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{{inline citations|date=July 2013}}
{{Calculus |Differential}}
 
In [[calculus]], the '''power rule''' is one of the most important [[differentiation rules]]. Since differentiation is linear, [[polynomial]]s can be differentiated using this rule.
 
:<math> \frac{d}{dx} x^n = nx^{n-1} , \qquad n \neq 0.</math>
The power rule holds for all powers except for the constant value <math>x^0</math> which is covered by the constant rule. The derivative is just <math>0</math> rather than <math>0 \cdot x^{-1}</math> which is undefined when <math>x=0</math>.
 
The inverse of the power rule enables all powers of a variable <math>x</math> except <math>x^{-1}</math> to be integrated. This integral is called [[Cavalieri's quadrature formula]] and was first found in a geometric form by [[Bonaventura Cavalieri]] for <math>n \ge 0</math>. It is considered the first general theorem of calculus to be discovered.
 
:<math>\int\! x^n \,dx= \frac{ x^{n+1}}{n+1} + C, \qquad n \neq -1.</math>
 
This is an  [[indefinite integral]] where <math>C</math> is the [[arbitrary constant of integration]].  
 
The integration of <math>x^{-1}</math> requires a separate rule.
 
:<math>\int \! x^{-1}\, dx= \ln |x|+C,</math>
 
Hence, the derivative of <math>x^{100}</math>  is  <math>100 x^{99}</math>  and the integral of <math>x^{100}</math> is <math> \frac{1}{101} x^{101} +C</math>.
 
== Power rule==
Historically the power rule was derived as the inverse of [[Cavalieri's quadrature formula]]  which gave the area under <math>x^n</math> for any integer <math>n \geq 0</math>. Nowadays the power rule is derived first and integration considered as its inverse.
 
For integers <math>n \geq 1</math>, the derivative of <math>f(x)=x^n \!</math> is <math>f'(x)=nx^{n-1},\!</math> that is,
:<math>\left(x^n\right)'=nx^{n-1}.</math>
 
The power rule ''for integration''
:<math>\int\! x^n \, dx=\frac{x^{n+1}}{n+1}+C</math>
for <math>n \geq 0</math> is then an easy consequence. One just needs to take the derivative of this equality and use the power rule and [[linear transformation|linearity]] of differentiation on the right-hand side.
 
===Proof===
 
To prove the power rule for differentiation, we use the [[derivative#Definition via difference quotients|definition of the derivative]] as a [[Limit of a function|limit]]. But first, note the [[Factorization of polynomials|factorization]] for <math>n \geq 1</math>:
 
:<math>f(x)-f(a) =  x^n-a^n = (x-a)(x^{n-1}+ax^{n-2}+ \cdots +a^{n-2}x+a^{n-1})</math>
 
Using this, we can see that  
 
:<math>f'(a) = \lim_{x\rarr a} \frac{x^n-a^n}{x-a} = \lim_{x\rarr a} x^{n-1}+ax^{n-2}+ \cdots +a^{n-2}x+a^{n-1} </math>
 
Since the division has been eliminated and we have a continuous function, we can freely substitute to find the limit:
 
:<math>f'(a) = \lim_{x\rarr a} x^{n-1}+ax^{n-2}+ \cdots +a^{n-2}x+a^{n-1} = a^{n-1}+a^{n-1}+ \cdots +a^{n-1}+a^{n-1} = n\cdot a^{n-1} </math>
 
The use of the quotient rule allows the extension of this rule for n as a negative integer, and the use of the laws of exponents and the [[chain rule]] allows this rule to be extended to all rational values of&nbsp;<math>n</math> . For an irrational <math>n</math>, a rational approximation is appropriate.
 
==Differentiation of arbitrary polynomials==
 
To differentiate arbitrary polynomials, one can use the [[linear transformation|linearity property]] of the  [[differential operator]] to obtain:
 
:<math>\left( \sum_{r=0}^n a_r x^r \right)' =
\sum_{r=0}^n \left(a_r x^r\right)' =
\sum_{r=0}^n a_r \left(x^r\right)' =
\sum_{r=0}^n ra_rx^{r-1}.</math>
 
Using the linearity of integration and the power rule for integration, one shows in the same way that
:<math>\int\!\left( \sum^n_{k=0} a_k x^k\right)\,dx= \sum^n_{k=0} \frac{a_k x^{k+1}}{k+1}  + C.</math>
 
==Generalizations==
 
One can prove that the power rule is valid for any exponent {{mvar|r}}, that is
 
:<math>\left(x^r\right)' = rx^{r-1},</math>
 
as long as {{mvar|x}} is in the domain of the functions on the left and right hand sides and {{mvar|r}} is nonzero. Using this formula, together with
:<math>\int \! x^{-1}\, dx= \ln |x|+C,</math>
one can differentiate and integrate linear combinations of powers of {{mvar|x}} which are not necessarily polynomials.
 
==References==
*  Larson, Ron; Hostetler, Robert P.; and Edwards, Bruce H. (2003). ''Calculus of a Single Variable: Early Transcendental Functions'' (3rd edition). Houghton Mifflin Company. ISBN 0-618-22307-X.
 
[[Category:Calculus]]
[[Category:Articles containing proofs]]

Latest revision as of 21:31, 3 January 2015

Obtaining an offshore account is one the best ways to get a person to safeguard their cash, plus one of the finest types of offshore accounts are called no ID offshore account. This sort of account doesn't require a individual to prove their individuality when starting the account, as well as in most instances it is perfectly great for a individual to open up the account under a name that is different than their own. There are always a handful of items an individual ought to know a few zero identification offshore account including the process of starting a merchant account, and what most of these accounts are usually employed for.

Howto open a number ID account

The process of opening up a no identification account is extremely easy. In most cases an individual may only walk into a bank office, then feel the procedure for opening up an account. This typically entails having a person writedown the name of the account, and choosing what selections they desire for that account. An individual can then just withdraw money in the account my writing down a secret signal. Some banks that provide offshore accounts will not possibly need a person to go to the financial institution office.

What these accounts are used for

These types of accounts usually are employed by individuals who would like to defend their finances from such things as lawsuits, or having them recinded by way of a government. This really is essential, as it is one of many methods an individual may make certain that their cash merely does not get seized for any reason. More Click This Link.