A Bio-Inspired Navigation Strategy Fused Polarized Skylight and Starlight for Unmanned Aerial Vehicles

The migratory animals are capable of traveling long distances by fusing varied information, such as the halteres, the star positions, and the polarization pattern. Motivated by the navigation strategy of migratory animals, a bio-inspired navigation strategy based on polarized skylight, starlight, and halteres is presented in this paper. To enhance the environmental adaptability of the polarization navigation system, a sun vector calculation method tightly fusing the degree of polarization (DoP) and the azimuth of polarization (e-vector) is proposed. By setting the threshold of DoP values of the observation points, the DoP and the e-vector within the threshold range can be selected to deduce the sun position. As such, the robustness and reliability of the sun position can be improved. Concerned with the issue of attitude and heading determination in GNSS-challenged conditions, an integrated navigation strategy combined with polarized light and starlight is proposed. In addition, a Kalman filter is adopted to fuse the navigation data of polarized light, starlight, and inertial sensors. Finally, simulations are conducted to validate the performance of the integrated model. The results illustrated that the proposed navigation strategy is capable of determining the attitude and heading in the scenarios of which the Global Navigation Satellite System (GNSS) is disturbed.

[1]  Jinkui Chu,et al.  Integrated Polarization Dependent Photodetector and Its Application for Polarization Navigation , 2014, IEEE Photonics Technology Letters.

[2]  Xiaofeng He,et al.  Performance improvement of visual-inertial navigation system by using polarized light compass , 2016, Ind. Robot.

[3]  S. Emlen The stellar-orientation system of a migratory bird. , 1975, Scientific American.

[4]  Jiancheng Fang,et al.  INS/CNS/GNSS Integrated navigation technology , 2015 .

[5]  Naser El-Sheimy,et al.  Low-Cost MEMS-Based Pedestrian Navigation Technique for GPS-Denied Areas , 2013, J. Sensors.

[6]  W. Wiltschko,et al.  Magnetic orientation in birds , 1996, The Journal of experimental biology.

[7]  Yuehai Wang,et al.  Multiple Disturbance Analysis and Calibration of an Inspired Polarization Sensor , 2019, IEEE Access.

[8]  Jinkui Chu,et al.  Integrated navigation system for UAVs based on the sensor of polarization , 2016, 2016 IEEE International Conference on Mechatronics and Automation.

[9]  Lu Wang,et al.  A novel autonomous real-time position method based on polarized light and geomagnetic field , 2015, Scientific Reports.

[10]  Lei Guo,et al.  A Bionic Polarization Navigation Sensor Based on Polarizing Beam Splitter , 2018, IEEE Access.

[11]  Liang Zhang,et al.  Flight strategy optimization for high-altitude long-endurance solar-powered aircraft based on Gauss pseudo-spectral method , 2019, Chinese Journal of Aeronautics.

[12]  Gábor Horváth,et al.  Polarized Light and Polarization Vision in Animal Sciences , 2014, Springer Series in Vision Research.

[13]  Jinkui Chu,et al.  A Novel Attitude Determination System Aided by Polarization Sensor , 2018, Sensors.

[14]  Xiaofeng He,et al.  Polarized Light Compass-Aided Visual-Inertial Navigation Under Foliage Environment , 2017, IEEE Sensors Journal.

[15]  Hiroshi Kobayashi,et al.  An Autonomous Agent Navigating with a Polarized Light Compass , 1997, Adapt. Behav..

[16]  Z. M. Gizatullin,et al.  Physical modeling of electromagnetic interference in unmanned aerial vehicle under action of indirect lightning strike , 2017, 2017 Dynamics of Systems, Mechanisms and Machines (Dynamics).

[17]  George T. Schmidt,et al.  Navigation sensors and systems in GNSS degraded and denied environments , 2015 .

[18]  Xin Liu,et al.  Method and Implementation of a Bioinspired Polarization-Based Attitude and Heading Reference System by Integration of Polarization Compass and Inertial Sensors , 2020, IEEE Transactions on Industrial Electronics.

[19]  F. Moore,et al.  Calibration of the sun compass by sunset polarized light patterns in a migratory bird , 1992, Behavioral Ecology and Sociobiology.

[20]  Jinliang Zhang,et al.  SINS/CNS integration algorithm and simulations for extended time flights using linearized Kalman filtering , 2015, 2015 IEEE International Conference on Communication Software and Networks (ICCSN).

[21]  J. Chahl,et al.  Biomimetic Attitude and Orientation Sensors , 2012, IEEE Sensors Journal.

[22]  David Wettergreen,et al.  Star tracker celestial localization system for a lunar rover , 2007, 2007 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[23]  P. Berthold Genetic control of migratory behaviour in birds. , 1991, Trends in ecology & evolution.

[24]  R. Pfeifer,et al.  A mobile robot employing insect strategies for navigation , 2000, Robotics Auton. Syst..

[25]  Rogelio Lozano,et al.  A Vision and GPS-Based Real-Time Trajectory Planning for a MAV in Unknown and Low-Sunlight Environments , 2014, J. Intell. Robotic Syst..

[26]  Wei Huang,et al.  Research on the airborne SINS/CNS integrated navigation system assisted by BD navigation system , 2016, Selected Proceedings from CSOE.

[27]  Sven Behnke,et al.  Autonomous Navigation for Micro Aerial Vehicles in Complex GNSS-denied Environments , 2016, J. Intell. Robotic Syst..

[28]  Masayoshi Tomizuka,et al.  Novel hybrid of strong tracking Kalman filter and wavelet neural network for GPS/INS during GPS outages , 2013 .

[29]  Liu Yingying,et al.  Measuring solar vector with polarization sensors based on polarization pattern , 2017 .

[30]  Zheng You,et al.  Real-time polarization imaging algorithm for camera-based polarization navigation sensors. , 2017, Applied optics.

[31]  Stéphane Viollet,et al.  AntBot: A six-legged walking robot able to home like desert ants in outdoor environments , 2019, Science Robotics.