A Strict Gap Between Relaxed and Partition-Constrained Spectral Compression in a Six-State Lumpable Markov Chain

Abstract

This paper studies a finite reversible lumpable Markov chain for which relaxed spectral compression yields a larger determinant than partition-constrained compression. For a symmetric six-state lumpable chain and the positive operator T=P2, I compare the relaxed benchmark equation* Drel3(T):=U*U=I3(U*TU) equation* and the partition-constrained benchmark equation* A\,3-partition Q A(T), Q A(T)=H A*TH A. equation* Here the partition-constrained benchmark is the compression induced by normalized indicator vectors of genuine partitions of the state space. I derive closed formulas for the two analytically central partition families, prove strict upper bounds for both in a local-mode-dominated regime, and combine these bounds with an exhaustive enumeration of all 90 partitions into three nonempty cells in an explicit six-state model. For this model, one obtains a strict global gap: equation* A Q A(T)< Drel3(T). equation* Thus, in this model, indicator-based partition frames are strictly weaker than relaxed orthonormal frames even after global partition-constrained optimization.