Journal
JOURNAL OF REAL-TIME IMAGE PROCESSING
Volume 19, Issue 5, Pages 893-910Publisher
SPRINGER HEIDELBERG
DOI: 10.1007/s11554-022-01230-2
Keywords
Acceleration; Light-field; GPU; Super-resolution; OpenCL; Optimization
Categories
Funding
- Projekt DEAL
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This paper proposes a GPU-accelerated computational framework for reconstructing high-resolution light-field images under mixed noise conditions. The framework combines a joint data fidelity term and weighted non-local total variation approach for regularization. Experimental results demonstrate that the proposed approach achieves better reconstruction quality and overcomes the limitations of previous work in handling large-scale tasks.
Light-field (LF) super-resolution (SR) plays an essential role in alleviating the current technology challenge in the acquisition of a 4D LF, which assembles both high-density angular and spatial information. Due to the algorithm complexity and data-intensive property of LF images, LFSR demands a significant computational effort and results in a long CPU processing time. This paper presents a GPU-accelerated computational framework for reconstructing high-resolution (HR) LF images under a mixed Gaussian-Impulse noise condition. The main focus is on developing a high-performance approach considering processing speed and reconstruction quality. From a statistical perspective, we derive a joint l(1)-l(2) data fidelity term for penalizing the HR reconstruction error taking into account the mixed noise situation. For regularization, we employ the weighted non-local total variation approach, which allows us to effectively realize LF image prior through a proper weighting scheme. We show that the alternating direction method of the multipliers algorithm (ADMM) can be used to simplify the computation complexity and results in a high-performance parallel computation on the GPU Platform. An extensive experiment is conducted on both synthetic 4D LF dataset and natural image dataset to validate the proposed SR model's robustness and evaluate the accelerated optimizer's performance. The experimental results show that our approach achieves better reconstruction quality under severe mixed-noise conditions as compared to the state-of-the-art approaches. In addition, the proposed approach overcomes the limitation of the previous work in handling large-scale SR tasks. While fitting within a single off-the-shelf GPU, the proposed accelerator provides an average speedup of 2.46x and 1.57x for x2 and x3 SR tasks, respectively. In addition, a speedup of 77x is achieved as compared to CPU execution.
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