3D Video Generation and Service Based on a TOF Depth Sensor in MPEG-4 Multimedia Framework

1. 3D Video Generation and Service Based on a TOF Depth Sensor in MPEG-4 Multimedia Framework IEEE Consumer Electronics Sung-YeolKim Ji-Ho Cho Andres Koschan Mongi A. Abidi

2. Outline • Introduction • Video-Plus-Depth Generation • System Architecture • Experimental Result • Conclusion

3. Introduction(1/2) • 3D video is recognized as an essential part of the next-generation multimedia application • Questions: • How can we stream 3D video contents • How can we obtain high-quality 3D video

4. Introduction(2/2) • The problems of depth images captured by TOF: • Optical noise • Unmatched boundaries • Lost depth data • Temporal depth flickering artifacts

5. Video-Plus-Depth • Outer Boundary Matching • Inner Optical Noise Minimization • Recovery of Lost Depth Data • Temporal Consistency

6. Outer Boundary Matching • Employ a closed form matting to find globally optimal alpha matte • Use alpha maps to compensate the depth image • Run a local iterative threshold selection

7. Inner Optical Noise Minimization

8. Recovery of Lost Depth Data • Detection of the lost depth dataregion • Recovery of the boundary • Estimation of the lost data(use quadratic Bazier curve to interpolate depth information)

9. Temporal Consistency • Using block matching to find motion vector • Motion image • Detect the stationary regions • Stationary image • Enhanced depth image

10. System Architecture

11. Experiment Result • Test sequences are obtained from a TOF depth sensor • Resolution of both sequences was 720*480

12. Experiment Result

13. Experiment Result

14. Experiment Result

15. Reconstruction of dynamic 3D scenes

16. Quality Evaluation

17. 3D video content played by an MPEG-4 player

18. Conclusion • Propose a new method to enhance depth images captured by a TOF depth sensor • Show the possibility of 3D video services based on video-plus-depth data in MPEG-4 multimedia framework