The sequel focuses on the robustness properties of fractionally-spaced CMA. Though the literature contains reasonable treatment for CMA's robustness properties to violation of three of the four perfect equalization assumptions, essentially no analytical work exists for the undeniably practical case when the equalizer length is less than that needed for perfect equalization. Original algebraic analysis is presented for the constant modulus (CM) cost function, describing the deformation of the CM error surface due to undermodeling. The analysis is connected to previous work on CMA misadjustment, suggesting that similar to noisy LMS, a longer fractionally-spaced equalizer (FSE) is not always better than a shorter FSE.
Next, a truncated Taylor series of the binary CM cost function is used to estimate the location of the undermodeled CM minima. A measure is proposed from this estimate to determine the proximity of CM and mean squared error (MSE) minima, suggesting that those CM minima with better MSE performance stay closer to their corresponding Wiener solutions than those CM minima with worse MSE performance.
This dissertation can be used to determine design guidelines for length selection of a FSE updated by CMA (CMA-FSE) given specific signalling formats and channel models. Together, this work and the recent work of others can be used to establish a cohesive behavioral theory of CMA-FSE describing the robustness properties of the CM criterion to practical situations.