2025年2月28日星期五

Inverse mapping and implicit mapping theorem

Inverse mapping theorem:

is an open set of , is a mapping.

if , then there is a open neighborhood of and open neighborhood of

such that

  1. is an invertible mapping.
  2. Its inverse is still a mapping.
Proof:

Translation do not change the topology or differential properties of the function

so we can assume , and set .

From we know is invertible.

is an identity mapping because (chain rule)

is a linear mapping so ,

().

Linear transformation do not change the topology or differential properties of the function

so we can assume .

Let’s review a classic conclusion:

A linear mapping is invertible and has , i.e., is injective.

Furthermore, we have the following:

for a linear mapping with , then is invertible.

In fact, suppose , then , which implies that .

This example means that a invertible mapping such as an identity map is still invertible after a small twist.

In general, any invertible linear mapping remains invertible under perturbation.

Back to inverse mapping theorem,

we need to represent the difference between and , that is .

So is a mapping from to and

, , .

Accroding to differential mean value theorem ,

Given , solve equation

It is equivalent to finding the fixed point on in .

Firstly, .

Further, , it is a constraction mapping.

So the equation has a unique solution.

Note , thus is bijective. (The proof of (1) is done.)

Define is the inverse of on , from together with

we know so .

.

Take the norm on both sides of the equation:

.

We can infer that , , is a continous mapping.

Further, is a differentiable mapping. Let , then for ,

we have:

This can be rewritten as: .

Thus,

is differentiable at , .

From the proof of above:

Since , we know .

We have proved is a mapping , we finally obtain by analogy.

Implicit mapping theorem:

Let be a subset of , and represents a point in , where , .

Let be a map, where

Assume that , , and , then

Then, in a neighborhood around , there exists a unique map such that

  1. , , for ,
  2. ,

where

Proof:

Let be defined by

The original problem is transferred to solving equation in the neighborhood of .

Now , and

By the inverse function theorem, near , is invertible.

If is near and exists near , then , which leads to the equation:

Thus,

Two-dimentional case:

The function is called the implicit function defined by .

四个“反向 / companion”不等式(按“缺口坐标”统一构造)

四个反向/companion 不等式(缺口坐标法) 四个“反向 / companion”不等式(按“缺口坐标”统一构造) 0) 统一记号 \(n\ge 2\)。 ...