exponential function

(noun)

Any function in which an independent variable is in the form of an exponent; they are the inverse functions of logarithms.

Related Terms

  • Interest
  • compound interest
  • tangent
  • asymptote
  • exponential growth

Examples of exponential function in the following topics:

  • The Natural Exponential Function: Differentiation and Integration

    • Now that we have derived a specific case, let us extend things to the general case of exponential function.
    • Here we consider integration of natural exponential function.
    • Note that the exponential function $y = e^{x}$ is defined as the inverse of $\ln(x)$.
  • Derivatives of Exponential Functions

    • The derivative of the exponential function is equal to the value of the function.
    • The importance of the exponential function in mathematics and the sciences stems mainly from properties of its derivative.
    • Functions of the form $ce^x$ for constant $c$ are the only functions with this property.
    • If a variable's growth or decay rate is proportional to its size—as is the case in unlimited population growth, continuously compounded interest, or radioactive decay—then the variable can be written as a constant times an exponential function of time.
    • Graph of the exponential function illustrating that its derivative is equal to the value of the function.
  • Graphs of Exponential Functions, Base e

    • The function $f(x) = e^x$ is a basic exponential function with some very interesting properties.
    • The basic exponential function, sometimes referred to as the exponential function, is $f(x)=e^{x}$ where $e$ is the number (approximately 2.718281828) described previously.
    • The exponential function is used to model a relationship in which a constant change in the independent variable gives the same proportional change (i.e., percentage increase or decrease) in the dependent variable.
    • If the change is positive, this is called exponential growth and if it is negative, it is called exponential decay.
    • For example, because a radioactive substance decays at a rate proportional to the amount of the substance present, the amount of the substance present at a given time can be modeled with an exponential function.
  • Exponential and Logarithmic Functions

    • Both exponential and logarithmic functions are widely used in scientific and engineering applications.
    • Exponential function is the function $e^x$ the number (approximately 2.718281828) such that the function $e^x$ is its own derivative .
    • The exponential function arises whenever a quantity grows or decays at a rate proportional to its current value.
    • The exponential function $e^x$ can be characterized in a variety of equivalent ways.
    • The derivative (or slope of a tangential line) of the exponential function is equal to the value of the function.
  • Introduction to Exponential and Logarithmic Functions

    • Logarithmic functions and exponential functions are inverses of each other.
    • The inverse of an exponential function is a logarithmic function and vice versa.
    • That is, the two functions undo each other.
    • In the following graph you can see an exponential function in red and its inverse, a logarithmic function, in blue.
    • The natural logarithm is the inverse of the exponential function $f(x)=e^x$.
  • Basics of Graphing Exponential Functions

    • The exponential function $y=b^x$ where $b>0$ is a function that will remain proportional to its original value when it grows or decays.
    • At the most basic level, an exponential function is a function in which the variable appears in the exponent.
    • The most basic exponential function is a function of the form $y=b^x$ where $b$ is a positive number.
    • This is true of the graph of all exponential functions of the form $y=b^x$ for $x>1$.
    • This is true of the graph of all exponential functions of the form $y=b^x$ for $0
  • Problem-Solving

    • Graphically solving problems with exponential functions allows visualization of sometimes complicated interrelationships.
    • The exponential function has numerous applications.
    • Biology, Economics, and Finance are only just a few of the applications that use exponential functions.
    • In general, a real world application that can be modeled with an exponential function is one that will continuously increase at an increasing rate based on the current value.
    • Graph of an exponential function with the equation $y=2^x$.
  • Limited Growth

    • Exponential functions can be used to model growth and decay.
    • Even if we account for varying rates of growth, the idea that human population can be modeled strictly with an exponential function is misguided.
    • Exponential functions are ever-increasing so saying that an exponential function models population growth exactly means that the human population will grow without bound.
    • Graphically, the logistic function resembles an exponential function followed by a logarithmic function that approaches a horizontal asymptote.
    • Below is the graph of a logistic function.
  • Exponential Growth and Decay

    • Exponential growth occurs when the growth rate of the value of a mathematical function is proportional to the function's current value.
    • Exponential growth occurs when the growth rate of the value of a mathematical function is proportional to the function's current value.
    • Exponential decay occurs in the same way, providing the growth rate is negative.
    • If $\tau > 0$ and $b > 1$, then $x$ has exponential growth.
    • Apply the exponential growth and decay formulas to real world examples
  • Exponential Decay

    • Exponential decay is the result of a function that decreases in proportion to its current value.
    • Just as it is possible for a variable to grow exponentially as a function of another, so can the a variable decrease exponentially.
    • Exponential rate of change can be modeled algebraically by the following formula:
    • The exponential decay of the substance is a time-dependent decline and a prime example of exponential decay.
    • Below is a graph highlighting exponential decay of a radioactive substance.
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