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In multivariable calculus, the implicit function theorem is a tool which allows relations to be converted to functions. It does this by representing the relation as the graph of a function. There may not be a single function whose graph is the entire relation, but there may be such a function on a restriction of the domain of the relation. The implicit function theorem gives a sufficient condition to ensure that there is such a function.

The theorem states that if the equation ${\displaystyle R(x,y)=0}$ (an implicit function) satisfies some mild conditions on its partial derivatives, then one can in principle solve this equation for ${\displaystyle y}$, at least over some small interval. Geometrically, the locus defined by ${\displaystyle R(x,y)=0}$ will overlap locally with the graph of a function ${\displaystyle y=f(x)}$ (an explicit function, see article on implicit functions).

First example

If we define the function ${\displaystyle f(x,y)=x^{2}+y^{2}}$, then the equation ${\displaystyle f(x,y)=1}$ cuts out the unit circle as the level set ${\displaystyle \{(x,y)|f(x,y)=1\}}$. There is no way to represent the unit circle as the graph of a function of one variable ${\displaystyle y=g(x)}$ because for each choice of ${\displaystyle x\in (-1,1),}$ there are two choices of ${\displaystyle y}$, namely ${\displaystyle \pm {\sqrt {1-x^{2}}}}$.

However, it is possible to represent part of the circle as the graph of a function of one variable. If we let ${\displaystyle g_{1}(x)={\sqrt {1-x^{2}}}}$ for ${\displaystyle -1<x<1}$, then the graph of ${\displaystyle y=g_{1}(x)}$ provides the upper half of the circle. Similarly, if ${\displaystyle g_{2}(x)=-{\sqrt {1-x^{2}}}}$, then the graph of ${\displaystyle y=g_{2}(x)}$ gives the lower half of the circle.

The purpose of the implicit function theorem is to tell us the existence of functions like ${\displaystyle g_{1}(x)}$ and ${\displaystyle g_{2}(x)}$, even in situations where we cannot write down explicit formulas. It guarantees that ${\displaystyle g_{1}(x)}$ and ${\displaystyle g_{2}(x)}$ are differentiable, and it even works in situations where we do not have a formula for ${\displaystyle f(x,y)}$.

Statement of the theorem

Let f : R^n+m → R^m be a continuously differentiable function. We think of R^n+m as the Cartesian product Rⁿ × R^m, and we write a point of this product as (x,y) = (x₁, ..., x_n, y₁, ..., y_m). Starting from the given function f, our goal is to construct a function g : Rⁿ → R^m whose graph (x, g(x)) is precisely the set of all (x, y) such that f(x, y) = 0.

As noted above, this may not always be possible. We will therefore fix a point (a,b) = (a₁, ..., a_n, b₁, ..., b_m) which satisfies f(a, b) = 0, and we will ask for a g that works near the point (a, b). In other words, we want an open set U of Rⁿ, an open set V of R^m, and a function g : U → V such that the graph of g satisfies the relation f = 0 on U × V. In symbols,

${\displaystyle \{(\mathbf {x} ,g(\mathbf {x} ))\mid \mathbf {x} \in U\}=\{(\mathbf {x} ,\mathbf {y} )\in U\times V\mid f(\mathbf {x} ,\mathbf {y} )=0\}.}$

To state the implicit function theorem, we need the Jacobian, also called the differential or total derivative, of ${\displaystyle f}$. This is the matrix of partial derivatives of ${\displaystyle f}$. Abbreviating (a₁, ..., a_n, b₁, ..., b_m) to (a, b), the Jacobian matrix is

${\displaystyle {\begin{matrix}(Df)(\mathbf {a} ,\mathbf {b} )&=&\left[{\begin{matrix}{\frac {\partial f_{1}}{\partial x_{1}}}(\mathbf {a} ,\mathbf {b} )&\cdots &{\frac {\partial f_{1}}{\partial x_{n}}}(\mathbf {a} ,\mathbf {b} )\\\vdots &\ddots &\vdots \\{\frac {\partial f_{m}}{\partial x_{1}}}(\mathbf {a} ,\mathbf {b} )&\cdots &{\frac {\partial f_{m}}{\partial x_{n}}}(\mathbf {a} ,\mathbf {b} )\end{matrix}}\right|\left.{\begin{matrix}{\frac {\partial f_{1}}{\partial y_{1}}}(\mathbf {a} ,\mathbf {b} )&\cdots &{\frac {\partial f_{1}}{\partial y_{m}}}(\mathbf {a} ,\mathbf {b} )\\\vdots &\ddots &\vdots \\{\frac {\partial f_{m}}{\partial y_{1}}}(\mathbf {a} ,\mathbf {b} )&\cdots &{\frac {\partial f_{m}}{\partial y_{m}}}(\mathbf {a} ,\mathbf {b} )\\\end{matrix}}\right]\\&=&{\begin{bmatrix}X&|&Y\end{bmatrix}}\\\end{matrix}}}$

where ${\displaystyle X}$ is the matrix of partial derivatives in the ${\displaystyle x}$'s and ${\displaystyle Y}$ is the matrix of partial derivatives in the ${\displaystyle y}$'s. The implicit function theorem says that if ${\displaystyle Y}$ is an invertible matrix, then there are ${\displaystyle U}$, ${\displaystyle V}$, and ${\displaystyle g}$ as desired. Writing all the hypotheses together gives the following statement.

Let f : R^n+m → R^m be a continuously differentiable function, and let R^n+m have coordinates (x, y). Fix a point (a₁,...,a_n,b₁,...,b_m) = (a,b) with f(a,b)=c, where c∈ R^m. If the matrix [(∂f_i/∂y_j)(a,b)] is invertible, then there exists an open set U containing a, an open set V containing b, and a unique continuously differentiable function g:U → V such that

${\displaystyle \{(\mathbf {x} ,g(\mathbf {x} ))|\mathbf {x} \in U\}=\{(\mathbf {x} ,\mathbf {y} )\in U\times V|f(\mathbf {x} ,\mathbf {y} )=\mathbf {c} \}.}$

Regularity

It can be proven that whenever we have the additional hypothesis that f is continuously differentiable up to k times inside U×V, then the same holds true for the explicit function g inside U and

${\displaystyle {\frac {\partial g}{\partial x_{j}}}(x)=-\left({\frac {\partial f}{\partial y}}(x,g(x))\right)^{-1}{\frac {\partial f}{\partial x_{j}}}(x,g(x))}$.

Similarly, if f is analytic inside U×V, then the same holds true for the explicit function g inside U.^[1] This generalization is called the analytic implicit function theorem.

The circle example

Let us go back to the example of the unit circle. In this case ${\displaystyle n=m=1}$ and ${\displaystyle f(x,y)=x^{2}+y^{2}-1}$. The matrix of partial derivatives is just a 1×2 matrix, given by

${\displaystyle {\begin{matrix}(Df)(a,b)&=&{\begin{bmatrix}{\frac {\partial f}{\partial x}}(a,b)&{\frac {\partial f}{\partial y}}(a,b)\\\end{bmatrix}}\\&=&{\begin{bmatrix}2a&2b\end{bmatrix}}.\\\end{matrix}}}$

Thus, here, ${\displaystyle Y}$ is just a number; the linear map defined by it is invertible iff ${\displaystyle b\neq 0}$. By the implicit function theorem we see that we can write the circle in the form ${\displaystyle y=g(x)}$ for all points where ${\displaystyle y\neq 0}$. For ${\displaystyle (-1,0)}$ and ${\displaystyle (1,0)}$ we run into trouble, as noted before.

Application: change of coordinates

Suppose we have an m-dimensional space, parametrised by a set of coordinates ${\displaystyle (x_{1},\ldots ,x_{m})}$. We can introduce a new coordinate system ${\displaystyle (x'_{1},\ldots ,x'_{m})}$ by supplying m functions ${\displaystyle h_{1}\ldots h_{m}}$. These functions allow to calculate the new coordinates ${\displaystyle (x'_{1},\ldots ,x'_{m})}$ of a point, given the point's old coordinates ${\displaystyle (x_{1},\ldots ,x_{m})}$ using ${\displaystyle x'_{1}=h_{1}(x_{1},\ldots ,x_{m}),\ldots ,x'_{m}=h_{m}(x_{1},\ldots ,x_{m})}$. One might want to verify if the opposite is possible: given coordinates ${\displaystyle (x'_{1},\ldots ,x'_{m})}$, can we 'go back' and calculate the same point's original coordinates ${\displaystyle (x_{1},\ldots ,x_{m})}$? The implicit function theorem will provide an answer to this question. The (new and old) coordinates ${\displaystyle (x'_{1},\ldots ,x'_{m},x_{1},\ldots ,x_{m})}$ are related by ${\displaystyle f=0}$, with

${\displaystyle f(x'_{1},\ldots ,x'_{m},x_{1},\ldots x_{m})=(h_{1}(x_{1},\ldots x_{m})-x'_{1},\ldots ,h_{m}(x_{1},\ldots ,x_{m})-x'_{m}).}$

Now the Jacobian matrix of f at a certain point ${\displaystyle (a,b)}$ [ where ${\displaystyle a=(x'_{1},\ldots ,x'_{m}),b=(x_{1},\ldots ,x_{m})}$ ] is given by

${\displaystyle {\begin{matrix}(Df)(a,b)&=&{\begin{bmatrix}-1&\cdots &0&{\frac {\partial h_{1}}{\partial x_{1}}}(b)&\cdots &{\frac {\partial h_{1}}{\partial x_{m}}}(b)\\\vdots &\ddots &\vdots &\vdots &\ddots &\vdots \\0&\cdots &-1&{\frac {\partial h_{m}}{\partial x_{1}}}(b)&\cdots &{\frac {\partial h_{m}}{\partial x_{m}}}(b)\\\end{bmatrix}}\\&=&{\begin{bmatrix}-1_{m}&|&J\end{bmatrix}}.\\\end{matrix}}}$

where ${\displaystyle 1_{m}}$ denotes the ${\displaystyle m\times m}$ identity matrix, and J is the ${\displaystyle m\times m}$ matrix of partial derivatives, evaluated at ${\displaystyle (a,b)}$. (In the above, these blocks were denoted by X and Y. As it happens, in this particular application of the theorem, neither matrix depends on ${\displaystyle a}$.) The implicit function theorem now states that we can locally express ${\displaystyle (x_{1},\ldots ,x_{m})}$ as a function of ${\displaystyle (x'_{1},\ldots ,x'_{m})}$ if J is invertible. Demanding J is invertible is equivalent to ${\displaystyle \det J\neq 0}$, thus we see that we can go back from the primed to the unprimed coordinates if the determinant of the Jacobian J is non-zero. This statement is also known as the inverse function theorem.

Example: polar coordinates

As a simple application of the above, consider the plane, parametrised by polar coordinates ${\displaystyle (R,\theta )}$. We can go to a new coordinate system (cartesian coordinates) by defining functions ${\displaystyle x(R,\theta )=R\cos \theta }$ and ${\displaystyle y(R,\theta )=R\sin \theta }$. This makes it possible given any point ${\displaystyle (R,\theta )}$ to find corresponding cartesian coordinates ${\displaystyle (x,y)}$. When can we go back and convert cartesian into polar coordinates? By the previous example, we need ${\displaystyle \det J\neq 0}$, with

${\displaystyle J={\begin{bmatrix}{\frac {\partial x(R,\theta )}{\partial R}}&{\frac {\partial x(R,\theta )}{\partial \theta }}\\{\frac {\partial y(R,\theta )}{\partial R}}&{\frac {\partial y(R,\theta )}{\partial \theta }}\\\end{bmatrix}}={\begin{bmatrix}\cos \theta &-R\sin \theta \\\sin \theta &R\cos \theta \end{bmatrix}}.}$

Since ${\displaystyle \det J=R}$, the conversion back to polar coordinates is only possible if ${\displaystyle R\neq 0}$. This is a consequence of the fact that at the origin, polar coordinates don't exist: the value of ${\displaystyle \theta }$ is not well-defined.

Generalizations

Banach space version

Based on the inverse function theorem in Banach spaces, it is possible to extend the implicit function theorem to Banach space valued mappings.

Let ${\displaystyle X}$, ${\displaystyle Y}$, ${\displaystyle Z}$ be Banach spaces. Let the mapping ${\displaystyle f:X\times Y\to Z}$ be continuously Fréchet differentiable. If ${\displaystyle (x_{0},y_{0})\in X\times Y}$, ${\displaystyle f(x_{0},y_{0})=0}$, and ${\displaystyle y\mapsto Df(x_{0},y_{0})(0,y)}$ is a Banach space isomorphism from ${\displaystyle Y}$ onto ${\displaystyle Z}$, then there exist neighbourhoods ${\displaystyle U}$ of ${\displaystyle x_{0}}$ and ${\displaystyle V}$ of ${\displaystyle y_{0}}$ and a Frechet differentiable function ${\displaystyle g:U\to V}$ such that ${\displaystyle f(x,g(x))=0}$ and ${\displaystyle f(x,y)=0}$ if and only if ${\displaystyle y=g(x)}$, for all ${\displaystyle (x,y)\in U\times V}$.

Implicit functions from non-differentiable functions

Various forms of the implicit function theorem exist for the case when the function ${\displaystyle f}$ is not differentiable. It is standard that it holds in one dimension.^[2] The following more general form was proven by Kumagai^[3] based on an observation by Jittorntrum.^[4]

Consider a continuous function ${\displaystyle f:R^{n}\times R^{m}\rightarrow R^{n}}$ such that ${\displaystyle f(x_{0},y_{0})=0}$. If there exist open neighbourhoods ${\displaystyle A\subset R^{n}}$ and ${\displaystyle B\subset R^{m}}$ of ${\displaystyle x_{0}}$ and ${\displaystyle y_{0}}$, respectively, such that, for all ${\displaystyle y\in B}$, ${\displaystyle f(\cdot ,y):A\rightarrow R^{n}}$ is locally one-to-one then there exist open neighbourhoods ${\displaystyle A_{0}\subset R^{n}}$ and ${\displaystyle B_{0}\subset R^{m}}$ of ${\displaystyle x_{0}}$ and ${\displaystyle y_{0}}$, such that, for all ${\displaystyle y\in B_{0}}$, the equation

${\displaystyle f(x,y)=0}$

has a unique solution

${\displaystyle x=g(y)\in A_{0}}$,

where ${\displaystyle g}$ is a continuous function from ${\displaystyle B_{0}}$ into ${\displaystyle A_{0}}$.

See also

• Constant rank theorem: Both the implicit function theorem and the Inverse function theorem can be seen as special cases of the constant rank theorem.

Notes

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References

• Other Sports Official Kull from Drumheller, has hobbies such as telescopes, property developers in singapore and crocheting. Identified some interesting places having spent 4 months at Saloum Delta.
  
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• Other Sports Official Kull from Drumheller, has hobbies such as telescopes, property developers in singapore and crocheting. Identified some interesting places having spent 4 months at Saloum Delta.
  
  my web-site http://himerka.com/

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