ALBAYZIN Query-by-example Spoken Term Detection 2016 evaluation

[EN] Query-by-example Spoken Term Detection (QbE STD) aims to retrieve data from a speech repository given an acoustic (spoken) query containing the term of interest as the input. This paper presents the systems submitted to the ALBAYZIN QbE STD 2016 Evaluation held as a part of the ALBAYZIN 2016 Evaluation Campaign at the IberSPEECH 2016 conference. Special attention was given to the evaluation design so that a thorough post-analysis of the main results could be carried out. Two different Spanish speech databases, which cover different acoustic and language domains, were used in the evaluation: the MAVIR database, which consists of a set of talks from workshops, and the EPIC database, which consists of a set of European Parliament sessions in Spanish. We present the evaluation design, both databases, the evaluation metric, the systems submitted to the evaluation, the results, and a thorough analysis and discussion. Four different research groups participated in the evaluation, and a total of eight template matching-based systems were submitted. We compare the systems submitted to the evaluation and make an in-depth analysis based on some properties of the spoken queries, such as query length, single-word/multi-word queries, and in-language/out-of-language queries.This work was partially supported by Fundacao para a Ciencia e Tecnologia (FCT) under the projects UID/EEA/50008/2013 (pluriannual funding in the scope of the LETSREAD project) and UID/CEC/50021/2013, and Grant SFRH/BD/97187/2013. Jorge Proenca is supported by the SFRH/BD/97204/2013 FCT Grant. This work was also supported by the Galician Government ('Centro singular de investigacion de Galicia' accreditation 2016-2019 ED431G/01 and the research contract GRC2014/024 (Modalidade: Grupos de Referencia Competitiva 2014)), the European Regional Development Fund (ERDF), the projects "DSSL: Redes Profundas y Modelos de Subespacios para Deteccion y Seguimiento de Locutor, Idioma y Enfermedades Degenerativas a partir de la Voz" (TEC2015-68172-C2-1-P) and the TIN2015-64282-R funded by Ministerio de Economia y Competitividad in Spain, the Spanish Government through the project "TraceThem" (TEC2015-65345-P), and AtlantTIC ED431G/04.Tejedor, J.; Toledano, DT.; Lopez-Otero, P.; Docio-Fernandez, L.; Proença, J.; Perdigão, F.; García-Granada, F.... (2018). ALBAYZIN Query-by-example Spoken Term Detection 2016 evaluation. EURASIP Journal on Audio, Speech and Music Processing. 1-25. https://doi.org/10.1186/s13636-018-0125-9S125Jarina, R, Kuba, M, Gubka, R, Chmulik, M, Paralic, M (2013). 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Comparison of ALBAYZIN query-by-example spoken term detection 2012 and 2014 evaluations

Query-by-example spoken term detection (QbE STD) aims at retrieving data from a speech repository given an acoustic query containing the term of interest as input. Nowadays, it is receiving much interest due to the large volume of multimedia information. This paper presents the systems submitted to the ALBAYZIN QbE STD 2014 evaluation held as a part of the ALBAYZIN 2014 Evaluation campaign within the context of the IberSPEECH 2014 conference. This is the second QbE STD evaluation in Spanish, which allows us to evaluate the progress in this technology for this language. The evaluation consists in retrieving the speech files that contain the input queries, indicating the start and end times where the input queries were found, along with a score value that reflects the confidence given to the detection of the query. Evaluation is conducted on a Spanish spontaneous speech database containing a set of talks from workshops, which amount to about 7 h of speech. We present the database, the evaluation metric, the systems submitted to the evaluation, the results, and compare this second evaluation with the first ALBAYZIN QbE STD evaluation held in 2012. Four different research groups took part in the evaluations held in 2012 and 2014. In 2014, new multi-word and foreign queries were added to the single-word and in-language queries used in 2012. Systems submitted to the second evaluation are hybrid systems which integrate letter transcription- and template matching-based systems. Despite the significant improvement obtained by the systems submitted to this second evaluation compared to those of the first evaluation, results still show the difficulty of this task and indicate that there is still room for improvement.This research was funded by the Spanish Government ('SpeechTech4All Project' TEC2012 38939 C03 01 and 'CMC-V2 Project' TEC2012 37585 C02 01), the Galician Government through the research contract GRC2014/024 (Modalidade: Grupos de Referencia Competitiva 2014) and 'AtlantTIC Project' CN2012/160, and also by the Spanish Government and the European Regional Development Fund (ERDF) under project TACTICA

Implementación y evaluación de un sistema QbE-STD (Query-by-Example Spoken Term Detection)

Con el fin de extraer información y reconocer palabras clave en los ficheros de audio presentes en medios de comunicación e Internet, surgen los sistemas QbE-STD (Query-by- Example Spoken Term Detecion). Los sistemas QbE-STD tratan, por un lado de buscar un ejemplo de un objeto o parte de él en otro objeto (QbE), y por otro de encontrar palabras o secuencias de ellas en archivos de audio (STD). En este Trabajo Fin de Máster se ha desarrollado un sistema QbE-STD independiente del idioma cuya entrada o query está basada en términos hablados, lo que permite a un usuario realizar una búsqueda en un repositorio de audio emitiendo con su voz el término a buscar. Como técnica de representación del habla se han empleado los llamados posteriorgramas fonéticos, obtenidos mediante los decodificadores fonéticos desarrollados por la Universidad de Tecnología de Brno (BUT). Para la detección de los términos de búsqueda en los repositorios de audio se ha utilizado el algoritmo Subsequence Dynamic Time Warping (S-DTW). Además de desarrollar un sistema QbE-STD que sirva como punto de partida para futuras vías de trabajo del grupo AUDIAS1, se han incluido distintas técnicas y aportaciones con el objetivo de intentar mejorar los resultados obtenidos. Entre estas técnicas se encuentra la selección de unidades fonéticas o la fusión de idiomas. Para el desarrollo de la solución y la realización de las pruebas se han utilizado los audios pertenecientes a las evaluaciones Albayzin 2016 y 2018 Search on Speech. Los resultados obtenidos se han podido contrastar con otros sistemas publicados, ya que para el cálculo de la precisión se ha empleado un procedimiento de evaluación oficial propuesto por el instituto de tecnología NIST y ampliamente utilizado. Los valores de precisión alcanzados demuestran que mediante el sistema básico se obtienen unos resultados competitivos y semejantes a los de otras implementaciones de este tipo.In order to extract information and recognize key words in the audio files belonging to media and Internet, QbE-STD (Query-by-Example Spoken Term Detection) systems are developed. QbE-STD systems have as purpose, on the one hand, to search for an example of an object or part of it in another object (QbE), and on the other, to find words or sequences of them in audio files (STD). In this Master Thesis, a language-independent QbE-STD system has been developed, whose input or query is based on spoken terms, which allows an user to perform a search in an audio repository by saying the search term with his/her own voice. As a technique of speech representation, phonetic posteriorgrams have been used, obtained through the phonetic decoders developed by the Brno University of Technology (BUT). The Subsequence Dynamic Time Warping (S-DTW) algorithm has been used to detect the search terms in the audio repositories. In addition to developing a QbE-STD system that will be used as a first point for future investigation of AUDIAS2 group, different techniques and contributions have been included in order to try to improve the achieved results. Among these techniques, the phonetic units selection or the languages fusion have been implemented. In the development and test phases, the audios belonging to the Albayzin 2016 and 2018 Search on Speech evaluation have been used. The achieved results have been compared with other published systems, because of the use of an official evaluation procedure proposed by NIST technology has been implemented to obtain accuracy. The precision values obtained show that competitive results have been achieved through the basic system, and these are similar to those of other implementations of this type

Detección de palabras clave en voz mediante ejemplos empleando redes neuronales profundas

Actualmente nos vemos inmersos en un mundo donde los datos multimedia son cada vez más cuantiosos y frecuentes. Con el objetivo de extraer información y detectar palabras clave en ficheros de audio presentes en medios de comunicación e Internet, entre otras aplicaciones como la interacción con sistemas sin teclado o búsquedas para personas ciegas, surgen los sistemas QbE-STD (Query-by-Example Spoken Term Detecion). Estos sistemas tienen como objetivo, buscar un ejemplo de un objeto o parte de él en otro objeto, que aplicado a nuestro trabajo consiste, en el reconocimiento de palabras o secuencias de ellas en archivos de audio. En este Trabajo Fin de Grado se ha tomado como punto de partida el Trabajo Fin de Máster con el título de “Implementación y evaluación de un sistema QbE-STD (Query-by-Example Spoken Term Detection)” de María Cabello Aguilar con el fin de desarrollar un nuevo módulo, donde emplearemos redes neuronales profundas, que servirá para mejorar los resultados obtenidos en las últimas evaluaciones Albayzin 2016 y 2018 Search on Speech. Al igual que anteriormente nuestro sistema deberá realizar la correcta detección independiente del idioma de la entrada o query, basada en términos hablados. Llegando incluso a ser posible que un usuario realice una búsqueda en un repositorio de audio emitiendo con su voz el término a buscar. La técnica empleada para representar estos términos hablados ha sido la de posteriorgramas fonéticos. Estos posteriorgramas se han obtenido haciendo uso de los decodificadores fonéticos desarrollados por la Universidad de Tecnología de Brno (BUT), empleandose también el kit de herramientas de modelos ocultos de Markov oculto (HTK) para la correcta utilización de estos posteriorgramas. Para realizar la detección de los terminos hablados en los correspondientes repositorios de audio se ha empleado las ya mencionadas redes neuronales profundas. Previo a esto se realizó un exahustivo trabajo de tratamiento de la base de datos con el fin de poder adaptar el material disponible a este nuevo módulo. De esta manera conseguimos desarrollar un sistema que puede servir como punto de partida para futuras vías de trabajo del grupo AUDIAS. 1 Para el desarrollo de la solución y la realización de las pruebas se han utilizado los audios pertenecientes a las evaluaciones Albayzin 2016 y 2018 Search on Speech, mencionado anteriormente. Con la intención de obtener resultados que se puedan contrastar con otros sistemas publicados similares pudiendo llegar a ser competitivos y semejantes a los de otras implementaciones parecidas

LOW RESOURCE HIGH ACCURACY KEYWORD SPOTTING

Keyword spotting (KWS) is a task to automatically detect keywords of interest in continuous speech, which has been an active research topic for over 40 years. Recently there is a rising demand for KWS techniques in resource constrained conditions. For example, as for the year of 2016, USC Shoah Foundation covers audio-visual testimonies from survivors and other witnesses of the Holocaust in 63 countries and 39 languages, and providing search capability for those testimonies requires substantial KWS technologies in low language resource conditions, as for most languages, resources for developing KWS systems are not as rich as that for English. Despite the fact that KWS has been in the literature for a long time, KWS techniques in resource constrained conditions have not been researched extensively. In this dissertation, we improve KWS performance in two low resource conditions: low language resource condition where language specific data is inadequate, and low computation resource condition where KWS runs on computation constrained devices. For low language resource KWS, we focus on applications for speech data mining, where large vocabulary continuous speech recognition (LVCSR)-based KWS techniques are widely used. Keyword spotting for those applications are also known as keyword search (KWS) or spoken term detection (STD). A key issue for this type of KWS technique is the out-of-vocabulary (OOV) keyword problem. LVCSR-based KWS can only search for words that are defined in the LVCSR's lexicon, which is typically very small in a low language resource condition. To alleviate the OOV keyword problem, we propose a technique named "proxy keyword search" that enables us to search for OOV keywords with regular LVCSR-based KWS systems. We also develop a technique that expands LVCSR's lexicon automatically by adding hallucinated words, which increases keyword coverage and therefore improves KWS performance. Finally we explore the possibility of building LVCSR-based KWS systems with limited lexicon, or even without an expert pronunciation lexicon. For low computation resource KWS, we focus on wake-word applications, which usually run on computation constrained devices such as mobile phones or tablets. We first develop a deep neural network (DNN)-based keyword spotter, which is lightweight and accurate enough that we are able to run it on devices continuously. This keyword spotter typically requires a pre-defined keyword, such as "Okay Google". We then propose a long short-term memory (LSTM)-based feature extractor for query-by-example KWS, which enables the users to define their own keywords