Byung Cheol Song Shin- Cheol Jeong Yanglim Choi

1. Video Super-Resolution Algorithm Using Bi-directional Overlapped Block Motion Compensation ByungCheol Song Shin-CheolJeong Yanglim Choi IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS FOR VIDEO TECHNOLOGY, VOL. 21, NO. 3, MARCH 2011

2. outline • Introduction • Motion-compensated SR • Basic concept • Hierarchical motion estimation • Bi-directional OBMC • Result • Learning-based SR • Hybrid super-resolution • Experimental Results

3. Introduction • For the last few decades, many image interpolation algorithms have been developed to display high quality scaled images on cutting-edge digital consumer application such as HDTV,DSC. • Traditional interpolation methods usually suffer from several types of visual degradation. • To overcome the problem, many algorithms are proposed. But there are many problem.(Ex. structurally weak against textures, computational complexity)

4. Introduction • Brandi et al. presented an interesting SR approach. • They defined the so-called key frames (KF) that sparsely exist in a video sequence and have HR resolution. The remaining frames in the video sequence, i.e., non-key frames(NKF) had LR resolution • Brandi et al. took advantage of the fact that few KF (encoded at HR) may provide enough HF information to the up-scale NKF (encoded at LR) • However, it rarely found true motion information because it made use of the conventional full-search motion estimation. • This paper presents a hybrid SR algorithm where each LR patch is adaptively selected between a temporally super-resolved patch and a spatially super-resolved patch using adjacent HR KFs. • Temporally super-resolved patch  MSR • Spatially super-resolved patch  LSR

5. Motion-compensated SR Basic concept • A target frame in LR video sequence is interpolated by using forward and backward HRkey-frame(KF). • The KF interval N can be constant or variable. • These paper employ cubic convolution for Up-Scaling.

6. Motion-compensated SR Hierarchical motion estimation • First, the MV for overlapping M×Mmatching block is searched by using a rate-constrained ME. • The conventional rate-constrained ME find the best v for each matching block by minimizing the rate as well as distortion • In order to maximize the ME performance andto concurrently reduce the computational burden, we adopt arate-constrained fast full search algorithm presented in [15]. λ : Lagrange multipier

7. Motion-compensated SR Bi-directional OBMC • Assume that MVsbetween up-scaled LR frames are statistically very similar to those between corresponding HR frame. • Replace the unknown MVs for HR frames with the MVs obtains from the up-scaled LR frames. • Employ BOBMC based on bi-directional MVs .the BOBMC is performed on a 4×4block basis. • Each MV may be a forward or backward MV. The direction is determined according to SAD

8. Motion-compensated SR Result Fan’s [12] Brandi’s [14] original MSR

9. Motion-compensated SR Drawback • It cannot often provide acceptable visual quality due to non-translational motion, occlusion, inaccurate motion estimation and limited motion search range. • When such temporal motion compensation does not work well, we employ a learning-based SR in order to avoid the degradation of visual quality.

10. Learning-based SR • On-the-fly learning stage • Construct a trained dictionary using adjacent LR KFs and HR KFs. • Inference stage • The best-matched patch for the is exhaustively searched from the dictionary.(the patch having minimum SAD is chosen as best-match) • Produce a spatially super-resolved HR patch from Seek optimal K-means clustering Produce Laplacian patch Optimal dictionary LMS algorithm

11. Compare MSR & LSR MSR LSR Background is well- motion-compensated Better Quality Seldom be well- motion-compensated

12. Hybrid super-resolution • The boundary between the temporally super-resolved patches and spatially super-resolved patches, we can observe blocking artifact because they are derived from different frames. • We apply a simple smoothing filter to the boundary pixels

13. Experimental Results • PSNR performance of the MSR according to N Without/with little global motion  N seldom affects With large global motion

14. Experimental Results BLI Bi-cubic NEDI[1] Fan’s[12] Barsiu’s N = 30 M =16 L = 4 Search range =±64 MSR Hybrid SR Brandi’s[14] [1] X. Li and M. T. Orchard, “New edge-directed interpolation,” IEEE Trans. Image Process., vol. 10, no. 10, pp. 1521–1527, Oct. 2001. [12] W. Fan and D. Y. Yeung, “Image hallucination using neighbor embedding over visual primitive manifolds,” in Proc. CVPR, 2007, pp. 1–7. [14] F. Brandi, R. Queiroz, and D. Mukherjee, “Super-resolution of video using key frames and motion estimation,” in Proc. IEEE ICIP, Oct.2008, pp. 321–324.

15. Experimental Results N = 30 M =16 L = 4 Search range =±64

16. Experimental Results N = 30 M =16 L = 4 Search range =±64