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There is an opportunity for universities and national laboratories to partner and harness high performance computing architectures to make these models a reality. Despite the promising idea of the continuum electromechanical dynamic model, not much research has been produced in this area, particularly due to its complexity and computational burden. A continuum model like this can provide a macro-scale or ​ “birds-eye” understanding of the power system electromechanical frequency which can be used to find grid weak spots and design appropriate protection schemes. One notable attempt is the continuum electromechanical dynamic model which generalizes the classical phasor transient stability model and allows for the characterization of the spatiotemporal propagation of electromechanical waves produced by faults and other types of disturbances. There are few models available that can characterize the electromechanical wave phenomenon in large-scale transmission systems. The ability to predict the frequency disturbance behavior in order to advert failures and design protection and control schemes would greatly increase the resiliency of the electrical power grid. Understanding it could permit new developments in protection and control of power system frequency transients. This phenomenon has been named ​ “electromechanical wave propagation”. Phasor Measurement Units have confirmed these local disturbances to propagate through the grid in a wave-like fashion. As a result, local disturbances might result in wide-area blackouts causing large social and economic losses. Owing to increased penetration of renewable energy resources, rapid load growth, and the energy market reform taking place in the power system, many interconnected grids are approaching their safe operating limits.