Terms and Expressions with Exponents
Learning Outcomes
- Evaluate exponential expressions
Anatomy of Exponential Terms
We use exponential notation to write repeated multiplication. For example, [latex]10\cdot10\cdot10[/latex] can be written more succinctly as [latex]10^{3}[/latex]. The [latex]10[/latex] in [latex]10^{3}[/latex] is called the base. The [latex]3[/latex] in [latex]10^{3}[/latex] is called the exponent. The expression [latex]10^{3}[/latex] is called the exponential expression. Knowing the names for the parts of an exponential expression or term will help you learn how to perform mathematical operations on them.[latex]\text{base}\rightarrow10^{3\leftarrow\text{exponent}}[/latex]
[latex]10^{3}[/latex] is read as “[latex]10[/latex] to the third power” or “[latex]10[/latex] cubed.” It means [latex]10\cdot10\cdot10[/latex], or [latex]1,000[/latex]. [latex]8^{2}[/latex] is read as “[latex]8[/latex] to the second power” or “[latex]8[/latex] squared.” It means [latex]8\cdot8[/latex], or [latex]64[/latex]. [latex]5^{4}[/latex] is read as “[latex]5[/latex] to the fourth power.” It means [latex]5\cdot5\cdot5\cdot5[/latex], or [latex]625[/latex]. [latex]b^{5}[/latex] is read as “b to the fifth power.” It means [latex]{b}\cdot{b}\cdot{b}\cdot{b}\cdot{b}[/latex]. Its value will depend on the value of b. The exponent applies only to the number that it is next to. Therefore, in the expression [latex]xy^{4}[/latex], only the y is affected by the [latex]4[/latex]. [latex]xy^{4}[/latex] means [latex]{x}\cdot{y}\cdot{y}\cdot{y}\cdot{y}[/latex]. The x in this term is a coefficient of y. If the exponential expression is negative, such as [latex]−3^{4}[/latex], it means [latex]–\left(3\cdot3\cdot3\cdot3\right)[/latex], or [latex]−81[/latex]. If [latex]−3[/latex] is to be the base, it must be written as [latex]\left(−3\right)^{4}[/latex], which means [latex]−3\cdot−3\cdot−3\cdot−3[/latex], or [latex]81[/latex]. Likewise, [latex]\left(−x\right)^{4}=\left(−x\right)\cdot\left(−x\right)\cdot\left(−x\right)\cdot\left(−x\right)=x^{4}[/latex], while [latex]−x^{4}=–\left(x\cdot x\cdot x\cdot x\right)[/latex]. You can see that there is quite a difference, so you have to be very careful! The following examples show how to identify the base and the exponent as well as how to identify the expanded and exponential format of writing repeated multiplication.Example
Identify the exponent and the base in the following terms, then simplify:- [latex]7^{2}[/latex]
- [latex]{\left(\dfrac{1}{2}\right)}^{3}[/latex]
- [latex]2x^{3}[/latex]
- [latex]\left(-5\right)^{2}[/latex]
Answer:
1) [latex]7^{2}[/latex] The exponent in this term is [latex]2[/latex], and the base is [latex]7[/latex]. To simplify, expand the term: [latex]7^{2}=7\cdot{7}=49[/latex] 2) [latex]{\left(\dfrac{1}{2}\right)}^{3}[/latex] The exponent on this term is [latex]3[/latex], and the base is [latex]\dfrac{1}{2}[/latex]. To simplify, expand the multiplication and remember how to multiply fractions: [latex]{\left(\dfrac{1}{2}\right)}^{3}=\dfrac{1}{2}\cdot{\dfrac{1}{2}}\cdot{\dfrac{1}{2}}=\dfrac{1}{8}[/latex] 3) [latex]2x^{3}[/latex] The exponent on this term is [latex]3[/latex], and the base is x. The [latex]2[/latex] is not getting the exponent, because there are no parentheses that tell us it is. This term is in its most simplified form. 4) [latex]\left(-5\right)^{2}[/latex] The exponent on this term is [latex]2[/latex], and the base is [latex]-5[/latex]. To simplify, expand the multiplication: [latex]\left(-5\right)^{2}=-5\cdot{-5}=25[/latex]In the following video, you are provided more examples of applying exponents to various bases.
https://youtu.be/ocedY91LHKUEvaluate Expressions
Evaluating expressions containing exponents is the same as evaluating the linear expressions from earlier in the course. You substitute the value of the variable into the expression and simplify. You can use the order of operations to evaluate the expressions containing exponents. First, evaluate anything in parentheses or grouping symbols. Next, look for exponents, followed by multiplication and division (reading from left to right), and lastly, addition and subtraction (again, reading from left to right). So, when you evaluate the expression [latex]5x^{3}[/latex] if [latex]x=4[/latex], first substitute the value 4 for the variable x, then evaluate using order of operations.Example
Evaluate the following expressions for the given value.- [latex]5x^{3}[/latex] if [latex]x=4[/latex]
- [latex]\left(5x\right)^{3}[/latex] if [latex]x=4[/latex]
- [latex]x^{3}[/latex] if [latex]x=−4[/latex]
- [latex]3^x[/latex] if [latex]x = 4[/latex]
Answer: 1) Substitute 4 for the variable x.
[latex]5\cdot4^{3}[/latex]
Evaluate [latex]4^{3}[/latex]. Multiply.[latex]5\left(4\cdot4\cdot4\right)=5\cdot64=320[/latex]
2) [latex]\left(5x\right)^{3}[/latex] if [latex]x=4[/latex] Substitute 4 for the variable x. Notice how including parentheses can change the outcome when you are simplifying terms with exponents.[latex]\left(5\cdot4\right)^{3}[/latex]
Multiply inside the parentheses, then apply the exponent—follow the order of operations.[latex]20^{3}[/latex]
Evaluate [latex]20^{3}[/latex].[latex]20\cdot20\cdot20=8,000[/latex]
3) [latex]x^{3}[/latex] if [latex]x=−4[/latex]. Substitute [latex]−4[/latex] for the variable x.[latex]\left(−4\right)^{3}[/latex]
Evaluate. Note how placing parentheses around the [latex]−4[/latex] means the negative sign is included as part of the base.[latex]−4\cdot−4\cdot−4[/latex]
Multiply.[latex]−4\cdot−4\cdot−4=−64[/latex]
4) [latex]3^x[/latex] if [latex]x = 4[/latex] Substitute x = 4 into the exponent. [latex]3^x=3^4=3\cdot3\cdot3\cdot3=81[/latex]- [latex]-{3}^{2}[/latex]
- [latex]{\left(-3\right)}^{2}[/latex]
[latex]\begin{array}{c}-\left({3}^{2}\right)=-\left(9\right) = -9\end{array}[/latex]
To evaluate 2), you would apply the exponent to the 3 and the negative sign:
[latex]\begin{array}{c}{\left(-3\right)}^{2}=\left(-3\right)\cdot\left(-3\right)={ 9}\end{array}[/latex]
The key to remembering this is to follow the order of operations. The first expression does not include parentheses so you would apply the exponent to the integer 3 first, then apply the negative sign. The second expression includes parentheses, so hopefully you will remember that the negative sign also gets squared.
Coming up, you will learn how to simplify expressions that contain exponents. Come back to this page if you forget how to apply the order of operations to a term with exponents or forget which is the base and which is the exponent!
In the following video, you are provided with examples of evaluating exponential expressions for a given number.
https://youtu.be/pQNz8IpVVg0Licenses & Attributions
CC licensed content, Original
- Simplify Basic Exponential Expressions. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. License: CC BY: Attribution.
- Revision and Adaptation. Provided by: Lumen Learning License: CC BY: Attribution.
- Repeated Image. Provided by: Lumen Learning License: CC BY: Attribution.
- Evaluate Basic Exponential Expressions. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. License: CC BY: Attribution.
CC licensed content, Shared previously
- Unit 11: Exponents and Polynomials, from Developmental Math: An Open Program. Provided by: Monterey Institute of Technology and Education Located at: https://www.nroc.org/. License: CC BY: Attribution.