A novel ubiquitous system to monitor medicinal cold chains in transportation

Cold chain is a term related to the equipment and processes used to keep the correct temperature, in which the products, such as food, vaccines, blood, tissues, amongst others, should be stable to be preserved. Any change in temperature can cause a damage in the specific properties in products. Beca...

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Tipo de recurso:
Fecha de publicación:
2017
Institución:
Universidad de Medellín
Repositorio:
Repositorio UDEM
Idioma:
eng
OAI Identifier:
oai:repository.udem.edu.co:11407/4357
Acceso en línea:
http://hdl.handle.net/11407/4357
Palabra clave:
Cold chain
Single board computers
Temperature
Ubiquitous Commuting
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http://purl.org/coar/access_right/c_16ec
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network_acronym_str REPOUDEM2
network_name_str Repositorio UDEM
repository_id_str
dc.title.spa.fl_str_mv A novel ubiquitous system to monitor medicinal cold chains in transportation
title A novel ubiquitous system to monitor medicinal cold chains in transportation
spellingShingle A novel ubiquitous system to monitor medicinal cold chains in transportation
Cold chain
Single board computers
Temperature
Ubiquitous Commuting
title_short A novel ubiquitous system to monitor medicinal cold chains in transportation
title_full A novel ubiquitous system to monitor medicinal cold chains in transportation
title_fullStr A novel ubiquitous system to monitor medicinal cold chains in transportation
title_full_unstemmed A novel ubiquitous system to monitor medicinal cold chains in transportation
title_sort A novel ubiquitous system to monitor medicinal cold chains in transportation
dc.contributor.affiliation.spa.fl_str_mv Palacio, M.G., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
Palacio, L.G., Computer Science Engineering Department, University of Medellín Medellín, Colombia
Montealegre, J.J.Q., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
Pabon, H.J.O., Computer Science Engineering Department, University of Medellín Medellín, Colombia
Del Risco, M.A.L., Energy Engineering Department, University of Medellín Medellín, Colombia
Roldan, D., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
Salgarriaga, S., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
Vasquez, P., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
Hernandez, S., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
Martinez, C., Telecommunications Enginnering Department, University of Medellín Medellín, Colombia
dc.subject.keyword.eng.fl_str_mv Cold chain
Single board computers
Temperature
Ubiquitous Commuting
topic Cold chain
Single board computers
Temperature
Ubiquitous Commuting
description Cold chain is a term related to the equipment and processes used to keep the correct temperature, in which the products, such as food, vaccines, blood, tissues, amongst others, should be stable to be preserved. Any change in temperature can cause a damage in the specific properties in products. Because of that, it is mandatory to constantly monitor temperature and log it to offer traceability. Furthermore, if products must be transported, the position coordinates should be taken into account as well, due to the possibility of making mistakes in logistics personnel, taking non-optimal routes to arrive to the destination, and increasing transportation time. Thus, logistics managers need tools to measure, save and analyze temperature and position in real time to make the most optimal decisions. The implementation of systems meeting Ubiquitous Computing can fulfill the challenge, because the generated information is available to be read, modified and stored everywhere and every time. Besides, messengers can be warned about anomalies regarding change of temperatures or coordinates, adding context awareness to the system. This work aims to show a novel architecture to monitor cold chains by using Ubiquitous Computing paradigm, by means of Single Board Computers. The system includes instrumentation, embedded processing with Single Board Computers, real time databases, Human Computer Interfaces, remote management and support to deploy a complete solution. By using this system, companies ensure traceability and integrity of data in cold chains. A study case is presented to validate the approach. © 2017 AISTI.
publishDate 2017
dc.date.accessioned.none.fl_str_mv 2017-12-19T19:36:50Z
dc.date.available.none.fl_str_mv 2017-12-19T19:36:50Z
dc.date.created.none.fl_str_mv 2017
dc.type.eng.fl_str_mv Conference Paper
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dc.identifier.isbn.none.fl_str_mv 9789899843479
dc.identifier.issn.none.fl_str_mv 21660727
dc.identifier.uri.none.fl_str_mv http://hdl.handle.net/11407/4357
dc.identifier.doi.none.fl_str_mv 10.23919/CISTI.2017.7975685
dc.identifier.reponame.spa.fl_str_mv reponame:Repositorio Institucional Universidad de Medellín
dc.identifier.instname.spa.fl_str_mv instname:Universidad de Medellín
identifier_str_mv 9789899843479
21660727
10.23919/CISTI.2017.7975685
reponame:Repositorio Institucional Universidad de Medellín
instname:Universidad de Medellín
url http://hdl.handle.net/11407/4357
dc.language.iso.none.fl_str_mv eng
language eng
dc.relation.isversionof.spa.fl_str_mv https://www.scopus.com/inward/record.uri?eid=2-s2.0-85027063049&doi=10.23919%2fCISTI.2017.7975685&partnerID=40&md5=d5878eeaa78567a8f73f436ccb2b9c5b
dc.relation.ispartofes.spa.fl_str_mv Iberian Conference on Information Systems and Technologies, CISTI
dc.relation.references.spa.fl_str_mv Weiser, M., Hot topics-ubiquitous computing (1993) Computer, 26, pp. 71-72
Giacomantone, J., Abásolo Guerrero, M.J., Bria, O.N., Cristina, F., Dapoto, S.H., Artola, V., Lorenti, L., Más Sansó, R., Sistemas de visión automática y reconocimiento de patrones interfaces avanzadas, realidad virtual y aumentada (2012) XIV Workshop de Investigadores en Ciencias de la Computación
Zhang, L., (2007) Cold Chain Management
Ruiz García, L., Lunadei, L., (2010) Monitoring Cold Chain Logistics by Means of RFID: In-Tech
Keja, K., Chan, C., Hayden, G., Henderson, R.H., Expanded programme on immunization (1987) World Health Statistics Quarterly. Rapport Trimestriel de Statistiques Sanitaires Mondiales, 41, pp. 59-63
Kartoglu, U., Milstien, J., Tools and approaches to ensure quality of vaccines throughout the cold chain (2014) Expert Review of Vaccines, 13, pp. 843-854
Hess, J.R., Measures of stored red blood cell quality (2014) Vox Sanguinis, 107, pp. 1-9
Bishara, R.H., Cold chain management-an essential component of the global pharmaceutical supply chain (2006) American Pharmaceutical Review, 9, pp. 105-109
Organization, W.H., (2006) Good Distribution Practices (GDP) for Pharmaceutical Products, 2. , working document QAS/04. 068/Rev
Reynolds, D.W., Facchine, K.L., Mullaney, J.F., Alsante, K.M., Hatajik, T.D., Motto, M.G., Conducting forced degradation studies (2002) Pharmaceutical Technology, pp. 48-56
(1998) Guidance for Industry: Stability Testing of Drug Substances and Drug Product, Draft Guidance, , Food and D. Administration, FDA: Washington, DC
Okeke, C., Bailey, L., Medwick, T., Grady, L., Temperature fluctuations during mail order shipment of pharmaceutical articles using mean kinetic temperature approach (1997) Pharmacopeial Forum, pp. 4155-4182
(2005) Guidelines for Temperature Control of Drug Products during Storage and Transportation, , H. Canada, Health Canada, CanadaOctober
(1994) Guidelines on Good Distribution Practice of Medicinal Product for Human Use, , E. Union, European Union
Ruiz-Garcia, L., Lunadei, L., Barreiro, P., Robla, I., A review of wireless sensor technologies and applications in agriculture and food industry: State of the art and current trends (2009) Sensors, 9, pp. 4728-4750
Yeoh, C.-M., Chai, B.-L., Lim, H., Kwon, T.-H., Yi, K.-O., Kim, T.-H., Lee, C.-S., Kwark, G.-H., Ubiquitous containerized cargo monitoring system development based on wireless sensor network technology (2011) International Journal of Computers Communications & Control, 6, pp. 779-793
Martin, G., Zurawski, R., Trends in embedded systems (2006) ABB Rev, 2, pp. 9-13
Puccinelli, D., Haenggi, M., Wireless sensor networks: Applications and challenges of ubiquitous sensing (2005) Circuits and Systems Magazine, IEEE, 5, pp. 19-31
Desai, V.P., Bavarva, A., Image processing method for embedded optical peanut sorting (2016) International Journal of Image, Graphics and Signal Processing, 8, p. 20
Molano, J.I.R., Medina, V.H., Sánchez, J.F.M., Industrial internet of things: An architecture prototype for monitoring in confined spaces using a raspberry pi (2016) International Conference on Data Mining and Big Data, pp. 521-528
Ferdoush, S., Li, X., Wireless sensor network system design using Raspberry Pi and Arduino for environmental monitoring applications (2014) Procedia Computer Science, 34, pp. 103-110
Prasad, S., Mahalakshmi, P., Sunder, A.J.C., Swathi, R., Smart surveillance monitoring system using raspberry PI and PIR sensor (2014) Int. J. Comput. Sci. Inf. Technol, 5, pp. 7107-7109
Smith, N., Caldwell, H., (2015) Ubiquitous Computing Devices in the Training of Teacher-trainers
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rights_invalid_str_mv http://purl.org/coar/access_right/c_16ec
dc.publisher.spa.fl_str_mv IEEE Computer Society
dc.publisher.faculty.spa.fl_str_mv Facultad de Ingenierías
dc.source.spa.fl_str_mv Scopus
institution Universidad de Medellín
repository.name.fl_str_mv Repositorio Institucional Universidad de Medellin
repository.mail.fl_str_mv repositorio@udem.edu.co
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spelling 2017-12-19T19:36:50Z2017-12-19T19:36:50Z2017978989984347921660727http://hdl.handle.net/11407/435710.23919/CISTI.2017.7975685reponame:Repositorio Institucional Universidad de Medellíninstname:Universidad de MedellínCold chain is a term related to the equipment and processes used to keep the correct temperature, in which the products, such as food, vaccines, blood, tissues, amongst others, should be stable to be preserved. Any change in temperature can cause a damage in the specific properties in products. Because of that, it is mandatory to constantly monitor temperature and log it to offer traceability. Furthermore, if products must be transported, the position coordinates should be taken into account as well, due to the possibility of making mistakes in logistics personnel, taking non-optimal routes to arrive to the destination, and increasing transportation time. Thus, logistics managers need tools to measure, save and analyze temperature and position in real time to make the most optimal decisions. The implementation of systems meeting Ubiquitous Computing can fulfill the challenge, because the generated information is available to be read, modified and stored everywhere and every time. Besides, messengers can be warned about anomalies regarding change of temperatures or coordinates, adding context awareness to the system. This work aims to show a novel architecture to monitor cold chains by using Ubiquitous Computing paradigm, by means of Single Board Computers. The system includes instrumentation, embedded processing with Single Board Computers, real time databases, Human Computer Interfaces, remote management and support to deploy a complete solution. By using this system, companies ensure traceability and integrity of data in cold chains. A study case is presented to validate the approach. © 2017 AISTI.engIEEE Computer SocietyFacultad de Ingenieríashttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85027063049&doi=10.23919%2fCISTI.2017.7975685&partnerID=40&md5=d5878eeaa78567a8f73f436ccb2b9c5bIberian Conference on Information Systems and Technologies, CISTIWeiser, M., Hot topics-ubiquitous computing (1993) Computer, 26, pp. 71-72Giacomantone, J., Abásolo Guerrero, M.J., Bria, O.N., Cristina, F., Dapoto, S.H., Artola, V., Lorenti, L., Más Sansó, R., Sistemas de visión automática y reconocimiento de patrones interfaces avanzadas, realidad virtual y aumentada (2012) XIV Workshop de Investigadores en Ciencias de la ComputaciónZhang, L., (2007) Cold Chain ManagementRuiz García, L., Lunadei, L., (2010) Monitoring Cold Chain Logistics by Means of RFID: In-TechKeja, K., Chan, C., Hayden, G., Henderson, R.H., Expanded programme on immunization (1987) World Health Statistics Quarterly. Rapport Trimestriel de Statistiques Sanitaires Mondiales, 41, pp. 59-63Kartoglu, U., Milstien, J., Tools and approaches to ensure quality of vaccines throughout the cold chain (2014) Expert Review of Vaccines, 13, pp. 843-854Hess, J.R., Measures of stored red blood cell quality (2014) Vox Sanguinis, 107, pp. 1-9Bishara, R.H., Cold chain management-an essential component of the global pharmaceutical supply chain (2006) American Pharmaceutical Review, 9, pp. 105-109Organization, W.H., (2006) Good Distribution Practices (GDP) for Pharmaceutical Products, 2. , working document QAS/04. 068/RevReynolds, D.W., Facchine, K.L., Mullaney, J.F., Alsante, K.M., Hatajik, T.D., Motto, M.G., Conducting forced degradation studies (2002) Pharmaceutical Technology, pp. 48-56(1998) Guidance for Industry: Stability Testing of Drug Substances and Drug Product, Draft Guidance, , Food and D. Administration, FDA: Washington, DCOkeke, C., Bailey, L., Medwick, T., Grady, L., Temperature fluctuations during mail order shipment of pharmaceutical articles using mean kinetic temperature approach (1997) Pharmacopeial Forum, pp. 4155-4182(2005) Guidelines for Temperature Control of Drug Products during Storage and Transportation, , H. Canada, Health Canada, CanadaOctober(1994) Guidelines on Good Distribution Practice of Medicinal Product for Human Use, , E. Union, European UnionRuiz-Garcia, L., Lunadei, L., Barreiro, P., Robla, I., A review of wireless sensor technologies and applications in agriculture and food industry: State of the art and current trends (2009) Sensors, 9, pp. 4728-4750Yeoh, C.-M., Chai, B.-L., Lim, H., Kwon, T.-H., Yi, K.-O., Kim, T.-H., Lee, C.-S., Kwark, G.-H., Ubiquitous containerized cargo monitoring system development based on wireless sensor network technology (2011) International Journal of Computers Communications & Control, 6, pp. 779-793Martin, G., Zurawski, R., Trends in embedded systems (2006) ABB Rev, 2, pp. 9-13Puccinelli, D., Haenggi, M., Wireless sensor networks: Applications and challenges of ubiquitous sensing (2005) Circuits and Systems Magazine, IEEE, 5, pp. 19-31Desai, V.P., Bavarva, A., Image processing method for embedded optical peanut sorting (2016) International Journal of Image, Graphics and Signal Processing, 8, p. 20Molano, J.I.R., Medina, V.H., Sánchez, J.F.M., Industrial internet of things: An architecture prototype for monitoring in confined spaces using a raspberry pi (2016) International Conference on Data Mining and Big Data, pp. 521-528Ferdoush, S., Li, X., Wireless sensor network system design using Raspberry Pi and Arduino for environmental monitoring applications (2014) Procedia Computer Science, 34, pp. 103-110Prasad, S., Mahalakshmi, P., Sunder, A.J.C., Swathi, R., Smart surveillance monitoring system using raspberry PI and PIR sensor (2014) Int. J. Comput. Sci. Inf. Technol, 5, pp. 7107-7109Smith, N., Caldwell, H., (2015) Ubiquitous Computing Devices in the Training of Teacher-trainersScopusA novel ubiquitous system to monitor medicinal cold chains in transportationConference Paperinfo:eu-repo/semantics/conferenceObjecthttp://purl.org/coar/version/c_970fb48d4fbd8a85http://purl.org/coar/resource_type/c_c94fPalacio, M.G., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaPalacio, L.G., Computer Science Engineering Department, University of Medellín Medellín, ColombiaMontealegre, J.J.Q., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaPabon, H.J.O., Computer Science Engineering Department, University of Medellín Medellín, ColombiaDel Risco, M.A.L., Energy Engineering Department, University of Medellín Medellín, ColombiaRoldan, D., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaSalgarriaga, S., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaVasquez, P., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaHernandez, S., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaMartinez, C., Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaPalacio M.G.Palacio L.G.Montealegre J.J.Q.Pabon H.J.O.Del Risco M.A.L.Roldan D.Salgarriaga S.Vasquez P.Hernandez S.Martinez C.Telecommunications Enginnering Department, University of Medellín Medellín, ColombiaComputer Science Engineering Department, University of Medellín Medellín, ColombiaEnergy Engineering Department, University of Medellín Medellín, ColombiaCold chainSingle board computersTemperatureUbiquitous CommutingCold chain is a term related to the equipment and processes used to keep the correct temperature, in which the products, such as food, vaccines, blood, tissues, amongst others, should be stable to be preserved. Any change in temperature can cause a damage in the specific properties in products. Because of that, it is mandatory to constantly monitor temperature and log it to offer traceability. Furthermore, if products must be transported, the position coordinates should be taken into account as well, due to the possibility of making mistakes in logistics personnel, taking non-optimal routes to arrive to the destination, and increasing transportation time. Thus, logistics managers need tools to measure, save and analyze temperature and position in real time to make the most optimal decisions. The implementation of systems meeting Ubiquitous Computing can fulfill the challenge, because the generated information is available to be read, modified and stored everywhere and every time. Besides, messengers can be warned about anomalies regarding change of temperatures or coordinates, adding context awareness to the system. This work aims to show a novel architecture to monitor cold chains by using Ubiquitous Computing paradigm, by means of Single Board Computers. The system includes instrumentation, embedded processing with Single Board Computers, real time databases, Human Computer Interfaces, remote management and support to deploy a complete solution. By using this system, companies ensure traceability and integrity of data in cold chains. A study case is presented to validate the approach. © 2017 AISTI.http://purl.org/coar/access_right/c_16ec11407/4357oai:repository.udem.edu.co:11407/43572020-05-27 17:32:44.873Repositorio Institucional Universidad de Medellinrepositorio@udem.edu.co

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