Introduction to Logarithms
Introduction to Logarithms
Have you ever looked at an equation like 2x=32 and wondered how to solve for x? A logarithm is the mathematical tool designed to do exactly that. It answers the question: "To what power must the base be raised to produce a given number?"
Exponents and Logarithms: Two Sides of the Same Coin
Logarithms and exponential functions are inverses of each other. Every exponential equation can be rewritten as a logarithmic equation, and vice versa.
The fundamental relationship is: logbâ(a)=câºbc=a
Here is what each part means:
- b is the base (the number being multiplied by itself).
- c is the exponent (the power the base is raised to).
- a is the argument (the result of the exponential expression).
When you read logbâ(a)=c, say out loud: "The power I need to raise b to, in order to get a, is c."
Evaluating Logarithms
Let's look at how to evaluate a logarithmic expression.
Example: Evaluate log2â(32).
- Set the expression equal to a variable: log2â(32)=x.
- Rewrite it in exponential form using the fundamental relationship: 2x=32.
- Ask yourself: "2 raised to what power equals 32?"
- Since 2Ã2Ã2Ã2Ã2=32, we know that 25=32.
- Therefore, log2â(32)=5.
Converting Between Forms
Being able to switch back and forth between exponential and logarithmic forms is a crucial skill in algebra.
Example: Rewrite 53=125 in logarithmic form.
- Identify the base (b=5), the exponent (c=3), and the result (a=125).
- Plug these into the logarithmic structure: logbâ(a)=c.
- The logarithmic form is: log5â(125)=3.
Important Restrictions
When working with logarithms logbâ(a), keep these rules in mind:
- The base b must be strictly greater than 0 and cannot equal 1 (b>0,bî =1).
- The argument a must be strictly positive (a>0). You cannot take the logarithm of zero or a negative number!