4. Consider the Lotka-Volterra model for the interaction between a predator population (wolves W(t)) and a prey population (moose M(t)), M W = −cW+dMW = aM - bMW with the four constants all positive. (a) Explain the meaning of the terms. (b) Non-dimensionalize the equations in the form dx/d = x(1 − y) and dy/dî = µy(x − 1). (c) Find the fixed points, linearize, classify their stability and sketch the trajectories for various initial conditions (again, using a computer is fine). You should find a center. Can you trust that this is really a center? (d) To answer this, try to find a conserved quantity for this system (read Strogatz §6.5 nonlinear centers form at minima and maxima of this quantity. The most fundamental case is energy an undamped, unforced oscillator has a nonlinear center). Find the minima or maxima of this quantity, and show that the center found above lies at the same point. (Hint: to find the conserved quantity, notice that x/x = d(lnx)/dt).

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4. Consider the Lotka- Volterra model for the interaction between a predator population (wolves W(t)) and a prey population (moose M(t)), M W = −cW+dMW = aM - bMW with the four constants all positive. (a) Explain the meaning of the terms. (b) Non-dimensionalize the equations in the form dx/d = x(1 − y) and dy/dî = µy(x − 1). (c) Find the fixed points, linearize, classify their stability and sketch the trajectories for various initial conditions (again, using a computer is fine). You should find a center. Can you trust that this is really a center? (d) To answer this, try to find a conserved quantity for this system (read Strogatz §6.5 nonlinear centers form at minima and maxima of this quantity. The most fundamental case is energy an undamped, unforced oscillator has a nonlinear center). Find the minima or maxima of this quantity, and show that the center found above lies at the same point. (Hint: to find the conserved quantity, notice that x/x = d(lnx)/dt).