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Using 0 as a base for an exponential function would create a graph that violates the properties of exponential functions.
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Prepared at the University of Georgia in Dr. Wilsonโs EMAT 6500 Class July 25, 2013 โ Sarah Major
A teacher prompts her students to turn in their homework on exponential functions, but one of the students raises his hand and says, โI donโt understand why we have restrictions on the bases of exponential functions. You can raise 0 to any power and still get a value, and you can do the same for 1 and negative numbers. So why canโt we use those?โ
Though this prompt is fairly simple, it has a lot of relevancy within a high school Mathematics classroom. Students are told of these restrictions on the base values of exponential functions, but when they question their teacher on why, many teachers simply state that it is contained in the definition of the function. They do not give intuitive reasons as to why these values cannot be included as bases of exponential functions. This lack of explanation may not only hinder their understanding of the true properties of exponential functions but also the properties of these numbers in general.
Exponential functions adhere to distinct properties, including those that limit the values of what the base can be. The parent form of the exponential function appears in the form: ๐ ๐ฅ = ๐! where ๐, known as the base is a fixed number and ๐ฅ is any real number. These types of functions adhere to certain properties:
Using 0 as a base for an exponential function would create a graph that violates the properties of exponential functions. 7 6 5 4 3 2 1
4 โ 3 โ 2 โ 1 1 2 6 5 4 3 2 1 g ( x ) = 2 x
Similar to using 0 as a base, using 1 as a base for an exponential function would create a graph that violates the properties of exponential functions. Similar to the case of using 0 , many students believe that the function ๐ ๐ฅ = 1!^ is an exponential function because its values can be calculated for any real number. However, 1 raised to any power will result in 1 , so it, too, is a constant function: The following properties are therefore violated:
Using 0 as a base for an exponential function would be undefined for negative values of ๐ฅ. As shown in the graph in Focus 2 , the domain of ๐ ๐ฅ = 0!^ is only defined in the interval ( 0 , โ). This is because negative values of ๐ฅ would produce a denominator of 0 , which makes the value undefined. For example, 0 !!^ = ! ! , which is undefined. However, one of the properties of exponential functions states that such functions include the domain of all real numbers. In this case, since the 8 6 4 2
domain only includes half of real numbers, ๐ ๐ฅ = 0!^ cannot be classified as an exponential function.
Using negative base values would make the function values complex for certain fractional values of ๐ฅ and hinder the functionโs ability to be a continuous exponential function. Similar to the cases seen above, many values can be evaluated for functions in the form of exponential functions with negative bases. However, this does not necessarily mean that these functions can be classified as exponential functions. One property of exponential functions that is violated when dealing with negative bases is that the function has the inability to consistently increase or decrease as ๐ฅ โถ โ. Because of properties dealing with the multiplication of negative numbers, these type of functions will constantly alternate between positive and negative values as ๐ฅ โถ โ. For example, using the equation ๐ ๐ฅ = (โ 2 )!: (โ 2 )!^ = โ 2 (โ 2 )!^ = 4 (โ 2 )!^ = โ 8 Another problem we run into as we deal with negative bases is that some negative values raised to certain exponent powers may result in complex values that cannot be graphed on a two-dimensional Cartesian plane. For example, continuing with our example ๐ ๐ฅ = (โ 2 )!: (โ 2 ) ! ! (^) = (โ 2 ) = ๐ 2 This value cannot be graphed without having a complex axis. This is also why unlike our scenarios for a base of 0 or 1 , ๐ ๐ฅ = (โ 2 )!^ cannot be graphed. Because of their inability to consistently increase or decrease and restrictions on the domain, exponential functions cannot have negative bases.
Compound interest is a practical application for exponential functions that displays the restrictions on base values. The most common example for the application of exponential functions is compound interest. The formula for calculating this value is: ๐ด = ๐( 1 + ๐^ ๐)!"
However, there is one more restriction to logarithmic functions that exponential functions do not share: ๐ฅ > 0. However, this makes sense intuitively because ๐ > 0. Therefore, if ๐ is always positive, so will ๐ฅ. This will make sense after the explanation of the relationship between logarithmic and exponential functions given below. Logarithmic and exponential functions are directly related because of the fact that: ๐ฆ = log! ๐ฅ โ ๐!^ = ๐ฅ where the first equation is known as logarithm form and the second is known as exponential form. Therefore, we can see that ๐ฅ must be positive because an exponential function is always positive. Raising any positive number to some power will always result in a positive number. Many of the other properties hold for both because their forms are interchangeable.