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E Peres, MA Fernandes, R Morais, CR Cunha, JA López, SR Matos, P Ferreira, M Reis (2011)
An autonomous intelligent gateway infrastructure for in-field processing in precision viticultureComputers and Electronics in Agriculture, 78
M Mafuta, M Zennaro, A Bagula, G Ault, H Gombachika, T Chadza (2013)
Successful deployment of a wireless sensor network for precision agriculture in MalawiInternational Journal of Distributed Sensor Networks, 2013
Z Can, M Demirbas (2013)
A survey on in-network querying and tracking services for wireless sensor networksAd Hoc Networks, 11
P Vicaire, T He, Q Cao, T Yan, G Zhou, L Gu, L Luo, R Stoleru, JA Stankovic, TF Abdelzaher (2009)
Achieving long-term surveillance in vigilnetACM Transactions on Sensor Networks (TOSN), 5
C Watras, M Morrow, K Morrison, S Scannell, S Yaziciaglu, J Read, Y-H Hu, P Hanson, T Kratz (2014)
Evaluation of wireless sensor networks (WSNs) for remote wetland monitoring: design and initial resultsEnvironmental Monitoring and Assessment, 186
SE Díaz, JC Pérez, AC Mateos, M-C Marinescu, BB Guerra (2011)
A novel methodology for the monitoring of the agricultural production process based on wireless sensor networksComputers and Electronics in Agriculture, 76
MA Fernandes, SG Matos, E Peres, CR Cunha, JA López, P Ferreira, M Reis, R Morais (2013)
A framework for wireless sensor networks management for precision viticulture and agriculture based on IEEE 1451 standardComputers and Electronics in Agriculture, 95
A Rathnayaka, VM Potdar (2013)
Wireless sensor network transport protocol: A critical reviewJournal of Network and Computer Applications, 36
JA Stankovic (2008)
When sensor and actuator networks cover the worldETRI Journal, 30
MH Anisi, AH Abdullah, SA Razak (2013)
Energy-efficient and reliable data delivery in wireless sensor networksWireless Networks, 19
Y-D Kim, Y-M Yang, W-S Kang, D-K Kim (2011)
On the design of beacon based wireless sensor network for agricultural emergency monitoring systemsComputer Standards & Interfaces, 36
M Nesa Sudha, M Valarmathi, AS Babu (2011)
Energy efficient data transmission in automatic irrigation system using wireless sensor networksComputers and Electronics in Agriculture, 78
M Zhang, M Li, W Wang, C Liu, H Gao (2012)
Temporal and spatial variability of soil moisture based on WSNMathematical and Computer Modelling, 58
RW Coates, MJ Delwiche, A Broad, M Holler (2013)
Wireless sensor network with irrigation valve controlComputers and Electronics in Agriculture, 96
G Anastasi, M Conti, M Francesco, A Passarella (2009)
Energy conservation in wireless sensor networks: A surveyAd Hoc Networks, 7
G Owojaiye, Y Sun (2012)
Focal design issues affecting the deployment of wireless sensor networks for pipeline monitoringAd Hoc Networks, 11
E Theodoridis, I Chatzigiannakis, S Dulman (2012)
Post-processing in wireless sensor networks: Benchmarking sensor trace files for in-network data aggregationJournal of Network and Computer Applications, 35
N Wang, N Zhang, M Wang (2006)
Wireless sensors in agriculture and food industry—recent development and future perspectiveComputers and Electronics in Agriculture, 50
L Hoesel, A TüYsüZ Erman, A Dilo, PJ Havinga (2013)
Geo-casting of queries combined with coverage area reporting for wireless sensor networksAd Hoc Networks, 11
Z Xu, B Lou, G Shao (2012)
An intelligent irrigation system for greenhouse jonquil based on ZigBee wireless sensor networks. Internet of things.
R-B Zhang, J-J Guo, L Zhang, Y-C Zhang, L-H Wang, Q Wang (2011)
A calibration method of detecting soil water content based on the information-sharing in wireless sensor networkComputers and Electronics in Agriculture, 76
P Levis, S Madden, J Polastre, R Szewczyk, K Whitehouse, A Woo, D Gay, J Hill, M Welsh, E Brewer, D Culler (2005)
Ambient intelligence
NR Peplinski, FT Ulaby, MC Dobson (1995)
Dielectric properties of soils in the 0.3–1.3 GHz rangeIEEE Transactions on Geoscience and Remote Sensing, 33
A-J Garcia-Sanchez, F Garcia-Sanchez, J Garcia-Haro (2011)
Wireless sensor network deployment for integrating video-surveillance and data-monitoring in precision agriculture over distributed cropsComputers and Electronics in Agriculture, 75
L Ruiz-Garcia, L Lunadei, P Barreiro, I Robla (2009)
A review of wireless sensor technologies and applications in agriculture and food industry: State of the art and current trendsSensors, 9
DM Pozar (2000)
Microwave and RF design of wireless systems
MH Anisi, AH Abdullah, Y Coulibaly, SA Razak (2013)
EDR: Efficient data routing in wireless sensor networksInternational Journal of Ad Hoc and Ubiquitous Computing, 12
X Yu, P Wu, W Han, Z Zhang (2013)
A survey on wireless sensor network infrastructure for agricultureComputer Standards & Interfaces, 35
G Vellidis, M Tucker, C Perry, C Kvien, C Bednarz (2008)
A real-time wireless smart sensor array for scheduling irrigationComputers and Electronics in Agriculture, 61
X Dong, MC Vuran, S Irmak (2013)
Autonomous precision agriculture through integration of wireless underground sensor networks with center pivot irrigation systemsAd Hoc Networks, 11
B Majone, F Viani, E Filippi, A Bellin, A Massa, G Toller, F Robol, M Salucci (2013)
Wireless sensor network deployment for monitoring soil moisture dynamics at the field scaleProcedia Environmental Sciences, 19
L Gao, M Zhang, G Chen (2013)
An Intelligent irrigation system based on wireless sensor network and fuzzy controlJournal of Networks, 8
P Baronti, P Pillai, VW Chook, S Chessa, A Gotta, YF Hu (2007)
Wireless sensor networks: A survey on the state of the art and the 802.15.4 and ZigBee standardsComputer Communications, 30
Precision agriculture (PA) is the use of information and communication technology together with best agricultural practices for farm management. PA requires the acquisition, transmission and processing of large amounts of data from farm fields. A wireless sensor network (WSN) is a system for monitoring agriculture fields. Several researchers have used WSNs to collect the required data from the regions of interest for their intended usages in various applications. In a WSN, the energy consumption of the sensor nodes is the main issue, due to its direct impact on the lifetime of the network. Many approaches have been proposed to address this issue using different power sources and types of nodes. Specifically, in PA, because of the extended time period that is required to monitor fields, using an appropriate WSN approach is important. There is a need for a comprehensive review of WSN approaches for PA. The aim of this paper is to classify and describe the state-of-the-art of WSNs and analyze their energy consumption based on their power sources. WSN approaches in PA are categorized and discussed according to their features.
Precision Agriculture – Springer Journals
Published: Sep 11, 2014
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