A target-free calibration method for automotive augmented reality head-up displays

In this paper, we introduce a newly developed target-free calibration method for automotive augmented reality head-up displays (AR-HUDs), which can be performed fully automatically using a smartphone camera. Our method requires no calibration target to be set up in front of the vehicle. Instead, it utilizes feature points of the environment, which makes it robust against misplaced targets and allows for an easy deployment, i.e. in garages. Under the pinhole model assumption, we decouple the perspective projection matrix into three parts: intrinsic matrix, relative pose between the vehicle’s 3D sensor and the smartphone camera, and then rotation between the camera space and the HUD field of view (HUD-FOV). Based on the epipolar constraint, we acquire the relative pose. The determination of intrinsic and rotation matrices is also accomplished without any pre-designed calibration target. The calibration itself takes less than 5 minutes for an eye box with 9 different training viewpoints. With our new approach, we achieve a competitive average reprojection error of 6.7 mm at a distance of 7.5 m, which is comparable to the previous work that applied targets.

[1]  Haruhiko Okumura Human Centric AR&VR Display and Interface Technologies for Automobile , 2019, IEEE Consumer Electron. Mag..

[2]  Marc Necker,et al.  A Calibration Method For Automotive Augmented Reality Head-Up Displays Based On A Consumer-Grade Mono-Camera , 2019, 2019 IEEE International Conference on Image Processing (ICIP).

[3]  Harald Wuest,et al.  A camera-based calibration for automotive augmented reality Head-Up-Displays , 2013, 2013 IEEE International Symposium on Mixed and Augmented Reality (ISMAR).

[4]  Alois Ferscha,et al.  A New Visualization Concept for Navigation Systems , 2004, User Interfaces for All.

[5]  Gerhard Rigoll,et al.  Contact-analog information representation in an automotive head-up display , 2008, ETRA '08.

[6]  Xubo Yang,et al.  A Calibration Method for On-Vehicle AR-HUD System Using Mixed Reality Glasses , 2018, 2018 IEEE Conference on Virtual Reality and 3D User Interfaces (VR).

[7]  Marc Necker,et al.  A calibration method for automotive augmented reality head-up displays using a chessboard and warping maps , 2020, International Conference on Machine Vision.

[8]  Marc Necker,et al.  A low-complexity yet accurate calibration method for automotive augmented reality head-up displays , 2021, International Conference on Machine Vision.

[9]  Yuichi Ohta,et al.  VISUAL NAVIGATION SYSTEM ON WINDSHIELD HEAD-UP DISPLAY , 2006 .

[10]  S N Roscoe,et al.  Eye accommodation to head-up virtual images. , 1988, Human factors.

[11]  G LoweDavid,et al.  Distinctive Image Features from Scale-Invariant Keypoints , 2004 .

[12]  Karlheinz Blankenbach Requirements and System Aspects of AR-Head-Up Displays , 2019, IEEE Consumer Electronics Magazine.

[13]  Mainak Biswas,et al.  47.3: Invited Paper: World Fixed Augmented‐Reality HUD for Smart Notifications , 2015 .