Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

HIGHER-ORDER ORDINARY DIFFERENTIAL EQUATIONS


15.29 The equation of motion for a driven damped harmonic oscillator can be written


̈x+2x ̇+(1+κ^2 )x=f(t),
withκ=0.Ifitstartsfromrestwithx(0) = 0 andx ̇(0) = 0, find the corresponding
Green’s functionG(t, τ) and verify that it can be written as a function oft−τ
only. Find the explicit solution when the driving force is the unit step function,
i.e.f(t)=H(t). Confirm your solution by taking the Laplace transforms of both
it and the original equation.
15.30 Show that the Green’s function for the equation


d^2 y
dx^2

+


y
4

=f(x),

subject to the boundary conditionsy(0) =y(π) = 0, is given by

G(x, z)=

{


−2cos^12 xsin^12 z 0 ≤z≤x,

−2sin^12 xcos^12 zx≤z≤π.

15.31 Find the Green’s functionx=G(t, t 0 ) that solves


d^2 x
dt^2


dx
dt

=δ(t−t 0 )

under the initial conditionsx=dx/dt=0att=0.Hencesolve

d^2 x
dt^2


dx
dt

=f(t),

wheref(t)=0fort<0.
Evaluate your answer explicitly forf(t)=Ae−at(t>0).
15.32 Consider the equation


d^2 y
dx^2

+f(y)=0,

wheref(y) can be any function.
(a) By multiplying through bydy/dx, obtain the general solution relatingxand
y.
(b) A massm, initially at rest at the pointx= 0, is accelerated by a force

f(x)=A(x 0 −x)

[


1+2ln

(


1 −


x
x 0

)]


.


Its equation of motion ismd^2 x/dt^2 =f(x). Findxas a function of time, and
show that ultimately the particle has travelled a distancex 0.

15.33 Solve


2 y

d^3 y
dx^3

+2


(


y+3

dy
dx

)


d^2 y
dx^2

+2


(


dy
dx

) 2


=sinx.

15.34 Find the general solution of the equation


x

d^3 y
dx^3

+2


d^2 y
dx^2

=Ax.

15.35 Express the equation


d^2 y
dx^2

+4x

dy
dx

+(4x^2 +6)y=e−x

2
sin 2x

in canonical form and hence find its general solution.
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