Given the third order homogeneous constant coefficient equation y′′′+4y′′+y′−26y=0 1) the auxiliary equation is ar3+br2+cr+d= ?...

Consider the equation y'' + 4y = 0. a) Justify why the functions y1 = cos(4t)...

Consider the equation y'' + 4y = 0. a) Justify why the functions y1 = cos(4t) and y2 = sin(4t) do not constitute a fundamental set of solutions of the above equation. b) Find y1, y2 that constitute a fundamental set of solutions, justifying your answer.

B. a non-homogeneous differential equation, a complementary solution, and a particular solution are given. Find a...

B. a non-homogeneous differential equation, a complementary solution, and a particular solution are given. Find a solution satisfying the given initial conditions. y''-2y'-3y=6 y(0)=3 y'(0) = 11 yc= C1e-x+C2e3x yp = -2 C. a third-order homogeneous linear equation and three linearly independent solutions are given. Find a particular solution satisfying the given initial conditions y'''+2y''-y'-2y=0, y(0) =1, y'(0) = 2, y''(0) = 0 y1=ex, y2=e-x,, y3= e-2x

Consider the second-order homogeneous linear equation y''−6y'+9y=0. (a) Use the substitution y=e^(rt) to attempt to find...

Consider the second-order homogeneous linear equation y''−6y'+9y=0. (a) Use the substitution y=e^(rt) to attempt to find two linearly independent solutions to the given equation. (b) Explain why your work in (a) only results in one linearly independent solution, y1(t). (c) Verify by direct substitution that y2=te^(3t) is a solution to y''−6y'+9y=0. Explain why this function is linearly independent from y1 found in (a). (d) State the general solution to the given equation

Given that y1=e3x is a solution of the DE y′′−4y′+3y=0 . Using the reduction of order...

Given that y1=e3x is a solution of the DE y′′−4y′+3y=0 . Using the reduction of order method a second solution of the equation is y2=uy1 where u is ?

The nonhomogeneous equation t2 y′′−2 y=19 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular...

The nonhomogeneous equation t2 y′′−2 y=19 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular solution to the nonhomogeneous equation that does not involve any terms from the homogeneous solution. Enter an exact answer. Enclose arguments of functions in parentheses. For example, sin(2x). y(t)=

The nonhomogeneous equation t2 y′′−2 y=29 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular...

The nonhomogeneous equation t2 y′′−2 y=29 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular solution to the nonhomogeneous equation that does not involve any terms from the homogeneous solution.

Consider the differential equation x^2y′′ − 3xy′ − 5y = 0. Note that this is not...

Consider the differential equation x^2y′′ − 3xy′ − 5y = 0. Note that this is not a constant coefficient differential equation, but it is linear. The theory of linear differential equations states that the dimension of the space of all homogeneous solutions equals the order of the differential equation, so that a fundamental solution set for this equation should have two linearly fundamental solutions. • Assume that y = x^r is a solution. Find the resulting characteristic equation for r....

Consider the differential equation L[y] = y′′ + p(t)y′ + q(t)y = f(t) + g(t), and...

Consider the differential equation L[y] = y′′ + p(t)y′ + q(t)y = f(t) + g(t), and suppose L[yf] = f(t) and L[yg] = g(t). Explain why yp = yf + yg is a solution to L[y] = f + g. Suppose y and y ̃ are both solutions to L[y] = f + g, and suppose {y1, y2} is a fundamental set of solutions to the homogeneous equation L[y] = 0. Explain why y = C1y1 + C2y2 + yf...