(a) Show that only one solution exists that satisfy y″ – 9y = 0, y(0) =...

Show that the IVP dy/dx = xy^(3/2) y(2) = 0 has a solution but it may...

Show that the IVP dy/dx = xy^(3/2) y(2) = 0 has a solution but it may or may not be unique (i.e. the Existence and Uniqueness Theorem doesn’t imply uniqueness). (Remark: Make sure to draw an appropriate rectangular region.)

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

Use the Existence and Uniqueness Theorem to find the maximum interval for the existing unique solution...

Use the Existence and Uniqueness Theorem to find the maximum interval for the existing unique solution for this IVP: ((x^2)-9)y' + (x + 3)y = cosx and y(0) = 0

Find the general solution of the equation: y''+6y'+9y=0 where y(1)=3 y' (1)=-2 and then find the...

Find the general solution of the equation: y''+6y'+9y=0 where y(1)=3 y' (1)=-2 and then find the particular solution.

Consider the differential equation y′′+ 9y′= 0.( a) Let u=y′=dy/dt. Rewrite the differential equation as a...

Consider the differential equation y′′+ 9y′= 0.( a) Let u=y′=dy/dt. Rewrite the differential equation as a first-order differential equation in terms of the variables u. Solve the first-order differential equation for u (using either separation of variables or an integrating factor) and integrate u to find y. (b) Write out the auxiliary equation for the differential equation and use the methods of Section 4.2/4.3 to find the general solution. (c) Find the solution to the initial value problem y′′+ 9y′=...

Solve the initial-value problem. y"-6y'+9y=0; y(0)=2, y'(0)=3 Given that y1=x2 is a solution to y"+(1/x) y'-(4/x2)...

Solve the initial-value problem. y"-6y'+9y=0; y(0)=2, y'(0)=3 Given that y1=x2 is a solution to y"+(1/x) y'-(4/x2) y=0, find a second, linearly independent solution y2. Find the Laplace transform. L{t2 * tet} Thanks for solving!

(a) Solve the differential equations. 4y´´ + 12y´ + 9y= 0 (b) Find the general solution...

(a) Solve the differential equations. 4y´´ + 12y´ + 9y= 0 (b) Find the general solution of the ODE y´´- 5y´+4y=e^4t (c) Solve the following initial value problem: y´´+ y =0, y(0)=2, y´(0)=2

Find the Laplace transform Y(s)=L{y} of the solution of the given initial value problem. y′′+9y={t, 0≤t<1...

Find the Laplace transform Y(s)=L{y} of the solution of the given initial value problem. y′′+9y={t, 0≤t<1 1, 1≤t<∞, y(0)=3, y′(0)=4 Enclose numerators and denominators in parentheses. For example, (a−b)/(1+n). Y(s)=

In the following problems determine whether existence of at least one solution of the given initial...

In the following problems determine whether existence of at least one solution of the given initial value problem is thereby guaranteed and if so, whether the uniqueness of that solution is guaranteed. For each initial value problem determine all solutions and the intervals where they hold, if the case. (a) dy/dx = y^(1/3); y(1) = 1. (b) dy/dx = y^(1/3); y(1) = 0. (c) dy/dx =sqrt(x - y); y(2) = 1. Can you explain how can we approach these kind...

1) show that tanh-1(x) = 1/2 ln (1+x/1-x) 2) show that a) d/dx (cosh-1(x)) = 1/sqrt...

1) show that tanh-1(x) = 1/2 ln (1+x/1-x) 2) show that a) d/dx (cosh-1(x)) = 1/sqrt x2-1 b) d/dx (tanh-1(x)) = 1/1-x2 3) verify that y = A cosh(3x) + B sinh(3x) is a solution to the equation y''-9y = 0