FIRST-ORDER ORDINARY DIFFERENTIAL EQUATIONS
Find an expression for the velocityvof the mass as a function of time, given
that it has an initial velocityv 0.
14.13 Using the results about Laplace transforms given in chapter 13 fordf/dtand
tf(t), show, for a functiony(t)thatsatisfies
tdy
dt+(t−1)y=0 (∗)withy(0) finite, that ̄y(s)=C(1 +s)−^2 for some constantC.
Given thaty(t)=t+∑∞
n=2antn,determineCand show thatan=(−1)n−^1 /(n−1)!. Compare this result with that
obtained by integrating (∗)directly.
14.14 Solve
dy
dx
=
1
x+2y+1.
14.15 Solve
dy
dx
=−
x+y
3 x+3y− 4.
14.16 Ifu=1+tany,calculated(lnu)/dy; hence find the general solution of
dy
dx=tanxcosy(cosy+siny).14.17 Solve
x(1− 2 x^2 y)dy
dx+y=3x^2 y^2 ,given thaty(1) = 1/2.
14.18 A reflecting mirror is made in the shape of the surface of revolution generated by
revolving the curvey(x) about thex-axis. In order that light rays emitted from a
point source at the origin are reflected back parallel to thex-axis, the curvey(x)
must obey
y
x
=
2 p
1 −p^2,
wherep=dy/dx. By solving this equation forx, find the curvey(x).
14.19 Find the curve with the property that at each point on it the sum of the intercepts
on thex-andy-axes of the tangent to the curve (taking account of sign) is equal
to 1.
14.20 Find a parametric solution of
x(
dy
dx) 2
+
dy
dx−y=0as follows.(a) Write an equation foryin terms ofp=dy/dxand show thatp=p^2 +(2px+1)dp
dx.
(b) Usingpas the independent variable, arrange this as a linear first-order
equation forx.