You are told that a certain second order, linear, constant
coefficient, homogeneous ode has the solutions
y1(x) = e^γx cos ωx, and y2(x) = e^γx sin ωx,
where γ and ω are real-valued parameters and −∞ < x < ∞.
You are told that a certain second order, linear, constant coefficient, homogeneous ode has the s...
just focus on A,B,D
1. Homogeneous ODE Find a general solution of the linear non-constant coefficient, homogeneous ODE for y(x) x3y'" – 3xy" + (6 – x2)xy' – (6 – x?)y = 0 as follows. a) You are given that yı(x) = x is a solution to the above homogeneous ODE. Confirm (by substitution) that this is the case. b) Apply reduction of order to find the remaining two solutions, then state the general solution. (Hint: The substitution y2(x) =...
It's in Mathematical Methods for Physicists 7e, Arfken ch7.7
Inhomogeeous linear ODEs.
Please help.
Thank you.
7.7.1 If our linear, second-order ODE is inhomogeneous, tha is, of the form of Eq. (7.94), the most general solution is where yi and y2 are independent solutions of the homogeneous equation Show that yi(x)2()Fsds W[yi(s), y2()) Wyi(), y2(s) with Wlyxy2x)) the Wronskian of yi(s) and y2(s) Find the general solutions to the following inhomogeneous ODEs:
7.7.1 If our linear, second-order ODE is inhomogeneous,...
Consider the following statements.
(i) Given a second-order linear ODE, the method of variation of
parameters gives a particular solution in terms of an integral
provided y1 and y2 can be
found.
(ii) The Laplace Transform is an integral transform that turns
the problem of solving constant coefficient ODEs into an algebraic
problem. This transform is particularly useful when it comes to
studying problems arising in applications where the forcing
function in the ODE is piece-wise continuous but not necessarily...
Consider the second-order, linear, homogeneous ODE for y = y(x) (a2- 1) 1) y0 (1) = -1 is a regular singular point of (1) (a) Show that xo (b) Use the Method of Frobenius to find the first four terms of each of the two linearly independent solutions of (1) about xo Show your work! -1. How many of coefficients are nonzero?
2. (Sturm-Liouville Theory) Consider the following linear homogeneous second-order differential equation and boundary conditions v(T where a and b are finite, p(x), p(x,)) are real and continuous on [a, b), and p(x),w(x) > 0 on a,b]. Show that two distinct solutions to this ODE, Pm(z) and (x), are orthogonal to each other on the interval [a,b]. That is, prove the following relationship 0
2. (Sturm-Liouville Theory) Consider the following linear homogeneous second-order differential equation and boundary conditions v(T where a...
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...
Le-t are solutions of a second-order /2e5t and y2(t) Suppose y1(t) = homogeneous linear ODE on R. Which one of the following is also a solution to the same ODE? y(t) e5t-2 y(t) ee y(t) e5t e 1 y(t) 2e5t
Le-t are solutions of a second-order /2e5t and y2(t) Suppose y1(t) = homogeneous linear ODE on R. Which one of the following is also a solution to the same ODE? y(t) e5t-2 y(t) ee y(t) e5t e 1 y(t) 2e5t
2. You can use Dand write an operator instead of an equation in this question. (a) Find a constant coefficient linear homogeneous differential equation of lowest order that has n(x)-x , y2(z) = x2 , and y3(z) = eェamong its solutions. (b) Now find a different linear homogeneous differential equation of an order lower than the one in (a) that has the same y1,U2,U3 among its solutions. (c) Find a constant coefficient linear homogeneous differential equation of lowest order that...
8. (9 points) Suppose the characteristic equation of a certain twentieth order, linear, constant coefficient, homogeneous differential equation has roots: 2,0, a, 2+3i, ti, +4i, ti, 2, 3, a, 2+3i ,2,3,0, and -3. (where a is a real constant) Write the general solution to this differential equation. (Do not attempt to solve for the coefficients).
Given a second order linear homogeneous differential equation а2(х)у" + а (х)У + аo(х)у — 0 we know that a fundamental set for this ODE consists of a pair linearly independent solutions yı, V2. But there are times when only one function, call it y, 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 a2(x) F 0 we rewrite...