Imaginary Numbers (Intro)
By the end of this lesson, you’ll be able to:
- Understand why imaginary numbers were introduced.
- Interpret \(i\) as the square root of \(-1\).
- Rewrite negative square roots using \(i\).
- Distinguish between real, imaginary, and complex numbers.
Key Ideas
Imaginary numbers arise when we try to take the square root of a negative number.
Since no real number satisfies
\[
x^2 = -1,
\]
we define a new number:
\[ i = \sqrt{-1}. \]
This leads to:
- \(\sqrt{-9} = 3i\)
- \(\sqrt{-25} = 5i\)
- \(\sqrt{-a} = i\sqrt{a}\) for any positive \(a\)
A pure imaginary number looks like \(bi\), where \(b\) is real.
A complex number has the form
\[
a + bi,
\] where \(a\) and \(b\) are real.
Common Problem Types
Rewriting Square Roots of Negatives
Convert negative square roots into multiples of \(i\).
Example:
\(\sqrt{-12} = i\sqrt{12} = 2i\sqrt{3}\).
Distinguishing Real vs. Imaginary vs. Complex
Classify numbers.
Example:
- \(7\) → real
- \(4i\) → imaginary
- \(3 - 2i\) → complex
Using the Definition of \(i\)
Use \(i^2 = -1\) to simplify expressions.
Example:
\(\sqrt{-1} = i\), \(\sqrt{-16} = 4i\).
Converting Real–Imaginary Forms
Rewrite expressions like \(\sqrt{-a}\) into \(i\sqrt{a}\).
Example:
\(\sqrt{-50} = 5i\sqrt{2}\)
Strategies
- Always rewrite \(\sqrt{-a}\) as \(i\sqrt{a}\).
- Factor the negative first:
\[ \sqrt{-a} = \sqrt{-1}\sqrt{a} = i\sqrt{a}. \] - Check whether the expression simplifies (perfect squares).
- Recognize “complex number” includes all real numbers too.
Worked Examples
Example 1 — Rewrite a negative square root
\[ \sqrt{-18} = i\sqrt{18} = 3i\sqrt{2}. \]
Example 2 — Classify a number
Number: \(12 - 7i\)
- Real part: \(12\)
- Imaginary part: \(-7i\)
This is complex.
Example 3 — Evaluate
\[ \sqrt{-49} = 7i. \]
- Forgetting to pull out the negative: rewrite \(\sqrt{-a}\) as \(i\sqrt{a}\).
- Thinking imaginary numbers “don’t exist”—they extend the number system.
- Mixing up real vs. imaginary vs. complex categories.
- Simplifying incorrectly: \(\sqrt{-ab} \neq \sqrt{-a}\sqrt{-b}\).
Practice Problems
- Rewrite: \(\sqrt{-20}\).
- Determine the type (real, imaginary, complex):
- \(5i\)
- \(-3\)
- \(7 + 4i\)
- \(5i\)
- Simplify: \(\sqrt{-64}\).
- Rewrite: \(\sqrt{-72}\) in simplest radical form.
1.
\[
\sqrt{-20} = i\sqrt{20} = 2i\sqrt{5}.
\]
2a. \(5i\): imaginary
2b. \(-3\): real
2c. \(7 + 4i\): complex
3.
\[
\sqrt{-64} = 8i.
\]
4.
\[
\sqrt{-72} = i\sqrt{72} = 6i\sqrt{2}.
\]
Summary
- Imaginary numbers arise from the definition \(i = \sqrt{-1}\).
- Rewrite \(\sqrt{-a}\) as \(i\sqrt{a}\).
- Pure imaginary numbers look like \(bi\).
- Complex numbers look like \(a + bi\).
- Always factor out \(\sqrt{-1} = i\).
- Real numbers are a subset of complex numbers.
- Check for perfect squares before simplifying.