12.4 Particular solutions 347
or by the equivalent trigonometric form (12.17),
y(x) 1 = 1 d
1cos 1 ωx 1 + 1 d
21 sin 1 ωx (12.22)
Ifωis a given constant then two initial or boundary conditions are normally sufficient
to specify a particular solution. This is exemplified in Section 12.5 for the classical
harmonic oscillator as an initial value problem. However, ifωis a parameter to be
determined, then an additional condition is required. This is the case for the quantum-
mechanical ‘particle in a box’, as a boundary value problem, discussed in Section 12.6.
A third possibility arises when the physical situation requires the imposition of a
periodic (cyclic) boundary condition(see Section 8.6),
y(x 1 + 1 λ) 1 = 1 y(x) (12.23)
whereλis the period. In this case, replacement ofxbyx 1 + 1 λin the general solution
(12.21) gives
y(x 1 + 1 λ) 1 = 1 c
1e
iω(x+λ)1 + 1 c
2e
−iω(x+λ)1 = 1 c
1e
iωxe
iωλ1 + 1 c
2e
−iωxe
−iωλThe condition (12.23) is then satisfied if bothe
iωλ1 = 11 ande
−iωλ1 = 11. As discussed in
Section 8.6, this is the case whenωλis a multiple of 2 π,
ωλ 1 = 12 πn, n 1 = 1 0, ±1, ±2, ±3,1= (12.24)
The possible values ofωare then (using nto label the values) ω
n1 = 12 πn 2 λ, and the
corresponding solutions are
y
n(x) 1 = 1 c
1e
(2πnx 2 λ)i1 + 1 c
2e
−(2πnx 2 λ)i, n 1 = 1 0, ±1, ±2, ±3,1= (12.25)
The trigonometric form of these solutions is
(12.26)
The constants c
1and c
2, or d
1and d
2, are not determined. The case of the periodic
boundary condition is exemplified in Section 12.7 for the quantum-mechanical
problem of the ‘particle in a ring’.
EXAMPLE 12.9Solve the equation for the cyclic boundary
conditionsy(θ 1 + 1 π) 1 = 1 y(θ).
The general solution is
y(θ) 1 = 1 c
1e
iω
θ1 + 1 c
2e
−iω
θ.
dy
d
y
2220
θ
+=ω
yd
nx
d
nx
n=+
1222
cos sin
ππ
λλ