Quadratic Equations
By. Eshal Khaliq

b²-4ac

Negative discriminant = no real roots

Positive discriminant = 2 roots

If discriminant is zero there is 1 root

y = ax^2 + bx + c

a value cannot be 0
x is the unknown variable
a, b and c are all known values
c value is the y-intercept of parabola
a = vertical stretch factor

y = a(x-r)(x-s)

If a > 1 or a < -1, then the graph is stretched vertically by a
factor of a
a = vertical stretch/compression factor

a = vertical stretch/compression factor

Use Step Pattern for plotting points of parabola

Step Pattern
--------------
a=1
1,3,5,7,9,....

Step Pattern
--------------
a=2
2, 6, 10, 14,....

y = a(x-h)^2 + k

Vertex
(h,k)
k = y value of the vertex
"k" represents a vertical shift
h = x value of the vertex and axis of symmetry

Square Roots

Used to turn a quadratic into factored form to solve equation by finding X-intercepts
Finding what to multiply together to get an expression

First Outside Inside Last ( x + 3 ) (x + 2 ) = x^2 + 2x + 3x + 6 = x^2 + 5x + 6

( x + a ) ( x - a )
= x^2 - 5x + 5x -25
= x^2 -25
The middle terms cancel out

Example

Same method of factoring is used as factoring trinomials except you write the product as the square of a binomial

Example 1

a^2±2ab+b^2 = (a±b)^2 We have to find out what a and b are

a^2 = 4x^2 so a=√4x^2 = 2x
b^2 = 9 so b=√9 = 3

2ab = 2(2x)(3)
= 4x(3)
= 12x

Therefore, 2ab is the middle term which means it is a square trinomial

4x^2+12x+9
4(9) = 36
m(n)=36 m = 6

n+n=12 n = 6

Substitute as bx term = 12x

=4x^2+6x+6x+9

=2x(2x+3)+3(2x+3)

=(2x+3)(2x+3)

=(2x+3)^2

Example 2

Factor out the GCF by dividing it with all the terms
Move GCF outside of bracket
Multiply a value and c value
Find two numbers that multiply to the product of a(c) and have the sum of b
Substitute the two numbers for the middle term
Group the terms with common factors and factor each binomial group
The last two binomials should be the same so you simplify them together by writing the product as the square of the binomial

(2x – 3)(2x – 3) = (2x – 3)^2

(a + b)(c + d)
= ac + ad + bc + bd

e.g. (x + 4)(x – 3)
= x^2 – 3x + 4x – 12
= x^2 + x – 12

Example 1

a(b + c)
= ab + ac

Example 1

2(x + 4)

= 2(x + 4)
=2x+8

Example 2

Completing the Square

Convert Standard Form to Vertex Form and find Maximum/Minimum values or vertex of parabolas

ax^2 + bx + c = a(x-h)^2 + k

y=3x^2-12x-5
y=(3x^2-12x)-5
y=3(x^2-4x)-5

-4/2=-2^2=4

y=3(x^2-4x+4)-5

y=3(x^2-4x+4)-17

y=3(x-2)^2-17

Put brackets around ax^2+bx terms
Common Factor the "a" value
Make Perfect Square Trinomial inside bracket using: (b/2)^2
Add the opposite sign of the (b/2)^2 inside the bracket
EX. 2(x^2+6x+9-9)+11
Move the opposite sign (b/2)^2 value outside bracket by multiplying it by "a" value
Add this value with the k value outside bracket to get final k value
Keep the "a" value outside bracket and square root the first term x^2, keep the sign of the middle term (addition or subtraction) and square root the last term in bracket, add a square outside of end bracket to give you: (x-h)^2
Write out the final Equation that is left over
Vertex = (2,17) Minimum = -17

Quadratic Equation

Finding x-intercepts from Standard Form using Quadratic Formula

X-intercepts/Roots/Zeroes = Solutions

(b^2-4ac)

Negative discriminant = no real roots

Positive discriminant = 2 roots

If discriminant is zero there is 1 root

Y- Intercept

The co-ordinate where the parabola crosses the y-axis.

Zeros

Also called roots. They are the x-intercepts of a parabola, and can have one, two, or zero roots.

Axis of Symmetry

Is a vertical line that divides the parabola into two equal parts. The axis of symmetry is the sum of the roots divided by two.

Vertex

The point where the axis of symmetry and the parabola meet at it's maximum or minimum value.

Optimum Value

The highest or lowest point on a parabola. If the parabola goes downwards it's maximum, and if it's going upwards it's minimum.

Substitute in these numbers for b value

These two integers end up being (x-r) and (x-s) in factored form