Difference between revisions of "Exponentiation"

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* [[base]] - in <math>10^9</math> the base is 10; this tells us what we will be multiplying 9 times
 
* [[base]] - in <math>10^9</math> the base is 10; this tells us what we will be multiplying 9 times
  
Our definition of exponentiation makes sense if the exponent is a positive integer.  How about negative integers such as <math>2^{-4}</math>?  How do we multiply 2 by itself -4 times!?  Let's think about what a negative sign means a little more.  When we append a negative sign to a number (say 4, for example) we are basically saying go four units in the ''opposite'' direction.  So we want to do the opposite of multiplication four times.  In other words, we want to divide by 3 four times.  Therefore <math> 2^{-4}=\frac 1{2^4}.</math>
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Our definition of exponentiation makes sense if the exponent is a positive integer.  How about negative integers such as <math>2^{-4}</math>?  How do we multiply 2 by itself -4 times!?  Let's think about what a negative sign means a little more.  When we append a negative sign to a number (say 4, for example) we are basically saying go four units in the ''opposite'' direction.  So we want to do the opposite of multiplication four times.  In other words, we want to divide by 2 four times.  Therefore <math> 2^{-4}=\frac 1{2^4}.</math>
  
 
It is also possible to extend the exponential function to all non-integers.
 
It is also possible to extend the exponential function to all non-integers.

Revision as of 15:59, 23 June 2006

Introduction

To understand exponents and the exponential function, let's first review how multiplication came about. Let's say we wanted to add 3 ten times. We could write this out as $3 + 3 +3 + 3 +3 + 3 +3 + 3 +3 + 3$ but this gets burdensome if we wanted to add, for example, 3 three hundred times. Thus, we define the multiplication function (usually denoted $\times$ or $\cdot$) such that $3\times 300=3+3+\cdots+3$ where there are 300 threes in the sum. For integers, it is straightforward how multiplaction works. We can then extend the notion of multiplication to non-integers.

Similarly, the exponential function is defined as the repitition of multiplication. For example, writing out $3\cdot 3\cdot 3\cdot 3\cdot 3$ can get boring fast. So we define the exponential function to express this in a much more compact form so that the preceeding example can be written as $3^5$ (read 3 to the 5th or 3 to the 5 power). What this means is that we are multiplying 3 by itself 5 times.

Before we proceed, we define 3 terms:

  • exponent or power - in $4^6$ the exponent is 6; this tells us how many times we multiply the 4
  • base - in $10^9$ the base is 10; this tells us what we will be multiplying 9 times

Our definition of exponentiation makes sense if the exponent is a positive integer. How about negative integers such as $2^{-4}$? How do we multiply 2 by itself -4 times!? Let's think about what a negative sign means a little more. When we append a negative sign to a number (say 4, for example) we are basically saying go four units in the opposite direction. So we want to do the opposite of multiplication four times. In other words, we want to divide by 2 four times. Therefore $2^{-4}=\frac 1{2^4}.$

It is also possible to extend the exponential function to all non-integers.

Basic Properties

Listed below are some important properties of exponents:

  1. $b^x\cdot b^y = b^{x+y}$
  2. $b^{-x}=\frac 1{b^x}$
  3. $\frac{b^x}{b^y}=b^{x-y}$
  4. $(b^x)^y = b^{xy}$
  5. $(ab)^x = a^x b^x$

Here are explanations of the properties listed above:

  1. On both sides we are multiplying b together x+y times. Thus, they are equivalent.
  2. This is described in the previous section.
  3. This results from using the previous two properties.
  4. We are multiplying $b^x$ by itself y times which is the same as multiplying b by itself xy times.
  5. After multiplying ab by itself x times we can collect a and b terms thus establishing the property.

See also

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