2019
Trilles-Oliver, Sergio; González-Pérez, Alberto; Huerta-Guijarro, Joaquín
Adapting models to warn fungal diseases in vineyards using in-field Internet of Things (IoT) nodes Journal Article
In: Sustainability , vol. 11, pp. 416, 2019.
BibTeX | Tags: Internet of things, senviro
@article{Trilles-Oliver2019,
title = {Adapting models to warn fungal diseases in vineyards using in-field Internet of Things (IoT) nodes},
author = {Sergio Trilles-Oliver and Alberto González-Pérez and Joaquín Huerta-Guijarro },
year = {2019},
date = {2019-02-01},
journal = {Sustainability },
volume = {11},
pages = {416},
keywords = {Internet of things, senviro},
pubstate = {published},
tppubtype = {article}
}
2018
Trilles-Oliver, Sergio; González-Pérez, Alberto; Huerta-Guijarro, Joaquín
A Comprehensive IoT Node Proposal Using Open Hardware. A Smart Farming Use Case to Monitor Vineyards Journal Article
In: Electronics, vol. 7, no. 12, pp. 419, 2018, (IF: ).
Abstract | Links | BibTeX | Tags: Agriculture, crop monitoring, Internet of things, senviro
@article{Trilles-Oliver2018,
title = {A Comprehensive IoT Node Proposal Using Open Hardware. A Smart Farming Use Case to Monitor Vineyards},
author = {Sergio Trilles-Oliver and Alberto González-Pérez and Joaquín Huerta-Guijarro},
doi = {10.3390/electronics7120419},
year = {2018},
date = {2018-03-28},
journal = {Electronics},
volume = {7},
number = {12},
pages = {419},
abstract = {The last decade has witnessed a significant reduction in prices and an increased performance of electronic components, coupled with the influence of the shift towards the generation of open resources, both in terms of knowledge (open access), programs (open-source software), and components (open hardware). This situation has produced different effects in today’s society, among which is the empowerment of citizens, called makers, who are themselves able to generate citizen science or build assembly developments. Situated in the context described above, the current study follows a Do-It-Yourself (DIY) approach. In this way, it attempts to define a conceptual design of an Internet of Things (IoT) node, which is reproducible at both physical and behavioral levels, to build IoT nodes which can cover any scenario. To test this conceptual design, this study proposes a sensorization node to monitor meteorological phenomena. The node is called SEnviro (node) and features different improvements such as: the possibility of remote updates using Over-the-Air (OTA) updates; autonomy, using 3G connectivity, a solar panel, and applied energy strategies to prolong its
life; and replicability, because it is made up of open hardware and other elements such as 3D-printed pieces. The node is validated in the field of smart agriculture, with the aim of monitoring different meteorological phenomena, which will be used as input to disease detection models to detect possible diseases within vineyards.},
note = {IF: },
keywords = {Agriculture, crop monitoring, Internet of things, senviro},
pubstate = {published},
tppubtype = {article}
}
The last decade has witnessed a significant reduction in prices and an increased performance of electronic components, coupled with the influence of the shift towards the generation of open resources, both in terms of knowledge (open access), programs (open-source software), and components (open hardware). This situation has produced different effects in today’s society, among which is the empowerment of citizens, called makers, who are themselves able to generate citizen science or build assembly developments. Situated in the context described above, the current study follows a Do-It-Yourself (DIY) approach. In this way, it attempts to define a conceptual design of an Internet of Things (IoT) node, which is reproducible at both physical and behavioral levels, to build IoT nodes which can cover any scenario. To test this conceptual design, this study proposes a sensorization node to monitor meteorological phenomena. The node is called SEnviro (node) and features different improvements such as: the possibility of remote updates using Over-the-Air (OTA) updates; autonomy, using 3G connectivity, a solar panel, and applied energy strategies to prolong its
life; and replicability, because it is made up of open hardware and other elements such as 3D-printed pieces. The node is validated in the field of smart agriculture, with the aim of monitoring different meteorological phenomena, which will be used as input to disease detection models to detect possible diseases within vineyards.
life; and replicability, because it is made up of open hardware and other elements such as 3D-printed pieces. The node is validated in the field of smart agriculture, with the aim of monitoring different meteorological phenomena, which will be used as input to disease detection models to detect possible diseases within vineyards.
Trilles-Oliver, Sergio; González-Pérez, Alberto; Soria, Francisco Javier Zarazaga; Huerta-Guijarro, Joaquín
SEnviro for Agriculture: An IoT full stack for monitoring vineyards – Early steps Proceedings Article
In: Mansourian, A., Pilesjö, P., Harrie, L., & von Lammeren, R. (Eds.), 2018. Geospatial Technologies for All: short papers, posters and poster abstracts of the 21th AGILE Conference on Geographic Information Science. Lund University 12-15 June 2018, Lund, Sweden. , AGILE, Lund , 2018, ISBN: 978-3-319-78208-9.
Links | BibTeX | Tags: Agriculture, Conference, senviro
@inproceedings{,
title = {SEnviro for Agriculture: An IoT full stack for monitoring vineyards – Early steps},
author = {Sergio Trilles-Oliver and Alberto González-Pérez and Francisco Javier Zarazaga Soria and Joaquín Huerta-Guijarro},
url = {https://agile-online.org/conference_paper/cds/agile_2018/posters/58%20agileSEnviroPoster58.pdf},
isbn = {978-3-319-78208-9},
year = {2018},
date = {2018-01-01},
booktitle = {Mansourian, A., Pilesjö, P., Harrie, L., & von Lammeren, R. (Eds.), 2018. Geospatial Technologies for All: short papers, posters and poster abstracts of the 21th AGILE Conference on Geographic Information Science. Lund University 12-15 June 2018, Lund, Sweden. },
publisher = {AGILE},
address = {Lund },
keywords = {Agriculture, Conference, senviro},
pubstate = {published},
tppubtype = {inproceedings}
}
2017
Trilles-Oliver, Sergio; Calia, Andrea; Belmonte, Óscar; Torres-Sospedra, Joaquín; Montoliu, Raul; and, Joaquín Huerta-Guijarro
Deployment of an open sensorized platform in a smart city context Journal Article
In: Future Generation Computer Systems, vol. 76, pp. 221-233, 2017, ISSN: 0167-739X.
Abstract | Links | BibTeX | Tags: environmental monitoring, GEOEvent, GIScience, Internet of things, Open-hardware, senviro, Smart Cities
@article{Trilles2017,
title = {Deployment of an open sensorized platform in a smart city context },
author = {Sergio Trilles-Oliver and Andrea Calia and Óscar Belmonte and Joaquín Torres-Sospedra and Raul Montoliu and Joaquín Huerta-Guijarro and
},
doi = {http://dx.doi.org/10.1016/j.future.2016.11.005},
issn = {0167-739X},
year = {2017},
date = {2017-02-28},
journal = {Future Generation Computer Systems},
volume = {76},
pages = {221-233},
abstract = {The race to achieve smart cities is producing a continuous effort to adapt new developments and knowledge, for administrations and citizens. Information and Communications Technology are called on to be one of the key players to get these cities to use smart devices and sensors (Internet of Things) to know at every moment what is happening within the city, in order to make decisions that will improve the management of resources. The proliferation of these “smart things” is producing significant deployment of networks in the city context. Most of these devices are proprietary solutions, which do not offer free access to the data they provide. Therefore, this prevents the interoperability and compatibility of these solutions in the current smart city developments.
This paper presents how to embed an open sensorized platform for both hardware and software in the context of a smart city, more specifically in a university campus. For this integration, GIScience comes into play, where it offers different open standards that allow full control over “smart things” as an agile and interoperable way to achieve this. To test our system, we have deployed a network of different sensorized platforms inside the university campus, in order to monitor environmental phenomena.},
keywords = {environmental monitoring, GEOEvent, GIScience, Internet of things, Open-hardware, senviro, Smart Cities},
pubstate = {published},
tppubtype = {article}
}
The race to achieve smart cities is producing a continuous effort to adapt new developments and knowledge, for administrations and citizens. Information and Communications Technology are called on to be one of the key players to get these cities to use smart devices and sensors (Internet of Things) to know at every moment what is happening within the city, in order to make decisions that will improve the management of resources. The proliferation of these “smart things” is producing significant deployment of networks in the city context. Most of these devices are proprietary solutions, which do not offer free access to the data they provide. Therefore, this prevents the interoperability and compatibility of these solutions in the current smart city developments.
This paper presents how to embed an open sensorized platform for both hardware and software in the context of a smart city, more specifically in a university campus. For this integration, GIScience comes into play, where it offers different open standards that allow full control over “smart things” as an agile and interoperable way to achieve this. To test our system, we have deployed a network of different sensorized platforms inside the university campus, in order to monitor environmental phenomena.
This paper presents how to embed an open sensorized platform for both hardware and software in the context of a smart city, more specifically in a university campus. For this integration, GIScience comes into play, where it offers different open standards that allow full control over “smart things” as an agile and interoperable way to achieve this. To test our system, we have deployed a network of different sensorized platforms inside the university campus, in order to monitor environmental phenomena.
2015
Trilles-Oliver, Sergio; Luján, Alejandro; Belmonte-Fernández, Óscar; Montoliu-Colás, Raúl; Torres-Sospedra, Joaquín; Huerta-Guijarro, Joaquín
SEnviro: A sensorized platform proposal using open hardware and open standards Journal Article
In: Sensors, vol. 15, no. 3, pp. 5555–5582, 2015, ISSN: 14248220, (IF: 2.033, Q1).
Abstract | Links | BibTeX | Tags: Internet of things, Interoperability, Open hardware, Sensor networks, Sensor networks, senviro, Web of things
@article{TrillesOliver2015a,
title = {SEnviro: A sensorized platform proposal using open hardware and open standards},
author = {Sergio Trilles-Oliver and Alejandro Luján and Óscar Belmonte-Fernández and Raúl Montoliu-Colás and Joaquín Torres-Sospedra and Joaquín Huerta-Guijarro},
url = {http://hdl.handle.net/10234/150305},
doi = {10.3390/s150305555},
issn = {14248220},
year = {2015},
date = {2015-01-01},
journal = {Sensors},
volume = {15},
number = {3},
pages = {5555--5582},
abstract = {The need for constant monitoring of environmental conditions has produced an increase in the development of wireless sensor networks (WSN). The drive towards smart cities has produced the need for smart sensors to be able to monitor what is happening in our cities. This, combined with the decrease in hardware component prices and the increase in the popularity of open hardware, has favored the deployment of sensor networks based on open hardware. The new trends in Internet Protocol (IP) communication between sensor nodes allow sensor access via the Internet, turning them into smart objects (Internet of Things and Web of Things). Currently, WSNs provide data in different formats. There is a lack of communication protocol standardization, which turns into interoperability issues when connecting different sensor networks or even when connecting different sensor nodes within the same network. This work presents a sensorized platform proposal that adheres to the principles of the Internet of Things and the Web of Things. Wireless sensor nodes were built using open hardware solutions, and communications rely on the HTTP/IP Internet protocols. The Open Geospatial Consortium (OGC) SensorThings API candidate standard was used as a neutral format to avoid interoperability issues. An environmental WSN developed following the proposed architecture was built as a proof of concept. Details on how to build each node and a study regarding energy concerns are presented.12pt},
note = {IF: 2.033, Q1},
keywords = {Internet of things, Interoperability, Open hardware, Sensor networks, Sensor networks, senviro, Web of things},
pubstate = {published},
tppubtype = {article}
}
The need for constant monitoring of environmental conditions has produced an increase in the development of wireless sensor networks (WSN). The drive towards smart cities has produced the need for smart sensors to be able to monitor what is happening in our cities. This, combined with the decrease in hardware component prices and the increase in the popularity of open hardware, has favored the deployment of sensor networks based on open hardware. The new trends in Internet Protocol (IP) communication between sensor nodes allow sensor access via the Internet, turning them into smart objects (Internet of Things and Web of Things). Currently, WSNs provide data in different formats. There is a lack of communication protocol standardization, which turns into interoperability issues when connecting different sensor networks or even when connecting different sensor nodes within the same network. This work presents a sensorized platform proposal that adheres to the principles of the Internet of Things and the Web of Things. Wireless sensor nodes were built using open hardware solutions, and communications rely on the HTTP/IP Internet protocols. The Open Geospatial Consortium (OGC) SensorThings API candidate standard was used as a neutral format to avoid interoperability issues. An environmental WSN developed following the proposed architecture was built as a proof of concept. Details on how to build each node and a study regarding energy concerns are presented.12pt