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 Page 1


Handout 4. The Inverse and Implicit Function Theorems
Recall that a linear map L : R
n
? R
n
with detL 6= 0 is one-to-one. By the
next theorem, a continuously di?erentiable map between regions in R
n
is locally
one-to-one near any point where its di?erential has nonzero determinant.
Inverse Function Theorem. Suppose U is open in R
n
and F : U ? R
n
is a
continuously di?erentiable mapping, p ? U, and the di?erential at p, dF
p
, is an
isomorphism. Then there exist neighborhoods V of p in U and W of F(p) in R
n
so
that F :V ?W has a continuously di?erentiable inverse F
-1
:W ?V with
d(F
-1
)
y
=

dF
F
-1
{y}

-1
for y?W .
Moreover, F
-1
is smooth (in?nitely di?erentiable) whenever F is smooth.
Thus, the equation y = F(x), written in component form as a system of n
equations,
y
i
= F
i
(x
1
,...,x
n
) for i = 1,...,n ,
can be solved for x
1
,...,x
n
in terms of y
1
,...,y
n
provided we restrict the points x
and y to small enough neighborhoods of p and F(p). The solutions are then unique
and continuously di?erentaible.
Proof : Let L =dF
p
, and note that the number
? =
1
2
inf
|v|=1
|L(v)| =
1
2sup
|w|=1
|L
-1
(w)|
is positive. Since dF
x
is continuous in x at x =p, we have the inequality
sup
|v|=1
|dF
x
(v)-L(v)| = ?
true for all x in some su?ciently small ball V about p in U. Thus, by linearity,
|dF
x
(v)-L(v)| = ?|v| for all v?R
n
and x?V .
With each y?R
n
, we associate the function
A
y
(x) = x + L
-1

y - F(x)

.
Then
F(x) =y if and only if x is a fixed point of A
y
.
1
Page 2


Handout 4. The Inverse and Implicit Function Theorems
Recall that a linear map L : R
n
? R
n
with detL 6= 0 is one-to-one. By the
next theorem, a continuously di?erentiable map between regions in R
n
is locally
one-to-one near any point where its di?erential has nonzero determinant.
Inverse Function Theorem. Suppose U is open in R
n
and F : U ? R
n
is a
continuously di?erentiable mapping, p ? U, and the di?erential at p, dF
p
, is an
isomorphism. Then there exist neighborhoods V of p in U and W of F(p) in R
n
so
that F :V ?W has a continuously di?erentiable inverse F
-1
:W ?V with
d(F
-1
)
y
=

dF
F
-1
{y}

-1
for y?W .
Moreover, F
-1
is smooth (in?nitely di?erentiable) whenever F is smooth.
Thus, the equation y = F(x), written in component form as a system of n
equations,
y
i
= F
i
(x
1
,...,x
n
) for i = 1,...,n ,
can be solved for x
1
,...,x
n
in terms of y
1
,...,y
n
provided we restrict the points x
and y to small enough neighborhoods of p and F(p). The solutions are then unique
and continuously di?erentaible.
Proof : Let L =dF
p
, and note that the number
? =
1
2
inf
|v|=1
|L(v)| =
1
2sup
|w|=1
|L
-1
(w)|
is positive. Since dF
x
is continuous in x at x =p, we have the inequality
sup
|v|=1
|dF
x
(v)-L(v)| = ?
true for all x in some su?ciently small ball V about p in U. Thus, by linearity,
|dF
x
(v)-L(v)| = ?|v| for all v?R
n
and x?V .
With each y?R
n
, we associate the function
A
y
(x) = x + L
-1

y - F(x)

.
Then
F(x) =y if and only if x is a fixed point of A
y
.
1
Since dA
y
= Id -L
-1

dF
x

=L
-1

L-dF
x

, the above inequalities imply that
|dA
y
x
(v)| =
1
2
|v| for x?V and v?R
n
.
Thus, for w,x?V,
|A
y
(w)-A
y
(x)| = |
Z
1
0
d
dt
A
y

x+t(w-x)

dt|
=
Z
1
0
|dA
y
x+t(w-x)
(w-x)|dt =
1
2
|w-x| . (*)
ItfollowsthatA
y
hasatmostone?xedpointinV,andthereisatmostonesolution
x?V for F(x) =y.
Next we verify that W = F(V) is open. To do this, we choose, for any point
˜ w =F(˜ x)?W with ˜ x?V,asu?cientlysmallpositiver,sothattheballB =B
r
(˜ x)
has closure B ?V. We will show that B
?r
(˜ w)?W. This will give the openness of
W.
For any y?B
?r
(˜ w), and A
y
as above,
|A
y
(˜ x)- ˜ x| = |L
-1
(y- ˜ w)| <
1
2?
?r =
r
2
.
For x?B it follows that
|A
y
(x)- ˜ x| = |A
y
(x)-A
y
(˜ x)|+|A
y
(˜ x)- ˜ x| <
1
2
|x- ˜ x|+
r
2
= r .
So A
y
(x)?B. By (*) A
y
thus gives a contraction of B. So A
y
has ?xed point x in
B, and y =F(x)?F(B)?F(V) =W. Thus B
?r
(˜ w)?W.
Next we show that F
-1
: W ? V is di?erentiable at each point y ? W and
that
d(F
-1
)
y
= M
-1
where M =dF
x
with x =F
-1
(y)?V .
Supposey+k?W andx+h =F
-1
(y+k)?V. Then, withourpreviousnotations,
|h-L
-1
(k)| = |h-L
-1

F(x+h)-F(x)

| = |A
y
(x+h)-A
y
(x)|=
1
2
|h| ,
which implies that
1
2
|h| = |L
-1
(k)| =

1
2?

|k| .
2
Page 3


Handout 4. The Inverse and Implicit Function Theorems
Recall that a linear map L : R
n
? R
n
with detL 6= 0 is one-to-one. By the
next theorem, a continuously di?erentiable map between regions in R
n
is locally
one-to-one near any point where its di?erential has nonzero determinant.
Inverse Function Theorem. Suppose U is open in R
n
and F : U ? R
n
is a
continuously di?erentiable mapping, p ? U, and the di?erential at p, dF
p
, is an
isomorphism. Then there exist neighborhoods V of p in U and W of F(p) in R
n
so
that F :V ?W has a continuously di?erentiable inverse F
-1
:W ?V with
d(F
-1
)
y
=

dF
F
-1
{y}

-1
for y?W .
Moreover, F
-1
is smooth (in?nitely di?erentiable) whenever F is smooth.
Thus, the equation y = F(x), written in component form as a system of n
equations,
y
i
= F
i
(x
1
,...,x
n
) for i = 1,...,n ,
can be solved for x
1
,...,x
n
in terms of y
1
,...,y
n
provided we restrict the points x
and y to small enough neighborhoods of p and F(p). The solutions are then unique
and continuously di?erentaible.
Proof : Let L =dF
p
, and note that the number
? =
1
2
inf
|v|=1
|L(v)| =
1
2sup
|w|=1
|L
-1
(w)|
is positive. Since dF
x
is continuous in x at x =p, we have the inequality
sup
|v|=1
|dF
x
(v)-L(v)| = ?
true for all x in some su?ciently small ball V about p in U. Thus, by linearity,
|dF
x
(v)-L(v)| = ?|v| for all v?R
n
and x?V .
With each y?R
n
, we associate the function
A
y
(x) = x + L
-1

y - F(x)

.
Then
F(x) =y if and only if x is a fixed point of A
y
.
1
Since dA
y
= Id -L
-1

dF
x

=L
-1

L-dF
x

, the above inequalities imply that
|dA
y
x
(v)| =
1
2
|v| for x?V and v?R
n
.
Thus, for w,x?V,
|A
y
(w)-A
y
(x)| = |
Z
1
0
d
dt
A
y

x+t(w-x)

dt|
=
Z
1
0
|dA
y
x+t(w-x)
(w-x)|dt =
1
2
|w-x| . (*)
ItfollowsthatA
y
hasatmostone?xedpointinV,andthereisatmostonesolution
x?V for F(x) =y.
Next we verify that W = F(V) is open. To do this, we choose, for any point
˜ w =F(˜ x)?W with ˜ x?V,asu?cientlysmallpositiver,sothattheballB =B
r
(˜ x)
has closure B ?V. We will show that B
?r
(˜ w)?W. This will give the openness of
W.
For any y?B
?r
(˜ w), and A
y
as above,
|A
y
(˜ x)- ˜ x| = |L
-1
(y- ˜ w)| <
1
2?
?r =
r
2
.
For x?B it follows that
|A
y
(x)- ˜ x| = |A
y
(x)-A
y
(˜ x)|+|A
y
(˜ x)- ˜ x| <
1
2
|x- ˜ x|+
r
2
= r .
So A
y
(x)?B. By (*) A
y
thus gives a contraction of B. So A
y
has ?xed point x in
B, and y =F(x)?F(B)?F(V) =W. Thus B
?r
(˜ w)?W.
Next we show that F
-1
: W ? V is di?erentiable at each point y ? W and
that
d(F
-1
)
y
= M
-1
where M =dF
x
with x =F
-1
(y)?V .
Supposey+k?W andx+h =F
-1
(y+k)?V. Then, withourpreviousnotations,
|h-L
-1
(k)| = |h-L
-1

F(x+h)-F(x)

| = |A
y
(x+h)-A
y
(x)|=
1
2
|h| ,
which implies that
1
2
|h| = |L
-1
(k)| =

1
2?

|k| .
2
We now obtain the desired formula for d(F
-1
)
y
by computing that
|F
-1
(y+k)-F
-1
(y)-M
-1
k|
|k|
=
|h-M
-1
k|
|k|
= |M
-1

F(x+h)-F(x)-Mh
|h|

|
|h|
|k|
=
1
?
|M
-1

F(x+h)-F(x)-Mh
|h|

| ,
which approaches 0 as |k|? 0 because M =dF
x
.
Finally, since the inversion of matrices is, by Cramer’s rule, a continuous, in
fact, smooth, function of the entries, we deduce from our formula that F
-1
is
continuously di?erentiable. Moreover, repeatly di?erentiating the formula shows
that F
-1
is a smooth mapping whenever F is.
Next we turn to the Implicit Function Theorem. This important theorem gives
a condition under which one can locally solve an equation (or, via vector notation,
system of equations)
f(x,y) = 0
for y in terms of x. Geometrically the solution locus of points (x,y) satisfying the
equation is thus represented as the graph of a function y =g(x). For smooth f this
is a smooth manifold.
Let (x,y) =

(x
1
,...,x
m
),(y
1
,...,y
n
)

denote a point in R
m
×R
n
, and, for
an R
n
-valued function f(x,y) = (f
1
,...,f
n
)(x,y) , let d
x
f denote the partial
di?erential represented by the n × m matrix

?f
i
?x
j

and d
y
f denote the partial
di?erential represented by the n×n matrix

?f
i
?y
j

.
ImplicitFunctionTheorem. Supposef(x,y) is a continuously di?erentiableR
n
-
valued function near a point (a,b)? R
m
×R
n
, f(a,b) = 0, and detd
y
f|
(a,b)
6= 0 .
Then
{(x,y)?W : f(x,y) = 0} = {

x,g(x)

: x?X}
for some open neighborhood W of (a,b) in R
m
× R
n
and some continuously
di?erentiable functiong mapping someR
m
neighborhoodX ofa intoR
n
. Moreover,
(d
x
g)
x
= -(d
y
f)
-1
|
(x,g(x))
d
x
f|
(x,g(x))
,
and g is smooth in case f is smooth.
3
Page 4


Handout 4. The Inverse and Implicit Function Theorems
Recall that a linear map L : R
n
? R
n
with detL 6= 0 is one-to-one. By the
next theorem, a continuously di?erentiable map between regions in R
n
is locally
one-to-one near any point where its di?erential has nonzero determinant.
Inverse Function Theorem. Suppose U is open in R
n
and F : U ? R
n
is a
continuously di?erentiable mapping, p ? U, and the di?erential at p, dF
p
, is an
isomorphism. Then there exist neighborhoods V of p in U and W of F(p) in R
n
so
that F :V ?W has a continuously di?erentiable inverse F
-1
:W ?V with
d(F
-1
)
y
=

dF
F
-1
{y}

-1
for y?W .
Moreover, F
-1
is smooth (in?nitely di?erentiable) whenever F is smooth.
Thus, the equation y = F(x), written in component form as a system of n
equations,
y
i
= F
i
(x
1
,...,x
n
) for i = 1,...,n ,
can be solved for x
1
,...,x
n
in terms of y
1
,...,y
n
provided we restrict the points x
and y to small enough neighborhoods of p and F(p). The solutions are then unique
and continuously di?erentaible.
Proof : Let L =dF
p
, and note that the number
? =
1
2
inf
|v|=1
|L(v)| =
1
2sup
|w|=1
|L
-1
(w)|
is positive. Since dF
x
is continuous in x at x =p, we have the inequality
sup
|v|=1
|dF
x
(v)-L(v)| = ?
true for all x in some su?ciently small ball V about p in U. Thus, by linearity,
|dF
x
(v)-L(v)| = ?|v| for all v?R
n
and x?V .
With each y?R
n
, we associate the function
A
y
(x) = x + L
-1

y - F(x)

.
Then
F(x) =y if and only if x is a fixed point of A
y
.
1
Since dA
y
= Id -L
-1

dF
x

=L
-1

L-dF
x

, the above inequalities imply that
|dA
y
x
(v)| =
1
2
|v| for x?V and v?R
n
.
Thus, for w,x?V,
|A
y
(w)-A
y
(x)| = |
Z
1
0
d
dt
A
y

x+t(w-x)

dt|
=
Z
1
0
|dA
y
x+t(w-x)
(w-x)|dt =
1
2
|w-x| . (*)
ItfollowsthatA
y
hasatmostone?xedpointinV,andthereisatmostonesolution
x?V for F(x) =y.
Next we verify that W = F(V) is open. To do this, we choose, for any point
˜ w =F(˜ x)?W with ˜ x?V,asu?cientlysmallpositiver,sothattheballB =B
r
(˜ x)
has closure B ?V. We will show that B
?r
(˜ w)?W. This will give the openness of
W.
For any y?B
?r
(˜ w), and A
y
as above,
|A
y
(˜ x)- ˜ x| = |L
-1
(y- ˜ w)| <
1
2?
?r =
r
2
.
For x?B it follows that
|A
y
(x)- ˜ x| = |A
y
(x)-A
y
(˜ x)|+|A
y
(˜ x)- ˜ x| <
1
2
|x- ˜ x|+
r
2
= r .
So A
y
(x)?B. By (*) A
y
thus gives a contraction of B. So A
y
has ?xed point x in
B, and y =F(x)?F(B)?F(V) =W. Thus B
?r
(˜ w)?W.
Next we show that F
-1
: W ? V is di?erentiable at each point y ? W and
that
d(F
-1
)
y
= M
-1
where M =dF
x
with x =F
-1
(y)?V .
Supposey+k?W andx+h =F
-1
(y+k)?V. Then, withourpreviousnotations,
|h-L
-1
(k)| = |h-L
-1

F(x+h)-F(x)

| = |A
y
(x+h)-A
y
(x)|=
1
2
|h| ,
which implies that
1
2
|h| = |L
-1
(k)| =

1
2?

|k| .
2
We now obtain the desired formula for d(F
-1
)
y
by computing that
|F
-1
(y+k)-F
-1
(y)-M
-1
k|
|k|
=
|h-M
-1
k|
|k|
= |M
-1

F(x+h)-F(x)-Mh
|h|

|
|h|
|k|
=
1
?
|M
-1

F(x+h)-F(x)-Mh
|h|

| ,
which approaches 0 as |k|? 0 because M =dF
x
.
Finally, since the inversion of matrices is, by Cramer’s rule, a continuous, in
fact, smooth, function of the entries, we deduce from our formula that F
-1
is
continuously di?erentiable. Moreover, repeatly di?erentiating the formula shows
that F
-1
is a smooth mapping whenever F is.
Next we turn to the Implicit Function Theorem. This important theorem gives
a condition under which one can locally solve an equation (or, via vector notation,
system of equations)
f(x,y) = 0
for y in terms of x. Geometrically the solution locus of points (x,y) satisfying the
equation is thus represented as the graph of a function y =g(x). For smooth f this
is a smooth manifold.
Let (x,y) =

(x
1
,...,x
m
),(y
1
,...,y
n
)

denote a point in R
m
×R
n
, and, for
an R
n
-valued function f(x,y) = (f
1
,...,f
n
)(x,y) , let d
x
f denote the partial
di?erential represented by the n × m matrix

?f
i
?x
j

and d
y
f denote the partial
di?erential represented by the n×n matrix

?f
i
?y
j

.
ImplicitFunctionTheorem. Supposef(x,y) is a continuously di?erentiableR
n
-
valued function near a point (a,b)? R
m
×R
n
, f(a,b) = 0, and detd
y
f|
(a,b)
6= 0 .
Then
{(x,y)?W : f(x,y) = 0} = {

x,g(x)

: x?X}
for some open neighborhood W of (a,b) in R
m
× R
n
and some continuously
di?erentiable functiong mapping someR
m
neighborhoodX ofa intoR
n
. Moreover,
(d
x
g)
x
= -(d
y
f)
-1
|
(x,g(x))
d
x
f|
(x,g(x))
,
and g is smooth in case f is smooth.
3
Proof : De?ne F(x,y) = (x,f(x,y)

, and compute that
detdF
(a,b)
= det(d
y
f)
(a,b)
6= 0 .
The Inverse Function Theorem thus gives a continuously di?erentiable inverse
F
-1
:W ?V forsomeopenneighborhoodsV of(a,b)andW of(a,0)inR
m
×R
n
.
The set X = {x ? R
m
: (x,0) ? W} is open in R
m
, and, for each point
x?X, F
-1
(x,0) =

x,g(x)

for some point g(x)?R
n
. Moreover,
{(x,y)?W : f(x,y) = 0} = (F
-1
?F)

W nf
-1
{0}

= F
-1

W n(R
m
×{0})

= {

x,g(x)

: x?X} .
One readily checks that g is continuously di?erentiable with
?g
i
?x
j
(x) =
?(F
-1
)
m+i
?x
j
(x,0)
for i = 1,...,n, j = 1,...,m, and x ? W. The formula for (d
x
g)
x
follows from
di?erentiating the identity
f

x,g(x)

= 0 on W ,
and using the chain rule. Smoothness of g follows from smoothness of f by
repeatedly di?erentiating this identity.
4
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FAQs on Inverse and Implicit Function Theorems - Differential Calculus, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is the Inverse Function Theorem?
Ans. The Inverse Function Theorem states that if a function is differentiable at a point and its derivative is non-zero at that point, then the function has an inverse function which is also differentiable at that point.
2. How can the Inverse Function Theorem be used to find the derivative of inverse functions?
Ans. The Inverse Function Theorem provides a method to find the derivative of inverse functions. If a function f(x) has an inverse function g(x), and f'(x) is non-zero at a point, then the derivative of the inverse function g'(x) can be determined using the formula g'(x) = 1 / f'(g(x)).
3. What is the Implicit Function Theorem?
Ans. The Implicit Function Theorem states that if a function is defined implicitly by an equation, then under certain conditions, it is possible to solve for one of the variables in terms of the others and find a function representing that variable.
4. How can the Implicit Function Theorem be used to find derivatives of implicitly defined functions?
Ans. The Implicit Function Theorem provides a method to find derivatives of implicitly defined functions. By differentiating the given equation with respect to a variable, the derivative of the implicitly defined function with respect to that variable can be obtained. This allows us to find the rate of change of the function with respect to that variable.
5. What are the conditions for the Implicit Function Theorem to hold?
Ans. The conditions for the Implicit Function Theorem to hold are: - The equation should define the function implicitly, i.e., it should not be possible to solve the equation explicitly for the function. - The function should be continuously differentiable. - The partial derivative of the equation with respect to the dependent variable should not be zero. - The partial derivatives of the equation with respect to the dependent and independent variables should be continuous.
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