# Is bilinear filtering reversible?

When using a bilinear filter to magnify an image (by some non-integer factor), is that process lossless? That is, is there some way to calculate the original image, as long as the original resolution, the upscaled image and the exact algorithm used are known, and there is no loss in precision when upscaling (no rounding errors)?

My guess would be that it is, but that is based on some calculations on a napkin regarding the one-dimensional case only.

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Taking the 1D case as a simplification. Each output point can be expressed as a linear combination of two of the input points, i.e.:

``````y_n = k_n * x_m + (1-k_n) * x_{m+1}
``````

You have a whole set of these equations, which can be expressed in vector notation as:

``````Y = K * X
``````

where `X` is a length-`M` vector of input points, `Y` is a length-`N` vector of output points, and `K` is a sparse matrix (size `NxM`) containing the (known) values of `k`.

For the interpolation to be reversible, `K` must be an invertible matrix. This means that there must be at least `M` linearly-independent rows. This is true if and only if there is at least one output point in-between each pair of input points.

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That was exactly my napkin calculation, I was just wondering whether it was applicable to the 2D case as well :) The condition of one output point between each pair of input points seems logical and should be satisfied in case of an upscale, right? –  lxgr Apr 2 '12 at 22:45
@lxgr: I think similar logic applies for 2D, but I can't prove it right now... –  Oli Charlesworth Apr 2 '12 at 22:48
@OliCharlesworth: Filtering can be described as convolution. If the filterkernel in nonperiodic, the process can be reversed. Look up the term "deconvolution", crazy, interesting stuff. In general if you know the convolution kernel, and have enough data points you can reverse the process. Which means: If you apply a aperiodic blurring filter on a image and don't throw away the data at the edges and don't reduce the resolution, you can reverse the process. –  datenwolf Apr 3 '12 at 8:00