Taylor's theorem
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In calculus, Taylor's theorem, named after the mathematician Brook Taylor, who stated it in 1712, gives the approximation of a differentiable function near a point by a polynomial whose coefficients depend only on the derivatives of the function at that point. This result was first discovered 41 years earlier in 1671 by James Gregory.
Taylor's theorem in one variable
The most basic example of Taylor's theorem is the approximation of the exponential function [ \textrm^x] near x = 0. Namely,
- [ \textrm^x \approx 1 + x + \frac + \frac + \cdots + \frac.]
- [ f(x) = f(a) + \frac(x - a) + \frac(a)}(x - a)^2 + \cdots + \frac(a)}(x - a)^n + R_n ]
The Lagrange form of the remainder term states that there exists a number ξ between a and x such that
- [ R_n = \frac(\xi)} (x-a)^.]
The Cauchy form of the remainder term is
- [ R_n(x) = \int_a^x \frac (t)} (x - t)^n \, dt.]
For some functions f(x), one can show that the remainder term Rn approaches zero as n approaches ∞; those functions can be expressed as a Taylor series in a neighbourhood of the point a and are called analytic.
Taylor's theorem (with the integral formulation of the remainder term) is also valid if the function f has complex values or vector values. Furthermore, there is a version of Taylor's theorem for functions in several variables.
For complex functions analytic in a region containing a circle C surrounding a and its interior, we have a contour integral expression for the remainder
- [ R_n(x) = \frac\int_C \frac(z-x)}dz]
Taylor's theorem for several variables
multi-index notation (see also Taylor series for several variables), Taylor's theorem can be generalized to several variables as follows. Let B be a ball in RN centered at a point a, and f be a real-valued function defined on the closure [\bar] having n+1 continuous partial derivatives at every point. Taylor's theorem asserts that for any [x\in B],
- [f(x)=\sum_^n\frac(x-a)^\alpha+\sum_R_(x)(x-a)^\alpha]
The remainder terms satisfy the inequality
- [|R_(x)|\le\sup_ }\left|\frac\right|]
Proof: Taylor's theorem in one variable
We first prove Taylor's theorem with the integral remainder term.
The fundamental theorem of calculus states that
- [f(x) = f(a) + \int_a^x (x-t)^0 \, f'(t) \, dt.]
Integration by parts yields the case n = 1:
- [f(x) = f(a) +f'(a)\,(x-a)+\int_a^x (x-t)^1 \, f''(t) \, dt.]
This can be formalized by applying the technique of induction. So, suppose that Taylor's theorem holds for a particular n, that is, suppose that
- [ f(x) = f(a) + \frac(x - a) + \cdots + \frac(a)}(x - a)^n + \int_a^x \frac (t)} (x - t)^n \, dt. \qquad(*)]
- [ \int_a^x \frac (t)} (x - t)^n \, dt ]
- :[ = - \left[ frac (t)} (x - t)^ right]_a^x + \int_a^x \frac (t)} (x - t)^ \, dt ]
- :[ = \frac (a)} (x - a)^ + \int_a^x \frac (t)} (x - t)^ \, dt. ]
The remainder term in the Lagrange form can be derived by the mean value theorem in the following way:
- [ R_n = \int_a^x \frac (t)} (x - t)^n \, dt =f^(\xi) \int_a^x \frac \, dt.]
- [ R_n = \frac(\xi)} (x-a)^.]
Proof: several variables
Let x=(x1,...,xN) lie in the ball B with center a. Parametrize the line segment between a and x by u(t)=a+t(x-a). We apply the one-variable version of Taylor's theorem to the function f(u(t)):
- [f(x)=f(u(1))=f(a)+\sum_^n\left.\frac\frac\right|_f(u(t))\ +\ \int_0^1 \left. \frac\frac}}\right|_ f(u(s))ds.]
- [\fracf(a+t(x-a))=\sum_\left(\begini\\ \alpha\end\right)(D^\alpha f)(a+t(x-a))\cdot (x-a)^\alpha]
- [f(x)= f(a)+\sum_^n\fracD^\alpha f(a)(x-a)^\alpha+\sum_\frac\int_0^1 D^\alpha f(a+s(x-a))ds.]
- [\sum_\frac\int_0^1 D^\alpha f(a+s(x-a))ds,]
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