mathleaks.com mathleaks.com Start chapters home Start History history History expand_more Community
Community expand_more
menu_open Close
{{ filterOption.label }}
{{ item.displayTitle }}
{{ item.subject.displayTitle }}
arrow_forward
No results
{{ searchError }}
search
Expand menu menu_open home
{{ courseTrack.displayTitle }}
{{ statistics.percent }}% Sign in to view progress
{{ printedBook.courseTrack.name }} {{ printedBook.name }}
search Use offline Tools apps
Login account_circle menu_open
Exponential and Logarithmic Functions

The Natural Base e

The number — commonly called the natural base — is an irrational mathematical constant named by the mathematician Leonhard Euler.

Euler's number appears in several areas of mathematics, and has multiple uses. For instance, it is often used as the base of exponential functions.

Explanation

Deriving

The value of the number can be found in different ways. Here, compound interest will be used to find its value. The formula for compound interest is the exponential growth function where the constant is the interest rate in decimal form. If the interest rate was which is extremely profitable, the value of equals The number is the amount of times the interest is compounded each year. That is, how often the accrued interest is added to the balance. The more often the interest is compounded, the higher the profit will be each year. What happens if the interest is compounded very often? That is, when is large. To examine this, the function will be rewritten using the the power of a power property. For the rewritten function, the expression inside the outer parentheses is a constant depending only on To analyze what happens when  increases, larger and larger values will be substituted into the expression.

Expression value

The table shows that for high values of the expression seems to approach In fact, as the value of the expression approaches the natural base : Substituting for the expression gives the function

which applies when the interest rate is compounded infinitely often. When interest is compounded infinitely often, it is said to be continuously compounded. Using this exponential function, instead of the original formula, makes this growth easier to work with.

Concept

Natural Base Exponential Function

Exponential functions are commonly expressed using the natural base , as they then exhibit useful characteristics. These functions are called natural base exponential functions and are written in the form If and are both positive, the function is an exponential growth function. If is positive and is negative, the resulting function is instead an exponential decay function.

fullscreen
Exercise


Determine whether the exponential function shows growth or decay. Then, rewrite the function in the form and graph it.

Show Solution
Solution

The function is currently expressed as a natural base exponential function, Thus, identifying the signs of the constants and will help us decide whether it is an exponential growth or decay function. Both and are positive in this case. Thus, it models an exponential growth. To rewrite the function as we have to make sure that the exponent is nothing but This is achieved using the power of a power property and calculating the new base.

Now that the function is rewritten, we can graph it as usual, starting by plotting the initial value,

Next, more points are found by repeatedly increasing the -value by and multiplying the function value by the constant multiplier,

Connecting the points with a smooth curve gives us the desired graph.


Rule

Continuously Compounded Interest

When an interest rate of is compounded continuously, meaning it is compounded infinitely often, the resulting function is When the interest rate is something other than the arbitrary rate is used. Suppose that the interest rate doubles, Because interest is compounded continuously, this effectively leads to the same growth in half the time. Similarly, three times the interest leads to the same growth in a third of the time. This corresponds to a horizontal stretch or shrink, leading to the following function.

fullscreen
Exercise


Carlos won the lottery! In total, his winnings are He wants to buy a high quality miniature blimp, which costs Since his winnings aren't enough, he's decided to deposit them into a savings account for years, earning yearly interest compounded continuously. Assuming the price stays constant, will he have enough money in his account to buy the miniature blimp after the years?

Show Solution
Solution

As the interest of the account is continuously compounded, the balance can be modeled with the function where is the principal and is the interest rate in decimal form. In this case, the principal is and the interest rate is resulting in the function By substituting into the function, we'll find the balance at years.

At years, his account balance will be Thus, he will be able to afford the miniature blimp at

{{ 'mldesktop-placeholder-grade-tab' | message }}
{{ 'mldesktop-placeholder-grade' | message }} {{ article.displayTitle }}!
{{ grade.displayTitle }}
{{ exercise.headTitle }}
{{ 'ml-tooltip-premium-exercise' | message }}
{{ 'ml-tooltip-programming-exercise' | message }} {{ 'course' | message }} {{ exercise.course }}
Test
{{ 'ml-heading-exercise' | message }} {{ focusmode.exercise.exerciseName }}
{{ 'ml-btn-previous-exercise' | message }} arrow_back {{ 'ml-btn-next-exercise' | message }} arrow_forward