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Abstract

The Hough transform (HT) is a fundamental tool across various domains, from classical image analysis to neural networks and tomography. Two key aspects of the algorithms for computing the HT are their computational complexity and accuracy - the latter often defined as the error of approximation of continuous lines by discrete ones within the image region. The fast HT (FHT) algorithms with optimal linearithmic complexity - such as the Brady-Yong algorithm for power-of-two-sized images - are well established. Generalizations like $FHT2DT$ extend this efficiency to arbitrary image sizes, but with reduced accuracy that worsens with scale. Conversely, accurate HT algorithms achieve constant-bounded error but require near-cubic computational cost. This paper introduces $FHT2SP$ algorithm - a fast and highly accurate HT algorithm. It builds on our development of Brady's superpixel concept, extending it to arbitrary shapes beyond the original power-of-two square constraint, and integrates it into the $FHT2DT$ algorithm. With an appropriate choice of the superpixel's size, for an image of shape $w \times h$, the $FHT2SP$ algorithm achieves near-optimal computational complexity $\mathcal{O}(wh \ln^3 w)$, while keeping the approximation error bounded by a constant independent of image size, and controllable via a meta-parameter. We provide theoretical and experimental analyses of the algorithm's complexity and accuracy.