LNIFT: Locally Normalized Image for Rotation Invariant Multimodal Feature Matching

Severe nonlinear radiation distortion (NRD) is the bottleneck problem of multimodal image matching. Although many efforts have been made in the past few years, such as the radiation-variation insensitive feature transform (RIFT) and the histogram of orientated phase congruency (HOPC), almost all these methods are based on frequency-domain information that suffers from high computational overhead and memory footprint. In this article, we propose a simple but very effective multimodal feature matching algorithm in the spatial domain, called locally normalized image feature transform (LNIFT). We first propose a local normalization filter to convert original images into normalized images for feature detection and description, which largely reduces the NRD between multimodal images. We demonstrate that normalized matching pairs have a much larger correlation coefficient than the original ones. We then detect oriented FAST and rotated brief (ORB) keypoints on the normalized images and use an adaptive nonmaximal suppression (ANMS) strategy to improve the distribution of keypoints. We also describe keypoints on the normalized images based on a histogram of oriented gradient (HOG), such as a descriptor. Our LNIFT achieves rotation invariance the same as ORB without any additional computational overhead. Thus, LNIFT can be performed in near real-time on images with 1024 $\times 1024$ pixels (only costs 0.32 s with 2500 keypoints). Four multimodal image datasets with a total of 4000 matching pairs are used for comprehensive evaluations, including synthetic aperture radar (SAR)–optical, infrared–optical, and depth–optical datasets. Experimental results show that LNIFT is far superior to RIFT in terms of efficiency (0.49 s versus 47.8 s on a $1024 \times 1024$ image), success rate (99.9% versus 79.85%), and number of correct matches (309 versus 119). The source code and datasets will be publicly available at https://ljy-rs.github.io/web .