How to graph a quadratic function - Advanced Geometry

Card 0 of 20

Question

What are the possible values of if the parabola of the quadratic function $f (x) = Ax^{2} + 4x- 2$ is concave upward and does not intersect the -axis?

Answer

If the graph of $f (x) = Ax^{2} + 4x- 2$ is concave upward, then .

If the graph does not intersect the -axis, then $Ax^{2} + 4x- 2 = 0$ has no real solution, and the discriminant $4^{2} - 4 \cdot A \cdot \left ( -2\right )$ is negative:

$4^{2} - 4 \cdot A \cdot \left ( -2\right ) < 0$

$8 A \div 8< - 16 \div 8$

For the parabola to have both characteristics, it must be true that and , but these two events are mutually exclusive. Therefore, the parabola cannot exist.

Compare your answer with the correct one above

Question

Which of the following is the equation of the line of symmetry of a horizontal parabola on the coordinate plane with its vertex at ?

Answer

The line of symmetry of a horizontal parabola is a horizontal line, the equation of which takes the form for some . The line of symmetry passes through the vertex, which here is , so the equation must be .

Compare your answer with the correct one above

Question

Which of the following is the equation of the line of symmetry of a vertical parabola on the coordinate plane with its vertex at ?

Answer

The line of symmetry of a vertical parabola is a vertical line, the equation of which takes the form for some . The line of symmetry passes through the vertex, which here is , so the equation must be .

Compare your answer with the correct one above

Question

A vertical parabola has two -intercepts, one at and one at .

Which of the following must be true about this parabola?

Answer

A parabola with its -intercepts at and at has as its equation

for some nonzero . If this is multiplied out, the equation can be rewritten as

$y = a(x^{2}-12x+20)$

or, simplified,

$y = a x^{2}-12ax+20a$

The sign of quadratic coefficient determines whether it is concave upward or concave downward. We do not have the sign or any way of determining it.

The -coordinate of the -intercept is the contant, , but without knowing , we have no way of knowing .

The -coordinate of the vertex of $y = a x^{2}+bx+c$ is the value $- \frac{b}{2a}$ . since , this expression becomes

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

The -coordinate is

$y = a \cdot 6^{2}-12a\cdot 6+20a = 36a - 72a+20a = -16a$ ,

but without knowing , this coordinate, and the vertex itself, cannot be determined.

The line of symmetry is the line $x = - \frac{b}{2a}$ ; this value was computed to be equal to 6, so the line can be determined to be .

Compare your answer with the correct one above

Question

Give the vertex of the graph of the function

$f(x) = 2x^{2}- 8x + 17$ .

Answer

This can be answered rewriting this expression in the form

$f(x) = a(x-h)^{2}+ k$ .

Once this is done, we can identify the vertex as the point .

$f(x) = 2x^{2}- 8x + 17$

$f(x) = 2(x^{2}- 4x) + 17$

$f(x) = 2(x^{2}- 4x+4) - 2(4)+ 17$

$f(x) = 2(x-2) ^{2}- 8+ 17$

$f(x) = 2(x-2) ^{2}+9$

The vertex is

Compare your answer with the correct one above

Question

$f(x)= Ax^{2}+ Bx+ C$ has as its graph a vertical parabola on the coordinate plane. You are given that , but you are given neither nor .

Which of the following can you determine without knowing the values of and ?

I) Whether the curve opens upward or opens downward

II) The location of the vertex

III) The location of the -intercept

IV) The locations of the -intercepts, if there are any

V) The equation of the line of symmetry

Answer

I) The orientation of the parabola is determined solely by the value of . Since , the parabola can be determined to open upward.

II and V) The -coordinate of the vertex is $-\frac{B}{2A}$ ; since you are not given , you cannot find this. Also, since the line of symmetry has equation $x=-\frac{B}{2A}$ , for the same reason, you cannot find this either.

III) The -intercept is the point at which ; by substitution, it can be found to be at . is unknown, so the -intercept cannot be found.

IV) The -intercept(s), if any, are the point(s) at which $f(x)= Ax^{2}+ Bx+ C = 0$ . This is solvable using the quadratic formula

$x= \frac{-B \pm \sqrt{B^{2}-4AC}}{2A}$

Since all three of and must be known for this to be evaluated, and only is known, the -intercept(s) cannot be identified.

The correct response is I only.

Compare your answer with the correct one above

Question

$f(x)= Ax^{2}+ Bx+ C$ has as its graph a vertical parabola on the coordinate plane. You are given that and , but you are not given .

Which of the following can you determine without knowing the value of ?

I) Whether the graph is concave upward or concave downward

II) The location of the vertex

III) The location of the -intercept

IV) The locations of the -intercepts, if there are any

V) The equation of the line of symmetry

Answer

I) The orientation of the parabola is determined solely by the sign of . Since , the parabola can be determined to be concave downward.

II and V) The -coordinate of the vertex is $-\frac{B}{2A}$ ; since you are not given , you cannot find this. Also, since the line of symmetry has equation $x=-\frac{B}{2A}$ , for the same reason, you cannot find this either.

III) The -intercept is the point at which ; by substitution, it can be found to be at . known to be equal to 9, so the -intercept can be determined to be .

IV) The -intercept(s), if any, are the point(s) at which $f(x)= Ax^{2}+ Bx+ C = 0$ . This is solvable using the quadratic formula

$x= \frac{-B \pm \sqrt{B^{2}-4AC}}{2A}$

Since all three of and must be known for this to be evaluated, and only is known, the -intercept(s) cannot be identified.

The correct response is I and III only.

Compare your answer with the correct one above

Question

$f(x)= Ax^{2}+ Bx+ C$ has as its graph a vertical parabola on the coordinate plane. You are given that and , but you are not given the value of .

Which of the following can you determine without knowing the value of ?

I) Whether the graph is concave upward or concave downward

II) The location of the vertex

III) The location of the -intercept

IV) The locations of the -intercepts, if there are any

V) The equation of the line of symmetry

Answer

I) The orientation of the parabola is determined solely by the sign of . Since , a positive value, the parabola can be determined to be concave upward.

II) The -coordinate of the vertex is $-\frac{B}{2A}$ ; since you given both and , you can find this to be

$h = -\frac{B}{2A} = -\frac{10}{2 (4)} =- \frac{5}{4}$

The -coordinate is equal to $f\left ( \frac{-5}{4} \right )$ . However, you need the entire equation to determine this value; since you do not know , you cannot find the -coordinate. Therefore, you cannot find the vertex.

III) The -intercept is the point at which ; by substitution, it can be found to be at . is unknown, so the -intercept cannot be found.

IV) The -intercept(s), if any, are the point(s) at which $f(x)= Ax^{2}+ Bx+ C = 0$ . This is solvable using the quadratic formula

$x= \frac{-B \pm \sqrt{B^{2}-4AC}}{2A}$

Since all three of and must be known for this to be evaluated, and is unknown, the -intercept(s) cannot be identified.

V) The line of symmetry has equation $x=-\frac{B}{2A}$ . When exploring the vertex, we found that this value is equal to $- \frac{5}{4}$ , so the line of symmetry is the line of the equation $x=- \frac{5}{4}$ .

The correct response is I and V only.

Compare your answer with the correct one above

Question

$f(x)= Ax^{2}+ Bx+ C$ has as its graph a vertical parabola on the coordinate plane. You are given that , but you are given no other information about these values.

Which of the following can you determine without knowing the value of ?

I) Whether the graph is concave upward or concave downward

II) The location of the vertex

III) The location of the -intercept

IV) The locations of the -intercepts,or whether there are any

V) The equation of the line of symmetry

Answer

I) The orientation of the parabola is determined solely by the sign of . It is given in the problem that is negative, so it follows that the parabola is concave downward.

II) The -coordinate of the vertex is $-\frac{B}{2A}$ ; since , this number is $-\frac{A}{2A} = -\frac{1}{2}$ . The -coordinate is $f\left (- \frac{1}{2} \right )$ , but since we do not know the values of , , and , we cannot find this value. Therefore, we cannot know the vertex.

III) The -intercept is the point at which ; by substitution, it can be found to be at . is unknown, so the -intercept cannot be found.

IV) The -intercept(s), if any, are the point(s) at which $f(x)= Ax^{2}+ Bx+ C = 0$ . This is solvable using the quadratic formula

$x= \frac{-B \pm \sqrt{B^{2}-4AC}}{2A}$

Since , this can be rewritten and simplified as follows:

$x= \frac{-A \pm \sqrt{A^{2}-4A \cdot A}}{2A}$

$x= \frac{-A \pm \sqrt{A^{2}-4A^{2}}}{2A}$

$x= \frac{-A \pm \sqrt{ -3A^{2}}}{2A}$

$x= \frac{-A \pm A \sqrt{ -3 }}{2A}$

$x= \frac{-1 \pm \sqrt{ -3 }}{2 }$

However, since has no real square root, $f(x)= Ax^{2}+ Bx+ C = 0$ has no real solutions, and its graph has no -intercepts.

V) The line of symmetry has equation $x=-\frac{B}{2A}$ . When exploring the vertex, we found that this value is equal to $- \frac{1}{2}$ , so the line of symmetry is the line of the equation $x=- \frac{1}{2}$ .

The correct response is I, IV, and V only.

Compare your answer with the correct one above

Question

Which of the following equations has as its graph a vertical parabola with line of symmetry ?

Answer

The graph of $f(x)= Ax^{2}+Bx+ C$ has as its line of symmetry the vertical line of the equation

$x=- \frac{B}{2A}$

Since in each choice, we want to find such that

$7=- \frac{B}{2A} = - \frac{B}{2(7)} = - \frac{B}{14}$

$- \frac{B}{14} = 7$

$B = 7\cdot (-14)=-98$

so the correct choice is $f(x)=7x^{2}-98x+140$ .

Compare your answer with the correct one above

Question

Which of the following equations can be graphed with a vertical parabola with exactly one -intercept?

Answer

The graph of $f(x)= Ax^{2}+Bx+ C$ has exactly one -intercept if and only if

$Ax^{2}+Bx+ C = 0$

has exactly one solution - or equivalently, if and only if

$B^{2}-4AC = 0$

Since in all three equations, , we find the value of that makes this statement true by substituting and solving:

$(12)^{2}-4(3)C = 0$

The correct choice is $f(x)= 3x^{2}- 12x + 12$ .

Compare your answer with the correct one above

Question

Which of the following equations has as its graph a concave-right horizontal parabola?

Answer

A horizontal parabola has as its equation, in standard form,

$x= Ay^{2}+ By+ C$ ,

with real, nonzero.

Its orientation depends on the sign of . In the equation of a concave-right parabola, is positive, so the correct choice is $x=7y^{2}- 4y+13$ .

Compare your answer with the correct one above

Question

The graphs of the functions and have the same -intercept.

If we define $f(x) = 2x^{2}+ 4x+7$ , which of the following is a possible definition of ?

Answer

The -coordinate of the -intercept of the graph of a function of the form $f(x)= Ax^{2}+Bx+C$ - a quadratic function - is the point . Since $f(x)= A \cdot 0^{2}+B \cdot 0 +C = C$ , the -intercept is at the point .

Because of this, the graph of $f(x) = 2x^{2}+ 4x+7$ has its -intercept at . Among the other choices, only $g(x) = 4x^{2}+ 8x+7$ has a graph with its -intercept also at .

Compare your answer with the correct one above

Question

Give the set of intercepts of the graph of the function $f(x)= \frac{1}{7} (x-7)^{2}$ .

Answer

The -intercepts, if any exist, can be found by setting :

$f(x)= \frac{1}{7} (x-7)^{2} = 0$

$\frac{1}{7} (x-7)^{2} \cdot 7 = 0\cdot 7$

$(x-7)^{2} = 0$

The only -intercept is .

The -intercept can be found by substituting 0 for :

$f(0)= \frac{1}{7} (0-7)^{2} = \frac{1}{7} ( -7)^{2}= \frac{1}{7} \cdot 49 = 7$

The -intercept is .

The correct set of intercepts is $\left { (7,0), (0,7) \right }$ .

Compare your answer with the correct one above

Question

The parabolas of the functions and on the coordinate plane have the same vertex.

If we define $f(x) = \frac{4}{5}(x-9)^{2}+ 6$ , which of the following is a possible equation for ?

Answer

The eqiatopm of is given in the vertex form

$f(x) =a(x-h)^{2}+ k$ ,

so the vertex of its parabola is . The graphs of and are parabolas with the same vertex, so they must have the same values for and .

For the function $f(x) = \frac{4}{5}(x-9)^{2}+ 6$ , and .

Of the five choices, the only equation of that has these same values, and that therefore has a parabola with the same vertex, is $g(x) = \frac{3}{5}(x-9)^{2}+ 6$ .

To verify, graph both functions on the same grid.

Compare your answer with the correct one above

Question

Give the -coordinate of a point of intersection of the graphs of the functions

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

and

.

Answer

The system of equations can be rewritten as

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

.

We can set the two expressions in equal to each other and solve:

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

$x^{2}- 8x+ 7 =0$

We can substitute back into the equation , and see that either or . The latter value is the correct choice.

Compare your answer with the correct one above

Question

The graphs of the functions and have the same pair of -intercepts.

If we define $g(x) = x^{2}- 7x +10$ , which of the following is a possible definition of ?

Answer

The -intercepts of the parabola

$g(x) = x^{2}- 7x +10$

can be determined by setting and solving for :

$x^{2}- 7x +10 = 0$

or

The intercepts of the parabola are and .

We can check each equation to see whether these two ordered pairs satisfy them.

$f(x) = x^{2}- 7x +20$ :

$f(2) = 2^{2}- 7 \cdot 2 +20 = 4-14+20 = 10 e 0$

$f(x) = - x^{2}- 7x +10$

$f(2) = - 2^{2}- 7 \cdot 2 +10 = -4 -14 + 10 = -8 e 0$

$f(x) = x^{2}- 7x-10$

$f(2) = 2^{2}- 7 \cdot 2-10 = 4 - 14 - 10 =-20 e 0$

$f(x) = 2 x^{2}- 14x +10$

$f(x) = 2 \cdot 2^{2}- 14\cdot 2 +10= 8 - 28+10 = -10 e 0$

Each of these equations has a parabola that does not have as an -intercept. However, we look at

$f(x) = 2 x^{2}- 14x +20$

$f(2) = 2\cdot 2^{2}- 14 \cdot 2 +20= 8 - 28 + 20 = 0$

$f(5) = 2\cdot 5^{2}- 14 \cdot 5 +20= 50 - 70+ 20 = 0$

and are also -intercepts of the graph of this function, so this is the correct choice.

Compare your answer with the correct one above

Question

Give the -coordinate of a point at which the graphs of the equations

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

and

$y = 2x^{2}- 6x+5$

intersect.

Answer

We can set the two quadratic expressions equal to each other and solve for .

$y= x^{2}+ 2x- 7$ and $y = 2x^{2}- 6x+5$ , so

$2x^{2}- 6x+5 = x^{2}+ 2x- 7$

$2x^{2}- 6x+5 -( x^{2}+ 2x- 7)= x^{2}+ 2x- 7 -( x^{2}+ 2x- 7)$

$2x^{2}- 6x+5 - x^{2}- 2x+ 7=0$

$x^{2}- 8x+12=0$

The -coordinates of the points of intersection are 2 and 6. To find the -coordinates, substitute in either equation:

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

$y= 2^{2}+ 2 \cdot 2 - 7$

One point of intersection is .

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

$y= 6^{2}+ 2 \cdot 6 - 7$

The other point of intersection is .

1 is not among the choices, but 41 is, so this is the correct response.

Compare your answer with the correct one above

Question

The graphs of the functions and have the same line of symmetry.

If we define $f(x) = 2x^{2}+ 4x+7$ , which of the following is a possible definition of ?

Answer

The graph of a function of the form $f(x)= Ax^{2}+Bx+C$ - a quadratic function - is a vertical parabola with line of symmetry $x= - \frac{B}{2A}$ .

The graph of the function $f(x) = 2x^{2}+ 4x+7$ therefore has line of symmetry

$x= - \frac{4}{2 (2)}$ , or

We examine all four definitions of to find one with this line of symmetry.

$g(x) = 2x^{2}-4x-7$ :

$x= - \frac{-4}{2 (2)}$ , or

$g(x) = x^{2}+ 4x+7$ :

$x= - \frac{ 4}{2 (1)}$ , or

$g(x) = 2x^{2}+ 8x+7$

$x= - \frac{ 8}{2 (2)}$ , or

$g(x) = 4x^{2}+8x+7$

$x= - \frac{ 8}{2 (4)}$ , or

Since the graph of the function $g(x) = 4x^{2}+8x+7$ has the same line of symmetry as that of the function $f(x) = 2x^{2}+ 4x+7$ , that is the correct choice.

Compare your answer with the correct one above

Question

Find the vertex and determine if the vertex is a maximum or minimum for below.

$f(x)=-x^{2}+2x-8$

Answer

The correct answer for the vertex is found by first finding the x of the vertex:

$x=\frac{-b}{2a}\ where\ a=-1\ and\ b=2$

Plug in a and b to get:

$x=\frac{-2}{2(-1)}=\boldsymbol{\mathit{}1}$

To find the y value of the vertex, plug in what was found for x above in the original f(x).

$f(x)=-x^{2}+2x-8\ plug\ in\ x=1$

$f(1)=-(1)^{2}+2(1)-8=\boldsymbol{\mathit{}-7}$

a common mistake here is the order of operations, at the beginning the 1 is squared before it is multipled by the negative out front.

$The\ vertex\ is\ \boldsymbol{\mathbf{\mathit{}}(1,-7)}$

Now we must consider if the vertex is a MAX or a MIN

Since the a value is negative, this means the parabola will open down, which means the vertex is the highest point on the graph.

$The\ vertex\ is\ the\ \boldsymbol{MAX}$

Compare your answer with the correct one above

Tap the card to reveal the answer