Bessel’s equation, Bessel’s equation ,16-52 – HP 50g Graphing Calculator User Manual
Page 529
Page 16-52
where M = n/2 or (n-1)/2, whichever is an integer.
Legendre’s polynomials are pre-programmed in the calculator and can be
recalled by using the function LEGENDRE given the order of the polynomial, n.
The function LEGENDRE can be obtained from the command catalog (
‚N)
or through the menu ARITHMETIC/POLYNOMIAL menu (see Chapter 5). In
RPN mode, the first six Legendre polynomials are obtained as follows:
0 LEGENDRE, result: 1,
i.e.,
P
0
(x) = 1.0.
1 LEGENDRE, result: ‘X’,
i.e.,
P
1
(x) = x.
2 LEGENDRE, result: ‘(3*X^2-1)/2’,
i.e.,
P
2
(x) = (3x
2
-1)/2.
3 LEGENDRE, result: ‘(5*X^3-3*X)/2’,
i.e.,
P
3
(x) =(5x
3
-3x)/2.
4 LEGENDRE, result: ‘(35*X^4-30*X^2+3)/8’, i.e.,
P
4
(x) =(35x
4
-30x
2
+3)/8.
5 LEGENDRE, result: ‘(63*X^5-70*X^3+15*X)/8’, i.e.,
P
5
(x) =(63x
5
-70x
3
+15x)/8.
The ODE (1-x
2
)
⋅(d
2
y/dx
2
)-2
⋅x⋅ (dy/dx)+[n⋅ (n+1)-m
2
/(1-x
2
)]
⋅y = 0, has for
solution the function y(x) = P
n
m
(x)= (1-x
2
)
m/2
⋅(d
m
Pn/dx
m
). This function is
referred to as an associated Legendre function.
Bessel’s equation
The ordinary differential equation x
2
⋅(d
2
y/dx
2
) + x
⋅ (dy/dx)+ (x
2
-
ν
2
)
⋅y = 0,
where the parameter
ν is a nonnegative real number, is known as Bessel’s
differential equation. Solutions to Bessel’s equation are given in terms of
Bessel functions of the first kind of order
ν:
m
n
M
m
n
m
n
x
m
n
m
n
m
m
n
x
P
2
0
)!
2
(
)!
(
!
2
)!
2
2
(
)
1
(
)
(
−
=
∑
⋅
−
⋅
−
⋅
⋅
−
⋅
−
=
..
...
)!
2
(
)!
1
(
!
1
2
)!
2
2
(
)
!
(
2
)!
2
(
2
2
−
+
⋅
−
−
⋅
⋅
−
−
⋅
⋅
=
−
n
n
n
n
x
n
n
n
x
n
n
∑
∞
=
+
+
+
Γ
⋅
⋅
⋅
−
⋅
=
0
2
2
,
)
1
(
!
2
)
1
(
)
(
m
m
m
m
m
m
x
x
x
J
ν
ν
ν
ν