Textbook Question
In Exercises 1–3, perform the indicated operations and write the result in standard form. ___ ___ 2√−49 + 3√−64
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Ch. 5 - Complex Numbers, Polar Coordinates and Parametric Equations
Blitzer3rd EditionTrigonometryISBN: 9780137316601
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Blitzer 3rd EditionCh. 5 - Complex Numbers, Polar Coordinates and Parametric EquationsProblem 4
Blitzer 3rd EditionCh. 5 - Complex Numbers, Polar Coordinates and Parametric EquationsProblem 4Chapter 5, Problem 4
_ Write −√3 + i in polar form.
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Identify the complex number given: \(-\sqrt{3} + i\). Here, the real part is \(-\sqrt{3}\) and the imaginary part is \(1\).
Calculate the modulus \(r\) of the complex number using the formula \(r = \sqrt{x^2 + y^2}\), where \(x\) is the real part and \(y\) is the imaginary part. So, compute \(r = \sqrt{(-\sqrt{3})^2 + 1^2}\).
Find the argument \(\theta\) (also called the angle) using \(\theta = \tan^{-1}\left(\frac{y}{x}\right)\). Substitute \(x = -\sqrt{3}\) and \(y = 1\) to get \(\theta = \tan^{-1}\left(\frac{1}{-\sqrt{3}}\right)\).
Determine the correct quadrant for the angle \(\theta\). Since the real part is negative and the imaginary part is positive, the complex number lies in the second quadrant. Adjust the angle accordingly to reflect this quadrant.
Write the polar form of the complex number as \(r(\cos \theta + i \sin \theta)\) or equivalently \(r e^{i \theta}\), using the modulus \(r\) and the argument \(\theta\) found in the previous steps.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Complex Numbers in Cartesian and Polar Form
A complex number can be expressed in Cartesian form as a + bi, where a is the real part and b is the imaginary part. The polar form represents the same number using a magnitude (radius) and an angle (argument), written as r(cos θ + i sin θ) or r e^{iθ}, which is useful for multiplication and division.
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Complex Numbers In Polar Form
Magnitude (Modulus) of a Complex Number
The magnitude of a complex number a + bi is the distance from the origin to the point (a, b) in the complex plane, calculated as r = √(a² + b²). This value represents the radius in the polar form and is always non-negative.
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Argument (Angle) of a Complex Number
The argument θ of a complex number is the angle formed with the positive real axis, found using θ = arctan(b/a). It determines the direction of the vector representing the complex number in the plane and is essential for expressing the number in polar form.
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Related Practice
Textbook Question
In Exercises 1–8, parametric equations and a value for the parameter t are given. Find the coordinates of the point on the plane curve described by the parametric equations corresponding to the given value of t. x = t² + 1, y = 5 − t³; t = 2
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Textbook Question
In Exercises 1–8, parametric equations and a value for the parameter t are given. Find the coordinates of the point on the plane curve described by the parametric equations corresponding to the given value of t. x = t² + 3, y = 6 − t³; t = 2
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Textbook Question
In Exercises 21–28, divide and express the result in standard form.
2+3i / 2+i
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Textbook Question
In Exercises 45–52, use your answers from Exercises 41–44 and the parametric equations given in Exercises 41–44 to find a set of parametric equations for the conic section or the line.
Ellipse: Center: (−2,3); Vertices: 5 units to the left and right of the center; Endpoints of Minor Axis: 2 units above and below the center
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Textbook Question
In Exercises 1–10, perform the indicated operations and write the result in standard form. (3 − 4i)²
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