Viewing Distance-Based Perceived Error Control for Local Backlight Dimming

This paper presents an effective local dimming algorithm that preserves the perceived image quality consistently in the backlight dimmed images regardless of viewing distances. The proposed algorithm determines the clipped points of each LED block by limiting the maximum size of image area to be distorted, and guarantying the minimum image quality in terms of the peak signal-to-noise ratio. It also preserves the perceived image quality of the dimmed images by adjusting the size of area to be distorted depending on the viewing distances of users. Simulation results show that the proposed method improves the average PSNR and the average SSIM values of the dimmed images by 4.19-13.21 dB and 0.002-0.004, compared with the benchmark methods, for viewing distances of 2.5-6.5 m, respectively. The proposed method also maintains the image quality of the dimmed images regardless of the image's characteristics, compared with the benchmark methods. In addition, it is confirmed that the proposed method achieves the higher power savings as the viewing distance increases. At the viewing distance of 6.5 m, although the image quality of the dimmed images are higher than that of the benchmark methods, the proposed method consumes 0.56% less power.

[1]  Paul R. Cohen,et al.  Camera Calibration with Distortion Models and Accuracy Evaluation , 1992, IEEE Trans. Pattern Anal. Mach. Intell..

[2]  Hyunsuk Cho,et al.  A color local dimming algorithm for liquid crystals displays using color light emitting diode backlight systems , 2013 .

[3]  Suk-Ju Kang,et al.  SSIM Preservation-Based Backlight Dimming , 2014, Journal of Display Technology.

[4]  Jiang-Hong Han,et al.  Dynamic Backlight Adaptation Based on the Details of Image for Liquid Crystal Displays , 2012, Journal of Display Technology.

[5]  Naehyuck Chang,et al.  DLS: dynamic backlight luminance scaling of liquid crystal display , 2004, IEEE Transactions on Very Large Scale Integration (VLSI) Systems.

[6]  Chung-Hao Tien,et al.  Design and Evaluation of Light Spread Function for Area-Adaptive LCD System , 2009 .

[7]  Xiaolin Wu,et al.  Modeling Power-Constrained Optimal Backlight Dimming for Color Displays , 2013, Journal of Display Technology.

[8]  Jari Korhonen,et al.  Block-Based Gradient Descent for Local Backlight Dimming and Flicker Reduction , 2014, Journal of Display Technology.

[9]  Young Hwan Kim,et al.  Viewing Distance-Aware Backlight Dimming of Liquid Crystal Displays , 2014, Journal of Display Technology.

[10]  Stefano Mattoccia,et al.  A Compact 3D Camera Suited for Mobile and Embedded Vision Applications , 2014, 2014 IEEE Conference on Computer Vision and Pattern Recognition Workshops.

[11]  Paul A. Viola,et al.  Rapid object detection using a boosted cascade of simple features , 2001, Proceedings of the 2001 IEEE Computer Society Conference on Computer Vision and Pattern Recognition. CVPR 2001.

[12]  Gaurav Sharma Digital Color Imaging Handbook , 2002 .

[13]  Baining Guo,et al.  Pocket reflectometry , 2011, SIGGRAPH 2011.

[14]  Young Hwan Kim,et al.  Multi-Histogram-Based Backlight Dimming for Low Power Liquid Crystal Displays , 2011, Journal of Display Technology.

[15]  Ming-Hwa Sheu,et al.  High-Performance Local Dimming Algorithm and Its Hardware Implementation for LCD Backlight , 2013, Journal of Display Technology.

[16]  Zhou Wang,et al.  Multi-scale structural similarity for image quality assessment , 2003 .

[17]  Wolfgang Heidrich,et al.  HDR-VDP-2: a calibrated visual metric for visibility and quality predictions in all luminance conditions , 2011, SIGGRAPH 2011.

[18]  Yu-Kuo Cheng,et al.  Design and Evaluation of Light Spread Function for Area-Adaptive LCD System , 2009, Journal of Display Technology.