Since the blur kernel is unknown, the algorithm should be a blind-deconvolution algorithm. A typical blind-deconvolution algorithm would recover the convolution kernel (point-spread function) as well as the image itself.
But most such algorithm only deals with spatially invariant blur, which need the blur kernel to be stable across the whole image. The image you provided contains shift-variant spatially-variant blur. Both the camera and the dog are moving during exposure, result in an very complex blurred image. AFAIK, there is no algorithm that can recover your blurred dog. If you can remove the dog from the image the result could be much better.
Moreover, camera blur can also affect the result. Since it is a real photo, the focal point should be clearer while other stuff outside the depth of focus is blured out. It adds another dimention of spacial variance. A lot of research papers only evaluate their algorithm against computed blur images or simple real photos. The deblur algorithm for complex shift-variant blur is still a open problem.
Further more, noises in images can also affect the deblur quality. And real photos always contains noises.
At last, you should remember that mathematically speaking, deblurring is an ill-posed inverse problem, so small perturbations in the data (for instance noise in the measured
“blurred” image) lead to large errors in the reconstruction. It is not always possible to recover a blured image since a lot of information are lost in the blurring.