expression

(noun)

An arrangement of symbols denoting values, operations performed on them, and grouping symbols (e.g., $(2x+4)$).

Related Terms

(noun)

An arrangement of symbols denoting values, operations performed on them, and grouping symbols, e.g. $\displaystyle \frac{(2x+4)}{2}$

Related Terms

Examples of expression in the following topics:

  • Simplifying Exponential Expressions

    • Multiplying exponential expressions with the same base: $a^m \cdot a^n = a^{m+n}$
    • Previously, we have applied these rules only to expressions involving integers.
    • The same rule applies to expressions with variables.
    • Now apply the rule for dividing exponential expressions with the same base:
    • To simplify the first part of the expression, apply the rule for multiplying two exponential expressions with the same base:

  • Simplifying, Multiplying, and Dividing Rational Expressions

    • Performing these operations on rational expressions often involves factoring polynomial expressions out of the numerator and denominator.
    • As a first example, consider the rational expression $\frac { 3x^3 }{ x }$.
    • We follow the same rules to multiply two rational expressions together.
    • Dividing rational expressions follows the same rules as dividing fractions.
    • The same applies to dividing rational expressions; the first expression is multiplied by the reciprocal of the second.

  • Simplifying Radical Expressions

    • A radical expression that contains variables can often be simplified to a more basic expression, much as can expressions involving only integers.
    • Expressions that include roots are known as radical expressions.
    • A radical expression is said to be in simplified form if:
    • For the purposes of simplification, radical expressions containing variables are treated no differently from expressions containing integers.
    • This follows the same logic that we used above, when simplifying the radical expression with integers:

  • Adding and Subtracting Algebraic Expressions

    • Every algebraic expression is made up of one or more terms. 
    • Terms in these expressions are separated by the operators $+$ or $-$.
    • For instance, in the expression $x + 5$, there are two terms; in the expression $2x^2$, there is only one term.
    • The same rules apply when an expression involves subtraction.
    • The expression therefore simplifies to:

  • Negative Exponents

    • This rule makes it possible to simplify expressions with negative exponents.
    • For example, consider the rule for multiplying two exponential expressions with the same base.
    • Note that the rule for raising an exponential expression to another exponent can be applied:
    • Recall that the rule for multiplying two exponential expressions with the same base can be applied.
    • Therefore, we can simplify the expression inside the parentheses:

  • Introduction to Radicals

    • Radical expressions yield roots and are the inverse of exponential expressions.
    • Mathematical expressions with roots are called radical expressions and can be easily recognized because they contain a radical symbol ($\sqrt{}$).
    • Since roots are the inverse operation of exponentiation, they allow us to work backwards from the solution of an exponential expression to the number in the base of the expression.
    • In this expression, the symbol is known as the "radical," and the solution of 7 is called the "root."
    • Finding the value for a particular root can be much more difficult than solving an exponential expression

  • The Order of Operations

    • The order of operations is an approach to evaluating expressions that involve multiple arithmetic operations.
    • The order of operations is a way of evaluating expressions that involve more than one arithmetic operation.
    • For example, when faced with the expression $4+2\cdot 3$, how do you proceed?
    • In order to be able to communicate using mathematical expressions, we must have an agreed-upon order of operations so that each expression is unambiguous.
    • This expression correctly simplifies to 9.

  • Rational Algebraic Expressions

    • When applying this strategy to rational expressions, first look at the denominators of the two rational expressions and see if they are the same.
    • This requires factoring algebraic expressions.
    • For example, consider the expression $2x^2 + 4$.
    • This expression therefore has two factors: $2$ and $(x^2 + 2)$.
    • The rational expressions therefore become:

  • Equations and Inequalities

    • An equation states that two expressions are equal, while an inequality relates two different values.
    • An equation is a mathematical statement that asserts the equality of two expressions.
    • This is written by placing the expressions on either side of an equals sign (=), for example:
    • Equations often express relationships between given quantities—the knowns—and quantities yet to be determined—the unknowns.
    • The process of expressing the unknowns in terms of the knowns is called solving the equation.

  • Introduction to Exponents

    • For example, the expression $b^3$ represents $b \cdot b \cdot b$.
    • Here, the exponent is 3, and the expression can be read in any of the following ways:
    • Now that we understand the basic idea, let's practice simplifying some exponential expressions.
    • Let's look at an exponential expression with 2 as the base and 3 as the exponent:
    • Let's look at another exponential expression, this time with 3 as the base and 5 as the exponent: