All Advanced Geometry Resources
Example Questions
Example Question #111 : Advanced Geometry
Example Question #112 : Advanced Geometry
Give the range of the function
.
The set of all real numbers
The set of all real numbers
Let
A logarithm can take any real value. Therefore, the range of is the set of real numbers, as is any linear transformation of .
In terms of ,
making such a transformation. This makes the range of the set of all real numbers.
Example Question #113 : Advanced Geometry
Give the domain of the equation
.
The set of all real numbers
A logarithm can be taken of a number if and only if the number is positive. Therefore,
is defined if and only if
or equivalently, subtracting 2 from both sides:
The correct domain is the set .
Example Question #21 : How To Graph A Logarithm
Give the equation of the vertical asymptote of the graph of the equation
.
The graph of does not have a vertical asymptote.
Let
In terms of ,
This is the graph of shifted left 2 units ( ), then shifted down 3 units ( ).
The graph of has as its vertical asymptote the line of the equation . The downward shift does not affect the position of this asymptote, but the left shift moves it down to the line of the equation .
Example Question #115 : Advanced Geometry
Give the equation of the horizontal asymptote of the graph of the equation
.
The graph of does not have a horizontal asymptote.
The graph of does not have a horizontal asymptote.
Let
In terms of ,
This is the graph of shifted left 2 units, then shifted down 3 units.
The graph of does not have a horizontal asymptote; therefore, a transformation of this graph, such as that of , does not have a horizontal asymptote either.
Example Question #26 : Graphing
Give the -coordinate of the -intercept of the graph of the equation
.
The graph of does not have a -intercept
The -intercept of the graph of is the point at which it intersects the -axis. Its -coordinate is 0; its -coordinate is , which can be found by substituting 0 for in the definition:
or
This does not appear among the choices in this form. However, by definition,
,
so if
,
,
and
.
And
By a property of logarithms, the difference of the logarithms of two numbers is equal to the logarithm of the quotient of those numbers, so
.
This is the correct choice.
Example Question #23 : Coordinate Geometry
Give the -coordinate of the -intercept of the graph of the equation
.
The graph of does not have an -intercept
The -intercept(s) of the graph of are the point(s) at which it intersects the -axis. The -coordinate of each is 0; their -coordinate(s) are those value(s) of for which , so set up, and solve for , the equation:
Add 3 to both sides:
"Log" indicates a common, or base ten, logarithm, so raise 10 to the power of both sides to eliminate the logarithm:
Subtract 2 from both sides:
,
the correct choice.
Example Question #1 : Graphing
Give the -intercept(s) of the graph of the equation
The graph has no -intercept.
Set and solve for :
Example Question #1 : How To Graph An Exponential Function
Define a function as follows:
Give the -intercept of the graph of .
The graph of has no -intercept.
The graph of has no -intercept.
Since the -intercept is the point at which the graph of intersects the -axis, the -coordinate is 0, and the -coordinate can be found by setting equal to 0 and solving for . Therefore, we need to find such that . However, any power of a positive number must be positive, so for all real , and has no real solution. The graph of therefore has no -intercept.
Example Question #2 : Graphing
Define a function as follows:
Give the vertical aysmptote of the graph of .
The graph of does not have a vertical asymptote.
The graph of does not have a vertical asymptote.
Since any number, positive or negative, can appear as an exponent, the domain of the function is the set of all real numbers; in other words, is defined for all real values of . It is therefore impossible for the graph to have a vertical asymptote.