All Algebra II Resources
Example Questions
Example Question #111 : Quadratic Functions
In which direction does the graph of the hyperbola open?
vertical
horizontal
horizontal
The equation for a horizontal hyperbola is . The equation for a vertical hyperbola is . The x-term appears first, so the given equation represents a horizontal hyperbola.
Example Question #112 : Quadratic Functions
In which direction does the graph of the above hyperbola open?
vertical
horizontal
horizontal
To determine which direction a hyperbola opens, first get the equation into standard form for a conic section:
This equation gives us a hyperbola when the coefficient in front of either the x-squared or the y-squared term (but not both!) is negative. In this problem, the coefficient in front of the x-squared term is positive, but the coefficient of the y-squared term is negative. Here are the rules for hyperbola directions:
- If the coefficient of the x-squared term is positive but the coefficient of the y-squared term is negative, this is a hyperbola that opens horizontally.
- If the coefficient of the x-squared term is negative but the coefficient of the y-squared term is positive, this is a hyperbola that opens vertically.
Thus, we have a graph of a horizontal hyperbola.
Example Question #2 : Graphing Hyperbolic Functions
What are the vertices of this hyperbola?
The first thing we need to find for this hyperbola is the center. This is simply the point where and both equal , which is . Since the term is the positive one, the hyperbola opens horizontally, which means we need to look at the denominator of that term.
The denominator is which is , so our vertices are , or
and .
Example Question #2 : Graphing Hyperbolic Functions
Write the expression for this hyperbola in standard form:
The standard form of a hyperbola is
or the similar form with a positive term and negative term. So to start out getting this equation in standard form, we must complete the square on the quadratics in and .
the coefficient of is , so completing the square we get
and similarly with we get
and so our starting expression can be written as
Dividing by on both sides we get the standard representation of the hyperbola,
Example Question #1 : Graphing Hyperbolic Functions
Find the vertices of the following hyperbolic function:
We start by noticing that our hyperbola is given in the following form:
In order to determine the vertices of the hyperbola, we must first locate its center. Using the standard form given above, we know the center of the hyperbola occurs at the point (h,k), so for the equation given in the problem the center is at (2,-3). Now that we know the location of the hyperbola's center, our next step is to determine how far the vertices are from the center of the hyperbola. Looking at our equation, we can see it is in the form where the x term occurs first, which means the hyperbola opens left and right as opposed to up and down (which would be the case if the y term occurred first. Given this information, we know the vertices of the hyperbola are going to be a distance to the left and right of the center. The denominator of the x term in the hyperbolic equation is 16, which means is equal to 4, so the vertices of the hyperbola will be 4 units to the left and right of the center (2,-3), which gives us:
and
Example Question #1 : Graphing Parabolic Inequalities
Give the solution set of the inequality:
The inequality has no solution
Rewrite in standard form and factor:
The zeroes of the polynomial are therefore , so we test one value in each of three intervals , , and to determine which ones are included in the solution set.
:
Test :
False; is not in the solution set.
:
Test
True; is in the solution set
:
Test :
False; is not in the solution set.
Since the inequality symbol is , the boundary points are not included. The solution set is the interval .
Example Question #511 : Functions And Graphs
Give the set of solutions for this inequality:
This inequality has no solution.
The first step of questions like this is to get the quadratic in its standard form. So we move the over to the left side of the inequality:
This quadratic can easily be factored as. So now we can write this in the form
and look at each of the factors individually. Recall that a negative number times a negative is a positive number. Therefore the boundaries of our solution interval is going to be when both of these factors are negative. is negative whenever , and is negative whenever . Since , one of our boundaries will be . Remember that this will be an open interval since it is less than, not less than or equal to.
Our other boundary will be the other point when the product of the factors becomes positive. Remember that is positive when , so our other boundary is . So the solution interval we arrive at is
Example Question #3 : Graphing Parabolic Inequalities
Solve for
When asked to solve for x we need to isolate x on one side of the equation.
To do this our first step is to subtract 7 from both sides.
From here, we divide by 4 to solve for x.
Example Question #1 : Graphing Parabolic Inequalities
Solve for
When asked to solve for y we need to isolate the variable on one side and the constants on the other side.
To do this we first add 9 to both sides.
From here, we divide by -12 to solve for y.
Example Question #1 : Quadratic Inequalities
The graphs for the lines and are shown in the figure. The region is defined by which two inequalities?
The region contains only values which are greater than or equal to those on the line , so its values are .
Also, the region contains only values which are less than or equal to those on the line , so its values are .