On the Fundamental Limit of the Stochastic Gradient Identification Algorithm Under Non-Persistent Excitation

Abstract

Stochastic gradient (SG) methods are fundamental to system identification and machine learning, enabling online parameter estimation in large-scale and streaming-data settings. As a classical identification method, the SG algorithm has been extensively studied for decades. Under non-persistent excitation, the strongest currently available convergence result assumes that the condition number of the Fisher information matrix is \(O(( rn)α)\), where \(rn = 1 + Σi=1n \|i\|2\). Existing theory establishes strong consistency when \(α 1/3\), whereas the same condition with \(α > 1\) is insufficient to guarantee strong consistency. We prove that strong consistency holds throughout the range \(0 α < 1\). The proof is based on a new algebraic framework that yields substantially sharper matrix norm bounds. This result nearly resolves the four-decade-old Chen--Guo conjecture by establishing strong consistency throughout the previously open range \(1/3 < α < 1\).

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