Experimenting with real human hearts isn’t possible, but experimenting with accurate mathematical models of the human heart has led to a new understanding of its complex processes. Mathematics and the computers can replace years of experimentation in laboratories. For example, understanding resulting from mathematics greatly speeds up the design and implementation of artificial valves.
Equations based on Hooke’s Law model the geometry of the heart by representing muscle fibers as close curves of different elasticities. The Navier-Stokers Equations, which describe all fluid flows, model blood flow in and around the heart. The fact that the heart’s shape is constantly changing, however, makes the equations especially hard to solve, and a precise solution to the equation can’t be found. Approximate solutions are generated by computers.
Equations based on Hooke’s Law model the geometry of the heart by representing muscle fibers as close curves of different elasticities. The Navier-Stokers Equations, which describe all fluid flows, model blood flow in and around the heart. The fact that the heart’s shape is constantly changing, however, makes the equations especially hard to solve, and a precise solution to the equation can’t be found. Approximate solutions are generated by computers.
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