Power rule: Difference between revisions
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→Statement of the power rule: Tightening up statement of the power rule. There is no need to say 'if f is differentiable at x...', because the proof of the power rule shows that f is differentiable everywhere. |
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== Statement of the power rule== |
== Statement of the power rule== |
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Let <math>f:\mathbb{R}\mapsto\mathbb{R}</math> be a function satisfying <math>f(x)=x^r</math> for all <math>x</math>, with <math>r \in \mathbb{R}</math>. Then, |
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:<math>f'(x) = rx^{r-1}</math> |
:<math>f'(x) = rx^{r-1}</math> |
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The power rule |
The power rule for integration states |
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:<math>\int\! x^r \, dx=\frac{x^{r+1}}{r+1}+C</math> |
:<math>\int\! x^r \, dx=\frac{x^{r+1}}{r+1}+C</math> |
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for any real number <math>r \neq -1</math> |
for any real number <math>r \neq -1</math>. It may be derived by inverting the power rule for differentiation. |
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==Proofs== |
==Proofs== |
Revision as of 17:53, 2 June 2021
Part of a series of articles about |
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In calculus, the power rule is used to differentiate functions of the form , whenever is a real number. Since differentiation is a linear operation on the space of differentiable functions, polynomials can also be differentiated using this rule. The power rule underlies the Taylor series as it relates a power series with a function's derivatives.
Statement of the power rule
Let be a function satisfying for all , with . Then,
The power rule for integration states
for any real number . It may be derived by inverting the power rule for differentiation.
Proofs
Proof for real exponents
To start, we should choose a working definition of the value of , where is any real number. Although it is feasible to define the value as the limit of a sequence of rational powers that approach the irrational power whenever we encounter such a power, or as the least upper bound of a set of rational powers less than the given power, this type of definition is not amenable to differentiation. It is therefore preferable to use a functional definition, which is usually taken to be for all values of , where is the natural exponential function and is Euler's number.[1][2] First, we may demonstrate that the derivative of is .
If , then , where is the natural logarithm function, the inverse function of the exponential function, as demonstrated by Euler.[3] Since the latter two functions are equal for all values of , their derivatives are also equal, whenever either derivative exists, so we have, by the chain rule,
or , as was required. Therefore, applying the chain rule to , we see that
which simplifies to .
When , we may use the same definition with , where we now have . This necessarily leads to the same result. Note that because does not have a conventional definition when is not a rational number, irrational power functions are not well defined for negative bases. In addition, as rational powers of -1 with even denominators (in lowest terms) are not real numbers, these expressions are only real valued for rational powers with odd denominators (in lowest terms).
Finally, whenever the function is differentiable at , the defining limit for the derivative is:
which yields 0 only when is a rational number with odd denominator (in lowest terms) and , and 1 when r = 1. For all other values of r, the expression is not well-defined for , as was covered above, or is not a real number, so the limit does not exist as a real-valued derivative. For the two cases that do exist, the values agree with the value of the existing power rule at 0, so no exception need be made.
The exclusion of the expression (the case x = 0) from our scheme of exponentiation is due to the fact that the function has no limit at (0,0), since approaches 1 as x approaches 0, while approaches 0 as y approaches 0. Thus, it would be problematic to ascribe any particular value to it, as the value would contradict one of the two cases, dependent on the application. It is traditionally left undefined.
Proofs for non-zero integer exponents
Proof by induction (positive integers)
Let n be a positive integer. It is required to prove that
When , Therefore, the base case holds.
Suppose the statement holds for some positive integer k, i.e.
When ,
By the principle of mathematical induction, the statement is true for all positive integers n.
Proof by binomial theorem (positive integers)
Let , where
Then
Generalization to negative integer exponents
For a negative integer n, let so that m is a positive integer. Using the reciprocal rule,
In conclusion, for any non-zero integer ,
Generalization to rational exponents
Upon proving that the power rule holds for integer exponents, the rule can be extended to rational exponents.
Case-by-case generalization
1. Let , where
Then
By the chain rule, we get
Thus,
2. Let , where , so that
By the chain rule,
3. Let , where and
By using chain rule and reciprocal rule, we have
From the above results, we can conclude that when r is a rational number,
Proof by implicit differentiation
A more straightforward generalization of the power rule to rational exponents makes use of implicit differentiation.
Let , where so that .
Then,
Solving for ,
Since ,
Applying laws of exponents,
Thus, letting , we can conclude that when is a rational number.
History
The power rule for integrals was first demonstrated in a geometric form by Italian mathematician Bonaventura Cavalieri in the early 17th century for all positive integer values of , and during the mid 17th century for all rational powers by the mathematicians Pierre de Fermat, Evangelista Torricelli, Gilles de Roberval, John Wallis, and Blaise Pascal, each working independently. At the time, they were treatises on determining the area between the graph of a rational power function and the horizontal axis. With hindsight, however, it is considered the first general theorem of calculus to be discovered.[4] The power rule for differentiation was derived by Isaac Newton and Gottfried Wilhelm Leibniz, each independently, for rational power functions in the mid 17th century, who both then used it to derive the power rule for integrals as the inverse operation. This mirrors the conventional way the related theorems are presented in modern basic calculus textbooks, where differentiation rules usually precede integration rules.[5]
Although both men stated that their rules, demonstrated only for rational quantities, worked for all real powers, neither sought a proof of such, as at the time the applications of the theory were not concerned with such exotic power functions, and questions of convergence of infinite series were still ambiguous.
The unique case of was resolved by Flemish Jesuit and mathematician Grégoire de Saint-Vincent and his student Alphonse Antonio de Sarasa in the mid 17th century, who demonstrated that the associated definite integral,
representing the area between the rectangular hyperbola and the x-axis, was a logarithmic function, whose base was eventually discovered to be the transcendental number e. The modern notation for the value of this definite integral is , the natural logarithm.
Generalizations
Complex power functions
If we consider functions of the form where is any complex number and is a complex number in a slit complex plane that excludes the branch point of 0 and any branch cut connected to it, and we use the conventional multivalued definition , then it is straightforward to show that, on each branch of the complex logarithm, the same argument used above yields a similar result: .[6]
In addition, if is a positive integer, then there is no need for a branch cut: one may define , or define positive integral complex powers through complex multiplication, and show that for all complex , from the definition of the derivative and the binomial theorem.
However, due to the multivalued nature of complex power functions for non-integer exponents, one must be careful to specify the branch of the complex logarithm being used. In addition, no matter which branch is used, if is not a positive integer, then the function is not differentiable at 0.
References
- ^ Landau, Edmund (1951). Differential and Integral Calculus. New York: Chelsea Publishing Company. p. 45. ISBN 978-0821828304.
- ^ Spivak, Michael (1994). Calculus (3 ed.). Texas: Publish or Perish, Inc. pp. 336–342. ISBN 0-914098-89-6.
- ^ Maor, Eli (1994). e: The Story of a Number. New Jersey: Princeton University Press. p. 156. ISBN 0-691-05854-7.
- ^ Boyer, Carl (1959). The History of the Calculus and its Conceptual Development. New York: Dover. p. 127. ISBN 0-486-60509-4.
- ^ Boyer, Carl (1959). The History of the Calculus and its Conceptual Development. New York: Dover. pp. 191, 205. ISBN 0-486-60509-4.
- ^ Freitag, Eberhard; Busam, Rolf (2009). Complex Analysis (2 ed.). Heidelberg: Springer-Verlag. p. 46. ISBN 978-3-540-93982-5.
- 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.