Completing the Square - Algebra 2

Card 1 of 280

0

Didn't Know

0

Didn't Know

Knew It

0

1 of 2019 left

Question

Re-write this quadratic in vertex form by completing the square:

Tap to reveal answer

Answer

First, factor out the 2 from the first 2 terms:

add 3 to both sides

inside the parentheses, add $\left (\frac{4}{2} \right )^2 = 2^2 = 4$

since the 4 was added in the parentheses, it's multiplied by 2. That means we added 8, so add 8 to the other side too

simplify by re-writing the left and adding 3 and 8 on the right

subtract 11 from both sides

← Didn't Know|Knew It →

Question

Solve by completing the square:

Tap to reveal answer

Answer

Add 7 to both sides:

Divide both sides by the coefficient on x^2:

$x^2+\frac{3}{2}x=\frac{7}{2}$

Add $(\frac{b}{2})^2$ to both sides:

$x^2+\frac{3}{2}x+(\frac{3}{4})^2=\frac{7}{2}+(\frac{3}{4})^2$

Form the perfect square on the left side:

$(x+\frac{3}{4})^2=\frac{7}{2}+\frac{9}{16}$

Simplify the right side:

$(x+\frac{3}{4})^2=\frac{65}{16}$

Take the square root of both sides:

$x+\frac{3}{4}=\pm\sqrt{\frac{65}{16}}$

Solve for x:

$x=-\frac{3}{4}\pm\frac{\sqrt{65}}{4}$

$x=-\frac{3\pm\sqrt{65}}{4}$

← Didn't Know|Knew It →

Question

Use the method of completing the square to find the roots of the function:

Tap to reveal answer

Answer

To complete the square, we must remember that our goal is to make a perfect square trinomial out of the terms we have.

We are given a function that we must set equal to zero if we want to find its roots:

Now, subratct 1 to the other side so we have only x-terms on one side:

Now, on the left side of the equation, in order to make a perfect square trinomial, we must take the coefficient of x - in this case, -6, and divide it by two, and then square that number:

$-\frac{6}{2}=-3$

This term becomes our "c" for the trinomial . However, because we introduced this new term on the left side of the equation, we must add it to the right hand side as well, so that we aren't "changing" the original equation:

Next, we can convert the perfect square trinomial into the square of a binomial:

This comes from the definition of the binomial, squared. When we FOIL (or use the memory tool "square the first term, square the last term, multiply the two terms and double") we get our original trinomial.

Now, to solve for x, take the square root of both sides, and add three to the other side:

$x-3=\pm \sqrt{8}=\pm\sqrt{4\cdot 2} = \pm2\sqrt{2}$

$x=3\pm2\sqrt{2}$ .

← Didn't Know|Knew It →

Question

What number should be added to the expression below in order to complete the square?

Tap to reveal answer

Answer

To complete the square for any expression in the form , you must add $\left ( \frac{b}{2}\right )^2$ .

In this case, $\left ( \frac{b}{2}\right )^2=\left ( \frac{14}{2}\right )^2=7^2=49$

← Didn't Know|Knew It →

Question

What number should be added to the expression below in order to complete the square?

Tap to reveal answer

Answer

To complete the square for any expression in the form , you must add $\left ( \frac{b}{2}\right )^2$ .

In this case, $\left ( \frac{b}{2}\right )^2=\left ( \frac{-9}{2}\right )^2=\frac{81}{4}$

← Didn't Know|Knew It →

Question

$y=x^{2}-4x+7$

Complete the square in order to find the vertex of this parabola.

Tap to reveal answer

Answer

To find the vertex of the parabola, you have to get it into vertex form:

$y=a[b(x-h)]^{2}+k$

The vertex can then be found at the coordinate .

To get to vertex form, we have to complete the square.

$y=x^{2}-4x+7$

Move the 7 over to the other side by subtracting 7 from both sides of the equation:

$y-7=x^{2}-4x$

You're going to have to add something to both sides of the equation...

$y-7+\square =x^{2}-4x+\square$

...the question now is what. What number, when put in the box, would create a "perfect square" on the right-hand side of the equation?

Well, a perfect square trinomial is one whose factors are the same, like so:

$(x+a)^{2}=x^{2}+2ax+a^{2}$

In other words, we're looking for .

Well, if $a^{2}$ is what goes in the box, and $x^{2}$ is just $x^{2}$ , then must equal . Now we can solve for .

And since $a^{2}$ goes in the box, we need to add 4 to both sides:

$y-7+4 =x^{2}-4x+4$

Now we can factor the right-hand side very neatly:

$y-7+4 =(x-2)^{2}$

After we clean up a bit...

$y-3 =(x-2)^{2}$

...we get:

$y=(x-2)^{2}+3$

That gives us a vertex of .

← Didn't Know|Knew It →

Question

Solve by completing the square:

$\small x^2-8x+9=0$

Tap to reveal answer

Answer

To complete the square, the equation must be in the form:

$\small \small ax^2+2ab+b^2=c$

$\small x^2-8x+9=0$

$\small a=1$

$\small 2ab=-8$

$\small b=-4$

$\small b^2=16$

$\small x^2-8x+9+7=0+7$

$\small x^2-8x+16=7$

$\small (x-4)^2=7$

$\small \small x-4=\pm\sqrt7$

$\small x=4\pm\sqrt7$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square. Use a calculator to determine the answer to the closest hundredth.

Tap to reveal answer

Answer

To solve by completing the square, you should first take the numerical coefficient to the “right side” of the equation:

Then, divide the middle coefficient by 2:

$\frac{4}{2}=2$

Square that and add it to both sides:

Now, you can factor the quadratic:

Take the square root of both sides:

$x+2 = \pm \sqrt{7}$

Finish out the solution:

$x = \pm\sqrt{7}-2$

$\sqrt{7}-2 = 0.64575131106459$

$-\sqrt{7}-2=-4.64575131106459$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square. Use a calculator to determine the answer to the closest hundredth.

Tap to reveal answer

Answer

To solve by completing the square, you should first take the numerical coefficient to the “right side” of the equation:

Then, divide the middle coefficient by 2:

$\frac{8}{2} = 4$

Square that and add it to both sides:

Now, you can easily factor the quadratic:

Take the square root of both sides:

$x+ 4 = \pm\sqrt{28}$

Finish out the solution:

$x=\pm\sqrt{28}-4$

$\sqrt{28} - 4 = 1.29150262212918$

$-\sqrt{28} - 4 = -9.29150262212918$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square. Use a calculator to determine the answer to the closest hundredth.

Tap to reveal answer

Answer

To solve by completing the square, you should first take the numerical coefficient to the “right side” of the equation:

Then, divide the middle coefficient by 2:

$\frac{-12}{2}=-6$

Square that and add it to both sides:

Now, you can easily factor the quadratic:

Take the square root of both sides:

$x- 6 = \pm\sqrt{52}$

Finish out the solution:

$x=\pm\sqrt{52}+6$

$\sqrt{52} + 6 = 13.21110255092798$

$-\sqrt{52} + 6 = -1.21110255092798$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square. Use a calculator to determine the answer to the closest hundredth.

Tap to reveal answer

Answer

To solve by completing the square, you should first take the numerical coefficient to the “right side” of the equation:

Then, divide the middle coefficient by 2:

$\frac{-20}{2}=-10$

Square that and add it to both sides:

Now, you can easily factor the quadratic:

Take the square root of both sides:

$x - 10 = \pm\sqrt{69}$

Finish out the solution:

$x=\pm\sqrt{69}+10$

$\sqrt{69} +10 = 18.30662386291807$

$-\sqrt{69} +10 = 1.69337613708192$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square. Use a calculator to determine the answer to the closest hundredth.

Tap to reveal answer

Answer

To solve by completing the square, you should first take the numerical coefficient to the “right side” of the equation:

Then, divide the middle coefficient by 2:

$\frac{5}{2}= 2.5$

Square that and add it to both sides:

Now, you can easily factor the quadratic:

Take the square root of both sides:

$x + 2.5 = \pm \sqrt{18.25}$

Finish out the solution:

$x=\pm\sqrt{18.25}-2.5$

$\sqrt{18.25} - 2.5=1.77200187265877$

$-\sqrt{18.25} - 2.5 = -6.77200187265876$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square. Use a calculator to determine the answer to the closest hundredth.

Tap to reveal answer

Answer

To solve by completing the square, you should first take the numerical coefficient to the “right side” of the equation:

Then, divide the middle coefficient by 2:

$\frac{7}{2} = 3.5$

Square that and add it to both sides:

Now, you can easily factor the quadratic:

Your next step would be to take the square root of both sides. At this point, however, you know that you cannot solve the problem. When you take the square root of both sides, you will be forced to take the square root of . This is impossible (at least in terms of real numbers), meaning that this problem must have no real solution.

← Didn't Know|Knew It →

Question

Use completing the square to solve the following equation, simplifying radicals completely:

Tap to reveal answer

Answer

From the original equation, we add 18 to both sides in order to set up our "completing the square."

To make completing the square sensible, we divide both sides by 2.

$\frac{22}{2} = \frac{2x^2 + 12x}{2}$

We now divide the x coefficient by 2, square the result, and add that to both sides.

$\frac{6}{2} = 3$

Since the right side is now a perfect square, we can rewrite it as a square binomial.

Take the square root of both sides, simplify the radical and solve for x.

$\sqrt{20}=\sqrt{(x+3)^2}$

$\pm2\sqrt{5} = x+ 3$

$-3 \pm 2\sqrt{5} = x$

← Didn't Know|Knew It →

Question

Use completing the square to re-write the follow parabola equation in vertex form:

Tap to reveal answer

Answer

Vertex form for a parabola is

where (h, k) is the vertex.

We start by eliminating the leading coefficient by dividing both sides by 3.

$\frac{y}{3} = \frac{3x^2 + 12x + 18}{3}$

$\frac{y}{3} = x^2 + 4x + 6$

We now subtract 6 from both sides to set up our "completing the square" technique.

$\frac{y}{3} - 6 = x^2 + 4x +6 - 6$

$\frac{y}{3} - 6 = x^2 + 4x$

To complete the square, we divide the x coefficient by 2, square the result, and add that result to both sides.

$\frac{y}{3} - 6 + 4 = x^2 + 4x + 4$

$\frac{y}{3} - 2 = x^2 + 4x +4$

Since the right side is now a perfect square, we can rewrite it as a squared binomial.

$\frac{y}{3} - 2 = (x + 2)^2$

Solve for y by adding 2 to both sides, then multiplying both sides by 3.

$\frac{y}{3} - 2 +2= (x + 2)^2 +2$

$\frac{y}{3} = (x + 2)^2 + 2$

$3\frac{y}{3} = ((x +2)^2 + 2)3$

← Didn't Know|Knew It →

Question

Solve the following equation by completing the square:

Tap to reveal answer

Answer

We start by moving the constant term of the quadratic to the other side of the equation, to set up the "completing the square" format.

Now to make completing the square sensible, we divide boths sides by 2 so that x^2 will not have a coefficient.

$\frac{2x^2 -4x}{2} = \frac{2}{2}$

Now we can complete the square by dividing the x coefficient by 2 and squaring the result, then adding that result to both sides.

$\frac{-2}{2} = -1$

Because the left side is now a perfect square, we can rewrite it as a squared binomial.

Take the square root of both sides, and then solve for x.

$\sqrt{(x-1)^2} = \sqrt{2}$

$x-1 = \pm \sqrt{2}$

$x = 1 \pm \sqrt{2}$

← Didn't Know|Knew It →

Question

Rewrite the follow parabola equation in vertex form:

Tap to reveal answer

Answer

We start by moving the constant term of the quadratic over to the other side of the equation, in order to set up our "completing the square" form.

Next we divide both sides by 4 so that the x^2 coefficient will be 1. That will allow us to complete the square.

$\frac{y-16}{4} = \frac{4x^2 + 24x}{4}$

$\frac{y}{4} - 4 = x^2 + 6 x$

Now we are ready to complete the square. We divide the x coefficient by 2, square the result, and add that result to both sides.

$\frac{6}{2} = 3$

$\frac{y}{4} - 4 + 9 = x^2 + 6 x + 9$

$\frac{y}{4} +5 = x^2 + 6 x + 9$

Because the right side is now a perfect square, we can rewrite it as a squared binomial.

$\frac{y}{4} + 5 = (x+3)^2$

To finish, all we have to do now is solve for y. We'll subtract 5 to both sides, then multiply by 4.

$\frac{y}{4} + 5 -5 = (x+3)^2 - 5$

$\frac{y}{4} = (x+3)^2 - 5$

$4\frac{y}{4} = ((x+3)^2 - 5)4$

← Didn't Know|Knew It →

Question

Solve $\small x^2-4x=4x+65$ by completing the square.

Tap to reveal answer

Answer

To complete the square, we need to have the x terms on one side and the numbers on the other. Therefore,

$\small \small x^2 -4x=4x+65$

becomes

$\small \small x^2-8x=65$

When we want to complete the square, we want an equation in the form $\small \small \small a^2 + 2ab + b^2$ or $\small \small a^2 -2ab+b^2$ so that we can factor it into $\small \small (a+ b)^{2}$ or $\small (a-b)^2$ . To do this, we take half of the numeric portion of what we want our b term to be (in this problem $\small \small -8x$ ) and square it, therefore:

$\small b^2 = (\frac{1}{2}(-8))^{2}=(-4)^2=16$

Therefore, we add 16 to each side to obtain:

$\small x^2-8x+16 = 81$

$\small (x-4)^{2}=81$

$\small x-4=\pm9$

$\small x=13$ and $\small x=-5$

← Didn't Know|Knew It →

Question

Solve $\small \small \small 3x^2 + 36x=-33$ by completing the square.

Tap to reveal answer

Answer

To complete the square, we need the left side in a form $\small a^2 + 2ab +b^2$ or $\small a^2-2ab+b^2$ so that we can factor it into form $\small (a+b)^2$ or $\small (a-b)^2$ .

To do this, we first divide out three on the left-hand side to obtain:

$\small 3(x^2+12x)=-33$

We then take 1/2 of the number in our $\small 2ab$ term (in this case $\small 12x$ ) to obtain $\small b^2$ :

$\small b^2=(\frac{1}{2}(12))^2=(6)^2=36$

We then must add this to each side, but because we are completing the square inside of a parenthesis which is being multiplied by 3, we don't add 36 to each side, but rather 3 times 36, or 108. Therefore, we obtain:

$\small 3(x^2 +12x+36)=-33+108$

$\small 3(x+6)^2=75$

$\small (x+6)^{2}=25$

$\small x+6=\pm5$

$\small x=-1$ and $\small x=-11$

← Didn't Know|Knew It →

Question

Solve for .

Tap to reveal answer

Answer

Once the polynominal is factored out and everything is moved to the left, the equation becomes which does not factor evenly, so you could use the quadratic formula, or complete the square. To complete the square, a coefficient must be found to factor the polynominal into a perfect square. The polynominal factors to so we know that so and . To complete the square you add and subtract from the left side of the equation and strategically place parentheses to get , this simplifies to , which simplifies to $x=-2\pm{\sqrt{5}}$ ,

← Didn't Know|Knew It →

0

Knew It