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Development of the SPACE intelligibility assessment method Catherine Middag, Gwen Van Nuffelen,

Development of the SPACE intelligibility assessment method Catherine Middag, Gwen Van Nuffelen, Jean-Pierre Martens, Marc De Bodt. Intelligibility = popular measure for pathological speech assessment Perceptual assessment affected by non-speech information :

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Development of the SPACE intelligibility assessment method Catherine Middag, Gwen Van Nuffelen,

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  1. Development of the SPACE intelligibility assessment method Catherine Middag, Gwen Van Nuffelen, Jean-Pierre Martens, Marc De Bodt SPACE Symposium - 06/02/09

  2. Intelligibility = popular measure for pathological speech assessment Perceptual assessment affected by non-speech information : familiarity of listener with speaker and type of disorder  hard to eliminate this subjective bias guessing on the basis of linguistic context  test material design must eliminate this bias Replacing the human listener by an automatic speech recognizer (ASR) can solve the two problems, but is the ASR sufficiently reliable? test case : automation of the Dutch Intelligibility Assessment (DIA) Introduction SPACE Symposium - 06/02/09

  3. top Dutch Intelligibility Assessment (DIA) • 50 isolated (nonsense) words • intelligibility = percent phonemes correct SPACE Symposium - 06/02/09

  4. How to apply ASR in the DIA? • Two approaches • let ASR recognize the words and count the percentage of correct decisions • let ASR check how well on average the acoustics support the phonetic transcription of the target word (=alignment) • Our experience • intelligibility emerging from first approach insufficiently reliable • therefore we developed a system based on alignment SPACE Symposium - 06/02/09

  5. acoustic feature sequence Xt target speech transcription System architecture : flow chart Speech aligner speaker features Intelligibility Prediction Model objective score SPACE Symposium - 06/02/09

  6. acoustic feature sequence Xt speaker features target speech transcription Intelligibility Prediction Model objective score System architecture : flow chart Speech aligner • Two systems: • complex state-of-the-art HMM-based system (ASR-ESAT) • simple system with a phonological layer (ASR-ELIS) • (point more directly to articulatory problems) • Acoustic models trained on speech of normal adult speakers SPACE Symposium - 06/02/09

  7. ASR - ESAT • Acoustic models • state-of-the-art Semi-Continuous HMM • triphone models trained on normal speech • states tied using decision trees + phonological questions • Output • each frame t assigned to state st • per frame : st, P(st|Xt)‏ SPACE Symposium - 06/02/09

  8. ASR - ELIS Xt 24 binary phonological features concerning : • voicing • manner of articulation • place of articulation target speech transcription PLF extractor P(S1|Xt), …, P(Sn|Xt) P(K1|Xt), …, P(K24|Xt) Probability product model Viterbi decoder P(K1|Xt)..P(K24|Xt)‏ st, P(st|Xt)‏ SPACE Symposium - 06/02/09

  9. acoustic feature sequence Xt target speech transcription System architecture : flow chart Speech aligner speaker features Intelligibility Prediction Model • Three feature sets: • Phonemic features (patient has trouble pronouncing a certain phoneme) • Phonological features (patient has problems with voicing, manner or place of articulation) • NEW : context-dependent features (patient has problems with a desired change of voicing, manner or place of articulation) objective score SPACE Symposium - 06/02/09

  10. Extraction of phonemic features (PMF) # : (0.7+0.5+0.3) /3 /p/ : (0.4+0.8) /2 /o/ : (0.6+0.8) /2 /l/ : 0.6 Speech aligner = ASR-ESAT Phonemic features SPACE Symposium - 06/02/09

  11. Extraction of phonological features (PLF) Speech aligner = ASR-ELIS Phonological features Burst : 0.6 Back : (0.7+0.9)/2 Voiced : (0.8+0.6+0.5)/3 SPACE Symposium - 06/02/09

  12. Extraction of phonological features (PLF) Speech aligner = ASR-ELIS Phonological features Not burst : (0.2+0.1+… Not back : (0.1+0.1+… Not voiced : (0.1+0.1+… SPACE Symposium - 06/02/09

  13. Extraction of phonological features (PLF) Speech aligner = ASR-ELIS Phonological features Irrelevant features for these phones SPACE Symposium - 06/02/09

  14. Extraction of context-dependent phonological features (CD-PLF) • How well is change in PLF realized? • use PLF target in preceding/succeeding phone as context • binary features  two values for target (present/absent) • binary features  restricted number of left & right contexts • Left or right context can be • present, absent, not relevant, silence • Model selection (preliminary) • maximum 4 * 2 * 4 = 32 CD-PLFs per PLF  768 in total • select only those CD-PLFs occurring at least twice in every test  123 in total SPACE Symposium - 06/02/09

  15. Extraction of context-dependent phonological features (CD-PLF) Speech aligner = ASR-ELIS CD-PLF features SPACE Symposium - 06/02/09

  16. acoustic feature sequence Xt target speech transcription System architecture : flow chart Speech aligner speaker features Intelligibility Prediction Model objective score SPACE Symposium - 06/02/09

  17. Intelligibility prediction model (IPM) • Objective map speaker features (PMF, PLF, CD-PLF or combinations) to speaker intelligibility score • Model training • train on DIA recordings • pathological speakers (+ some normal control speakers) • Model type and size • limited number of pathological speakers • high number of features  linear regression model  feature selection SPACE Symposium - 06/02/09

  18. Reference material (DIA) • 211 speakers : • 51 normals • 60 dysarthric • 12 clefts (children) • 42 hearing impaired • 37 with laryngectomy • 7 with dysphonia • 2 others • Pathological speakers : mean of 78,7 % • Normals : mean of 93,3 % • Few with very low score SPACE Symposium - 06/02/09

  19. Solving microphone issues • Two microphones were used. • Difference can be found in cepstral means ( Cepstral mean subtraction was performed) : SPACE Symposium - 06/02/09

  20. Training / validation • Models chosen with five-fold cross validation • Measure = Standard deviation (STD) : in case of normality, 67% of the computed score lie in an interval of STD around the perceptual score • More features = more chance of overfitting • Rule of thumb : take 1 feature for every 10 training examples  Restrict number of features to maximum 15 SPACE Symposium - 06/02/09

  21. Results : individual systems PMFelis : 9.52 PMFesat : 8.57 SPACE Symposium - 06/02/09

  22. Results : individual systems PLF (elis) : 9.35 CD-PLF (elis) : 8.48 SPACE Symposium - 06/02/09

  23. Results : all systems • New models with CD-PLF outperform old PLF models • CD-PLFs form best system with one feature set • PMFesat + CD-PLF best system with combined feature sets • Using three ELIS feature sets yields next best result and needs only one recognizer (the simplest one)  less complex system SPACE Symposium - 06/02/09

  24. Results : combined system CD-PLF + PMFesat: STD = 7.34 SPACE Symposium - 06/02/09

  25. Results : pathology-specific IPM • Instead of creating one general IPM, one can create IPMs for specific pathologies : • trained on all speakers (to have enough speakers) • model selection based on performance on speakers of that pathology (importance of features depends on type of disorder) SPACE Symposium - 06/02/09

  26. Results : pathology-specific IPM (2) • Very good match in case CD-PLFs are involved • New models with CD-PLF outperform old PLF models • CD-PLFs form best system with one feature set • Using three ELIS feature sets yields (almost) best result and needs only one recognizer (the simplest one)  less complex system SPACE Symposium - 06/02/09

  27. Results : pathology-specific IPM • Dysarthria : 6.32 (red circles) • Dispersion of other speakers is increased • Largest deviations in low intelligibility area : • scarce data in that area • can be solved by adding more weight to patients with very low intelligibility SPACE Symposium - 06/02/09

  28. Conclusions and future work • PMF, PLF and CD-PLF can predict intelligibility of pathological speech: • CD-PLFs seem to play an important role : • STD = 7.34 for general model combining CD-PLF and PMFesat • STDs less than 6.32 for pathology specific model using 3 elis feature sets  not the articulation pattern but the change in the articulation pattern matters? • More research is needed before adding this feature set to the tool • Results on validation set compete with human inter-rater agreements. • Future work: • more profound articulatory assessment, which is directly related to determination of appropriate therapy • monitoring of effectiveness of chosen therapy • using more natural speech (words, phrases) in tests SPACE Symposium - 06/02/09

  29. Questions? SPACE Symposium - 06/02/09

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