Rotation center identification based on geometric relationships for rotary motion deblurring
This work addresses a specific bottleneck in image deblurring for assembled imaging systems, offering an incremental improvement over existing methods.
The paper tackles the problem of accurately identifying the rotation center for non-blind rotary motion deblurring, which is crucial for recovering clear images from blurred ones, and demonstrates that their geometric-based method achieves less than 1-pixel error along a single axis, improving deblurring results.
Non-blind rotary motion deblurring (RMD) aims to recover the latent clear image from a rotary motion blurred (RMB) image. The rotation center is a crucial input parameter in non-blind RMD methods. Existing methods directly estimate the rotation center from the RMB image. However they always suffer significant errors, and the performance of RMD is limited. For the assembled imaging systems, the position of the rotation center remains fixed. Leveraging this prior knowledge, we propose a geometric-based method for rotation center identification and analyze its error range. Furthermore, we construct a RMB imaging system. The experiment demonstrates that our method achieves less than 1-pixel error along a single axis (x-axis or y-axis). We utilize the constructed imaging system to capture real RMB images, and experimental results show that our method can help existing RMD approaches yield better RMD images.