A Voice-Input Voice-Output Communication Aid for People With Severe Speech Impairment

Hawley, Mark; Cunningham, Stuart; Green, Phil; Enderby, Pam; Palmer, Rebecca; Sehgal, Siddharth; O'Neill, Peter

doi:10.1109/tnsre.2012.2209678

Cited by 88 publications

(61 citation statements)

References 18 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The benefits of such a setup has proved effective for dysarthric people using speech as an interface for natural communication [9] or enabling them to control physical devices through speech commands [7].…”

Section: Speech Interface and Dysarthriamentioning

confidence: 99%

Model adaptation and adaptive training for the recognition of dysarthric speech

Sehgal¹,

Cunningham²

2015

Proceedings of SLPAT 2015: 6th Workshop on Speech and Language Processing for Assistive Technologies

Self Cite

View full text Add to dashboard Cite

Dysarthria is a neurological speech disorder, which exhibits multi-fold disturbances in the speech production system of an individual and can have a detrimental effect on the speech output. In addition to the data sparseness problems, dysarthric speech is characterised by inconsistencies in the acoustic space making it extremely challenging to model. This paper investigates a variety of baseline speaker independent (SI) systems and its suitability for adaptation. The study also explores the usefulness of speaker adaptive training (SAT) for implicitly annihilating inter-speaker variations in a dysarthric corpus. The paper implements a hybrid MLLR-MAP based approach to adapt the SI and SAT systems. ALL the results reported uses UA-SPEECH dysarthric data. Our best adapted systems gave a significant absolute gain of 11.05% (20.42% relative) over the last published best result in the literature. A statistical analysis performed across various systems and its specific implementation in modelling different dysarthric severity sub-groups, showed that, SAT-adapted systems were more applicable to handle disfluencies of more severe speech and SI systems prepared from typical speech were more apt for modelling speech with low level of severity.

show abstract

Section: Speech Interface and Dysarthriamentioning

confidence: 99%

Model adaptation and adaptive training for the recognition of dysarthric speech

Sehgal¹,

Cunningham²

2015

Proceedings of SLPAT 2015: 6th Workshop on Speech and Language Processing for Assistive Technologies

Self Cite

View full text Add to dashboard Cite

show abstract

“…That is, 2 where s(n; m) and α i (m) are the n-th sample of clean voiced speech and the i-th LP coefficient at the m-th frame, respectively. Then, by searching the local maxima of FOD, we determine whether one of them is greater than a pre-defined threshold, which is set to 0.5 in this paper.…”

Section: Phoneme Classification For Noise Reductionmentioning

confidence: 99%

“…In fact, the performance of modern ASR systems is quite satisfactory, and thus a considerable number of applications have been actively deployed in real-world environments. Furthermore, several attempts have been made in recent years to bring the convenience of ASR to disabled people who have severe constraints to their body movement, allowing only a narrow scope of physical activity [2]. In particular, some of these attempts have been focused on people with dysarthria who have paralysis of the articulator as well as most other parts of the body due to damage to their central nervous system.…”

Section: Introductionmentioning

confidence: 99%

Reducing Speech Noise for Patients with Dysarthria in Noisy Environments

Seong

Park

Kim

2014

IEICE Trans. Inf. & Syst.

View full text Add to dashboard Cite

SUMMARYDysarthric speech results from damage to the central nervous system involving the articulator, which can mainly be characterized by poor articulation due to irregular sub-glottal pressure, loudness bursts, phoneme elongation, and unexpected pauses during utterances. Since dysarthric speakers have physical disabilities due to the impairment of their nervous system, they cannot easily control electronic devices. For this reason, automatic speech recognition (ASR) can be a convenient interface for dysarthric speakers to control electronic devices. However, the performance of dysarthric ASR severely degrades when there is background noise. Thus, in this paper, we propose a noise reduction method that improves the performance of dysarthric ASR. The proposed method selectively applies either a Wiener filtering algorithm or a Kalman filtering algorithm according to the result of voiced or unvoiced classification. Then, the performance of the proposed method is compared to a conventional Wiener filtering method in terms of ASR accuracy.

show abstract

“…As discussed in [6], traditional automatic speech recognition techniques are unsuitable for impaired speech for several reasons: the amount of training material is limited, the training samples are highly variable, and they are very different from voices corresponding to non-disabled users.…”

Section: Related Workmentioning

confidence: 99%

“…For example, VIVOCA [6] is a voice-input voice-output augmentative communication aid for people with severe impairment. Joode et al present a detailed study on assistive technologies for people with cognitive deficits including different uses of speech technology [7], and Lancioni et al provide a review of speech generating devices for augmented communication [8].…”

Section: Introductionmentioning

confidence: 99%

A cross-lingual adaptation approach for rapid development of speech recognizers for learning disabled users

Bohac

Kucharova

Callejas

et al. 2014

J AUDIO SPEECH MUSIC PROC.

View full text Add to dashboard Cite

Building a voice-operated system for learning disabled users is a difficult task that requires a considerable amount of time and effort. Due to the wide spectrum of disabilities and their different related phonopathies, most approaches available are targeted to a specific pathology. This may improve their accuracy for some users, but makes them unsuitable for others. In this paper, we present a cross-lingual approach to adapt a general-purpose modular speech recognizer for learning disabled people. The main advantage of this approach is that it allows rapid and cost-effective development by taking the already built speech recognition engine and its modules, and utilizing existing resources for standard speech in different languages for the recognition of the users' atypical voices. Although the recognizers built with the proposed technique obtain lower accuracy rates than those trained for specific pathologies, they can be used by a wide population and developed more rapidly, which makes it possible to design various types of speech-based applications accessible to learning disabled users.

show abstract

A Voice-Input Voice-Output Communication Aid for People With Severe Speech Impairment

Cited by 88 publications

References 18 publications

Model adaptation and adaptive training for the recognition of dysarthric speech

Model adaptation and adaptive training for the recognition of dysarthric speech

Reducing Speech Noise for Patients with Dysarthria in Noisy Environments

A cross-lingual adaptation approach for rapid development of speech recognizers for learning disabled users

Contact Info

Product

Resources

About