Algebra: Difference between revisions

Solving equations[edit | edit source]

Definitions[edit | edit source]

Expression[edit | edit source]

= any form of showing a mathematical value

• ex. the number 2 may be "expressed" as either "2" or "1+1"
• more complex "expressions" involve variables, such as "2y -5 = 10"
  • here, the value (expression) "10" can also be "expressed" as "2y - 5"

Equation[edit | edit source]

= a statement that uses an equal sign (=)

• which means that the expressions on both side of the equal sign have the same value

Inverse Operation[edit | edit source]

= a method for isolating variables by adding or multiplying a value to both sides of an equation

• the "inverse operation" reduces the value of the property on the side of the variable to 1 or 0

• that way the variable becomes "isolated" on one side of the equation

• ex.:
  • ${\displaystyle x+3=8}$
• the "inverse operation" adds -3 to both sides of the equation:
  • ${\displaystyle x+3-3=8-3}$

• which leaves us with
  • ${\displaystyle x+0=5}$
  • ${\displaystyle x=5}$

Operation[edit | edit source]

= a process to change a value

• addition, subtraction, multiplication and division are the fundamental "operations" of math

Property[edit | edit source]

• = the rule that is applied to numbers in an equation
• the property applied must be the same for both sides of the equation!
• properties include
  • Addition property (or subtraction)
  • Multiplication property (or division)

Isolating the variable[edit | edit source]

• Equations are solved by "isolating the variable"
  • which means "expressing" the unknown value by itself on one side of an equation
    • ex. to solve, "4 + x = 6" , we want to "isolate" x, so that we have "x = ___"

Properties of Equality[edit | edit source]

• property = a rule
• equality = that both sides of the equation (equal sign) have the same value

Variable[edit | edit source]

• an unknown value represented, usually represented by the letter ${\displaystyle x}$

How to solve an equation with a single variable[edit | edit source]

Using Addition Property[edit | edit source]

• when solving for ${\displaystyle x}$ when ${\displaystyle x}$ is added or subtracted to/from another number
  • we "isolate ${\displaystyle x}$" by using the "Inverse Operation" to remove the number from the side with the variable, ${\displaystyle x}$
  • note that
    • addition is adding a positive number: ${\displaystyle 5+(+3)=8}$
      • where ${\displaystyle (+3)}$ means "positive 3"
    • subtraction is adding a negative number: ${\displaystyle 5+(-3)=2}$
      • where ${\displaystyle (-3)}$ means "negative 3"
• examples:

Properties of Equality

		Addition Property
Equation		${\displaystyle x+4=6}$		${\displaystyle x-3=4}$
Inverse Operation	add ${\displaystyle -4}$ to both sides (i.e. subtract 4)	${\displaystyle x+4+(-4)=6+(-4)}$	add ${\displaystyle +3}$ to both sides (i.e. add 3)	${\displaystyle x-3+(3)=6+(3)}$
Solution		${\displaystyle x+0=2}$		${\displaystyle x+0=9}$
		${\displaystyle x=2}$		${\displaystyle x=9}$

• another way to look at the Inverse Operation, using the same equations is:

Properties of Equality

Addition Property
Equation		${\displaystyle x+4=6}$		${\displaystyle x-3=4}$
Inverse Operation	add ${\displaystyle -4}$ to both sides (i.e. subtract 4)	${\displaystyle x+4=6}$${\displaystyle -4|-4}$	add ${\displaystyle +3}$ to both sides (i.e. add 3)	${\displaystyle x-3=6}$${\displaystyle +3|+3}$
	simplify	${\displaystyle x+0=2}$	simplify	${\displaystyle x+0=9}$
Solution		${\displaystyle x=2}$		${\displaystyle x=9}$

Using Multiplication Property[edit | edit source]

Properties of Equality

Multiplication Property
Equation		${\displaystyle {\frac {x}{6}}=4}$		${\displaystyle 6x=24}$
Inverse Operation	multiply both sides by 6 (isolates x by making the expression ${\displaystyle x{\frac {6}{6}}}$ which is equal to ${\displaystyle x\times 1}$)	${\displaystyle {\frac {6\times x}{6}}={4}\times 6}$	divide both sides by 6 (isolate ${\displaystyle x}$ by making the expression ${\displaystyle x{\frac {6}{6}}}$ which is equal to ${\displaystyle x\times 1}$)	${\displaystyle {\frac {6x}{6}}={\frac {24}{6}}}$
	cancel ${\displaystyle 6\div 6}$ (because ${\displaystyle 6\div 6}$ ${\displaystyle =1}$ )	${\displaystyle {\frac {{\cancel {6}}\times x}{\cancel {6}}}={4}\times 6}$	cancel ${\displaystyle 6\div 6}$ (because ${\displaystyle 6\div 6}$ ${\displaystyle =1}$ ) (note: ${\displaystyle {\frac {24}{6}}}$ is the same as ${\displaystyle 24\div 6}$)	${\displaystyle {\frac {{\cancel {6}}\times x}{\cancel {6}}}={\frac {24}{6}}}$
Solution		${\displaystyle x=24}$		${\displaystyle x=4}$

Cross-multiplying[edit | edit source]

• use cross-multiplication to solve for ${\displaystyle x}$ when ${\displaystyle x}$ is a denominator (bottom of a fraction)

• see for numerators and denominators

How to solve for ${\displaystyle x}$ when ${\displaystyle x}$ is a denominator: "Cross-multiplication"[edit | edit source]

Using Cross-Multiplication

${\displaystyle {\frac {6}{x}}=8}$	is the same as	${\displaystyle {\frac {6}{x}}={\frac {8}{1}}}$
using cross-multiplication, we can move the variable ${\displaystyle x}$ to the top of the fraction (numerator)
${\displaystyle {\frac {6}{x}}={\frac {8}{1}}}$	is the same as (using cross-multiplication)	${\displaystyle 8x=6\times 1}$
	now we can solve for ${\displaystyle x}$
${\displaystyle 8x=6\times 1}$	${\displaystyle 8x=16}$${\displaystyle {\frac {8\times x}{8}}={\frac {16}{8}}}$${\displaystyle x={\frac {16}{8}}}$	${\displaystyle x=2}$

How to solve an equation with two of the same variables[edit | edit source]

• when an equation has two of the same variables, we isolate the variable by combining its instances
• ex.
  • ${\displaystyle 2x+5x=35}$
  • the values ${\displaystyle 2x}$ and ${\displaystyle 5x}$ may be "distributed" in order to make a single instance of ${\displaystyle x}$ and thereby allowing for it to be isolated

Distributive property[edit | edit source]

= the idea that multiplication can be "distributed" through addition

• multiplication is addition by a certain factor (number of times)
• ex. when we multiply ${\displaystyle 5\times 5}$, we are adding 5 five times: ${\displaystyle 5\times 5=5+5+5+5+5}$
  • that is the same as adding ${\displaystyle (2+3)}$ five times
  • so we can express ${\displaystyle (2+3)}$ times 5 as either
    • ${\displaystyle 5\times (2+3)}$ or
    • ${\displaystyle 5\times (5)}$ or
    • ${\displaystyle (5\times 2)+(5\times 3)}$
      • they all equal 25
• with variables, we use the process:
  • ${\displaystyle 2x+5x}$ =
  • ${\displaystyle x\times (2+5)}$ =
  • ${\displaystyle x\times 7}$ = 7${\displaystyle x}$