References
- Kocakusak A, Colak B, Helhel S. Frequency dependent complex dielectric permittivity of rubber and magnolia leaves and leaf water content relation. J Microwave Power Electromagn Energy. 2016;50(4):294–307.
- Dash C, Das A, Bisoyi DK. Influence of pretreatment on mechanical and dielectric properties of short sunn hemp fiber-reinforced polymer composite in correlation with fine structure of the fiber. J Compos Mater. 2020;54(23):3245–3260.
- Pinter PJ, Hatfield JL, Schepers JS, et al. Remote sensing for crop management. Photogramm Eng Remote Sens. 2003;69(6):647–664.
- Krraoui H, Mejri F, Aguili T. Dielectric constant measurement of materials by a microwave technique: application to the characterization of vegetation leaves. J Electromagn Waves Appl. 2016;30(12):1643–1660.
- Alonso-González A, Hajnsek I. Radar remote sensing of land surface parameters. in observation and measurement of ecohydrological processes. Berlin: Springer; 2019.
- Ulaby FT, Long DG. Microwave radar and radiometric remote sensing. Ann Arbor: The University of Michigan Press; 2014.
- Colak B. Moisture content effect of banana leaves to radio frequency absorbing. Microwave Opt Technol Lett. 2019;61(11):2591–2595.
- Romanov AN. Dielectric properties of water in saline soil and its solonchak vegetation at a frequency of 1.41 GHz. IEEE Geosci Remote Sens Lett. 2020; doi:10.1109/LGRS.2020.3014374.
- Romanov AN, Ulanov PN. Seasonal differences in dielectric properties of dwarf woody tundra vegetation in a microwave range. IEEE Trans Geosci Remote Sens. 2019;57(6):3119–3125.
- van Emmerik T, Steele-Dunne SC, Judge J, et al. Dielectric response of corn leaves to water stress. IEEE Geosci Remote Sens Lett. 2017;14(1):1–6.
- Dogan H, Basyigit IB, Genc A. Determination and modelling of dielectric properties of the cherry leaves of varying moisture content over 3.30–7.05 GHz frequency range. J Microwave Power Electromagn Energy. 2020;54(3):254–270.
- Huang J, Pang C, Zhou J, et al. Complex-permittivity measurement and modeling of moso bamboo from 0. 5 to 18 GHz. IEEE Geosci Remote Sens Lett. 2020; doi:10.1109/LGRS.2020.3002458.
- Genc A, Dogan H, Basyigit IB. A new semiempirical model determining the dielectric characteristics of citrus leaves for the remote sensing at C band. Turk J Elec Eng Comp Sci. 2020;28:1644–1655.
- Basyigit IB. The examination and modeling of moisture content effect of banana leaves on dielectric constant for remote sensing. Microwave Opt Technol Lett. 2020;62(3):1087–1092.
- Metlek S, Kayaalp K, Basyigit IB, et al. The dielectric properties prediction of the vegetation depending on the moisture content using the deep neural network model. Int J RF Microwave Comput Aided Eng. 2021;31(1):1–10.
- Sharma A, Lang RH, Kurum M, et al. L-band radar experiment and modeling of a corn canopy over a full growing season. IEEE Trans Geosci Remote Sens. 2020;58(8):5821–5835.
- Johnson R. Defining hemp: a fact sheet. Washington, DC: Congressional Research Service; 2019. (no. R44742).
- Karadas S, Yeriskin SA, Balbasi M, et al. Commplex dielectric, complex electric modulus, and electrical conductivity in Al/(graphene-PVA)/p-Si (metal-polymer-semiconductor) structures. J Phys Chem Solids. 2021;148:1–8.
- Li Z, Zeng J, Chen Q, et al. The measurement and model construction of complex permittivity of vegetation. Sci China Earth Sci. 2014;57(4):729–740.
- Shrestha BL, Wood HC, Sokhansanj S. Microwave dielectric properties of alfalfa leaves from 0.3 to 18 GHz. IEEE Trans Instrum Meas. 2011;60(8):2926–2933.
- Cole KS, Cole RH. Dispersion and absorption in dielectrics I. Alternating current characteristics. J Chem Phys. 1941;9(4):341–351.