Analysis of the Potential and Carrying Capacity of By-Products from Oil Palm Plantations (Elaeis guineensis Jacq.) and Sago Plants (Metroxylon sp.) as Livestock Feed in Southeast Sulawesi

The potential of by-products from palm oil plantations (Elaeis guineensis Jacq.) and sago plants (Metroxylon sp.) in Southeast Sulawesi are a primary focus in the context of extensive plantations covering thousands of hectares. Despite their significant potential, the existence of these by-products has not been quantitatively assessed to support livestock feed provision in Southeast Sulawesi. This study aimed to evaluate the potential and support capacity of by-products from palm oil and sago plantations for livestock feed through statistical data analysis and laboratory analysis approaches. The research findings indicate that the oil palm plantation area (9,303 ha) can produce by-products such as PDS at a rate of 80,990 tons/ha/year, meeting the needs of cattle at 8,999 ST/hectare/year. Additionally, TKS production was 81,426 tons/ha/year, fulfilling the requirements for cattle at 9,047 LU/hectare/year. LKS production stands at 5,692 tons/ha/year, providing cattle at 632 ST/hectare/year, whereas BIS production reaches 8,542 tons/ha/year, meeting the needs of cattle at 949 LU/hectare/year. The sago plantation area (2,672 ha) can produce sago plant by-products in the form of ATS at a rate of 5,576 tons/ha/year, satisfying the requirements for cattle at 620 LU/hectare/year. Utilization of by-products from palm oil (Elaeis guineensis Jacq.) and sago plants (Metroxylon sp.) require more planning to maximize their utilization.

Keywords: Potential; carrying capacity; oil palm; sago; animal feed

DOI：10.62321/issn.1000-1298.2024.09.01

ZHAO Chunjiang. Current situation and future prospects of smart agriculture [ J ]. Journal of South China Agricultural University, 2021, 42(6) ;1 -7. (in Chinese)

VERDOUW С N, KRUIZE J W. Digital twins in farm management: illustrations from the FIWARE accelerators SmartAgriFood and Fractals [С ] //1 th Asian-Australasian Conference on Precision Agriculture, Hamilton, 2017.

VERDOUW C, TEKINERDOGAN B, BEULENS A, et al. Digital twins in smart farming [J]. Agricultural Systems, 2021, 189: 103046.

LIANG Chenguang. Research and implementation of rice field environmental monitoring system based on digital twin [D]. Changsha: Hunan Agricultural University ,2020. (in Chinese)

SKOBELEV P, LARYUKHIN V, SIMONOVA E,et al. Multi-agent approach for developing a digital twin of wheat[ С ]//2020 IEEE International Conference on Smart Computing (SMARTCOMP). IEEE, 2020.

WECKESSER F, BECK M, HCLSBERGEN К J, et al. A digital advisor twin for crop nitrogen management [J]. Agriculture, 2022, 12(2) :302.a

CAI Zhengwu. Research on the application of production marketing system of field agricultural digital production,[D]. Wuhan; Wuhan Polytechnic University, 2022. (in Chinese)

LOWE T, MOGHADAM P, EDWARDS E, et al. Canopy density estimation in perennial horticulture crops using 3D spinning LiDAR SLAM [ J ]. Journal of Field Robotics, 2021 , 38(4) :598 -618.

WANG Hongjun, LIN Junqiang, ZOU Xiangjun, et al. Construction of a virtual interactive system for orchards based on digital twins [ J]. Journal of System Simulation, 2024,36(6) : 1493 - 1508. (in Chinese)

EDEMETTI F, MAIALE A, CARLINI C, et al. Vineyard digital twin; construction and characterization via UAV images- diwine proof of concept [C] // 2022 IEEE 23rd International Symposium on a World of Wireless, Mobile and Multimedia Networks (WoWMoM) , 2022 :601 -606.

BELLVERT J, PELECHA A, PAMIES-SANS M, et al. Assimilation of Sentinel—2 biophysical variables into a digital twin for the automated irrigation scheduling of a vineyardl[ J]. Water, 2023, 15( 14) :2506.

GUO Тао, LI Zongnan, HE Zetao, et al. Design and implementation of a mobile management service platform for smart orchards [ J ]. Journal of Smart Agriculture, 2023, 3(11): 5 -8,12. (in Chinese)

ZANCHIN A, SOZZI M , GIORA D, et al. Digital twins analysis as a tool to find new descriptors for grapevine bunch morphology categorisation and grey mould infection risk evaluation [J]. Biosystems Engineering, 2024, 237; 71 -82.

TIAN Qianlong. Research on environmental control system of glass greenhouse based on digital twin [ D ]. Wuhan: Huazhong Agricultural University, 2023. (in Chinese)

LAI Lu'an, CHEN Ting, CHANG Jie, et al. Research on visualization monitoring system of greenhouse based on digital twin m. Agricultural Equipment & Vehicle Engineering, 2023, 61(2) : 128 - 131. (in Chinese)

KAVGA A, THOMOPOULOS V, PISCHINAS E, et al. Design and simulation of a greenhouse in a computational environment (ANSYS/FLUENT) and an automatic control system in a LABVIEW environment [ J ]. Simulation Modelling Practice and Theory, 2023, 129:102837.

REZVANI S M E, SHAMSHIRI R R, HAMEED 1 A, et al. Greenhouse crop simulation models and microclimate control systems, a review [ M ] // REDMOND R S. Next-Generation Greenhouses for Food Security, London;IntechOpen, 2021 :1 -22.

HOWARD D A, MA Z, AASLYNG J M,et al. Data architecture for digital twin of commercial greenhouse production [С ] // RIVF International Conference on Computing and Communication Technologies,2020.

JO S K, PARK D H, PARK H , et al. Energy planning of pigsty using digital twin [ С] / 2019 International Conference on Information and Communication Technology Convergence ( ICTC) ,2019 :723 -725.

REYES Y A, ABBASI R, MARTINEZ P, et al. Digital twinning of hydroponic grow beds in intelligent aquaponic systems [ J]. Sensors, 2022, 22 :7393.