김한솔 박사 Self-learning based joint multi image super-resolution and sub-pixel registration 논문 Digital Signal Processing 게재
2024.11.25 17:26
본 연구실 졸업생인 김한솔 박사가 연구한 “Self-learning based joint multi image super-resolution and sub-pixel registration” 제목의 논문이 Digital Signal Processing (Impact factor : 2.9, Rank : Q2)에 게재가 확정되었다. 본 연구는 김한솔 박사(1저자)와 동서대학교 정보통신공학과 이석호 교수(2저자), 강문기 교수(교신저자)가 진행하였다.
Abstract
Multi Image Super-resolution (MISR) refers to the task of enhancing the spatial resolution of a stack of lowresolution (LR) images representing the same scene. Although many deep learning-based single image superresolution (SISR) technologies have recently been developed, deep learning has not been widely exploited for
MISR, even though it can achieve higher reconstruction accuracy because more information can be extracted
from the stack of LR images. One of the primary obstacles encountered by deep networks when addressing the
MISR problem is the variability in the number of LR images that act as input to the network. This impedes the
feasibility of adopting an end-to-end learning approach, because the varying number of input images makes
it difficult to construct a training dataset for the network. Another challenge arises from the requirement to
align the LR input images to generate high-resolution (HR) image of high quality, which requires complex and
sophisticated methods.
In this paper, we propose a self-learning based method that can simultaneously perform super-resolution and
sub-pixel registration of multiple LR images. The proposed method trains a neural network with only the LR
images as input and without any true target HR images; i.e., the proposed method requires no extra training
dataset. Therefore, it is easy to use the proposed method to deal with different numbers of input images. To
our knowledge this is the first time that a neural network is trained using only LR images to perform a joint
MISR and sub-pixel registration. Experimental results confirmed that the HR images generated by the proposed
method achieved better results in both quantitative and qualitative evaluations than those generated by other
deep learning-based methods.