Polarization-coded material classification in automotive LIDAR aiming at safer autonomous driving implementations.

LIDAR sensors are one of the key enabling technologies for the wide acceptance of autonomous driving implementations. Target identification is a requisite in image processing, informing decision making in complex scenarios. The polarization from the backscattered signal provides an unambiguous signature for common metallic car paints and can serve as one-point measurement for target classification. This provides additional redundant information for sensor fusion and greatly alleviates hardware requirements for intensive morphological image processing. Industry decision makers should consider polarization-coded LIDAR implementations. Governmental policy makers should consider maximizing the potential for polarization-coded material classification by enforcing appropriate regulatory legislation. Both initiatives will contribute to faster (safer, cheaper, and more widely available) advanced driver-assistance systems and autonomous functions. Polarization-coded material classification in automotive applications stems from the characteristic signature of the source of LIDAR backscattering: specular components preserve the degree of polarization while diffuse contributions are predominantly depolarizing.

[1]  Jeffrey P. Thayer,et al.  Ranging through Shallow Semitransparent Media with Polarization Lidar , 2014 .

[2]  C. Guérin,et al.  A critical survey of approximate scattering wave theories from random rough surfaces , 2004 .

[3]  Rob A. Zuidwijk,et al.  Planning of Truck Platoons: A Literature Review and Directions for Future Research , 2017 .

[4]  James H. Churnside,et al.  Airborne lidar for fisheries applications , 2001 .

[5]  Jacob Holden,et al.  Potentials for Platooning in U.S. Highway Freight Transport , 2017 .

[6]  Bryan M. Williams,et al.  Non-destructive analysis of flake properties in automotive paints with full-field optical coherence tomography and 3D segmentation. , 2017, Optics express.

[7]  Thomas A. Germer,et al.  Modeling the appearance of special effect pigment coatings , 2001, Optics + Photonics.

[8]  Songxin Tan,et al.  Design and performance of a multiwavelength airborne polarimetric lidar for vegetation remote sensing. , 2004, Applied optics.

[9]  Jose M Sasian,et al.  Depolarization of diffusely reflecting man-made objects. , 2005, Applied optics.

[10]  Gary D. Sharp,et al.  54.2: Invited Paper: High Efficiency Polarization Preserving Cinema Projection Screens , 2013 .

[11]  Brent Schwarz,et al.  LIDAR: Mapping the world in 3D , 2010 .

[12]  J Scott Tyo,et al.  Review of passive imaging polarimetry for remote sensing applications. , 2006, Applied optics.

[13]  E. Kirchner,et al.  Measuring flake orientation for metallic coatings , 2009 .

[14]  T. Vorburger,et al.  Regimes of surface roughness measurable with light scattering. , 1993, Applied optics.

[15]  Dennis H. Goldstein Polarization measurements of automobile paints , 2008, SPIE Defense + Commercial Sensing.

[16]  D. Winker,et al.  Overview of the CALIPSO Mission and CALIOP Data Processing Algorithms , 2009 .

[17]  Philip W. Dabney,et al.  Remote sensing of the Earth's surface with an airborne polarized laser , 1993, IEEE Trans. Geosci. Remote. Sens..

[18]  David San Segundo Bello,et al.  Integrated Polarization Analyzing CMOS Image Sensor for Material Classification , 2011, IEEE Sensors Journal.

[19]  Nathan Seldomridge,et al.  Polarization lidar measurements of honey bees in flight for locating land mines. , 2005, Optics express.

[20]  F. Maile,et al.  Effect pigments—past, present and future , 2005 .

[21]  S. Tominaga,et al.  Polarization imaging for material classification , 2008 .

[22]  J. E. Harvey,et al.  Modeling of light scattering in different regimes of surface roughness. , 2011, Optics express.

[23]  J S Tyo,et al.  Target detection in optically scattering media by polarization-difference imaging. , 1996, Applied optics.

[24]  Kozo Saito,et al.  Evolution of the Automotive Body Coating Process—A Review , 2016 .

[25]  E. Marx,et al.  Optical reflectance of metallic coatings: Effect of aluminum flake orientation , 2002 .

[26]  Viktor Gruev,et al.  Bioinspired polarization imager with high dynamic range , 2018, Optica.

[27]  K. Sassen The Polarization Lidar Technique for Cloud Research: A Review and Current Assessment , 1991 .

[28]  Mukul Sarkar,et al.  Depth Resolution Enhancement in Time-of-Flight Cameras Using Polarization State of the Reflected Light , 2019, IEEE Transactions on Instrumentation and Measurement.

[29]  Kwan H. Lee,et al.  A Reflectance Model for Metallic Paints Using a Two-Layer Structure Surface with Microfacet Distributions , 2010, IEICE Trans. Inf. Syst..

[30]  M. Marciniak,et al.  Comparison of microfacet BRDF model to modified Beckmann-Kirchhoff BRDF model for rough and smooth surfaces. , 2015, Optics Express.