Blind hierarchical deconvolution
This addresses a fundamental limitation in signal processing by enabling blind deconvolution, which is incremental as it builds on existing model-based inversion techniques.
The paper tackles the problem of deconvolution without prior knowledge of the convolution kernel or signal regularity, achieving accurate reconstructions for functions with varying regularity and unknown kernel size through a joint estimation framework.
Deconvolution is a fundamental inverse problem in signal processing and the prototypical model for recovering a signal from its noisy measurement. Nevertheless, the majority of model-based inversion techniques require knowledge on the convolution kernel to recover an accurate reconstruction and additionally prior assumptions on the regularity of the signal are needed. To overcome these limitations, we parametrise the convolution kernel and prior length-scales, which are then jointly estimated in the inversion procedure. The proposed framework of blind hierarchical deconvolution enables accurate reconstructions of functions with varying regularity and unknown kernel size and can be solved efficiently with an empirical Bayes two-step procedure, where hyperparameters are first estimated by optimisation and other unknowns then by an analytical formula.