Learn on PengiAoPS: Introduction to Algebra (AMC 8 & 10)Chapter 19: Exponents and Logarithms

Lesson 19.1: Exponential Functions

In this Grade 4 AMC Math lesson from AoPS: Introduction to Algebra, students explore exponential functions by examining what happens when a variable serves as the exponent rather than the base. Using a rice-and-chessboard story, students compare linear growth to exponential growth and practice applying exponent rules such as (a^b)^c = a^bc and (a^b)(a^c) = a^(b+c). The lesson also introduces real-world applications of exponential functions, including carbon dating and half-life calculations.

Section 1

Exponential Function

Property

An exponential function has the form

f(x)=abx,where b>0 and b1,a0f(x) = ab^x, \quad \text{where } b > 0 \text{ and } b \neq 1, \quad a \neq 0

The constant aa is the yy-intercept of the graph because f(0)=ab0=a1=af(0) = a \cdot b^0 = a \cdot 1 = a.
The positive constant bb is called the base. We do not allow bb to be negative, because if b<0b < 0, then bxb^x is not a real number for some values of xx. We also exclude b=1b = 1 because 1x=11^x = 1 for all values of xx, which is a constant function.

Examples

  • The function f(x)=5(2)xf(x) = 5(2)^x is an exponential function where the initial value is a=5a=5 and the growth factor is the base b=2b=2.
  • The function P(t)=100(0.75)tP(t) = 100(0.75)^t represents exponential decay with an initial amount of 100100 and a decay factor of 0.750.75.

Section 2

Exponent Rules for Exponential Functions

Property

Power of a Power Rule: (ab)c=abc(a^b)^c = a^{bc}

Product of Powers Rule: (ab)(ac)=ab+c(a^b)(a^c) = a^{b+c}

Section 3

Graphs of Exponential Functions

Property

For an exponential function f(x)=bxf(x) = b^x:

  • The graph always passes through the point (0,1)(0, 1), which is the y-intercept.
  • The x-axis (y=0y=0) is a horizontal asymptote, meaning the graph gets infinitely close but never touches it.
  • If the base b>1b > 1, the function is always increasing (representing exponential growth).
  • If 0<b<10 < b < 1, the function is always decreasing (representing exponential decay).

Examples

  • The graph of f(x)=3xf(x) = 3^x is an increasing function. It passes through (0,1)(0, 1) and rises sharply to the right as xx increases.

Lesson overview

Expand to review the lesson summary and core properties.

Expand

Section 1

Exponential Function

Property

An exponential function has the form

f(x)=abx,where b>0 and b1,a0f(x) = ab^x, \quad \text{where } b > 0 \text{ and } b \neq 1, \quad a \neq 0

The constant aa is the yy-intercept of the graph because f(0)=ab0=a1=af(0) = a \cdot b^0 = a \cdot 1 = a.
The positive constant bb is called the base. We do not allow bb to be negative, because if b<0b < 0, then bxb^x is not a real number for some values of xx. We also exclude b=1b = 1 because 1x=11^x = 1 for all values of xx, which is a constant function.

Examples

  • The function f(x)=5(2)xf(x) = 5(2)^x is an exponential function where the initial value is a=5a=5 and the growth factor is the base b=2b=2.
  • The function P(t)=100(0.75)tP(t) = 100(0.75)^t represents exponential decay with an initial amount of 100100 and a decay factor of 0.750.75.

Section 2

Exponent Rules for Exponential Functions

Property

Power of a Power Rule: (ab)c=abc(a^b)^c = a^{bc}

Product of Powers Rule: (ab)(ac)=ab+c(a^b)(a^c) = a^{b+c}

Section 3

Graphs of Exponential Functions

Property

For an exponential function f(x)=bxf(x) = b^x:

  • The graph always passes through the point (0,1)(0, 1), which is the y-intercept.
  • The x-axis (y=0y=0) is a horizontal asymptote, meaning the graph gets infinitely close but never touches it.
  • If the base b>1b > 1, the function is always increasing (representing exponential growth).
  • If 0<b<10 < b < 1, the function is always decreasing (representing exponential decay).

Examples

  • The graph of f(x)=3xf(x) = 3^x is an increasing function. It passes through (0,1)(0, 1) and rises sharply to the right as xx increases.