so
2 x+ 2 y+ 2 x
dy
dx
+ 4 y
dy
dx
= 0
Hence(x+y)+(x+ 2 y)
dy
dx
= 0
and so
dy
dx
=−
x+y
x+ 2 y
B.This is a standard application of implicit differentiation. Ify=sin−^1 x
thenx=siny. But note that as usual with inverse trigonometric func-
tions we must restrict the range ofyto, say,−
π
2
≤y≤
π
2
to obtain
a single valued function (184
➤
).
Hence, on this range
dx
dy
=cosy
=
√
1 −sin^2 y
where we have taken the positive root since the cosine is positive on
−
π
2
≤y≤
π
2
=
√
1 −x^2
So, using
dy
dx
= 1
/
dx
dy
(see above) we get
dy
dx
=
1
√
1 −x^2
C.y=axis another case where we can use implicit differentiation to
advantage. If we take logs to baseewe have:
lny=lnax=xlna
Now differentiate through with respect tox:
d
dx
(lny)=
d
dx
(xlna)
or
1
y
dy
dx
=lna
by using the chain rule on the left-hand side.
So
dy
dx
=ylna=axlna