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Proceedings of the 19th Conference on Computer Science and Intelligence Systems (FedCSIS)

Annals of Computer Science and Information Systems, Volume 39

An AI-empowered energy-efficient portable NIRS solution for precision agriculture: A pilot study on a citrus fruit

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DOI: http://dx.doi.org/10.15439/2024F5111

Citation: Proceedings of the 19th Conference on Computer Science and Intelligence Systems (FedCSIS), M. Bolanowski, M. Ganzha, L. Maciaszek, M. Paprzycki, D. Ślęzak (eds). ACSIS, Vol. 39, pages 313318 ()

Full text

Abstract. Smart agriculture has seen impressive progresses in monitoring the quality of the crop and early detecting the onset of pathogens. However, this is typically achieved through smart, expensive, and energy-demanding robots and autonomous systems. We propose an AI-empowered portable low-cost short-wave near-infrared spectroscopy (sw-NIRS) solution that allows non-destructive measurements from plants and vegetables. In this pilot study, we specifically targeted an orange fruit and showed that it is possible to classify its different parts through sw-NIRS in the range 1350-2150 nm by using AI models, exceeding 98\% accuracy. Also, we explored the minimum amount of energy needed to reach such high classification performance. In the future, we aim to extend this investigation to other targets (e.g., bean plants), to develop AI architectures to more accurately model the physiological conditions of the target, and to create a network of sw-NIRS sensors to simultaneously monitor a large-scale crop.

References

  1. D. D. Tegegn, “Process of analyzing organic materials, based on processing of near-nfrared spectra through advanced methods (PhD Thesis),” 2023.
  2. P. Rodríguez, J. Villamizar, L. Londoño, T. Tran, and F. Davrieux, “Quantification of dry matter content in hass avocado by near-infrared spectroscopy (NIRS) scanning different fruit zones,” Plants, vol. 12, no. 17, p. 3135, 2023.
  3. K. Ncama, L. S. Magwaza, A. Mditshwa, and S. Z. Tesfay, “Application of visible to near-infrared spectroscopy for non-destructive assessment of quality parameters of fruit,” Infrared Spectroscopy-Principles, Advances, and Applications, 2018.
  4. A. M. Cavaco, D. Passos, R. M. Pires, M. D. Antunes, and R. Guerra, “Nondestructive assessment of citrus fruit quality and ripening by visible-near infrared reflectance spectroscopy,” Citrus-Research, Development and Biotechnology, p. 95970, 2021.
  5. A. Zancanaro, G. Cisotto, D. D. Tegegn, S. L. Manzoni, I. Reguzzoni, E. Lotti, and I. Zoppis, “Variational autoencoder for early stress detection in smart agriculture: A pilot study,” in 2022 IEEE Workshop on Metrology for Agriculture and Forestry (MetroAgriFor). IEEE, 2022, pp. 126–130.
  6. J. Müller-Maatsch and S. M. van Ruth, “Handheld devices for food authentication and their applications: A review,” Foods, vol. 10, no. 12, p. 2901, 2021.
  7. K. R. Borba, P. C. Spricigo, D. P. Aykas, M. C. Mitsuyuki, L. A. Colnago, and M. D. Ferreira, “Non-invasive quantification of vitamin C, citric acid, and sugar in Valência oranges using infrared spectroscopies,” Journal of Food Science and Technology, vol. 58, pp. 731–738, 2021.
  8. J. A. Cayuela and C. Weiland, “Intact orange quality prediction with two portable NIR spectrometers,” Postharvest Biology and Technology, vol. 58, no. 2, pp. 113–120, 2010.
  9. “Spectral Evolution NaturaSpec portable spectroradiometer,” https://spectralevolution.com/products/hardware/field-portable-spectroradiometers-for-remote-sensing/naturaspec-portable-spectroradiometer/, accessed: 2023-09-25.
  10. J. Martins, R. Guerra, R. Pires, M. Antunes, T. Panagopoulos, A. Brázio, A. Afonso, L. Silva, M. Lucas, and A. Cavaco, “SpectraNet–53: A deep residual learning architecture for predicting soluble solids content with VIS-NIR spectroscopy,” Computers and Electronics in Agriculture, vol. 197, p. 106945, 2022.
  11. Seletech Engineering Srl, “AI-empowered monitoring systems,” https://lnx.seletech.com/index.php/it/prodotti-e-progetti/intelligenza-artificiale/, accessed: 2023-09-25.
  12. W. Suphamitmongkol, G. Nie, R. Liu, S. Kasemsumran, and Y. Shi, “An alternative approach for the classification of orange varieties based on near infrared spectroscopy,” Computers and electronics in agriculture, vol. 91, pp. 87–93, 2013.
  13. J. A. Prananto, B. Minasny, and T. Weaver, “Near infrared (NIR) spectroscopy as a rapid and cost-effective method for nutrient analysis of plant leaf tissues,” Advances in agronomy, vol. 164, pp. 1–49, 2020.
  14. C.-C. Chang and C.-J. Lin, “LIBSVM: a library for support vector machines,” ACM transactions on intelligent systems and technology (TIST), vol. 2, no. 3, pp. 1–27, 2011.
  15. F. Cabitza and A. Campagner, “The need to separate the wheat from the chaff in medical informatics: Introducing a comprehensive checklist for the (self)-assessment of medical ai studies,” p. 104510, 2021.
  16. K. Choudhary, D. Wines, K. Li, K. F. Garrity, V. Gupta, A. H. Romero, J. T. Krogel, K. Saritas, A. Fuhr, P. Ganesh et al., “Jarvis-leaderboard: a large scale benchmark of materials design methods,” npj Computational Materials, vol. 10, no. 1, p. 93, 2024.
  17. G. Cisotto, “Python code associated with this publication at colab,” https://colab.research.google.com/drive/14xU8u1Ao3smfnc_epTcIP9AS8etUjG8V?usp=sharing, last access: 2024-07-18.
  18. G. Cisotto, D. D. Tegegn, I. Reguzzoni, and E. Lotti, “NIRS dataset associated with this publication,” https://github.com/CisottoGiulia/PON22-AI-NIRS-AgriFood.
  19. A. M. Cavaco, R. Pires, M. D. Antunes, T. Panagopoulos, A. Brázio, A. M. Afonso, L. Silva, M. R. Lucas, B. Cadeiras, S. P. Cruz et al., “Validation of short wave near infrared calibration models for the quality and ripening of Newhall orange on tree across years and orchards,” Postharvest Biology and Technology, vol. 141, pp. 86–97, 2018.
  20. A. Zancanaro, G. Cisotto, and L. Badia, “Modeling value of information in remote sensing from correlated sources,” Computer Communications, vol. 203, pp. 289–297, 2023.
  21. P. Bertellini, G. D’Addese, G. Franchini, S. Parisi, C. Scribano, D. Zanirato, and M. Bertogna, “Binary classification of agricultural crops using sentinel satellite data and machine learning techniques,” in 2023 18th Conference on Computer Science and Intelligence Systems (FedCSIS). IEEE, 2023, pp. 859–864.
  22. G. Castellano, P. De Marinis, and G. Vessio, “Applying knowledge distillation to improve weed mapping with drones,” in 2023 18th Conference on Computer Science and Intelligence Systems (FedCSIS). IEEE, 2023, pp. 393–400.