In this work, a general framework for computing accurate quaternion color moments and their corresponding invariants is proposed. The proposed unified scheme arose by studying the characteristics of different orthogonal polynomials. These polynomials are used as kernels in order to form moments, the invariants of which can easily be derived. The resulted scheme permits the usage of any polynomial-like kernel in a unified and consistent way. The resulted moments and moment invariants demonstrate robustness to noisy conditions and high discriminative power. Additionally, in the case of continuous moments, accurate computations take place to avoid approximation errors. Based on this general methodology, the quaternion Tchebichef, Krawtchouk, Dual Hahn, Legendre, Orthogonal Fourier-Mellin, Pseudo Zernike and Zernike color moments and their corresponding invariants are introduced. A selected paradigm presents the reconstruction capability of each moment family, while proper classification scenarios evaluate the performance of color moment invariants.
E.G. Karakasis, G.A. Papakostas, D.E. Koulouriotis and V.D. Tourassis, “A Unified Methodology for Computing Accurate Quaternion Color Moments and Moment Invariants”, IEEE Transactions on Image Processing, vol. 23, no. 2, pp. 596-611, 2014.