Applicability of Wireless Sensor Networks in Precision Agriculture: A Review (original) (raw)

References

1. Yick, J., Mukherjee, B., & Ghosal, D. (2008). Wireless sensor network survey. Computer Networks, 52(12), 2292–2330.
   Article Google Scholar
2. Baronti, P., Pillai, P., Chook, V. W., Chessa, S., Gotta, A., & Hu, Y. F. (2007). Wireless sensor networks: A survey on the state of the art and the and the 802.15.4 ZigBee standards. Computer Communications, 30(7), 1655–1695.
   Article Google Scholar
3. Kutter, T., Tiemann, S., Siebert, R., & Fountas, S. (2011). The role of communication and co-operation in the adoption of precision farming. Precision Agriculture, 12(1), 2–17.
   Article Google Scholar
4. Polo, J., Hornero, G., Duijneveld, C., García, A., & Casas, O. (2015). Design of a low-cost wireless sensor network with UAV mobile node for agricultural applications. Computers and Electronics in Agriculture, 119, 19–32.
   Article Google Scholar
5. Abbasi, A. Z., Islam, N., & Shaikh, Z. A. (2014). A review of wireless sensors and networks’ applications in agriculture. Computer Standards & Interfaces, 36(2), 263–270.
   Article Google Scholar
6. Garcia-Sanchez, A. J., Garcia-Sanchez, F., & Garcia-Haro, J. (2011). Wireless sensor network deployment for integrating video-surveillance and data-monitoring in precision agriculture over distributed crops. Computers and Electronics in Agriculture, 75(2), 288–303.
   Article Google Scholar
7. Zhang, R., Ren, Z., Sun, J., Tang, W., Ning, D., & Qian, Y. (2017). Method for monitoring the cotton plant vigor based on the WSN technology. Computers and Electronics in Agriculture, 133, 68–79.
   Article Google Scholar
8. Sai, Z., Fan, Y., Yuliang, T., Lei, X., & Yifong, Z. (2016). Optimized algorithm of sensor node deployment for intelligent agricultural monitoring. Computers and Electronics in Agriculture, 127, 76–86.
   Article Google Scholar
9. Jiang, J. A., Wang, C. H., Liao, M. S., Zheng, X. Y., Liu, J. H., Chuang, C. L., et al. (2016). A wireless sensor network-based monitoring system with dynamic convergecast tree algorithm for precision cultivation management in orchid greenhouses. Precision Agriculture, 17(6), 766–785.
   Article Google Scholar
10. Kim, Y. D., Yang, Y. M., Kang, W. S., & Kim, D. K. (2014). On the design of beacon based wireless sensor network for agricultural emergency monitoring systems. Computer Standards & Interfaces, 36(2), 288–299.
    Article Google Scholar
11. Bapat, V., Kale, P., Shinde, V., Deshpande, N., & Shaligram, A. (2017). WSN application for crop protection to divert animal intrusions in the agricultural land. Computers and Electronics in Agriculture, 133, 88–96.
    Article Google Scholar
12. Portz, G., Molin, J. P., & Jasper, J. (2012). Active crop sensor to detect variability of nitrogen supply and biomass on sugarcane fields. Precision Agriculture, 13(1), 33–44.
    Article Google Scholar
13. Reiser, D., Paraforos, D. S., Khan, M. T., Griepentrog, H. W., & Vázquez-Arellano, M. (2017). Autonomous field navigation, data acquisition and node location in wireless sensor networks. Precision Agriculture, 18(3), 279–292.
    Article Google Scholar
14. Smiljkovikj, K., & Gavrilovska, L. (2014). SmartWine: Intelligent end-to-end cloud-based monitoring system. Wireless Personal Communications, 78(3), 1777–1788.
    Article Google Scholar
15. Díaz, S. E., Pérez, J. C., Mateos, A. C., Marinescu, M. C., & Guerra, B. B. (2011). A novel methodology for the monitoring of the agricultural production process based on wireless sensor networks. Computers and Electronics in Agriculture, 76(2), 252–265.
    Article Google Scholar
16. Zhu, B., Han, W., Wang, Y., Wang, N., Chen, Y., & Guo, C. (2014). Development and evaluation of a wireless sensor network monitoring system in various agricultural environments. Journal of Microwave Power and Electromagnetic Energy, 48(3), 170–183.
    Article Google Scholar
17. Srbinovska, M., Gavrovski, C., Dimcev, V., Krkoleva, A., & Borozan, V. (2015). Environmental parameters monitoring in precision agriculture using wireless sensor networks. Journal of Cleaner Production, 88, 297–307.
    Article Google Scholar
18. Yu, X., Wu, P., Han, W., & Zhang, Z. (2013). A survey on wireless sensor network infrastructure for agriculture. Computer Standards & Interfaces, 35(1), 59–64.
    Article Google Scholar
19. Abouzar, P., Michelson, D. G., & Hamdi, M. (2016). RSSI-based distributed self-localization for wireless sensor networks used in precision agriculture. IEEE Transactions on Wireless Communications, 15(10), 6638–6650.
    Article Google Scholar
20. El-Kader, S. M. A., & El-Basioni, B. M. M. (2013). Precision farming solution in Egypt using the wireless sensor network technology. Egyptian Informatics Journal, 14(3), 221–233.
    Article Google Scholar
21. Georgieva, T., Paskova, N., Gaazi, B., Todorov, G., & Daskalov, P. (2016). Design of wireless sensor network for monitoring of soil quality parameters. Agriculture and Agricultural Science Procedia, 10, 431–437.
    Article Google Scholar
22. Kaiwartya, O., Abdullah, A. H., Cao, Y., Raw, R. S., Kumar, S., Lobiyal, D. K., et al. (2016). T-MQM: Testbed-based multi-metric quality measurement of sensor deployment for precision agriculture—A case study. IEEE Sensors Journal, 16(23), 8649–8664.
    Google Scholar
23. Tan Lam, P., Le Quang, T., Le Nguyen, N., & Dat Nguyen, S. (2018). Wireless sensing modules for rural monitoring and precision agriculture applications. Journal of Information and Telecommunication, 2(1), 107–123.
    Article Google Scholar
24. An, W., Ci, S., Luo, H., Wu, D., Adamchuk, V., Sharif, H., et al. (2015). Effective sensor deployment based on field information coverage in precision agriculture. Wireless Communications and Mobile Computing, 15(12), 1606–1620.
    Article Google Scholar
25. Lee, W. S., & Ehsani, R. (2015). Sensing systems for precision agriculture in Florida. Computers and Electronics in Agriculture, 112, 2–9.
    Article Google Scholar
26. Valente, J., Sanz, D., Barrientos, A., Cerro, J. D., Ribeiro, Á., & Rossi, C. (2011). An air-ground wireless sensor network for crop monitoring. Sensors, 11(6), 6088–6108.
    Article Google Scholar
27. Zhang, Z., Wu, P., Han, W., & Yu, X. (2017). Remote monitoring system for agricultural information based on wireless sensor network. Journal of the Chinese Institute of Engineers, 40(1), 75–81.
    Article Google Scholar
28. Li, X. H., Cheng, X., Yan, K., & Gong, P. (2010). A monitoring system for vegetable greenhouses based on a wireless sensor network. Sensors, 10(10), 8963–8980.
    Article Google Scholar
29. Park, D. H., & Park, J. W. (2011). Wireless sensor network-based greenhouse environment monitoring and automatic control system for dew condensation prevention. Sensors, 11(4), 3640–3651.
    Article Google Scholar
30. Mesas-Carrascosa, F. J., Santano, D. V., Meroño, J. E., de la Orden, M. S., & García-Ferrer, A. (2015). Open source hardware to monitor environmental parameters in precision agriculture. Biosystems Engineering, 137, 73–83.
    Article Google Scholar
31. Gutiérrez, J., Villa-Medina, J. F., Nieto-Garibay, A., & Porta-Gándara, M. Á. (2014). Automated irrigation system using a wireless sensor network and GPRS module. IEEE Transactions on Instrumentation and Measurement, 63(1), 166–176.
    Article Google Scholar
32. Levy, D., Coleman, W. K., & Veilleux, R. E. (2013). Adaptation of potato to water shortage: irrigation management and enhancement of tolerance to drought and salinity. American Journal of Potato Research, 90(2), 186–206.
    Article Google Scholar
33. Hedley, C. B., Roudier, P., Yule, I. J., Ekanayake, J., & Bradbury, S. (2013). Soil water status and water table depth modelling using electromagnetic surveys for precision irrigation scheduling. Geoderma, 199, 22–29.
    Article Google Scholar
34. Navarro-Hellín, H., Torres-Sánchez, R., Soto-Valles, F., Albaladejo-Pérez, C., López-Riquelme, J. A., & Domingo-Miguel, R. (2015). A wireless sensors architecture for efficient irrigation water management. Agricultural Water Management, 151, 64–74.
    Article Google Scholar
35. Nolz, R., Kammerer, G., & Cepuder, P. (2013). Calibrating soil water potential sensors integrated into a wireless monitoring network. Agricultural Water Management, 116, 12–20.
    Article Google Scholar
36. Viani, F., Bertolli, M., Salucci, M., & Polo, A. (2017). Low-cost wireless monitoring and decision support for water saving in agriculture. IEEE Sensors Journal, 17(13), 4299–4309.
    Article Google Scholar
37. Kim, Y., Evans, R. G., & Iversen, W. M. (2008). Remote sensing and control of an irrigation system using a distributed wireless sensor network. IEEE Transactions on Instrumentation and Measurement, 57(7), 1379–1387.
    Article Google Scholar
38. Zhao, W., Li, J., Yang, R., & Li, Y. (2018). Determining placement criteria of moisture sensors through temporal stability analysis of soil water contents for a variable rate irrigation system. Precision Agriculture, 19(4), 648–665.
    Article Google Scholar
39. Chávez, J. L., Pierce, F. J., Elliott, T. V., Evans, R. G., Kim, Y., & Iversen, W. M. (2010). A remote irrigation monitoring and control system (RIMCS) for continuous move systems. Part B: Field testing and results. Precision Agriculture, 11(1), 11–26.
    Article Google Scholar
40. Maurya, S., & Jain, V. K. (2016). Fuzzy based energy efficient sensor network protocol for precision agriculture. Computers and Electronics in Agriculture, 130, 20–37.
    Article Google Scholar
41. Sawant, S., Durbha, S. S., & Jagarlapudi, A. (2017). Interoperable agro-meteorological observation and analysis platform for precision agriculture: A case study in citrus crop water requirement estimation. Computers and Electronics in Agriculture, 138, 175–187.
    Article Google Scholar
42. Kim, Y., & Evans, R. G. (2009). Software design for wireless sensor-based site-specific irrigation. Computers and Electronics in Agriculture, 66(2), 159–165.
    Article Google Scholar
43. Coates, R. W., Delwiche, M. J., Broad, A., & Holler, M. (2013). Wireless sensor network with irrigation valve control. Computers and Electronics in Agriculture, 96, 13–22.
    Article Google Scholar
44. Nikolidakis, S. A., Kandris, D., Vergados, D. D., & Douligeris, C. (2015). Energy efficient automated control of irrigation in agriculture by using wireless sensor networks. Computers and Electronics in Agriculture, 113, 154–163.
    Article MATH Google Scholar
45. Nagarajan, G., & Minu, R. I. (2018). Wireless soil monitoring sensor for sprinkler irrigation automation system. Wireless Personal Communications, 98(2), 1835–1851.
    Article Google Scholar
46. Goumopoulos, C., O’Flynn, B., & Kameas, A. (2014). Automated zone-specific irrigation with wireless sensor/actuator network and adaptable decision support. Computers and Electronics in Agriculture, 105, 20–33.
    Article Google Scholar
47. Kim, Y., Schmid, T., Charbiwala, Z. M., Friedman, J., & Srivastava, M. B. (2008). NAWMS: Nonintrusive autonomous water monitoring system. In Proceedings of the 6th ACM conference on embedded network sensor systems (pp. 309–322). ACM.
48. Masseroni, D., Facchi, A., Depoli, E. V., Renga, F. M., & Gandolfi, C. (2016). Irrig-OH: An open-hardware device for soil water potential monitoring and irrigation management. Irrigation and Drainage, 65(5), 750–761.
    Article Google Scholar
49. Wong, B. P., & Kerkez, B. (2016). Real-time environmental sensor data: An application to water quality using web services. Environmental Modelling and Software, 84, 505–517.
    Article Google Scholar
50. Lozoya, C., Mendoza, C., Aguilar, A., Román, A., & Castelló, R. (2016). Sensor-based model driven control strategy for precision irrigation. Journal of Sensors, 2016, 9784071. https://doi.org/10.1155/2016/9784071.
    Article Google Scholar
51. Rossel, R. A. V., & Bouma, J. (2016). Soil sensing: A new paradigm for agriculture. Agricultural Systems, 148, 71–74.
    Article Google Scholar
52. Bernardi, A. D. C., Bettiol, G. M., Ferreira, R. D. P., Santos, K. E. L., Rabello, L. M., & Inamasu, R. Y. (2016). Spatial variability of soil properties and yield of a grazed alfalfa pasture in Brazil. Precision Agriculture, 17(6), 737–752.
    Article Google Scholar
53. Kuang, B., & Mouazen, A. M. (2013). Effect of spiking strategy and ratio on calibration of on-line visible and near infrared soil sensor for measurement in European farms. Soil and Tillage Research, 128, 125–136.
    Article Google Scholar
54. Pedrera-Parrilla, A., Van De Vijver, E., Van Meirvenne, M., Espejo-Pérez, A. J., Giráldez, J. V., & Vanderlinden, K. (2016). Apparent electrical conductivity measurements in an olive orchard under wet and dry soil conditions: significance for clay and soil water content mapping. Precision Agriculture, 17(5), 531–545.
    Article Google Scholar
55. Fu, W., Tunney, H., & Zhang, C. (2010). Spatial variation of soil nutrients in a dairy farm and its implications for site-specific fertilizer application. Soil and Tillage Research, 106(2), 185–193.
    Article Google Scholar
56. Bogena, H. R., Huisman, J. A., Oberdörster, C., & Vereecken, H. (2007). Evaluation of a low-cost soil water content sensor for wireless network applications. Journal of Hydrology, 344(1–2), 32–42.
    Article Google Scholar
57. Knadel, M., Thomsen, A., Schelde, K., & Greve, M. H. (2015). Soil organic carbon and particle sizes mapping using vis–NIR, EC and temperature mobile sensor platform. Computers and Electronics in Agriculture, 114, 134–144.
    Article Google Scholar
58. Li, Z., Wang, N., Franzen, A., Taher, P., Godsey, C., Zhang, H., et al. (2014). Practical deployment of an in-field soil property wireless sensor network. Computer Standards & Interfaces, 36(2), 278–287.
    Article Google Scholar
59. Ritsema, C. J., Kuipers, H., Kleiboer, L., Van Den Elsen, E., Oostindie, K., Wesseling, J. G., et al. (2009). A new wireless underground network system for continuous monitoring of soil water contents. Water resources research, 45(4), 1–9.
    Article Google Scholar
60. Majone, B., Viani, F., Filippi, E., Bellin, A., Massa, A., Toller, G., et al. (2013). Wireless sensor network deployment for monitoring soil moisture dynamics at the field scale. Procedia Environmental Sciences, 19, 426–435.
    Article Google Scholar
61. Kizito, F., Campbell, C. S., Campbell, G. S., Cobos, D. R., Teare, B. L., Carter, B., et al. (2008). Frequency, electrical conductivity and temperature analysis of a low-cost capacitance soil moisture sensor. Journal of Hydrology, 352(3–4), 367–378.
    Article Google Scholar
62. Cardenas-Lailhacar, B., & Dukes, M. D. (2010). Precision of soil moisture sensor irrigation controllers under field conditions. Agricultural Water Management, 97(5), 666–672.
    Article Google Scholar
63. Brocca, L., Hasenauer, S., Lacava, T., Melone, F., Moramarco, T., Wagner, W., et al. (2011). Soil moisture estimation through ASCAT and AMSR-E sensors: An intercomparison and validation study across Europe. Remote Sensing of Environment, 115(12), 3390–3408.
    Article Google Scholar
64. Ge, Y., Thomasson, J. A., & Sui, R. (2011). Remote sensing of soil properties in precision agriculture: A review. Frontiers of Earth Science, 5(3), 229–238.
    Google Scholar
65. Vuran, M. C., & Akyildiz, I. F. (2010). Channel model and analysis for wireless underground sensor networks in soil medium. Physical Communication, 3(4), 245–254.
    Article Google Scholar
66. Badia-Melis, R., Garcia-Hierro, J., Ruiz-Garcia, L., Jiménez-Ariza, T., Villalba, J. I. R., & Barreiro, P. (2014). Assessing the dynamic behavior of WSN motes and RFID semi-passive tags for temperature monitoring. Computers and Electronics in Agriculture, 103, 11–16.
    Article Google Scholar
67. Green, O., Nadimi, E. S., Blanes-Vidal, V., Jørgensen, R. N., Storm, I. M. D., & Sørensen, C. G. (2009). Monitoring and modeling temperature variations inside silage stacks using novel wireless sensor networks. Computers and Electronics in Agriculture, 69(2), 149–157.
    Article Google Scholar
68. Jahnavi, V. S., & Ahamed, S. F. (2015). Smart wireless sensor network for automated greenhouse. IETE Journal of Research, 61(2), 180–185.
    Article Google Scholar
69. Jackson, T., Mansfield, K., Saafi, M., Colman, T., & Romine, P. (2008). Measuring soil temperature and moisture using wireless MEMS sensors. Measurement, 41(4), 381–390.
    Article Google Scholar
70. Martínez, J., Egea, G., Agüera, J., & Pérez-Ruiz, M. (2017). A cost-effective canopy temperature measurement system for precision agriculture: a case study on sugar beet. Precision Agriculture, 18(1), 95–110.
    Article Google Scholar
71. Pierce, F. J., & Elliott, T. V. (2008). Regional and on-farm wireless sensor networks for agricultural systems in Eastern Washington. Computers and Electronics in Agriculture, 61(1), 32–43.
    Article Google Scholar
72. Mahan, J. R., Conaty, W., Neilsen, J., Payton, P., & Cox, S. B. (2010). Field performance in agricultural settings of a wireless temperature monitoring system based on a low-cost infrared sensor. Computers and Electronics in Agriculture, 71(2), 176–181.
    Article Google Scholar
73. Mendez, G. R., & Mukhopadhyay, S. C. (2013). A Wi-Fi based smart wireless sensor network for an agricultural environment. In Wireless sensor networks and ecological monitoring (pp. 247–268). Springer, Berlin.
74. Zhang, J., Li, W., Han, N., & Kan, J. (2008). Forest fire detection system based on a ZigBee wireless sensor network. Frontiers of Forestry in China, 3(3), 369–374.
    Article Google Scholar
75. Versichele, M., Neutens, T., Delafontaine, M., & Van de Weghe, N. (2012). The use of Bluetooth for analysing spatiotemporal dynamics of human movement at mass events: A case study of the Ghent Festivities. Applied Geography, 32(2), 208–220.
    Article Google Scholar
76. Leroy, D., Detal, G., Cathalo, J., Manulis, M., Koeune, F., & Bonaventure, O. (2011). SWISH: Secure WiFi sharing. Computer Networks, 55(7), 1614–1630.
    Article Google Scholar
77. Gu, Q. H., Lu, C. W., Li, F. B., & Wan, C. Y. (2008). Monitoring dispatch information system of trucks and shovels in an open pit based on GIS/GPS/GPRS. Journal of China University of Mining and Technology, 18(2), 288–292.
    Article Google Scholar
78. Gungor, V. C., & Lambert, F. C. (2006). A survey on communication networks for electric system automation. Computer Networks, 50(7), 877–897.
    Article Google Scholar
79. http://www.stevenswater.com/.
80. http://au.ictinternational.com/.
81. https://www.meade.com/.
82. https://www.sensirion.com/en/.

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