectrum are
observed to have deviant acoustic characteristics and spectral tilt. Several techniques are proposed in the literature to
overcome the smoothening affect, where one of the approach
corresponds to the parametric voice conversion (VC) method
which is reported to alleviate the oversmoothing effect. Therefore, nonnegative matrix factorization (NMF) based speech
enhancement is used to modify the /FVFV/ word and shown
in Fig. 1 (g)-(h) [7]. The modified /FVFV/ word shows
some improvement compared to original /FVFV/ word but
its acoustic characteristics are still far from that of the nonCLP /FVFV/ word shown in Fig. 1 (a)-(b). Although some
improvements are observed as reduction in nasalization and
spectral prominence in the high-frequency region for fricatives. However, further observation showed that low frequency
energy in the fricatives persists and the formants of the vowels
are not distinct. Thus, it projects the importance of processing
different class of sound units separately.
C. Modification of consonant-vowel-consonant-vowel words
The consonant-vowel-consonant-vowel (CVCV) words consisting of the stops /k/, /t/ and /T/ in vowel contexts /a/, /i/, and
/u/ are analyzed similar to that of the /FVFV/ described in previous section. The possible combination of words are /kaka/,
/kiki/, /kuku/, /tata/, /titi/, /tutu/, /TaTa/, /TiTi/, and /TuTu/. The
spectral compression technique may not effectively transform
the /CVCV/ word because the spectral prominence of consonants are not confined to a specific frequency band. For example, the velar stop /k/ is characterized by prominent spectral
energy in the low-frequency region, whereas, the alveolar stop
/t/ shows spectral prominence around mid-frequency region
and retroflex /T/ shows spectral prominence above 2 kHz.
Additionally, formants of the vowels are observed in the lowfrequency region. Therefore, spectral energy compression in
the low-frequency region will result in further deterioration of
the /CVCV/ words. Further, temporal processing will result in
vowel modification only and using insertion method artificially
synthesized phoneme can be used for speech modification.
However, insertion method does not preserve the individuality
information. Hence, spectral compression, temporal processing
and insertion method might not be effective in transforming the
entire /CVCV/ word. The consonants are very short duration
phonemes with dynamic characteristics that represents different spectral and temporal importance [29], [30]. The spectral
prominence for consonants ranges from low-frequency region
to high-frequency region and in vowels the lower frequency
region are mostly considered to carry important perceptual
information [22]. Hence, the modification technique designed
for a specific category of phoneme may or may not be effective
in transforming the disordered nature of other phoneme. As
stated in the previous section, mapping the disordered speech
spectra into that of the non-CLP speech spectra may improve
the speech intelligibility and quality. Hence, the modification
Fig. 2. Comparison of (a)-(b) non-CLP /kaka/, (c)-(d) misarticulated /kaka/,
(e)-(f) enhanced /kaka/ using GMM based spectral conversion method and
(g)-(h) enhanced /kaka/ using NMF based spectral conversion method.
of /CVCV/ word is also attempted using GMM and NMF
based spectral conversion respectively.
For illustration, the transformed signals for the word /kaka/
is shown in Fig. 2. From the figure, it is observed that
the vowel formants and the consonants in Fig. 2 (e)-(f) and
Fig. 2 (g)-(h) are not similar to non-CLP speech characteristics
shown in Fig. 2 (a)-(b). Based on the above figures, it is
observed that the enhanced speech signal does not show significant improvement relative to the original unprocessed signal.
The reason may be attributed to the complex relationship of
the misarticulations and nasality in CLP speech. Hypernasality
and articulation error both show an impact in the same word
reducing the speech intelligibility and quality. In the above
figures, for an illustration only /kaka/ is depicted. However,
similar analysis are observed for other misarticulations in
the stop /t/ and /T/, respectively. Both the NMF and GMM
based spectral conversion had shown some improvement in the
speech characteristics, however, they are not able to effectively
enhanced the speech signal as desired. Therefore, this necessitates further analysis of the signal characteristics and then
perform modification. Hence, phoneme specific enhancement
can be attempted to observe the impact on the overall speech
intelligibility and quality of a word.
III. E XPERIMENTAL EVALUATION
In this section, the impact of the combined phoneme specific
modification techniques are analyzed. From Fig. 1 and Fig. 2,
it is observed that when entire word is modified, all the
phoneme distortions (either fricative or consonant misarticulation or nasalization) were not reduced as desired.
When each of the phoneme in a word are modified independently as shown in Fig. 3 and Fig. 4, the impact of the
speech distortions are reduced significantly. Due to severity,
both articulation error and nasalization are observed in CLP
speech. To have an enhancement system capable of performing
the desired task, it is essential to improve the entire word
intelligibility.
�TABLE I
P-STOI VALUES FOR DIFFERENT COMBINATION OF NONSENSICAL WORDS . F DENOTE FRICATIVE / S /, C1 DENOTE CONSONANT / K /, C2 DENOTE
CONSONANT / T /, C 3 DENOTE CONSONANT /T/, GS DENOTE GLOTTAL STOP SUBSTITUTION , PA DENOTE PALATALIZED ARTICULATION , PSNAE DENOTE
PHONEME SPECIFIC NASAL AIR EMISSION , AND VELAR DENOTE VELAR SUBSTITUTIONS .
Words
Normal Reference
CLPoriginal
/FVFV/ (GS)
/FVFV/ (PA)
/FVFV/ (PSNAE)
/C1 VC1 V/ (GS)
/C2 VC2 V/ (GS)
/C2 VC2 V/ (Velar)
/C2 VC2 V/ (PA)
/C3 VC3 V/ (GS)
/C3 VC3 V/ (Velar)
/C3 VC3 V/ (PA)
0.88
0.88
0.88
0.84
0.81
0.81
0.81
0.82
0.82
0.82
0.02
0.11
0.12
0.04
0.12
0.13
0.13
0.15
0.18
0.16
Obstruent
0.27
0.26
0.35
0.11
0.14
0.14
0.14
0.17
0.19
0.18
CLPmodified
Vowel
Obstruent + vowel
0.23
0.46
0.22
0.44
0.21
0.49
0.33
0.40
0.16
0.37
0.18
0.39
0.19
0.42
0.24
0.43
0.23
0.39
0.18
0.42
A. Objective evaluation
Fig. 3. Illustration of waveform and spectrogram of: (a)-(b) clp /kaka/, (c)-(d)
modified /k/, (e)-(f) modified /a/, and (g)-(h) modified /k/ and /a/.
To analyze the effectiveness of the transformation method
exploited in our earlier works, the evaluation is carried out for
entire word modification and compared with isolated phoneme
modifications. At first the impact on word-level intelligibility
is evaluated for the enhanced speech obtained by transforming
only fricatives/consonants.
Fig. 4. Illustration of waveform and spectrogram of: (a)-(b) clp /sasa/, (c)-(d)
modified /s/, (e)-(f) modified /a/, and (g)-(h) modified /s/ and /a/.
In the second step, the enhanced speech obtained using only
vowel modification is evaluated. Finally, in the third step, the
enhanced speech obtained by exploiting the consonant and
vowel modification both are evaluated.
The modified CLP speech is assessed using pathological
short-time objective intelligibility (P-STOI) and pathological
extended short-time objective intelligibility (P-ESTOI) measures. The mathematical descriptions of P-STOI and P-ESTOI
can be found in [31].
The objective measures corresponding to P-STOI and PESTOI are noted in Table. I and Table. II, respectively. The
P-STOI and P-ESTOI values are computed for time-aligned
CLP speech signals and non-CLP (reference) signals. Before
comparing the measures, word specific reference templates
are created from non-CLP speaker’s speech. The reported
values are averaged across all the listeners corresponding to
the specific errors in all the vowel contexts. P-STOI values
in Table I indicate that compared to original CLP speech
misarticulation, modification of either of the error (obstruents
misarticulation or vowel nasalization) results in improved
intelligibility. However, from the P-STOI values, it is also
observed that modification of both the distorted obstruents
and vowels provide higher P-STOI values as compared to
standalone modification. Similar observations are also noted
for the P-ESTOI values tabulated in Table II.
For an illustration, the original and modified CLP words
are also analyzed using automatic speech recognition (ASR)
performance. As the speech data for this study are in the
Kannada language, a Kannada ASR system is developed using
KALDI speech recognition toolkit [32]. The ASR system
performance for various phoneme modification categories is
measured using phone error rate (PER) metric. The PER for
the original and modified CLP speech is shown in Table III.
Compared to the original unprocessed CLP speech, the recognition performance of the modified speech is relatively higher.
The modification of a specific phoneme also yield reduced
PER value compared to that of the original distorted CLP
speech. However, better performances are observed when both
the phonemes in the word are modified. In certain instances,
the PER of the combined modification is comparable to the
standalone modification of the phoneme. This implies that,
in those utterances, the distortion caused by that specific
phoneme is dominant.
�TABLE II
P-ESTOI VALUES FOR DIFFERENT COMBINATION OF NONSENSICAL WORDS . F DENOTE FRICATIVE / S /, C1 DENOTE CONSONANT / K /, C2 DENOTE
CONSONANT / T /, C 3 DENOTE CONSONANT /T/, GS DENOTE GLOTTAL STOP SUBSTITUTION , PA DENOTE PALATALIZED ARTICULATION , PSNAE DENOTE
PHONEME SPECIFIC NASAL AIR EMISSION , AND VELAR DENOTE VELAR SUBSTITUTIONS .
Words
Normal Reference
CLPoriginal
/FVFV/ (GS)
/FVFV/ (PA)
/FVFV/ (PSNAE)
/C1 VC1 V/ (GS)
/C2 VC2 V/ (GS)
/C2 VC2 V/ (Velar)
/C2 VC2 V/ (PA)
/C3 VC3 V/ (GS)
/C3 VC3 V/ (Velar)
/C3 VC3 V/ (PA)
0.25
0.25
0.25
0.19
0.31
0.31
0.31
0.29
0.29
0.29
0.02
0.06
0.01
0.03
0.09
0.07
0.06
0.12
0.15
0.01
TABLE III
P HONEME ERROR RATE (%) FOR VARIOUS COMBINATION OF
NONSENSICAL WORDS . F CORRESPONDS TO FRICATIVE / S /, C 1
CORRESPONDS TO CONSONANT / K /, C 2 CORRESPONDS TO CONSONANT
/ T /, C3 CORRESPONDS TO CONSONANT /T/, GS CORRESPONDS TO
GLOTTAL STOP SUBSTITUTION , PA CORRESPONDS TO PALATALIZED
ARTICULATION , PSNAE CORRESPONDS TO PHONEME SPECIFIC NASAL
AIR EMISSION , AND VELAR CORRESPONDS TO VELAR SUBSTITUTIONS .
Words
CLPoriginal
/FVFV/ (GS)
/FVFV/ (PA)
/FVFV/ (PSNAE)
/C1 VC1 V/ (GS)
/C2 VC2 V/ (GS)
/C2 VC2 V/ (Velar)
/C2 VC2 V/ (PA)
/C3 VC3 V/ (GS)
/C3 VC3 V/ (Velar)
/C3 VC3 V/ (PA)
68.85
59.23
63.38
67.17
64.30
68.46
49.72
77.31
75.26
72.54
Obstruent
56.08
38.80
39.99
55.44
53.04
59.96
43.52
63.09
64.91
61.43
CLPmodified
Vowel
Obstruent + vowel
58.15
54.53
36.83
31.58
35.28
32.97
58.78
53.14
59.27
52.73
50.18
54.04
48.06
42.98
65.92
62.28
67.22
63.29
62.18
57.65
TABLE IV
MCD VALUES FOR DIFFERENT COMBINATION OF NONSENSICAL WORDS . F
CORRESPONDS TO FRICATIVE / S /, C 1 CORRESPONDS TO CONSONANT / K /,
C2 CORRESPONDS TO CONSONANT / T /, C3 CORRESPONDS TO CONSONANT
/T/, GS CORRESPONDS TO GLOTTAL STOP SUBSTITUTION , PA
CORRESPONDS TO PALATALIZED ARTICULATION , PSNAE CORRESPONDS
TO PHONEME SPECIFIC NASAL AIR EMISSION , AND VELAR CORRESPONDS
TO VELAR SUBSTITUTIONS .
Words
CLPoriginal
/FVFV/ (GS)
/FVFV/ (PA)
/FVFV/ (PSNAE)
/C1 VC1 V/ (GS)
/C2 VC2 V/ (GS)
/C2 VC2 V/ (Velar)
/C2 VC2 V/ (PA)
/C3 VC3 V/ (GS)
/C3 VC3 V/ (Velar)
/C3 VC3 V/ (PA)
13.00
12.94
13.00
12.34
12.73
13.58
13.58
13.74
13.80
13.91
Obstruent
11.20
11.31
11.50
11.91
10.81
10.91
10.58
10.85
10.67
10.46
CLPmodified
Vowel
Obstruent + vowel
11.80
11.90
12.23
12.29
12.18
12.26
11.41
11.53
11.91
11.98
11.75
12.22
11.90
12.13
11.76
12.02
11.87
12.27
11.88
12.36
Considering the MCD values shown in Table IV, it is
observed that the combined modification of the obstruent and
vowels, results in lower MCD values relative to that of the
original distorted CLP words. The MCD values reported in
Table IV are averaged across all the listeners corresponding
to the specific errors in all the vowel contexts. The lower
MCD values of the modified words indicate that the spectral
difference between non-CLP (reference) and misarticulated
words are reduced significantly for all the words evaluated
Obstruent
0.06
0.09
0.02
0.07
0.15
0.08
0.10
0.17
0.15
0.07
CLPmodified
Vowel
Obstruent + vowel
0.13
0.18
0.16
0.22
0.15
0.24
0.16
0.20
0.17
0.23
0.10
0.16
0.17
0.23
0.20
0.22
0.21
0.19
0.11
0.27
in the study.
In certain cases, the objective intelligibility values of combined modifications are observed to be comparable with standalone modification. The probable reason may be attributed
to the fact that either obstruent or vowel in the word is less
distorted, hence resulting in comparable values.
B. Subjective evaluation
Listening experiment is also carried out to assess the wordlevel intelligibility by exploiting the phoneme specific modification techniques reported in the earlier works. The speech
quality of the distorted CLP speech and the modified CLP
speech is measured using a 5-point rating scale mean opinion
score (MOS) where, 1 = bad, 2 = fair, 3 = good, 4 = very good,
and 5 = excellent. A total of 10 naive listeners have particTABLE V
MOS FOR DIFFERENT COMBINATION OF NONSENSICAL WORDS . F
CORRESPONDS TO FRICATIVE / S /, C 1 CORRESPONDS TO CONSONANT / K /,
C2 CORRESPONDS TO CONSONANT / T /, C3 CORRESPONDS TO CONSONANT
/T/, GS CORRESPONDS TO GLOTTAL STOP SUBSTITUTION , PA
CORRESPONDS TO PALATALIZED ARTICULATION , PSNAE CORRESPONDS
TO PHONEME SPECIFIC NASAL AIR EMISSION , AND VELAR CORRESPONDS
TO VELAR SUBSTITUTIONS .
Words
CLPoriginal
/FVFV/ (GS)
/FVFV/ (PA)
/FVFV/ (PSNAE)
/C1 VC1 V/ (GS)
/C2 VC2 V/ (GS)
/C2 VC2 V/ (Velar)
/C2 VC2 V/ (PA)
/C3 VC3 V/ (GS)
/C3 VC3 V/ (Velar)
/C3 VC3 V/ (PA)
1.00±0.09
1.10±0.15
1.50±0.40
1.58±1.17
1.12±1.11
1.08±1.19
1.94±0.98
1.20±1.01
1.15±0.83
1.53±1.25
Obstruent
1.5±0.07
1.54±0.55
1.90±0.60
1.88±0.75
1.53±0.51
1.97±0.99
2.02±0.58
1.54±0.74
1.72±1.20
1.72±0.58
CLPmodified
Vowel
2.10±0.15
2.42±0.26
2.50±0.20
2.85±0.46
2.27±0.47
2.92±0.88
2.80±0.76
2.10±0.92
2.30±0.57
2.70±0.89
Obstruent + vowel
3.10±0.50
3.92±0.50
3.80±0.20
3.72±0.45
3.57±0.99
3.82±0.55
3.71±0.87
2.99±0.22
3.05±1.09
3.59±1.12
ipated in the study and the speech samples were randomly
numbered to avoid any bias towards the original or modified
speech. The listeners bear the knowledge of speech science.
Each of the listener have evaluated 120 speech samples (3
vowel contexts × 3 fricative /s/ errors × 4 variations = 36,
3 vowel contexts × 1 stop /k/ error × 4 variations = 12, 3
vowel contexts × 3 stop /t/ errors × 4 variations = 36, 3
vowel contexts × 3 stop /T/ errors × 4 variations = 36). The
MOS values are derived by averaging all the values across
each vowel context of the specific word from all the listeners.
�The averaged MOS values shown in Table V indicate that the
modification of all phonemes provide significant improvement
compared to the original and standalone modified CLP speech.
This study has been performed on speech data collected
in clinical settings from children having mild to moderate
CLP speech disorder. The scope of the work is limited to
studying specific CLP speech distortions in isolated phonemes
in the context of /CVCV/ words with identical /CV/ pairs. The
study primarily focuses on enhancing a few select obstruents
and vowels. Later, it is extended to some nonsensical /CVCV/
words that can be formed by combining the studied obstruents
and vowels. The proposed system is developed based on
certain assumptions in a controlled environment. Therefore,
realization of the proposed techniques in real-time deserves
future explorations.
IV. C ONCLUSION
The word-level intelligibility is attempted by combining
the specific phoneme modifications discussed in our previous
works. A comparison study is also done to observe whether
the transformation method exploited in our earlier works can
improve the entire word intelligibility. When the transformation method is used to modify the word as a whole, it is
observed that the speech sounds muffled. Hence, phoneme
specific modifications are exploited to observe its impact in
word intelligibility. From the evaluation results, it is observed
that, a significant improvement in the word-level intelligibility
can be achieved when all phonemes in the words are modified
independently.
V. ACKNOWLEDGEMENT
The authors would like to thank Dr. M. Pushpavathi and
Dr. Ajish Abraham, AIISH Mysore, for providing insights
about CLP speech disorder. The authors would also like to
acknowledge the research scholars of IIT Guwahati for their
participation in the perceptual test. This work is in part supported by a project entitled “NASOSPEECH: Development of
Diagnostic system for Severity Assessment of the Disordered
Speech” funded by the Department of Biotechnology (DBT),
Govt. of India.
R EFERENCES
[1] A. B. Kain, J.-P. Hosom, X. Niu, J. P. van Santen, M. Fried-Oken, and
J. Staehely, “Improving the intelligibility of dysarthric speech,” Speech
Communication, vol. 49, no. 9, pp. 743–759, 2007.
[2] F. Rudzicz, “Adjusting dysarthric speech signals to be more intelligible,”
Computer Speech & Language, vol. 27, no. 6, pp. 1163–1177, 2013.
[3] K. Nakamura, T. Toda, H. Saruwatari, and K. Shikano, “Speakingaid systems using GMM-based voice conversion for electrolaryngeal
speech,” Speech Communication, vol. 54, no. 1, pp. 134–146, 2012.
[4] T. L. Whitehill, “Assessing intelligibility in speakers with cleft palate: a
critical review of the literature,” The Cleft Palate-Craniofacial Journal,
vol. 39, no. 1, pp. 50–58, 2002.
[5] Y.-H. Lai and W.-Z. Zheng, “Multi-objective learning based speech
enhancement method to increase speech quality and intelligibility for
hearing aid device users,” Biomedical Signal Processing and Control,
vol. 48, pp. 35–45, 2019.
[6] F. Biadsy, R. J. Weiss, P. J. Moreno, D. Kanevsky, and Y. Jia, “Parrotron:
An end-to-end speech-to-speech conversion model and its applications
to hearing-impaired speech and speech separation,” in Proceedings of
Interspeech, 2019, pp. 4115–4119.
[7] S.-W. Fu, P.-C. Li, Y.-H. Lai, C.-C. Yang, L.-C. Hsieh, and Y. Tsao,
“Joint dictionary learning-based non-negative matrix factorization for
voice conversion to improve speech intelligibility after oral surgery,”
IEEE Transactions on Biomedical Engineering, vol. 64, no. 11, pp.
2584–2594, 2017.
[8] R. Aihara, R. Takashima, T. Takiguchi, and Y. Ariki, “Individualitypreserving voice conversion for articulation disorders based on nonnegative matrix factorization,” in Proceedings of IEEE International
Conference on Acoustics, Speech and Signal Processing (ICASSP), 2013,
pp. 8037–8040.
[9] K. Xiao, S. Wang, M. Wan, and L. Wu, “Reconstruction of mandarin
electrolaryngeal fricatives with hybrid noise source,” IEEE/ACM Transactions on Audio, Speech and Language Processing (TASLP), vol. 27,
no. 2, pp. 383–391, 2019.
[10] N. Bi and Y. Qi, “Application of speech conversion to alaryngeal speech
enhancement,” IEEE Transactions on Speech and Audio Processing,
vol. 5, no. 2, pp. 97–105, 1997.
[11] A. W. Kummer, Cleft Palate & Craniofacial Anomalies: Effects on
Speech and Resonance. Nelson Education, 2013.
[12] S. J. Peterson-Falzone, M. A. Hardin-Jones, and M. P. Karnell, Cleft
Palate Speech. Mosby St. Louis, 2001.
[13] G. Henningsson, D. P. Kuehn, D. Sell, T. Sweeney, J. E. TrostCardamone, and T. L. Whitehill, “Universal parameters for reporting
speech outcomes in individuals with cleft palate,” The Cleft PalateCraniofacial Journal, vol. 45, no. 1, pp. 1–17, 2008.
[14] M. Scipioni, M. Gerosa, D. Giuliani, E. Nöth, and A. Maier, “Intelligibility assessment in children with cleft lip and palate in Italian
and German,” in Tenth Annual Conference of the International Speech
Communication Association, 2009.
[15] A. Maier, C. Hacker, E. Noth, E. Nkenke, T. Haderlein, F. Rosanowski,
and M. Schuster, “Intelligibility of children with cleft lip and palate:
Evaluation by speech recognition techniques,” in 18th International
Conference on Pattern Recognition (ICPR), vol. 4. IEEE, 2006, pp.
274–277.
[16] P. Grunwell and D. Sell, “Speech and cleft palate/velopharyngeal anomalies,” Management of Cleft Lip and Palate. London: Whurr, 2001.
[17] C. Vikram, N. Adiga, and S. M. Prasanna, “Spectral enhancement of
cleft lip and palate speech.” in Proceedings of Interspeech, 2016, pp.
117–121.
[18] P. N. Sudro and S. M. Prasanna, “Modification of misarticulated fricative
/s/ in cleft lip and palate speech,” Biomedical Signal Processing and
Control, vol. 67, p. 102088, 2021.
[19] P. N. Sudro, C. Vikram, and S. M. Prasanna, “Event-based transformation of misarticulated stops in cleft lip and palate speech,” Circuits,
Systems, and Signal Processing, vol. 40, no. 8, pp. 4064–4088, 2021.
[20] P. N. Sudro and S. M. Prasanna, “Enhancement of cleft palate speech
using temporal and spectral processing,” Speech Communication, vol.
123, pp. 70–82, 2020.
[21] Bruel and Kjaer, 1942, https://www.bksv.com/en.
[22] K. Singh and N. Tiwari, “The structure of Hindi stop consonants,” The
Journal of the Acoustical Society of America, vol. 140, no. 5, pp. 3633–
3642, 2016.
[23] Y. Stylianou, O. Cappé, and E. Moulines, “Continuous probabilistic
transform for voice conversion,” IEEE Transactions on Speech and
Audio Processing, vol. 6, no. 2, pp. 131–142, 1998.
[24] P. Krishnamoorthy and S. R. M. Prasanna, “Enhancement of noisy
speech by temporal and spectral processing,” Speech Communication,
vol. 53, no. 2, pp. 154–174, 2011.
[25] K. N. Stevens, Acoustic phonetics. MIT press, 2000, vol. 30.
[26] S. Narayanan and A. Alwan, “Noise source models for fricative consonants,” IEEE Transactions on Speech and Audio processing, vol. 8,
no. 3, pp. 328–344, 2000.
[27] C. H. Shadle, “The acoustics of fricative consonants,” 1985.
[28] C. H. Shadle and S. J. Mair, “Quantifying spectral characteristics of
fricatives,” in Proceedings of 4th International Conference on Spoken
Language Processing (ICSLP), vol. 3, 1996, pp. 1521–1524.
[29] A. Prathosh, A. Ramakrishnan, and T. Ananthapadmanabha, “Estimation
of voice-onset time in continuous speech using temporal measures,” The
Journal of the Acoustical Society of America, vol. 136, no. 2, pp. EL122–
EL128, 2014.
[30] P. C. Delattre, A. M. Liberman, and F. S. Cooper, “Acoustic loci and
transitional cues for consonants,” The Journal of the Acoustical Society
of America, vol. 27, no. 4, pp. 769–773, 1955.
�[31] P. Janbakhshi, I. Kodrasi, and H. Bourlard, “Pathological speech intelligibility assessment based on the short-time objective intelligibility measure,” in Proceedings of IEEE International Conference on Acoustics,
Speech and Signal Processing (ICASSP), 2019, pp. 6405–6409.
[32] D. Povey, A. Ghoshal, G. Boulianne, L. Burget, O. Glembek, N. Goel,
M. Hannemann, P. Motlicek, Y. Qian, P. Schwarz et al., “The kaldi
speech recognition toolkit,” in IEEE 2011 workshop on automatic speech
recognition and understanding, no. CONF. IEEE Signal Processing
Society, 2011.
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Rohit Sinha