# Final Unit Assessment

### MPM2D0-G

## Introduction

Quadratics is one major unit in grade 10. In this unit, you will learn about the three different forms of equations and how to solve word problems, or graph using these equations. Quadratics may seem a bit complicated at first since it is a new unit, and hard to understand. However, by looking through this website, you will find many tutorials, videos, and examples of Quadratics to get you back on track. Please keep scrolling to learn more.

## UNIT 1: VERTEX FORM

## Parabola in Depth

__Parabola:__ graph of a quadratic equation (a symmetrical curved line).

__Vertex:__ is the maximum or minimum point of the parabola and is the point where the axis of symmetry and parabola make contact

__Optimal Value:__ is the y-coordinate of the vertex (if parabola opens upwards, then it is a minimum value while if parabola opens downwards, it will be a maximum value

__Zeros:__ when the parabola passes the x-axis (x-intercep

## Learning Goals

__1. Using finite differences to analyze quadratic relation__

- Create a table of values of the graph

- Find the first differences of the y-values

- If all the first differences are not constant, then continue to find the second differences.

If the first differences of the y-values are equal, then the equation is linear.

If the second differences of the y-values are equal, then the equation is quadratic.

If neither the first or second differences are constant, then it is neither a linear or quadratic relation.

In other words, the first differences of the table determine that the line is linear, while the second differences determine that the line is quadratic.

__2. Using a table of values to create a graph__

Using a table of values to create a graph is simple.

First of all, locate the first (x,y) values of the table.

After, locating, plot the points on the graph.

Continue to follow this process until you have plotted all the points from the table

Then, use the line of best fit to determine whether the graph is a linear equation or a quadratic equation.

__3. Graphing the base graph of a quadratic function without technology__

Create a table of values for y=x^2

If the equation is y=3x^2 all you have to do, it multiply the y value for y=x^2 by three.

After finding all the values, plot the points on the graph

## Step Pattern:

## Video to Help you Better Understand

## Word Problem

A flare is fired into the air from the ground. It reaches it's higest point at 120 metres, at 5.0 seconds. It falls back at the ground at 9.95 seconds. What is the equation for this problem ?

## Video of Mapping Notation

## UNIT 2: FACTORED FORM

Now, you will learn all about factored form and equations using factored form. I will also guide you through solving a few equations and word problems. Furthermore, you after scrolling through this website you will understand the seven different types/methods of factoring. So please, continue moving down the page to learn more about Quadratics using factored form.

## Learning Goals

·

Learning Goals:

I am able to identify the different types of quadratic relations used and how to factor it efficiently· I am able to identify the x-intercepts using factored form

· I am able to find the axis of symmetry using factored form

· I am able to find the vertex using factored form

· I am able to graph using factored form

## Summary of the Unit

· Formula for Factoring: Y=a(x-r)(x-s)

· When finding y-intercept, you have to sub x=0, and then solve the equation to find the value of y

· Graph the equation using the factors (x-int, y-int)

__Finding Values:__

· The value of **A **determines the shape and direction of opening (up or down)

· X-Intercepts= the value of R and S

· To find the axis of symmetry, you have to find the average of the value of **R **and **S**

You can find the average by adding the two numbers, then dividing by 2.

## GRAPHING A FACTORED FORM EQUATION

Step 1: Solving for x-intercepts:

The x-intercepts can be easily solved by finding the value of **R **and **S** but reversed operations.

For Example:

y=(x-9)(x+7)

the x-intercepts are: (9,0)(-7,0)

Step 2: Solving for the Axis of Symmetry

Solving for the Axis of Symmetry is simple, all you have to do is find the average of both x-intercepts.

Step 3: Solving for Y-value

After solving for Axis of Symmetry, you use that value and replace is with the x in the equation and solve for y.

Step 4: Plotting the Points

Once you have figured all the points, begin to plot them on a graph.

## Types of Factoring

Factoring: Grouping (4 Terms)

Complex Trinomial Factoring

Common Factoring

Simple Trinomial Factoring

Expanding and Simplifying

Perfect Square Trinomials

## Grouping (4 terms)

Step 2: Follow the same steps of step 1 and factor the last two terms.

Step 3: After Factoring, you take the two terms outside the bracket and put it with one of the two terms in the bracket.

## Simple Trinomial Factoring

## Complex Trinomial Factoring

Step 1: Multiply the a value and c value.

Step 2: Then, find one number that is the product of the c value and the sum of the middle value

## Common Factoring

Common factors= finding a greatest common term and dividing the rest

Lets say we have a polynomial 8x^3y^2+3xy^3+15x^2y^2

The greatest common factor is 3xy^2.

So, we factor the whole expression by that.

## Expanding and Simplifying

Step 2: Do the same step with the second term.

These are the only two main steps to Factoring

## Perfect Square Trinomial

Perfect squares are any numbers that can be squared into a whole number. However in Quadratics we can use Perfect Squares to our advantage. We can have a Binomial that is being squared, and convert it into a Trinomial. You might be confused as to how we can do this. Well, lets take an example (x+4)^2. Now to convert this Binomial into a Trinomial, we will write the equation as Binomial *Binomial { (x+4)*(x+4) }. Next, use F.OI.L and you will end up with a Quartic polynomial ( x^2+4x+4x+16 ). Finally collect like terms and you will have a Trinomial. You might be thinking "I dont wan't to do these steps, how can I make it easier?"

Well, a simpler rule would be to square the first term (in this case "x"), then add 2*the product of the first and second term (2*(4*x)), and finally add the second term squared (4^2). You will end up with the same answer but in a faster way. This rule applies in the same way if the two terms are being subtracted, but one step would change. Instead of adding 2*the product of the first and second term as our second step, we will subtract 2*the product of the first and second term.

## Difference of Squares

Difference of Squares are when you have two binomials and you want to simplify it.

You will *always *end up with a *single binomial *at the end. For starters, to use Difference of Squares, you need to have two binomials with one of them being added and the second needs to be subtracted (x+4)(x-4).

Now you will use F.O.I.L and will end up with something like this (x^2+4x-4x+16). After collecting like terms you will have a Binomial (x^2-16) (note: for difference of squares you will always end up with the two numbers being subtracted).

You end up with a Binomial because the two middle terms cancel each other out. Again, you might be saying "is there anyway to make this faster?"

Lucky for you, you can just* square the first number and subtract that by the square of the second diget* which would be { (x^2)-(4^2) }.

## Word Problem Using Factored Form (height of a rock)

## Video to Better Understand

## UNIT 3: STANDARD FORM

## Learning Goals

- I am able to use the quadratic formula in a quadratic equation.
- I am able to use the standard form equation, to complete the square, and graph the parabola
- I am able to find the x-intercepts of the equation, by using the quadratic formula.
- I am able to find the vertex of the equation, by completing the square.
- I am able to graph the x-intercepts and the vertex, then draw the parabola.

## Properties

y=ax^2+bx+c Text

"a" value: represents the parabola's direction of opening and shape (stretched or compressed)

"c" value: represents the y-intercept

## Discriminant

The Discriminant adapts the formula that is inside the square root of the Quadratic Formula (b^2-4ac). The Discriminant helps us find out how many solutions the given quadratic equation will have, without us solving the entire equation with the Quadratic Formula. If the value of “** d**” is less than 0, so if it’s a negative, there will be no solutions. If the value of

**is greater than 0, there will be 2 solutions and if the value of**

*d***is 0, there will be 1 solution. So to sum up the Discriminant:**

*d*D<0- no solutions

D>0- 2 solutions

D=0- 1 solution

The Discriminant adapts the formula that is inside the square root of the Quadratic Formula (b^2-4ac). The Discriminant helps us find out how many solutions the given quadratic equation will have, without us solving the entire equation with the Quadratic Formula. If the value of “

” is less than 0, so if it’s a negative, there will be no solutions. If the value of*d*is greater than 0, there will be 2 solutions and if the value of*d*is 0, there will be 1 solution. So to sum up the Discriminant:*d*D<0- no solutions

D>0- 2 solutions

D=0- 1 solution

## Word Problems

## Video to Better Understand

## Reflection

How the Three Different Types of Equations Relate to Graphing:

Vertex Form: Using this form of equation, you will be able to find the vertex using the flipped operation of the value "h" and "k". This helps you determine the maximal or minimal point of the parabola.

Factored Form: Using this form of equation, you will be able to determine the two x-intercepts of the parabola. This will help you plot the x-values on the graph.

Standard Form: Using this form of equation, the direction of opening will be determined. As well as how stretched or compressed the parabola is.