Image Denoising Using Tensor Product Complex Tight Framelets with Increasing Directionality

Abstract

Tensor product real-valued wavelets have been employed in many applications such as image processing with impressive performance. Though edge singularities are ubiquitous and play a fundamental role in two-dimensional problems, tensor product real-valued wavelets are known to be only sub-optimal since they can only capture edges well along the coordinate axis directions. The dual tree complex wavelet transform (DTCWT), proposed by Kingsbury [16] and further developed by Selesnick et al. [24], is one of the most popular and successful enhancements of the classical tensor product real-valued wavelets. The two-dimensional DTCWT is obtained via tensor product and offers improved directionality with 6 directions. In this paper we shall further enhance the performance of DTCWT for the problem of image denoising. Using framelet-based approach and the notion of discrete affine systems, we shall propose a family of tensor product complex tight framelets TPCTFn for all integers n>2 with increasing directionality, where n refers to the number of filters in the underlying one-dimensional complex tight framelet filter bank. For dimension two, such tensor product complex tight framelet TPCTFn offers (n-1)(n-3)/2+4 directions when n is odd, and (n-4)(n+2)/2+6 directions when n is even. In particular, TPCTF4, which is different to DTCWT in both nature and design, provides an alternative to DTCWT. Indeed, TPCTF4 behaves quite similar to DTCWT by offering 6 directions in dimension two, employing the tensor product structure, and enjoying slightly less redundancy than DTCWT. When TPCTF4 is applied to image denoising, its performance is comparable to DTCWT. Moreover, better results on image denoising can be obtained by using TPCTF6. Moreover, TPCTFn allows us to further improve DTCWT by using TPCTFn as the first stage filter bank in DTCWT.