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Chapter 2: Problem 23

Find the real and imaginary parts of the complex number. $$-\pi i$$

Short Answer

Expert verified
The real part is 0. The imaginary part is \(-\pi\).

Step by step solution

01

Identify the Real Part

A real part in a complex number is represented by a number that does not have the imaginary unit 'i' associated with it. In the given complex number, \(-\pi i\), there is no such number. Therefore, the real part of the complex number is 0.
02

Identify the Imaginary Part

The imaginary part of the complex number is represented by the coefficient of 'i'. In this case, it's \(-\pi\), which is the imaginary part of the given complex number.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Real Part
The real part of a complex number is the component that doesn't involve the imaginary unit, which we represent as 'i'. For instance, if you have a complex number of the form \(a + bi\), 'a' is the real part and 'b' is the imaginary part. In the original exercise, we're looking at the complex number \(-\pi i\). Notice that there’s no term without 'i', which means there is no real component in this case.

Since no standalone number without 'i' exists in \(-\pi i\), the real part is simply 0. It might seem a little confusing because we’re often used to seeing a number before the imaginary part, but remember:
  • The real part is always the constant term without 'i'.
  • If no such term is present, the real part is 0.
Understanding this helps in separating complex numbers into their respective parts accurately.
Imaginary Part
The imaginary part in a complex number is equally essential to understand as it defines how the number interacts with the imaginary plane, a crucial concept in complex analysis. For a number expressed as \(a + bi\), the imaginary part is 'b'. It is strictly the coefficient that multiplies the imaginary unit 'i'.

In this scenario, with the complex number \(-\pi i\), we identify the imaginary part by noting what multiplies 'i'. Here, that would be \(-\pi\). So, the imaginary part is \(-\pi\).
  • Imaginary parts are always linked with the 'i', but are independent of it in calculation.
  • They can be positive, negative, fractions, or even irrational numbers like \(-\pi\).
Grasping the concept of the imaginary part aids significantly when solving or manipulating complex numbers.
Imaginary Unit
The imaginary unit, denoted as 'i', is a fundamental component of complex numbers. It's unique because it satisfies the equation \(i^2 = -1\). This property of the imaginary unit allows us to perform calculations involving the square root of negative numbers, which is not possible with real numbers alone.

In the complex number \(-\pi i\), 'i' works as an indicator showing that the number lies somewhere on the imaginary axis of the complex plane.
  • 'i' takes the square root of -1, a non-existent solution in the domain of real numbers.
  • Combinations of real numbers and 'i' form the basis of complex number calculations.
Understanding 'i' connects real and imaginary worlds, leading to a more comprehensive grasp of complex mathematics.

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Most popular questions from this chapter

The average amount of money spent on books and magazines per household in the United States can be modeled by the function \(r(t)=-0.2837 t^{2}+5.547 t+\) \(136.7 .\) Here, \(r(t)\) is in dollars and \(t\) is the number of years since \(1985 .\) The model is based on data for the years \(1985-2000 .\) According to this model, in what year(s) was the average expenditure per household for books and magazines equal to \(\$ 160 ?\) (Source: U.S. Bureau of Labor Statistics)

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