View full metadata
Cite as
-
Full Title
MECOSAN
-
Publisher
FrancoAngeli
-
ISSN
1121-6921 (Printed Journal)
2384-8804 (Online Journal)
-
Journal Issue Number
98
-
Journal Issue Designation
98
-
Journal Issue Date (YYYY/MM)
2016/11
-
Full Title
Uso delle piattaforme ICT a supporto dei servizi socio-sanitari: il progetto Attiv@bili
-
By (author)
-
First Page
125
-
Last Page
140
-
Language of text
Italian
-
Publication Date
2016/11
-
Copyright
2016 FrancoAngeli srl
Introduction or preface
Il presente lavoro si focalizza sul progetto Attiv@bili - Innovazione Sociale e Assistenza Digitale in Ambienti Controllati. Tale progetto, finanziato da Regione Lombardia, è finalizzato a disegnare un nuovo modello tecnologico per l'integrazione delle cure a supporto delle persone fragili (Integrated Care - IC) erogate presso il domicilio dell'assistito, per aumentarne l'empowerment e l'inclusione sociale. L'assistenza domiciliare integrata ai soggetti fragili prevede l'erogazione congiunta e coordinata di servizi sanitari e socio-assistenziali lungo tutte le fasi del processo di supporto. L'impiego di strumenti tecnologici, quali sistemi informativi e piattaforme di interoperabilità fra processi, nonché strumenti di supporto domotico, risulta indispensabile a garantire gli obiettivi sopra-descritti. Per questi motivi, il progetto Attiv@bili si è focalizzato sulla progettazione e lo sviluppo di una soluzione tecnologica focalizzata da una parte sull'integrazione dei processi di cura e dall'altra sul monitoraggio e supporto degli interventi erogati direttamente al domicilio dell'assistito. Questo lavoro descrive il risultato della fase di progettazione, inquadrando l'architettura logica prevista nello stato dell'arte in ambito Ambient Assisted Living ed evidenzia alcuni spunti utili per un riutilizzo del modello tecnologico in ambito sociosanitario.
Reference list of
10.3280/MESA2016-098007
Unstructured Citation
Aarts E., Encarnacao J. (2006). True Visions: The Emergence of Ambient Intelligence. Berlin Heidelberg: Springer-Verlag.
https://doi.org/10.1007/978-3-540-28974-6
Unstructured Citation
Aarts E., De Ruyter B. (2009). New perspectives on ambient intelligence. Journal of Ambient Intelligence and Smart Environments,
1(1): 5-14.
https://doi.org/10.3233/AIS-2009-0001
Unstructured Citation
Agnello M., Bragato D., Merlino L., Zocchetti C. (2011). Una nuova proposta per la cronicità: i CReG. Tendenze nuove, 5: 377-398.
Unstructured Citation
Amigoni F., Gatti N., Pinciroli C., Roveri M. (2005). What planner for ambient intelligence applications?. IEEE Transactions
on Systems, Man, and Cybernetics, Part A: Systems and Humans, 35 (1): 7-21.
https://doi.org/10.1109/TSMCA.2004.838465
Unstructured Citation
Baig M.M., Gholamhosseini H., Connolly M.J. (2013). A comprehensive survey of wearable and wireless ECG monitoring systems
for older adults. Medical & Biological Engineering & Computing, 51(5): 485-495.
https://doi.org/10.1007/s11517-012-1021-6
Unstructured Citation
Bieber G., Voskamp J., Urban B. (2009). Activity recognition for everyday life on mobile phones. In: Stephanidis C. (a cura di). Universal access in human-computer interaction. Fifth International Conference, UAHCI 2009, Held as Part of HCI International 2009, San Diego, CA, USA, July 19-24, 2009. Proceedings, Part II. San Francisco: Springer. ISBN 3-642-02709-1.
Unstructured Citation
Cook D.J., Augusto J.C., Jakkula V.R. (2009). Ambient intelligence: Technologies, applications, and opportunities. Pervasive
and Mobile Computing, 5 (4): 277-298.
https://doi.org/10.1016/j.pmcj.2009.04.001
Unstructured Citation
Crutzen C.K.M. (2006). Invisibility and the meaning of ambient intelligence. International Review of Information Ethics, 6:
1-11.
https://doi.org/10.29173/irie140
Unstructured Citation
Ding D., Cooper R.A., Pasquina P.F., Fici-Pasquina L. (2011). Sensor technology for smart homes. Maturitas, 69 (2): 131-136.
https://doi.org/10.1016/j.maturitas.2011.03.016
Unstructured Citation
Doctor F., Hagras H., Callaghan V. (2005). A fuzzy embedded agent-based approach for realizing ambient intelligence in intelligent
inhabited environments. IEEE Transactions on Systems, Man, and Cybernetics – Part A: Systems and Humans, 35 (1): 55-65.
https://doi.org/10.1109/TSMCA.2004.838488
Unstructured Citation
Fergenson M. (2013). TigerPlace: An innovative “Aging in Place” community. The American Journal of Nursing, 113 (1): 68-69.
Fitrianie S., Huldtgren A., Alers H., Guldemond
https://doi.org/10.1097/01.NAJ.0000425760.74321.97
Unstructured Citation
N.A. (2013). A SmartTV Platform for Wellbeing, Care and Social Support for Elderly at Home. In: Biswas J., Kobayashi H. (a cura di). Inclusive Society: Health and Wellbeing in the Community, and Care at Home. Berlin Heidelberg: Springer.
Unstructured Citation
Frontoni E., Mancini A., Zingaretti P. (2014). RGBD Sensors for human activity detection in AAL environments. In: Longhi S.,
Siciliano P., Germani
https://doi.org/10.1007/978-3-319-01119-6_13
Unstructured Citation
M., Monteriù A. (a cura di). Ambient Assisted Living. Italian Forum 2013. Switzerland: Springer International Publishing.
Unstructured Citation
Gottfried B., Guesgen H., Hüebner S. (2006). Spatiotemporal reasoning for smart homes. In: Augusto J.C., Nugent C.D. (eds).
Designing Smart Homes – The Role of Artificial Intelligence, in LNCS, vol. 4008, pp. 16-34. Heidelberg: Springer.
https://doi.org/10.1007/11788485_2
Unstructured Citation
Hammer M. (1990). Re-engineering work: Don’t automate, obliterate. Harvard Business Review, 77 (6): 104-112.
Unstructured Citation
Lesser V., Atighetchi M., Benyo B., Horling B., Raja A., Vincent R., Wagner T., Ping X., Zhang S.X. (1999). The intelligent home testbed. In: AA.VV. Proceedings of the Autonomy Control Software Workshop (Autonomous Agent Workshop), Seattle.
Unstructured Citation
Leutz W. (1999). Five Laws for Integrating Acute and Long-term Care. Milbank Quarterly, 77 (1): 77-110.
https://doi.org/10.1111/1468-0009.00125
Unstructured Citation
Mannini A., Intille S.S., Rosenberger M., Sabatini
Unstructured Citation
A.M., Haskell W. (2013). Activity recognition using a single accelerometer placed at the wrist or ankle. Medicine and Science
in Sports and Exercise, 45 (11): 2193-2203.
https://doi.org/10.1249/MSS.0b013e31829736d6
Unstructured Citation
Maurer U., Rowe A., Smailagic A., Siewiorek D. (2006). Location and activity recognition using eWatch: a wearable sensor platform,
ambient intelligence in everyday life. In: Cai Y., Abascal J. (a cura di). Ambient Intelligence in Everyday Life. Berlin:
Springer.
https://doi.org/10.1007/11825890_4
Unstructured Citation
Mehner S., Klauck R., Koenig H. (2013). Location-independent fall detection with smartphone. In: AA.VV. Proceedings of the
sixth International Conference on PErvasive Technologies Related to Assistive Environments. New York: ACM.
https://doi.org/10.1145/2504335.2504346
Unstructured Citation
Montalto F., Bianchi V., De Munari I., Ciampolini P. (2014). A Wearable Multi-sensors Device for AAL Environment. In: Longhi
S., Siciliano P., Ger mani M., Monteriù A. (a cura di). Ambient Assisted Living. Italian Forum 2013. Switzerland: Springer
International Publishing.
https://doi.org/10.1007/978-3-319-01119-6_12
Unstructured Citation
Mozer M.C. (2004). Lessons from an adaptive home. In: Cook D.J., Das S.K. (a cura di). Smart Environments: Technology, Protocols,
and Applications. Hoboken, New Jersey: Wiley.
https://doi.org/10.1002/047168659X.ch12
Unstructured Citation
Okeyo G., Liming C., Hui W. (2014). Combining ontological and temporal formalisms for composite activity modelling and recognition
in smart homes. Future Generation Computer Systems, 39: 29-43.
https://doi.org/10.1016/j.future.2014.02.014
Unstructured Citation
Peter C., Kreiner A., Schröter M., Bieber G., Waterworth J. (2012). The AGNES system for ambient social interaction. In: AA.VV.
Proceedings of the fifth International Conference on PErvasive Technologies Related to Assistive Environments. New York: ACM.
Phillips Research (2007). Other perspective on ambient intelligence.
https://doi.org/10.1145/2413097.2413151
Unstructured Citation
Portet F., Vacher M., Golanski C., Roux C., Meillon B. (2013). Design and evaluation of a smart home voice interface for the
elderly: acceptability and objection aspects. Personal and Ubiquitous Computing, 17 (1): 127-144.
https://doi.org/10.1007/s00779-011-0470-5
Unstructured Citation
Rashidi P., Cook D.J (2013). COM: A method for mining and monitoring human activity patterns in home-based health monitoring
systems. ACM Transactions on Intelligent Systems and Technology, 4(4): 64.
https://doi.org/10.1145/2508037.2508045
Unstructured Citation
Ring L., Shi L., Totzke K., Bickmore T. (2014). Social support agents for older adults: longitudinal affective computing in
the home. Journal of Multimodal User Interfaces, pp. 1-10.
https://doi.org/10.1007/s12193-014-0157-0
Unstructured Citation
Santarelli P. (2013). Sistema di sensori ambientali finalizzati al tele-monitoraggio dell’utente anziano, integrati all’interno dell’ambiente domestico in modo da rilevare la caduta a partire dall’analisi dell’attività motoria. Tesi di Laurea, Politecnico di Milano.
Unstructured Citation
Timmins M.W., McCann J. (2015). Overview of the design requirements of the active ageing. In: McCann J., Bryson D. (a cura
di). Textile-Led Design for the Active Ageing Population, Cambridge: Woodhead Publishing.
https://doi.org/10.1016/B978-0-85709-538-1.00012-2
Unstructured Citation
Tsai T.-Y., You K.-M., Ma Y.-C., Chao Y.-P. (2014). CGU Smart Clothes Platform – Development of a Gateway Device and Real-time
Mobile Display. Biomedical and Health Informatics (BHI), 2014 IEEE-EMBS International Conference on 1-4 June 2014.
https://doi.org/10.1109/BHI.2014.6864293
Unstructured Citation
Valladares S.M., Fernández-Iglesias M.J., Rivas C., Gómez M., Anido L.E. (2013). An Adaptive System for the Smart Home. In: Zaharim A., Shang Y., Jimenez Serrano E., Alharbi S., Prepelita V. (a cura di). Recent Advances in Electrical and Computer Engineering. WSEAS Press. Vidal G.M., Geerts M., Feki M.A. (2013). The Role of Affordances and Interaction Bits in the
Unstructured Citation
Design of a New Tangible Programming Interface: A Preliminary Result. Bell Labs Technical Journal, 17(4): 157-174.
Unstructured Citation
Wang J.-C., Lin C.-H., Siahaan E., Chen B.-W.,
Unstructured Citation
Chuang H.-L. (2014). Mixed sound event verification on wireless sensor network for home automation. Industrial Informatics
IEEE Transactions, 10 (1): 803-812.
https://doi.org/10.1109/TII.2013.2262283
Unstructured Citation
Youngblood G.M. (2005). Automating inhabitant interactions in home and workplace environments through data-driven generation of hierarchical partially-observable Markov decision processes. Ph.D. Thesis, University of Texas at Arlington.