(1 point) Math 216 Homework webHW3, Problem 11 Find the solution of the system where primes...
Math 216 Homework webHW10, Problem 9 Consider the spring model *" – 1x + 1x2 = 0, we looked at in the previous problem. Linearize the first-order system that you obtained there at the second of the critical points you found. [")=[*] where A = Then solve this to find the eigenvalues of the linearized system (enter any complex numbers you may obtain by using "i" for V-1. For real answers, enter them in ascending order; for complex, enter the...
Math 216 Homework webHW10, Problem 5 Consider the predator/prey model r' = 73 - 22 - ry y = -5y + xy. Find the linearization of this system at the second of the critical points you found in problem 3. , where A = [)] = A ( 3 ) where A = Then solve this to find the eigenvalues of the linearized system (enter any complex numbers you may obtain by using "" for V-1. For real answers, enter...
(1 point) Math 216 Homework webHW7, Problem 10 Find the steady periodic solution to the differential equation x" + 3x' + 25x = 4 sin(3t) in the form Xsp(t) = C cos(wt – a), with C > 0 and 0 < a < 21. Xsp(t) = 4/sqrt(337) cos
Consider the following differential equation system: x' = 16x + 8y y = -24x – 12y (a) Find the general solution. (b) Without a computer, sketch a phase diagram that shows four linear solution trajectories and that shows one solution trajectory in each of the four regions between the separatrices. (c) Determine the solution that satisfies x(0) = 1 and y(0) = 0. x(t) = yt) = (d) The point (0,0) is a ... Osaddle point stable node unstable node...
Problem 8. 1 point) a. Find the most general real-valued solution to the linear system of differential equations x (1) C: + C2 x2 (1) b. In the phase plane, this system is best described as a source / unstable node sink / stable node saddle center point / ellipses spiral source spiral sink none of these
Problem 7. (1 point) a. Find the most genera reat valued solution to the inear system of diferential equations t' = [": -); x1 (1) = C C + C2 x2 (1) u b. In the phase plane, this system is best described as a source / unstable node sink / stable node O saddle center point / ellipses O spiral source spiral sink none of these
For each of the following systems: (i) Find the general solution by using eigenvalues and eigenvectors. (ii) State whether the origin is stable, asymptotically stable, or unstable. (iii) State whether the origin is a node, saddle, center, or spiral. For each of the following systems: (i) Find the general solution by using eigenvalues and eigenvectors. (ii) State whether the origin is stable, asymptotically stable, or unstable. |(iii) State whether the origin is a node, saddle, center, or spiral. Problem 1:...
Problem 7. (1 point) a. Find the most general real-valued solution to the linear system of differential equations X' = [ * ] x1(1) C1 x2(1) + C2 b. In the phase plane, this system is best described as a source / unstable node sink / stable node saddle center point / ellipses O spiral source spiral sink none of these
(1 point) a. Find the most general real-valued solution to the linear system of differential equations a' 2.(0) z(t) C + c b. In the phase plane, this system is best described as a O source / unstable node sink/stable node O saddle O center point/ ellipses spiral source Ospiral sink
(1 point) a. Find the most general real-valued solution to the linear system of differential equations x -8 -10 x. xi(t) = C1 + C2 x2(t) b. In the phase plane, this system is best described as a source / unstable node sink / stable node saddle center point / ellipses spiral source spiral sink none of these ОООООО (1 point) Calculate the eigenvalues of this matrix: [Note-- you'll probably want to use a calculator or computer to estimate the...