Analytical PI Tuning for Second-Order Plants with Monotonic Response and Minimum Settling Time

Background: Tuning proportional-integral (PI) controllers for second-order plants to achieve monotonic step response with minimum settling time is an important problem in analytical control design. Existing methods address these objectives only partially or require numerical optimization. Methods: A closed-form analytical solution is derived through pole placement in the framework of Astrom and Hagglund. The key insight is that designing the closed-loop poles slower than the fast plant pole forces pole-zero cancellation of the slow plant pole as a consequence, not an assumption. The critically damped condition is then applied to minimize settling time. Results: The optimal PI parameters are K=T1/(4KpT2), Ti=T1, where T1 and T2 are the plant time constants and Kp is the plant gain. No free parameter remains. The resulting closed-loop system possesses universal robustness properties independent of plant parameters: maximum complementary sensitivity Mt = 1, maximum sensitivity Ms = 1.155, and phase margin PM = 76.35 degree. Conclusions: The proposed tuning formulas are explicit, analytically proven, and apply directly to any stable second-order plant with two real poles. Simulation results across six plant configurations confirm the analytical predictions exactly. The notation follows Astrom and Hagglund [5] throughout. Keywords: PI controller; second-order plant; pole placement; critically damped; monotonic response; settling time; robustness