2. Transform the following differential equation into an equivalent system of first-order differential equations 2-(3) –...
2. Transform the following differential equation into an equivalent system of first-order differential equations 2-(3) – 3r(2) – 4.x' + 2x² = 2 cos 4t
2. Transform the following differential equation into an equivalent system of first-order differential equations -3° - 4x' +2.? = 2 cos 4t L M e e 00 O TI
transform the given differential equation or system into an equivalent system of first order differential equation x"+3x²+48-2y=0 y"+24'-3x+y = cost
Find a first-order system of ordinary differential equations equivalent to the second-order nonlinear ordinary differential equation y ^-- = 3y 0 + (y 3 − y) (3 points) Find a first-order system of ordinary differential equations equivalent to the second-order nonlinear ordinary differential equation y" = 3y' +(y3 – y).
Along with x1' please solve for x2'. Thanks! Transform the given differential equation into an equivalent system of first-order differential equations. y' (t) + 5y' (t) - 6ty(t) = 6 cost Let x, = y and X, Ey. Complete the differential equation for X.
Differential Equations 11. Which ordinary differential equation below is equivalent to the following system of linear equations? = -12 t = 3.81 - 12 + cos(t) (a) u" - 3u' +u = cos(t) (b) " +34 +u = -cos(t) (c) " + u' + 3u = -cos(t) (d) " + x - 3u = cos(t)
(6 points) Find a first-order system of ordinary differential equations equivalent to the second-order ordinary differential equation Y" + 2y' + y = 0. From the system, find all equilibrium solutions, and determine if each equilibrium solution is asymptotically stable, or unstable.
Solve the following system of first order differential equations: Given the system of first-order differential equations ()=(3) () determine without solving the differential equations, if the origin is a stable or an unstable equilibrium. Explain your answer.
consider 111 2+²y-dy' =-374 al write the equation abole as an equivalent system of first order differential equations. TET, +2 = 4², +3=y" luse b) express the system in matrix vector of equations formi 7 = Actix tgct)
Question 12 (3 marks) Special Attempt 2 A system of two first order differential equations can be written as 0 dr A second order explicit Runge-Kutta scheme for the system of two first order equations is 1hg(n,un,vn), un+1 Consider the following second order differential equation d2 0cy-6, with v(1)-1 and y'()-o Use the Runge-kutta scheme to find an approximate solution of the second order differential equation, at x = 1.2, if the step size h Maintain at least eight decimal...