Given the solutions of a third order differential equation f₁(x)=2 x²-x, f₂(x)=2 x²+1 and f₃(x)=-x+2 use the Wronskian determinant to show the functions are linearly independent. Will this set be a fundamental solution set this ODE?
3 multiple choice questions Two solutions to a second order differential equation are linearly independent if (a) their Wronskian determinant is zero. (b) their Wronskian determinant is nonzero. (c) they are not scalar multiples of one another. (d) they each have a corresponding initial condition. (e) Both (b) and (c) are correct. Given the differential equation y"+9y' = e-91, the correct guess for a particular solution would be (a) yp = Ae-94 (b) yp = (Ax + B)e-9r. (c) yp...
Question Find three linearly independent solutions of the given third-order differential equation and write a general solution as an arbitrary linear combination of them. y-y"-21y' +5y 0 -0 A general solution is y(t)
(4) (12 points)For the differential equation: Compute the recursion formula for the coefficients of the power series solution centered at o 0 and use it to compute the first three nonzero terms of the solution with y(0) 12, y'(0)0. (5) (12 points)For the equation y" - 5ty -7y 0 (t>0), (t)t is a solution (a) Use the method of Reduction of Order to obtain a second, independent solution. (b) Solve the equation directly, using that it is an Euler Equation....
Verify that the given function form a fundamental set of solutions on the interval (0, 0), compute the Wronskian, and form the general solution. xy'' – 6xy' +12y = 0 x?; x+ I verified the solution. ONo Yes Find the Wronskian and verify that the functions are linearly independent on the interval (0, 0). W(x", x4) = 0 Preview I found the general solution. OYes ONO
(1 point) Given a second order inear homogeneous differential equation az(x) + we know that a fundamental set for this ODE consists of a pair nearly ndependent solutions . linearly independent solution We can find using the method et reduction of (2) + Golly=0 But there are times when only one functional and we would e nd a con First under the necessary assumption the a, (2) we rewrite the equation as * +++ (2) - Plz) - ) Then...
6. The vectors x-[)and X - [-] are solutions vectors corresponding to the system of differential equation X = AX (a) Use the Wronskian to show that X, and X, are linearly independent. (b) Write down a general solution to the system of equations. (e) Find the solution to the system subject to the initial condition X(0) -
Differential equation 1. Chapter 4 covers differential equations of the form an(x)y("4a-,(x)ye-i) + +4(x)y'+4(x)-g(x) Subject to initial conditions y)oyy-Co) Consider the second order differential equation 2x2y" + 5xy, + y-r-x 2- The Existence of a Unique Solution Theorem says there will be a unique solution y(x) to the initial-value problem at x=而over any interval 1 for which the coefficient functions, ai (x) (0 S is n) and g(x) are continuous and a, (x)0. Are there any values of x for...
Given a second order linear homogeneous differential equation a2(x)” + a (x2y + a)(x2y = 0 we know that a fundamental set for this ODE consists of a pair linearly independent solutions yı, y. But there are times when only one function, call it yi, is available and we would like to find a second linearly independent solution. We can find y2 using the method of reduction of order. First, under the necessary assumption the az(x) + 0 we rewrite...
Problem 1 (14 points) (a) Find the general solution to a third-order linear homogeneous differential equation for y(1) with real numbers as coefficients if two linearly independent solutions are known to be e-21 and sin(3.c). e (b) Determine that differential equation described in part (a).
Problem 1 (14 points) (a) Find the general solution to a third-order linear homogeneous differential equation for y(1) with real numbers as coefficients if two linearly independent solutions are known to be e-21 and sin(3.c). e (b) Determine that differential equation described in part (a).