Abstract
In this paper, we propose a multi-frame depth super-resolution (SR) method based on L 1 data fidelity with the total variation regularization (TV-L 1 ) model. The majority of time-of-flight (ToF) sensors exhibit limited spatial resolution compared to RGB sensors and the improvement of the depth image resolution is an inherently ill-posed problem. To overcome this under-determined problem, the solution space is limited by the regularization term through prior knowledge and the data fidelity term using statistical information of the noise. Firstly, the statistical characteristics of ToF depth images are analyzed to specify the appropriate observation model. Thereafter, the objective function for multi-frame depth SR based on the TV-L 1 model is designed by considering the prior knowledge of the depth images. This approach enables the sharpness of the edges to be preserved and the noise amplification to be suppressed simultaneously. Furthermore, an efficient solver based on half-quadratic splitting is proposed. The algorithm minimizes the objective function for the multi-frame SR problem consisting of the TV regularization term and L 1 data fidelity term. The proposed method is verified on a synthetic dataset and real-world data acquired from a ToF sensor. The experimental results demonstrate that the proposed method can substantially reconstruct high-resolution depth images in terms of preserving sharp depth discontinuities, without any obvious artifacts, and can increase robustness to noise.
Highlights
Accurate depth measurement is an essential requirement in image processing and computer vision
We propose a method based on the L1 data fidelity with the total variation (TV) regularization (TV-L1) model to overcome the limitations of other methods in terms of preserving the sharp depth discontinuities and suppressing the noise amplification
Thereafter, we introduce an image restoration algorithm based on the TV-L1 approach
Summary
Accurate depth (distance) measurement is an essential requirement in image processing and computer vision. The demand for accurate depth information has increased in numerous applications, such as image enhancement [1], virtual reality [2], robotics [3], and autonomous driving [4]. Face recognition technology that utilizes depth information [5] has been adopted in traditional business models to provide access control in various fields (e.g., finance systems or identity verification). The significance of depth images is rapidly increasing, several artifacts are still frequently observed. Devices suffer from interferences between waves during depth measurements. Depth images exhibit the additional problem of low quality because the depth measurement requires high costs in terms of complexity or hardware implementation
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