Applications of Linear Equations with Constant Coefficients 305Case 2. If y' is assumed to be small compa red to 1 (that is, if the bending
of the b eam is small , then (y')^2 is very small compared to 1 and may be
neglected. So equation (37) becomes( 40)II -M
y =EI.
Differentiating this equation twice, we obtain(^4 ) = _!f__ (-M)
y dx^2 EI.
a. If, in addition, I is assumed to b e constant, then substitut ing from
equations (38) we obtain the following simple linear fourth-order differential
equation for the deflection of the b eam
( 41) (^4 ) = -1 (d
2M) = w(x)
y EI dx^2 EI.
Once the load, w(x), and the initial or boundary conditions a re sp ecified the
deflection of the beam, y(x), at a ny point can easily be calculated by finding
the general solution of ( 41) and satisfying t he initial or boundary conditions.
b. If I is assumed to be a variable, then one differentiation of ( 40) followed
by substitution from (38) and (40) yields
( 42)MI' M' I' II
y<3
) = E I 2 - EI= -Iyv
EI
Differentiation of ( 42) followed by some algebraic rearrangement and substi-
tution from (38) and (41), gives
y(4) = --yI' (3) + (I')- yll - - yll + --- -
2
I" VI' V'. I I I EI^2 EI
2I' (3) I
11
II w
=--y --y + -
I I EI'So if we assume y' is small comp ared to 1 and I is a variable, we obtain
the foll owing linear fourth-order differential equation for the deflection of the
beam
(43)