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Published byGeorge Robbins Modified over 9 years ago
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What are the two main features of a vector? Magnitude (length) and Direction (angle) How do we define the length of a complex number a + bi ? Absolute value:
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Another name for the absolute value (or magnitude) of a complex number is the MODULUS. To relate the modulus to circular trigonometry, if the complex number represents a point on a circle centered at the origin, then the modulus is equivalent to the radius of the circle containing that point. So … given a complex number z, such that z = a + bi,
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The other feature of a vector is its direction, which is measured as an angle. A complex number is referenced by an angle as well. The angle associated with a complex number is found in the same trigonometric way that the direction angle is found for a vector. These angles are measured between 0° and 360°,or between 0 and 2π. (Recall that you must consider the quadrant!)
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The angle θ for a complex number z = a + bi is referred to as the ARGUMENT and is found using For example: Given z = 3 + 4i, determine the modulus and the argument of z.
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We need to use the combination of the modulus (r) and the argument (θ) of a complex number in order to write complex numbers in trigonometric form, aka POLAR FORM. TRIGONOMETRIC FORM of a complex number:
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For example: Given z = 3 + 4i, re-write z in trigonometric form (aka polar form). From our previous example we know that Therefore, z = 3 + 4i = 5 cis 53.1°.
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Finally, think about how to reverse the process. How do you go from trigonometric (polar) form to standard complex number form (rectangular)? For example, write the complex number in rectangular form: 6 cis 120° = ___________
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Given two complex numbers in polar form: & Then, What about division of two complex numbers in polar form?
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Given a complex number in polar form: Then, Note: when completing these operations, if your new angle goes outside of the range of 0° to 360°, you will need to answer with a coterminal angle that is between 0° and 360°
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How is raising a number to a power related to multiplication? Since raising a number to a power represents repeated multiplication, the rule for raising a complex number to a power is an extension of the rule for multiplying complex numbers.
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Given two complex numbers in polar form: & Then, DeMoivre’s Theorem: Note: If (nθ) is too large, subtract 360 so that it falls within the acceptable range.
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One final reminder about polar form of complex numbers: This is important because if any of the operations you perform cause the angle to go outside of this range, then you must adjust it (using coterminal angle rules).
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Finding roots of a complex number requires just a little bit more trigonometry knowledge. 2 nd Recall from early trig lessons that coterminal angles are angles that differ by 360°. Therefore, if the argument of a complex number is 88°, then 88 + 360 = 448° is a coterminal angle and will need to be used when finding roots. 1 st Every non-zero complex number has exactly n n th roots. In other words, a complex number has 4 fourth roots, and nine ninth roots, etc.
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DeMoivre’s Theorem works for finding roots of complex numbers, too. It uses roots and division, instead of powers and multiplication.
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Example: Find all complex cube roots of Record answers in polar form.
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Quick Check: Please answer these questions on a clean sheet of paper & turn in when complete. Given and 1 st convert both numbers to polar form 2 nd find the product of z and w (in polar form) 3 rd find the quotient of z and w (in polar form) 4 th find z 6 (in polar form, then convert to rectangular) 5 th find the complex cube roots of w (in polar form)
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