A scaling characterization of nc-rank via unbounded gradient flow
Abstract
Given a tuple of n × n complex matrices A = (A1,A2,…, Am), the linear symbolic matrix A = A1x1 + A2x2 + ·s + Am xm is nonsingular in the noncommutative sense if and only if the completely positive operators T A (X) = Σi=1m Ai X Ai and T A*(X) = Σi=1m Ai X Ai can be scaled to be doubly stochastic: For every ε > 0 there are g,h ∈ GL(n,C) such that \|Tg Ah(I)- I\| < ε, \| T*g Ah(I) - I\| < ε. In this paper, we show a refinement: The noncommutative corank of A is equal to one-half of the minimum residual \|Tg Ah(I) - I\|1 + \|T*g Ah(I) - I\|1 over all possible scalings g Ah, where \|· \|1 is the trace norm. To show this, we interpret the residuals as gradients of a convex function on symmetric space GL(n,C)/Un, and establish a general duality relation of the minimum gradient-norm of a lower-unbounded convex function f on GL(n,C)/Un with an invariant Finsler metric, by utilizing the unbounded gradient flow of f at infinity.
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