This work is licensed under the Creative Commons Attribution 4.0 International License.
Sheludchenko, B., Sarauskis, E., Kukharets, S., et al. (2022). Graphic analytical optimization of design and operating parameters of tires for drive wheels of agricultural machinery. Soil & Tillage Research, (215-), 215.Search in Google Scholar
Janulevicius., Damanauskas., Pupinis. (2018). Effect of variations in front wheels driving lead on performance of a farm tractor with mechanical front-wheel-drive. J TERRAMECHANICS, 2018, 77(-), 23-30.Search in Google Scholar
Cho, Y. (2021). Development and verification of individual motor control technology to improve the driving performance of independently rotating wheel type railway vehicle using hardware-in-the-loop (HIL) Simulator: Measurement and Control, 54(1-2), 11-24.Search in Google Scholar
Ahmadi, I. (2017). A power estimator for an integrated active-passive tillage machine using the laws of classical mechanics. Soil and Tillage Research, 171, 1-8.Search in Google Scholar
Mudarisov, S. G., Gabitov, I. I., Rakhimov, R. S., et al. (2019). REASONING OF MODULAR-TYPE TILLAGE AND SEEDING MACHINES CONSTRUCTION DIAGRAM AND PARAMETERS. Journal of the Balkan Tribological Association, (3), 25.Search in Google Scholar
Sattolo, T., Pereira, L. M., Otto, R., et al. (2021). Effects of land use, tillage management, and crop diversification on soil physical quality in Cerrado agricultural systems. Soil Science Society of America Journal.Search in Google Scholar
Sg, A., He, B., Mt, C., et al. (2021). The Advent of Modern Solar-powered Electric Agricultural Machinery: A Solution for Sustainable Farm Operations. Journal of Cleaner Production.Search in Google Scholar
Thomas, G., Balocco, S., Mann, D., et al. (2021). Intelligent Agricultural Machinery Using Deep Learning. IEEE Instrumentation & Measurement Magazine.Search in Google Scholar
Fawzi, H., Mostafa, S. A, Ahmed, D., et al. (2021). TOQO: A new Tillage Operations Quality Optimization model based on parallel and dynamic Decision Support System. Journal of Cleaner Production, 316, 128263-.Search in Google Scholar
Kener, A., R, Chotěborsk., Linda, M., et al. (2021). Stress distribution on a soil tillage machine frame segment with a chisel shank simulated using discrete element and finite element methods and validate by experiment. Biosystems Engineering, 209(2), 125-138.Search in Google Scholar
Mattetti, M., Beltramin, A., Estevez, M., et al. (2022). Start and stop systems on agricultural tractors as solution for saving fuel and emissions. Biosystems Engineering, 216, 108-120.Search in Google Scholar
Wen, L., Liu, H., Chen, J., et al. (2021). Fractional linear regression equation in agricultural disaster assessment model based on geographic information system analysis technology. Applied Mathematics and Nonlinear Sciences, 7(1), 275-284.Search in Google Scholar
Hilal, Y. Y., Al-Rajabo, S. A. J., & Dahham, G. A. (2021). The effects of vibrating wings subsoiler plow on driver’s seat of agricultural tractors and mechanization performance. Soil and Tillage Research, 205, 104806.Search in Google Scholar
Mano, K. (2020). Mechanization in land preparation and agricultural intensification: The case of rice farming in the Cote d’Ivoire. Agricultural Economics, 51(6).Search in Google Scholar
Koniuszy, A., Kostencki, P., Berger, A., et al. (2017). Power performance of farm tractor in eld operations. Eksploatacja i Niezawodnosc - Maintenance and Reliability, 19(1), 43-47.Search in Google Scholar
A, Janulevičius., Šarauskis., Egidijus., Čiplienė., Aušra., et al. (2019). Estimation of farm tractor performance as a function of time efficiency during ploughing in fields of different sizes. Biosystems Engineering, 179, 80-93.Search in Google Scholar
Lankenau, G., Winter, V. (2018). An Engineering Review of the Farm Tractor’s Evolution to a Dominant Design. Journal of Mechanical Design, 141(3).Search in Google Scholar