Standardization of acoustic measures for normal voice patterns

Felippe, Ana Clara Naufel de; Grillo, Maria Helena Marotti Martelletti; Grechi, Thaís Helena

doi:10.1590/S0034-72992006000500013

Abstracts

Studies have established that normative data is necessary for acoustic analysis. The aim of the present study is to standardize fundamental frequency measures (fo), jitter, shimmer and harmonic-noise ratio (HNR) for young adults with normal voice. METHOD: 20 males and 20 females, between 20 and 45 years, without signs and symptoms of vocal problems; CSL-4300 Kay-Elemetrics; vowels /a/ and /é/. RESULTS: for females, vowels /a/ and /é/ had average measures of: fo 205.82 Hz and 206.56 Hz; jitter of 0.62% and 0.59%; shimmer of 0.22 dB and 0.19 dB; PHR of 10.9 dB and 11.04 dB, respectively. For males, vowel /a/ and /é/ had average measures of: fo 119.84 Hz and 118.92 Hz; jitter of 0.49% and 0.5%; shimmer of 0.22 dB and 0.21 dB; HNR 9.56 dB and 9.63 dB, respectively. Both fo and NHR female measures were significantly higher than their male counterparts. CONCLUSION: our results differ from the literature; therefore, it is important to standardize the program in use.

acoustic measures; standardization; normal voice

Pesquisas têm estabelecido que cada serviço deve estabelecer seus padrões normativos para a análise acústica. O objetivo do presente estudo é normatizar as medidas de freqüência fundamental (fo), jitter, shimmer e proporção harmônico-ruído (PHR) para adultos jovens com voz normal. MÉTODO: Participaram deste estudo 20 homens e 20 mulheres, de 20 a 45 anos de idade, sem sinais e sintomas de problemas vocais, produzindo as vogais sustentadas /a/ e /é/, analisadas pelo programa CSL- 4300 Kay-Elemetrics. RESULTADOS: Para as mulheres, respectivamente para a vogal /a/ e /é/ os valores médios foram: fo de 205,82Hz e 206,56Hz; jitter de 0,62% e 0,59%; shimmer de 0,22dB e 0,19dB; PHR de 10,9 dB e 11,04 dB. Para os homens, respectivamente para a vogal /a/ e /é/, os valores médios foram: fo de 119,84Hz e 118,92Hz; jitter de 0,49% e 0,5%; shimmer de 0,22 dB e 0,21 dB; PHR de 9,56 dB e 9,63dB. As medidas de fo e PHR foram significativamente maiores para as mulheres em comparação aos homens. CONCLUSÃO: As diferenças entre os nossos resultados e os dos outros autores confirmam a necessidade de se realizar a normatização para cada programa a ser utilizado.

medidas acústicas; normatização; voz normal

ORIGINAL ARTICLE

Standardization of acoustic measures for normal voice patterns

Ana Clara Naufel de Felippe^I; Maria Helena Marotti Martelletti Grillo^II; Thaís Helena Grechi^III

^IMS. PhD - FFCLRP-USP. Voice Specialist - CFFa. Professor of Speech and Hearing Therapy-Unaerp

^IIMS in Education - Voice Specialist - CFFa. Professor of Speech and Hearing Therapy-Unaerp

^IIISpecialist in Orofacial Movement- Professor of Speech and Hearing Therapy-Unaerp Especialista em Motricidade

^{Send correspondence to} Send correspondence to: R. Dr. João Gomes da Rocha 880 apto. 51 Ribeirão Preto SP 14.020-550. Tel: (0xx16) 623-1519 E-mail: anaedufelippe@netsite.com.br

SUMMARY

Studies have established that normative data is necessary for acoustic analysis. The aim of the present study is to standardize fundamental frequency measures (fo), jitter, shimmer and harmonic-noise ratio (HNR) for young adults with normal voice.

METHOD: 20 males and 20 females, between 20 and 45 years, without signs and symptoms of vocal problems; CSL-4300 Kay-Elemetrics; vowels /a/ and /é/.

RESULTS: for females, vowels /a/ and /é/ had average measures of: fo 205.82 Hz and 206.56 Hz; jitter of 0.62% and 0.59%; shimmer of 0.22 dB and 0.19 dB; PHR of 10.9 dB and 11.04 dB, respectively. For males, vowel /a/ and /é/ had average measures of: fo 119.84 Hz and 118.92 Hz; jitter of 0.49% and 0.5%; shimmer of 0.22 dB and 0.21 dB; HNR 9.56 dB and 9.63 dB, respectively. Both fo and NHR female measures were significantly higher than their male counterparts.

CONCLUSION: our results differ from the literature; therefore, it is important to standardize the program in use.

Keywords: acoustic measures, normal voice, standardization

INTRODUCTION

Acoustic analysis is one of the components of computerized voice labs, and it is useful to supplement voice assessment^1,2 and to assess speech^3-5.

Many are the acoustic parameters evaluated in this analysis, and the most commonly used for voice assessment are: fundamental frequency, jitter, shimmer and the harmony-noise ratio.

The fundamental frequency is an important parameter in both the functional and anatomical larynx assessment6 , and it is determined by the number of cycles produced by the vocal folds per second. Such measure is the result of the iteraction among vocal fold length, mass and tension during speech. Among acoustic parameters, fundamental frequency has proven to be the most uniform of them when we consider different acoustic analysis systems, and the one less sensitive to voice recording characteristics^7-9.

Frequency and cycle-to-cycle amplitude variation measures, jitter and shimmer, respectively, in the production of sustained vowels have proved to be useful in the description of normal and dysphonic speakers vocal characteristics, being respectively related to hoarseness and roughness^6,10-13. Fundamental frequency, jitter and shimmer seem to also suffer the influence of smoking - fundamental frequency is significantly lower and both jitter and shimmer are higher when we compare smokers to non-smokers¹⁴.

The harmony-noise ratio characterizes the relationship between the two components of the acoustic wave of a sustained vowel: the periodic component, vocal fold regular sign and the additional noise coming from the vocal folds and the vocal tract^15,16.

This ratio is also significantly different between genders, being higher for females¹⁷ , and it is also influenced by age, being lower for the elderly (from 70 to 90 years), when compared to a group of young (from 21 to 34 years) and middle age women(from 40 to 63 years)16, but it is not a sensitive parameter to differentiate the dysphonic from the normal voice. ¹³.

In Brazil, acoustic analysis has been more intensely used in the last decade. Casmerides and Costa18 carried out a study with 32 speech therapists who worked with voice, all of them were professors of Speech Therapy, in order to characterize this group of users, and found that 47% were interested in solving their clinical needs. This was the reason why they used acoustic analysis programs as a complementary tool in their practice. As a general opinion, they attempted to obtain less subjective and more quantitative data. Another result from such study was that, despite the fact that the users seemed to be worried about the quality of recorded samples, standardization did not occur among the users of the same type of lab, nor among the users of different lab types.

According to Titze¹⁹, standardization educates; simplifies; saves time, money and effort, and assures certification.

Knowing that speech and voice computerized analysis programs use different modes to calculate acoustic parameters, some studies attempt to standardize data for their equipment^{6,10,17,20,21} and others have compared their main acoustic measures among the different analysis programs, trying to know whether or not there is an agreement among them^7,22,23.

Karnell et al.²², compared the fundamental frequency, jitter and shimmer among 3 programs and found a measure agreement for the fundamental frequency, but not for jitter and shimmer.

Morris e Brown⁷ compared 6 different acoustic analysis systems in order to assess their reliability levels and the agreement among them in determining the fundamental frequency. Their results pointed towards high reliability in each one of the systems when they repeated the assessment of the same signal; however, the agreement among signals varied, being high for the fundamental frequency in men when they uttered a sustained vowel and also in oral reading for women, but low agreement for oral reading in men and sustained vowel for women. The authors also found that the CSL program proved to be the most accurate system to measure the fundamental frequency for the sustained vowel /a/; notwithstanding, it has the highest level of standard deviation, specially for vowel /a/.

Aiming at determining and comparing fundamental frequency values, jitter and shimmer of female individuals, through 4 acoustic wave analysis methods, Spinelli and Behlau²³ assessed 24 subjects without signs and prior history of vocal alterations when uttering the sustained vowel /a/. Results have shown that the fundamental frequency values were similar only between the Soundscope software and stroboscopy, which in turn were lower than the values found by the Vocal-2 software and higher than those found by the Dr. Speech software. Values for jitter and shimmer determined by the Soundscope and Dr. Speech software were statistically different.

Since the literature shows that there are many variables which compete for the final result of a computerized acoustic analysis, it is necessary to normatize the specific data from the software we are utilizing.

Thus, the goal of the present study was to normatize fundamental frequency, jitter, shimmer and noise-harmony ratio (NHR) measures for the CSL 4300 software, from Kay Elemetrics, used in the Speech Therapy Clinic of Ribeirão Preto, so as to obtain comparison data for voice analysis.

METHOD

This study was approved by the Ethics Committee for Research of the Ribeirão Preto University (protocol # 10/03). The subjects were informed about the goal, procedure and disclosure of its results. After agreeing, they signed an informed consent approved by the aforementioned committee and in agreement with Resolution # 196/96 Ministry of Health/ National Health Board/ National Committee of Research Ethics (MS/CNS/CNEP).

Forty young adults, 20 men and 20 women took part in this study. They all went to the University of Ribeirão Preto: they were employees, students, or they were accompanying patients who were going to the Speech Therapy Clinic. Minimum age was of 20 years, since puberty brings about voice alterations stemming from the voice change. Maximum age was of 45 years, because of possible voice changes caused by the very aging of the vocal apparatus as of this age. Age is a relevant variable in vocal assessment¹⁶.

Other selection criteria for the subjects included not having any signs and symptoms of voice change and not smoke¹⁴. The procedure used to assess the selection criteria was a questionnaire answered by the participant prior to sample collection (Attachment 1).

Besides not presenting voice alterations signs and symptoms (checked by the questionnaire), the participants voice was also assessed by the same two speech therapists (paper authors) and only data from the individuals considered with normal voice became part of the present study.

Data collection was carried out in a sound treated room, using the acoustic analysis software CSL-4300 from Kay-Elemetrics, at the Speech Therapy Clinic of the Ribeirão Preto University. The microphone used was a Shure SM 48 dynamic, and it was kept at a fixed distance of 5 cm in front of the subjects mouth. We used the sustained vowels /a/ and /é/, in a comfortable and habitual way, after deep inhaling. The sustained vowel is preferred over regular speech in vocal acoustic assessment²⁴. When the sample differed from the regular subjects voice, a new sample was collected. Vocal intensity was controlled by monitoring the softwares Vu meter.

In order to analyze the samples, we used the time of 3 seconds, and both the beginning and end of the vowel uttering were discarded. We also discarded the samples in which the authors found altered voice quality.

These vowels were analyzed as to their acoustic parameters: fundamental frequency (Hz), jitter (%), shimmer (dB) and noise-harmony ratio (NHR) (dB). Each one of these parameters was analyzed as to gender and vowel.

The statistical data analysis was carried out through SAS25 GLM procedure, considering the variance analysis mathematical model for random outlining, in split plots (split plot)26, using the following expression:

Where yijk = value observed regarding the in gender, from the jn subject, in the kn vowel; m = fixed factor, estimated by the general average; Ii = effect of the in gender (i = female and male); eij = random error corresponding to the plots, supposedly homocedastic, independent and normally distributed; Vk = effect of the kn vowel (k = /a/ and /e/); (SV)ik = effect of the interaction between the in gender with the kn vowel; eijk = random error, corresponding to the subplots, supposedly homocedastic, independent and normally distributed. The minimum level of significance used was of 5% (p£0.05).

RESULTS

Table 1 depicts the likelihood descriptive levels of the F test for the values assessed.

Thumbnail

We can see in Table 1 that the vowel factor and its interaction with gender was not significant (p>0.05) in all the cases, there has been a significant effect for the gender factor only on variables fo (p<0.0001) and NHR (p=0.0360), and the female averages were higher than their male counterparts for these variables (Graphs 1, ⁴ ). For jitter and shimmer, although female averages were higher than the male averages, they did not differ among themselves (p=0.0865) (Graphs 2, 3).

DISCUSSION

The fundamental frequency average found in the present study for vowel /a/, in men (120Hz) was lower than the ones found by Horii10 - 125Hz, by Araújo et al.²⁰ - 127.61Hz, by Morente et al.¹³ - 139.72Hz and higher than the one found by Behlau and Tosi²¹ - 113.01Hz. The average of the same parameter for women, 206Hz, was lower than the one found by Araújo et al.²⁰ - 215.42Hz and the one found by Morente et al.¹³ - 267.33Hz; however, it was very similar to the ones found by Ferrand¹⁶, which were 209.68Hz for young women and 204.49Hz for middle aged women.

The significant difference in the fundamental frequency average values in function of gender, found in the present study was expected, since it is influenced by the length of the vocal folds, which is longer in males. This difference has been often pointed out in the literature^20,21.

The jitter average regarding vowel /a/, for men was 0.498%, lower than the one found by Horii^6,10, which were 0.61% and 0.66%, respectively; however, it was higher than the average found by Tajada14 - 0.23% and by Araújo et al.²⁰ - 0.37%. As to the average jitter regarding vowel /a/, for females, our result (0.62%) was lower than the one found by Araújo et al.²⁰ - 0.85%, but similar to the one found by Ferrand¹⁶ - 0.69%.

The shimmer average for men, producing the vowel /a/, was 0.23dB, and such value was lower than the one found by Horii⁶, which was 0.47 dB and the one found by Araújo et al.²⁰, which was 2.37dB, but greater than the one found by Horii¹⁰, which was 0.132dB. Average shimmer for females producing the vowel /a/, in the present study was 0.22dB. This value was much lower than the one found by Araújo et al.²⁰, which was 2.52dB.

The jitter averages in function of gender were not significantly different, although the female gender presented a value that was below the one presented by males. Behlau and Tosi²¹ found a similar result and they also found it difficult to launch the hypothesis about which would be the reasons for this better sound control shown by women. These authors raised the possibility that it could happen because females use their voices more frequently, and this could be seen as training.

This lack of difference in the gender-related average jitter values corroborate other studies^6,13,21; however it disagrees from another one that found the average jitter value of 0.37% for men and 0.85% for women²⁰. As to shimmer, there was no difference as far as gender was concerned in the present study, and such data was also found in other papers^20,21.

The average of the noise-harmony ratio for men and women in the present study, when producing the vowel /a/, was respectively 9.56dB and 10.98dB, values above the ones found by Rodrigues et al.¹⁷, which were 8.63dB and 10.17dB and to the ones from Ferrand¹⁶, who found the value of 7.82 dB for young women. Just like it happened in the present study, Rodrigues et al.¹⁷, found a significant difference between genders, in other words, that women presented values significantly higher for the noise-harmony ratio in comparison to men. It may be that this is related to the fact that men use fluid voice more frequently, which is characterized by lesser glottal closure, and this favors voice production with less harmonics and or greater amount of glottal noise. In normal voices, basal recording is associated to a greater noise level¹⁷ and since such recording is more frequent in males, this would justify the result found.

In general, our results are similar only to those found by Ferrand¹⁶, maybe it is because they used the CSL model 4300 software, from Kay Elemetrics, as we did in the present study. The other studies mentioned used other acoustic analysis programs, such as Dr. Speech Science^13,14,23, Soundscope^17,23, Matlab¹², Vocal II²³, Kay Elemetrics 5500 DSP²² and a software developed by the Federal University of São Carlos²⁰.

Knowing of the possible value difference in acoustic parameters between different analysis software, some authors studied the issue^7,22,23. For fundamental frequency, one study found agreement among the software²², another found it only in sustained vowels for men, but not for women⁷ and a third one found an agreement in the fundamental frequency values between the software Soundscope and Stroboscopy, but not between Dr. Speech and the Vocal II²³. When we compare shimmer and jitter values from the different software, we have noticed a certain variability^22,23, and this makes it unfeasible to use the standards of a certain software in another.

Besides these differences among the different software, the recording criteria, the microphone, the way by which the programs calculate the parameters are factors that generate variations in the acoustic parameters. We should also consider the cultural variations that affect speech and voice, for example a higher or lower pattern in voice production.

The difference between our results and those from other authors confirm the need to normatize each software to be used.

We lack the references to discuss the values found for the vowel /é/, since the authors approaches did not use this vowel, but we also did not find significant differences among the vowels /é/ e /a/ in the present study.

CONCLUSION

The average values of normality found in the present study for male voices producing the vowel /a/ were fo = 120Hz, jitter = 0.498%, shimmer = 0.23dB and NHR = 9.56dB and producing the vowel /é/ were fo = 119Hz, jitter = 0.591%, shimmer = 0.218dB and NHR = 9.632dB. The average values found for females voices, producing the vowel /a/ were f0 = 206Hz, jitter = 0.62%, shimmer = 0.22dB and NHR = 10.98dB and for vowel /é/ were f0 = 207Hz, jitter = 0.590%, shimmer = 0.198dB and NHR = 11.04dB.

The differences in the programming of the various acoustic analysis systems, as well as the use of recording criteria and computers, microphones and other devices make each one of these systems a single one, thus, precluding a single normatization. Therefore, users should base themselves on their own normatization.

REFERENCES

Paper submitted to the ABORL-CCF SGP (Management Publications System) on August 31st, 2005 and accepted for publication on June 7th, 2006. Cod. 989.

Linked to the Course of Speech and Hearing Therapy - Universidade de Ribeirão Preto (UNAERP).

¹
Behlau M, Madazio G. Os laboratórios de voz na clínica moderna. Fono Atual 1997;3(3):9-16.
²
Yu P, Ouaknine M, Revis J, Giovanni A. Objective voice analysis for dysphonic patients: a multiparametric protocol including acoustic and aerodynamic measurements. J Voice 2001;15(4):529-42.
³
Behlau M, Pontes PAL. Análise perceptual acústica das vogais do português brasileiro falado em São Paulo. Acta AWHO 1988;7(2):67-73.
⁴
Panhoca I. Uma nova ótica para o "distúrbio articulatório" severo: contribuições da análise espectrográfica. Em: Lacerda CBF, Panhoca I. organizadores. Tempo em Fonoaudiologia. São Paulo: Cabral Editora Universitária; 1996/1997. p.35-60.
⁵
Fernandes LC, Polido A, Wertzner HF. Contribuições da análise acústica para o processo diagnóstico da alteração da articulação. Pró-fono 1999;11(2):61-7.
⁶
Horii Y. Vocal shimmer in sustained phonation. J. Speech Hear Res 1980;23(1):202-9.
⁷
Morris RJ, Brown WSJ. Comparison of various automatic means for measuring mean fundamental frequency. J. Voice 1996;10(2):159-65.
⁸
Behlau M, Madazio G, Feijó D, Pontes PAL. Avaliação de Voz. Em: Behlau M, editor. Voz: o livro do especialista. São Paulo: Revinter; 2001. 1:85-245.
⁹
Carson CP, Ingrisano DRS, Eggleston KD. The effect of noise on computer-aided measures of voice: a comparison of CSpeechSP and the Multi-Dimensional Voice Program Software using the CSL 4300B Module and Multi-Speech for Windows. J Voice 2003;17(1):12-20.
¹⁰
Horii Y. Jitter and shimmer differences among sustained vowel phonations. J Speech Hear Res 1982;25(1):12-4.
¹¹
Baken RJ, Orlikoff RF. Clinical measurement of speech and voice. 2nd ed. Delmar: Singular Publishing Group; 2000.
¹²
Jones TM, Trabold M, Plante F, Cheetham BM, Earis JE. Objective assessment of horseness by measuring jitter. Clin Otolaryngol 2001;26(1):29-32.
¹³
Morente JCC. Torres JAA, Jiménez MC, Maroto DP, Rodriguez VP, Gomariz EM, Baños EC, Ramos AJ. Estudio objetivo de la voz en población normal y en la disfonía por nódulos y pólipos vocales. Acta Otorrinolaringol Esp 2001;52(6):476-82.
¹⁴
Tajada JD, Liesa RF, Arenas EL, Gálvez MJN, Garrido CM Gormedino PR, García AO. The effect of tobacco consumption on acoustic voice analysis. Acta Otorrinolaringol Esp 1999;50(6):448-52.
¹⁵
Madazio G, Behlau M, Pontes P. Análise da proporção harmônico-ruído pré e pós-reabilitação vocal. In: Marchesan IQ, Zorzi JL, Dias ICG (org.) Tópicos em Fonoaudiologia. São Paulo: Lovise; 1998. p.169-89.
¹⁶
Ferrand CT. Harmonics-to-noise ratio: an index of vocal aging. J Voice 2002;16(4):480-7.
¹⁷
Rodrigues S, Behlau M, Pontes P. Proporção harmônico-ruído: valores para indivíduos adultos brasileiros. Acta AWHO 1994;13(3):112-6.
¹⁸
Casmerides MCB, Costa HO. Laboratório computadorizado de voz: caracterização de um grupo de usuários. In: Ferreira LP, Costa HO. Voz Ativa: falando sobre a clínica fonoaudiológica. São Paulo: Roca; 2001. p.263-80.
¹⁹
Titze IR. Toward standards in acoustic analysis of voice. J. Voice 1994;8(1):1-7.
²⁰
Araujo SA, Grellet M, Pereira JC. Normatização de medidas acústicas da voz normal. Rev Bras Otorrinolaringol 2002;68(4):540-4.
²¹
Behlau MS, Tosi O. Determinação da freqüência fundamental e suas variações em altura ("jitter") e intensidade ("shimmer") para falantes do português brasileiro. Acta AWHO 1985;4(1):5-10.
²²
Karnell MP, Hall KD, Landahl KL. Comparison of fundamental frequency and perturbation measurements among three analysis systems. J Voice 1995;9(4):383-93.
²³
Spinelli ICP, Behlau M. Estudo comparativo das medidas de freqüência fundamental, jitter e shimmer em diferentes sistemas de análise vocal. In: Behlau M. organizador. A voz do especialista. v.1. Rio de Janeiro: Revinter; 2001. p.265-71.
²⁴
Parsa V, Jamieson DG. Acoustic discrimination of pathological voice: sustained vowels versus continuous speech. J Speech Lang Hear Res 2001;44(2):327-39.
²⁵
SAS INSTITUTE. SAS/STAT Users Guide 8.0. Cary: SAS Institute Inc., 1999. CD-ROM. Produzido por Sas Institute Inc.
²⁶
Gomes FP. Curso de Estatística Experimental. 14nd ed. Piracicaba: o autor, 2000. 477 p.

Send correspondence to:

R. Dr. João Gomes da Rocha 880 apto. 51

Ribeirão Preto SP 14.020-550.

Tel: (0xx16) 623-1519

E-mail:

anaedufelippe@netsite.com.br

Publication Dates

Publication in this collection
21 Dec 2006
Date of issue
Oct 2006

History

Received
31 Aug 2005
Accepted
07 June 2006

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] ¹
Behlau M, Madazio G. Os laboratórios de voz na clínica moderna. Fono Atual 1997;3(3):9-16.

[2] ²
Yu P, Ouaknine M, Revis J, Giovanni A. Objective voice analysis for dysphonic patients: a multiparametric protocol including acoustic and aerodynamic measurements. J Voice 2001;15(4):529-42.

[3] ³
Behlau M, Pontes PAL. Análise perceptual acústica das vogais do português brasileiro falado em São Paulo. Acta AWHO 1988;7(2):67-73.

[4] ⁴
Panhoca I. Uma nova ótica para o "distúrbio articulatório" severo: contribuições da análise espectrográfica. Em: Lacerda CBF, Panhoca I. organizadores. Tempo em Fonoaudiologia. São Paulo: Cabral Editora Universitária; 1996/1997. p.35-60.

[5] ⁵
Fernandes LC, Polido A, Wertzner HF. Contribuições da análise acústica para o processo diagnóstico da alteração da articulação. Pró-fono 1999;11(2):61-7.

[6] ⁶
Horii Y. Vocal shimmer in sustained phonation. J. Speech Hear Res 1980;23(1):202-9.

[7] ⁷
Morris RJ, Brown WSJ. Comparison of various automatic means for measuring mean fundamental frequency. J. Voice 1996;10(2):159-65.

[8] ⁸
Behlau M, Madazio G, Feijó D, Pontes PAL. Avaliação de Voz. Em: Behlau M, editor. Voz: o livro do especialista. São Paulo: Revinter; 2001. 1:85-245.

[9] ⁹
Carson CP, Ingrisano DRS, Eggleston KD. The effect of noise on computer-aided measures of voice: a comparison of CSpeechSP and the Multi-Dimensional Voice Program Software using the CSL 4300B Module and Multi-Speech for Windows. J Voice 2003;17(1):12-20.

[10] ¹⁰
Horii Y. Jitter and shimmer differences among sustained vowel phonations. J Speech Hear Res 1982;25(1):12-4.

[11] ¹¹
Baken RJ, Orlikoff RF. Clinical measurement of speech and voice. 2nd ed. Delmar: Singular Publishing Group; 2000.

[12] ¹²
Jones TM, Trabold M, Plante F, Cheetham BM, Earis JE. Objective assessment of horseness by measuring jitter. Clin Otolaryngol 2001;26(1):29-32.

[13] ¹³
Morente JCC. Torres JAA, Jiménez MC, Maroto DP, Rodriguez VP, Gomariz EM, Baños EC, Ramos AJ. Estudio objetivo de la voz en población normal y en la disfonía por nódulos y pólipos vocales. Acta Otorrinolaringol Esp 2001;52(6):476-82.

[14] ¹⁴
Tajada JD, Liesa RF, Arenas EL, Gálvez MJN, Garrido CM Gormedino PR, García AO. The effect of tobacco consumption on acoustic voice analysis. Acta Otorrinolaringol Esp 1999;50(6):448-52.

[15] ¹⁵
Madazio G, Behlau M, Pontes P. Análise da proporção harmônico-ruído pré e pós-reabilitação vocal. In: Marchesan IQ, Zorzi JL, Dias ICG (org.) Tópicos em Fonoaudiologia. São Paulo: Lovise; 1998. p.169-89.

[16] ¹⁶
Ferrand CT. Harmonics-to-noise ratio: an index of vocal aging. J Voice 2002;16(4):480-7.

[17] ¹⁷
Rodrigues S, Behlau M, Pontes P. Proporção harmônico-ruído: valores para indivíduos adultos brasileiros. Acta AWHO 1994;13(3):112-6.

[18] ¹⁸
Casmerides MCB, Costa HO. Laboratório computadorizado de voz: caracterização de um grupo de usuários. In: Ferreira LP, Costa HO. Voz Ativa: falando sobre a clínica fonoaudiológica. São Paulo: Roca; 2001. p.263-80.

[19] ¹⁹
Titze IR. Toward standards in acoustic analysis of voice. J. Voice 1994;8(1):1-7.

[20] ²⁰
Araujo SA, Grellet M, Pereira JC. Normatização de medidas acústicas da voz normal. Rev Bras Otorrinolaringol 2002;68(4):540-4.

[21] ²¹
Behlau MS, Tosi O. Determinação da freqüência fundamental e suas variações em altura ("jitter") e intensidade ("shimmer") para falantes do português brasileiro. Acta AWHO 1985;4(1):5-10.

[22] ²²
Karnell MP, Hall KD, Landahl KL. Comparison of fundamental frequency and perturbation measurements among three analysis systems. J Voice 1995;9(4):383-93.

[23] ²³
Spinelli ICP, Behlau M. Estudo comparativo das medidas de freqüência fundamental, jitter e shimmer em diferentes sistemas de análise vocal. In: Behlau M. organizador. A voz do especialista. v.1. Rio de Janeiro: Revinter; 2001. p.265-71.

[24] ²⁴
Parsa V, Jamieson DG. Acoustic discrimination of pathological voice: sustained vowels versus continuous speech. J Speech Lang Hear Res 2001;44(2):327-39.

[25] ²⁵
SAS INSTITUTE. SAS/STAT Users Guide 8.0. Cary: SAS Institute Inc., 1999. CD-ROM. Produzido por Sas Institute Inc.

[26] ²⁶
Gomes FP. Curso de Estatística Experimental. 14nd ed. Piracicaba: o autor, 2000. 477 p.

Brasil

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Standardization of acoustic measures for normal voice patterns

Abstracts

Publication Dates

History