Accurate representation of local frequency using a computationally efficient Gabor filter fusion approach with application to image registration

Recently local frequency has been suggested as an efficient feature for performing image analysis and multi-modal image registration. While local frequency representation can detect the structure of the scene in the image (ridges and edges simultaneously), its computation typically requires using a bank of analytic filters such as two-dimensional (2-D) Gabor filters characterized by a set of parameters (spatial frequency, orientation angle and the filter bandwidth). Tuning a set of Gabor filters that can cover the entire frequency space for the given image is critical for obtaining an accurate representation of the local frequency; however, choosing the size of the filter bank is often done in an ad hoc manner and one usually errs on the conservative side by employing a larger than needed set of filters in order to cover the entire range of frequencies, thus sacrificing computational efficiency. In this paper, we propose a computationally efficient approach for developing the local frequency representation from given images. The new algorithm employs a filter bank of size four, whose parameters are adaptively selected based on the image content. Motivation for the new scheme comes from biological considerations and it is shown that an accurate local frequency representation can be developed from a fusion of the four Gabor filter outputs. Among the notable advantages of the proposed algorithm are reduction in computational requirements (which makes it ideal for the registration and fusion of large-format images) and its robustness to specific scene details.