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G. Naithani, J. Kivinummi, T. Virtanen, O. Tammela, M. J. Peltola et al., Automatic segmentation of infant cry signals using hidden Markov models, EURASIP Journal on Audio, Speech, and Music, vol.1, pp.1-14, 2018.

S. Orlandi, A. Guzzetta, A. Bandini, V. Belmonti, S. D. Barbagallo et al., AVIM-a contactless system for infant data acquisition and analysis: Software architecture and first results, Biomedical Signal Processing and Control, vol.20, pp.85-99, 2015.

, AUDIO-BASED CHARACTERIZATION OF NEWBORN CRIES FOR NEURO-DEVELOPMENTAL MONITORING

N. Otsu, A threshold selection method from gray-level histograms, IEEE Transactions on Systems, Man, and Cybernetics, vol.9, pp.62-66, 1979.

G. Raboshchuk, C. Nadeu, P. Jan?ovi?, A. P. Lilja, M. Köküer et al., A knowledge-based approach to automatic detection of equipment alarm sounds in a neonatal intensive care unit environment, IEEE journal of Translational Engineering in Health and Medicine, vol.6, pp.1-10, 2018.

Y. Shinya, M. Kawai, F. Niwa, and M. Myowa-yamakoshi, Preterm birth is associated with an increased fundamental frequency of spontaneous crying in human infants at term-equivalent age, Biology Letters, vol.10, 2014.

Y. Stylianou, Harmonic plus noise models for speech, combined with statistical methods, for speech and speaker modification, 1996.

J. Tukey, Exploratory data analysis. Reading, 1977.

G. Várallyay, Future prospects of the application of the infant cry in the medicine, Periodica Polytechnica Electrical Engineering, vol.50, issue.2, pp.47-62, 2006.

G. Várallyay, The melody of crying, International Journal of Pediatric Otorhinolaryngology, vol.71, pp.1699-1708, 2007.

J. Bekhof, J. B. Reitsma, J. H. Kok, and I. H. Van-straaten, Clinical signs to identify lateonset sepsis in preterm infants, European journal of pediatrics, vol.172, pp.501-508, 2013.

S. Cabon, F. Porée, A. Simon, U. , M. Rosec et al., Caractérisation du mouvement chez les nouveau-nés prématurés par analyse automatique de vidéos, Recherche en Imagerie et Technologies pour la Santé (RITS, 2017.

S. Cabon, F. Porée, A. Simon, U. , M. Rosec et al., Motion estimation and characterization in premature newborns using long duration video recordings, IRBM, vol.38, pp.207-213, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01535540

S. Cabon, F. Porée, A. Simon, B. Met-montot, P. Pladys et al., Audio-and video-based estimation of the sleep stages of newborns in neonatal intensive care unit, Biomedical Signal Processing and Control, 2019.
URL : https://hal.archives-ouvertes.fr/inserm-02138465

S. Cabon, F. Porée, A. Simon, O. Rosec, P. Pladys et al., Video and audio processing in paediatrics: a review, Physiological Measurement, 2019.
URL : https://hal.archives-ouvertes.fr/hal-01998530

N. Mazille, A. Lebris, P. Simonot, M. Luherne, G. Gascoin et al., Parents' and caregivers' perceptions of the use of live video recording in neonatal units, a qualitative study, 2019.

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, LIST OF PUBLICATIONS International journal with peer-review processes

S. Cabon, F. Porée, A. Simon, B. Met-montot, P. Pladys et al.,

G. , Audio-and Video-based estimation of the sleep stages of newborns in Neonatal Intensive Care Unit, Biomedical Signal Processing and Control, vol.52, pp.362-370, 2019.

S. Cabon, F. Porée, A. Simon, M. Ugolin, O. Rosec et al., Motion Estimation and Characterization in Premature Newborns Using Long Duration Video Recordings, Innovation and Research in BioMedical engineering, vol.38, issue.4, pp.207-213, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01535540

S. Cabon, F. Porée, A. Simon, M. Ugolin, O. Rosec et al., et Pladys P. Caractérisation du mouvement chez les nouveau-nés prématurés par analyse automatique de vidéos, Journées RITS, 2017.

F. Porée, A. Simon, S. Cabon, A. Corolleur, N. Nardi et al., Traitement de vidéos de polysomnographie pour l'estimation de l'état des yeux chez le nouveau-né prématuré, XXVe Colloque GRETSI, pp.1-4, 2015.

R. Weber, S. Cabon, F. Porée, A. Simon, and G. Et-carrault, ViSiAnnoT: Video and Signal Annotation Tool, Dépôt APP, 2019.

F. Porée, A. Simon, G. Carrault, P. Pladys, S. Cabon et al.,

, Caractérisation Automatique du comportement en Pédiatrie par Traitements Informatisés de Vidéos. Dépôt APP no IDDN, 2016.

. .. Liste-du-materiel,

.. .. Nettoyage,

. .. Installation-du-dispositif-d'enregistrement,

, Système d'enregistrement des signaux électrophysiologiques

. .. Système-d'enregistrement-vidéo, 2.3. Configuration « Lit ouvert avec pied à perfusion »

. .. Mise-en-route,

C. .. De-l'enregistrement,

A. and .. .. ,

, 1.2. Vérification de l'orientation

A. De-l'enregistrement and .. .. ,

. .. Stockage-des-donnees,

. .. Transfert-des-enregistrements,

N. .. Mise-en-route-du,

. .. Mise-a-jour-du-logiciel,

. En and . .. De-difficultes, , vol.19

, Câble d'alimentation

, Câble de connexion

, Liste du matériel Capteur multimodal : Système de fixation : Système d'enregistrement : Unité de configuration (*)

, Une seule unité par centre 16. Câbles de connexion noirs 17

U. Adaptateur and . Rj45,

, Boîtier principal (+rotule)

P. C. Mini and . Nuc,

, Multiprise électrique 11. Raspberry Pi ou « RPi » 12

, Lingettes Bactynéa® (Laboratoire Garcin-Bactinyl)

. Procédure-d'entretien,

, Le capteur multimodal complet et son système de fixation (cf. « Liste du matériel ») devra être nettoyé avant chaque session d'enregistrement. Il devra également être retiré du lit de l'enfant afin de permettre un entretien complet à chaque nettoyage de la couveuse

, Penser à éteindre le capteur en appuyant sur le bouton du boîtier principal

, Le dispositif vidéo devra être repositionné après l'entretien quotidien dans le lit de l'enfant au même emplacement que lors de la mise en place du système, Ne pas oublier de rallumer le boîtier si vous l'avez éteint

, Le reste du matériel d'enregistrement vidéo et signal seront intégrés au bionettoyage de la chambre

, Essuyage humide des surfaces avec la lingette en portant une attention

, Séchage passif 3. Rinçage avec une chiffonnette à usage unique, propre, imprégnée (bien essorée) d'eau du robinet Bien refermer le couvercle des lingettes après utilisation pour que le taux d'imprégnation soit optimum jusqu

, Ajouter l'adaptateur (#18) au câble de connexion noir (#16)

, Brancher le tout entre le NUC sur un des ports USB à l'avant et le PC sur le port Ethernet

, Brancher et allumer le PC de configuration (#17)

, Accès à l'interface utilisateur

, Lors de l'allumage du PC de configuration, une fenêtre intitulée « Visionneur de bureaux distants Remmina » s'ouvre automatiquement. Pour accéder à l'interface utilisateur, il suffit de double-cliquer sur « NUC

, Pour se déconnecter de l'interface, cliquer sur le bouton « Déconnexion » tout en haut de l'écran

, Brancher le câble Ethernet noir (#20) sur le PC de configuration et sur la prise Ethernet 3 du NAS

, Faire un double-clic sur l

, Un navigateur s'ouvre et demande une identification

, L'interface de pilotage du NAS s'affiche. Cliquer sur l'icône « File Station

, Copier les données à collecter (cf. fichier de suivi des collectes) vers le disque de collecte