Compression of Voxelized Vector Field Data by Boxes is Hard

Voxelized vector field data consists of a vector field over a high dimensional lattice. The lattice consists of integer coordinates called voxels. The voxelized vector field assigns a vector at each voxel. This data type encompasses images, tensors, and voxel data. Assume there is a nice energy function on the vector field. We consider the problem of lossy compression of voxelized vector field data in Shannon's rate-distortion framework. This means the data is compressed then decompressed up to a bound on the distortion of the energy at each voxel. We formulate this in terms of compressing a single voxelized vector field by a collection of box summary pairs. We call this problem the $(k,D)$-RectLossyVFCompression} problem. We show three main results about this problem. The first is that decompression for this problem is polynomial time tractable. This means that the only obstruction to a tractable solution of the $(k,D)$-RectLossyVFCompression problem lies in the compression stage. This is shown by the two hardness results about the compression stage. We show that the compression stage is NP-Hard to compute exactly and that it is even APX-Hard to approximate for $k,D\geq 2$. Assuming $P\neq NP$, this shows that when $k,D \geq 2$ there can be no exact polynomial time algorithm nor can there even be a PTAS approximation algorithm for the $(k,D)$-RectLossyVFCompression problem.