MAP-based Problem-Agnostic diffusion model for Inverse Problems

Diffusion models have indeed shown great promise in solving inverse problems in image processing. In this paper, we propose a novel, problem-agnostic diffusion model called the maximum a posteriori (MAP)-based guided term estimation method for inverse problems. We divide the conditional score function into two terms according to Bayes' rule: the unconditional score function and the guided term. We design the MAP-based guided term estimation method, while the unconditional score function is approximated by an existing score network. To estimate the guided term, we base on the assumption that the space of clean natural images is inherently smooth, and introduce a MAP estimate of the $t$-th latent variable. We then substitute this estimation into the expression of the inverse problem and obtain the approximation of the guided term. We evaluate our method extensively on super-resolution, inpainting, and denoising tasks, and demonstrate comparable performance to DDRM, DMPS, DPS and $\Pi$GDM.