Reliable, Robust, and Resilient System Design Framework with Application to Wastewater-Treatment Plant Control

This paper presents a framework for reliable, robust, and resilient system design, addressing the need for acceptable performance not only to be provided under expected conditions, but to be maintained and/or quickly returned to when threats act upon a system. This is achieved through incorporation of multiobjective optimization; assessment of reliability, robustness, and resilience; and filtering and prioritization of solutions at key intervals. The effectiveness of the framework and benefits of its use are demonstrated with a wastewater treatment plant (WWTP) control strategy design problem. The effects of extreme,nondesign loads on highly optimized control strategies have not previously been explored, and it is found in this example that options yielding the greatest improvements under design conditions typically provide poor effluent quality robustness and resilience to influent perturbations. By integrating robustness and resilience, solutions can be identified that meet key performance objectives under design conditions while also minimizing the magnitude and duration of potential failures under extreme conditions. Application of this framework can also yield knowledge of threats to which the system is least robust and/or the requirements most prone to failure under extreme conditions. It is shown here that, when attempting to reduce greenhouse gas emissions by improved WWTP control, decreased influent temperature poses a significant threat and maintaining an acceptable total nitrogen concentration in the effluent under extreme conditions is a key issue. (C) 2016 American Society of Civil Engineers.