The ordinary differential equation
(1)
(Byerly 1959, p. 255). The solution is denoted ellipsoidal
harmonic of the first kind , or Lamé function. Whittaker and Watson (1990,
pp. 554-555) give the alternative forms
(Whittaker and Watson 1990, pp. 554-555; Ward 1987; Zwillinger 1997, p. 124). Here, Weierstrass elliptic function ,
Jacobi elliptic function , and
Two other equations named after Lamé are given by
(10)
and
(11)
(Moon and Spencer 1961, p. 157; Zwillinger 1997, p. 124).
See also Ellipsoidal Wave Equation ,
Lamé's Differential Equation
Types ,
Wangerin Differential Equation
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References Byerly, W. E. An Elementary Treatise on Fourier's Series, and Spherical, Cylindrical, and Ellipsoidal
Harmonics, with Applications to Problems in Mathematical Physics. Moon, P. and Spencer, D. E. Field
Theory for Engineers. Ward, R. S.
"The Nahm Equations, Finite-Gap Potentials and Lamé Functions."
J. Phys. A: Math. Gen. 20 , 2679-2683, 1987. Whittaker,
E. T. and Watson, G. N. A
Course in Modern Analysis, 4th ed. Zwillinger, D. Handbook
of Differential Equations, 3rd ed. Referenced on Wolfram|Alpha Lamé's Differential
Equation
Cite this as:
Weisstein, Eric W. "Lamé's Differential Equation." From MathWorld https://mathworld.wolfram.com/LamesDifferentialEquation.html
Subject classifications
![(x^2-b^2)(x^2-c^2)(d^2z)/(dx^2)+x(x^2-b^2+x^2-c^2)(dz)/(dx)-[m(m+1)x^2-(b^2+c^2)p]z=0.](/images/equations/LamesDifferentialEquation/NumberedEquation1.svg)
and is known as an ellipsoidal
harmonic of the first kind, or Lamé function. Whittaker and Watson (1990,
pp. 554-555) give the alternative forms
![4Delta_lambdad/(dlambda)[Delta_lambda(dLambda)/(dlambda)]=[n(n+1)lambda+C]Lambda](/images/equations/LamesDifferentialEquation/Inline2.svg)
/(dlambda)](/images/equations/LamesDifferentialEquation/Inline3.svg)
![=([n(n+1)lambda+C]Lambda)/(4Delta_lambda)](/images/equations/LamesDifferentialEquation/Inline4.svg)
![(d^2Lambda)/(du^2)=[n(n+1)P(u)+C-1/3n(n+1)(a^2+b^2+c^2)]Lambda](/images/equations/LamesDifferentialEquation/Inline5.svg)
is a Weierstrass elliptic function,
is a Jacobi elliptic function, and
![y^('')+1/2[1/(x-a_1)+1/(x-a_2)+1/(x-a_3)]y^'+1/4[(A_0+A_1x)/((x-a_1)(x-a_2)(x-a_3))]y=0](/images/equations/LamesDifferentialEquation/NumberedEquation2.svg)
![y^('')+1/2[1/x+1/(x-a_2)+1/(x-a_3)]y^'+1/4[((a_2^2+a_3^2)q-p(p+1)x+kappax^2)/(x(x-a_2)(x-a_3))]y=0](/images/equations/LamesDifferentialEquation/NumberedEquation3.svg)
