Adverse-Environment Recognition of Speech

Objectif

The objective of ARS was to develop improved algorithms for medium-size vocabulary speaker-dependent speech recognition in the presence of noise, and to build a real-time demonstrator. The demonstrator was to incorporate an isolated word noise-robust recogniser, verify algorithm performance, and address the problem of speech-based person-machine dialogue as a system interface in practical applications. The application environment chosen was the car.
The aim of the project is to extend the state of the art in speech recognition and to place this innovative technology in adverse environments such as car and factory floor. Starting from an established base of expertise, this project involves theoretical work on algorithms and the development of hardware prototypes. To get the best recognition performance, algorithms covering the different aspects of signal processing were considered. The activities were subdivided into 6 work packages concerning respectively system definition and standards, transducers and noise reduction, feature extraction, pattern processing, human factors and user interface, system prototyping and evaluation. After a brief presentation of the general structure of the project (objectives, organisation, participation, resources), this paper presents the state of the work after two years.

The objective of adverse environment recognition of speech (ARS) project was to develop improved algorithms for speech recognition in the presence of noise and to build a real time demonstrator. The demonstrator was to incorporate an isolated word noise robust recognizer, verify algorithm performance, and address the problem of speech based person machine dialogue as a system interface in practical applications.

The application environment chosen was the car. The system has a 100 word vocabulary, chosen by each national group of partners and tailored to the specific application environment. Advances were made in:
reduction, by signal preprocessing, of the effects of noise on speech signals;
feature extraction, to improve noise robustness;
study and refinement of algorithms for speech pattern matching in noisy environments;
speaker adaptation;
dynamic system adjustment to user feedback and the development of error correction strategies in the human interface;
development of system prototypes (hardware and firmware) for real time speech recognition.

The real time demonstrator was based on a general purpose digital signal processing (DSP) chip attached to a personal computer or a stand alone system. A multilingual database collected in noisy environments was made available and used for the evaluation of baseline systems. These were realized according to a common standard suitable for exchanging the software modules of the algorithms. Various algorithms were developed and evaluated and a set of algorithms for the final prototype were selected. A human machine interface concept was defined and the porting of the various models to the target system hardware was initiated.
The complete chain of processing has been initiated on a real time hardware; 2 demonstrators have been installed inside cars for assessment of their performance in real operating conditions.
The requirements included a 100-word vocabulary, chosen for each language group of partners and tailored to the specific application environment. Advances were needed in terms of:

- reduction, by signal preprocessing, of the effects of noise on speech signals
- feature extraction, to improve noise robustness
- study and refinement of algorithms for speech pattern matching in noisy environments
- speaker adaptation
- dynamic system adjustment to user feedback and the development of error correction strategies in the human interface
- development of system prototypes (hardware and firmware) for real-time speech recognition.

The system would be integrated in a real-time demonstrator based on a general-purpose DSP chip attached to a personal computer on a stand-alone system. Performance evaluations were first scheduled in the laboratory, using databases collected in noisy environments, to evaluate the resulting rate of correct recognition. Performance under field conditions were then to be assessed from a prototype fitted in a car and a laboratory system installed in a factory.

Champ scientifique (EuroSciVoc)

CORDIS classe les projets avec EuroSciVoc, une taxonomie multilingue des domaines scientifiques, grâce à un processus semi-automatique basé sur des techniques TLN. Voir: Le vocabulaire scientifique européen.

• sciences naturelles informatique et science de l'information logiciel
• sciences naturelles informatique et science de l'information bases de données
• ingénierie et technologie génie électrique, génie électronique, génie de l’information ingénierie électronique traitement des signaux
• sciences sociales psychologie psychologie ergonomique

Programme(s)

Programmes de financement pluriannuels qui définissent les priorités de l’UE en matière de recherche et d’innovation.

• FP2-ESPRIT 2 - European strategic programme (EEC) for research and development in information technologies (ESPRIT), 1987-1992

Thème(s)

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Régime de financement

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Coordinateur

Participants (9)