Authors: Roberto Sabatini, Celia Bartel, Anish Kaharkar, Tesheen Shaid, Subramanian Ramasamy

Abstract:

Two multisensor system architectures for navigation and guidance of small Unmanned Aircraft (UA) are presented and compared. The main objective of our research is to design a compact, light and relatively inexpensive system capable of providing the required navigation performance in all phases of flight of small UA, with a special focus on precision approach and landing, where Vision Based Navigation (VBN) techniques can be fully exploited in a multisensor integrated architecture. Various existing techniques for VBN are compared and the Appearance-Based Navigation (ABN) approach is selected for implementation. Feature extraction and optical flow techniques are employed to estimate flight parameters such as roll angle, pitch angle, deviation from the runway centreline and body rates. Additionally, we address the possible synergies of VBN, Global Navigation Satellite System (GNSS) and MEMS-IMU (Micro-Electromechanical System Inertial Measurement Unit) sensors, and the use of Aircraft Dynamics Model (ADM) to provide additional information suitable to compensate for the shortcomings of VBN and MEMS-IMU sensors in high-dynamics attitude determination tasks. An Extended Kalman Filter (EKF) is developed to fuse the information provided by the different sensors and to provide estimates of position, velocity and attitude of the UA platform in real-time. The key mathematical models describing the two architectures i.e., VBN-IMU-GNSS (VIG) system and VIGADM (VIGA) system are introduced. The first architecture uses VBN and GNSS to augment the MEMS-IMU. The second mode also includes the ADM to provide augmentation of the attitude channel. Simulation of these two modes is carried out and the performances of the two schemes are compared in a small UA integration scheme (i.e., AEROSONDE UA platform) exploring a representative cross-section of this UA operational flight envelope, including high dynamics manoeuvres and CAT-I to CAT-III precision approach tasks. Simulation of the first system architecture (i.e., VIG system) shows that the integrated system can reach position, velocity and attitude accuracies compatible with the Required Navigation Performance (RNP) requirements. Simulation of the VIGA system also shows promising results since the achieved attitude accuracy is higher using the VBN-IMU-ADM than using VBN-IMU only. A comparison of VIG and VIGA system is also performed and it shows that the position and attitude accuracy of the proposed VIG and VIGA systems are both compatible with the RNP specified in the various UA flight phases, including precision approach down to CAT-II.

Keywords: Global Navigation Satellite System (GNSS), Lowcost Navigation Sensors, MEMS Inertial Measurement Unit (IMU), Unmanned Aerial Vehicle, Vision Based Navigation.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092255

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References:

[1] B. Sinopoli, M. Micheli, G. Donato, and T. J. Koo, "Vision based navigation for unmanned aerial vehicles,” in Proc. International Conf. of Robotics & Automation, vol. 2, 2001, pp. 1757 – 1764.
[2] S. Se, D. G. Lowe, and J. J. Little, "Vision based global localisation and mapping,” IEEE Trans. on Robotics, vol. 21, no.3, pp. 364-375, June 2005.
[3] P. Cui and F. Yue, "Stereo vision-based autonomous navigation for lunar rovers,” Aircraft Engineering and Aerospace Technology: An International Journal, vol. 79, no. 4, pp. 398-405, 2007.
[4] Y. Matsumoto, K. Sakai, M. Inaba, and H. Inoue, "View-based approach to robot navigation,” in Proc. IEEE/RSJ Conf. on Intelligent Robots and Systems, vol. 3, Japan, Nov. 2000, pp. 1702-1708.
[5] J. Courbon, Y. Mezouar, N. Guenard, and P. Martinet, "Visual navigation of a quadrotor aerial vehicle,” in Proc. IEEE/RSJ Conf. on Intelligent Robots and Systems, Oct. 2009, pp. 5315-5320.
[6] J. Courbon, Y. Mezouar, N. Guenard, and P. Martinet, "Vision-based navigation of unmanned aerial vehicles,” Control Engineering Practice, vol. 18, no. 7, pp. 789-799, July 2010.
[7] Z. Chen and S. T. Birchfield, "Qualitative vision-based path following,” IEEE Trans. on Robotics, vol. 25, no. 3, pp. 749-754, June 2009.
[8] A. Remazeilles, and F. Chaumette, "Image-based robot navigation from an image memory,” Journal of Robotics and Autonomous Systems, vol. 55, no. 4, 2007.
[9] L. Xinhua and Y. Cao, "Research on the application of the vision-based autonomous navigation to the landing of the UAV,” in Proc. Fifth International Symposium on Instrumentation and Control Technology, vol. 5253, 2003, pp. 385-388.
[10] D. Dusha, L. Mejias, and R. Walker, "Fixed-wing attitude estimation using temporal tracking of the horizon and optical flow,” Journal of Field Robotics, vol. 28, no. 3, pp. 355-372, 2011.
[11] M. A. Olivares-Mendez, I. F. Mondragon, P. Campoy, and C. Martinez, "Fuzzy controller for UAV-landing task using 3D position visual estimation,” in Proc. IEEE International Conf. on Fuzzy Systems, 2010.
[12] S. I. Roumeliotis, A. E. Johnson, and J. F. Montgomery, "Augmenting Inertial Navigation with image-basedestimation,” in Proc. International Conf. of Robotics & Automation, 2002, pp. 4326-4333.
[13] G. N. Desouza and A. C. Kak, "Vision for mobile robot navigation: a survey,” IEEE Trans. Pattern Analysis and Machine Intelligence, vol. 24, no. 2, pp. 237 – 267, Feb. 2002.
[14] D. Santosh, S. Achar, and C. V. Jawahar, "Autonomous image-based exploration for mobile robot navigation,” in Proc. International Conf. of Robotics & Automation, 2008, pp. 2717 – 2722.
[15] P. Rives and J. R. Azinheira, "Visual auto-landing of an autonomous aircraft,” INRIA, no. 4606, 2002.
[16] G. Blanc, Y. Mezouar, and P. Martinet, "Indoor navigation of a wheeled mobile robot along visual routes,” in Proc. International Conf. of Robotics & Automation, 2005, pp. 3354-3359.
[17] G. Rangasamy, "Image sensor fusion algorithms for obstacle detection, location and avoidance for autonomous navigation of UAVs,” M.Sc. Thesis, School of Engineering, Cranfield University, 2010.
[18] E. H. Shin, "Estimation technics for low-cost inertial navigation,” PhD Thesis, University of Calgary, Alberta, Canada, 2005.
[19] A. Angrisano, "GNSS/INS Integration Methods,” PhD Thesis, Department of Applied Sciences, Parthenope University of Naples, Italy, 2010.
[20] C. Tiberius, Standard positioning service, "Handheld GPS receiver accuracy,” GPS World, 2003.
[21] W. Ding and J. Wang, "Precise Velocity Estimation with a Stand-Alone GPS receiver,” The Journal of Navigation, vol. 69, no. 2, pp. 311-325, 2011.
[22] D. Titterton and J. Weston, "Strap down Inertial Navigation Technology,” (2nd Edition), The Institution of Electrical Engineers, 2004.
[23] S. Troy, "Investigation of MEMS Inertial Sensors and Aircraft Dynamic Models in Global Positioning System Integrity Monitoring for Approaches with Vertical Guidance,” PhD thesis, Queensland University of Technology, School of Engineering, 2009.
[24] S. Godha, "Performance Evaluation of Low Cost MEMS-Based IMU Integrated With GPS for Land Vehicle Navigation Application,” UCGE Report No. 20239, University of Calgary, Department of Geomatics Engineering, Alberta, Canada, 2006.
[25] R. Sabatini, C. Bartel, A. Kaharkar, T. Shaid, H. Jia, and D. Zammit- Mangion , "Design and Integration of Vision-based Navigation Sensors for Unmanned Aerial Vehicles Navigation and Guidance,” in Proc. SPIE Photonics Europe Conf., Brussels, Belgium, 2012.
[26] R. Sabatini, L. RodríguezSalazar, A. Kaharkar, C. Bartel, and T. Shaid, "GNSS Data Processing for Attitude Determination and Control of Unmanned Aerial and Space Vehicles,” in Proc. European Navigation Conf., Gdansk (Poland), April 2012.
[27] R. Sabatini, L. RodríguezSalazar, A. Kaharkar, C. Bartel, and T. Shaid, "Low-Cost Vision Sensors and Integrated Systems for Unmanned Aerial Vehicle Navigation and Guidance,” ARPN Journal of Systems and Software, ISSN: 2222-9833, vol. 2, no. 11, pp. 323-349, 2013.
[28] R. Sabatini, L. RodríguezSalazar, A. Kaharkar, C. Bartel, T. Shaid, D. Zammit-Mangion, and H. Jia, "Low-Cost Navigation and Guidance Systems for Unmanned Aerial Vehicles – Part 1: Vision-Based and Integrated Sensors,” Annual of Navigation Journal, vol. 19, pp. 71-98, 2012.
[29] R. Sabatini, L. RodríguezSalazar, A. Kaharkar, C. Bartel, and T. Shaid, "Carrier-Phase GNSS Attitude Determination and Control System for Unmanned Aerial Vehicle Applications,”ARPN Journal of Systems and Software, ISSN: 2222-9833, vol. 2, no. 11, pp.297-322, 2012.
[30] R. Sabatini, C. Bartel, A. Kaharkar, T. Shaid, D. Zammit-Mangion, and H. Jia, "Vision Based Sensors and Multisensor Systems for Unmanned Aerial Vehicles Navigation and Guidance,” in Proc. European Navigation Conf., Gdansk, Poland, 2012.
[31] R. Sabatini, L. RodríguezSalazar, A. Kaharkar, C. Bartel, and T. Shaid, "Satellite Navigation Data Processing for Attitude Determination and Control of Unmanned Air Vehicles,” in Proc. European Navigation Conf., Gdansk, Poland, 2012.
[32] R. Sabatini, C. Bartel, A. Kaharkar, T. Shaid, L. RodríguezSalazar, and D. Zammit-Mangion, "Low-Cost Navigation and Guidance Systems for Unmanned Aerial Vehicles – Part 2: Attitude Determination and Control,” Annual of Navigation, vol. 20, pp. 97-126, 2013.
[33] R. Sabatini, S. Ramasamy, A. Gardi, and L. RodríguezSalazar, "Lowcost Sensors Data Fusion for Small Size Unmanned Aerial Vehicles Navigation and Guidance,”International Journal of Unmanned Systems Engineering, vol. 1, no. 3, pp. 16-47, 2013.
[34] R. Sabatini, A. Kaharkar, C. Bartel, and T. Shaid, "Carrier-phase GNSS Attitude Determination and Control for Small UA Applications,”Journal of Aeronautics and Aerospace Engineering, vol. 2, no. 4, 2013.
[35] R. Sabatini, C. Bartel, A. Kaharkar, T. Shaid, and S. Ramasamy, "A Novel Low-cost Navigation and Guidance System for Small Unmanned Aircraft Applications,” in Proc. WASET International Conf. on Aeronautical and Astronautical Engineering (ICAAE 2013), Melbourne, Australia, 2013.
[36] ICAO - Annex 10 to the Convention on International Civil Aviation, "Aeronautical Telecommunications - Volume 1: Radio Navigation Aids,” Edition 6, July 2006.
[37] CAA Safety Regulation Group Paper 2003/09, "GPS Integrity and Potential Impact on Aviation Safety,” 2003.
[38] RMIT University, "Sky's the limit,”2013, Available online at: http://rmit.com.au/browse;ID=wcga2pa6sovqz.
[Accessed 9th April, 2014].
[39] R. Sabatini, T. Moore, and C. Hill, "A Novel GNSS Integrity Augmentation System for Civil and Military Aircraft,” International Journal of Mechanical, Industrial Science and Engineering, vol. 7, no. 12, pp. 1433-1449. International Science Index 84, 2013.
[40] R. Sabatini, T. Moore, and C. Hill, "A New Avionics Based GNSS Integrity Augmentation System: Part 2 – Integrity Flags,” Journal of Navigation, vol. 66, no. 4, pp. 511-522, 2013.
[41] R. Sabatini, T. Moore, and C. Hill, "A New Avionics Based GNSS Integrity Augmentation System: Part 1 – Fundamentals,” Journal of Navigation, vol. 66, no. 3, pp. 363-383, 2013.
[42] R. Sabatini, T. Moore, and C. Hill, "Avionics Based GNSS Integrity Augmentation for Mission- and Safety-Critical Applications,” in Proc. 25th International Technical Meeting of the Satellite Division of the Institute of Navigation: ION GNSS-2012, Nashville, Tennessee, September 2012.