Introduces the dual Burnside process via role interchange, proves it shares all nonzero eigenvalues with the classical kernel through matrix factorization, and demonstrates orbit and conjugacy lumpings plus fixed-symbol quotients that reduce state space while preserving spectrum.
The low-rank eigenvalue problem
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abstract
The nonzero eigenvalues of $AB$ are equal to those of $BA$: an identity that holds as long as the products are square, even when $A,B$ are rectangular. This fact naturally suggests an efficient algorithm for computing eigenvalues and eigenvectors of a low-rank matrix $X= AB$ with $A,B^T\in\mathbb{C}^{N\times r}, N\gg r$: form the small $r\times r$ matrix $BA$ and find its eigenvalues and eigenvectors. For nonzero eigenvalues, the eigenvectors are related by $ ABv = \lambda v \Leftrightarrow BAw = \lambda w $ with $w=Bv$, and the same holds for Jordan vectors. For zero eigenvalues, the Jordan blocks can change sizes between $AB$ and $BA$, and we characterize this behavior.
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The dual Burnside process
Introduces the dual Burnside process via role interchange, proves it shares all nonzero eigenvalues with the classical kernel through matrix factorization, and demonstrates orbit and conjugacy lumpings plus fixed-symbol quotients that reduce state space while preserving spectrum.