This paper studies breakpoints in root loci with polynomial gain parameterization, which are critical for understanding the stability and performance of control systems with complex gain dependencies. Unlike affine root loci, polynomially parameterized root loci require a more nuanced approach due to irregular branch distributions near breakpoints. Using tools from algebraic geometry, such as Puiseux series expansions and Newton polygons, we characterize the local behavior of roots and derive computational procedures for determining departure and arrival angles at breakpoints. The main contributions include a formalization of breakpoint conditions and a demonstration of irregular root distributions, supported by illustrative examples. This work provides a theoretical foundation for analyzing systems with nonlinear gain dependencies, bridging the gap between classical root locus techniques and modern control system requirements.
Juan Ignacio Mulero-Martínez (Thu,) studied this question.