Lamé's Differential Equation (Types)

Whittaker and Watson (1990, pp. 539-540) write Lamé's differential equation for Ellipsoidal Harmonics of the four types as

$\displaystyle 4\Delta(\theta) {d\over d\theta}\left[{F(\theta){d\Lambda(\theta)\over d\theta}}\right]$	$\textstyle =$	$\displaystyle [2m(2m+1)\theta+C]\Lambda(\theta)$
			(1)
$\displaystyle 4\Delta(\theta) {d\over d\theta}\left[{F(\theta){d\Lambda(\theta)\over d\theta}}\right]$	$\textstyle =$	$\displaystyle [(2m+1)(2m+2)\theta+C]\Lambda(\theta)$
			(2)
$\displaystyle 4\Delta(\theta) {d\over d\theta}\left[{F(\theta){d\Lambda(\theta)\over d\theta}}\right]$	$\textstyle =$	$\displaystyle [(2m+2)(2m+3)\theta+C]\Lambda(\theta)$
			(3)
$\displaystyle 4\Delta(\theta) {d\over d\theta}\left[{F(\theta){d\Lambda(\theta)\over d\theta}}\right]$	$\textstyle =$	$\displaystyle [(2m+3)(2m+4)\theta+C]\Lambda(\theta),$
			(4)

$\displaystyle \Delta(\theta)$	$\textstyle \equiv$	$\displaystyle \sqrt{(a^2+\theta)(b^2+\theta)(c^2+\theta)}$	(5)
$\displaystyle \Lambda(\theta)$	$\textstyle \equiv$	$\displaystyle \prod_{q=1}^m(\theta-\theta_q).$	(6)