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Journal of Zhejiang University SCIENCE A 2005 Vol.6 No.4 P.270-275

http://doi.org/10.1631/jzus.2005.A0270


Study on dynamic model of tractor system for automated navigation applications


Author(s):  FENG Lei, HE Yong

Affiliation(s):  School of Bio-system Engineering and Food Science, Zhejiang University, Hangzhou 310029, China

Corresponding email(s):   hzfenglei@mail.hz.zj.cn, yhe@zju.edu.cn

Key Words:  Tractor, Cornering stiffness, Automated navigation, Simulation, GPS


FENG Lei, HE Yong. Study on dynamic model of tractor system for automated navigation applications[J]. Journal of Zhejiang University Science A, 2005, 6(4): 270-275.

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author="FENG Lei, HE Yong",
journal="Journal of Zhejiang University Science A",
volume="6",
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publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.2005.A0270"
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T1 - Study on dynamic model of tractor system for automated navigation applications
A1 - FENG Lei
A1 - HE Yong
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PB - Zhejiang University Press & Springer
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DOI - 10.1631/jzus.2005.A0270


Abstract: 
This research aims at using a dynamic model of tractor system to support navigation system design for an automatically guided agricultural tractor. This model, consisting of a bicycle model of the tractor system, has been implemented in the MATLAB environment and was developed based on a John Deere tractor. The simulation results from this MATLAB model was validated through field navigation tests. The accuracy of the trajectory estimation is strongly affected by the determination of the cornering stiffness of the tractor. In this simulation, the tractor cornering stiffness analysis was identified during simulation analysis using the MATLAB model based on the recorded trajectory data. The obtained data was used in simulation analyses for various navigation operations in the field of interest. The analysis on field validation test results indicated that the developed tractor system could accurately estimate wheel trajectories of a tractor system while operating in agricultural fields at various speeds. The results also indicated that the developed system could accurately determine tractor velocity and steering angle while the tractor operates in curved fields.

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1] Bevly, D.M., Sheridan, R., Gerdes, J.C., 2001. Integrating INS sensors with GPS velocity measurements for continuous estimation of vehicle sideslip and tire cornering stiffness. Proceedings of the American control conference, 7:25-30.

[2] Bukta, A.J., 1998. Nonlinear dynamics of traveling tractor-implement system generated by free play in the linkage. J Japanese Society of Agricultural Machinery, 60(4):45-53.

[3] Bukta, A.J., Sasao, A., Sakai, K., Shibusawa, S., 1998. Nonlinear Dynamics of Tractor-implement System during Transport. ASAE International Meeting, ASAE, p.981087.

[4] Bukta, A.J., Sakai, K., Sasao, A., Shibusawa, S., 2002. Free play as a source of nonlinearity in tractor-implement systems during transport. Transactions of the ASAE, 45(3):503-508.

[5] Collins, T.S., 1991. Loads in tractor linkages when transporting rear-mounted implements: Development of modeling and measurement techniques. J Agricultural Engineering Research, 49:165-188.

[6] Crolla, D.A., 1976. Effect of cultivation implements on tractor ride vibration and implications for implement control. J Agricultural Engineering Research, 21:247-261.

[7] Guo, L., Zhang, Q., Feng, L., 2003. A Low-Cost Integrated Positioning System of GPS and Inertial Sensors for Autonomous Agricultural Vehicles. ASAE International Meeting, ASAE, p.033112.

[8] Han, S., Zhang, Q., 2001. Map-based Control Functions for Autonomous Tractors. ASAE International Meeting, p.011191.

[9] Kitahama, K., Sakai, H., 2000. Measurement method of normalized cornering stiffness. J Japanese Soc. of Agricultural Engineering, 21(2):213-217.

[10] Reid, J.F., Zhang, Q., Noguchi, N., Dickson, M., 2000. Agricultural automatic guidance research in North America. Computers and Electronics in Agriculture, 25:155-167.

[11] Sakai, K., 2000. Experimental analysis of nonlinear dynamics and chaos in bouncing tractor. J Japanese Soc. of Agricultural Machinery, 62(4):63-70.

[12] Sakai, K., Aihra, K., 1994. Nonlinear vibrations in an agricultural implement system. Int. J. Bifurcation and Chaos, 4(2):465-470.

[13] Sienel, W., 1997. Estimation of the tire cornering stiffness and its application to active car steering. Proceedings of the IEEE Conference on Decision and Control, 5:4744-4749.

[14] Wong, J.Y., 1993. Theory of Ground Vehicles. John Wiley & Sons Ltd, New York, p.50-55.

[15] Zhang, Q., 1999. Automated guidance control for agricultural tractor using redundant sensors. Journal of Commercial Vehicles, 108:27-31.

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Zeru<zmskifle@gmail.com>

2014-12-17 18:55:57

Thanks for you support

jagdish@csir<jagdish.iitd@gmail.com>

2013-09-27 16:43:58

kindly send me this paper

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