Blur identification with assumption validation for sensor-based video reconstruction and its implementation on field programmable gate array

M.E. Angelopoulou; C.-S. Bouganis; P.Y.K. Cheung

Blur identification with assumption validation for sensor-based video reconstruction and its implementation on field programmable gate array

Access Full Text

Blur identification with assumption validation for sensor-based video reconstruction and its implementation on field programmable gate array

Author(s): M.E. Angelopoulou ; C.-S. Bouganis ; P.Y.K. Cheung
DOI: 10.1049/iet-cdt.2009.0053

For access to this article, please select a purchase option:

Buy article PDF

Buy Knowledge Pack

IET members benefit from discounts to all IET publications and free access to E&T Magazine. If you are an IET member, log in to your account and the discounts will automatically be applied.

Learn more about IET membership

Recommend Title Publication to library

IET Computers & Digital Techniques — Recommend this title to your library

Thank you

Your recommendation has been sent to your librarian.

Author(s): M.E. Angelopoulou ¹ ; C.-S. Bouganis ¹ ; P.Y.K. Cheung ¹
- Affiliations: 1: Department of Electrical and Electronic Engineering, Imperial College London, London, UK
Source: Volume 5, Issue 4, July 2011, p. 271 – 286
DOI: 10.1049/iet-cdt.2009.0053 , Print ISSN 1751-8601, Online ISSN 1751-861X

Published

Restoration methods, such as super-resolution (SR), largely depend on the accuracy of the point spread function (PSF). PSF estimation is an ill-posed problem, and a linear and uniform motion is often assumed. In real-life systems, this may deviate significantly from the actual motion, impairing subsequent restoration. To address the above, this work proposes a dynamically configurable imaging system that combines algorithmic video enhancement, field programmable gate array (FPGA)-based video processing and adaptive image sensor technology. Specifically, a joint blur identification and validation (BIV) scheme is proposed, which validates the initial linear and uniform motion assumption. For the cases that significantly deviate from that assumption, the real-time reconfiguration property of an adaptive image sensor is utilised, and the sensor is locally reconfigured to larger pixels that produce higher frame-rate samples with reduced blur. Results demonstrate that once the sensor reconfiguration gives rise to a valid motion assumption, highly accurate PSFs are estimated, resulting in improved SR reconstruction quality. To enable real-time reconstruction, an FPGA-based BIV architecture is proposed. The system's throughput is significantly higher than 25 fps, for frame sizes up to 1024 × 1024, and its performance is robust to noise for signal-to-noise ratio (SNR) as low as 20 dB.

References

1. 1)
  - M.E. Angelopoulou , C.-S. Bouganis , P.Y.K. Cheung , G.A. Constantinides . Robust real-time super-resolution on FPGA and an application to video enhancement. ACM Trans. Reconfig. Technol. Syst. , 4 , 22:1 - 22:29
2. 2)
  - Angelopoulou, M.E., Bouganis, C.-S., Cheung, P.Y.K.: `Video enhancement on an adaptive image sensor', Proc. IEEE Int. Conf. on Image Processing (ICIP), October 2008, San Diego, California, USA, p. 681–684.
3. 3)
  - Y. Yitzhaky , N.S. Kopeika . Identification of blur parameters from motion blurred images. Graph. Models Image Process. , 5 , 310 - 320
4. 4)
  - S. Farsiu , D. Robinson , M. Elad , P. Milanfar . Advances and challenges in super-resolution. Int. J. Imag. Syst. Technol. , 2 , 47 - 57
5. 5)
  - Farrell, J., Xiao, F., Kavusi, S.: `Resolution and light sensitivity tradeoff with pixel size', Proc. SPIE Electronic Imaging, February 2006, San Jose, CA, USA, p. 211–218, vol. 6069.
6. 6)
  - Chen, T., Catrysse, P., Gamal, A.E., Wandell, B.: `How small should pixel size be?', Proc. SPIE Sensors and Camera Systems for Scientific, Industrial and Digital Photography Applications, January 2000, p. 451–459, Vol. 3965.
7. 7)
  - Xilinx, Inc., San Jose: http://www.xilinx.com, June 2009.
8. 8)
  - A. Tekalp , H. Kaufman , J. Woods . Identification of image and blur parameters for the restoration of noncausal blurs. IEEE Trans. Acoust. Speech Signal Process. , 4 , 963 - 972
9. 9)
  - H. Stark , P. Oskoui . High-resolution image recovery from image-plane arrays, using convex projections. J. Opt. Soc. Am. A , 11 , 1715 - 1726
10. 10)
  - Welch, G., Bishop, G.: ‘An introduction to the Kalman filter’, http://www.cs.unc.edu/welch/media/pdf/kalman_intro.pdf, 2006.
11. 11)
  - T. Fawcett . An introduction to ROC analysis. Pattern Recogn. Lett. , 8 , 861 - 874
12. 12)
  - H. Tian , B. Fowler , A.E. Gamal . Analysis of temporal noise in CMOS photodiode active pixel sensor. IEEE J. Solid-State Circuits , 1 , 92 - 101
13. 13)
  - A. Stern , Y. Porat , A. Ben-Dor , N.S. Kopeika . Enhanced-resolution image restoration from a sequence of low-frequency vibrated images by use of convex projections. Appl. Opt. , 26 , 4706 - 4715
14. 14)
  - A.E. Gamal , H. Eltoukhy . CMOS image sensors. IEEE Circuits Devices Mag. , 3 , 6 - 20
15. 15)
  - M. Cannon . Blind deconvolution of spatially invariant image blurs with phase. IEEE Trans. Acoust. Speech Signal Process. , 1 , 58 - 63
16. 16)
  - J.S. Lim . (1990) Two-dimensional signal and image processing.
17. 17)
  - Celoxica: http://www.celoxica.com, June 2009.
18. 18)
  - J.-Y. Bouguet . (2002) Pyramidal implementation of the Lucas Kanade feature tracker: description of the algorithm.
19. 19)
  - Foveon, Inc.: ‘Foveon X3 image sensor’, www.foveon.com, June 2009.
20. 20)
  - D. Kundur , D. Hatzinakos . Blind image deconvolution. IEEE Signal Process. Mag. , 3 , 43 - 64
21. 21)
  - Constandinou, T.G., Degenaar, P., Toumazou, C.: `An adaptable foveating vision chip', Proc. IEEE Int. Symp. on Circuits and Systems (ISCAS), May 2006, Island of Kos, Greece, p. 3566–3569.
22. 22)
  - M. Ben-Ezra , S.K. Nayar . Motion-based motion deblurring. IEEE Trans. Pattern Anal. Mach. Intell. , 6 , 689 - 698
23. 23)
  - M.M. Chang , A.M. Tekalp , A.T. Erdem . Blur identification using the bispectrum. IEEE Trans. Signal Process. , 10 , 2323 - 2325
24. 24)
  - L. Chen , K.-H. Yap . Efficient discrete spatial techniques for blur support identification in blind image deconvolution. IEEE Trans. Signal Process. , 4 , 1557 - 1562
25. 25)
  - M. Irani , S. Peleg . Improving resolution by image registration. CVGIP Graph Models Image Process. , 3 , 231 - 239
26. 26)
  - M.E. Moghaddam , M. Jamzad . Motion blur identification in noisy images using mathematical models and statistical measures. Pattern Recogn. , 7 , 1946 - 1957
27. 27)
  - Liu, Y., Bouganis, C.-S., Cheung, P.Y.K.: `Efficient mapping of a Kalman filter into an FPGA using Taylor expansion', Proc. Int. Conf. on Field Programmable Logic and Applications (FPL), August 2007, Amsterdam, Netherlands, p. 345–350.
28. 28)
  - Shi, J., Tomasi, C.: `Good features to track', Proc. IEEE Conf. on Computer Vision and Pattern Recognition (CVPR), June 1994, Washington, DC, USA, p. 593–600.

Login

Not registered yet?

Share

Tools

Login to add to favourites

Key

Blur identification with assumption validation for sensor-based video reconstruction and its implementation on field programmable gate array

Blur identification with assumption validation for sensor-based video reconstruction and its implementation on field programmable gate array

Buy article PDF

Buy Knowledge Pack

Thank you

References

Related content