Autors: Ganev, B. T., Hristov, H. I., Laskov, L. B., A Popov., Marinov, M. B.
Title: Multi-sensor System for Monitoring in Agriculture
Keywords: multi-sensing; relative humidity measurement; soil moisture

Abstract: This paper presents the implementation of a system for monitoring some basic environmental parameters, necessary for accurate analysis of plant growing. The observed parameters are air temperature at three different heights, relative humidity at three different heights, soil temperature, and humidity at two more points located at different depths.

References

  1. 1. Allen RG, Pereira LS, Raes D, Smith M. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements [Internet]. 1998 2. West JS, Bravo C, Oberti R, Lemaire D, Moshou D, McCartney HA. The Potential of Optical Canopy Measurement for Targeted Control of Field Crop Diseases; 2003. 593 p. DOI: 10.1146/annurev.phyto.41.121702.103726 3. Costa JM, Grant OM, Chaves MM. Thermography to explore plant-environment interactions. J Exp Bot [Internet]. 2013;64(13):3937-49. Available from: www.scopus.com 4. Zhang J, Huang Y, Pu R, Gonzalez-Moreno P, Yuan L, Wu K, Huang W. Monitoring plant diseases and pests through remote sensing technology: A review. Comput Electron Agric [Internet]. 2019;165 5. Liaghat S, Balasundram SK. A review: The role of remote sensing in precision agriculture. Am J Agric Biol Sci [Internet]. 2010;5(1):50-5. 6. Ishimwe R, Abutaleb K, Ahmed F. Applications of thermal imaging in agriculture—a review. Advances in Remote Sensing [Internet]. 2014;3(3):128-40. 7. Lorenzen B, Jensen A. Changes in leaf spectral properties induced in barley by cereal powdery mildew. Remote Sens Environ [Internet]. 1989;27(2):201-9. 8. Barnes EM, Baker MG. Multispectral data for mapping soil texture: Possibilities and limitations. Appl Eng Agric [Internet]. 2000;16(6):731-41. 9. Khanal S, Kushal KC, Fulton JP, Shearer S, Ozkan E. Remote sensing in agriculture—accomplishments, limitations, and opportunities. Remote Sens [Internet]. 2020;12(22):1-29. 10. Shanmugapriya P, Rathika S, Ramesh T, Janaki P. Applications of remote sensing in agriculture-A review. Int.J.Curr.Microbiol.Appl.Sci [Internet]. 2019;8(1):2270-83. 11. Sanders KT, Masri SF. The energy-water agriculture nexus: The past, present and future of holistic resource management via remote sensing technologies. J Clean Prod [Internet]. 2016;117:73-88. 12. Stoll M, Jones HG. Thermal imaging as a viable tool for monitoring plant stress. J Int Sci Vigne Vin [Internet]. 2007;41(2):77-84. 13. Méndez-Barroso LA, Garatuza-Payán J, Vivoni ER. Quantifying water stress on wheat using remote sensing in the yaqui valley, sonora, mexico. Agric Water Manage [Internet]. 2008;95(6):725-36. 14. Kulkarni SS, Bajwa SG, Huitink G. Investigation of the effects of soil compaction in cotton. Trans ASABE [Internet]. 2010;53(3):667-74. 15. Hoffmann N, Schröder T, Schlüter F, Meinlschmidt P. Potential of infrared thermography to detect insect stages and defects in young trees. J Kulturpflanzen [Internet]. 2013;65(9):337-46. 16. Nikolov GT, Ganev BT, Marinov MB, Galabov VT. Comparative Analysis of Sensors for Soil Moisture Measurement. In: 2021 30th International Scientific Conference Electronics, ET 2021 - Proceedings [Internet]; 20212021 DOI: 10.1109/ET52713.2021.9580162 17. DS18B20, Programmable Resolution 1-Wire Digital Thermometer rev.6 [Internet]. 2019 18. BME680, Low power gas, pressure, temperature & humidity sensor Datasheet Document rev.1.0 [Internet]. 2017 19. Heltec WiFi LoRa 32 V2.WiFi LoRa 32-classic IoT dev-board [Internet].

Issue

13th National Conference with International Participation, ELECTRONICA 2022, 2022, Bulgaria, DOI 10.1109/ELECTRONICA55578.2022.9874374

Вид: публикация в международен форум, публикация в реферирано издание, индексирана в Scopus