Journal of Biosystems Engineering

Korean Society for Agricultural Machinery (한국농업기계학회)
권호 표지
DOI QR코드

DOI QR Code

Evaluation of Spray Flight Attitude for Agricultural Roll-balanced Helicopter using Kalman Filter

칼만필터를 이용한 농용 균평헬리콥터의 살포비행자세 평가

  • Park, Hee Jin (Daegu Gyeongbuk Institute of Science and Technology) ;
  • Koo, Young Mo (Dept. of Bio-industrial Machinery Engineering, Kyungpook National University)
  • Received : 2012.10.20
  • Accepted : 2012.12.12
  • Published : 2012.12.31
Download PDF
⟨ Previous Next ⟩

Abstract

Purpose: Aerial spraying with an agricultural unmanned helicopter became a new paradigm in the agricultural practice. Laterally tilting behavior of a conventional agricultural helicopter, resulting in the biased down-wash and uneven spray deposit is a physically intrinsic phenomenon while hovering and cruise flights. Authors studied and developed a roll-balanced agricultural helicopter with a raised pylon tail rotor system. In this study, the attitude of the roll-balanced helicopter was determined using the Kalman filter algorithm, and the quality of roll balancing of a bare-airframe helicopter was evaluated. Methods: Instantaneous attitudes were estimated using the advantage of gyroscope, followed by the long term correction and prediction using accelerometer data for the advantage of convergence. The attitudes of the fuselage were calculated by applying the Kalman filter algorithm. The spraying maneuver of the helicopter was performed at a field of 50 m long, and the attitude data were acquired and evaluated. Results: The determination of attitude using the inertial measurement unit(IMU) and Kalman filter was reliable and practical. The intrinsic attitude of the developed helicopter was stable and roll-balanced. The deviation of roll angle was ${\pm}6.3^{\circ}$ with an average of $0^{\circ}$, referring to roll-balanced. Conclusions: Handling quality of the roll attitude determined to be steadily balanced. The balancing behavior of the developed helicopter would result in an even spray pattern during aerial application.

Keywords

References

  1. Heo, O. C. 2009. Attitude estimation of the moving bodies using the MEMS sensors. MS Thesis. Suwon, Korea: Sungkyunkwan University, Department of Electrical and Computer Engineering. (In Korean)
  2. Kim, B. S., Y. D. Kim, H. C. Bang, M. J. Tahk and S. K. Hong. 2004. Flight Dynamics and Control. Seoul, Korea: Kyungmoon Co. (In Korean)
  3. Kim, T. 2011. Development of attitude heading reference system using fuzzy logic and kalman filter. MS Thesis. Pusan, Korea: Pusan National University, Department of Electronic and Electrical Engineering. (In Korean)
  4. Koo, Y. M., C. S. Lee, T. S. Seok, S. K. Shin, T. G. Kang, S. H. Kim and T. Y. Choi. 2006. Aerial application using a small RF controlled helicopter (I), status and cost analysis. Biosystems Engineering. 31(2): 95-101. (In Korean) https://doi.org/10.5307/JBE.2006.31.2.095
  5. Koo, Y. M., T. S. Seok and S. K. Shin. 2010a. SW05 rotor lift of an unmanned helicopter for precise ULV aerial application. Journal of Biosystems Engineering. 35(1): 31-36. (In Korean) https://doi.org/10.5307/JBE.2010.35.1.031
  6. Koo, Y. M., Y. Bae T. S. Soek, S. K. Shin and H. J. Park. 2010b. Tail rotor design and thrust test for a roll-balanced agricultural unmanned helicopter. Journal of Biosystems Engineering. 35(5): 302-309. (In Korean) https://doi.org/10.5307/JBE.2010.35.5.302
  7. Lee, K. T. and K. H. Lee. 2000. UAV-Current and Future. Journal of the Korean Society for Aeronautical and Space Science. 28(6): 142-163. (In Korean)
  8. Lee, J. H. and T. W. Jeong. 2004. Design and instrumentation aerial vehicles's navigation system using kalman filter. 2004. In: Proceedings of Summer Meeting of Korean Society of Electric Engineers, pp. 2218-2220: KSEE. (In Korean)
  9. Park H. J., Y. M. Koo and H. B. Park. 2011. Determination of flight attitude using kalman filter for an agricultural unmanned helicopter. In: Proceedings of 2nd International Conference on Instrumentation, Control and Automation, pp. 169-174: IEEE-ICA.
  10. Rojas, R. 2012 (accessed). The kalman filter. Available at robocup.mi.fu-berlin/bush /kalman.pdf.
  11. Tenn, H. K., S. S. Jan and F. B. Hsiao. 2009. Pitch and roll attitude estimation of a small-scaled helicopter using single antenna GPS with gyroscopes. GPS solute, Springer :209-220.

Cited by

  1. Fundamental Experiment for the Development of Water Pipeline Locator vol.30, pp.3, 2016, https://doi.org/10.11001/jksww.2016.30.3.253