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VCE 12 Methods 2023

4.02 Transformations of the natural exponent function

Lesson

In the investigation for this chapter we look at a special number, the mathematical constant, $e$e. We showed that $e$e is defined as $\lim_{n\rightarrow\infty}\left(1+\frac{1}{n}\right)^n$limn(1+1n)n and is the irrational number $2.7128\dots$2.7128. In our previous lesson we explored exponential functions of the form $y=a^x$y=ax, a very important member of this family of curves is $y=e^x$y=ex

As a member of this family of curves we can see it has the same properties and sits between the functions $y=2^x$y=2x and $y=3^x$y=3x.

 

Graphs of $y=2^x$y=2x$y=e^x$y=ex and $y=3^x$y=3x

 

Key features:

  • Exponential growth: As the $x$x-values increase, the $y$y-values increase at an increasing rate.

  • The $y$y-intercept is $\left(0,1\right)$(0,1), since when $x=0$x=0$y=a^0=1$y=a0=1, for any positive value $a$a.

  • $y=0$y=0 is a horizontal asymptote for each graph. As $x\ \rightarrow-\infty$x , $y\ \rightarrow0^+$y 0+

  • Domain: $x$x is any real number

  • Range: $y>0$y>0

The three functions above can be viewed as horizontal dilations of each other. Using transformations we can in fact write any exponential function with a base of $e$e. Using a base of $e$e will become fundamental in exponential applications involving calculus. The function $f\left(x\right)=e^x$f(x)=ex has the remarkable property that $f'\left(x\right)=f\left(x\right)$f(x)=f(x) and we will see using a base of $e$e will often simplify required processes and calculations.

Just as with functions of the form $y=a^x$y=ax we can perform transformations on the graph $y=e^x$y=ex.

Worked example

a) For the function $y=e^x$y=ex, describe the transformations required to obtain the graph of $y=2\times e^x+3$y=2×ex+3.

Think: For the function $y=A\times e^{\left(bx-h\right)}+k$y=A×e(bxh)+k, what impact does each parameter have? Which parameters have been altered?

Do: We have $A=2$A=2 and $k=3$k=3, hence, the function has been vertically dilated by a factor of $2$2 and a vertical translation by $3$3 units upwards.

b) Sketch the function.

Think: From the basic graph of $y=e^x$y=ex a vertical dilation by a factor of $2$2 will stretch each point away from the $x$x-axis by a factor of $2$2. Hence, the point $\left(0,1\right)$(0,1) becomes $\left(0,2\right)$(0,2), $\left(1,e\right)$(1,e) becomes $\left(1,2e\right)$(1,2e) and so forth. Then we can shift the graph $3$3 units vertically, each point moves up $3$3 units and the horizontal asymptote becomes $y=3$y=3.

Do:

Step 1. Dilate the graph by a factor of $2$2 from the $x$x-axis. Step 2. Translate the graph upwards $3$3 units, this includes the horizontal asymptote.

 

Practice questions

Question 1

The functions $y=2^x$y=2x and $y=3^x$y=3x have been graphed on the same coordinate axes.

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  1. Using $e=2.718$e=2.718 and by considering the graph of $y=e^x$y=ex, complete the statement below:

    For $x>\editable{}$x>, the graph of $y=e^x$y=ex will lie above the graph of $y=\left(\editable{}\right)^x$y=()x and below the graph of $y=\left(\editable{}\right)^x$y=()x.

    For $x<\editable{}$x<, the graph of $y=e^x$y=ex will lie above the graph of $y=\left(\editable{}\right)^x$y=()x and below the graph of $y=\left(\editable{}\right)^x$y=()x.

Question 2

Using a graphing calculator, graph the curves of $y=e^x$y=ex, $y=e^x+2$y=ex+2, and $y=e^x-3$y=ex3 on the same screen.

  1. Select the correct statement from the following:

    The three graphs are the same.

    A

    The three graphs have the same shape.

    B

    The three graphs have the same $y$y-intercepts.

    C

    The three graphs have the same $x$x-intercepts.

    D

Question 3

Beginning with the equation $y=e^x$y=ex, we want to find the new function that results from the following transformations.

  1. Starting from $y=e^x$y=ex, the function is first dilated by a factor of $3$3 vertically. What is the equation of the new function?

  2. The function is then translated $2$2 units upwards. What is the equation of the new function?

  3. What is the equation of the horizontal asymptote of the new function?

  4. What is the value of the $y$y-intercept of the new function?

  5. Using the previous parts, choose the correct graph of the transformed function.

    Loading Graph...

    A

    Loading Graph...

    B

    Loading Graph...

    C

    Loading Graph...

    D

Outcomes

U34.AoS1.2

graphs of the following functions: power functions, y=x^n; exponential functions, y=a^x, in particular y = e^x ; logarithmic functions, y = log_e(x) and y=log_10(x) ; and circular functions, 𝑦 = sin(𝑥) , 𝑦 = cos (𝑥) and 𝑦 = tan(𝑥) and their key features

U34.AoS1.7

the key features and properties of a function or relation and its graph and of families of functions and relations and their graphs

U34.AoS1.14

identify key features and properties of the graph of a function or relation and draw the graphs of specified functions and relations, clearly identifying their key features and properties, including any vertical or horizontal asymptotes

U34.AoS1.10

the concepts of domain, maximal domain, range and asymptotic behaviour of functions

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